Add cuda_device_count_stateless (#5473 )

[Kernel] Disable CUTLASS kernels for fp8 (#5505 )
[CI/Build] Disable test_fp8.py (#5508 )
2024-06-13 16:06:49 -07:00 · 2024-06-13 13:38:05 -07:00 · 2024-06-13 13:37:48 -07:00 · 2024-06-13 12:09:16 -07:00 · 2024-06-13 11:22:50 -07:00 · 2024-06-13 11:22:41 -07:00
637 changed files with 75021 additions and 16078 deletions
--- a/.buildkite/check-wheel-size.py
+++ b/.buildkite/check-wheel-size.py
@@ -0,0 +1,36 @@
 import os
 import zipfile
 MAX_SIZE_MB = 200
 def print_top_10_largest_files(zip_file):
    with zipfile.ZipFile(zip_file, 'r') as z:
        file_sizes = [(f, z.getinfo(f).file_size) for f in z.namelist()]
        file_sizes.sort(key=lambda x: x[1], reverse=True)
        for f, size in file_sizes[:10]:
            print(f"{f}: {size/(1024*1024)} MBs uncompressed.")
 def check_wheel_size(directory):
    for root, _, files in os.walk(directory):
        for f in files:
            if f.endswith(".whl"):
                wheel_path = os.path.join(root, f)
                wheel_size = os.path.getsize(wheel_path)
                wheel_size_mb = wheel_size / (1024 * 1024)
                if wheel_size_mb > MAX_SIZE_MB:
                    print(
                        f"Wheel {wheel_path} is too large ({wheel_size_mb} MB) "
                        f"compare to the allowed size ({MAX_SIZE_MB} MB).")
                    print_top_10_largest_files(wheel_path)
                    return 1
                else:
                    print(f"Wheel {wheel_path} is within the allowed size "
                          f"({wheel_size_mb} MB).")
    return 0
 if __name__ == "__main__":
    import sys
    sys.exit(check_wheel_size(sys.argv[1]))
--- a/.buildkite/nightly-benchmarks/kickoff-pipeline.sh
+++ b/.buildkite/nightly-benchmarks/kickoff-pipeline.sh
@@ -0,0 +1,26 @@
 #!/usr/bin/env bash
 set -euo pipefail
 # Install system packages
 apt update
 apt install -y curl jq
 # Install minijinja for templating
 curl -sSfL https://github.com/mitsuhiko/minijinja/releases/latest/download/minijinja-cli-installer.sh | sh
 source $HOME/.cargo/env
 # If BUILDKITE_PULL_REQUEST != "false", then we check the PR labels using curl and jq
 if [ "$BUILDKITE_PULL_REQUEST" != "false" ]; then
  PR_LABELS=$(curl -s "https://api.github.com/repos/vllm-project/vllm/pulls/$BUILDKITE_PULL_REQUEST" | jq -r '.labels[].name')
  if [[ $PR_LABELS == *"perf-benchmarks"* ]]; then
    echo "This PR has the 'perf-benchmarks' label. Proceeding with the nightly benchmarks."
  else
    echo "This PR does not have the 'perf-benchmarks' label. Skipping the nightly benchmarks."
    exit 0
  fi
 fi
 # Upload sample.yaml
 buildkite-agent pipeline upload .buildkite/nightly-benchmarks/sample.yaml
--- a/.buildkite/nightly-benchmarks/sample.yaml
+++ b/.buildkite/nightly-benchmarks/sample.yaml
@@ -0,0 +1,39 @@
 steps:
  # NOTE(simon): You can create separate blocks for different jobs
  - label: "A100: NVIDIA SMI"
    agents:
      queue: A100
    plugins:
    - kubernetes:
        podSpec:
          containers:
          # - image: us-central1-docker.pkg.dev/vllm-405802/vllm-ci-test-repo/vllm-test:$BUILDKITE_COMMIT
          # TODO(simon): check latest main branch or use the PR image.
          - image: us-central1-docker.pkg.dev/vllm-405802/vllm-ci-test-repo/vllm-test:45c35f0d58f4508bf43bd6af1d3d0d0ec0c915e6
            command:
            - bash -c 'nvidia-smi && nvidia-smi topo -m && pwd && ls'
            resources:
              limits:
                nvidia.com/gpu: 8
            volumeMounts:
            - name: devshm
              mountPath: /dev/shm
          nodeSelector:
            nvidia.com/gpu.product: NVIDIA-A100-SXM4-80GB
          volumes:
          - name: devshm
            emptyDir:
              medium: Memory
  # TODO(simon): bring H100 online
  # - label: "H100: NVIDIA SMI"
  #   agents:
  #     queue: H100
  #   plugins:
  #   - docker#v5.11.0:
  #       image: us-central1-docker.pkg.dev/vllm-405802/vllm-ci-test-repo/vllm-test:45c35f0d58f4508bf43bd6af1d3d0d0ec0c915e6
  #       command:
  #       - bash -c 'nvidia-smi && nvidia-smi topo -m'
  #       propagate-environment: true
  #       ipc: host
  #       gpus: all
--- a/.buildkite/run-amd-test.sh
+++ b/.buildkite/run-amd-test.sh
@@ -1,38 +1,73 @@
-# This script build the ROCm docker image and run the API server inside the container.
+# This script runs test inside the corresponding ROCm docker container.
 # It serves a sanity check for compilation and basic model usage.
 set -ex
 # Print ROCm version
 echo "--- ROCm info"
 rocminfo
-# Try building the docker image
+# cleanup older docker images
-docker build -t rocm -f Dockerfile.rocm .
+cleanup_docker() {
-
+  # Get Docker's root directory
-# Setup cleanup
+  docker_root=$(docker info -f '{{.DockerRootDir}}')
-remove_docker_container() { docker rm -f rocm || true; }
+  if [ -z "$docker_root" ]; then
-trap remove_docker_container EXIT
+    echo "Failed to determine Docker root directory."
-remove_docker_container
+    exit 1
-
+  fi
-# Run the image
+  echo "Docker root directory: $docker_root"
-docker run --device /dev/kfd --device /dev/dri --network host --name rocm rocm python3 -m vllm.entrypoints.api_server &
+  # Check disk usage of the filesystem where Docker's root directory is located
-
+  disk_usage=$(df "$docker_root" | tail -1 | awk '{print $5}' | sed 's/%//')
-# Wait for the server to start
+  # Define the threshold
-wait_for_server_to_start() {
+  threshold=70
-    timeout=300
+  if [ "$disk_usage" -gt "$threshold" ]; then
-    counter=0
+    echo "Disk usage is above $threshold%. Cleaning up Docker images and volumes..."
-
+    # Remove dangling images (those that are not tagged and not used by any container)
-    while [ "$(curl -s -o /dev/null -w ''%{http_code}'' localhost:8000/health)" != "200" ]; do
+    docker image prune -f
-        sleep 1
+    # Remove unused volumes
-        counter=$((counter + 1))
+    docker volume prune -f
-        if [ $counter -ge $timeout ]; then
+    echo "Docker images and volumes cleanup completed."
-            echo "Timeout after $timeout seconds"
+  else
-            break
+    echo "Disk usage is below $threshold%. No cleanup needed."
-        fi
+  fi
    done
 }
 wait_for_server_to_start
-# Test a simple prompt
+# Call the cleanup docker function
-curl -X POST -H "Content-Type: application/json" \
+cleanup_docker
-    localhost:8000/generate \
+
-    -d '{"prompt": "San Francisco is a"}'
+echo "--- Resetting GPUs"
 echo "reset" > /opt/amdgpu/etc/gpu_state
 while true; do
        sleep 3
        if grep -q clean /opt/amdgpu/etc/gpu_state; then
                echo "GPUs state is \"clean\""
                break
        fi
 done
 echo "--- Building container"
 sha=$(git rev-parse --short HEAD)
 image_name=rocm_${sha}
 container_name=rocm_${sha}_$(tr -dc A-Za-z0-9 < /dev/urandom | head -c 10; echo)
 docker build \
        -t ${image_name} \
        -f Dockerfile.rocm \
        --progress plain \
        .
 remove_docker_container() {
   docker rm -f ${container_name} || docker image rm -f ${image_name} || true
 }
 trap remove_docker_container EXIT
 echo "--- Running container"
 docker run \
        --device /dev/kfd --device /dev/dri \
        --network host \
        --rm \
        -e HF_TOKEN \
        --name ${container_name} \
        ${image_name} \
        /bin/bash -c "${@}"
--- a/.buildkite/run-benchmarks.sh
+++ b/.buildkite/run-benchmarks.sh
@@ -9,10 +9,10 @@ cd "$(dirname "${BASH_SOURCE[0]}")/.."
 (which wget && which curl) || (apt-get update && apt-get install -y wget curl)
 # run python-based benchmarks and upload the result to buildkite
-python3 benchmarks/benchmark_latency.py 2>&1 | tee benchmark_latency.txt
+python3 benchmarks/benchmark_latency.py --output-json latency_results.json 2>&1 | tee benchmark_latency.txt
 bench_latency_exit_code=$?
-python3 benchmarks/benchmark_throughput.py --input-len 256 --output-len 256 2>&1 | tee benchmark_throughput.txt
+python3 benchmarks/benchmark_throughput.py --input-len 256 --output-len 256 --output-json throughput_results.json 2>&1 | tee benchmark_throughput.txt
 bench_throughput_exit_code=$?
 # run server-based benchmarks and upload the result to buildkite
@@ -50,11 +50,16 @@ echo "### Serving Benchmarks" >> benchmark_results.md
 sed -n '1p' benchmark_serving.txt >> benchmark_results.md # first line
 echo "" >> benchmark_results.md
 echo '```' >> benchmark_results.md
-tail -n 20 benchmark_serving.txt >> benchmark_results.md # last 20 lines
+tail -n 24 benchmark_serving.txt >> benchmark_results.md # last 24 lines
 echo '```' >> benchmark_results.md
 # if the agent binary is not found, skip uploading the results, exit 0
 if [ ! -f /usr/bin/buildkite-agent ]; then
    exit 0
 fi
 # upload the results to buildkite
-/workspace/buildkite-agent annotate --style "info" --context "benchmark-results" < benchmark_results.md
+buildkite-agent annotate --style "info" --context "benchmark-results" < benchmark_results.md
 # exit with the exit code of the benchmarks
 if [ $bench_latency_exit_code -ne 0 ]; then
@@ -69,4 +74,5 @@ if [ $bench_serving_exit_code -ne 0 ]; then
    exit $bench_serving_exit_code
 fi
-/workspace/buildkite-agent artifact upload openai-*.json
+rm ShareGPT_V3_unfiltered_cleaned_split.json
 buildkite-agent artifact upload "*.json"
--- a/.buildkite/run-cpu-test.sh
+++ b/.buildkite/run-cpu-test.sh
@@ -0,0 +1,24 @@
 # This script build the CPU docker image and run the offline inference inside the container.
 # It serves a sanity check for compilation and basic model usage.
 set -ex
 # Try building the docker image
 docker build -t cpu-test -f Dockerfile.cpu .
 # Setup cleanup
 remove_docker_container() { docker rm -f cpu-test || true; }
 trap remove_docker_container EXIT
 remove_docker_container
 # Run the image
 docker run -itd -v ~/.cache/huggingface:/root/.cache/huggingface --cpuset-cpus=48-95 --cpuset-mems=1 --network host -e HF_TOKEN --env VLLM_CPU_KVCACHE_SPACE=4 --name cpu-test cpu-test
 # offline inference
 docker exec cpu-test bash -c "python3 examples/offline_inference.py"
 # Run basic model test
 docker exec cpu-test bash -c "cd tests;
  pip install pytest Pillow protobuf
  bash ../.buildkite/download-images.sh
  cd ../
  pytest -v -s tests/models --ignore=tests/models/test_llava.py --ignore=tests/models/test_embedding.py --ignore=tests/models/test_registry.py"
--- a/.buildkite/run-neuron-test.sh
+++ b/.buildkite/run-neuron-test.sh
@@ -0,0 +1,51 @@
 # This script build the Neuron docker image and run the API server inside the container.
 # It serves a sanity check for compilation and basic model usage.
 set -e
 # Try building the docker image
 aws ecr get-login-password --region us-west-2 | docker login --username AWS --password-stdin 763104351884.dkr.ecr.us-west-2.amazonaws.com
 # prune old image and containers to save disk space, and only once a day
 # by using a timestamp file in tmp.
 if [ -f /tmp/neuron-docker-build-timestamp ]; then
    last_build=$(cat /tmp/neuron-docker-build-timestamp)
    current_time=$(date +%s)
    if [ $((current_time - last_build)) -gt 86400 ]; then
        docker system prune -f
        echo $current_time > /tmp/neuron-docker-build-timestamp
    fi
 else
    echo $(date +%s) > /tmp/neuron-docker-build-timestamp
 fi
 docker build -t neuron -f Dockerfile.neuron .
 # Setup cleanup
 remove_docker_container() { docker rm -f neuron || true; }
 trap remove_docker_container EXIT
 remove_docker_container
 # Run the image
 docker run --device=/dev/neuron0 --device=/dev/neuron1 --network host --name neuron neuron python3 -m vllm.entrypoints.api_server \
       --model TinyLlama/TinyLlama-1.1B-Chat-v1.0 --max-num-seqs 8 --max-model-len 128 --block-size 128 --device neuron --tensor-parallel-size 2 &
 # Wait for the server to start
 wait_for_server_to_start() {
    timeout=300
    counter=0
    while [ "$(curl -s -o /dev/null -w ''%{http_code}'' localhost:8000/health)" != "200" ]; do
        sleep 1
        counter=$((counter + 1))
        if [ $counter -ge $timeout ]; then
            echo "Timeout after $timeout seconds"
            break
        fi
    done
 }
 wait_for_server_to_start
 # Test a simple prompt
 curl -X POST -H "Content-Type: application/json" \
    localhost:8000/generate \
    -d '{"prompt": "San Francisco is a"}'
--- a/.buildkite/test-pipeline.yaml
+++ b/.buildkite/test-pipeline.yaml
@@ -5,92 +5,165 @@
 steps:
 - label: Regression Test
  mirror_hardwares: [amd]
  command: pytest -v -s test_regression.py
  working_dir: "/vllm-workspace/tests" # optional
 - label: AsyncEngine Test
  #mirror_hardwares: [amd]
  command: pytest -v -s async_engine
 - label: Basic Correctness Test
-  command: pytest -v -s basic_correctness
+  mirror_hardwares: [amd]
  commands:
  - VLLM_ATTENTION_BACKEND=XFORMERS pytest -v -s basic_correctness/test_basic_correctness.py
  - VLLM_ATTENTION_BACKEND=FLASH_ATTN pytest -v -s basic_correctness/test_basic_correctness.py
  - VLLM_ATTENTION_BACKEND=XFORMERS pytest -v -s basic_correctness/test_chunked_prefill.py
  - VLLM_ATTENTION_BACKEND=FLASH_ATTN pytest -v -s basic_correctness/test_chunked_prefill.py
  - VLLM_TEST_ENABLE_ARTIFICIAL_PREEMPT=1 pytest -v -s basic_correctness/test_preemption.py
 - label: Core Test
  mirror_hardwares: [amd]
  command: pytest -v -s core
 - label: Distributed Comm Ops Test
-  command: pytest -v -s test_comm_ops.py
+  #mirror_hardwares: [amd]
-  working_dir: "/vllm-workspace/tests/distributed"
+  command: pytest -v -s distributed/test_comm_ops.py
-  num_gpus: 2 # only support 1 or 2 for now.
+  working_dir: "/vllm-workspace/tests"
  num_gpus: 2
 - label: Distributed Tests
-  working_dir: "/vllm-workspace/tests/distributed"
+  mirror_hardwares: [amd]
-  num_gpus: 2 # only support 1 or 2 for now.
+  working_dir: "/vllm-workspace/tests"
  num_gpus: 2
  commands:
-  - pytest -v -s test_pynccl.py
+  - VLLM_TEST_SAME_HOST=1 torchrun --nproc-per-node=4 distributed/test_same_node.py
-  - TEST_DIST_MODEL=facebook/opt-125m pytest -v -s test_basic_distributed_correctness.py
+  - TEST_DIST_MODEL=facebook/opt-125m DISTRIBUTED_EXECUTOR_BACKEND=ray pytest -v -s distributed/test_basic_distributed_correctness.py
-  - TEST_DIST_MODEL=meta-llama/Llama-2-7b-hf pytest -v -s test_basic_distributed_correctness.py
+  - TEST_DIST_MODEL=meta-llama/Llama-2-7b-hf DISTRIBUTED_EXECUTOR_BACKEND=ray pytest -v -s distributed/test_basic_distributed_correctness.py
  - TEST_DIST_MODEL=facebook/opt-125m DISTRIBUTED_EXECUTOR_BACKEND=ray pytest -v -s distributed/test_chunked_prefill_distributed.py
  - TEST_DIST_MODEL=meta-llama/Llama-2-7b-hf DISTRIBUTED_EXECUTOR_BACKEND=ray pytest -v -s distributed/test_chunked_prefill_distributed.py
  - TEST_DIST_MODEL=facebook/opt-125m DISTRIBUTED_EXECUTOR_BACKEND=mp pytest -v -s distributed/test_basic_distributed_correctness.py
  - TEST_DIST_MODEL=meta-llama/Llama-2-7b-hf DISTRIBUTED_EXECUTOR_BACKEND=mp pytest -v -s distributed/test_basic_distributed_correctness.py
  - TEST_DIST_MODEL=facebook/opt-125m DISTRIBUTED_EXECUTOR_BACKEND=mp pytest -v -s distributed/test_chunked_prefill_distributed.py
  - TEST_DIST_MODEL=meta-llama/Llama-2-7b-hf DISTRIBUTED_EXECUTOR_BACKEND=mp pytest -v -s distributed/test_chunked_prefill_distributed.py
  - pytest -v -s spec_decode/e2e/test_integration_dist.py
  - CUDA_VISIBLE_DEVICES=0,1 pytest -v -s test_sharded_state_loader.py
  - CUDA_VISIBLE_DEVICES=0,1 pytest -v -s distributed/test_utils.py
 - label: Distributed Tests (Multiple Groups)
  #mirror_hardwares: [amd]
  working_dir: "/vllm-workspace/tests"
  num_gpus: 4
  commands:
  - pytest -v -s distributed/test_pynccl.py
 - label: Engine Test
-  command: pytest -v -s engine tokenization test_sequence.py test_config.py
+  mirror_hardwares: [amd]
  command: pytest -v -s engine tokenization test_sequence.py test_config.py test_logger.py
 - label: Entrypoints Test
-  command: pytest -v -s entrypoints
+  mirror_hardwares: [amd]
  commands:
  - pytest -v -s entrypoints -m llm
  - pytest -v -s entrypoints -m openai
 - label: Examples Test
  working_dir: "/vllm-workspace/examples"
  mirror_hardwares: [amd]
  commands:
    # install aws cli for llava_example.py
-    - pip install awscli
+    # install tensorizer for tensorize_vllm_model.py
    - pip install awscli tensorizer
    - python3 offline_inference.py
    - python3 offline_inference_with_prefix.py
    - python3 llm_engine_example.py
    - python3 llava_example.py
    - python3 tensorize_vllm_model.py --model facebook/opt-125m serialize --serialized-directory /tmp/ --suffix v1 && python3 tensorize_vllm_model.py --model facebook/opt-125m deserialize --path-to-tensors /tmp/vllm/facebook/opt-125m/v1/model.tensors
 - label: Inputs Test
  #mirror_hardwares: [amd]
  commands:
    - bash ../.buildkite/download-images.sh
    - pytest -v -s test_inputs.py
    - pytest -v -s multimodal
 - label: Kernels Test %N
  #mirror_hardwares: [amd]
  command: pytest -v -s kernels --shard-id=$$BUILDKITE_PARALLEL_JOB --num-shards=$$BUILDKITE_PARALLEL_JOB_COUNT
  parallelism: 4
 - label: Models Test
  #mirror_hardwares: [amd]
  commands:
-    - bash ../.buildkite/download-images.sh
+    - pytest -v -s models -m \"not llava\"
    - pytest -v -s models --ignore=models/test_llava.py --ignore=models/test_mistral.py
 - label: Llava Test
  mirror_hardwares: [amd]
  commands:
    - bash ../.buildkite/download-images.sh
-    - pytest -v -s models/test_llava.py
+    - pytest -v -s models -m llava
 - label: Prefix Caching Test
  mirror_hardwares: [amd]
  commands:
    - pytest -v -s prefix_caching
 - label: Samplers Test
  #mirror_hardwares: [amd]
  command: pytest -v -s samplers
 - label: LogitsProcessor Test
  mirror_hardwares: [amd]
  command: pytest -v -s test_logits_processor.py
 - label: Utils Test
  command: pytest -v -s test_utils.py
 - label: Worker Test
  mirror_hardwares: [amd]
  command: pytest -v -s worker
 - label: Speculative decoding tests
-  command: pytest -v -s spec_decode
+  #mirror_hardwares: [amd]
  commands:
    # See https://github.com/vllm-project/vllm/issues/5152
    - export VLLM_ATTENTION_BACKEND=XFORMERS
    - pytest -v -s spec_decode
 - label: LoRA Test %N
-  command: pytest -v -s lora --shard-id=$$BUILDKITE_PARALLEL_JOB --num-shards=$$BUILDKITE_PARALLEL_JOB_COUNT
+  #mirror_hardwares: [amd]
  command: pytest -v -s lora --shard-id=$$BUILDKITE_PARALLEL_JOB --num-shards=$$BUILDKITE_PARALLEL_JOB_COUNT --ignore=lora/test_long_context.py
  parallelism: 4
 - label: LoRA Long Context (Distributed)
  #mirror_hardwares: [amd]
  num_gpus: 4
  # This test runs llama 13B, so it is required to run on 4 GPUs.
  commands:
    - pytest -v -s -x lora/test_long_context.py
 - label: Tensorizer Test
  #mirror_hardwares: [amd]
  command: apt-get install curl libsodium23 && pytest -v -s tensorizer_loader
 - label: Metrics Test
  mirror_hardwares: [amd]
  command: pytest -v -s metrics
 - label: Quantization Test
  #mirror_hardwares: [amd]
  command: pytest -v -s quantization
 - label: Benchmarks
  working_dir: "/vllm-workspace/.buildkite"
  mirror_hardwares: [amd]
  commands:
  - pip install aiohttp
  - bash run-benchmarks.sh
 - label: Documentation Build
-  working_dir: "/vllm-workspace/docs"
+  working_dir: "/vllm-workspace/test_docs/docs"
  no_gpu: True
  commands:
  - pip install -r requirements-docs.txt
--- a/.buildkite/test-template-aws.j2
+++ b/.buildkite/test-template-aws.j2
@@ -0,0 +1,92 @@
 {% set docker_image = "public.ecr.aws/q9t5s3a7/vllm-ci-test-repo:$BUILDKITE_COMMIT" %}
 {% set default_working_dir = "/vllm-workspace/tests" %}
 steps:
  - label: ":docker: build image"
    agents:
      queue: cpu_queue
    commands:
      - "aws ecr-public get-login-password --region us-east-1 | docker login --username AWS --password-stdin public.ecr.aws/q9t5s3a7"
      - "docker build --build-arg max_jobs=16 --build-arg USE_SCCACHE=1 --tag {{ docker_image }} --target test --progress plain ."
      - "docker push {{ docker_image }}"
    env:
      DOCKER_BUILDKIT: "1"
    retry:
      automatic:
        - exit_status: -1  # Agent was lost
          limit: 5
        - exit_status: -10  # Agent was lost
          limit: 5
  - wait
  - group: "AMD Tests"
    depends_on: ~
    steps:
    {% for step in steps %}
    {% if step.mirror_hardwares and "amd" in step.mirror_hardwares %}
      - label: "AMD: {{ step.label }}"
        agents:
          queue: amd
        command: bash .buildkite/run-amd-test.sh "cd {{ (step.working_dir or default_working_dir) | safe  }} ; {{ step.command  or (step.commands | join(" ; ")) | safe }}"
        env:
          DOCKER_BUILDKIT: "1"
        soft_fail: true
    {% endif %}
    {% endfor %}
  - label: "Neuron Test"
    depends_on: ~
    agents:
      queue: neuron
    command: bash .buildkite/run-neuron-test.sh
    soft_fail: false
  - label: "Intel Test"
    depends_on: ~
    agents:
      queue: intel
    command: bash .buildkite/run-cpu-test.sh
  {% for step in steps %}
  - label: "{{ step.label }}"
    agents:
      {% if step.label == "Documentation Build" %}
      queue: small_cpu_queue
      {% elif step.no_gpu %}
      queue: cpu_queue
      {% elif step.num_gpus == 2 or step.num_gpus == 4 %}
      queue: gpu_4_queue
      {% else %}
      queue: gpu_1_queue
      {% endif %}
    soft_fail: {{ step.soft_fail or false }}
    {% if step.parallelism %}
    parallelism: {{ step.parallelism }}
    {% endif %}
    retry:
      automatic:
        - exit_status: -1  # Agent was lost
          limit: 5
        - exit_status: -10  # Agent was lost
          limit: 5
    plugins:
      - docker#v5.2.0:
          image: {{ docker_image }}
          always-pull: true
          propagate-environment: true
          {% if not step.no_gpu %}
          gpus: all
          {% endif %}
          {% if step.label == "Benchmarks" %}
          mount-buildkite-agent: true
          {% endif %}
          command: ["bash", "-c", "cd {{ (step.working_dir or default_working_dir) | safe  }} && {{ step.command  or (step.commands | join(' && ')) | safe }}"]
          environment:
            - VLLM_USAGE_SOURCE=ci-test
            - HF_TOKEN
            {% if step.label == "Speculative decoding tests" %}
            - VLLM_ATTENTION_BACKEND=XFORMERS
            {% endif %}
          volumes:
            - /dev/shm:/dev/shm
  {% endfor %}
--- a/.buildkite/test-template.j2
+++ b/.buildkite/test-template.j2
@@ -3,11 +3,6 @@
 {% set default_working_dir = "/vllm-workspace/tests" %}
 steps:
  - label: "AMD Test"
    agents:
      queue: amd
    command: bash .buildkite/run-amd-test.sh
  - label: ":docker: build image"
    commands:
      - "docker build --build-arg max_jobs=16 --tag {{ docker_image }} --target test --progress plain ."
@@ -18,8 +13,38 @@ steps:
      automatic:
        - exit_status: -1  # Agent was lost
          limit: 5
        - exit_status: -10  # Agent was lost
          limit: 5
  - wait
  - group: "AMD Tests"
    depends_on: ~
    steps:
    {% for step in steps %}
    {% if step.mirror_hardwares and "amd" in step.mirror_hardwares %}
      - label: "AMD: {{ step.label }}"
        agents:
          queue: amd
        command: bash .buildkite/run-amd-test.sh "cd {{ (step.working_dir or default_working_dir) | safe  }} ; {{ step.command  or (step.commands | join(" ; ")) | safe }}"
        env:
          DOCKER_BUILDKIT: "1"
        soft_fail: true
    {% endif %}
    {% endfor %}
  - label: "Neuron Test"
    depends_on: ~
    agents:
      queue: neuron
    command: bash .buildkite/run-neuron-test.sh
    soft_fail: false
  - label: "Intel Test"
    depends_on: ~
    agents:
      queue: intel
    command: bash .buildkite/run-cpu-test.sh
  {% for step in steps %}
  - label: "{{ step.label }}"
    agents:
@@ -32,9 +57,14 @@ steps:
      automatic:
        - exit_status: -1  # Agent was lost
          limit: 5
        - exit_status: -10  # Agent was lost
          limit: 5
    plugins:
      - kubernetes:
          podSpec:
            {% if step.num_gpus %}
            priorityClassName: gpu-priority-cls-{{ step.num_gpus }}
            {% endif %}
            volumes:
              - name: dshm
                emptyDir:
--- a/.clang-format
+++ b/.clang-format
@@ -0,0 +1,26 @@
 BasedOnStyle: Google
 UseTab: Never
 IndentWidth: 2
 ColumnLimit: 80
 # Force pointers to the type for C++.
 DerivePointerAlignment: false
 PointerAlignment: Left
 # Reordering #include statements can (and currently will) introduce errors
 SortIncludes: false
 # Style choices
 AlignConsecutiveAssignments: false
 AlignConsecutiveDeclarations: false
 IndentPPDirectives: BeforeHash
 IncludeCategories:
  - Regex:           '^<'
    Priority:        4
  - Regex:           '^"(llvm|llvm-c|clang|clang-c|mlir|mlir-c)/'
    Priority:        3
  - Regex:           '^"(qoda|\.\.)/'
    Priority:        2
  - Regex:           '.*'
    Priority:        1
--- a/.github/ISSUE_TEMPLATE/200-installation.yml
+++ b/.github/ISSUE_TEMPLATE/200-installation.yml
@@ -18,6 +18,7 @@ body:
      # For security purposes, please feel free to check the contents of collect_env.py before running it.
      python collect_env.py
      ```
      It is suggested to download and execute the latest script, as vllm might frequently update the diagnosis information needed for accurately and quickly responding to issues.
    value: |
      ```text
      The output of `python collect_env.py`
--- a/.github/ISSUE_TEMPLATE/300-usage.yml
+++ b/.github/ISSUE_TEMPLATE/300-usage.yml
@@ -18,6 +18,7 @@ body:
      # For security purposes, please feel free to check the contents of collect_env.py before running it.
      python collect_env.py
      ```
      It is suggested to download and execute the latest script, as vllm might frequently update the diagnosis information needed for accurately and quickly responding to issues.
    value: |
      ```text
      The output of `python collect_env.py`
--- a/.github/ISSUE_TEMPLATE/400-bug
+++ b/.github/ISSUE_TEMPLATE/400-bug
@@ -18,6 +18,7 @@ body:
      # For security purposes, please feel free to check the contents of collect_env.py before running it.
      python collect_env.py
      ```
      It is suggested to download and execute the latest script, as vllm might frequently update the diagnosis information needed for accurately and quickly responding to issues.
    value: |
      ```text
      The output of `python collect_env.py`
@@ -57,6 +58,10 @@ body:
      If the code is too long (hopefully, it isn't), feel free to put it in a public gist and link it in the issue: https://gist.github.com.
      Please also paste or describe the results you observe instead of the expected results. If you observe an error, please paste the error message including the **full** traceback of the exception. It may be relevant to wrap error messages in ```` ```triple quotes blocks``` ````.
      Please set the environment variable `export VLLM_LOGGING_LEVEL=DEBUG` to turn on more logging to help debugging potential issues.
      If you experienced crashes or hangs, it would be helpful to run vllm with `export VLLM_TRACE_FUNCTION=1` . All the function calls in vllm will be recorded. Inspect these log files, and tell which function crashes or hangs.
    placeholder: |
      A clear and concise description of what the bug is.
--- a/.github/ISSUE_TEMPLATE/700-performance
+++ b/.github/ISSUE_TEMPLATE/700-performance
@@ -39,6 +39,7 @@ body:
      # For security purposes, please feel free to check the contents of collect_env.py before running it.
      python collect_env.py
      ```
      It is suggested to download and execute the latest script, as vllm might frequently update the diagnosis information needed for accurately and quickly responding to issues.
    value: |
      ```text
      The output of `python collect_env.py`
--- a/.github/ISSUE_TEMPLATE/750-RFC.yml
+++ b/.github/ISSUE_TEMPLATE/750-RFC.yml
@@ -0,0 +1,49 @@
 name: 💬 Request for comments (RFC).
 description: Ask for feedback on major architectural changes or design choices.
 title: "[RFC]: "
 labels: ["RFC"]
 body:
 - type: markdown
  attributes:
    value: >
      #### Please take a look at previous [RFCs](https://github.com/vllm-project/vllm/issues?q=label%3ARFC+sort%3Aupdated-desc) for reference.
 - type: textarea
  attributes:
    label: Motivation.
    description: >
      The motivation of the RFC.
  validations:
    required: true
 - type: textarea
  attributes:
    label: Proposed Change.
    description: >
      The proposed change of the RFC.
  validations:
    required: true
 - type: textarea
  attributes:
    label: Feedback Period.
    description: >
      The feedback period of the RFC. Usually at least one week.
  validations:
    required: false
 - type: textarea
  attributes:
    label: CC List.
    description: >
      The list of people you want to CC.
  validations:
    required: false
 - type: textarea
  attributes:
    label: Any Other Things.
    description: >
      Any other things you would like to mention.
  validations:
    required: false
 - type: markdown
  attributes:
    value: >
      Thanks for contributing 🎉!
--- a/.github/workflows/clang-format.yml
+++ b/.github/workflows/clang-format.yml
@@ -0,0 +1,42 @@
 name: clang-format
 on:
  # Trigger the workflow on push or pull request,
  # but only for the main branch
  push:
    branches:
      - main
  pull_request:
    branches:
      - main
 jobs:
  clang-format:
    runs-on: ubuntu-latest
    strategy:
      matrix:
        python-version: ["3.11"]
    steps:
    - uses: actions/checkout@v2
    - name: Set up Python ${{ matrix.python-version }}
      uses: actions/setup-python@v2
      with:
        python-version: ${{ matrix.python-version }}
    - name: Install dependencies
      run: |
        python -m pip install --upgrade pip
        pip install clang-format==18.1.5
    - name: Running clang-format
      run: |
        EXCLUDES=(
            'csrc/moe/topk_softmax_kernels.cu'
            'csrc/punica/bgmv/bgmv_bf16_bf16_bf16.cu'
            'csrc/punica/bgmv/bgmv_config.h'
            'csrc/punica/bgmv/bgmv_impl.cuh'
            'csrc/punica/bgmv/vec_dtypes.cuh'
            'csrc/punica/punica_ops.cu'
            'csrc/punica/type_convert.h'
        )
        find csrc/ \( -name '*.h' -o -name '*.cpp' -o -name '*.cu' -o -name '*.cuh' \) -print \
            | grep -vFf <(printf "%s\n" "${EXCLUDES[@]}") \
            | xargs clang-format --dry-run --Werror
--- a/.github/workflows/mypy.yaml
+++ b/.github/workflows/mypy.yaml
@@ -0,0 +1,51 @@
 name: mypy
 on:
  # Trigger the workflow on push or pull request,
  # but only for the main branch
  push:
    branches:
      - main
  pull_request:
    branches:
      - main
 jobs:
  ruff:
    runs-on: ubuntu-latest
    strategy:
      matrix:
        python-version: ["3.8", "3.9", "3.10", "3.11"]
    steps:
    - uses: actions/checkout@v2
    - name: Set up Python ${{ matrix.python-version }}
      uses: actions/setup-python@v2
      with:
        python-version: ${{ matrix.python-version }}
    - name: Install dependencies
      run: |
        python -m pip install --upgrade pip
        pip install mypy==1.9.0
        pip install types-setuptools
        pip install types-PyYAML
        pip install types-requests
        pip install types-setuptools
    - name: Mypy
      run: |
        mypy vllm/attention --config-file pyproject.toml
        mypy vllm/core --config-file pyproject.toml
        mypy vllm/distributed --config-file pyproject.toml
        mypy vllm/entrypoints --config-file pyproject.toml
        mypy vllm/executor --config-file pyproject.toml
        mypy vllm/multimodal --config-file pyproject.toml
        mypy vllm/usage --config-file pyproject.toml
        mypy vllm/*.py --config-file pyproject.toml
        mypy vllm/transformers_utils --config-file pyproject.toml
        mypy vllm/engine  --config-file pyproject.toml
        mypy vllm/worker --config-file pyproject.toml
        mypy vllm/spec_decode --config-file pyproject.toml
        mypy vllm/model_executor  --config-file pyproject.toml
        mypy vllm/lora --config-file pyproject.toml
        mypy vllm/logging --config-file pyproject.toml
        mypy vllm/model_executor --config-file pyproject.toml
--- a/.github/workflows/publish.yml
+++ b/.github/workflows/publish.yml
@@ -49,13 +49,19 @@ jobs:
      matrix:
          os: ['ubuntu-20.04']
          python-version: ['3.8', '3.9', '3.10', '3.11']
-          pytorch-version: ['2.1.2']  # Must be the most recent version that meets requirements.txt.
+          pytorch-version: ['2.3.0']  # Must be the most recent version that meets requirements-cuda.txt.
          cuda-version: ['11.8', '12.1']
    steps:
      - name: Checkout
        uses: actions/checkout@v3
      - name: Setup ccache
        uses: hendrikmuhs/ccache-action@v1.2
        with:
          create-symlink: true
          key: ${{ github.job }}-${{ matrix.python-version }}-${{ matrix.cuda-version }}
      - name: Set up Linux Env
        if: ${{ runner.os == 'Linux' }}
        run: |
@@ -76,6 +82,8 @@ jobs:
      - name: Build wheel
        shell: bash
        env:
          CMAKE_BUILD_TYPE: Release # do not compile with debug symbol to reduce wheel size
        run: |
          bash -x .github/workflows/scripts/build.sh ${{ matrix.python-version }} ${{ matrix.cuda-version }}
          wheel_name=$(ls dist/*whl | xargs -n 1 basename)
--- a/.github/workflows/ruff.yml
+++ b/.github/workflows/ruff.yml
@@ -15,7 +15,7 @@ jobs:
    runs-on: ubuntu-latest
    strategy:
      matrix:
-        python-version: ["3.10"]
+        python-version: ["3.8", "3.9", "3.10", "3.11"]
    steps:
    - uses: actions/checkout@v2
    - name: Set up Python ${{ matrix.python-version }}
@@ -25,7 +25,7 @@ jobs:
    - name: Install dependencies
      run: |
        python -m pip install --upgrade pip
-        pip install ruff==0.1.5 codespell==2.2.6 tomli==2.0.1 isort==5.13.2
+        pip install ruff==0.1.5 codespell==2.3.0 tomli==2.0.1 isort==5.13.2
    - name: Analysing the code with ruff
      run: |
        ruff .
--- a/.github/workflows/scripts/build.sh
+++ b/.github/workflows/scripts/build.sh
@@ -9,12 +9,13 @@ LD_LIBRARY_PATH=${cuda_home}/lib64:$LD_LIBRARY_PATH
 # Install requirements
 $python_executable -m pip install wheel packaging
-$python_executable -m pip install -r requirements.txt
+$python_executable -m pip install -r requirements-cuda.txt
 # Limit the number of parallel jobs to avoid OOM
 export MAX_JOBS=1
 # Make sure punica is built for the release (for LoRA)
 export VLLM_INSTALL_PUNICA_KERNELS=1
-
+# Make sure release wheels are built for the following architectures
 export TORCH_CUDA_ARCH_LIST="7.0 7.5 8.0 8.6 8.9 9.0+PTX"
 # Build
 $python_executable setup.py bdist_wheel --dist-dir=dist
--- a/.github/workflows/scripts/create_release.js
+++ b/.github/workflows/scripts/create_release.js
@@ -8,7 +8,7 @@ module.exports = async (github, context, core) => {
 			generate_release_notes: true,
 			name: process.env.RELEASE_TAG,
 			owner: context.repo.owner,
-			prerelease: false,
+			prerelease: true,
 			repo: context.repo.repo,
 			tag_name: process.env.RELEASE_TAG,
 		});
--- a/.github/workflows/yapf.yml
+++ b/.github/workflows/yapf.yml
@@ -14,7 +14,7 @@ jobs:
    runs-on: ubuntu-latest
    strategy:
      matrix:
-        python-version: ["3.10"]
+        python-version: ["3.8", "3.9", "3.10", "3.11"]
    steps:
    - uses: actions/checkout@v2
    - name: Set up Python ${{ matrix.python-version }}
--- a/.gitignore
+++ b/.gitignore
@@ -70,6 +70,8 @@ instance/
 # Sphinx documentation
 docs/_build/
 docs/source/getting_started/examples/*.rst
 !**/*.template.rst
 # PyBuilder
 .pybuilder/
@@ -181,6 +183,7 @@ _build/
 # hip files generated by PyTorch
 *.hip
 *_hip*
 hip_compat.h
 # Benchmark dataset
 *.json
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@@ -2,7 +2,10 @@ cmake_minimum_required(VERSION 3.21)
 project(vllm_extensions LANGUAGES CXX)
 option(VLLM_TARGET_DEVICE "Target device backend for vLLM" "cuda")
 message(STATUS "Build type: ${CMAKE_BUILD_TYPE}")
 message(STATUS "Target device: ${VLLM_TARGET_DEVICE}")
 include(${CMAKE_CURRENT_LIST_DIR}/cmake/utils.cmake)
@@ -16,7 +19,7 @@ set(PYTHON_SUPPORTED_VERSIONS "3.8" "3.9" "3.10" "3.11")
 set(CUDA_SUPPORTED_ARCHS "7.0;7.5;8.0;8.6;8.9;9.0")
 # Supported AMD GPU architectures.
-set(HIP_SUPPORTED_ARCHS "gfx908;gfx90a;gfx942;gfx1100")
+set(HIP_SUPPORTED_ARCHS "gfx906;gfx908;gfx90a;gfx940;gfx941;gfx942;gfx1030;gfx1100")
 #
 # Supported/expected torch versions for CUDA/ROCm.
@@ -28,7 +31,7 @@ set(HIP_SUPPORTED_ARCHS "gfx908;gfx90a;gfx942;gfx1100")
 # requirements.txt files and should be kept consistent.  The ROCm torch
 # versions are derived from Dockerfile.rocm
 #
-set(TORCH_SUPPORTED_VERSION_CUDA "2.1.2")
+set(TORCH_SUPPORTED_VERSION_CUDA "2.3.0")
 set(TORCH_SUPPORTED_VERSION_ROCM_5X "2.0.1")
 set(TORCH_SUPPORTED_VERSION_ROCM_6X "2.1.1")
@@ -64,17 +67,17 @@ endif()
 find_package(Torch REQUIRED)
 #
-# Normally `torch.utils.cpp_extension.CUDAExtension` would add
+# Forward the non-CUDA device extensions to external CMake scripts.
 # `libtorch_python.so` for linking against an extension. Torch's cmake
 # configuration does not include this library (presumably since the cmake
 # config is used for standalone C++ binaries that link against torch).
 # The `libtorch_python.so` library defines some of the glue code between
 # torch/python via pybind and is required by VLLM extensions for this
 # reason. So, add it by manually with `find_library` using torch's
 # installed library path.
 #
-find_library(torch_python_LIBRARY torch_python PATHS
+if (NOT VLLM_TARGET_DEVICE STREQUAL "cuda" AND
-  "${TORCH_INSTALL_PREFIX}/lib")
+    NOT VLLM_TARGET_DEVICE STREQUAL "rocm")
    if (VLLM_TARGET_DEVICE STREQUAL "cpu")
        include(${CMAKE_CURRENT_LIST_DIR}/cmake/cpu_extension.cmake)
    else()
        message(FATAL_ERROR "Unsupported vLLM target device: ${VLLM_TARGET_DEVICE}")
    endif()
    return()
 endif()
 #
 # Set up GPU language and check the torch version and warn if it isn't
@@ -151,15 +154,47 @@ set(VLLM_EXT_SRC
  "csrc/layernorm_kernels.cu"
  "csrc/quantization/squeezellm/quant_cuda_kernel.cu"
  "csrc/quantization/gptq/q_gemm.cu"
  "csrc/quantization/compressed_tensors/int8_quant_kernels.cu"
  "csrc/quantization/fp8/common.cu"
  "csrc/cuda_utils_kernels.cu"
  "csrc/moe_align_block_size_kernels.cu"
-  "csrc/pybind.cpp")
+  "csrc/torch_bindings.cpp")
 if(VLLM_GPU_LANG STREQUAL "CUDA")
  include(FetchContent)
  SET(CUTLASS_ENABLE_HEADERS_ONLY=ON)
  FetchContent_Declare(
        cutlass
        GIT_REPOSITORY https://github.com/nvidia/cutlass.git
        # CUTLASS 3.5.0
        GIT_TAG 7d49e6c7e2f8896c47f586706e67e1fb215529dc
  )
  FetchContent_MakeAvailable(cutlass)
  list(APPEND VLLM_EXT_SRC
    "csrc/quantization/aqlm/gemm_kernels.cu"
    "csrc/quantization/awq/gemm_kernels.cu"
-    "csrc/quantization/marlin/marlin_cuda_kernel.cu"
+    "csrc/quantization/marlin/dense/marlin_cuda_kernel.cu"
-    "csrc/custom_all_reduce.cu")
+    "csrc/quantization/marlin/sparse/marlin_24_cuda_kernel.cu"
    "csrc/quantization/gptq_marlin/gptq_marlin.cu"
    "csrc/quantization/gptq_marlin/gptq_marlin_repack.cu"
    "csrc/custom_all_reduce.cu"
    "csrc/quantization/cutlass_w8a8/scaled_mm_entry.cu"
    "csrc/quantization/cutlass_w8a8/scaled_mm_c2x.cu"
    "csrc/quantization/cutlass_w8a8/scaled_mm_c3x.cu")
  #
  # The CUTLASS kernels for Hopper require sm90a to be enabled.
  # This is done via the below gencode option, BUT that creates kernels for both sm90 and sm90a.
  # That adds an extra 17MB to compiled binary, so instead we selectively enable it.
  if(${CMAKE_CUDA_COMPILER_VERSION} VERSION_GREATER 12.0)
    set_source_files_properties(
          "csrc/quantization/cutlass_w8a8/scaled_mm_c3x.cu"
          PROPERTIES
          COMPILE_FLAGS
          "-gencode arch=compute_90a,code=sm_90a")
  endif()
 endif()
 define_gpu_extension_target(
@@ -169,6 +204,8 @@ define_gpu_extension_target(
  SOURCES ${VLLM_EXT_SRC}
  COMPILE_FLAGS ${VLLM_GPU_FLAGS}
  ARCHITECTURES ${VLLM_GPU_ARCHES}
  INCLUDE_DIRECTORIES ${CUTLASS_INCLUDE_DIR};${CUTLASS_TOOLS_UTIL_INCLUDE_DIR}
  USE_SABI 3
  WITH_SOABI)
 #
@@ -176,7 +213,7 @@ define_gpu_extension_target(
 #
 set(VLLM_MOE_EXT_SRC
-  "csrc/moe/moe_ops.cpp"
+  "csrc/moe/torch_bindings.cpp"
  "csrc/moe/topk_softmax_kernels.cu")
 define_gpu_extension_target(
@@ -186,6 +223,7 @@ define_gpu_extension_target(
  SOURCES ${VLLM_MOE_EXT_SRC}
  COMPILE_FLAGS ${VLLM_GPU_FLAGS}
  ARCHITECTURES ${VLLM_GPU_ARCHES}
  USE_SABI 3
  WITH_SOABI)
 #
@@ -194,24 +232,13 @@ define_gpu_extension_target(
 set(VLLM_PUNICA_EXT_SRC
  "csrc/punica/bgmv/bgmv_bf16_bf16_bf16.cu"
  "csrc/punica/bgmv/bgmv_bf16_bf16_fp16.cu"
  "csrc/punica/bgmv/bgmv_bf16_fp16_bf16.cu"
  "csrc/punica/bgmv/bgmv_bf16_fp16_fp16.cu"
  "csrc/punica/bgmv/bgmv_bf16_fp32_bf16.cu"
  "csrc/punica/bgmv/bgmv_bf16_fp32_fp16.cu"
  "csrc/punica/bgmv/bgmv_fp16_bf16_bf16.cu"
  "csrc/punica/bgmv/bgmv_fp16_bf16_fp16.cu"
  "csrc/punica/bgmv/bgmv_fp16_fp16_bf16.cu"
  "csrc/punica/bgmv/bgmv_fp16_fp16_fp16.cu"
  "csrc/punica/bgmv/bgmv_fp16_fp32_bf16.cu"
  "csrc/punica/bgmv/bgmv_fp16_fp32_fp16.cu"
  "csrc/punica/bgmv/bgmv_fp32_bf16_bf16.cu"
  "csrc/punica/bgmv/bgmv_fp32_bf16_fp16.cu"
  "csrc/punica/bgmv/bgmv_fp32_fp16_bf16.cu"
  "csrc/punica/bgmv/bgmv_fp32_fp16_fp16.cu"
-  "csrc/punica/bgmv/bgmv_fp32_fp32_bf16.cu"
+  "csrc/punica/punica_ops.cu"
-  "csrc/punica/bgmv/bgmv_fp32_fp32_fp16.cu"
+  "csrc/punica/torch_bindings.cpp")
  "csrc/punica/punica_ops.cc")
 #
 # Copy GPU compilation flags+update for punica
@@ -235,6 +262,9 @@ if (${VLLM_GPU_LANG} STREQUAL "CUDA")
    endif()
  endforeach()
  message(STATUS "Punica target arches: ${VLLM_PUNICA_GPU_ARCHES}")
 elseif(${VLLM_GPU_LANG} STREQUAL "HIP")
  set(VLLM_PUNICA_GPU_ARCHES ${VLLM_GPU_ARCHES})
  message(STATUS "Punica target arches: ${VLLM_PUNICA_GPU_ARCHES}")
 endif()
 if (VLLM_PUNICA_GPU_ARCHES)
@@ -245,6 +275,7 @@ if (VLLM_PUNICA_GPU_ARCHES)
    SOURCES ${VLLM_PUNICA_EXT_SRC}
    COMPILE_FLAGS ${VLLM_PUNICA_GPU_FLAGS}
    ARCHITECTURES ${VLLM_PUNICA_GPU_ARCHES}
    USE_SABI 3
    WITH_SOABI)
 else()
  message(WARNING "Unable to create _punica_C target because none of the "
@@ -269,9 +300,7 @@ add_custom_target(default)
 if(VLLM_GPU_LANG STREQUAL "CUDA" OR VLLM_GPU_LANG STREQUAL "HIP")
  message(STATUS "Enabling C extension.")
  add_dependencies(default _C)
 endif()
 if(VLLM_GPU_LANG STREQUAL "CUDA")
  message(STATUS "Enabling moe extension.")
  add_dependencies(default _moe_C)
--- a/CONTRIBUTING.md
+++ b/CONTRIBUTING.md
@@ -21,7 +21,6 @@ Express your support on Twitter if vLLM aids you, or simply offer your appreciat
 ### Build from source
 ```bash
 pip install -r requirements.txt
 pip install -e .  # This may take several minutes.
 ```
@@ -30,6 +29,8 @@ pip install -e .  # This may take several minutes.
 ```bash
 pip install -r requirements-dev.txt
 # linting and formatting
 bash format.sh
 # Static type checking
 mypy
 # Unit tests
--- a/140
+++ b/140
@@ -1,33 +1,48 @@
 # The vLLM Dockerfile is used to construct vLLM image that can be directly used
 # to run the OpenAI compatible server.
 # Please update any changes made here to
 # docs/source/dev/dockerfile/dockerfile.rst and
 # docs/source/assets/dev/dockerfile-stages-dependency.png
 #################### BASE BUILD IMAGE ####################
-FROM nvidia/cuda:12.1.0-devel-ubuntu22.04 AS dev
+# prepare basic build environment
 FROM nvidia/cuda:12.4.1-devel-ubuntu22.04 AS dev
 RUN apt-get update -y \
-    && apt-get install -y python3-pip git
+    && apt-get install -y python3-pip git curl sudo
 # Workaround for https://github.com/openai/triton/issues/2507 and
 # https://github.com/pytorch/pytorch/issues/107960 -- hopefully
 # this won't be needed for future versions of this docker image
 # or future versions of triton.
-RUN ldconfig /usr/local/cuda-12.1/compat/
+RUN ldconfig /usr/local/cuda-12.4/compat/
 WORKDIR /workspace
 # install build and runtime dependencies
-COPY requirements.txt requirements.txt
+COPY requirements-common.txt requirements-common.txt
 COPY requirements-cuda.txt requirements-cuda.txt
 RUN --mount=type=cache,target=/root/.cache/pip \
-    pip install -r requirements.txt
+    pip install -r requirements-cuda.txt
 # install development dependencies
 COPY requirements-lint.txt requirements-lint.txt
 COPY requirements-test.txt requirements-test.txt
 COPY requirements-dev.txt requirements-dev.txt
 RUN --mount=type=cache,target=/root/.cache/pip \
    pip install -r requirements-dev.txt
 # cuda arch list used by torch
 # can be useful for both `dev` and `test`
 # explicitly set the list to avoid issues with torch 2.2
 # see https://github.com/pytorch/pytorch/pull/123243
 ARG torch_cuda_arch_list='7.0 7.5 8.0 8.6 8.9 9.0+PTX'
 ENV TORCH_CUDA_ARCH_LIST=${torch_cuda_arch_list}
 #################### BASE BUILD IMAGE ####################
-#################### EXTENSION BUILD IMAGE ####################
+#################### WHEEL BUILD IMAGE ####################
 FROM dev AS build
 # install build dependencies
@@ -38,18 +53,16 @@ RUN --mount=type=cache,target=/root/.cache/pip \
 # install compiler cache to speed up compilation leveraging local or remote caching
 RUN apt-get update -y && apt-get install -y ccache
-# copy input files
+# files and directories related to build wheels
 COPY csrc csrc
 COPY setup.py setup.py
 COPY cmake cmake
 COPY CMakeLists.txt CMakeLists.txt
-COPY requirements.txt requirements.txt
+COPY requirements-common.txt requirements-common.txt
 COPY requirements-cuda.txt requirements-cuda.txt
 COPY pyproject.toml pyproject.toml
-COPY vllm/__init__.py vllm/__init__.py
+COPY vllm vllm
 # cuda arch list used by torch
 ARG torch_cuda_arch_list='7.0 7.5 8.0 8.6 8.9 9.0+PTX'
 ENV TORCH_CUDA_ARCH_LIST=${torch_cuda_arch_list}
 # max jobs used by Ninja to build extensions
 ARG max_jobs=2
 ENV MAX_JOBS=${max_jobs}
@@ -59,79 +72,84 @@ ENV NVCC_THREADS=$nvcc_threads
 # make sure punica kernels are built (for LoRA)
 ENV VLLM_INSTALL_PUNICA_KERNELS=1
 ARG USE_SCCACHE
 # if USE_SCCACHE is set, use sccache to speed up compilation
 RUN --mount=type=cache,target=/root/.cache/pip \
    if [ "$USE_SCCACHE" = "1" ]; then \
        echo "Installing sccache..." \
        && curl -L -o sccache.tar.gz https://github.com/mozilla/sccache/releases/download/v0.8.1/sccache-v0.8.1-x86_64-unknown-linux-musl.tar.gz \
        && tar -xzf sccache.tar.gz \
        && sudo mv sccache-v0.8.1-x86_64-unknown-linux-musl/sccache /usr/bin/sccache \
        && rm -rf sccache.tar.gz sccache-v0.8.1-x86_64-unknown-linux-musl \
        && export SCCACHE_BUCKET=vllm-build-sccache \
        && export SCCACHE_REGION=us-west-2 \
        && sccache --show-stats \
        && python3 setup.py bdist_wheel --dist-dir=dist \
        && sccache --show-stats; \
    fi
 ENV CCACHE_DIR=/root/.cache/ccache
 RUN --mount=type=cache,target=/root/.cache/ccache \
-    python3 setup.py build_ext --inplace
+    --mount=type=cache,target=/root/.cache/pip \
    if [ "$USE_SCCACHE" != "1" ]; then \
        python3 setup.py bdist_wheel --dist-dir=dist; \
    fi
 # check the size of the wheel, we cannot upload wheels larger than 100MB
 COPY .buildkite/check-wheel-size.py check-wheel-size.py
 RUN python3 check-wheel-size.py dist
 #################### EXTENSION Build IMAGE ####################
-#################### FLASH_ATTENTION Build IMAGE ####################
+#################### vLLM installation IMAGE ####################
-FROM dev as flash-attn-builder
+# image with vLLM installed
-# max jobs used for build
+FROM nvidia/cuda:12.4.1-base-ubuntu22.04 AS vllm-base
-ARG max_jobs=2
+WORKDIR /vllm-workspace
 ENV MAX_JOBS=${max_jobs}
 # flash attention version
 ARG flash_attn_version=v2.5.6
 ENV FLASH_ATTN_VERSION=${flash_attn_version}
-WORKDIR /usr/src/flash-attention-v2
+RUN apt-get update -y \
    && apt-get install -y python3-pip git vim
-# Download the wheel or build it if a pre-compiled release doesn't exist
+# Workaround for https://github.com/openai/triton/issues/2507 and
-RUN pip --verbose wheel flash-attn==${FLASH_ATTN_VERSION} \
+# https://github.com/pytorch/pytorch/issues/107960 -- hopefully
-    --no-build-isolation --no-deps --no-cache-dir
+# this won't be needed for future versions of this docker image
 # or future versions of triton.
 RUN ldconfig /usr/local/cuda-12.4/compat/
 # install vllm wheel first, so that torch etc will be installed
 RUN --mount=type=bind,from=build,src=/workspace/dist,target=/vllm-workspace/dist \
    --mount=type=cache,target=/root/.cache/pip \
    pip install dist/*.whl --verbose
 #################### vLLM installation IMAGE ####################
 #################### FLASH_ATTENTION Build IMAGE ####################
 #################### TEST IMAGE ####################
 # image to run unit testing suite
-FROM dev AS test
+# note that this uses vllm installed by `pip`
 FROM vllm-base AS test
 # copy pytorch extensions separately to avoid having to rebuild
 # when python code changes
 WORKDIR /vllm-workspace
 # ADD is used to preserve directory structure
 ADD . /vllm-workspace/
 COPY --from=build /workspace/vllm/*.so /vllm-workspace/vllm/
 # Install flash attention (from pre-built wheel)
 RUN --mount=type=bind,from=flash-attn-builder,src=/usr/src/flash-attention-v2,target=/usr/src/flash-attention-v2 \
    pip install /usr/src/flash-attention-v2/*.whl --no-cache-dir
 # ignore build dependencies installation because we are using pre-complied extensions
 RUN rm pyproject.toml
 RUN --mount=type=cache,target=/root/.cache/pip VLLM_USE_PRECOMPILED=1 pip install . --verbose
 #################### TEST IMAGE ####################
-
+# install development dependencies (for testing)
 #################### RUNTIME BASE IMAGE ####################
 # We used base cuda image because pytorch installs its own cuda libraries.
 # However pynccl depends on cuda libraries so we had to switch to the runtime image
 # In the future it would be nice to get a container with pytorch and cuda without duplicating cuda
 FROM nvidia/cuda:12.1.0-runtime-ubuntu22.04 AS vllm-base
 # libnccl required for ray
 RUN apt-get update -y \
    && apt-get install -y python3-pip
 WORKDIR /workspace
 COPY requirements.txt requirements.txt
 RUN --mount=type=cache,target=/root/.cache/pip \
-    pip install -r requirements.txt
+    pip install -r requirements-dev.txt
-# Install flash attention (from pre-built wheel)
+# doc requires source code
-RUN --mount=type=bind,from=flash-attn-builder,src=/usr/src/flash-attention-v2,target=/usr/src/flash-attention-v2 \
+# we hide them inside `test_docs/` , so that this source code
-    pip install /usr/src/flash-attention-v2/*.whl --no-cache-dir
+# will not be imported by other tests
-
+RUN mkdir test_docs
-#################### RUNTIME BASE IMAGE ####################
+RUN mv docs test_docs/
 RUN mv vllm test_docs/
 #################### TEST IMAGE ####################
 #################### OPENAI API SERVER ####################
 # openai api server alternative
 FROM vllm-base AS vllm-openai
 # install additional dependencies for openai api server
 RUN --mount=type=cache,target=/root/.cache/pip \
    pip install accelerate hf_transfer modelscope
 COPY --from=build /workspace/vllm/*.so /workspace/vllm/
 COPY vllm vllm
 ENV VLLM_USAGE_SOURCE production-docker-image
 ENTRYPOINT ["python3", "-m", "vllm.entrypoints.openai.api_server"]
--- a/Dockerfile.cpu
+++ b/Dockerfile.cpu
@@ -0,0 +1,30 @@
 # This vLLM Dockerfile is used to construct image that can build and run vLLM on x86 CPU platform.
 FROM ubuntu:22.04 AS cpu-test-1
 RUN apt-get update  -y \
    && apt-get install -y git wget vim numactl gcc-12 g++-12 python3 python3-pip libtcmalloc-minimal4 \
    && update-alternatives --install /usr/bin/gcc gcc /usr/bin/gcc-12 10 --slave /usr/bin/g++ g++ /usr/bin/g++-12
 RUN echo 'export LD_PRELOAD=/usr/lib/x86_64-linux-gnu/libtcmalloc_minimal.so.4:$LD_PRELOAD' >> ~/.bashrc
 RUN pip install https://intel-extension-for-pytorch.s3.amazonaws.com/ipex_dev/cpu/intel_extension_for_pytorch-2.3.100%2Bgit0eb3473-cp310-cp310-linux_x86_64.whl
 RUN pip install --upgrade pip \
    && pip install wheel packaging ninja "setuptools>=49.4.0" numpy
 FROM cpu-test-1 AS build
 COPY ./ /workspace/vllm
 WORKDIR /workspace/vllm
 RUN pip install -v -r requirements-cpu.txt --extra-index-url https://download.pytorch.org/whl/cpu
 RUN VLLM_TARGET_DEVICE=cpu python3 setup.py install
 WORKDIR /workspace/
 RUN ln -s /workspace/vllm/tests && ln -s /workspace/vllm/examples && ln -s /workspace/vllm/benchmarks
 CMD ["/bin/bash"]
--- a/Dockerfile.neuron
+++ b/Dockerfile.neuron
@@ -0,0 +1,36 @@
 # default base image
 ARG BASE_IMAGE="763104351884.dkr.ecr.us-west-2.amazonaws.com/pytorch-inference-neuronx:2.1.1-neuronx-py310-sdk2.17.0-ubuntu20.04"
 FROM $BASE_IMAGE
 RUN echo "Base image is $BASE_IMAGE"
 # Install some basic utilities
 RUN apt-get update && apt-get install python3 python3-pip -y
 ### Mount Point ###
 # When launching the container, mount the code directory to /app
 ARG APP_MOUNT=/app
 VOLUME [ ${APP_MOUNT} ]
 WORKDIR ${APP_MOUNT}
 RUN python3 -m pip install --upgrade pip
 RUN python3 -m pip install --no-cache-dir fastapi ninja tokenizers pandas
 RUN python3 -m pip install sentencepiece transformers==4.36.2 -U
 RUN python3 -m pip install transformers-neuronx --extra-index-url=https://pip.repos.neuron.amazonaws.com -U
 RUN python3 -m pip install --pre neuronx-cc==2.12.* --extra-index-url=https://pip.repos.neuron.amazonaws.com -U
 COPY ./vllm /app/vllm/vllm
 COPY ./setup.py /app/vllm/setup.py
 COPY ./requirements-common.txt /app/vllm/requirements-common.txt
 COPY ./requirements-neuron.txt /app/vllm/requirements-neuron.txt
 RUN cd /app/vllm \
    && python3 -m pip install -U -r requirements-neuron.txt
 ENV VLLM_TARGET_DEVICE neuron
 RUN cd /app/vllm \
    && pip install -e . \
    && cd ..
 CMD ["/bin/bash"]
--- a/Dockerfile.rocm
+++ b/Dockerfile.rocm
@@ -14,7 +14,7 @@ RUN echo "Base image is $BASE_IMAGE"
 ARG FA_GFX_ARCHS="gfx90a;gfx942"
 RUN echo "FA_GFX_ARCHS is $FA_GFX_ARCHS"
-ARG FA_BRANCH="3d2b6f5"
+ARG FA_BRANCH="ae7928c"
 RUN echo "FA_BRANCH is $FA_BRANCH"
 # whether to build flash-attention
@@ -23,6 +23,9 @@ RUN echo "FA_BRANCH is $FA_BRANCH"
 # In that case, we need to use the python reference attention implementation in vllm
 ARG BUILD_FA="1"
 # whether to build triton on rocm
 ARG BUILD_TRITON="1"
 # Install some basic utilities
 RUN apt-get update && apt-get install python3 python3-pip -y
@@ -43,7 +46,7 @@ RUN apt-get update && apt-get install -y \
 ### Mount Point ###
 # When launching the container, mount the code directory to /app
-ARG APP_MOUNT=/app
+ARG APP_MOUNT=/vllm-workspace
 VOLUME [ ${APP_MOUNT} ]
 WORKDIR ${APP_MOUNT}
@@ -75,21 +78,38 @@ RUN if [ "$BUILD_FA" = "1" ]; then \
 RUN if [ "$BASE_IMAGE" = "rocm/pytorch:rocm6.0_ubuntu20.04_py3.9_pytorch_2.1.1" ]; then \
    rm -rf /opt/conda/envs/py_3.9/lib/python3.9/site-packages/numpy-1.20.3.dist-info/; fi
-COPY ./ /app/vllm
+# build triton
 RUN if [ "$BUILD_TRITON" = "1" ]; then \
    mkdir -p libs \
    && cd libs \
    && pip uninstall -y triton \
    && git clone https://github.com/ROCm/triton.git \
    && cd triton/python \
    && pip3 install . \
    && cd ../..; \
    fi
-RUN python3 -m pip install --upgrade pip
+WORKDIR /vllm-workspace
-RUN python3 -m pip install xformers==0.0.23 --no-deps
+COPY . .
-RUN cd /app \
+#RUN python3 -m pip install pynvml # to be removed eventually
-    && cd vllm \
+RUN python3 -m pip install --upgrade pip numba
-    && pip install -U -r requirements-rocm.txt \
+
-    && if [ "$BUILD_FA" = "1" ]; then \
+# make sure punica kernels are built (for LoRA)
-       bash patch_xformers.rocm.sh; fi \
+ENV VLLM_INSTALL_PUNICA_KERNELS=1
-    && patch /opt/rocm/include/hip/amd_detail/amd_hip_bf16.h /app/vllm/rocm_patch/rocm_bf16.patch \
+# Workaround for ray >= 2.10.0
 ENV RAY_EXPERIMENTAL_NOSET_ROCR_VISIBLE_DEVICES=1
 ENV VLLM_NCCL_SO_PATH=/opt/rocm/lib/librccl.so
 RUN --mount=type=cache,target=/root/.cache/pip \
    pip install -U -r requirements-rocm.txt \
    && patch /opt/rocm/include/hip/amd_detail/amd_hip_bf16.h ./rocm_patch/rocm_bf16.patch \
    && python3 setup.py install \
    && cp build/lib.linux-x86_64-cpython-39/vllm/_C.abi3.so vllm/ \
    && cp build/lib.linux-x86_64-cpython-39/vllm/_punica_C.abi3.so vllm/ \
    && cp build/lib.linux-x86_64-cpython-39/vllm/_moe_C.abi3.so vllm/ \
    && cd ..
 RUN python3 -m pip install --upgrade pip
 RUN python3 -m pip install --no-cache-dir ray[all]==2.9.3
 CMD ["/bin/bash"]
--- a/Dockerfile.tpu
+++ b/Dockerfile.tpu
@@ -0,0 +1,19 @@
 ARG NIGHTLY_DATE="20240601"
 ARG BASE_IMAGE="us-central1-docker.pkg.dev/tpu-pytorch-releases/docker/xla:nightly_3.10_tpuvm_$NIGHTLY_DATE"
 FROM $BASE_IMAGE
 WORKDIR /workspace
 COPY . /workspace/vllm
 ENV VLLM_TARGET_DEVICE="tpu"
 # Install aiohttp separately to avoid build errors.
 RUN pip install aiohttp
 # Install the TPU and Pallas dependencies.
 RUN pip install torch_xla[tpu] -f https://storage.googleapis.com/libtpu-releases/index.html
 RUN pip install torch_xla[pallas] -f https://storage.googleapis.com/jax-releases/jax_nightly_releases.html -f https://storage.googleapis.com/jax-releases/jaxlib_nightly_releases.html
 # Build vLLM.
 RUN cd /workspace/vllm && python setup.py develop
 CMD ["/bin/bash"]
--- a/MANIFEST.in
+++ b/MANIFEST.in
@@ -1,5 +1,9 @@
 include LICENSE
-include requirements.txt
+include requirements-common.txt
 include requirements-cuda.txt
 include requirements-rocm.txt
 include requirements-neuron.txt
 include requirements-cpu.txt
 include CMakeLists.txt
 recursive-include cmake *
--- a/README.md
+++ b/README.md
@@ -16,16 +16,18 @@ Easy, fast, and cheap LLM serving for everyone
 ---
-**The Third vLLM Bay Area Meetup (April 2nd 6pm-8:30pm PT)**
+**Ray Summit CPF is Open (June 4th to June 20th)!**
-We are thrilled to announce our third vLLM Meetup!
+There will be a track for vLLM at the Ray Summit (09/30-10/02, SF) this year!
-The vLLM team will share recent updates and roadmap.
+If you have cool projects related to vLLM or LLM inference, we would love to see your proposals.
-We will also have vLLM collaborators from Roblox coming up to the stage to discuss their experience in deploying LLMs with vLLM.
+This will be a great chance for everyone in the community to get together and learn.
-Please register [here](https://robloxandvllmmeetup2024.splashthat.com/) and join us!
+Please submit your proposal [here](https://raysummit.anyscale.com/flow/anyscale/raysummit2024/landing/page/eventsite)
 ---
 *Latest News* 🔥
 - [2024/06] We hosted [the fourth vLLM meetup](https://lu.ma/agivllm) with Cloudflare and BentoML! Please find the meetup slides [here](https://docs.google.com/presentation/d/1iJ8o7V2bQEi0BFEljLTwc5G1S10_Rhv3beed5oB0NJ4/edit?usp=sharing).
 - [2024/04] We hosted [the third vLLM meetup](https://robloxandvllmmeetup2024.splashthat.com/) with Roblox! Please find the meetup slides [here](https://docs.google.com/presentation/d/1A--47JAK4BJ39t954HyTkvtfwn0fkqtsL8NGFuslReM/edit?usp=sharing).
 - [2024/01] We hosted [the second vLLM meetup](https://lu.ma/ygxbpzhl) in SF! Please find the meetup slides [here](https://docs.google.com/presentation/d/12mI2sKABnUw5RBWXDYY-HtHth4iMSNcEoQ10jDQbxgA/edit?usp=sharing).
 - [2024/01] Added ROCm 6.0 support to vLLM.
 - [2023/12] Added ROCm 5.7 support to vLLM.
@@ -57,43 +59,18 @@ vLLM is flexible and easy to use with:
 - Tensor parallelism support for distributed inference
 - Streaming outputs
 - OpenAI-compatible API server
- Support NVIDIA GPUs and AMD GPUs
+- Support NVIDIA GPUs, AMD GPUs, and Intel CPUs
 - (Experimental) Prefix caching support
 - (Experimental) Multi-lora support
-vLLM seamlessly supports many Hugging Face models, including the following architectures:
+vLLM seamlessly supports most popular open-source models on HuggingFace, including:
 - Transformer-like LLMs (e.g., Llama)
 - Mixture-of-Expert LLMs (e.g., Mixtral)
 - Multi-modal LLMs (e.g., LLaVA)
- Aquila & Aquila2 (`BAAI/AquilaChat2-7B`, `BAAI/AquilaChat2-34B`, `BAAI/Aquila-7B`, `BAAI/AquilaChat-7B`, etc.)
+Find the full list of supported models [here](https://docs.vllm.ai/en/latest/models/supported_models.html).
- Baichuan & Baichuan2 (`baichuan-inc/Baichuan2-13B-Chat`, `baichuan-inc/Baichuan-7B`, etc.)
+
- BLOOM (`bigscience/bloom`, `bigscience/bloomz`, etc.)
+## Getting Started
 - ChatGLM (`THUDM/chatglm2-6b`, `THUDM/chatglm3-6b`, etc.)
 - Command-R (`CohereForAI/c4ai-command-r-v01`, etc.)
 - DBRX (`databricks/dbrx-base`, `databricks/dbrx-instruct` etc.)
 - DeciLM (`Deci/DeciLM-7B`, `Deci/DeciLM-7B-instruct`, etc.)
 - Falcon (`tiiuae/falcon-7b`, `tiiuae/falcon-40b`, `tiiuae/falcon-rw-7b`, etc.)
 - Gemma (`google/gemma-2b`, `google/gemma-7b`, etc.)
 - GPT-2 (`gpt2`, `gpt2-xl`, etc.)
 - GPT BigCode (`bigcode/starcoder`, `bigcode/gpt_bigcode-santacoder`, etc.)
 - GPT-J (`EleutherAI/gpt-j-6b`, `nomic-ai/gpt4all-j`, etc.)
 - GPT-NeoX (`EleutherAI/gpt-neox-20b`, `databricks/dolly-v2-12b`, `stabilityai/stablelm-tuned-alpha-7b`, etc.)
 - InternLM (`internlm/internlm-7b`, `internlm/internlm-chat-7b`, etc.)
 - InternLM2 (`internlm/internlm2-7b`, `internlm/internlm2-chat-7b`, etc.)
 - Jais (`core42/jais-13b`, `core42/jais-13b-chat`, `core42/jais-30b-v3`, `core42/jais-30b-chat-v3`, etc.)
 - LLaMA & LLaMA-2 (`meta-llama/Llama-2-70b-hf`, `lmsys/vicuna-13b-v1.3`, `young-geng/koala`, `openlm-research/open_llama_13b`, etc.)
 - Mistral (`mistralai/Mistral-7B-v0.1`, `mistralai/Mistral-7B-Instruct-v0.1`, etc.)
 - Mixtral (`mistralai/Mixtral-8x7B-v0.1`, `mistralai/Mixtral-8x7B-Instruct-v0.1`, etc.)
 - MPT (`mosaicml/mpt-7b`, `mosaicml/mpt-30b`, etc.)
 - OLMo (`allenai/OLMo-1B`, `allenai/OLMo-7B`, etc.)
 - OPT (`facebook/opt-66b`, `facebook/opt-iml-max-30b`, etc.)
 - Orion (`OrionStarAI/Orion-14B-Base`, `OrionStarAI/Orion-14B-Chat`, etc.)
 - Phi (`microsoft/phi-1_5`, `microsoft/phi-2`, etc.)
 - Qwen (`Qwen/Qwen-7B`, `Qwen/Qwen-7B-Chat`, etc.)
 - Qwen2 (`Qwen/Qwen2-7B-beta`, `Qwen/Qwen-7B-Chat-beta`, etc.)
 - Qwen2MoE (`Qwen/Qwen1.5-MoE-A2.7B`, `Qwen/Qwen1.5-MoE-A2.7B-Chat`, etc.)
 - StableLM(`stabilityai/stablelm-3b-4e1t`, `stabilityai/stablelm-base-alpha-7b-v2`, etc.)
 - Starcoder2(`bigcode/starcoder2-3b`, `bigcode/starcoder2-7b`, `bigcode/starcoder2-15b`, etc.)
 - Xverse (`xverse/XVERSE-7B-Chat`, `xverse/XVERSE-13B-Chat`, `xverse/XVERSE-65B-Chat`, etc.)
 - Yi (`01-ai/Yi-6B`, `01-ai/Yi-34B`, etc.)
 Install vLLM with pip or [from source](https://vllm.readthedocs.io/en/latest/getting_started/installation.html#build-from-source):
@@ -101,9 +78,7 @@ Install vLLM with pip or [from source](https://vllm.readthedocs.io/en/latest/get
 pip install vllm
 ```
-## Getting Started
+Visit our [documentation](https://vllm.readthedocs.io/en/latest/) to learn more.
 Visit our [documentation](https://vllm.readthedocs.io/en/latest/) to get started.
 - [Installation](https://vllm.readthedocs.io/en/latest/getting_started/installation.html)
 - [Quickstart](https://vllm.readthedocs.io/en/latest/getting_started/quickstart.html)
 - [Supported Models](https://vllm.readthedocs.io/en/latest/models/supported_models.html)
@@ -113,6 +88,33 @@ Visit our [documentation](https://vllm.readthedocs.io/en/latest/) to get started
 We welcome and value any contributions and collaborations.
 Please check out [CONTRIBUTING.md](./CONTRIBUTING.md) for how to get involved.
 ## Sponsors
 vLLM is a community project. Our compute resources for development and testing are supported by the following organizations. Thank you for your support!
 <!-- Note: Please sort them in alphabetical order. -->
 <!-- Note: Please keep these consistent with docs/source/community/sponsors.md -->
 - a16z
 - AMD
 - Anyscale
 - AWS
 - Crusoe Cloud
 - Databricks
 - DeepInfra
 - Dropbox
 - Lambda Lab
 - NVIDIA
 - Replicate
 - Roblox
 - RunPod
 - Sequoia Capital
 - Trainy
 - UC Berkeley
 - UC San Diego
 We also have an official fundraising venue through [OpenCollective](https://opencollective.com/vllm). We plan to use the fund to support the development, maintenance, and adoption of vLLM.
 ## Citation
 If you use vLLM for your research, please cite our [paper](https://arxiv.org/abs/2309.06180):
--- a/benchmarks/backend_request_func.py
+++ b/benchmarks/backend_request_func.py
@@ -27,8 +27,8 @@ class RequestFuncInput:
 class RequestFuncOutput:
    generated_text: str = ""
    success: bool = False
-    latency: float = 0
+    latency: float = 0.0
-    ttft: float = 0  # Time to first token
+    ttft: float = 0.0  # Time to first token
    itl: List[float] = field(
        default_factory=list)  # List of inter-token latencies
    prompt_len: int = 0
@@ -58,23 +58,28 @@ async def async_request_tgi(
        output = RequestFuncOutput()
        output.prompt_len = request_func_input.prompt_len
-        ttft = 0
+        ttft = 0.0
        st = time.perf_counter()
        most_recent_timestamp = st
        try:
            async with session.post(url=api_url, json=payload) as response:
                if response.status == 200:
-                    async for chunk in response.content:
+                    async for chunk_bytes in response.content:
-                        chunk = chunk.strip()
+                        chunk_bytes = chunk_bytes.strip()
-                        if not chunk:
+                        if not chunk_bytes:
                            continue
                        chunk_bytes = chunk_bytes.decode("utf-8")
-                        chunk = remove_prefix(chunk.decode("utf-8"), "data:")
+                        #NOTE: Sometimes TGI returns a ping response without
                        # any data, we should skip it.
                        if chunk_bytes.startswith(":"):
                            continue
                        chunk = remove_prefix(chunk_bytes, "data:")
                        data = json.loads(chunk)
                        timestamp = time.perf_counter()
                        # First token
-                        if ttft == 0:
+                        if ttft == 0.0:
                            ttft = time.perf_counter() - st
                            output.ttft = ttft
@@ -88,6 +93,9 @@ async def async_request_tgi(
                    output.latency = most_recent_timestamp - st
                    output.success = True
                    output.generated_text = data["generated_text"]
                else:
                    output.error = response.reason or ""
                    output.success = False
        except Exception:
            output.success = False
            exc_info = sys.exc_info()
@@ -119,23 +127,25 @@ async def async_request_trt_llm(
        output = RequestFuncOutput()
        output.prompt_len = request_func_input.prompt_len
-        ttft = 0
+        ttft = 0.0
        st = time.perf_counter()
        most_recent_timestamp = st
        try:
            async with session.post(url=api_url, json=payload) as response:
                if response.status == 200:
-                    async for chunk in response.content:
+                    async for chunk_bytes in response.content:
-                        chunk = chunk.strip()
+                        chunk_bytes = chunk_bytes.strip()
-                        if not chunk:
+                        if not chunk_bytes:
                            continue
-                        chunk = remove_prefix(chunk.decode("utf-8"), "data:")
+                        chunk = remove_prefix(chunk_bytes.decode("utf-8"),
                                              "data:")
                        data = json.loads(chunk)
                        output.generated_text += data["text_output"]
                        timestamp = time.perf_counter()
                        # First token
-                        if ttft == 0:
+                        if ttft == 0.0:
                            ttft = time.perf_counter() - st
                            output.ttft = ttft
@@ -147,11 +157,10 @@ async def async_request_trt_llm(
                        most_recent_timestamp = timestamp
                    output.latency = most_recent_timestamp - st
                    output.generated_text = json.loads(data)["text_output"]
                    output.success = True
                else:
-                    output.error = response.reason
+                    output.error = response.reason or ""
                    output.success = False
        except Exception:
            output.success = False
@@ -195,7 +204,7 @@ async def async_request_deepspeed_mii(
                    output.generated_text = parsed_resp["text"][0]
                    output.success = True
                else:
-                    output.error = response.reason
+                    output.error = response.reason or ""
                    output.success = False
        except Exception:
            output.success = False
@@ -234,19 +243,20 @@ async def async_request_openai_completions(
        output.prompt_len = request_func_input.prompt_len
        generated_text = ""
-        ttft = 0
+        ttft = 0.0
        st = time.perf_counter()
        most_recent_timestamp = st
        try:
            async with session.post(url=api_url, json=payload,
                                    headers=headers) as response:
                if response.status == 200:
-                    async for chunk in response.content:
+                    async for chunk_bytes in response.content:
-                        chunk = chunk.strip()
+                        chunk_bytes = chunk_bytes.strip()
-                        if not chunk:
+                        if not chunk_bytes:
                            continue
-                        chunk = remove_prefix(chunk.decode("utf-8"), "data: ")
+                        chunk = remove_prefix(chunk_bytes.decode("utf-8"),
                                              "data: ")
                        if chunk == "[DONE]":
                            latency = time.perf_counter() - st
                        else:
@@ -255,7 +265,7 @@ async def async_request_openai_completions(
                            if data["choices"][0]["text"]:
                                timestamp = time.perf_counter()
                                # First token
-                                if ttft == 0:
+                                if ttft == 0.0:
                                    ttft = time.perf_counter() - st
                                    output.ttft = ttft
@@ -273,6 +283,9 @@ async def async_request_openai_completions(
                    output.generated_text = generated_text
                    output.success = True
                    output.latency = latency
                else:
                    output.error = response.reason or ""
                    output.success = False
        except Exception:
            output.success = False
            exc_info = sys.exc_info()
@@ -315,28 +328,30 @@ async def async_request_openai_chat_completions(
        output.prompt_len = request_func_input.prompt_len
        generated_text = ""
-        ttft = 0
+        ttft = 0.0
        st = time.perf_counter()
        most_recent_timestamp = st
        try:
            async with session.post(url=api_url, json=payload,
                                    headers=headers) as response:
                if response.status == 200:
-                    async for chunk in response.content:
+                    async for chunk_bytes in response.content:
-                        chunk = chunk.strip()
+                        chunk_bytes = chunk_bytes.strip()
-                        if not chunk:
+                        if not chunk_bytes:
                            continue
-                        chunk = remove_prefix(chunk.decode("utf-8"), "data: ")
+                        chunk = remove_prefix(chunk_bytes.decode("utf-8"),
                                              "data: ")
                        if chunk == "[DONE]":
                            latency = time.perf_counter() - st
                        else:
                            timestamp = time.perf_counter()
                            data = json.loads(chunk)
-                            if "content" in data["choices"][0]["delta"]:
+                            delta = data["choices"][0]["delta"]
                            if delta.get("content", None):
                                # First token
-                                if ttft == 0:
+                                if ttft == 0.0:
                                    ttft = time.perf_counter() - st
                                    output.ttft = ttft
@@ -345,8 +360,7 @@ async def async_request_openai_chat_completions(
                                    output.itl.append(timestamp -
                                                      most_recent_timestamp)
-                                generated_text += data["choices"][0]["delta"][
+                                generated_text += delta["content"]
                                    "content"]
                            most_recent_timestamp = timestamp
@@ -354,7 +368,7 @@ async def async_request_openai_chat_completions(
                    output.success = True
                    output.latency = latency
                else:
-                    output.error = response.reason
+                    output.error = response.reason or ""
                    output.success = False
        except Exception:
            output.success = False
--- a/benchmarks/benchmark_latency.py
+++ b/benchmarks/benchmark_latency.py
@@ -1,14 +1,17 @@
 """Benchmark the latency of processing a single batch of requests."""
 import argparse
 import json
 import time
 from pathlib import Path
-from typing import Optional
+from typing import List, Optional
 import numpy as np
 import torch
 from tqdm import tqdm
 from vllm import LLM, SamplingParams
 from vllm.inputs import PromptStrictInputs
 from vllm.model_executor.layers.quantization import QUANTIZATION_METHODS
 def main(args: argparse.Namespace):
@@ -17,6 +20,8 @@ def main(args: argparse.Namespace):
    # NOTE(woosuk): If the request cannot be processed in a single batch,
    # the engine will automatically process the request in multiple batches.
    llm = LLM(model=args.model,
              speculative_model=args.speculative_model,
              num_speculative_tokens=args.num_speculative_tokens,
              tokenizer=args.tokenizer,
              quantization=args.quantization,
              tensor_parallel_size=args.tensor_parallel_size,
@@ -24,11 +29,15 @@ def main(args: argparse.Namespace):
              dtype=args.dtype,
              enforce_eager=args.enforce_eager,
              kv_cache_dtype=args.kv_cache_dtype,
              quantization_param_path=args.quantization_param_path,
              device=args.device,
              ray_workers_use_nsight=args.ray_workers_use_nsight,
              use_v2_block_manager=args.use_v2_block_manager,
              enable_chunked_prefill=args.enable_chunked_prefill,
              download_dir=args.download_dir,
-              block_size=args.block_size)
+              block_size=args.block_size,
              gpu_memory_utilization=args.gpu_memory_utilization,
              distributed_executor_backend=args.distributed_executor_backend)
    sampling_params = SamplingParams(
        n=args.n,
@@ -42,7 +51,9 @@ def main(args: argparse.Namespace):
    dummy_prompt_token_ids = np.random.randint(10000,
                                               size=(args.batch_size,
                                                     args.input_len))
-    dummy_prompt_token_ids = dummy_prompt_token_ids.tolist()
+    dummy_inputs: List[PromptStrictInputs] = [{
        "prompt_token_ids": batch
    } for batch in dummy_prompt_token_ids.tolist()]
    def run_to_completion(profile_dir: Optional[str] = None):
        if profile_dir:
@@ -53,13 +64,13 @@ def main(args: argparse.Namespace):
                    ],
                    on_trace_ready=torch.profiler.tensorboard_trace_handler(
                        str(profile_dir))) as p:
-                llm.generate(prompt_token_ids=dummy_prompt_token_ids,
+                llm.generate(dummy_inputs,
                             sampling_params=sampling_params,
                             use_tqdm=False)
            print(p.key_averages())
        else:
            start_time = time.perf_counter()
-            llm.generate(prompt_token_ids=dummy_prompt_token_ids,
+            llm.generate(dummy_inputs,
                         sampling_params=sampling_params,
                         use_tqdm=False)
            end_time = time.perf_counter()
@@ -67,7 +78,8 @@ def main(args: argparse.Namespace):
            return latency
    print("Warming up...")
-    run_to_completion(profile_dir=None)
+    for _ in tqdm(range(args.num_iters_warmup), desc="Warmup iterations"):
        run_to_completion(profile_dir=None)
    if args.profile:
        profile_dir = args.profile_result_dir
@@ -83,7 +95,22 @@ def main(args: argparse.Namespace):
    latencies = []
    for _ in tqdm(range(args.num_iters), desc="Profiling iterations"):
        latencies.append(run_to_completion(profile_dir=None))
    latencies = np.array(latencies)
    percentages = [10, 25, 50, 75, 90]
    percentiles = np.percentile(latencies, percentages)
    print(f'Avg latency: {np.mean(latencies)} seconds')
    for percentage, percentile in zip(percentages, percentiles):
        print(f'{percentage}% percentile latency: {percentile} seconds')
    # Output JSON results if specified
    if args.output_json:
        results = {
            "avg_latency": np.mean(latencies),
            "latencies": latencies.tolist(),
            "percentiles": dict(zip(percentages, percentiles.tolist())),
        }
        with open(args.output_json, "w") as f:
            json.dump(results, f, indent=4)
 if __name__ == '__main__':
@@ -91,10 +118,12 @@ if __name__ == '__main__':
        description='Benchmark the latency of processing a single batch of '
        'requests till completion.')
    parser.add_argument('--model', type=str, default='facebook/opt-125m')
    parser.add_argument('--speculative-model', type=str, default=None)
    parser.add_argument('--num-speculative-tokens', type=int, default=None)
    parser.add_argument('--tokenizer', type=str, default=None)
    parser.add_argument('--quantization',
                        '-q',
-                        choices=['awq', 'gptq', 'squeezellm', None],
+                        choices=[*QUANTIZATION_METHODS, None],
                        default=None)
    parser.add_argument('--tensor-parallel-size', '-tp', type=int, default=1)
    parser.add_argument('--input-len', type=int, default=32)
@@ -105,9 +134,13 @@ if __name__ == '__main__':
                        default=1,
                        help='Number of generated sequences per prompt.')
    parser.add_argument('--use-beam-search', action='store_true')
    parser.add_argument('--num-iters-warmup',
                        type=int,
                        default=10,
                        help='Number of iterations to run for warmup.')
    parser.add_argument('--num-iters',
                        type=int,
-                        default=3,
+                        default=30,
                        help='Number of iterations to run.')
    parser.add_argument('--trust-remote-code',
                        action='store_true',
@@ -125,12 +158,23 @@ if __name__ == '__main__':
                        action='store_true',
                        help='enforce eager mode and disable CUDA graph')
    parser.add_argument(
-        "--kv-cache-dtype",
+        '--kv-cache-dtype',
        type=str,
-        choices=['auto', 'fp8_e5m2'],
+        choices=['auto', 'fp8', 'fp8_e5m2', 'fp8_e4m3'],
-        default='auto',
+        default="auto",
-        help=
+        help='Data type for kv cache storage. If "auto", will use model '
-        'Data type for kv cache storage. If "auto", will use model data type.')
+        'data type. CUDA 11.8+ supports fp8 (=fp8_e4m3) and fp8_e5m2. '
        'ROCm (AMD GPU) supports fp8 (=fp8_e4m3)')
    parser.add_argument(
        '--quantization-param-path',
        type=str,
        default=None,
        help='Path to the JSON file containing the KV cache scaling factors. '
        'This should generally be supplied, when KV cache dtype is FP8. '
        'Otherwise, KV cache scaling factors default to 1.0, which may cause '
        'accuracy issues. FP8_E5M2 (without scaling) is only supported on '
        'cuda version greater than 11.8. On ROCm (AMD GPU), FP8_E4M3 is '
        'instead supported for common inference criteria.')
    parser.add_argument(
        '--profile',
        action='store_true',
@@ -145,18 +189,18 @@ if __name__ == '__main__':
        "--device",
        type=str,
        default="cuda",
-        choices=["cuda"],
+        choices=["cuda", "cpu", "tpu"],
-        help='device type for vLLM execution, supporting CUDA only currently.')
+        help='device type for vLLM execution, supporting CUDA and CPU.')
    parser.add_argument('--block-size',
                        type=int,
                        default=16,
                        help='block size of key/value cache')
    parser.add_argument(
        '--enable-chunked-prefill',
-        type=bool,
+        action='store_true',
        default=False,
        help='If True, the prefill requests can be chunked based on the '
        'max_num_batched_tokens')
    parser.add_argument('--use-v2-block-manager', action='store_true')
    parser.add_argument(
        "--ray-workers-use-nsight",
        action='store_true',
@@ -167,5 +211,23 @@ if __name__ == '__main__':
                        default=None,
                        help='directory to download and load the weights, '
                        'default to the default cache dir of huggingface')
    parser.add_argument(
        '--output-json',
        type=str,
        default=None,
        help='Path to save the latency results in JSON format.')
    parser.add_argument('--gpu-memory-utilization',
                        type=float,
                        default=0.9,
                        help='the fraction of GPU memory to be used for '
                        'the model executor, which can range from 0 to 1.'
                        'If unspecified, will use the default value of 0.9.')
    parser.add_argument(
        '--distributed-executor-backend',
        choices=['ray', 'mp'],
        default=None,
        help='Backend to use for distributed serving. When more than 1 GPU '
        'is used, will be automatically set to "ray" if installed '
        'or "mp" (multiprocessing) otherwise.')
    args = parser.parse_args()
    main(args)
--- a/benchmarks/benchmark_prefix_caching.py
+++ b/benchmarks/benchmark_prefix_caching.py
@@ -16,20 +16,22 @@ def test_prefix(llm=None, sampling_params=None, prompts=None):
 def main(args):
-    llm = LLM(model="baichuan-inc/Baichuan2-13B-Chat",
+    llm = LLM(model=args.model,
              tokenizer_mode='auto',
              trust_remote_code=True,
              enforce_eager=True,
              use_v2_block_manager=args.use_v2_block_manager,
              tensor_parallel_size=args.tensor_parallel_size,
              enable_prefix_caching=args.enable_prefix_caching)
    num_prompts = 100
    prompts = [PROMPT] * num_prompts
-    sampling_params = SamplingParams(temperature=0, max_tokens=100)
+    sampling_params = SamplingParams(temperature=0, max_tokens=args.output_len)
    print("------warm up------")
    test_prefix(
        llm=llm,
-        prompts=prompts[:1],
+        prompts=prompts,
        sampling_params=sampling_params,
    )
@@ -45,8 +47,16 @@ if __name__ == "__main__":
    parser = argparse.ArgumentParser(
        description='Benchmark the performance with or without automatic '
        'prefix caching.')
    parser.add_argument('--model',
                        type=str,
                        default='baichuan-inc/Baichuan2-13B-Chat')
    parser.add_argument('--tensor-parallel-size', '-tp', type=int, default=1)
    parser.add_argument('--output-len', type=int, default=10)
    parser.add_argument('--enable-prefix-caching',
                        action='store_true',
                        help='enable prefix caching')
    parser.add_argument('--use-v2-block-manager',
                        action='store_true',
                        help='Use BlockSpaceMangerV2')
    args = parser.parse_args()
    main(args)
--- a/benchmarks/benchmark_serving.py
+++ b/benchmarks/benchmark_serving.py
@@ -17,6 +17,10 @@ On the client side, run:
        --dataset-path <path to dataset> \
        --request-rate <request_rate> \ # By default <request_rate> is inf
        --num-prompts <num_prompts> # By default <num_prompts> is 1000
    when using tgi backend, add
        --endpoint /generate_stream
    to the end of the command above.
 """
 import argparse
 import asyncio
@@ -27,7 +31,7 @@ import time
 import warnings
 from dataclasses import dataclass
 from datetime import datetime
-from typing import AsyncGenerator, List, Tuple
+from typing import AsyncGenerator, List, Optional, Tuple
 import numpy as np
 from backend_request_func import (ASYNC_REQUEST_FUNCS, RequestFuncInput,
@@ -52,13 +56,20 @@ class BenchmarkMetrics:
    mean_tpot_ms: float
    median_tpot_ms: float
    p99_tpot_ms: float
    mean_itl_ms: float
    median_itl_ms: float
    p99_itl_ms: float
 def sample_sharegpt_requests(
    dataset_path: str,
    num_requests: int,
    tokenizer: PreTrainedTokenizerBase,
    fixed_output_len: Optional[int] = None,
 ) -> List[Tuple[str, int, int]]:
    if fixed_output_len is not None and fixed_output_len < 4:
        raise ValueError("output_len too small")
    # Load the dataset.
    with open(dataset_path) as f:
        dataset = json.load(f)
@@ -68,38 +79,32 @@ def sample_sharegpt_requests(
    dataset = [(data["conversations"][0]["value"],
                data["conversations"][1]["value"]) for data in dataset]
-    # some of these will be filtered out, so sample more than we need
+    # Shuffle the dataset.
-    sampled_indices = random.sample(range(len(dataset)),
+    random.shuffle(dataset)
                                    int(num_requests * 1.2))
    dataset = [dataset[i] for i in sampled_indices]
-    # Tokenize the prompts and completions.
+    # Filter out sequences that are too long or too short
    prompts = [prompt for prompt, _ in dataset]
    prompt_token_ids = tokenizer(prompts).input_ids
    completions = [completion for _, completion in dataset]
    completion_token_ids = tokenizer(completions).input_ids
    tokenized_dataset = []
    for i in range(len(dataset)):
        output_len = len(completion_token_ids[i])
        tokenized_dataset.append((prompts[i], prompt_token_ids[i], output_len))
    # Filter out too long sequences.
    filtered_dataset: List[Tuple[str, int, int]] = []
-    for prompt, prompt_token_ids, output_len in tokenized_dataset:
+    for i in range(len(dataset)):
        if len(filtered_dataset) == num_requests:
            break
        # Tokenize the prompts and completions.
        prompt = dataset[i][0]
        prompt_token_ids = tokenizer(prompt).input_ids
        completion = dataset[i][1]
        completion_token_ids = tokenizer(completion).input_ids
        prompt_len = len(prompt_token_ids)
        output_len = len(completion_token_ids
                         ) if fixed_output_len is None else fixed_output_len
        if prompt_len < 4 or output_len < 4:
            # Prune too short sequences.
            # This is because TGI causes errors when the input or output length
            # is too short.
            continue
        if prompt_len > 1024 or prompt_len + output_len > 2048:
            # Prune too long sequences.
            continue
        filtered_dataset.append((prompt, prompt_len, output_len))
-    # Sample the requests.
+    return filtered_dataset
    sampled_requests = random.sample(filtered_dataset, num_requests)
    return sampled_requests
 def sample_sonnet_requests(
@@ -110,7 +115,9 @@ def sample_sonnet_requests(
    prefix_len: int,
    tokenizer: PreTrainedTokenizerBase,
 ) -> List[Tuple[str, str, int, int]]:
-    assert input_len > prefix_len, "input_len must be greater than prefix_len."
+    assert (
        input_len > prefix_len
    ), "'args.sonnet-input-len' must be greater than 'args.prefix-input-len'."
    # Load the dataset.
    with open(dataset_path) as f:
@@ -131,8 +138,9 @@ def sample_sonnet_requests(
        base_message, add_generation_prompt=True, tokenize=False)
    base_prompt_offset = len(tokenizer(base_prompt_formatted).input_ids)
-    assert (input_len > base_prompt_offset
+    assert (
-            ), f"Please set 'args.input-len' higher than {base_prompt_offset}."
+        input_len > base_prompt_offset
    ), f"Please set 'args.sonnet-input-len' higher than {base_prompt_offset}."
    num_input_lines = round(
        (input_len - base_prompt_offset) / average_poem_len)
@@ -140,7 +148,7 @@ def sample_sonnet_requests(
    # prompt are fixed poem lines.
    assert (
        prefix_len > base_prompt_offset
-    ), f"Please set 'args.prefix-len' higher than {base_prompt_offset}."
+    ), f"Please set 'args.sonnet-prefix-len' higher than {base_prompt_offset}."
    num_prefix_lines = round(
        (prefix_len - base_prompt_offset) / average_poem_len)
@@ -195,21 +203,34 @@ def calculate_metrics(
    actual_output_lens = []
    total_input = 0
    completed = 0
    itls = []
    tpots = []
    ttfts = []
    for i in range(len(outputs)):
        if outputs[i].success:
-            output_len = len(tokenizer(outputs[i].generated_text).input_ids)
+            # We use the tokenizer to count the number of output tokens for all
            # serving backends instead of looking at len(outputs[i].itl) since
            # multiple output tokens may be bundled together
            # Note: this may inflate the output token count slightly
            output_len = len(
                tokenizer(outputs[i].generated_text,
                          add_special_tokens=False).input_ids)
            actual_output_lens.append(output_len)
            total_input += input_requests[i][1]
            if output_len > 1:
                tpots.append(
                    (outputs[i].latency - outputs[i].ttft) / (output_len - 1))
            itls += outputs[i].itl
            ttfts.append(outputs[i].ttft)
            completed += 1
        else:
            actual_output_lens.append(0)
    if completed == 0:
        warnings.warn(
            "All requests failed. This is likely due to a misconfiguration "
            "on the benchmark arguments.",
            stacklevel=2)
    metrics = BenchmarkMetrics(
        completed=completed,
        total_input=total_input,
@@ -221,9 +242,12 @@ def calculate_metrics(
        1000,  # ttfts is empty if streaming is not supported by backend
        median_ttft_ms=np.median(ttfts or 0) * 1000,
        p99_ttft_ms=np.percentile(ttfts or 0, 99) * 1000,
-        mean_tpot_ms=np.mean(tpots) * 1000,
+        mean_tpot_ms=np.mean(tpots or 0) * 1000,
-        median_tpot_ms=np.median(tpots) * 1000,
+        median_tpot_ms=np.median(tpots or 0) * 1000,
-        p99_tpot_ms=np.percentile(tpots, 99) * 1000,
+        p99_tpot_ms=np.percentile(tpots or 0, 99) * 1000,
        mean_itl_ms=np.mean(itls or 0) * 1000,
        median_itl_ms=np.median(itls or 0) * 1000,
        p99_itl_ms=np.percentile(itls or 0, 99) * 1000,
    )
    return metrics, actual_output_lens
@@ -245,6 +269,24 @@ async def benchmark(
    else:
        raise ValueError(f"Unknown backend: {backend}")
    print("Starting initial single prompt test run...")
    test_prompt, test_prompt_len, test_output_len = input_requests[0]
    test_input = RequestFuncInput(
        model=model_id,
        prompt=test_prompt,
        api_url=api_url,
        prompt_len=test_prompt_len,
        output_len=test_output_len,
        best_of=best_of,
        use_beam_search=use_beam_search,
    )
    test_output = await request_func(request_func_input=test_input)
    if not test_output.success:
        raise ValueError(
            "Initial test run failed - Please make sure benchmark arguments "
            f"are correctly specified. Error: {test_output.error}")
    else:
        print("Initial test run completed. Starting main benchmark run...")
    print(f"Traffic request rate: {request_rate}")
    pbar = None if disable_tqdm else tqdm(total=len(input_requests))
@@ -305,6 +347,10 @@ async def benchmark(
    print("{:<40} {:<10.2f}".format("Median TPOT (ms):",
                                    metrics.median_tpot_ms))
    print("{:<40} {:<10.2f}".format("P99 TPOT (ms):", metrics.p99_tpot_ms))
    print("{s:{c}^{n}}".format(s='Inter-token Latency', n=50, c='-'))
    print("{:<40} {:<10.2f}".format("Mean ITL (ms):", metrics.mean_itl_ms))
    print("{:<40} {:<10.2f}".format("Median ITL (ms):", metrics.median_itl_ms))
    print("{:<40} {:<10.2f}".format("P99 ITL (ms):", metrics.p99_itl_ms))
    print("=" * 50)
    result = {
@@ -321,6 +367,9 @@ async def benchmark(
        "mean_tpot_ms": metrics.mean_tpot_ms,
        "median_tpot_ms": metrics.median_tpot_ms,
        "p99_tpot_ms": metrics.p99_tpot_ms,
        "mean_itl_ms": metrics.mean_itl_ms,
        "median_itl_ms": metrics.median_itl_ms,
        "p99_itl_ms": metrics.p99_itl_ms,
        "input_lens": [output.prompt_len for output in outputs],
        "output_lens": actual_output_lens,
        "ttfts": [output.ttft for output in outputs],
@@ -358,6 +407,7 @@ def main(args: argparse.Namespace):
            dataset_path=args.dataset,
            num_requests=args.num_prompts,
            tokenizer=tokenizer,
            fixed_output_len=args.sharegpt_output_len,
        )
    elif args.dataset_name == "sharegpt":
@@ -365,6 +415,7 @@ def main(args: argparse.Namespace):
            dataset_path=args.dataset_path,
            num_requests=args.num_prompts,
            tokenizer=tokenizer,
            fixed_output_len=args.sharegpt_output_len,
        )
    elif args.dataset_name == "sonnet":
@@ -373,9 +424,9 @@ def main(args: argparse.Namespace):
            input_requests = sample_sonnet_requests(
                dataset_path=args.dataset_path,
                num_requests=args.num_prompts,
-                input_len=args.input_len,
+                input_len=args.sonnet_input_len,
-                output_len=args.output_len,
+                output_len=args.sonnet_output_len,
-                prefix_len=args.prefix_len,
+                prefix_len=args.sonnet_prefix_len,
                tokenizer=tokenizer,
            )
            input_requests = [(prompt, prompt_len, output_len)
@@ -388,9 +439,9 @@ def main(args: argparse.Namespace):
            input_requests = sample_sonnet_requests(
                dataset_path=args.dataset_path,
                num_requests=args.num_prompts,
-                input_len=args.input_len,
+                input_len=args.sonnet_input_len,
-                output_len=args.output_len,
+                output_len=args.sonnet_output_len,
-                prefix_len=args.prefix_len,
+                prefix_len=args.sonnet_prefix_len,
                tokenizer=tokenizer,
            )
            input_requests = [(prompt_formatted, prompt_len, output_len)
@@ -521,6 +572,12 @@ if __name__ == "__main__":
        default=1000,
        help="Number of prompts to process.",
    )
    parser.add_argument(
        "--sharegpt-output-len",
        type=int,
        default=None,
        help="Output length for each request. Overrides the output length "
        "from the ShareGPT dataset.")
    parser.add_argument(
        "--sonnet-input-len",
        type=int,
--- a/benchmarks/benchmark_throughput.py
+++ b/benchmarks/benchmark_throughput.py
@@ -10,6 +10,8 @@ from tqdm import tqdm
 from transformers import (AutoModelForCausalLM, AutoTokenizer,
                          PreTrainedTokenizerBase)
 from vllm.model_executor.layers.quantization import QUANTIZATION_METHODS
 def sample_requests(
    dataset_path: str,
@@ -29,22 +31,23 @@ def sample_requests(
    dataset = [(data["conversations"][0]["value"],
                data["conversations"][1]["value"]) for data in dataset]
-    # Tokenize the prompts and completions.
+    # Shuffle the dataset.
-    prompts = [prompt for prompt, _ in dataset]
+    random.shuffle(dataset)
    prompt_token_ids = tokenizer(prompts).input_ids
    completions = [completion for _, completion in dataset]
    completion_token_ids = tokenizer(completions).input_ids
    tokenized_dataset = []
    for i in range(len(dataset)):
        output_len = len(completion_token_ids[i])
        if fixed_output_len is not None:
            output_len = fixed_output_len
        tokenized_dataset.append((prompts[i], prompt_token_ids[i], output_len))
-    # Filter out too long sequences.
+    # Filter out sequences that are too long or too short
    filtered_dataset: List[Tuple[str, int, int]] = []
-    for prompt, prompt_token_ids, output_len in tokenized_dataset:
+    for i in range(len(dataset)):
        if len(filtered_dataset) == num_requests:
            break
        # Tokenize the prompts and completions.
        prompt = dataset[i][0]
        prompt_token_ids = tokenizer(prompt).input_ids
        completion = dataset[i][1]
        completion_token_ids = tokenizer(completion).input_ids
        prompt_len = len(prompt_token_ids)
        output_len = len(completion_token_ids
                         ) if fixed_output_len is None else fixed_output_len
        if prompt_len < 4 or output_len < 4:
            # Prune too short sequences.
            continue
@@ -53,9 +56,7 @@ def sample_requests(
            continue
        filtered_dataset.append((prompt, prompt_len, output_len))
-    # Sample the requests.
+    return filtered_dataset
    sampled_requests = random.sample(filtered_dataset, num_requests)
    return sampled_requests
 def run_vllm(
@@ -72,47 +73,54 @@ def run_vllm(
    max_model_len: Optional[int],
    enforce_eager: bool,
    kv_cache_dtype: str,
    quantization_param_path: Optional[str],
    device: str,
    enable_prefix_caching: bool,
    enable_chunked_prefill: bool,
    max_num_batched_tokens: int,
    distributed_executor_backend: Optional[str],
    gpu_memory_utilization: float = 0.9,
    download_dir: Optional[str] = None,
 ) -> float:
    from vllm import LLM, SamplingParams
-    llm = LLM(model=model,
+    llm = LLM(
-              tokenizer=tokenizer,
+        model=model,
-              quantization=quantization,
+        tokenizer=tokenizer,
-              tensor_parallel_size=tensor_parallel_size,
+        quantization=quantization,
-              seed=seed,
+        tensor_parallel_size=tensor_parallel_size,
-              trust_remote_code=trust_remote_code,
+        seed=seed,
-              dtype=dtype,
+        trust_remote_code=trust_remote_code,
-              max_model_len=max_model_len,
+        dtype=dtype,
-              gpu_memory_utilization=gpu_memory_utilization,
+        max_model_len=max_model_len,
-              enforce_eager=enforce_eager,
+        gpu_memory_utilization=gpu_memory_utilization,
-              kv_cache_dtype=kv_cache_dtype,
+        enforce_eager=enforce_eager,
-              device=device,
+        kv_cache_dtype=kv_cache_dtype,
-              enable_prefix_caching=enable_prefix_caching,
+        quantization_param_path=quantization_param_path,
-              download_dir=download_dir)
+        device=device,
        enable_prefix_caching=enable_prefix_caching,
        download_dir=download_dir,
        enable_chunked_prefill=enable_chunked_prefill,
        max_num_batched_tokens=max_num_batched_tokens,
        distributed_executor_backend=distributed_executor_backend,
    )
    # Add the requests to the engine.
    prompts = []
    sampling_params = []
    for prompt, _, output_len in requests:
-        sampling_params = SamplingParams(
+        prompts.append(prompt)
-            n=n,
+        sampling_params.append(
-            temperature=0.0 if use_beam_search else 1.0,
+            SamplingParams(
-            top_p=1.0,
+                n=n,
-            use_beam_search=use_beam_search,
+                temperature=0.0 if use_beam_search else 1.0,
-            ignore_eos=True,
+                top_p=1.0,
-            max_tokens=output_len,
+                use_beam_search=use_beam_search,
-        )
+                ignore_eos=True,
-        # FIXME(woosuk): Do not use internal method.
+                max_tokens=output_len,
-        llm._add_request(
+            ))
            prompt=prompt,
            prompt_token_ids=None,
            sampling_params=sampling_params,
        )
    start = time.perf_counter()
-    # FIXME(woosuk): Do not use internal method.
+    llm.generate(prompts, sampling_params, use_tqdm=True)
    llm._run_engine(use_tqdm=True)
    end = time.perf_counter()
    return end - start
@@ -212,14 +220,15 @@ def main(args: argparse.Namespace):
                                   args.output_len)
    if args.backend == "vllm":
-        elapsed_time = run_vllm(requests, args.model, args.tokenizer,
+        elapsed_time = run_vllm(
-                                args.quantization, args.tensor_parallel_size,
+            requests, args.model, args.tokenizer, args.quantization,
-                                args.seed, args.n, args.use_beam_search,
+            args.tensor_parallel_size, args.seed, args.n, args.use_beam_search,
-                                args.trust_remote_code, args.dtype,
+            args.trust_remote_code, args.dtype, args.max_model_len,
-                                args.max_model_len, args.enforce_eager,
+            args.enforce_eager, args.kv_cache_dtype,
-                                args.kv_cache_dtype, args.device,
+            args.quantization_param_path, args.device,
-                                args.enable_prefix_caching,
+            args.enable_prefix_caching, args.enable_chunked_prefill,
-                                args.gpu_memory_utilization, args.download_dir)
+            args.max_num_batched_tokens, args.distributed_executor_backend,
            args.gpu_memory_utilization, args.download_dir)
    elif args.backend == "hf":
        assert args.tensor_parallel_size == 1
        elapsed_time = run_hf(requests, args.model, tokenizer, args.n,
@@ -235,6 +244,18 @@ def main(args: argparse.Namespace):
    print(f"Throughput: {len(requests) / elapsed_time:.2f} requests/s, "
          f"{total_num_tokens / elapsed_time:.2f} tokens/s")
    # Output JSON results if specified
    if args.output_json:
        results = {
            "elapsed_time": elapsed_time,
            "num_requests": len(requests),
            "total_num_tokens": total_num_tokens,
            "requests_per_second": len(requests) / elapsed_time,
            "tokens_per_second": total_num_tokens / elapsed_time,
        }
        with open(args.output_json, "w") as f:
            json.dump(results, f, indent=4)
 if __name__ == "__main__":
    parser = argparse.ArgumentParser(description="Benchmark the throughput.")
@@ -259,7 +280,7 @@ if __name__ == "__main__":
    parser.add_argument("--tokenizer", type=str, default=None)
    parser.add_argument('--quantization',
                        '-q',
-                        choices=['awq', 'gptq', 'squeezellm', None],
+                        choices=[*QUANTIZATION_METHODS, None],
                        default=None)
    parser.add_argument("--tensor-parallel-size", "-tp", type=int, default=1)
    parser.add_argument("--n",
@@ -304,27 +325,58 @@ if __name__ == "__main__":
                        action="store_true",
                        help="enforce eager execution")
    parser.add_argument(
-        "--kv-cache-dtype",
+        '--kv-cache-dtype',
        type=str,
-        choices=["auto", "fp8_e5m2"],
+        choices=['auto', 'fp8', 'fp8_e5m2', 'fp8_e4m3'],
        default="auto",
-        help=
+        help='Data type for kv cache storage. If "auto", will use model '
-        'Data type for kv cache storage. If "auto", will use model data type.')
+        'data type. CUDA 11.8+ supports fp8 (=fp8_e4m3) and fp8_e5m2. '
        'ROCm (AMD GPU) supports fp8 (=fp8_e4m3)')
    parser.add_argument(
        '--quantization-param-path',
        type=str,
        default=None,
        help='Path to the JSON file containing the KV cache scaling factors. '
        'This should generally be supplied, when KV cache dtype is FP8. '
        'Otherwise, KV cache scaling factors default to 1.0, which may cause '
        'accuracy issues. FP8_E5M2 (without scaling) is only supported on '
        'cuda version greater than 11.8. On ROCm (AMD GPU), FP8_E4M3 is '
        'instead supported for common inference criteria.')
    parser.add_argument(
        "--device",
        type=str,
        default="cuda",
-        choices=["cuda"],
+        choices=["cuda", "cpu", "tpu"],
-        help='device type for vLLM execution, supporting CUDA only currently.')
+        help='device type for vLLM execution, supporting CUDA and CPU.')
    parser.add_argument(
        "--enable-prefix-caching",
        action='store_true',
        help="enable automatic prefix caching for vLLM backend.")
    parser.add_argument("--enable-chunked-prefill",
                        action='store_true',
                        help="enable chunked prefill for vLLM backend.")
    parser.add_argument('--max-num-batched-tokens',
                        type=int,
                        default=None,
                        help='maximum number of batched tokens per '
                        'iteration')
    parser.add_argument('--download-dir',
                        type=str,
                        default=None,
                        help='directory to download and load the weights, '
                        'default to the default cache dir of huggingface')
    parser.add_argument(
        '--output-json',
        type=str,
        default=None,
        help='Path to save the throughput results in JSON format.')
    parser.add_argument(
        '--distributed-executor-backend',
        choices=['ray', 'mp'],
        default=None,
        help='Backend to use for distributed serving. When more than 1 GPU '
        'is used, will be automatically set to "ray" if installed '
        'or "mp" (multiprocessing) otherwise.')
    args = parser.parse_args()
    if args.tokenizer is None:
        args.tokenizer = args.model
--- a/benchmarks/cutlass_benchmarks/w8a8_benchmarks.py
+++ b/benchmarks/cutlass_benchmarks/w8a8_benchmarks.py
@@ -0,0 +1,348 @@
 import argparse
 import copy
 import itertools
 import pickle as pkl
 import time
 from typing import Callable, Iterable, List, Tuple
 import torch
 import torch.utils.benchmark as TBenchmark
 from torch.utils.benchmark import Measurement as TMeasurement
 from weight_shapes import WEIGHT_SHAPES
 from vllm import _custom_ops as ops
 DEFAULT_MODELS = list(WEIGHT_SHAPES.keys())[1:]
 DEFAULT_BATCH_SIZES = [1, 16, 32, 64, 128, 256, 512]
 DEFAULT_TP_SIZES = [1]
 # helpers
 def to_fp8(tensor: torch.tensor) -> torch.tensor:
    finfo = torch.finfo(torch.float8_e4m3fn)
    return torch.round(tensor.clamp(
        min=finfo.min, max=finfo.max)).to(dtype=torch.float8_e4m3fn)
 def to_int8(tensor: torch.tensor) -> torch.tensor:
    return torch.round(tensor.clamp(min=-128, max=127)).to(dtype=torch.int8)
 def make_rand_tensors(dtype: torch.dtype, m: int, n: int,
                      k: int) -> Tuple[torch.tensor, torch.tensor]:
    a = torch.randn((m, k), device='cuda') * 5
    b = torch.randn((n, k), device='cuda').t() * 5
    if dtype == torch.int8:
        return to_int8(a), to_int8(b)
    if dtype == torch.float8_e4m3fn:
        return to_fp8(a), to_fp8(b)
    raise ValueError("unsupported dtype")
 # impl
 def pytorch_i8_impl(a: torch.tensor, b: torch.tensor, scale_a: torch.tensor,
                    scale_b: torch.tensor,
                    out_dtype: torch.dtype) -> torch.tensor:
    return torch.mm(a, b)
 def pytorch_fp8_impl(a: torch.tensor, b: torch.tensor, scale_a: torch.tensor,
                     scale_b: torch.tensor,
                     out_dtype: torch.dtype) -> torch.tensor:
    return torch._scaled_mm(a,
                            b,
                            scale_a=scale_a,
                            scale_b=scale_b,
                            out_dtype=out_dtype)
 def pytorch_fp8_impl_fast_accum(a: torch.tensor, b: torch.tensor,
                                scale_a: torch.tensor, scale_b: torch.tensor,
                                out_dtype: torch.dtype) -> torch.tensor:
    return torch._scaled_mm(a,
                            b,
                            scale_a=scale_a,
                            scale_b=scale_b,
                            out_dtype=out_dtype,
                            use_fast_accum=True)
 def cutlass_impl(a: torch.tensor, b: torch.tensor, scale_a: torch.tensor,
                 scale_b: torch.tensor,
                 out_dtype: torch.dtype) -> torch.tensor:
    return ops.cutlass_scaled_mm(a, b, scale_a, scale_b, out_dtype=out_dtype)
 # bench
 def bench_fn(a: torch.tensor, b: torch.tensor, scale_a: torch.tensor,
             scale_b: torch.tensor, out_dtype: torch.dtype, label: str,
             sub_label: str, fn: Callable, description: str) -> TMeasurement:
    min_run_time = 1
    globals = {
        "a": a,
        "b": b,
        "scale_a": scale_a,
        "scale_b": scale_b,
        "out_dtype": out_dtype,
        "fn": fn,
    }
    return TBenchmark.Timer(
        stmt="fn(a, b, scale_a, scale_b, out_dtype)",
        globals=globals,
        label=label,
        sub_label=sub_label,
        description=description,
    ).blocked_autorange(min_run_time=min_run_time)
 def bench_int8(dtype: torch.dtype, m: int, k: int, n: int, label: str,
               sub_label: str) -> Iterable[TMeasurement]:
    assert dtype == torch.int8
    a, b = make_rand_tensors(torch.int8, m, n, k)
    scale_a = torch.tensor(1.0, device="cuda", dtype=torch.float32)
    scale_b = torch.tensor(1.0, device="cuda", dtype=torch.float32)
    timers = []
    # pytorch impl
    timers.append(
        bench_fn(a.to(dtype=torch.bfloat16, device="cuda"),
                 b.to(dtype=torch.bfloat16, device="cuda"), scale_a, scale_b,
                 torch.bfloat16, label, sub_label, pytorch_i8_impl,
                 "pytorch_bf16_bf16_bf16_matmul-no-scales"))
    # cutlass impl
    timers.append(
        bench_fn(a, b, scale_a.to(device="cpu"), scale_b.to(device="cpu"),
                 torch.bfloat16, label, sub_label, cutlass_impl,
                 "cutlass_i8_i8_bf16_scaled_mm"))
    return timers
 def bench_fp8(dtype: torch.dtype, m: int, k: int, n: int, label: str,
              sub_label: str) -> Iterable[TMeasurement]:
    assert dtype == torch.float8_e4m3fn
    a, b = make_rand_tensors(torch.float8_e4m3fn, m, n, k)
    scale_a = torch.tensor(1.0, device="cuda", dtype=torch.float32)
    scale_b = torch.tensor(1.0, device="cuda", dtype=torch.float32)
    timers = []
    # pytorch impl: bf16 output, without fp8 fast accum
    timers.append(
        bench_fn(a, b, scale_a, scale_b, torch.bfloat16, label, sub_label,
                 pytorch_fp8_impl, "pytorch_fp8_fp8_bf16_scaled_mm"))
    # pytorch impl: bf16 output, with fp8 fast accum
    timers.append(
        bench_fn(a, b, scale_a, scale_b, torch.bfloat16, label, sub_label,
                 pytorch_fp8_impl_fast_accum,
                 "pytorch_fp8_fp8_bf16_scaled_mm_fast_accum"))
    # pytorch impl: fp16 output, without fp8 fast accum
    timers.append(
        bench_fn(a, b, scale_a, scale_b, torch.float16, label, sub_label,
                 pytorch_fp8_impl, "pytorch_fp8_fp8_fp16_scaled_mm"))
    # pytorch impl: fp16 output, with fp8 fast accum
    timers.append(
        bench_fn(a, b, scale_a, scale_b, torch.float16, label, sub_label,
                 pytorch_fp8_impl_fast_accum,
                 "pytorch_fp8_fp8_fp16_scaled_mm_fast_accum"))
    # cutlass impl: bf16 output
    timers.append(
        bench_fn(a, b, scale_a.to(device="cpu"), scale_b.to(device="cpu"),
                 torch.bfloat16, label, sub_label, cutlass_impl,
                 "cutlass_fp8_fp8_bf16_scaled_mm"))
    # cutlass impl: fp16 output
    timers.append(
        bench_fn(a, b, scale_a.to(device="cpu"), scale_b.to(device="cpu"),
                 torch.float16, label, sub_label, cutlass_impl,
                 "cutlass_fp8_fp8_fp16_scaled_mm"))
    return timers
 def bench(dtype: torch.dtype, m: int, k: int, n: int, label: str,
          sub_label: str) -> Iterable[TMeasurement]:
    if dtype == torch.int8:
        return bench_int8(dtype, m, k, n, label, sub_label)
    if dtype == torch.float8_e4m3fn:
        return bench_fp8(dtype, m, k, n, label, sub_label)
    raise ValueError("unsupported type")
 # runner
 def print_timers(timers: Iterable[TMeasurement]):
    compare = TBenchmark.Compare(timers)
    compare.print()
 def run(dtype: torch.dtype,
        MKNs: Iterable[Tuple[int, int, int]]) -> Iterable[TMeasurement]:
    results = []
    for m, k, n in MKNs:
        timers = bench(dtype, m, k, n, f"scaled-{dtype}-gemm",
                       f"MKN=({m}x{k}x{n})")
        print_timers(timers)
        results.extend(timers)
    return results
 # output makers
 def make_output(data: Iterable[TMeasurement],
                MKNs: Iterable[Tuple[int, int, int]],
                base_description: str,
                timestamp=None):
    print(f"== All Results {base_description} ====")
    print_timers(data)
    # pickle all the results
    timestamp = int(time.time()) if timestamp is None else timestamp
    with open(f"{base_description}-{timestamp}.pkl", "wb") as f:
        pkl.dump(data, f)
 # argparse runners
 def run_square_bench(args):
    dim_sizes = list(
        range(args.dim_start, args.dim_end + 1, args.dim_increment))
    MKNs = list(zip(dim_sizes, dim_sizes, dim_sizes))
    data = run(args.dtype, MKNs)
    make_output(data, MKNs, f"square_bench-{args.dtype}")
 def run_range_bench(args):
    dim_sizes = list(range(args.dim_start, args.dim_end, args.dim_increment))
    n = len(dim_sizes)
    Ms = [args.m_constant] * n if args.m_constant is not None else dim_sizes
    Ks = [args.k_constant] * n if args.k_constant is not None else dim_sizes
    Ns = [args.n_constant] * n if args.n_constant is not None else dim_sizes
    MKNs = list(zip(Ms, Ks, Ns))
    data = run(args.dtype, MKNs)
    make_output(data, MKNs, f"range_bench-{args.dtype}")
 def run_model_bench(args):
    print("Benchmarking models:")
    for i, model in enumerate(args.models):
        print(f"[{i}]  {model}")
    def model_shapes(model_name: str, tp_size: int) -> List[Tuple[int, int]]:
        KNs = []
        for KN, tp_split_dim in copy.deepcopy(WEIGHT_SHAPES[model_name]):
            KN[tp_split_dim] = KN[tp_split_dim] // tp_size
            KNs.append(KN)
        return KNs
    model_bench_data = []
    models_tps = list(itertools.product(args.models, args.tp_sizes))
    for model, tp_size in models_tps:
        Ms = args.batch_sizes
        KNs = model_shapes(model, tp_size)
        MKNs = []
        for m in Ms:
            for k, n in KNs:
                MKNs.append((m, k, n))
        data = run(args.dtype, MKNs)
        model_bench_data.append(data)
    # Print all results
    for data, model_tp in zip(model_bench_data, models_tps):
        model, tp_size = model_tp
        print(f"== Results {args.dtype} {model}-TP{tp_size} ====")
        print_timers(data)
    timestamp = int(time.time())
    all_data = []
    for d in model_bench_data:
        all_data.extend(d)
    # pickle all data
    with open(f"model_bench-{args.dtype}-{timestamp}.pkl", "wb") as f:
        pkl.dump(all_data, f)
 if __name__ == '__main__':
    def to_torch_dtype(dt):
        if dt == "int8":
            return torch.int8
        if dt == "fp8":
            return torch.float8_e4m3fn
        raise ValueError("unsupported dtype")
    parser = argparse.ArgumentParser(
        description="""
 Benchmark Cutlass GEMM.
    To run square GEMMs:
        python3 ./benchmarks/cutlass_benchmarks/w8a8_benchmarks.py --dtype fp8 square_bench --dim-start 128 --dim-end 512 --dim-increment 64
    To run constant N and K and sweep M:
        python3 ./benchmarks/cutlass_benchmarks/w8a8_benchmarks.py --dtype fp8 range_bench --dim-start 128 --dim-end 512 --dim-increment 64 --n-constant 16384 --k-constant 16384
    To run dimensions from a model:
        python3 ./benchmarks/cutlass_benchmarks/w8a8_benchmarks.py --dtype fp8 model_bench --models meta-llama/Llama-2-7b-hf --batch-sizes 16 --tp-sizes 1
    Output:
        - a .pkl file, that is a list of raw torch.benchmark.utils.Measurements for the pytorch and cutlass implementations for the various GEMMs.
            """,  # noqa: E501
        formatter_class=argparse.RawTextHelpFormatter)
    parser.add_argument("--dtype",
                        type=to_torch_dtype,
                        required=True,
                        help="Available options are ['int8', 'fp8']")
    subparsers = parser.add_subparsers(dest="cmd")
    square_parser = subparsers.add_parser("square_bench")
    square_parser.add_argument("--dim-start", type=int, required=True)
    square_parser.add_argument("--dim-end", type=int, required=True)
    square_parser.add_argument("--dim-increment", type=int, required=True)
    square_parser.set_defaults(func=run_square_bench)
    range_parser = subparsers.add_parser("range_bench")
    range_parser.add_argument("--dim-start", type=int, required=True)
    range_parser.add_argument("--dim-end", type=int, required=True)
    range_parser.add_argument("--dim-increment", type=int, required=True)
    range_parser.add_argument("--m-constant", type=int, default=None)
    range_parser.add_argument("--n-constant", type=int, default=None)
    range_parser.add_argument("--k-constant", type=int, default=None)
    range_parser.set_defaults(func=run_range_bench)
    model_parser = subparsers.add_parser("model_bench")
    model_parser.add_argument("--models",
                              nargs="+",
                              type=str,
                              default=DEFAULT_MODELS,
                              choices=WEIGHT_SHAPES.keys())
    model_parser.add_argument("--tp-sizes",
                              nargs="+",
                              type=int,
                              default=DEFAULT_TP_SIZES)
    model_parser.add_argument("--batch-sizes",
                              nargs="+",
                              type=int,
                              default=DEFAULT_BATCH_SIZES)
    model_parser.set_defaults(func=run_model_bench)
    args = parser.parse_args()
    args.func(args)
--- a/benchmarks/cutlass_benchmarks/weight_shapes.py
+++ b/benchmarks/cutlass_benchmarks/weight_shapes.py
@@ -0,0 +1,37 @@
 # Weight Shapes are in the format
 # ([K, N], TP_SPLIT_DIM)
 # Example:
 #  A shape of ([14336, 4096], 0) indicates the following GEMM shape,
 #   - TP1 : K = 14336, N = 4096
 #   - TP2 : K = 7168, N = 4096
 #  A shape of ([4096, 6144], 1) indicates the following GEMM shape,
 #   - TP1 : K = 4096, N = 6144
 #   - TP4 : K = 4096, N = 1536
 # TP1 shapes
 WEIGHT_SHAPES = {
    "mistralai/Mistral-7B-v0.1": [
        ([4096, 6144], 1),
        ([4096, 4096], 0),
        ([4096, 28672], 1),
        ([14336, 4096], 0),
    ],
    "meta-llama/Llama-2-7b-hf": [
        ([4096, 12288], 1),
        ([4096, 4096], 0),
        ([4096, 22016], 1),
        ([11008, 4096], 0),
    ],
    "meta-llama/Llama-2-13b-hf": [
        ([5120, 15360], 1),
        ([5120, 5120], 0),
        ([5120, 27648], 1),
        ([13824, 5120], 0),
    ],
    "meta-llama/Llama-2-70b-hf": [
        ([8192, 10240], 1),
        ([8192, 8192], 0),
        ([8192, 57344], 1),
        ([28672, 8192], 0),
    ],
 }
--- a/benchmarks/kernels/benchmark_aqlm.py
+++ b/benchmarks/kernels/benchmark_aqlm.py
@@ -0,0 +1,302 @@
 import argparse
 import os
 import sys
 from typing import Optional
 import torch
 import torch.nn.functional as F
 from vllm import _custom_ops as ops
 from vllm.model_executor.layers.quantization.aqlm import (
    dequantize_weight, generic_dequantize_gemm, get_int_dtype,
    optimized_dequantize_gemm)
 os.environ['CUDA_VISIBLE_DEVICES'] = '0'
 def torch_mult(
        input: torch.Tensor,  #  [..., in_features]
        weights: torch.Tensor,
        scales: torch.Tensor,  #  [num_out_groups, 1, 1, 1]
 ) -> torch.Tensor:
    output = F.linear(input, weights)
    return output
 def dequant_out_scale(
    input: torch.Tensor,  #  [..., in_features]
    codes: torch.IntTensor,  #  [num_out_groups, num_in_groups, num_codebooks]
    codebooks: torch.
    Tensor,  #  [num_codebooks, codebook_size, out_group_size, in_group_size]
    scales: torch.Tensor,  #  [num_out_groups, 1, 1, 1]
    output_partition_sizes: torch.IntTensor,
    bias: Optional[torch.Tensor],
 ) -> torch.Tensor:
    weights = ops.aqlm_dequant(codes, codebooks, output_partition_sizes)
    if bias is None:
        output = F.linear(input, weights, bias)
        orig_shape = output.shape
        flattened_output = output.view(-1, output.size(-1))
        f_scales = scales.view(-1, scales.shape[0])
        b_scales = f_scales.expand(flattened_output.shape[0], -1)
        flattened_output *= b_scales
        return flattened_output.view(orig_shape)
    else:
        b_scales = scales.view(scales.shape[:-3] + (-1, )).expand(
            -1, weights.shape[1])
        weights *= b_scales
        return F.linear(input, weights, bias)
 def dequant_weight_scale(
    input: torch.Tensor,  #  [..., in_features]
    codes: torch.IntTensor,  #  [num_out_groups, num_in_groups, num_codebooks]
    codebooks: torch.
    Tensor,  #  [num_codebooks, codebook_size, out_group_size, in_group_size]
    scales: torch.Tensor,  #  [num_out_groups, 1, 1, 1]
    output_partition_sizes: torch.IntTensor,
    bias: Optional[torch.Tensor],
 ) -> torch.Tensor:
    weights = ops.aqlm_dequant(codes, codebooks, output_partition_sizes)
    b_scales = scales.view(scales.shape[:-3] + (-1, )).expand(
        -1, weights.shape[1])
    weights *= b_scales
    return F.linear(input, weights, bias)
 def dequant_no_scale(
    input: torch.Tensor,  #  [..., in_features]
    codes: torch.IntTensor,  #  [num_out_groups, num_in_groups, num_codebooks]
    codebooks: torch.
    Tensor,  #  [num_codebooks, codebook_size, out_group_size, in_group_size]
    scales: torch.Tensor,  #  [num_out_groups, 1, 1, 1]
    output_partition_sizes: torch.IntTensor,
    bias: Optional[torch.Tensor],
 ) -> torch.Tensor:
    weights = ops.aqlm_dequant(codes, codebooks, output_partition_sizes)
    return F.linear(input, weights, bias)
 # Compare the optimized 1x16 and 2x8 cuda decompression/dequant kernels against
 # the generic pytorch version.
 # Just visual comparison.
 def dequant_test(k: int, parts: torch.tensor, nbooks: int, bits: int) -> None:
    n = parts.sum().item()
    device = torch.device('cuda:0')
    code_range = (1 << bits) // 2
    ingroups = 8
    codes = torch.randint(-code_range,
                          code_range,
                          size=(n, k // ingroups, nbooks),
                          dtype=get_int_dtype(bits),
                          device=device)
    codebooks = torch.randn(size=(parts.shape[0] * nbooks, 1 << bits, 1, 8),
                            dtype=torch.float16,
                            device=device)
    count = 0
    for index in range(16):
        for i in range(8):
            for book in range(nbooks):
                codebooks[book, index, 0, i] = count * (10**book)
            count += 1
    print("codes shape", codes.shape)
    for i in range(16):
        for book in range(nbooks):
            codes[0, i, book] = i
            codes[0, -i, book] = i
    weights = dequantize_weight(codes, codebooks, None)
    weights2 = ops.aqlm_dequant(codes, codebooks, parts)
    print("weights shape:", weights.shape)
    print("weights2 shape:", weights2.shape)
    print("weights are:", weights)
    print("weights2 are:", weights2)
    print("first 128 weights are", weights[0, 0:128].to(torch.int32))
    print("first 128 weights2 are:", weights2[0, 0:128].to(torch.int32))
    print("last 128 weights are", weights[0, -128:])
    print("last 128 weights2 are:", weights2[0, -128:])
 def main():
    parser = argparse.ArgumentParser(description="Benchmark aqlm performance.")
    # Add arguments
    parser.add_argument("--nbooks",
                        type=int,
                        default=1,
                        help="Number of codebooks (default: 1)")
    parser.add_argument("--bits",
                        type=int,
                        default=16,
                        help="Number of bits per code element (default: 16)")
    parser.add_argument(
        "--test",
        type=bool,
        default=False,
        help="Run the decompression/dequant tester rather than benchmarking "
        "(default: False)")
    # Parse the arguments
    args = parser.parse_args()
    # Extract values
    nbooks = args.nbooks
    bits = args.bits
    if args.test:
        dequant_test(4096, torch.tensor((4096, )), nbooks, bits)
        return
    # Otherwise, benchmark.
    methods = [
        ops.aqlm_gemm,
        dequant_out_scale,
        generic_dequantize_gemm,
        optimized_dequantize_gemm,
        dequant_weight_scale,
        torch_mult,
        dequant_no_scale,
    ]
    filename = f"./aqlm_benchmark_{nbooks}x{bits}.csv"
    print(f"writing benchmarks to file {filename}")
    with open(filename, "w") as f:
        sys.stdout = f
        print('m | k | n | n parts', end='')
        for method in methods:
            print(f" | {method.__name__.replace('_', ' ')} (µs)", end='')
        print('')
        # These are reasonable prefill sizes.
        ksandpartions = ((4096, (4096, 4096, 4096)), (4096, (4096, )),
                         (4096, (11008, 11008)), (11008, (4096, )))
        # reasonable ranges for m.
        for m in [
                1, 2, 4, 8, 10, 12, 14, 16, 24, 32, 48, 52, 56, 64, 96, 112,
                128, 256, 512, 1024, 1536, 2048, 3072, 4096
        ]:
            print(f'{m}', file=sys.__stdout__)
            for ksp in ksandpartions:
                run_grid(m, ksp[0], torch.tensor(ksp[1]), nbooks, bits,
                         methods)
        sys.stdout = sys.__stdout__
 def run_grid(m: int, k: int, parts: torch.tensor, nbooks: int, bits: int,
             methods):
    # I didn't see visible improvements from increasing these, but feel free :)
    num_warmup_trials = 1
    num_trials = 1
    num_calls = 100
    # warmup.
    for method in methods:
        for _ in range(num_warmup_trials):
            run_timing(
                num_calls=num_calls,
                m=m,
                k=k,
                parts=parts,
                nbooks=nbooks,
                bits=bits,
                method=method,
            )
    n = parts.sum().item()
    print(f'{m} | {k} | {n} | {parts.tolist()}', end='')
    for method in methods:
        best_time_us = 1e20
        for _ in range(num_trials):
            kernel_dur_ms = run_timing(
                num_calls=num_calls,
                m=m,
                k=k,
                parts=parts,
                nbooks=nbooks,
                bits=bits,
                method=method,
            )
            kernel_dur_us = 1000 * kernel_dur_ms
            if kernel_dur_us < best_time_us:
                best_time_us = kernel_dur_us
        print(f' | {kernel_dur_us:.0f}', end='')
    print('')
 def run_timing(num_calls: int, m: int, k: int, parts: torch.tensor,
               nbooks: int, bits: int, method) -> float:
    n = parts.sum().item()
    device = torch.device('cuda:0')
    input = torch.randn((1, m, k), dtype=torch.float16, device=device)
    code_range = (1 << bits) // 2
    ingroups = 8
    codes = torch.randint(-code_range,
                          code_range,
                          size=(n, k // ingroups, nbooks),
                          dtype=get_int_dtype(bits),
                          device=device)
    codebooks = torch.randn(size=(parts.shape[0] * nbooks, 1 << bits, 1, 8),
                            dtype=torch.float16,
                            device=device)
    scales = torch.randn(size=(n, 1, 1, 1), dtype=torch.float16, device=device)
    # for comparison to just a pytorch mult.
    weights = torch.randn((n, k), dtype=torch.float16, device=device)
    start_event = torch.cuda.Event(enable_timing=True)
    end_event = torch.cuda.Event(enable_timing=True)
    start_event.record()
    if method is torch_mult:
        for i in range(num_calls):
            torch_mult(input, weights, scales)
    else:
        for i in range(num_calls):
            method(input, codes, codebooks, scales, parts, None)
    end_event.record()
    end_event.synchronize()
    dur_ms = start_event.elapsed_time(end_event) / num_calls
    return dur_ms
 if __name__ == "__main__":
    sys.exit(main())
--- a/benchmarks/kernels/benchmark_marlin.py
+++ b/benchmarks/kernels/benchmark_marlin.py
@@ -0,0 +1,233 @@
 import argparse
 import torch
 import torch.utils.benchmark as benchmark
 from benchmark_shapes import WEIGHT_SHAPES
 from vllm import _custom_ops as ops
 from vllm.model_executor.layers.quantization.gptq_marlin import (
    GPTQ_MARLIN_MAX_PARALLEL, GPTQ_MARLIN_MIN_THREAD_N,
    GPTQ_MARLIN_SUPPORTED_GROUP_SIZES, GPTQ_MARLIN_SUPPORTED_NUM_BITS)
 from vllm.model_executor.layers.quantization.gptq_marlin_24 import (
    GPTQ_MARLIN_24_MAX_PARALLEL, GPTQ_MARLIN_24_MIN_THREAD_N,
    GPTQ_MARLIN_24_SUPPORTED_GROUP_SIZES, GPTQ_MARLIN_24_SUPPORTED_NUM_BITS)
 from vllm.model_executor.layers.quantization.utils.marlin_utils import (
    MarlinWorkspace, marlin_24_quantize, marlin_quantize)
 from vllm.model_executor.layers.quantization.utils.quant_utils import (
    gptq_pack, quantize_weights, sort_weights)
 DEFAULT_MODELS = ["meta-llama/Llama-2-7b-hf/TP1"]
 DEFAULT_BATCH_SIZES = [1, 16, 32, 64, 128, 256, 512]
 ACT_ORDER_OPTS = [False, True]
 K_FULL_OPTS = [False, True]
 def bench_run(results, model, act_order, is_k_full, num_bits, group_size,
              size_m, size_k, size_n):
    label = "Quant Matmul"
    sub_label = ("{}, act={} k_full={}, b={}, g={}, "
                 "MKN=({}x{}x{})".format(model, act_order, is_k_full, num_bits,
                                         group_size, size_m, size_k, size_n))
    print(f"Testing: {sub_label}")
    a = torch.randn(size_m, size_k).to(torch.half).cuda()
    b = torch.rand(size_k, size_n).to(torch.half).cuda()
    a_tmp = (torch.zeros(size_m, size_k).to(torch.half).cuda())
    # Marlin quant
    (
        marlin_w_ref,
        marlin_q_w,
        marlin_s,
        marlin_g_idx,
        marlin_sort_indices,
        marlin_rand_perm,
    ) = marlin_quantize(b, num_bits, group_size, act_order)
    # Marlin_24 quant
    (marlin_24_w_ref, marlin_24_q_w_comp, marlin_24_meta,
     marlin_24_s) = marlin_24_quantize(b, num_bits, group_size)
    # GPTQ quant
    (w_ref, q_w, s, g_idx,
     rand_perm) = quantize_weights(b, num_bits, group_size, act_order)
    q_w_gptq = gptq_pack(q_w, num_bits, size_k, size_n)
    # For act_order, sort the "weights" and "g_idx"
    # so that group ids are increasing
    repack_sort_indices = torch.empty(0, dtype=torch.int, device=b.device)
    if act_order:
        (q_w, g_idx, repack_sort_indices) = sort_weights(q_w, g_idx)
    # Prepare
    marlin_workspace = MarlinWorkspace(size_n, GPTQ_MARLIN_MIN_THREAD_N,
                                       GPTQ_MARLIN_MAX_PARALLEL)
    marlin_24_workspace = MarlinWorkspace(size_n, GPTQ_MARLIN_24_MIN_THREAD_N,
                                          GPTQ_MARLIN_24_MAX_PARALLEL)
    globals = {
        # Gen params
        "num_bits": num_bits,
        "group_size": group_size,
        "size_m": size_m,
        "size_n": size_n,
        "size_k": size_k,
        "a": a,
        "a_tmp": a_tmp,
        # Marlin params
        "marlin_w_ref": marlin_w_ref,
        "marlin_q_w": marlin_q_w,
        "marlin_s": marlin_s,
        "marlin_g_idx": marlin_g_idx,
        "marlin_sort_indices": marlin_sort_indices,
        "marlin_rand_perm": marlin_rand_perm,
        "marlin_workspace": marlin_workspace,
        "is_k_full": is_k_full,
        # Marlin_24 params
        "marlin_24_w_ref": marlin_24_w_ref,
        "marlin_24_q_w_comp": marlin_24_q_w_comp,
        "marlin_24_meta": marlin_24_meta,
        "marlin_24_s": marlin_24_s,
        "marlin_24_workspace": marlin_24_workspace,
        # GPTQ params
        "q_w_gptq": q_w_gptq,
        "repack_sort_indices": repack_sort_indices,
        # Kernels
        "gptq_marlin_gemm": ops.gptq_marlin_gemm,
        "gptq_marlin_24_gemm": ops.gptq_marlin_24_gemm,
        "gptq_marlin_repack": ops.gptq_marlin_repack,
    }
    min_run_time = 1
    # Warmup pytorch
    for i in range(5):
        torch.matmul(a, marlin_w_ref)
    results.append(
        benchmark.Timer(
            stmt="torch.matmul(a, marlin_w_ref)",
            globals=globals,
            label=label,
            sub_label=sub_label,
            description="pytorch_gemm",
        ).blocked_autorange(min_run_time=min_run_time))
    results.append(
        benchmark.Timer(
            stmt=
            "output = gptq_marlin_gemm(a, marlin_q_w, marlin_s, marlin_g_idx, marlin_sort_indices, marlin_workspace.scratch, num_bits, size_m, size_n, size_k, is_k_full)",  # noqa: E501
            globals=globals,
            label=label,
            sub_label=sub_label,
            description="gptq_marlin_gemm",
        ).blocked_autorange(min_run_time=min_run_time))
    if (num_bits in GPTQ_MARLIN_24_SUPPORTED_NUM_BITS
            and group_size in GPTQ_MARLIN_24_SUPPORTED_GROUP_SIZES):
        results.append(
            benchmark.Timer(
                stmt=
                "output = gptq_marlin_24_gemm(a, marlin_24_q_w_comp, marlin_24_meta, marlin_24_s, marlin_24_workspace.scratch, num_bits, size_m, size_n, size_k)",  # noqa: E501
                globals=globals,
                label=label,
                sub_label=sub_label,
                description="gptq_marlin_24_gemm",
            ).blocked_autorange(min_run_time=min_run_time))
    results.append(
        benchmark.Timer(
            stmt=
            "q_res = gptq_marlin_repack(q_w_gptq, repack_sort_indices, size_k, size_n, num_bits)",  # noqa: E501
            globals=globals,
            label=label,
            sub_label=sub_label,
            description="gptq_marlin_repack",
        ).blocked_autorange(min_run_time=min_run_time))
 def main(args):
    print("Benchmarking models:")
    for i, model in enumerate(args.models):
        print(f"[{i}]  {model}")
    results = []
    for model in args.models:
        for layer in WEIGHT_SHAPES[model]:
            size_k = layer[0]
            size_n = layer[1]
            if len(args.limit_k) > 0 and size_k not in args.limit_k:
                continue
            if len(args.limit_n) > 0 and size_n not in args.limit_n:
                continue
            for act_order in ACT_ORDER_OPTS:
                if len(args.limit_act_order
                       ) > 0 and act_order not in args.limit_act_order:
                    continue
                for is_k_full in K_FULL_OPTS:
                    if len(args.limit_k_full
                           ) > 0 and is_k_full not in args.limit_k_full:
                        continue
                    for num_bits in GPTQ_MARLIN_SUPPORTED_NUM_BITS:
                        if len(args.limit_num_bits
                               ) > 0 and num_bits not in args.limit_num_bits:
                            continue
                        for group_size in GPTQ_MARLIN_SUPPORTED_GROUP_SIZES:
                            if len(
                                    args.limit_group_size
                            ) > 0 and group_size not in args.limit_group_size:
                                continue
                            # For act_order, the group_size must be less than
                            # size_k
                            if act_order and (group_size == size_k
                                              or group_size == -1):
                                continue
                            for size_m in args.batch_sizes:
                                bench_run(results, model, act_order, is_k_full,
                                          num_bits, group_size, size_m, size_k,
                                          size_n)
    compare = benchmark.Compare(results)
    compare.print()
 # For quick benchmarking use:
 #   python benchmark_marlin.py --batch-sizes 1 16 32 --limit-k 4096 --limit-n 4096 --limit-group-size 128 --limit-num-bits 4 --limit-act-order 0 --limit-k-full 1 # noqa E501
 #
 if __name__ == "__main__":
    parser = argparse.ArgumentParser(
        description="Benchmark Marlin across specified models/shapes/batches")
    parser.add_argument(
        "--models",
        nargs="+",
        type=str,
        default=DEFAULT_MODELS,
        choices=WEIGHT_SHAPES.keys(),
    )
    parser.add_argument("--batch-sizes",
                        nargs="+",
                        type=int,
                        default=DEFAULT_BATCH_SIZES)
    parser.add_argument("--limit-k", nargs="+", type=int, default=[])
    parser.add_argument("--limit-n", nargs="+", type=int, default=[])
    parser.add_argument("--limit-group-size", nargs="+", type=int, default=[])
    parser.add_argument("--limit-num-bits", nargs="+", type=int, default=[])
    parser.add_argument("--limit-act-order", nargs="+", type=int, default=[])
    parser.add_argument("--limit-k-full", nargs="+", type=int, default=[])
    args = parser.parse_args()
    main(args)
--- a/benchmarks/kernels/benchmark_mixtral_moe.py
+++ b/benchmarks/kernels/benchmark_mixtral_moe.py
@@ -1,182 +0,0 @@
 import json
 import os
 import sys
 import torch
 import torch.nn.functional as F
 import triton
 from vllm.model_executor.layers.fused_moe import (fused_moe,
                                                  get_config_file_name)
 os.environ['CUDA_VISIBLE_DEVICES'] = '0'
 def main():
    method = fused_moe
    for bs in [
            1, 2, 4, 8, 16, 24, 32, 48, 64, 96, 128, 256, 512, 1024, 1536,
            2048, 3072, 4096
    ]:
        run_grid(bs, method=method)
 def run_grid(bs, method):
    d_model = 4096
    num_total_experts = 8
    top_k = 2
    tp_size = 2
    model_intermediate_size = 14336
    num_layers = 32
    num_calls = 100
    num_warmup_trials = 1
    num_trials = 1
    configs = []
    if bs <= 16:
        BLOCK_SIZES_M = [16]
    elif bs <= 32:
        BLOCK_SIZES_M = [16, 32]
    elif bs <= 64:
        BLOCK_SIZES_M = [16, 32, 64]
    elif bs <= 128:
        BLOCK_SIZES_M = [16, 32, 64, 128]
    else:
        BLOCK_SIZES_M = [16, 32, 64, 128, 256]
    for block_size_n in [32, 64, 128, 256]:
        for block_size_m in BLOCK_SIZES_M:
            for block_size_k in [64, 128, 256]:
                for group_size_m in [1, 16, 32, 64]:
                    for num_warps in [4, 8]:
                        configs.append({
                            "BLOCK_SIZE_M": block_size_m,
                            "BLOCK_SIZE_N": block_size_n,
                            "BLOCK_SIZE_K": block_size_k,
                            "GROUP_SIZE_M": group_size_m,
                            "num_warps": num_warps,
                            "num_stages": 4,
                        })
    best_config = None
    best_time_us = 1e20
    for config in configs:
        print(f'{tp_size=} {bs=}')
        print(f'{config}')
        # warmup
        print('warming up')
        try:
            for _ in range(num_warmup_trials):
                run_timing(
                    num_calls=num_calls,
                    bs=bs,
                    d_model=d_model,
                    num_total_experts=num_total_experts,
                    top_k=top_k,
                    tp_size=tp_size,
                    model_intermediate_size=model_intermediate_size,
                    method=method,
                    config=config,
                )
        except triton.runtime.autotuner.OutOfResources:
            continue
        # trial
        print('benchmarking')
        for _ in range(num_trials):
            kernel_dur_ms = run_timing(
                num_calls=num_calls,
                bs=bs,
                d_model=d_model,
                num_total_experts=num_total_experts,
                top_k=top_k,
                tp_size=tp_size,
                model_intermediate_size=model_intermediate_size,
                method=method,
                config=config,
            )
            kernel_dur_us = 1000 * kernel_dur_ms
            model_dur_ms = kernel_dur_ms * num_layers
            if kernel_dur_us < best_time_us:
                best_config = config
                best_time_us = kernel_dur_us
            print(f'{kernel_dur_us=:.1f} {model_dur_ms=:.1f}'
                  f' {bs=} {tp_size=} {top_k=} {num_total_experts=} '
                  f'{d_model=} {model_intermediate_size=} {num_layers=}')
    print("best_time_us", best_time_us)
    print("best_config", best_config)
    # holds Dict[str, Dict[str, int]]
    filename = get_config_file_name(num_total_experts,
                                    model_intermediate_size // tp_size)
    print(f"writing config to file {filename}")
    existing_content = {}
    if os.path.exists(filename):
        with open(filename, "r") as f:
            existing_content = json.load(f)
    existing_content[str(bs)] = best_config
    with open(filename, "w") as f:
        json.dump(existing_content, f, indent=4)
        f.write("\n")
 def run_timing(num_calls: int, bs: int, d_model: int, num_total_experts: int,
               top_k: int, tp_size: int, model_intermediate_size: int, method,
               config) -> float:
    shard_intermediate_size = model_intermediate_size // tp_size
    hidden_states = torch.rand(
        (bs, d_model),
        device="cuda:0",
        dtype=torch.bfloat16,
    )
    ws = torch.rand(
        (num_total_experts, 2 * shard_intermediate_size, d_model),
        device=hidden_states.device,
        dtype=hidden_states.dtype,
    )
    w2s = torch.rand(
        (num_total_experts, d_model, shard_intermediate_size),
        device=hidden_states.device,
        dtype=hidden_states.dtype,
    )
    gating_output = F.softmax(torch.rand(
        (num_calls, bs, num_total_experts),
        device=hidden_states.device,
        dtype=torch.float32,
    ),
                              dim=-1)
    start_event = torch.cuda.Event(enable_timing=True)
    end_event = torch.cuda.Event(enable_timing=True)
    start_event.record()
    for i in range(num_calls):
        hidden_states = method(
            hidden_states=hidden_states,
            w1=ws,
            w2=w2s,
            gating_output=gating_output[i],
            topk=2,
            renormalize=True,
            inplace=True,
            override_config=config,
        )
    end_event.record()
    end_event.synchronize()
    dur_ms = start_event.elapsed_time(end_event) / num_calls
    return dur_ms
 if __name__ == "__main__":
    sys.exit(main())
--- a/benchmarks/kernels/benchmark_moe.py
+++ b/benchmarks/kernels/benchmark_moe.py
@@ -0,0 +1,322 @@
 import argparse
 import time
 from datetime import datetime
 from typing import Any, Dict, List, Tuple
 import ray
 import torch
 import triton
 from ray.experimental.tqdm_ray import tqdm
 from transformers import AutoConfig
 from vllm.model_executor.layers.fused_moe.fused_moe import *
 def benchmark_config(
    config: Dict[str, int],
    num_tokens: int,
    num_experts: int,
    shard_intermediate_size: int,
    hidden_size: int,
    topk: int,
    dtype: torch.dtype,
    use_fp8: bool,
    num_iters: int = 100,
 ) -> float:
    init_dtype = torch.float16 if use_fp8 else dtype
    x = torch.randn(num_tokens, hidden_size, dtype=dtype)
    w1 = torch.randn(num_experts,
                     shard_intermediate_size,
                     hidden_size,
                     dtype=init_dtype)
    w2 = torch.randn(num_experts,
                     hidden_size,
                     shard_intermediate_size // 2,
                     dtype=init_dtype)
    gating_output = torch.randn(num_iters,
                                num_tokens,
                                num_experts,
                                dtype=torch.float32)
    w1_scale = None
    w2_scale = None
    a1_scale = None
    a2_scale = None
    if use_fp8:
        w1_scale = torch.randn(num_experts, dtype=torch.float32)
        w2_scale = torch.randn(num_experts, dtype=torch.float32)
        a1_scale = torch.randn(1, dtype=torch.float32)
        a2_scale = torch.randn(1, dtype=torch.float32)
        w1 = w1.to(torch.float8_e4m3fn)
        w2 = w2.to(torch.float8_e4m3fn)
    input_gating = torch.empty(num_tokens, num_experts, dtype=torch.float32)
    def prepare(i: int):
        input_gating.copy_(gating_output[i])
    def run():
        fused_moe(
            x,
            w1,
            w2,
            input_gating,
            topk,
            renormalize=True,
            inplace=True,
            override_config=config,
            use_fp8=use_fp8,
            w1_scale=w1_scale,
            w2_scale=w2_scale,
            a1_scale=a1_scale,
            a2_scale=a2_scale,
        )
    # JIT compilation & warmup
    run()
    torch.cuda.synchronize()
    # Capture 10 invocations with CUDA graph
    graph = torch.cuda.CUDAGraph()
    with torch.cuda.graph(graph):
        for _ in range(10):
            run()
    torch.cuda.synchronize()
    # Warmup
    for _ in range(5):
        graph.replay()
    torch.cuda.synchronize()
    start_event = torch.cuda.Event(enable_timing=True)
    end_event = torch.cuda.Event(enable_timing=True)
    latencies = []
    for i in range(num_iters):
        prepare(i)
        torch.cuda.synchronize()
        start_event.record()
        graph.replay()
        end_event.record()
        end_event.synchronize()
        latencies.append(start_event.elapsed_time(end_event))
    avg = sum(latencies) / (num_iters * 10) * 1000  # us
    graph.reset()
    return avg
 def get_configs_compute_bound() -> List[Dict[str, int]]:
    # Reduced search space for faster tuning.
    # TODO(woosuk): Increase the search space and use a performance model to
    # prune the search space.
    configs = []
    for num_stages in [2, 3, 4, 5]:
        for block_m in [16, 32, 64, 128, 256]:
            for block_k in [64, 128, 256]:
                for block_n in [32, 64, 128, 256]:
                    for num_warps in [4, 8]:
                        for group_size in [1, 16, 32, 64]:
                            configs.append({
                                "BLOCK_SIZE_M": block_m,
                                "BLOCK_SIZE_N": block_n,
                                "BLOCK_SIZE_K": block_k,
                                "GROUP_SIZE_M": group_size,
                                "num_warps": num_warps,
                                "num_stages": num_stages,
                            })
    return configs
@ray.remote(num_gpus=1)
 class BenchmarkWorker:
    def __init__(self, seed: int) -> None:
        torch.set_default_device("cuda")
        torch.cuda.manual_seed_all(seed)
        self.seed = seed
    def benchmark(
        self,
        num_tokens: int,
        num_experts: int,
        shard_intermediate_size: int,
        hidden_size: int,
        topk: int,
        dtype: torch.dtype,
        use_fp8: bool,
    ) -> Tuple[Dict[str, int], float]:
        torch.cuda.manual_seed_all(self.seed)
        dtype_str = "float8" if use_fp8 else None
        # NOTE(woosuk): The current naming convention uses w2.shape[2], which
        # is the intermediate size after silu_and_mul.
        op_config = get_moe_configs(num_experts, shard_intermediate_size // 2,
                                    dtype_str)
        if op_config is None:
            config = get_default_config(num_tokens, num_experts,
                                        shard_intermediate_size, hidden_size,
                                        topk, dtype_str)
        else:
            config = op_config[min(op_config.keys(),
                                   key=lambda x: abs(x - num_tokens))]
        kernel_time = benchmark_config(config, num_tokens, num_experts,
                                       shard_intermediate_size, hidden_size,
                                       topk, dtype, use_fp8)
        return config, kernel_time
    def tune(
        self,
        num_tokens: int,
        num_experts: int,
        shard_intermediate_size: int,
        hidden_size: int,
        topk: int,
        dtype: torch.dtype,
        use_fp8: bool,
        search_space: List[Dict[str, int]],
    ) -> Dict[str, int]:
        best_config = None
        best_time = float("inf")
        for config in tqdm(search_space):
            try:
                kernel_time = benchmark_config(config,
                                               num_tokens,
                                               num_experts,
                                               shard_intermediate_size,
                                               hidden_size,
                                               topk,
                                               dtype,
                                               use_fp8,
                                               num_iters=10)
            except triton.runtime.autotuner.OutOfResources:
                # Some configurations may be invalid and fail to compile.
                continue
            if kernel_time < best_time:
                best_time = kernel_time
                best_config = config
        now = datetime.now()
        print(f"{now.ctime()}] Completed tuning for batch_size={num_tokens}")
        return best_config
 def sort_config(config: Dict[str, int]) -> Dict[str, int]:
    return {
        "BLOCK_SIZE_M": config["BLOCK_SIZE_M"],
        "BLOCK_SIZE_N": config["BLOCK_SIZE_N"],
        "BLOCK_SIZE_K": config["BLOCK_SIZE_K"],
        "GROUP_SIZE_M": config["GROUP_SIZE_M"],
        "num_warps": config["num_warps"],
        "num_stages": config["num_stages"],
    }
 def save_configs(
    configs: Dict[int, Dict[str, int]],
    num_experts: int,
    shard_intermediate_size: int,
    hidden_size: int,
    topk: int,
    dtype: torch.dtype,
    use_fp8: bool,
 ) -> None:
    dtype_str = "float8" if use_fp8 else None
    # NOTE(woosuk): The current naming convention uses w2.shape[2], which
    # is the intermediate size after silu_and_mul.
    filename = get_config_file_name(num_experts, shard_intermediate_size // 2,
                                    dtype_str)
    print(f"Writing best config to {filename}...")
    with open(filename, "w") as f:
        json.dump(configs, f, indent=4)
        f.write("\n")
 def main(args: argparse.Namespace):
    print(args)
    config = AutoConfig.from_pretrained(args.model)
    if config.architectures[0] == "DbrxForCausalLM":
        E = config.ffn_config.moe_num_experts
        topk = config.ffn_config.moe_top_k
        intermediate_size = config.ffn_config.ffn_hidden_size
        shard_intermediate_size = 2 * intermediate_size // args.tp_size
    else:
        # Default: Mixtral.
        E = config.num_local_experts
        topk = config.num_experts_per_tok
        intermediate_size = config.intermediate_size
        shard_intermediate_size = 2 * intermediate_size // args.tp_size
    hidden_size = config.hidden_size
    dtype = config.torch_dtype
    use_fp8 = args.dtype == "fp8"
    if args.batch_size is None:
        batch_sizes = [
            1, 2, 4, 8, 16, 24, 32, 48, 64, 96, 128, 256, 512, 1024, 1536,
            2048, 3072, 4096
        ]
    else:
        batch_sizes = [args.batch_size]
    ray.init()
    num_gpus = int(ray.available_resources()["GPU"])
    workers = [BenchmarkWorker.remote(args.seed) for _ in range(num_gpus)]
    def _distribute(method: str, inputs: List[Any]) -> List[Any]:
        outputs = []
        worker_idx = 0
        for input_args in inputs:
            worker = workers[worker_idx]
            worker_method = getattr(worker, method)
            output = worker_method.remote(*input_args)
            outputs.append(output)
            worker_idx = (worker_idx + 1) % num_gpus
        return ray.get(outputs)
    if args.tune:
        search_space = get_configs_compute_bound()
        print(f"Start tuning over {len(search_space)} configurations...")
        start = time.time()
        configs = _distribute(
            "tune", [(batch_size, E, shard_intermediate_size, hidden_size,
                      topk, dtype, use_fp8, search_space)
                     for batch_size in batch_sizes])
        best_configs = {
            M: sort_config(config)
            for M, config in zip(batch_sizes, configs)
        }
        save_configs(best_configs, E, shard_intermediate_size, hidden_size,
                     topk, dtype, use_fp8)
        end = time.time()
        print(f"Tuning took {end - start:.2f} seconds")
    else:
        outputs = _distribute("benchmark",
                              [(batch_size, E, shard_intermediate_size,
                                hidden_size, topk, dtype, use_fp8)
                               for batch_size in batch_sizes])
        for batch_size, (config, kernel_time) in zip(batch_sizes, outputs):
            print(f"Batch size: {batch_size}, config: {config}")
            print(f"Kernel time: {kernel_time:.2f} us")
 if __name__ == "__main__":
    parser = argparse.ArgumentParser()
    parser.add_argument("--model",
                        type=str,
                        default="mistralai/Mixtral-8x7B-Instruct-v0.1")
    parser.add_argument("--tp-size", "-tp", type=int, default=2)
    parser.add_argument("--dtype",
                        type=str,
                        choices=["auto", "fp8"],
                        default="auto")
    parser.add_argument("--seed", type=int, default=0)
    parser.add_argument("--batch-size", type=int, required=False)
    parser.add_argument("--tune", action="store_true")
    args = parser.parse_args()
    main(args)
--- a/benchmarks/kernels/benchmark_paged_attention.py
+++ b/benchmarks/kernels/benchmark_paged_attention.py
@@ -5,7 +5,7 @@ from typing import Optional
 import torch
-from vllm._C import ops
+from vllm import _custom_ops as ops
 from vllm.utils import STR_DTYPE_TO_TORCH_DTYPE, create_kv_caches_with_random
 NUM_BLOCKS = 1024
@@ -16,7 +16,7 @@ PARTITION_SIZE = 512
 def main(
    version: str,
    num_seqs: int,
-    context_len: int,
+    seq_len: int,
    num_query_heads: int,
    num_kv_heads: int,
    head_size: int,
@@ -48,12 +48,12 @@ def main(
                                   dtype=torch.float,
                                   device=device)
-    context_lens = [context_len for _ in range(num_seqs)]
+    seq_lens = [seq_len for _ in range(num_seqs)]
-    max_context_len = max(context_lens)
+    max_seq_len = max(seq_lens)
-    context_lens = torch.tensor(context_lens, dtype=torch.int, device=device)
+    seq_lens = torch.tensor(seq_lens, dtype=torch.int, device=device)
    # Create the block tables.
-    max_num_blocks_per_seq = (max_context_len + block_size - 1) // block_size
+    max_num_blocks_per_seq = (max_seq_len + block_size - 1) // block_size
    block_tables = []
    for _ in range(num_seqs):
        block_table = [
@@ -77,8 +77,7 @@ def main(
    # Prepare for the paged attention kernel.
    output = torch.empty_like(query)
    if version == "v2":
-        num_partitions = ((max_context_len + PARTITION_SIZE - 1) //
+        num_partitions = ((max_seq_len + PARTITION_SIZE - 1) // PARTITION_SIZE)
                          PARTITION_SIZE)
        tmp_output = torch.empty(
            size=(num_seqs, num_query_heads, num_partitions, head_size),
            dtype=output.dtype,
@@ -97,6 +96,9 @@ def main(
            torch.cuda.cudart().cudaProfilerStart()
        start_time = time.perf_counter()
        # Using default kv_scale
        kv_scale = 1.0
        for _ in range(num_iters):
            if version == "v1":
                ops.paged_attention_v1(
@@ -107,11 +109,12 @@ def main(
                    num_kv_heads,
                    scale,
                    block_tables,
-                    context_lens,
+                    seq_lens,
                    block_size,
-                    max_context_len,
+                    max_seq_len,
                    alibi_slopes,
                    kv_cache_dtype,
                    kv_scale,
                )
            elif version == "v2":
                ops.paged_attention_v2(
@@ -125,11 +128,12 @@ def main(
                    num_kv_heads,
                    scale,
                    block_tables,
-                    context_lens,
+                    seq_lens,
                    block_size,
-                    max_context_len,
+                    max_seq_len,
                    alibi_slopes,
                    kv_cache_dtype,
                    kv_scale,
                )
            else:
                raise ValueError(f"Invalid version: {version}")
@@ -161,12 +165,12 @@ if __name__ == '__main__':
                        choices=["v1", "v2"],
                        default="v2")
    parser.add_argument("--batch-size", type=int, default=8)
-    parser.add_argument("--context-len", type=int, default=4096)
+    parser.add_argument("--seq_len", type=int, default=4096)
    parser.add_argument("--num-query-heads", type=int, default=64)
    parser.add_argument("--num-kv-heads", type=int, default=8)
    parser.add_argument("--head-size",
                        type=int,
-                        choices=[64, 80, 96, 112, 128, 256],
+                        choices=[64, 80, 96, 112, 128, 192, 256],
                        default=128)
    parser.add_argument("--block-size", type=int, choices=[16, 32], default=16)
    parser.add_argument("--use-alibi", action="store_true")
@@ -179,11 +183,11 @@ if __name__ == '__main__':
    parser.add_argument(
        "--kv-cache-dtype",
        type=str,
-        choices=["auto", "fp8_e5m2"],
+        choices=["auto", "fp8", "fp8_e5m2", "fp8_e4m3"],
        default="auto",
-        help=
+        help="Data type for kv cache storage. If 'auto', will use model "
-        'Data type for kv cache storage. If "auto", will use model data type.')
+        "data type. CUDA 11.8+ supports fp8 (=fp8_e4m3) and fp8_e5m2. "
-    parser.add_argument("--device", type=str, choices=["cuda"], default="cuda")
+        "ROCm (AMD GPU) supports fp8 (=fp8_e4m3)")
    args = parser.parse_args()
    print(args)
@@ -192,7 +196,7 @@ if __name__ == '__main__':
    main(
        version=args.version,
        num_seqs=args.batch_size,
-        context_len=args.context_len,
+        seq_len=args.seq_len,
        num_query_heads=args.num_query_heads,
        num_kv_heads=args.num_kv_heads,
        head_size=args.head_size,
--- a/benchmarks/kernels/benchmark_rope.py
+++ b/benchmarks/kernels/benchmark_rope.py
@@ -93,7 +93,7 @@ if __name__ == '__main__':
    parser.add_argument("--num-heads", type=int, default=8)
    parser.add_argument("--head-size",
                        type=int,
-                        choices=[64, 80, 96, 112, 128, 256],
+                        choices=[64, 80, 96, 112, 128, 192, 256],
                        default=128)
    parser.add_argument("--rotary-dim", type=int, choices=[16, 32], default=32)
    parser.add_argument("--dtype",
--- a/benchmarks/kernels/benchmark_shapes.py
+++ b/benchmarks/kernels/benchmark_shapes.py
@@ -0,0 +1,75 @@
 WEIGHT_SHAPES = {
    "ideal": [[4 * 256 * 32, 256 * 32]],
    "mistralai/Mistral-7B-v0.1/TP1": [
        [4096, 6144],
        [4096, 4096],
        [4096, 28672],
        [14336, 4096],
    ],
    "mistralai/Mistral-7B-v0.1/TP2": [
        [4096, 3072],
        [2048, 4096],
        [4096, 14336],
        [7168, 4096],
    ],
    "mistralai/Mistral-7B-v0.1/TP4": [
        [4096, 1536],
        [1024, 4096],
        [4096, 7168],
        [3584, 4096],
    ],
    "meta-llama/Llama-2-7b-hf/TP1": [
        [4096, 12288],
        [4096, 4096],
        [4096, 22016],
        [11008, 4096],
    ],
    "meta-llama/Llama-2-7b-hf/TP2": [
        [4096, 6144],
        [2048, 4096],
        [4096, 11008],
        [5504, 4096],
    ],
    "meta-llama/Llama-2-7b-hf/TP4": [
        [4096, 3072],
        [1024, 4096],
        [4096, 5504],
        [2752, 4096],
    ],
    "meta-llama/Llama-2-13b-hf/TP1": [
        [5120, 15360],
        [5120, 5120],
        [5120, 27648],
        [13824, 5120],
    ],
    "meta-llama/Llama-2-13b-hf/TP2": [
        [5120, 7680],
        [2560, 5120],
        [5120, 13824],
        [6912, 5120],
    ],
    "meta-llama/Llama-2-13b-hf/TP4": [
        [5120, 3840],
        [1280, 5120],
        [5120, 6912],
        [3456, 5120],
    ],
    "meta-llama/Llama-2-70b-hf/TP1": [
        [8192, 10240],
        [8192, 8192],
        [8192, 57344],
        [28672, 8192],
    ],
    "meta-llama/Llama-2-70b-hf/TP2": [
        [8192, 5120],
        [4096, 8192],
        [8192, 28672],
        [14336, 8192],
    ],
    "meta-llama/Llama-2-70b-hf/TP4": [
        [8192, 2560],
        [2048, 8192],
        [8192, 14336],
        [7168, 8192],
    ],
 }
--- a/benchmarks/launch_tgi_server.sh
+++ b/benchmarks/launch_tgi_server.sh
@@ -4,7 +4,7 @@ PORT=8000
 MODEL=$1
 TOKENS=$2
-docker run --gpus all --shm-size 1g -p $PORT:80 \
+docker run -e HF_TOKEN=$HF_TOKEN --gpus all --shm-size 1g -p $PORT:80 \
           -v $PWD/data:/data \
           ghcr.io/huggingface/text-generation-inference:1.4.0 \
           --model-id $MODEL \
--- a/benchmarks/overheads/benchmark_hashing.py
+++ b/benchmarks/overheads/benchmark_hashing.py
@@ -0,0 +1,63 @@
 import argparse
 import cProfile
 import pstats
 from vllm import LLM, SamplingParams
 # A very long prompt, total number of tokens is about 15k.
 LONG_PROMPT = ["You are an expert in large language models, aren't you?"
               ] * 1000
 LONG_PROMPT = ' '.join(LONG_PROMPT)
 def main(args):
    llm = LLM(
        model=args.model,
        enforce_eager=True,
        enable_prefix_caching=True,
        tensor_parallel_size=args.tensor_parallel_size,
        use_v2_block_manager=args.use_v2_block_manager,
    )
    sampling_params = SamplingParams(temperature=0, max_tokens=args.output_len)
    profiler = cProfile.Profile()
    print("------warm up------")
    for i in range(3):
        output = llm.generate(LONG_PROMPT, sampling_params)
        print(output[0].outputs[0].text)
    print("------start generating------")
    for i in range(3):
        profiler.runctx('llm.generate(LONG_PROMPT, sampling_params)',
                        globals(), locals())
    # analyze the runtime of hashing function
    stats = pstats.Stats(profiler)
    stats.sort_stats('cumulative')
    total_time = 0
    total_calls = 0
    for func in stats.stats:
        if 'hash_of_block' in func[2]:
            total_time = stats.stats[func][3]
            total_calls = stats.stats[func][0]
    percentage = (total_time / stats.total_tt) * 100
    print(f"Hashing took {total_time:.2f} seconds,"
          f"{percentage:.2f}% of the total runtime.")
 if __name__ == "__main__":
    parser = argparse.ArgumentParser(
        description='Benchmark the performance of hashing function in'
        'automatic prefix caching.')
    parser.add_argument('--model', type=str, default='lmsys/longchat-7b-16k')
    parser.add_argument('--tensor-parallel-size', '-tp', type=int, default=1)
    parser.add_argument('--output-len', type=int, default=10)
    parser.add_argument('--enable-prefix-caching',
                        action='store_true',
                        help='enable prefix caching')
    parser.add_argument('--use-v2-block-manager',
                        action='store_true',
                        help='Use BlockSpaceMangerV2')
    args = parser.parse_args()
    main(args)
--- a/cmake/cpu_extension.cmake
+++ b/cmake/cpu_extension.cmake
@@ -0,0 +1,90 @@
 set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
 #
 # Define environment variables for special configurations
 #
 if(DEFINED ENV{VLLM_CPU_AVX512BF16})
    set(ENABLE_AVX512BF16 ON)
 endif()
 include_directories("${CMAKE_SOURCE_DIR}/csrc")
 #
 # Check the compile flags
 #
 list(APPEND CXX_COMPILE_FLAGS
    "-fopenmp"
    "-DVLLM_CPU_EXTENSION")
 execute_process(COMMAND cat /proc/cpuinfo
                RESULT_VARIABLE CPUINFO_RET
                OUTPUT_VARIABLE CPUINFO)
 if (NOT CPUINFO_RET EQUAL 0)
    message(FATAL_ERROR "Failed to check CPU features via /proc/cpuinfo")
 endif()
 function (find_isa CPUINFO TARGET OUT)
    string(FIND ${CPUINFO} ${TARGET} ISA_FOUND)
    if(NOT ISA_FOUND EQUAL -1)
        set(${OUT} ON PARENT_SCOPE)
    else()
        set(${OUT} OFF PARENT_SCOPE)
    endif()
 endfunction()
 find_isa(${CPUINFO} "avx512f" AVX512_FOUND)
 if (AVX512_FOUND)
    list(APPEND CXX_COMPILE_FLAGS
        "-mavx512f"
        "-mavx512vl"
        "-mavx512bw"
        "-mavx512dq")
    find_isa(${CPUINFO} "avx512_bf16" AVX512BF16_FOUND)
    if (AVX512BF16_FOUND OR ENABLE_AVX512BF16)
        if (CMAKE_CXX_COMPILER_ID STREQUAL "GNU" AND
            CMAKE_CXX_COMPILER_VERSION VERSION_GREATER_EQUAL 12.3)
            list(APPEND CXX_COMPILE_FLAGS "-mavx512bf16")
        else()
            message(WARNING "Disable AVX512-BF16 ISA support, requires gcc/g++ >= 12.3")
        endif()
    else()
        message(WARNING "Disable AVX512-BF16 ISA support, no avx512_bf16 found in local CPU flags." " If cross-compilation is required, please set env VLLM_CPU_AVX512BF16=1.")
    endif()
 else()
    message(FATAL_ERROR "vLLM CPU backend requires AVX512 ISA support.")
 endif()
 message(STATUS "CPU extension compile flags: ${CXX_COMPILE_FLAGS}")
 #
 # Define extension targets
 #
 #
 # _C extension
 #
 set(VLLM_EXT_SRC
    "csrc/cpu/activation.cpp"
    "csrc/cpu/attention.cpp"
    "csrc/cpu/cache.cpp"
    "csrc/cpu/layernorm.cpp"
    "csrc/cpu/pos_encoding.cpp"
    "csrc/cpu/torch_bindings.cpp")
 define_gpu_extension_target(
    _C
    DESTINATION vllm
    LANGUAGE CXX
    SOURCES ${VLLM_EXT_SRC}
    COMPILE_FLAGS ${CXX_COMPILE_FLAGS}
    USE_SABI 3
    WITH_SOABI
 )
 add_custom_target(default)
 message(STATUS "Enabling C extension.")
 add_dependencies(default _C)
--- a/cmake/utils.cmake
+++ b/cmake/utils.cmake
@@ -5,7 +5,7 @@
 macro (find_python_from_executable EXECUTABLE SUPPORTED_VERSIONS)
  file(REAL_PATH ${EXECUTABLE} EXECUTABLE)
  set(Python_EXECUTABLE ${EXECUTABLE})
-  find_package(Python COMPONENTS Interpreter Development.Module)
+  find_package(Python COMPONENTS Interpreter Development.Module Development.SABIModule)
  if (NOT Python_FOUND)
    message(FATAL_ERROR "Unable to find python matching: ${EXECUTABLE}.")
  endif()
@@ -99,7 +99,14 @@ function (get_torch_gpu_compiler_flags OUT_GPU_FLAGS GPU_LANG)
      "Failed to determine torch nvcc compiler flags")
    if (CUDA_VERSION VERSION_GREATER_EQUAL 11.8)
-      list(APPEND GPU_FLAGS "-DENABLE_FP8_E5M2")
+      list(APPEND GPU_FLAGS "-DENABLE_FP8")
    endif()
    if (CUDA_VERSION VERSION_GREATER_EQUAL 12.0)
      list(REMOVE_ITEM GPU_FLAGS
        "-D__CUDA_NO_HALF_OPERATORS__"
        "-D__CUDA_NO_HALF_CONVERSIONS__"
        "-D__CUDA_NO_BFLOAT16_CONVERSIONS__"
        "-D__CUDA_NO_HALF2_OPERATORS__")
    endif()
  elseif(${GPU_LANG} STREQUAL "HIP")
@@ -112,6 +119,7 @@ function (get_torch_gpu_compiler_flags OUT_GPU_FLAGS GPU_LANG)
    list(APPEND GPU_FLAGS
      "-DUSE_ROCM"
      "-DENABLE_FP8"
      "-U__HIP_NO_HALF_CONVERSIONS__"
      "-U__HIP_NO_HALF_OPERATORS__"
      "-fno-gpu-rdc")
@@ -286,6 +294,7 @@ endmacro()
 # INCLUDE_DIRECTORIES <dirs> - Extra include directories.
 # LIBRARIES <libraries>      - Extra link libraries.
 # WITH_SOABI                 - Generate library with python SOABI suffix name.
 # USE_SABI <version>         - Use python stable api <version>
 #
 # Note: optimization level/debug info is set via cmake build type.
 #
@@ -293,7 +302,7 @@ function (define_gpu_extension_target GPU_MOD_NAME)
  cmake_parse_arguments(PARSE_ARGV 1
    GPU
    "WITH_SOABI"
-    "DESTINATION;LANGUAGE"
+    "DESTINATION;LANGUAGE;USE_SABI"
    "SOURCES;ARCHITECTURES;COMPILE_FLAGS;INCLUDE_DIRECTORIES;LIBRARIES")
  # Add hipify preprocessing step when building with HIP/ROCm.
@@ -307,7 +316,11 @@ function (define_gpu_extension_target GPU_MOD_NAME)
    set(GPU_WITH_SOABI)
  endif()
-  Python_add_library(${GPU_MOD_NAME} MODULE "${GPU_SOURCES}" ${GPU_WITH_SOABI})
+  if (GPU_USE_SABI)
    Python_add_library(${GPU_MOD_NAME} MODULE USE_SABI ${GPU_USE_SABI} ${GPU_WITH_SOABI} "${GPU_SOURCES}")
  else()
    Python_add_library(${GPU_MOD_NAME} MODULE ${GPU_WITH_SOABI} "${GPU_SOURCES}")
  endif()
  if (GPU_LANGUAGE STREQUAL "HIP")
    # Make this target dependent on the hipify preprocessor step.
--- a/collect_env.py
+++ b/collect_env.py
@@ -63,6 +63,8 @@ DEFAULT_CONDA_PATTERNS = {
    "magma",
    "triton",
    "optree",
    "nccl",
    "transformers",
 }
 DEFAULT_PIP_PATTERNS = {
@@ -73,6 +75,8 @@ DEFAULT_PIP_PATTERNS = {
    "triton",
    "optree",
    "onnx",
    "nccl",
    "transformers",
 }
@@ -599,6 +603,11 @@ Versions of relevant libraries:
 {conda_packages}
 """.strip()
 # both the above code and the following code use `strip()` to
 # remove leading/trailing whitespaces, so we need to add a newline
 # in between to separate the two sections
 env_info_fmt += "\n"
 env_info_fmt += """
 ROCM Version: {rocm_version}
 Neuron SDK Version: {neuron_sdk_version}
--- a/csrc/activation_kernels.cu
+++ b/csrc/activation_kernels.cu
@@ -1,5 +1,5 @@
 #include <ATen/cuda/CUDAContext.h>
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <c10/cuda/CUDAGuard.h>
 #include <cmath>
@@ -10,11 +10,11 @@
 namespace vllm {
 // Activation and gating kernel template.
-template<typename scalar_t, scalar_t (*ACT_FN)(const scalar_t&)>
+template <typename scalar_t, scalar_t (*ACT_FN)(const scalar_t&)>
 __global__ void act_and_mul_kernel(
-  scalar_t* __restrict__ out,               // [..., d]
+    scalar_t* __restrict__ out,          // [..., d]
-  const scalar_t* __restrict__ input,       // [..., 2, d]
+    const scalar_t* __restrict__ input,  // [..., 2, d]
-  const int d) {
+    const int d) {
  const int64_t token_idx = blockIdx.x;
  for (int64_t idx = threadIdx.x; idx < d; idx += blockDim.x) {
    const scalar_t x = VLLM_LDG(&input[token_idx * 2 * d + idx]);
@@ -23,72 +23,66 @@ __global__ void act_and_mul_kernel(
  }
 }
-template<typename T>
+template <typename T>
 __device__ __forceinline__ T silu_kernel(const T& x) {
  // x * sigmoid(x)
-  return (T) (((float) x) / (1.0f + expf((float) -x)));
+  return (T)(((float)x) / (1.0f + expf((float)-x)));
 }
-template<typename T>
+template <typename T>
 __device__ __forceinline__ T gelu_kernel(const T& x) {
  // Equivalent to PyTorch GELU with 'none' approximation.
  // Refer to:
  // https://github.com/pytorch/pytorch/blob/8ac9b20d4b090c213799e81acf48a55ea8d437d6/aten/src/ATen/native/cuda/ActivationGeluKernel.cu#L36-L38
-  const float f = (float) x;
+  const float f = (float)x;
  constexpr float ALPHA = M_SQRT1_2;
-  return (T) (f * 0.5f * (1.0f + ::erf(f * ALPHA)));
+  return (T)(f * 0.5f * (1.0f + ::erf(f * ALPHA)));
 }
-template<typename T>
+template <typename T>
 __device__ __forceinline__ T gelu_tanh_kernel(const T& x) {
  // Equivalent to PyTorch GELU with 'tanh' approximation.
  // Refer to:
  // https://github.com/pytorch/pytorch/blob/8ac9b20d4b090c213799e81acf48a55ea8d437d6/aten/src/ATen/native/cuda/ActivationGeluKernel.cu#L25-L30
-  const float f = (float) x;
+  const float f = (float)x;
  constexpr float BETA = M_SQRT2 * M_2_SQRTPI * 0.5f;
  constexpr float KAPPA = 0.044715;
  float x_cube = f * f * f;
  float inner = BETA * (f + KAPPA * x_cube);
-  return (T) (0.5f * f * (1.0f + ::tanhf(inner)));
+  return (T)(0.5f * f * (1.0f + ::tanhf(inner)));
 }
-} // namespace vllm
+}  // namespace vllm
 // Launch activation and gating kernel.
-#define LAUNCH_ACTIVATION_GATE_KERNEL(KERNEL)                                             \
+#define LAUNCH_ACTIVATION_GATE_KERNEL(KERNEL)                            \
-  int d = input.size(-1) / 2;                                                             \
+  int d = input.size(-1) / 2;                                            \
-  int64_t num_tokens = input.numel() / input.size(-1);                                    \
+  int64_t num_tokens = input.numel() / input.size(-1);                   \
-  dim3 grid(num_tokens);                                                                  \
+  dim3 grid(num_tokens);                                                 \
-  dim3 block(std::min(d, 1024));                                                          \
+  dim3 block(std::min(d, 1024));                                         \
-  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));                       \
+  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));      \
-  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();                           \
+  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();          \
-  VLLM_DISPATCH_FLOATING_TYPES(                                                           \
+  VLLM_DISPATCH_FLOATING_TYPES(                                          \
-    input.scalar_type(),                                                                  \
+      input.scalar_type(), "act_and_mul_kernel", [&] {                   \
-    "act_and_mul_kernel",                                                                 \
+        vllm::act_and_mul_kernel<scalar_t, KERNEL<scalar_t>>             \
-    [&] {                                                                                 \
+            <<<grid, block, 0, stream>>>(out.data_ptr<scalar_t>(),       \
-      vllm::act_and_mul_kernel<scalar_t, KERNEL<scalar_t>><<<grid, block, 0, stream>>>(   \
+                                         input.data_ptr<scalar_t>(), d); \
-        out.data_ptr<scalar_t>(),                                                         \
+      });
        input.data_ptr<scalar_t>(),                                                       \
        d);                                                                               \
    });
-void silu_and_mul(
+void silu_and_mul(torch::Tensor& out,    // [..., d]
-  torch::Tensor& out,      // [..., d]
+                  torch::Tensor& input)  // [..., 2 * d]
  torch::Tensor& input)    // [..., 2 * d]
 {
  LAUNCH_ACTIVATION_GATE_KERNEL(vllm::silu_kernel);
 }
-void gelu_and_mul(
+void gelu_and_mul(torch::Tensor& out,    // [..., d]
-  torch::Tensor& out,      // [..., d]
+                  torch::Tensor& input)  // [..., 2 * d]
  torch::Tensor& input)    // [..., 2 * d]
 {
  LAUNCH_ACTIVATION_GATE_KERNEL(vllm::gelu_kernel);
 }
-void gelu_tanh_and_mul(
+void gelu_tanh_and_mul(torch::Tensor& out,    // [..., d]
-  torch::Tensor& out,      // [..., d]
+                       torch::Tensor& input)  // [..., 2 * d]
  torch::Tensor& input)    // [..., 2 * d]
 {
  LAUNCH_ACTIVATION_GATE_KERNEL(vllm::gelu_tanh_kernel);
 }
@@ -96,11 +90,11 @@ void gelu_tanh_and_mul(
 namespace vllm {
 // Element-wise activation kernel template.
-template<typename scalar_t, scalar_t (*ACT_FN)(const scalar_t&)>
+template <typename scalar_t, scalar_t (*ACT_FN)(const scalar_t&)>
 __global__ void activation_kernel(
-  scalar_t* __restrict__ out,               // [..., d]
+    scalar_t* __restrict__ out,          // [..., d]
-  const scalar_t* __restrict__ input,       // [..., d]
+    const scalar_t* __restrict__ input,  // [..., d]
-  const int d) {
+    const int d) {
  const int64_t token_idx = blockIdx.x;
  for (int64_t idx = threadIdx.x; idx < d; idx += blockDim.x) {
    const scalar_t x = VLLM_LDG(&input[token_idx * d + idx]);
@@ -108,54 +102,49 @@ __global__ void activation_kernel(
  }
 }
-} // namespace vllm
+}  // namespace vllm
 // Launch element-wise activation kernel.
-#define LAUNCH_ACTIVATION_KERNEL(KERNEL)                                                  \
+#define LAUNCH_ACTIVATION_KERNEL(KERNEL)                                       \
-  int d = input.size(-1);                                                                 \
+  int d = input.size(-1);                                                      \
-  int64_t num_tokens = input.numel() / d;                                                 \
+  int64_t num_tokens = input.numel() / d;                                      \
-  dim3 grid(num_tokens);                                                                  \
+  dim3 grid(num_tokens);                                                       \
-  dim3 block(std::min(d, 1024));                                                          \
+  dim3 block(std::min(d, 1024));                                               \
-  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));                       \
+  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));            \
-  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();                           \
+  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();                \
-  VLLM_DISPATCH_FLOATING_TYPES(                                                           \
+  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "activation_kernel", [&] { \
-    input.scalar_type(),                                                                  \
+    vllm::activation_kernel<scalar_t, KERNEL<scalar_t>>                        \
-    "activation_kernel",                                                                  \
+        <<<grid, block, 0, stream>>>(out.data_ptr<scalar_t>(),                 \
-    [&] {                                                                                 \
+                                     input.data_ptr<scalar_t>(), d);           \
-      vllm::activation_kernel<scalar_t, KERNEL<scalar_t>><<<grid, block, 0, stream>>>(    \
+  });
        out.data_ptr<scalar_t>(),                                                         \
        input.data_ptr<scalar_t>(),                                                       \
        d);                                                                               \
    });
 namespace vllm {
-template<typename T>
+template <typename T>
 __device__ __forceinline__ T gelu_new_kernel(const T& x) {
-  const float x3 = (float) (x * x * x);
+  const float x3 = (float)(x * x * x);
-  const T t = (T) tanhf((T) (0.79788456f * (float) (x + (T) (0.044715f * x3))));
+  const T t = (T)tanhf((T)(0.79788456f * (float)(x + (T)(0.044715f * x3))));
-  return ((T) 0.5) * x * (((T) 1.0) + t);
+  return ((T)0.5) * x * (((T)1.0) + t);
 }
-template<typename T>
+template <typename T>
 __device__ __forceinline__ T gelu_fast_kernel(const T& x) {
-  const float f = (float) x;
+  const float f = (float)x;
-  const T t = (T) tanhf(((T) (f * 0.79788456f)) * (((T) 1.0) + (T) (0.044715f * f) * x));
+  const T t =
-  return ((T) 0.5) * x * (((T) 1.0) + t);
+      (T)tanhf(((T)(f * 0.79788456f)) * (((T)1.0) + (T)(0.044715f * f) * x));
  return ((T)0.5) * x * (((T)1.0) + t);
 }
-} // namespace vllm
+}  // namespace vllm
-void gelu_new(
+void gelu_new(torch::Tensor& out,    // [..., d]
-  torch::Tensor& out,     // [..., d]
+              torch::Tensor& input)  // [..., d]
  torch::Tensor& input)   // [..., d]
 {
  LAUNCH_ACTIVATION_KERNEL(vllm::gelu_new_kernel);
 }
-void gelu_fast(
+void gelu_fast(torch::Tensor& out,    // [..., d]
-  torch::Tensor& out,     // [..., d]
+               torch::Tensor& input)  // [..., d]
  torch::Tensor& input)   // [..., d]
 {
  LAUNCH_ACTIVATION_KERNEL(vllm::gelu_fast_kernel);
 }
--- a/csrc/attention/attention_dtypes.h
+++ b/csrc/attention/attention_dtypes.h
@@ -4,4 +4,4 @@
 #include "dtype_float16.cuh"
 #include "dtype_float32.cuh"
 #include "dtype_bfloat16.cuh"
-#include "dtype_fp8_e5m2.cuh"
+#include "dtype_fp8.cuh"
--- a/csrc/attention/attention_generic.cuh
+++ b/csrc/attention/attention_generic.cuh
@@ -1,5 +1,6 @@
 /*
- * Adapted from https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
+ * Adapted from
 * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
 * Copyright (c) 2023, The vLLM team.
 * Copyright (c) 2020-2023, NVIDIA CORPORATION.  All rights reserved.
 *
@@ -22,31 +23,31 @@
 namespace vllm {
 // A vector type to store Q, K, V elements.
-template<typename T, int VEC_SIZE>
+template <typename T, int VEC_SIZE>
 struct Vec {};
 // A vector type to store FP32 accumulators.
-template<typename T>
+template <typename T>
 struct FloatVec {};
 // Template vector operations.
-template<typename Acc, typename A, typename B>
+template <typename Acc, typename A, typename B>
 inline __device__ Acc mul(A a, B b);
-template<typename T>
+template <typename T>
 inline __device__ float sum(T v);
-template<typename T>
+template <typename T>
 inline __device__ float dot(T a, T b) {
  return sum(mul<T, T, T>(a, b));
 }
-template<typename A, typename T>
+template <typename A, typename T>
 inline __device__ float dot(T a, T b) {
  return sum(mul<A, T, T>(a, b));
 }
-template<typename T>
+template <typename T>
 inline __device__ void zero(T& dst) {
  constexpr int WORDS = sizeof(T) / 4;
  union {
@@ -61,4 +62,4 @@ inline __device__ void zero(T& dst) {
  dst = tmp.raw;
 }
-} // namespace vllm
+}  // namespace vllm
--- a/csrc/attention/attention_kernels.cu
+++ b/csrc/attention/attention_kernels.cu
--- a/csrc/attention/attention_utils.cuh
+++ b/csrc/attention/attention_utils.cuh
@@ -1,5 +1,6 @@
 /*
- * Adapted from https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
+ * Adapted from
 * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
 * Copyright (c) 2023, The vLLM team.
 * Copyright (c) 2020-2023, NVIDIA CORPORATION.  All rights reserved.
 *
@@ -26,7 +27,7 @@
 namespace vllm {
 // Q*K^T operation.
-template<int THREAD_GROUP_SIZE, typename Vec, int N>
+template <int THREAD_GROUP_SIZE, typename Vec, int N>
 inline __device__ float qk_dot_(const Vec (&q)[N], const Vec (&k)[N]) {
  using A_vec = typename FloatVec<Vec>::Type;
  // Compute the parallel products for Q*K^T (treat vector lanes separately).
@@ -45,12 +46,12 @@ inline __device__ float qk_dot_(const Vec (&q)[N], const Vec (&k)[N]) {
  return qk;
 }
-template<typename T, int THREAD_GROUP_SIZE>
+template <typename T, int THREAD_GROUP_SIZE>
 struct Qk_dot {
-  template<typename Vec, int N>
+  template <typename Vec, int N>
  static inline __device__ float dot(const Vec (&q)[N], const Vec (&k)[N]) {
    return qk_dot_<THREAD_GROUP_SIZE>(q, k);
  }
 };
-} // namespace vllm
+}  // namespace vllm
--- a/csrc/attention/dtype_bfloat16.cuh
+++ b/csrc/attention/dtype_bfloat16.cuh
@@ -1,6 +1,8 @@
 /*
- * Adapted from https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
+ * Adapted from
- * and https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
+ * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
 * and
 * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
 * Copyright (c) 2023, The vLLM team.
 * Copyright (c) 2020-2023, NVIDIA CORPORATION.  All rights reserved.
 *
@@ -28,8 +30,8 @@
  #include <hip/hip_bf16.h>
  #include <hip/hip_fp16.h>
-  typedef __hip_bfloat162 __nv_bfloat162;
+typedef __hip_bfloat162 __nv_bfloat162;
-  typedef __hip_bfloat16 __nv_bfloat16;
+typedef __hip_bfloat16 __nv_bfloat16;
 #endif
 #include <stdint.h>
@@ -50,37 +52,37 @@ struct bf16_8_t {
 };
 // BF16 vector types for Q, K, V.
-template<>
+template <>
 struct Vec<__nv_bfloat16, 1> {
  using Type = __nv_bfloat16;
 };
-template<>
+template <>
 struct Vec<__nv_bfloat16, 2> {
  using Type = __nv_bfloat162;
 };
-template<>
+template <>
 struct Vec<__nv_bfloat16, 4> {
  using Type = bf16_4_t;
 };
-template<>
+template <>
 struct Vec<__nv_bfloat16, 8> {
  using Type = bf16_8_t;
 };
 // FP32 accumulator vector types corresponding to Vec.
-template<>
+template <>
 struct FloatVec<__nv_bfloat16> {
  using Type = float;
 };
-template<>
+template <>
 struct FloatVec<__nv_bfloat162> {
  using Type = float2;
 };
-template<>
+template <>
 struct FloatVec<bf16_4_t> {
  using Type = Float4_;
 };
-template<>
+template <>
 struct FloatVec<bf16_8_t> {
  using Type = Float8_;
 };
@@ -108,9 +110,9 @@ inline __device__ __nv_bfloat16 add(__nv_bfloat16 a, __nv_bfloat16 b) {
  assert(false);
 #else
  #ifndef USE_ROCM
-    return a + b;
+  return a + b;
  #else
-    return __hadd(a, b);
+  return __hadd(a, b);
  #endif
 #endif
 }
@@ -161,7 +163,7 @@ inline __device__ Float8_ add(bf16_8_t a, Float8_ fb) {
 }
 // Vector multiplication.
-template<>
+template <>
 inline __device__ __nv_bfloat16 mul(__nv_bfloat16 a, __nv_bfloat16 b) {
 #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ < 800
  assert(false);
@@ -170,7 +172,7 @@ inline __device__ __nv_bfloat16 mul(__nv_bfloat16 a, __nv_bfloat16 b) {
 #endif
 }
-template<>
+template <>
 inline __device__ __nv_bfloat162 mul(__nv_bfloat162 a, __nv_bfloat162 b) {
 #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ < 800
  assert(false);
@@ -179,12 +181,12 @@ inline __device__ __nv_bfloat162 mul(__nv_bfloat162 a, __nv_bfloat162 b) {
 #endif
 }
-template<>
+template <>
 inline __device__ __nv_bfloat162 mul(__nv_bfloat16 a, __nv_bfloat162 b) {
  return mul<__nv_bfloat162, __nv_bfloat162, __nv_bfloat162>(bf162bf162(a), b);
 }
-template<>
+template <>
 inline __device__ bf16_4_t mul(bf16_4_t a, bf16_4_t b) {
  bf16_4_t c;
  c.x = mul<__nv_bfloat162, __nv_bfloat162, __nv_bfloat162>(a.x, b.x);
@@ -192,7 +194,7 @@ inline __device__ bf16_4_t mul(bf16_4_t a, bf16_4_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ bf16_4_t mul(__nv_bfloat16 a, bf16_4_t b) {
  __nv_bfloat162 s = bf162bf162(a);
  bf16_4_t c;
@@ -201,7 +203,7 @@ inline __device__ bf16_4_t mul(__nv_bfloat16 a, bf16_4_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ bf16_8_t mul(bf16_8_t a, bf16_8_t b) {
  bf16_8_t c;
  c.x = mul<__nv_bfloat162, __nv_bfloat162, __nv_bfloat162>(a.x, b.x);
@@ -211,7 +213,7 @@ inline __device__ bf16_8_t mul(bf16_8_t a, bf16_8_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ bf16_8_t mul(__nv_bfloat16 a, bf16_8_t b) {
  __nv_bfloat162 s = bf162bf162(a);
  bf16_8_t c;
@@ -222,26 +224,26 @@ inline __device__ bf16_8_t mul(__nv_bfloat16 a, bf16_8_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ float mul(__nv_bfloat16 a, __nv_bfloat16 b) {
  float fa = __bfloat162float(a);
  float fb = __bfloat162float(b);
  return fa * fb;
 }
-template<>
+template <>
 inline __device__ float2 mul(__nv_bfloat162 a, __nv_bfloat162 b) {
  float2 fa = bf1622float2(a);
  float2 fb = bf1622float2(b);
  return mul<float2, float2, float2>(fa, fb);
 }
-template<>
+template <>
 inline __device__ float2 mul(__nv_bfloat16 a, __nv_bfloat162 b) {
  return mul<float2, __nv_bfloat162, __nv_bfloat162>(bf162bf162(a), b);
 }
-template<>
+template <>
 inline __device__ Float4_ mul(bf16_4_t a, bf16_4_t b) {
  Float4_ fc;
  fc.x = mul<float2, __nv_bfloat162, __nv_bfloat162>(a.x, b.x);
@@ -249,7 +251,7 @@ inline __device__ Float4_ mul(bf16_4_t a, bf16_4_t b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float4_ mul(__nv_bfloat16 a, bf16_4_t b) {
  __nv_bfloat162 s = bf162bf162(a);
  Float4_ fc;
@@ -258,7 +260,7 @@ inline __device__ Float4_ mul(__nv_bfloat16 a, bf16_4_t b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float8_ mul(bf16_8_t a, bf16_8_t b) {
  Float8_ fc;
  fc.x = mul<float2, __nv_bfloat162, __nv_bfloat162>(a.x, b.x);
@@ -268,7 +270,7 @@ inline __device__ Float8_ mul(bf16_8_t a, bf16_8_t b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float8_ mul(__nv_bfloat16 a, bf16_8_t b) {
  __nv_bfloat162 s = bf162bf162(a);
  Float8_ fc;
@@ -280,7 +282,8 @@ inline __device__ Float8_ mul(__nv_bfloat16 a, bf16_8_t b) {
 }
 // Vector fused multiply-add.
-inline __device__ __nv_bfloat162 fma(__nv_bfloat162 a, __nv_bfloat162 b, __nv_bfloat162 c) {
+inline __device__ __nv_bfloat162 fma(__nv_bfloat162 a, __nv_bfloat162 b,
                                     __nv_bfloat162 c) {
 #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ < 800
  assert(false);
 #else
@@ -288,7 +291,8 @@ inline __device__ __nv_bfloat162 fma(__nv_bfloat162 a, __nv_bfloat162 b, __nv_bf
 #endif
 }
-inline __device__ __nv_bfloat162 fma(__nv_bfloat16 a, __nv_bfloat162 b, __nv_bfloat162 c) {
+inline __device__ __nv_bfloat162 fma(__nv_bfloat16 a, __nv_bfloat162 b,
                                     __nv_bfloat162 c) {
 #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ < 800
  assert(false);
 #else
@@ -379,23 +383,23 @@ inline __device__ Float8_ fma(__nv_bfloat16 a, bf16_8_t b, Float8_ fc) {
 }
 // Vector sum.
-template<>
+template <>
 inline __device__ float sum(__nv_bfloat16 v) {
  return __bfloat162float(v);
 }
-template<>
+template <>
 inline __device__ float sum(__nv_bfloat162 v) {
  float2 vf = bf1622float2(v);
  return vf.x + vf.y;
 }
-template<>
+template <>
 inline __device__ float sum(bf16_4_t v) {
  return sum(v.x) + sum(v.y);
 }
-template<>
+template <>
 inline __device__ float sum(bf16_8_t v) {
  return sum(v.x) + sum(v.y) + sum(v.z) + sum(v.w);
 }
@@ -448,4 +452,4 @@ inline __device__ void zero(__nv_bfloat16& dst) {
 #endif
 }
-} // namespace vllm
+}  // namespace vllm
--- a/csrc/attention/dtype_float16.cuh
+++ b/csrc/attention/dtype_float16.cuh
@@ -1,6 +1,8 @@
 /*
- * Adapted from https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
+ * Adapted from
- * and https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
+ * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
 * and
 * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
 * Copyright (c) 2023, The vLLM team.
 * Copyright (c) 2020-2023, NVIDIA CORPORATION.  All rights reserved.
 *
@@ -30,37 +32,37 @@
 namespace vllm {
 // FP16 vector types for Q, K, V.
-template<>
+template <>
 struct Vec<uint16_t, 1> {
  using Type = uint16_t;
 };
-template<>
+template <>
 struct Vec<uint16_t, 2> {
  using Type = uint32_t;
 };
-template<>
+template <>
 struct Vec<uint16_t, 4> {
  using Type = uint2;
 };
-template<>
+template <>
 struct Vec<uint16_t, 8> {
  using Type = uint4;
 };
 // FP32 accumulator vector types corresponding to Vec.
-template<>
+template <>
 struct FloatVec<uint16_t> {
  using Type = float;
 };
-template<>
+template <>
 struct FloatVec<uint32_t> {
  using Type = float2;
 };
-template<>
+template <>
 struct FloatVec<uint2> {
  using Type = Float4_;
 };
-template<>
+template <>
 struct FloatVec<uint4> {
  using Type = Float8_;
 };
@@ -73,8 +75,8 @@ inline __device__ uint32_t h0_h0(uint16_t a) {
  return b;
 #else
  union {
-   uint32_t u32;
+    uint32_t u32;
-   uint16_t u16[2];
+    uint16_t u16[2];
  } tmp;
  tmp.u16[0] = a;
  tmp.u16[1] = a;
@@ -130,10 +132,12 @@ inline __device__ uint32_t float2_to_half2(float2 f) {
  } tmp;
 #ifndef USE_ROCM
  #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
-    asm volatile("cvt.rn.f16x2.f32 %0, %1, %2;\n" : "=r"(tmp.u32) : "f"(f.y), "f"(f.x));
+  asm volatile("cvt.rn.f16x2.f32 %0, %1, %2;\n"
               : "=r"(tmp.u32)
               : "f"(f.y), "f"(f.x));
  #else
-    asm volatile("cvt.rn.f16.f32 %0, %1;\n" : "=h"(tmp.u16[0]) : "f"(f.x));
+  asm volatile("cvt.rn.f16.f32 %0, %1;\n" : "=h"(tmp.u16[0]) : "f"(f.x));
-    asm volatile("cvt.rn.f16.f32 %0, %1;\n" : "=h"(tmp.u16[1]) : "f"(f.y));
+  asm volatile("cvt.rn.f16.f32 %0, %1;\n" : "=h"(tmp.u16[1]) : "f"(f.y));
  #endif
 #else
  tmp.u16[0] = float_to_half(f.x);
@@ -201,7 +205,7 @@ inline __device__ Float8_ add(uint4 a, Float8_ fb) {
 }
 // Vector multiplication.
-template<>
+template <>
 inline __device__ uint16_t mul(uint16_t a, uint16_t b) {
  uint16_t c;
 #ifndef USE_ROCM
@@ -212,7 +216,7 @@ inline __device__ uint16_t mul(uint16_t a, uint16_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ uint32_t mul(uint32_t a, uint32_t b) {
  uint32_t c;
 #ifndef USE_ROCM
@@ -223,12 +227,12 @@ inline __device__ uint32_t mul(uint32_t a, uint32_t b) {
  return c;
 }
-template<>
+template <>
 inline __device__ uint32_t mul(uint16_t a, uint32_t b) {
  return mul<uint32_t, uint32_t, uint32_t>(h0_h0(a), b);
 }
-template<>
+template <>
 inline __device__ uint2 mul(uint2 a, uint2 b) {
  uint2 c;
  c.x = mul<uint32_t, uint32_t, uint32_t>(a.x, b.x);
@@ -236,7 +240,7 @@ inline __device__ uint2 mul(uint2 a, uint2 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ uint2 mul(uint16_t a, uint2 b) {
  uint32_t s = h0_h0(a);
  uint2 c;
@@ -245,7 +249,7 @@ inline __device__ uint2 mul(uint16_t a, uint2 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ uint4 mul(uint4 a, uint4 b) {
  uint4 c;
  c.x = mul<uint32_t, uint32_t, uint32_t>(a.x, b.x);
@@ -255,7 +259,7 @@ inline __device__ uint4 mul(uint4 a, uint4 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ uint4 mul(uint16_t a, uint4 b) {
  uint32_t s = h0_h0(a);
  uint4 c;
@@ -266,26 +270,26 @@ inline __device__ uint4 mul(uint16_t a, uint4 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ float mul(uint16_t a, uint16_t b) {
  float fa = half_to_float(a);
  float fb = half_to_float(b);
  return fa * fb;
 }
-template<>
+template <>
 inline __device__ float2 mul(uint32_t a, uint32_t b) {
  float2 fa = half2_to_float2(a);
  float2 fb = half2_to_float2(b);
  return mul<float2, float2, float2>(fa, fb);
 }
-template<>
+template <>
 inline __device__ float2 mul(uint16_t a, uint32_t b) {
  return mul<float2, uint32_t, uint32_t>(h0_h0(a), b);
 }
-template<>
+template <>
 inline __device__ Float4_ mul(uint2 a, uint2 b) {
  Float4_ fc;
  fc.x = mul<float2, uint32_t, uint32_t>(a.x, b.x);
@@ -293,7 +297,7 @@ inline __device__ Float4_ mul(uint2 a, uint2 b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float4_ mul(uint16_t a, uint2 b) {
  uint32_t s = h0_h0(a);
  Float4_ fc;
@@ -302,7 +306,7 @@ inline __device__ Float4_ mul(uint16_t a, uint2 b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float8_ mul(uint4 a, uint4 b) {
  Float8_ fc;
  fc.x = mul<float2, uint32_t, uint32_t>(a.x, b.x);
@@ -312,7 +316,7 @@ inline __device__ Float8_ mul(uint4 a, uint4 b) {
  return fc;
 }
-template<>
+template <>
 inline __device__ Float8_ mul(uint16_t a, uint4 b) {
  uint32_t s = h0_h0(a);
  Float8_ fc;
@@ -327,9 +331,13 @@ inline __device__ Float8_ mul(uint16_t a, uint4 b) {
 inline __device__ uint32_t fma(uint32_t a, uint32_t b, uint32_t c) {
  uint32_t d;
 #ifndef USE_ROCM
-  asm volatile("fma.rn.f16x2 %0, %1, %2, %3;\n" : "=r"(d) : "r"(a), "r"(b), "r"(c));
+  asm volatile("fma.rn.f16x2 %0, %1, %2, %3;\n"
               : "=r"(d)
               : "r"(a), "r"(b), "r"(c));
 #else
-  asm volatile("v_pk_fma_f16 %0, %1, %2, %3;\n" : "=v"(d) : "v"(a), "v"(b), "v"(c));
+  asm volatile("v_pk_fma_f16 %0, %1, %2, %3;\n"
               : "=v"(d)
               : "v"(a), "v"(b), "v"(c));
 #endif
  return d;
 }
@@ -423,24 +431,24 @@ inline __device__ Float8_ fma(uint16_t a, uint4 b, Float8_ fc) {
 }
 // Vector sum.
-template<>
+template <>
 inline __device__ float sum(uint16_t v) {
  return half_to_float(v);
 }
-template<>
+template <>
 inline __device__ float sum(uint32_t v) {
  float2 tmp = half2_to_float2(v);
  return tmp.x + tmp.y;
 }
-template<>
+template <>
 inline __device__ float sum(uint2 v) {
  uint32_t c = add(v.x, v.y);
  return sum(c);
 }
-template<>
+template <>
 inline __device__ float sum(uint4 v) {
  uint32_t c = add(v.x, v.y);
  c = add(c, v.z);
@@ -470,13 +478,9 @@ inline __device__ void from_float(uint4& dst, Float8_ src) {
 }
 // From float16 to float32.
-inline __device__ float to_float(uint16_t u) {
+inline __device__ float to_float(uint16_t u) { return half_to_float(u); }
  return half_to_float(u);
 }
-inline __device__ float2 to_float(uint32_t u) {
+inline __device__ float2 to_float(uint32_t u) { return half2_to_float2(u); }
  return half2_to_float2(u);
 }
 inline __device__ Float4_ to_float(uint2 u) {
  Float4_ tmp;
@@ -495,8 +499,6 @@ inline __device__ Float8_ to_float(uint4 u) {
 }
 // Zero-out a variable.
-inline __device__ void zero(uint16_t& dst) {
+inline __device__ void zero(uint16_t& dst) { dst = uint16_t(0); }
  dst = uint16_t(0);
 }
-} // namespace vllm
+}  // namespace vllm
--- a/csrc/attention/dtype_float32.cuh
+++ b/csrc/attention/dtype_float32.cuh
@@ -1,6 +1,8 @@
 /*
- * Adapted from https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
+ * Adapted from
- * and https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
+ * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention/decoder_masked_multihead_attention_template.hpp
 * and
 * https://github.com/NVIDIA/FasterTransformer/blob/release/v5.3_tag/src/fastertransformer/kernels/decoder_masked_multihead_attention_utils.h
 * Copyright (c) 2023, The vLLM team.
 * Copyright (c) 2020-2023, NVIDIA CORPORATION.  All rights reserved.
 *
@@ -38,37 +40,35 @@ struct Float8_ {
 };
 // FP32 vector types for Q, K, V.
-template<>
+template <>
 struct Vec<float, 1> {
  using Type = float;
 };
-template<>
+template <>
 struct Vec<float, 2> {
  using Type = float2;
 };
-template<>
+template <>
 struct Vec<float, 4> {
  using Type = float4;
 };
 // FP32 accumulator vector types corresponding to Vec.
-template<>
+template <>
 struct FloatVec<float> {
  using Type = float;
 };
-template<>
+template <>
 struct FloatVec<float2> {
  using Type = float2;
 };
-template<>
+template <>
 struct FloatVec<float4> {
  using Type = float4;
 };
 // Vector addition.
-inline __device__ float add(float a, float b) {
+inline __device__ float add(float a, float b) { return a + b; }
  return a + b;
 }
 inline __device__ float2 add(float2 a, float2 b) {
  float2 c;
@@ -87,12 +87,12 @@ inline __device__ float4 add(float4 a, float4 b) {
 }
 // Vector multiplication.
-template<>
+template <>
 inline __device__ float mul<float, float>(float a, float b) {
  return a * b;
 }
-template<>
+template <>
 inline __device__ float2 mul(float2 a, float2 b) {
  float2 c;
  c.x = a.x * b.x;
@@ -100,7 +100,7 @@ inline __device__ float2 mul(float2 a, float2 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ float2 mul(float a, float2 b) {
  float2 c;
  c.x = a * b.x;
@@ -108,7 +108,7 @@ inline __device__ float2 mul(float a, float2 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ float4 mul(float4 a, float4 b) {
  float4 c;
  c.x = a.x * b.x;
@@ -118,7 +118,7 @@ inline __device__ float4 mul(float4 a, float4 b) {
  return c;
 }
-template<>
+template <>
 inline __device__ float4 mul(float a, float4 b) {
  float4 c;
  c.x = a * b.x;
@@ -129,9 +129,7 @@ inline __device__ float4 mul(float a, float4 b) {
 }
 // Vector fused multiply-add.
-inline __device__ float fma(float a, float b, float c) {
+inline __device__ float fma(float a, float b, float c) { return a * b + c; }
  return a * b + c;
 }
 inline __device__ float2 fma(float2 a, float2 b, float2 c) {
  float2 d;
@@ -182,35 +180,33 @@ inline __device__ Float8_ fma(float a, Float8_ b, Float8_ c) {
 }
 // Vector sum.
-template<>
+template <>
 inline __device__ float sum(float v) {
  return v;
 }
-template<>
+template <>
 inline __device__ float sum(float2 v) {
  return v.x + v.y;
 }
-template<>
+template <>
 inline __device__ float sum(float4 v) {
  return v.x + v.y + v.z + v.w;
 }
-template<>
+template <>
 inline __device__ float sum(Float4_ v) {
  return v.x.x + v.x.y + v.y.x + v.y.y;
 }
-template<>
+template <>
 inline __device__ float sum(Float8_ v) {
  return v.x.x + v.x.y + v.y.x + v.y.y + v.z.x + v.z.y + v.w.x + v.w.y;
 }
 // Vector dot product.
-inline __device__ float dot(float a, float b) {
+inline __device__ float dot(float a, float b) { return a * b; }
  return a * b;
 }
 inline __device__ float dot(float2 a, float2 b) {
  float2 c = mul<float2, float2, float2>(a, b);
@@ -232,42 +228,24 @@ inline __device__ float dot(Float8_ a, Float8_ b) {
 }
 // From float to float.
-inline __device__ void from_float(float& dst, float src) {
+inline __device__ void from_float(float& dst, float src) { dst = src; }
  dst = src;
 }
-inline __device__ void from_float(float2& dst, float2 src) {
+inline __device__ void from_float(float2& dst, float2 src) { dst = src; }
  dst = src;
 }
-inline __device__ void from_float(float4& dst, float4 src) {
+inline __device__ void from_float(float4& dst, float4 src) { dst = src; }
  dst = src;
 }
 // From float to float.
-inline __device__ float to_float(float u) {
+inline __device__ float to_float(float u) { return u; }
  return u;
 }
-inline __device__ float2 to_float(float2 u) {
+inline __device__ float2 to_float(float2 u) { return u; }
  return u;
 }
-inline __device__ float4 to_float(float4 u) {
+inline __device__ float4 to_float(float4 u) { return u; }
  return u;
 }
-inline __device__ Float4_ to_float(Float4_ u) {
+inline __device__ Float4_ to_float(Float4_ u) { return u; }
  return u;
 }
-inline __device__ Float8_ to_float(Float8_ u) {
+inline __device__ Float8_ to_float(Float8_ u) { return u; }
  return u;
 }
 // Zero-out a variable.
-inline __device__ void zero(float& dst) {
+inline __device__ void zero(float& dst) { dst = 0.f; }
  dst = 0.f;
 }
-} // namespace vllm
+}  // namespace vllm
--- a/csrc/attention/dtype_fp8.cuh
+++ b/csrc/attention/dtype_fp8.cuh
@@ -0,0 +1,41 @@
 #pragma once
 #include "attention_generic.cuh"
 #include <stdint.h>
 #ifdef ENABLE_FP8
  #ifndef USE_ROCM
    #include <cuda_fp8.h>
  #endif  // USE_ROCM
 #endif    // ENABLE_FP8
 namespace vllm {
 enum class Fp8KVCacheDataType {
  kAuto = 0,
  kFp8E4M3 = 1,
  kFp8E5M2 = 2,
 };
 // fp8 vector types for quantization of kv cache
 template <>
 struct Vec<uint8_t, 1> {
  using Type = uint8_t;
 };
 template <>
 struct Vec<uint8_t, 2> {
  using Type = uint16_t;
 };
 template <>
 struct Vec<uint8_t, 4> {
  using Type = uint32_t;
 };
 template <>
 struct Vec<uint8_t, 8> {
  using Type = uint2;
 };
 }  // namespace vllm
--- a/csrc/attention/dtype_fp8_e5m2.cuh
+++ b/csrc/attention/dtype_fp8_e5m2.cuh
@@ -1,35 +0,0 @@
 #pragma once
 #include "attention_generic.cuh"
 #include <stdint.h>
 #ifdef ENABLE_FP8_E5M2
 #include <cuda_fp8.h>
 #endif
 namespace vllm {
 #ifdef ENABLE_FP8_E5M2
 // fp8 vector types for quantization of kv cache
 template<>
 struct Vec<uint8_t, 1> {
    using Type = uint8_t;
 };
 template<>
 struct Vec<uint8_t, 2> {
    using Type = uint16_t;
 };
 template<>
 struct Vec<uint8_t, 4> {
    using Type = uint32_t;
 };
 template<>
 struct Vec<uint8_t, 8> {
    using Type = uint2;
 };
 #endif // ENABLE_FP8_E5M2
 } // namespace vllm
--- a/csrc/cache.h
+++ b/csrc/cache.h
@@ -1,29 +1,32 @@
 #pragma once
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <map>
 #include <vector>
-void swap_blocks(
+void swap_blocks(torch::Tensor& src, torch::Tensor& dst,
-  torch::Tensor& src,
+                 const torch::Tensor& block_mapping);
  torch::Tensor& dst,
  const std::map<int64_t, int64_t>& block_mapping);
-void copy_blocks(
+// Note: the key_caches and value_caches vectors are constant but
-  std::vector<torch::Tensor>& key_caches,
+// not the Tensors they contain. The vectors need to be const refs
-  std::vector<torch::Tensor>& value_caches,
+// in order to satisfy pytorch's C++ operator registration code.
-  const std::map<int64_t, std::vector<int64_t>>& block_mapping);
+void copy_blocks(std::vector<torch::Tensor> const& key_caches,
                 std::vector<torch::Tensor> const& value_caches,
                 const torch::Tensor& block_mapping);
-void reshape_and_cache(
+void reshape_and_cache(torch::Tensor& key, torch::Tensor& value,
-  torch::Tensor& key,
+                       torch::Tensor& key_cache, torch::Tensor& value_cache,
-  torch::Tensor& value,
+                       torch::Tensor& slot_mapping,
-  torch::Tensor& key_cache,
+                       const std::string& kv_cache_dtype,
-  torch::Tensor& value_cache,
+                       const double kv_scale);
-  torch::Tensor& slot_mapping,
+
-  const std::string& kv_cache_dtype);
+void reshape_and_cache_flash(torch::Tensor& key, torch::Tensor& value,
                             torch::Tensor& key_cache,
                             torch::Tensor& value_cache,
                             torch::Tensor& slot_mapping,
                             const std::string& kv_cache_dtype);
 // Just for unittest
-void convert_fp8_e5m2(
+void convert_fp8(torch::Tensor& dst_cache, torch::Tensor& src_cache,
-  torch::Tensor& src_cache,
+                 const double scale, const std::string& kv_cache_dtype);
  torch::Tensor& dst_cache);
--- a/csrc/cache_kernels.cu
+++ b/csrc/cache_kernels.cu
@@ -1,11 +1,14 @@
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <ATen/cuda/CUDAContext.h>
 #include <c10/cuda/CUDAGuard.h>
 #include "cuda_compat.h"
 #include "dispatch_utils.h"
-#ifdef ENABLE_FP8_E5M2
+
-#include "quantization/fp8_e5m2_kvcache/quant_utils.cuh"
+#ifdef USE_ROCM
  #include "quantization/fp8/amd/quant_utils.cuh"
 #else
  #include "quantization/fp8/nvidia/quant_utils.cuh"
 #endif
 #include <algorithm>
@@ -15,20 +18,17 @@
 #ifdef USE_ROCM
  #include <hip/hip_bf16.h>
-  typedef __hip_bfloat16 __nv_bfloat16;
+typedef __hip_bfloat16 __nv_bfloat16;
 #endif
-void swap_blocks(
+void swap_blocks(torch::Tensor& src, torch::Tensor& dst,
-  torch::Tensor& src,
+                 const torch::Tensor& block_mapping) {
  torch::Tensor& dst,
  const std::map<int64_t, int64_t>& block_mapping) {
  torch::Device src_device = src.device();
  torch::Device dst_device = dst.device();
  cudaMemcpyKind memcpy_type;
  if (src_device.is_cuda() && dst_device.is_cuda()) {
-    TORCH_CHECK(
+    TORCH_CHECK(src_device.index() == dst_device.index(),
-      src_device.index() == dst_device.index(),
+                "src and dst must be on the same GPU");
      "src and dst must be on the same GPU");
    memcpy_type = cudaMemcpyDeviceToDevice;
  } else if (src_device.is_cuda() && dst_device.is_cpu()) {
    memcpy_type = cudaMemcpyDeviceToHost;
@@ -38,41 +38,44 @@ void swap_blocks(
    TORCH_CHECK(false, "Invalid device combination");
  }
-  char *src_ptr = static_cast<char*>(src.data_ptr());
+  // NOTE(youkaichao): keep in mind that `block_mapping` should be
-  char *dst_ptr = static_cast<char*>(dst.data_ptr());
+  // a cpu tensor, otherwise every `item` call will require a gpu-cpu
  // synchronization.
  TORCH_CHECK(block_mapping.device().is_cpu(), "block_mapping must be on CPU");
  char* src_ptr = static_cast<char*>(src.data_ptr());
  char* dst_ptr = static_cast<char*>(dst.data_ptr());
  const int64_t block_size_in_bytes = src.element_size() * src[0].numel();
-  const at::cuda::OptionalCUDAGuard device_guard(src_device.is_cuda() ? src_device : dst_device);
+  const at::cuda::OptionalCUDAGuard device_guard(
      src_device.is_cuda() ? src_device : dst_device);
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  // NOTE(woosuk): This can be slow if the number of blocks is large.
-  for (const auto& pair : block_mapping) {
+  const int64_t num_blocks = block_mapping.size(0);
-    int64_t src_block_number = pair.first;
+  for (size_t i = 0; i < num_blocks; i++) {
-    int64_t dst_block_number = pair.second;
+    int64_t src_block_number = block_mapping[i][0].item<int64_t>();
    int64_t dst_block_number = block_mapping[i][1].item<int64_t>();
    int64_t src_offset = src_block_number * block_size_in_bytes;
    int64_t dst_offset = dst_block_number * block_size_in_bytes;
-    cudaMemcpyAsync(
+    cudaMemcpyAsync(dst_ptr + dst_offset, src_ptr + src_offset,
-      dst_ptr + dst_offset,
+                    block_size_in_bytes, memcpy_type, stream);
      src_ptr + src_offset,
      block_size_in_bytes,
      memcpy_type,
      stream);
  }
 }
 namespace vllm {
 // Grid: (num_layers, num_pairs)
-template<typename scalar_t>
+template <typename scalar_t>
-__global__ void copy_blocks_kernel(
+__global__ void copy_blocks_kernel(int64_t* key_cache_ptrs,
-  int64_t* key_cache_ptrs,
+                                   int64_t* value_cache_ptrs,
-  int64_t* value_cache_ptrs,
+                                   const int64_t* __restrict__ block_mapping,
-  const int64_t* __restrict__ block_mapping,
+                                   const int numel_per_block) {
  const int numel_per_block) {
  const int layer_idx = blockIdx.x;
  const int pair_idx = blockIdx.y;
  scalar_t* key_cache = reinterpret_cast<scalar_t*>(key_cache_ptrs[layer_idx]);
-  scalar_t* value_cache = reinterpret_cast<scalar_t*>(value_cache_ptrs[layer_idx]);
+  scalar_t* value_cache =
      reinterpret_cast<scalar_t*>(value_cache_ptrs[layer_idx]);
  int64_t src_block_number = block_mapping[2 * pair_idx];
  int64_t dst_block_number = block_mapping[2 * pair_idx + 1];
@@ -90,12 +93,14 @@ __global__ void copy_blocks_kernel(
  }
 }
-} // namespace vllm
+}  // namespace vllm
-void copy_blocks(
+// Note: the key_caches and value_caches vectors are constant but
-  std::vector<torch::Tensor>& key_caches,
+// not the Tensors they contain. The vectors need to be const refs
-  std::vector<torch::Tensor>& value_caches,
+// in order to satisfy pytorch's C++ operator registration code.
-  const std::map<int64_t, std::vector<int64_t>>& block_mapping) {
+void copy_blocks(std::vector<torch::Tensor> const& key_caches,
                 std::vector<torch::Tensor> const& value_caches,
                 const torch::Tensor& block_mapping) {
  int num_layers = key_caches.size();
  TORCH_CHECK(num_layers == value_caches.size());
  if (num_layers == 0) {
@@ -109,29 +114,23 @@ void copy_blocks(
  int64_t key_cache_ptrs[num_layers];
  int64_t value_cache_ptrs[num_layers];
  for (int layer_idx = 0; layer_idx < num_layers; ++layer_idx) {
-    key_cache_ptrs[layer_idx] = reinterpret_cast<int64_t>(key_caches[layer_idx].data_ptr());
+    key_cache_ptrs[layer_idx] =
-    value_cache_ptrs[layer_idx] = reinterpret_cast<int64_t>(value_caches[layer_idx].data_ptr());
+        reinterpret_cast<int64_t>(key_caches[layer_idx].data_ptr());
    value_cache_ptrs[layer_idx] =
        reinterpret_cast<int64_t>(value_caches[layer_idx].data_ptr());
  }
-  // Create block mapping array.
+
-  std::vector<int64_t> block_mapping_vec;
+  // block_mapping is a 2D tensor with shape (num_pairs, 2).
-  for (const auto& pair : block_mapping) {
+  int num_pairs = block_mapping.size(0);
    int64_t src_block_number = pair.first;
    for (int64_t dst_block_number : pair.second) {
      block_mapping_vec.push_back(src_block_number);
      block_mapping_vec.push_back(dst_block_number);
    }
  }
  int64_t* block_mapping_array = block_mapping_vec.data();
  int num_pairs = block_mapping_vec.size() / 2;
  // Move the data structures to the GPU.
  // NOTE: This synchronizes the CPU and GPU.
-  torch::Tensor key_cache_ptrs_tensor = torch::from_blob(
+  torch::Tensor key_cache_ptrs_tensor =
-    key_cache_ptrs, {num_layers}, torch::kInt64).to(cache_device);
+      torch::from_blob(key_cache_ptrs, {num_layers}, torch::kInt64)
-  torch::Tensor value_cache_ptrs_tensor = torch::from_blob(
+          .to(cache_device);
-    value_cache_ptrs, {num_layers}, torch::kInt64).to(cache_device);
+  torch::Tensor value_cache_ptrs_tensor =
-  torch::Tensor block_mapping_tensor = torch::from_blob(
+      torch::from_blob(value_cache_ptrs, {num_layers}, torch::kInt64)
-    block_mapping_array, {2 * num_pairs}, torch::kInt64).to(cache_device);
+          .to(cache_device);
  // Launch the kernel.
  const int numel_per_block = key_caches[0][0].numel();
@@ -140,30 +139,28 @@ void copy_blocks(
  const at::cuda::OptionalCUDAGuard device_guard(cache_device);
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  VLLM_DISPATCH_FLOATING_AND_BYTE_TYPES(
-    key_caches[0].scalar_type(), "copy_blocks_kernel", ([&] {
+      key_caches[0].scalar_type(), "copy_blocks_kernel", ([&] {
-      vllm::copy_blocks_kernel<scalar_t><<<grid, block, 0, stream>>>(
+        vllm::copy_blocks_kernel<scalar_t><<<grid, block, 0, stream>>>(
-        key_cache_ptrs_tensor.data_ptr<int64_t>(),
+            key_cache_ptrs_tensor.data_ptr<int64_t>(),
-        value_cache_ptrs_tensor.data_ptr<int64_t>(),
+            value_cache_ptrs_tensor.data_ptr<int64_t>(),
-        block_mapping_tensor.data_ptr<int64_t>(),
+            block_mapping.data_ptr<int64_t>(), numel_per_block);
-        numel_per_block);
+      }));
    }));
 }
 namespace vllm {
-template<typename scalar_t, typename cache_t, bool is_fp8_e5m2_kv_cache>
+template <typename scalar_t, typename cache_t, Fp8KVCacheDataType kv_dt>
 __global__ void reshape_and_cache_kernel(
-  const scalar_t* __restrict__ key,           // [num_tokens, num_heads, head_size]
+    const scalar_t* __restrict__ key,    // [num_tokens, num_heads, head_size]
-  const scalar_t* __restrict__ value,         // [num_tokens, num_heads, head_size]
+    const scalar_t* __restrict__ value,  // [num_tokens, num_heads, head_size]
-  cache_t* __restrict__ key_cache,            // [num_blocks, num_heads, head_size/x, block_size, x]
+    cache_t* __restrict__ key_cache,     // [num_blocks, num_heads, head_size/x,
-  cache_t* __restrict__ value_cache,          // [num_blocks, num_heads, head_size, block_size]
+                                         // block_size, x]
-  const int64_t* __restrict__ slot_mapping,   // [num_tokens]
+    cache_t* __restrict__ value_cache,   // [num_blocks, num_heads, head_size,
-  const int key_stride,
+                                         // block_size]
-  const int value_stride,
+    const int64_t* __restrict__ slot_mapping,  // [num_tokens]
-  const int num_heads,
+    const int key_stride, const int value_stride, const int num_heads,
-  const int head_size,
+    const int head_size, const int block_size, const int x,
-  const int block_size,
+    const float kv_scale) {
  const int x) {
  const int64_t token_idx = blockIdx.x;
  const int64_t slot_idx = slot_mapping[token_idx];
  if (slot_idx < 0) {
@@ -184,55 +181,84 @@ __global__ void reshape_and_cache_kernel(
    const int x_idx = head_offset / x;
    const int x_offset = head_offset % x;
-    const int64_t tgt_key_idx = block_idx * num_heads * (head_size / x) * block_size * x
+    const int64_t tgt_key_idx =
-                                + head_idx * (head_size / x) * block_size * x
+        block_idx * num_heads * (head_size / x) * block_size * x +
-                                + x_idx * block_size * x
+        head_idx * (head_size / x) * block_size * x + x_idx * block_size * x +
-                                + block_offset * x
+        block_offset * x + x_offset;
-                                + x_offset;
+    const int64_t tgt_value_idx =
-    const int64_t tgt_value_idx = block_idx * num_heads * head_size * block_size
+        block_idx * num_heads * head_size * block_size +
-                                  + head_idx * head_size * block_size
+        head_idx * head_size * block_size + head_offset * block_size +
-                                  + head_offset * block_size
+        block_offset;
                                  + block_offset;
    scalar_t tgt_key = key[src_key_idx];
    scalar_t tgt_value = value[src_value_idx];
-    if constexpr (is_fp8_e5m2_kv_cache) {
+    if constexpr (kv_dt == Fp8KVCacheDataType::kAuto) {
 #ifdef ENABLE_FP8_E5M2
      key_cache[tgt_key_idx] = fp8_e5m2_unscaled::vec_conversion<uint8_t, scalar_t>(tgt_key);
      value_cache[tgt_value_idx] = fp8_e5m2_unscaled::vec_conversion<uint8_t, scalar_t>(tgt_value);
 #else
      assert(false);
 #endif
    } else {
      key_cache[tgt_key_idx] = tgt_key;
      value_cache[tgt_value_idx] = tgt_value;
    } else {
      key_cache[tgt_key_idx] =
          fp8::scaled_convert<cache_t, scalar_t, kv_dt>(tgt_key, kv_scale);
      value_cache[tgt_value_idx] =
          fp8::scaled_convert<cache_t, scalar_t, kv_dt>(tgt_value, kv_scale);
    }
  }
 }
-} // namespace vllm
+template <typename scalar_t>
 __global__ void reshape_and_cache_flash_kernel(
    const scalar_t* __restrict__ key,    // [num_tokens, num_heads, head_size]
    const scalar_t* __restrict__ value,  // [num_tokens, num_heads, head_size]
    scalar_t* __restrict__ k_cache,      // [num_blocks, block_size, num_heads,
                                         // head_size]
    scalar_t* __restrict__ v_cache,      // [num_blocks, block_size, num_heads,
                                         // head_size]
    const int64_t* __restrict__ slot_mapping,  // [num_tokens]
    const int block_stride, const int key_stride, const int value_stride,
    const int num_heads, const int head_size, const int block_size) {
  const int64_t token_idx = blockIdx.x;
  const int64_t slot_idx = slot_mapping[token_idx];
  // NOTE: slot_idx can be -1 if the token is padded
  if (slot_idx < 0) {
    return;
  }
  const int64_t block_idx = slot_idx / block_size;
  const int64_t block_offset = slot_idx % block_size;
  const int n = num_heads * head_size;
  for (int i = threadIdx.x; i < n; i += blockDim.x) {
    const int64_t src_key_idx = token_idx * key_stride + i;
    const int64_t src_value_idx = token_idx * value_stride + i;
    const int head_idx = i / head_size;
    const int head_offset = i % head_size;
    const int64_t tgt_value_idx = block_idx * block_stride +
                                  block_offset * num_heads * head_size +
                                  head_idx * head_size + head_offset;
    k_cache[tgt_value_idx] = key[src_key_idx];
    v_cache[tgt_value_idx] = value[src_value_idx];
  }
 }
 }  // namespace vllm
-#define CALL_RESHAPE_AND_CACHE(KV_T, CACHE_T, IS_FP8_E5M2_KV_CACHE)                                \
+// KV_T is the stored data type of kv-cache.
-  vllm::reshape_and_cache_kernel<KV_T, CACHE_T, IS_FP8_E5M2_KV_CACHE><<<grid, block, 0, stream>>>( \
+// CACHE_T is the data type of key and value tensors.
-    reinterpret_cast<KV_T*>(key.data_ptr()),                                                       \
+// KV_DTYPE is the real data type of kv-cache.
-    reinterpret_cast<KV_T*>(value.data_ptr()),                                                     \
+#define CALL_RESHAPE_AND_CACHE(KV_T, CACHE_T, KV_DTYPE)               \
-    reinterpret_cast<CACHE_T*>(key_cache.data_ptr()),                                              \
+  vllm::reshape_and_cache_kernel<KV_T, CACHE_T, KV_DTYPE>             \
-    reinterpret_cast<CACHE_T*>(value_cache.data_ptr()),                                            \
+      <<<grid, block, 0, stream>>>(                                   \
-    slot_mapping.data_ptr<int64_t>(),                                                              \
+          reinterpret_cast<KV_T*>(key.data_ptr()),                    \
-    key_stride,                                                                                    \
+          reinterpret_cast<KV_T*>(value.data_ptr()),                  \
-    value_stride,                                                                                  \
+          reinterpret_cast<CACHE_T*>(key_cache.data_ptr()),           \
-    num_heads,                                                                                     \
+          reinterpret_cast<CACHE_T*>(value_cache.data_ptr()),         \
-    head_size,                                                                                     \
+          slot_mapping.data_ptr<int64_t>(), key_stride, value_stride, \
-    block_size,                                                                                    \
+          num_heads, head_size, block_size, x, kv_scale);
    x);
 void reshape_and_cache(
-  torch::Tensor& key,           // [num_tokens, num_heads, head_size]
+    torch::Tensor& key,    // [num_tokens, num_heads, head_size]
-  torch::Tensor& value,         // [num_tokens, num_heads, head_size]
+    torch::Tensor& value,  // [num_tokens, num_heads, head_size]
-  torch::Tensor& key_cache,     // [num_blocks, num_heads, head_size/x, block_size, x]
+    torch::Tensor&
-  torch::Tensor& value_cache,   // [num_blocks, num_heads, head_size, block_size]
+        key_cache,  // [num_blocks, num_heads, head_size/x, block_size, x]
-  torch::Tensor& slot_mapping,  // [num_tokens]
+    torch::Tensor&
-  const std::string& kv_cache_dtype)
+        value_cache,  // [num_blocks, num_heads, head_size, block_size]
-{
+    torch::Tensor& slot_mapping,  // [num_tokens]
    const std::string& kv_cache_dtype, const double kv_scale) {
  int num_tokens = key.size(0);
  int num_heads = key.size(1);
  int head_size = key.size(2);
@@ -246,57 +272,80 @@ void reshape_and_cache(
  dim3 block(std::min(num_heads * head_size, 512));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(key));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  if (kv_cache_dtype == "auto") {
+
-    if (key.dtype() == at::ScalarType::Float) {
+  DISPATCH_BY_KV_CACHE_DTYPE(key.dtype(), kv_cache_dtype,
-      CALL_RESHAPE_AND_CACHE(float, float, false);
+                             CALL_RESHAPE_AND_CACHE)
-    } else if (key.dtype() == at::ScalarType::Half) {
+}
-      CALL_RESHAPE_AND_CACHE(uint16_t, uint16_t, false);
+
-    } else if (key.dtype() == at::ScalarType::BFloat16) {
+void reshape_and_cache_flash(
-      CALL_RESHAPE_AND_CACHE(__nv_bfloat16, __nv_bfloat16, false);
+    torch::Tensor& key,      // [num_tokens, num_heads, head_size]
-    }
+    torch::Tensor& value,    // [num_tokens, num_heads, head_size]
-  } else if (kv_cache_dtype == "fp8_e5m2") {
+    torch::Tensor& k_cache,  // [num_blocks, block_size, num_heads, head_size]
-    if (key.dtype() == at::ScalarType::Float) {
+    torch::Tensor& v_cache,  // [num_blocks, block_size, num_heads, head_size]
-      CALL_RESHAPE_AND_CACHE(float, uint8_t, true);
+    torch::Tensor& slot_mapping,  // [num_tokens]
-    } else if (key.dtype() == at::ScalarType::Half) {
+    const std::string& kv_cache_dtype) {
-      CALL_RESHAPE_AND_CACHE(uint16_t, uint8_t, true);
+  // FIXME: only support auto datatype, does not support fp8
-    } else if (key.dtype() == at::ScalarType::BFloat16) {
+  if (kv_cache_dtype != "auto") {
      CALL_RESHAPE_AND_CACHE(__nv_bfloat16, uint8_t, true);
    }
  } else {
    TORCH_CHECK(false, "Unsupported data type of kv cache: ", kv_cache_dtype);
  }
  int num_tokens = key.size(0);
  int num_heads = key.size(1);
  int head_size = key.size(2);
  int block_size = k_cache.size(1);
  int key_stride = key.stride(0);
  int value_stride = value.stride(0);
  int block_stride = k_cache.stride(0);
  TORCH_CHECK(k_cache.stride(0) == v_cache.stride(0));
  dim3 grid(num_tokens);
  dim3 block(std::min(num_heads * head_size, 512));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(key));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  VLLM_DISPATCH_FLOATING_TYPES(
      key.scalar_type(), "reshape_and_cache_flash", [&] {
        vllm::reshape_and_cache_flash_kernel<scalar_t>
            <<<grid, block, 0, stream>>>(
                key.data_ptr<scalar_t>(), value.data_ptr<scalar_t>(),
                k_cache.data_ptr<scalar_t>(), v_cache.data_ptr<scalar_t>(),
                slot_mapping.data_ptr<int64_t>(), block_stride, key_stride,
                value_stride, num_heads, head_size, block_size);
      });
 }
 namespace vllm {
-template<typename Tout, typename Tin>
+template <typename Tout, typename Tin, Fp8KVCacheDataType kv_dt>
-__global__ void convert_fp8_e5m2_kernel(
+__global__ void convert_fp8_kernel(const Tin* __restrict__ src_cache,
-  const Tin* __restrict__ src_cache,
+                                   Tout* __restrict__ dst_cache,
-  Tout* __restrict__ dst_cache,
+                                   const float kv_scale,
-  const int64_t block_stride) {
+                                   const int64_t block_stride) {
  const int64_t block_idx = blockIdx.x;
  for (int i = threadIdx.x; i < block_stride; i += blockDim.x) {
    int64_t idx = block_idx * block_stride + i;
-#ifdef ENABLE_FP8_E5M2
+    dst_cache[idx] =
-    dst_cache[idx] = fp8_e5m2_unscaled::vec_conversion<Tout, Tin>(src_cache[idx]);
+        fp8::scaled_convert<Tout, Tin, kv_dt>(src_cache[idx], kv_scale);
 #else
    assert(false);
 #endif
  }
 }
-} // namespace vllm
+}  // namespace vllm
-#define CALL_CONVERT_FP8_E5M2(Tout, Tin)                                 \
+#define CALL_CONVERT_FP8(Tout, Tin, KV_DTYPE)                                \
-  vllm::convert_fp8_e5m2_kernel<Tout, Tin><<<grid, block, 0, stream>>>(  \
+  vllm::convert_fp8_kernel<Tout, Tin, KV_DTYPE><<<grid, block, 0, stream>>>( \
-    reinterpret_cast<Tin*>(src_cache.data_ptr()),                        \
+      reinterpret_cast<Tin*>(src_cache.data_ptr()),                          \
-    reinterpret_cast<Tout*>(dst_cache.data_ptr()),                       \
+      reinterpret_cast<Tout*>(dst_cache.data_ptr()), kv_scale, block_stride);
-    block_stride);
+
 // Only for testing.
 void convert_fp8(torch::Tensor& dst_cache, torch::Tensor& src_cache,
                 const double kv_scale, const std::string& kv_cache_dtype) {
  torch::Device src_device = src_cache.device();
  torch::Device dst_device = dst_cache.device();
  TORCH_CHECK(src_device.is_cuda(), "src must be on a GPU")
  TORCH_CHECK(dst_device.is_cuda(), "dst must be on a GPU")
  TORCH_CHECK(src_device.index() == dst_device.index(),
              "src and dst must be on the same GPU");
  at::cuda::OptionalCUDAGuard device_guard(src_device);
 void convert_fp8_e5m2(
  torch::Tensor& src_cache,
  torch::Tensor& dst_cache)
 {
  int64_t num_blocks = src_cache.size(0);
  int64_t block_stride = src_cache.stride(0);
@@ -304,17 +353,37 @@ void convert_fp8_e5m2(
  dim3 block(std::min(block_stride, int64_t(512)));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  if (src_cache.dtype() == at::ScalarType::Float) {
+  if (kv_cache_dtype == "auto") {
-    CALL_CONVERT_FP8_E5M2(uint8_t, float);
+    if (src_cache.dtype() == at::ScalarType::Float) {
-  } else if (src_cache.dtype() == at::ScalarType::Half) {
+      CALL_CONVERT_FP8(uint8_t, float, vllm::Fp8KVCacheDataType::kAuto);
-    CALL_CONVERT_FP8_E5M2(uint8_t, uint16_t);
+    } else if (src_cache.dtype() == at::ScalarType::Half) {
-  } else if (src_cache.dtype() == at::ScalarType::BFloat16) {
+      CALL_CONVERT_FP8(uint8_t, uint16_t, vllm::Fp8KVCacheDataType::kAuto);
-    CALL_CONVERT_FP8_E5M2(uint8_t, __nv_bfloat16);
+    } else if (src_cache.dtype() == at::ScalarType::BFloat16) {
-  } else if (dst_cache.dtype() == at::ScalarType::Float) {
+      CALL_CONVERT_FP8(uint8_t, __nv_bfloat16, vllm::Fp8KVCacheDataType::kAuto);
-    CALL_CONVERT_FP8_E5M2(float, uint8_t);
+    } else if (dst_cache.dtype() == at::ScalarType::Float) {
-  } else if (dst_cache.dtype() == at::ScalarType::Half) {
+      CALL_CONVERT_FP8(float, uint8_t, vllm::Fp8KVCacheDataType::kAuto);
-    CALL_CONVERT_FP8_E5M2(uint16_t, uint8_t);
+    } else if (dst_cache.dtype() == at::ScalarType::Half) {
-  } else if (dst_cache.dtype() == at::ScalarType::BFloat16) {
+      CALL_CONVERT_FP8(uint16_t, uint8_t, vllm::Fp8KVCacheDataType::kAuto);
-    CALL_CONVERT_FP8_E5M2(__nv_bfloat16, uint8_t);
+    } else if (dst_cache.dtype() == at::ScalarType::BFloat16) {
      CALL_CONVERT_FP8(__nv_bfloat16, uint8_t, vllm::Fp8KVCacheDataType::kAuto);
    }
  } else if (kv_cache_dtype == "fp8" || kv_cache_dtype == "fp8_e4m3") {
    if (src_cache.dtype() == at::ScalarType::Float) {
      CALL_CONVERT_FP8(uint8_t, float, vllm::Fp8KVCacheDataType::kFp8E4M3);
    } else if (src_cache.dtype() == at::ScalarType::Half) {
      CALL_CONVERT_FP8(uint8_t, uint16_t, vllm::Fp8KVCacheDataType::kFp8E4M3);
    } else if (src_cache.dtype() == at::ScalarType::BFloat16) {
      CALL_CONVERT_FP8(uint8_t, __nv_bfloat16,
                       vllm::Fp8KVCacheDataType::kFp8E4M3);
    } else if (dst_cache.dtype() == at::ScalarType::Float) {
      CALL_CONVERT_FP8(float, uint8_t, vllm::Fp8KVCacheDataType::kFp8E4M3);
    } else if (dst_cache.dtype() == at::ScalarType::Half) {
      CALL_CONVERT_FP8(uint16_t, uint8_t, vllm::Fp8KVCacheDataType::kFp8E4M3);
    } else if (dst_cache.dtype() == at::ScalarType::BFloat16) {
      CALL_CONVERT_FP8(__nv_bfloat16, uint8_t,
                       vllm::Fp8KVCacheDataType::kFp8E4M3);
    }
  } else {
    TORCH_CHECK(false, "Unsupported data type: ", kv_cache_dtype);
  }
 }
--- a/csrc/cpu/activation.cpp
+++ b/csrc/cpu/activation.cpp
@@ -0,0 +1,144 @@
 #include "cpu_types.hpp"
 namespace {
 template <typename scalar_t, vec_op::FP32Vec8 (*func)(const vec_op::FP32Vec8&),
          bool is_gated>
 void activation_kernel(int num_tokens, int d, scalar_t* __restrict__ input,
                       scalar_t* __restrict__ output) {
  using scalar_vec_t = vec_op::vec_t<scalar_t>;
  constexpr int VEC_ELEM_NUM = scalar_vec_t::get_elem_num();
  TORCH_CHECK(d % VEC_ELEM_NUM == 0);
 #pragma omp parallel for
  for (int i = 0; i < num_tokens; ++i) {
    for (int j = 0; j < d; j += VEC_ELEM_NUM) {
      int start = i * d;
      if constexpr (is_gated) {
        start *= 2;
      }
      const scalar_vec_t x(input + start + j);
      const vec_op::FP32Vec8 f32_x(x);
      vec_op::FP32Vec8 f32_ans = func(f32_x);
      if constexpr (is_gated) {
        const scalar_vec_t y(input + start + d + j);
        const vec_op::FP32Vec8 f32_y(y);
        f32_ans = f32_y * f32_ans;
      }
      const scalar_vec_t result(f32_ans);
      result.save(output + i * d + j);
    }
  }
 }
 FORCE_INLINE vec_op::FP32Vec8 silu_act(const vec_op::FP32Vec8& x) {
  const vec_op::FP32Vec8 zeros(0.0);
  const vec_op::FP32Vec8 ones(1.0);
  return x / (ones + (zeros - x).exp());
 }
 FORCE_INLINE vec_op::FP32Vec8 gelu_new_act(const vec_op::FP32Vec8& x) {
  const vec_op::FP32Vec8 ones(1.0);
  const vec_op::FP32Vec8 w1(0.79788456f);
  const vec_op::FP32Vec8 w2(0.044715f);
  const vec_op::FP32Vec8 w3(0.5);
  const vec_op::FP32Vec8 x3 = x * x * x;
  const vec_op::FP32Vec8 t = (w1 * (x + w2 * x3)).tanh();
  return w3 * x * (ones + t);
 }
 FORCE_INLINE vec_op::FP32Vec8 gelu_fast_act(const vec_op::FP32Vec8& x) {
  const vec_op::FP32Vec8 ones(1.0);
  const vec_op::FP32Vec8 w1(0.79788456f);
  const vec_op::FP32Vec8 w2(0.044715f);
  const vec_op::FP32Vec8 w3(0.5);
  const vec_op::FP32Vec8 t = (x * w1 * (ones + x * w2 * x)).tanh();
  return w3 * x * (ones + t);
 }
 FORCE_INLINE vec_op::FP32Vec8 gelu_act(const vec_op::FP32Vec8& x) {
  const vec_op::FP32Vec8 ones(1.0);
  const vec_op::FP32Vec8 w1(M_SQRT1_2);
  const vec_op::FP32Vec8 w2(0.5);
  return x * w2 * (ones + (x * w1).er());
 }
 FORCE_INLINE vec_op::FP32Vec8 gelu_tanh_act(const vec_op::FP32Vec8& x) {
  const vec_op::FP32Vec8 ones(1.0);
  const vec_op::FP32Vec8 w1(M_SQRT2 * M_2_SQRTPI * 0.5);
  const vec_op::FP32Vec8 w2(0.5);
  const vec_op::FP32Vec8 w3(0.044715);
  const vec_op::FP32Vec8 x_3 = x * x * x;
  const vec_op::FP32Vec8 inner = w1 * (x + x_3 * w3);
  return x * w2 * (ones + inner.tanh());
 }
 };  // namespace
 void silu_and_mul(torch::Tensor& out, torch::Tensor& input) {
  int num_tokens = input.numel() / input.size(-1);
  int d = input.size(-1) / 2;
  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "silu_and_mul_impl", [&] {
    CPU_KERNEL_GUARD_IN(silu_and_mul_impl)
    activation_kernel<scalar_t, silu_act, true>(
        num_tokens, d, input.data_ptr<scalar_t>(), out.data_ptr<scalar_t>());
    CPU_KERNEL_GUARD_OUT(silu_and_mul_impl)
  });
 }
 void gelu_and_mul(torch::Tensor& out,    // [..., d]
                  torch::Tensor& input)  // [..., 2 * d]
 {
  int num_tokens = input.numel() / input.size(-1);
  int d = input.size(-1) / 2;
  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "gelu_and_mul_impl", [&] {
    CPU_KERNEL_GUARD_IN(gelu_and_mul_impl)
    activation_kernel<scalar_t, gelu_act, true>(
        num_tokens, d, input.data_ptr<scalar_t>(), out.data_ptr<scalar_t>());
    CPU_KERNEL_GUARD_OUT(gelu_and_mul_impl)
  });
 }
 void gelu_tanh_and_mul(torch::Tensor& out,    // [..., d]
                       torch::Tensor& input)  // [..., 2 * d]
 {
  int num_tokens = input.numel() / input.size(-1);
  int d = input.size(-1) / 2;
  VLLM_DISPATCH_FLOATING_TYPES(
      input.scalar_type(), "gelu_tanh_and_mul_impl", [&] {
        CPU_KERNEL_GUARD_IN(gelu_tanh_and_mul_impl)
        activation_kernel<scalar_t, gelu_tanh_act, true>(
            num_tokens, d, input.data_ptr<scalar_t>(),
            out.data_ptr<scalar_t>());
        CPU_KERNEL_GUARD_OUT(gelu_tanh_and_mul_impl)
      });
 }
 void gelu_new(torch::Tensor& out, torch::Tensor& input) {
  int num_tokens = input.numel() / input.size(-1);
  int d = input.size(-1);
  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "gelu_new_impl", [&] {
    CPU_KERNEL_GUARD_IN(gelu_new_impl)
    activation_kernel<scalar_t, gelu_new_act, false>(
        num_tokens, d, input.data_ptr<scalar_t>(), out.data_ptr<scalar_t>());
    CPU_KERNEL_GUARD_OUT(gelu_new_impl)
  });
 }
 void gelu_fast(torch::Tensor& out, torch::Tensor& input) {
  int num_tokens = input.numel() / input.size(-1);
  int d = input.size(-1);
  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "gelu_fast_impl", [&] {
    CPU_KERNEL_GUARD_IN(gelu_fast_impl)
    activation_kernel<scalar_t, gelu_fast_act, false>(
        num_tokens, d, input.data_ptr<scalar_t>(), out.data_ptr<scalar_t>());
    CPU_KERNEL_GUARD_OUT(gelu_fast_impl)
  });
 }
--- a/csrc/cpu/attention.cpp
+++ b/csrc/cpu/attention.cpp
@@ -0,0 +1,758 @@
 #include "cpu_types.hpp"
 namespace {
 template <typename scalar_t>
 struct KernelVecType {
  using q_load_vec_type = void;
  using q_vec_type = void;
  using k_load_vec_type = void;
  using k_vec_type = void;
  using qk_acc_vec_type = void;
  using v_load_vec_type = void;
 };
 template <>
 struct KernelVecType<float> {
  using q_load_vec_type = vec_op::FP32Vec4;
  using q_vec_type = vec_op::FP32Vec16;
  using k_load_vec_type = vec_op::FP32Vec16;
  using k_vec_type = vec_op::FP32Vec16;
  using qk_acc_vec_type = vec_op::FP32Vec16;
  using v_load_vec_type = vec_op::FP32Vec16;
 };
 #ifdef __AVX512BF16__
 template <>
 struct KernelVecType<c10::BFloat16> {
  using q_load_vec_type = vec_op::BF16Vec8;
  using q_vec_type = vec_op::BF16Vec32;
  using k_load_vec_type = vec_op::BF16Vec32;
  using k_vec_type = vec_op::BF16Vec32;
  using qk_acc_vec_type = vec_op::FP32Vec16;
  using v_load_vec_type = vec_op::BF16Vec16;
 };
 #else
 template <>
 struct KernelVecType<c10::BFloat16> {
  using q_load_vec_type = vec_op::BF16Vec8;
  using q_vec_type = vec_op::FP32Vec16;
  using k_load_vec_type = vec_op::BF16Vec16;
  using k_vec_type = vec_op::FP32Vec16;
  using qk_acc_vec_type = vec_op::FP32Vec16;
  using v_load_vec_type = vec_op::BF16Vec16;
 };
 #endif
 template <typename T>
 FORCE_INLINE std::pair<T, T> reduceSoftmax(T* data, const int size,
                                           const int capacity) {
  T max = data[0];
  for (int i = 1; i < size; ++i) {
    max = max >= data[i] ? max : data[i];
  }
  T sum = 0;
  for (int i = 0; i < size; ++i) {
    data[i] = std::exp(data[i] - max);
    sum += data[i];
  }
  int i = 0;
  for (; i < size; ++i) {
    data[i] /= sum;
  }
  for (; i < capacity; ++i) {
    data[i] = 0;
  }
  return {max, sum};
 }
 template <typename T>
 FORCE_INLINE std::pair<T, T> reduceSoftmaxAlibi(T* data, const int size,
                                                const int capacity,
                                                const float alibi_slope,
                                                const int start_index,
                                                const int seq_len) {
  data[0] += alibi_slope * (start_index - seq_len + 1);
  T max = data[0];
  for (int i = 1; i < size; ++i) {
    T qk = data[i] + alibi_slope * (start_index + i - seq_len + 1);
    data[i] = qk;
    max = max >= qk ? max : qk;
  }
  T sum = 0;
  for (int i = 0; i < size; ++i) {
    data[i] = std::exp(data[i] - max);
    sum += data[i];
  }
  int i = 0;
  for (; i < size; ++i) {
    data[i] /= sum;
  }
  for (; i < capacity; ++i) {
    data[i] = 0;
  }
  return {max, sum};
 }
 template <typename T>
 FORCE_INLINE void reducePartitonSoftmax(const T* max_data, T* sum_data,
                                        const int size) {
  T max = max_data[0];
  for (int i = 1; i < size; ++i) {
    max = max >= max_data[i] ? max : max_data[i];
  }
  T rescaled_sum = 0;
  for (int i = 0; i < size; ++i) {
    T rescale_factor = std::exp(max_data[i] - max);
    rescaled_sum += rescale_factor * sum_data[i];
    sum_data[i] *= rescale_factor;
  }
  for (int i = 0; i < size; ++i) {
    sum_data[i] /= rescaled_sum + 1e-8;
  }
 }
 template <typename scalar_t, int HEAD_SIZE, int BLOCK_SIZE, int x>
 struct reduceQKBlockKernel {
  using q_load_vec_type = typename KernelVecType<scalar_t>::q_load_vec_type;
  using q_vec_type = typename KernelVecType<scalar_t>::q_vec_type;
  using k_load_vec_type = typename KernelVecType<scalar_t>::k_load_vec_type;
  using k_vec_type = typename KernelVecType<scalar_t>::k_vec_type;
  using qk_acc_vec_type = typename KernelVecType<scalar_t>::qk_acc_vec_type;
  constexpr static int TOKEN_PER_GROUP = k_load_vec_type::get_elem_num() / x;
  constexpr static int MAX_GROUP_NUM = 16 / TOKEN_PER_GROUP;
  constexpr static int UNROLL_GROUP_NUM = MAX_GROUP_NUM / 4;
  static_assert(MAX_GROUP_NUM == 8 || MAX_GROUP_NUM == 4);
  static_assert(k_load_vec_type::get_elem_num() % x == 0);
  static_assert(q_load_vec_type::get_elem_num() * sizeof(scalar_t) == 16);
  FORCE_INLINE static void call(const scalar_t* __restrict__ q,
                                const scalar_t* __restrict__ k_block,
                                float* __restrict__ logits, float scale,
                                const int token_num) {
    const int group_num = (token_num + TOKEN_PER_GROUP - 1) / TOKEN_PER_GROUP;
    qk_acc_vec_type group_accums[MAX_GROUP_NUM];
    if (token_num == BLOCK_SIZE) {
      for (int q_offset = 0; q_offset < HEAD_SIZE;
           q_offset += x, k_block += x * BLOCK_SIZE) {
        q_load_vec_type q_load_group_vec(q + q_offset);
        q_vec_type q_group_vec(q_load_group_vec);
        vec_op::unroll_loop<int, MAX_GROUP_NUM>(
            [k_block, &q_group_vec, &group_accums](int token_group_idx) {
              k_load_vec_type k_load_group_vec(k_block + token_group_idx * x *
                                                             TOKEN_PER_GROUP);
              k_vec_type k_group_vec(k_load_group_vec);
              vec_op::fma(group_accums[token_group_idx], q_group_vec,
                          k_group_vec);
              vec_op::prefetch(k_block + x * BLOCK_SIZE +
                               token_group_idx * x * TOKEN_PER_GROUP);
            });
      }
    } else {
      for (int q_offset = 0; q_offset < HEAD_SIZE;
           q_offset += x, k_block += x * BLOCK_SIZE) {
        q_load_vec_type q_load_group_vec(q + q_offset);
        q_vec_type q_group_vec(q_load_group_vec);
        for (int token_group_start = 0; token_group_start < group_num;
             token_group_start += UNROLL_GROUP_NUM) {
          vec_op::unroll_loop<int, UNROLL_GROUP_NUM>(
              [token_group_start, k_block, &q_group_vec,
               &group_accums](int token_group_idx) {
                token_group_idx += token_group_start;
                k_load_vec_type k_load_group_vec(k_block + token_group_idx * x *
                                                               TOKEN_PER_GROUP);
                k_vec_type k_group_vec(k_load_group_vec);
                vec_op::fma(group_accums[token_group_idx], q_group_vec,
                            k_group_vec);
                vec_op::prefetch(k_block + x * BLOCK_SIZE +
                                 token_group_idx * x * TOKEN_PER_GROUP);
              });
        }
      }
    }
    for (int token_group_idx = 0; token_group_idx < group_num;
         ++token_group_idx) {
      vec_op::unroll_loop<int, TOKEN_PER_GROUP>(
          [&group_accums, logits, scale, token_group_idx](int token_idx) {
            float dot_v =
                group_accums[token_group_idx]
                    .template reduce_sub_sum<qk_acc_vec_type::get_elem_num() /
                                             TOKEN_PER_GROUP>(token_idx);
            logits[token_group_idx * TOKEN_PER_GROUP + token_idx] =
                dot_v * scale;
          });
    }
  }
 };
 template <typename scalar_t, int HEAD_SIZE, int BLOCK_SIZE,
          int HEAD_PARTITION_SIZE, typename acc_t>
 FORCE_INLINE void reduceValueBlock(const float* prob, const scalar_t* v_block,
                                   acc_t&& acc) {
  using v_load_vec_type = typename KernelVecType<scalar_t>::v_load_vec_type;
  constexpr int ELEM_NUM = v_load_vec_type::get_elem_num();
  static_assert(BLOCK_SIZE == ELEM_NUM);
  vec_op::FP32Vec16 prob_vec(prob);
  vec_op::unroll_loop<int, HEAD_PARTITION_SIZE>([&](int head_elem_idx) {
    v_load_vec_type v_vec(v_block + BLOCK_SIZE * head_elem_idx);
    vec_op::FP32Vec16 fp32_v_vec(v_vec);
    acc[head_elem_idx] = acc[head_elem_idx] + prob_vec * fp32_v_vec;
  });
 }
 };  // namespace
 // Paged attention v1
 namespace {
 template <typename scalar_t, int HEAD_SIZE, int BLOCK_SIZE>
 struct paged_attention_v1_impl {
  static void call(
      scalar_t* __restrict__ out,            // [num_seqs, num_heads, head_size]
      const scalar_t* __restrict__ q,        // [num_seqs, num_heads, head_size]
      const scalar_t* __restrict__ k_cache,  // [num_blocks, num_kv_heads,
                                             // head_size/x, block_size, x]
      const scalar_t* __restrict__ v_cache,  // [num_blocks, num_kv_heads,
                                             // head_size, block_size]
      const int num_kv_heads, const float scale,
      const int* __restrict__ block_tables,  // [num_seqs,
                                             // max_num_blocks_per_seq]
      const int* __restrict__ seq_lens,      // [num_seqs]
      const int max_num_blocks_per_seq,
      const float* __restrict__ alibi_slopes,  // [num_heads]
      const int q_stride, const int kv_block_stride, const int kv_head_stride,
      const int num_seqs, const int num_heads) {
    constexpr int x = 16 / sizeof(scalar_t);
    const int num_queries_per_kv = num_heads / num_kv_heads;
    static_assert(BLOCK_SIZE == 16);
    int max_seq_len = max_num_blocks_per_seq * BLOCK_SIZE;
    int max_seq_len_padded = (max_seq_len + 15) & 0xFFFFFFF0;
    TORCH_CHECK((max_seq_len_padded * sizeof(float)) % 64 == 0);
    const int parallel_work_item_num = omp_get_max_threads();
    size_t logits_bytes =
        parallel_work_item_num * max_seq_len_padded * sizeof(float);
    float* logits = (float*)std::aligned_alloc(
        64, logits_bytes);  // Cacheline alignment for each context token.
                            // [parallel_work_item_num, max_seq_len_padded]
 #pragma omp parallel for collapse(2) schedule(dynamic, 1)
    for (int seq_idx = 0; seq_idx < num_seqs; ++seq_idx) {
      for (int head_idx = 0; head_idx < num_heads; ++head_idx) {
        int seq_len = seq_lens[seq_idx];
        const int* seq_block_table =
            block_tables + max_num_blocks_per_seq * seq_idx;
        const int block_num = (seq_len + BLOCK_SIZE - 1) / BLOCK_SIZE;
        const int64_t kv_head_idx = head_idx / num_queries_per_kv;
        const scalar_t* __restrict__ q_vec_ptr =
            q + seq_idx * q_stride + head_idx * HEAD_SIZE;
        const int last_block_token_num = seq_len - (block_num - 1) * BLOCK_SIZE;
        float* __restrict__ thread_block_logits =
            logits + omp_get_thread_num() * max_seq_len_padded;
        // Compute logits
        for (int block_idx = 0; block_idx < block_num; ++block_idx) {
          const int64_t physical_block_idx = seq_block_table[block_idx];
          const scalar_t* __restrict__ k_block_cache_ptr =
              k_cache + physical_block_idx * kv_block_stride +
              kv_head_idx * kv_head_stride;
          float* __restrict__ head_block_logits =
              thread_block_logits + block_idx * BLOCK_SIZE;
          reduceQKBlockKernel<scalar_t, HEAD_SIZE, BLOCK_SIZE, x>::call(
              q_vec_ptr, k_block_cache_ptr, head_block_logits, scale,
              block_idx == block_num - 1 ? last_block_token_num : BLOCK_SIZE);
        }
        // Compute softmax
        if (alibi_slopes) {
          reduceSoftmaxAlibi(thread_block_logits, seq_len,
                             block_num * BLOCK_SIZE, alibi_slopes[head_idx], 0,
                             seq_len);
        } else {
          reduceSoftmax(thread_block_logits, seq_len, block_num * BLOCK_SIZE);
        }
        // Compute value
        constexpr int head_elem_num_per_partition = 16;
        constexpr int head_partition_num =
            HEAD_SIZE / head_elem_num_per_partition;
        for (int head_part_idx = 0; head_part_idx < head_partition_num;
             ++head_part_idx) {
          vec_op::FP32Vec16 accums[head_elem_num_per_partition];
          scalar_t* __restrict__ out_ptr =
              out + seq_idx * num_heads * HEAD_SIZE + head_idx * HEAD_SIZE +
              head_part_idx * head_elem_num_per_partition;
          for (int block_idx = 0; block_idx < block_num; ++block_idx) {
            const int64_t physical_block_idx = seq_block_table[block_idx];
            const float* __restrict__ prob_vec_ptr =
                thread_block_logits + block_idx * BLOCK_SIZE;
            const scalar_t* __restrict__ v_block_cache_ptr =
                v_cache + physical_block_idx * kv_block_stride +
                kv_head_idx * kv_head_stride +
                BLOCK_SIZE * head_part_idx * head_elem_num_per_partition;
            reduceValueBlock<scalar_t, HEAD_SIZE, BLOCK_SIZE,
                             head_elem_num_per_partition>(
                prob_vec_ptr, v_block_cache_ptr, accums);
            if (block_idx != block_num - 1) {
              const int64_t next_physical_block_idx =
                  seq_block_table[block_idx + 1];
              const scalar_t* __restrict__ next_v_block_cache_ptr =
                  v_cache + next_physical_block_idx * kv_block_stride +
                  kv_head_idx * kv_head_stride +
                  BLOCK_SIZE * head_part_idx * head_elem_num_per_partition;
              vec_op::unroll_loop<int, head_elem_num_per_partition>(
                  [&](int head_elem_idx) {
                    if (head_elem_idx % 2 == 0) {
                      vec_op::prefetch(next_v_block_cache_ptr +
                                       BLOCK_SIZE * head_elem_idx);
                    }
                  });
            }
          }
          vec_op::unroll_loop<int, head_elem_num_per_partition>(
              [&](int head_elem_idx) {
                float value = accums[head_elem_idx].reduce_sum();
                vec_op::storeFP32(value, out_ptr + head_elem_idx);
              });
        }
      }
    }
    std::free(logits);
  }
 };
 #define LAUNCH_V1_ATTENTION_KERNEL(T, HEAD_SIZE, BLOCK_SIZE)                   \
  paged_attention_v1_impl<T, HEAD_SIZE, BLOCK_SIZE>::call(                     \
      out_ptr, query_ptr, key_cache_ptr, value_cache_ptr, num_kv_heads, scale, \
      block_tables_ptr, seq_lens_ptr, max_num_blocks_per_seq,                  \
      alibi_slopes_ptr, q_stride, kv_block_stride, kv_head_stride, num_seqs,   \
      num_heads);
 template <typename T, int BLOCK_SIZE>
 void paged_attention_v1_impl_launcher(
    torch::Tensor& out, torch::Tensor& query, torch::Tensor& key_cache,
    torch::Tensor& value_cache, int num_kv_heads, float scale,
    torch::Tensor& block_tables, torch::Tensor& seq_lens, int max_seq_len,
    const c10::optional<torch::Tensor>& alibi_slopes) {
  int num_seqs = query.size(0);
  int num_heads = query.size(1);
  int head_size = query.size(2);
  int max_num_blocks_per_seq = block_tables.size(1);
  int q_stride = query.stride(0);
  int kv_block_stride = key_cache.stride(0);
  int kv_head_stride = key_cache.stride(1);
  // NOTE: alibi_slopes is optional.
  const float* alibi_slopes_ptr =
      alibi_slopes
          ? reinterpret_cast<const float*>(alibi_slopes.value().data_ptr())
          : nullptr;
  T* out_ptr = reinterpret_cast<T*>(out.data_ptr());
  T* query_ptr = reinterpret_cast<T*>(query.data_ptr());
  T* key_cache_ptr = reinterpret_cast<T*>(key_cache.data_ptr());
  T* value_cache_ptr = reinterpret_cast<T*>(value_cache.data_ptr());
  int* block_tables_ptr = block_tables.data_ptr<int>();
  int* seq_lens_ptr = seq_lens.data_ptr<int>();
  switch (head_size) {
    case 64:
      LAUNCH_V1_ATTENTION_KERNEL(T, 64, BLOCK_SIZE);
      break;
    case 80:
      LAUNCH_V1_ATTENTION_KERNEL(T, 80, BLOCK_SIZE);
      break;
    case 96:
      LAUNCH_V1_ATTENTION_KERNEL(T, 96, BLOCK_SIZE);
      break;
    case 112:
      LAUNCH_V1_ATTENTION_KERNEL(T, 112, BLOCK_SIZE);
      break;
    case 128:
      LAUNCH_V1_ATTENTION_KERNEL(T, 128, BLOCK_SIZE);
      break;
    case 192:
      LAUNCH_V1_ATTENTION_KERNEL(T, 192, BLOCK_SIZE);
      break;
    case 256:
      LAUNCH_V1_ATTENTION_KERNEL(T, 256, BLOCK_SIZE);
      break;
    default:
      TORCH_CHECK(false, "Unsupported head size: ", head_size);
      break;
  }
 }
 #define CALL_V1_KERNEL_LAUNCHER(T, BLOCK_SIZE)                               \
  paged_attention_v1_impl_launcher<T, BLOCK_SIZE>(                           \
      out, query, key_cache, value_cache, num_kv_heads, scale, block_tables, \
      seq_lens, max_seq_len, alibi_slopes);
 #define CALL_V1_KERNEL_LAUNCHER_BLOCK_SIZE(T)                     \
  switch (block_size) {                                           \
    case 16:                                                      \
      CALL_V1_KERNEL_LAUNCHER(T, 16);                             \
      break;                                                      \
    default:                                                      \
      TORCH_CHECK(false, "Unsupported block size: ", block_size); \
      break;                                                      \
  }
 }  // namespace
 void paged_attention_v1(
    torch::Tensor& out, torch::Tensor& query, torch::Tensor& key_cache,
    torch::Tensor& value_cache, int64_t num_kv_heads, double scale,
    torch::Tensor& block_tables, torch::Tensor& seq_lens, int64_t block_size,
    int64_t max_seq_len, const c10::optional<torch::Tensor>& alibi_slopes,
    const std::string& kv_cache_dtype, double kv_scale, const int64_t tp_rank,
    const int64_t blocksparse_local_blocks,
    const int64_t blocksparse_vert_stride, const int64_t blocksparse_block_size,
    const int64_t blocksparse_head_sliding_step) {
  TORCH_CHECK(kv_scale == 1.0f);
  TORCH_CHECK(blocksparse_vert_stride <= 1,
              "CPU backend does not support blocksparse attention yet.");
  VLLM_DISPATCH_FLOATING_TYPES(query.scalar_type(), "paged_attention_v1_impl",
                               [&] {
                                 CPU_KERNEL_GUARD_IN(paged_attention_v1_impl)
                                 CALL_V1_KERNEL_LAUNCHER_BLOCK_SIZE(scalar_t);
                                 CPU_KERNEL_GUARD_OUT(paged_attention_v1_impl)
                               });
 }
 // Paged attention v2
 namespace {
 template <typename scalar_t, int HEAD_SIZE, int BLOCK_SIZE, int PARTITION_SIZE>
 struct paged_attention_v2_impl {
  static void call(
      scalar_t* __restrict__ out,            // [num_seqs, num_heads, head_size]
      float* __restrict__ exp_sums,          // [num_seqs, num_heads,
                                             // max_num_partitions]
      float* __restrict__ max_logits,        // [num_seqs, num_heads,
                                             // max_num_partitions]
      scalar_t* __restrict__ tmp_out,        // [num_seqs, num_heads,
                                             // max_num_partitions, head_size]
      const scalar_t* __restrict__ q,        // [num_seqs, num_heads, head_size]
      const scalar_t* __restrict__ k_cache,  // [num_blocks, num_kv_heads,
                                             // head_size/x, block_size, x]
      const scalar_t* __restrict__ v_cache,  // [num_blocks, num_kv_heads,
                                             // head_size, block_size]
      const int num_kv_heads, const float scale,
      const int* __restrict__ block_tables,  // [num_seqs,
                                             // max_num_blocks_per_seq]
      const int* __restrict__ seq_lens,      // [num_seqs]
      const int max_num_blocks_per_seq,
      const float* __restrict__ alibi_slopes,  // [num_heads]
      const int q_stride, const int kv_block_stride, const int kv_head_stride,
      const int num_seqs, const int num_heads, const int max_num_partitions) {
    constexpr int x = 16 / sizeof(scalar_t);
    const int num_queries_per_kv = num_heads / num_kv_heads;
    static_assert(BLOCK_SIZE == 16);
    static_assert(PARTITION_SIZE * sizeof(float) % 64 == 0);
    static_assert(PARTITION_SIZE % BLOCK_SIZE == 0);
 #pragma omp parallel for collapse(3) schedule(static, 1)
    for (int seq_idx = 0; seq_idx < num_seqs; ++seq_idx) {
      for (int partition_idx = 0; partition_idx < max_num_partitions;
           ++partition_idx) {
        for (int head_idx = 0; head_idx < num_heads; ++head_idx) {
          const int seq_len = seq_lens[seq_idx];
          const int start_token_idx = partition_idx * PARTITION_SIZE;
          if (start_token_idx >= seq_len) continue;
          const int partition_num =
              (seq_len + PARTITION_SIZE - 1) / PARTITION_SIZE;
          const bool no_reduce = (partition_num == 1);
          const int token_num =
              (std::min(seq_len, start_token_idx + PARTITION_SIZE) -
               start_token_idx);
          const int block_num = (token_num + BLOCK_SIZE - 1) / BLOCK_SIZE;
          const int last_block_token_num =
              token_num - (block_num - 1) * BLOCK_SIZE;
          const int* seq_block_table = block_tables +
                                       max_num_blocks_per_seq * seq_idx +
                                       start_token_idx / BLOCK_SIZE;
          const int64_t kv_head_idx = head_idx / num_queries_per_kv;
          const scalar_t* __restrict__ q_vec_ptr =
              q + seq_idx * q_stride + head_idx * HEAD_SIZE;
          float logits[PARTITION_SIZE] __attribute__((aligned(64))) = {0};
          // Compute logits
          for (int block_idx = 0; block_idx < block_num; ++block_idx) {
            const int64_t physical_block_idx = seq_block_table[block_idx];
            const scalar_t* __restrict__ k_block_cache_ptr =
                k_cache + physical_block_idx * kv_block_stride +
                kv_head_idx * kv_head_stride;
            float* __restrict__ head_block_logits =
                logits + block_idx * BLOCK_SIZE;
            reduceQKBlockKernel<scalar_t, HEAD_SIZE, BLOCK_SIZE, x>::call(
                q_vec_ptr, k_block_cache_ptr, head_block_logits, scale,
                block_idx == block_num - 1 ? last_block_token_num : BLOCK_SIZE);
          }
          std::pair<float, float> max_and_sum;
          if (alibi_slopes) {
            max_and_sum = reduceSoftmaxAlibi(
                logits, token_num, block_num * BLOCK_SIZE,
                alibi_slopes[head_idx], start_token_idx, seq_len);
          } else {
            max_and_sum =
                reduceSoftmax(logits, token_num, block_num * BLOCK_SIZE);
          }
          auto&& [max_logit, exp_sum] = max_and_sum;
          scalar_t* __restrict__ output_buffer = nullptr;
          if (!no_reduce) {
            auto idx = seq_idx * num_heads * max_num_partitions +
                       head_idx * max_num_partitions + partition_idx;
            max_logits[idx] = max_logit;
            exp_sums[idx] = exp_sum;
            output_buffer =
                tmp_out + seq_idx * num_heads * max_num_partitions * HEAD_SIZE +
                head_idx * max_num_partitions * HEAD_SIZE +
                partition_idx * HEAD_SIZE;
          } else {
            output_buffer =
                out + seq_idx * num_heads * HEAD_SIZE + head_idx * HEAD_SIZE;
          }
          // Compute value
          constexpr int head_elem_num_per_partition = 16;
          constexpr int head_partition_num =
              HEAD_SIZE / head_elem_num_per_partition;
          for (int head_part_idx = 0; head_part_idx < head_partition_num;
               ++head_part_idx) {
            vec_op::FP32Vec16 accums[head_elem_num_per_partition];
            scalar_t* __restrict__ out_ptr =
                output_buffer + head_part_idx * head_elem_num_per_partition;
            for (int block_idx = 0; block_idx < block_num; ++block_idx) {
              const int64_t physical_block_idx = seq_block_table[block_idx];
              const float* __restrict__ prob_vec_ptr =
                  logits + block_idx * BLOCK_SIZE;
              const scalar_t* __restrict__ v_block_cache_ptr =
                  v_cache + physical_block_idx * kv_block_stride +
                  kv_head_idx * kv_head_stride +
                  BLOCK_SIZE * head_part_idx * head_elem_num_per_partition;
              reduceValueBlock<scalar_t, HEAD_SIZE, BLOCK_SIZE,
                               head_elem_num_per_partition>(
                  prob_vec_ptr, v_block_cache_ptr, accums);
              if (block_idx != block_num - 1) {
                const int64_t next_physical_block_idx =
                    seq_block_table[block_idx + 1];
                const scalar_t* __restrict__ next_v_block_cache_ptr =
                    v_cache + next_physical_block_idx * kv_block_stride +
                    kv_head_idx * kv_head_stride +
                    BLOCK_SIZE * head_part_idx * head_elem_num_per_partition;
                vec_op::unroll_loop<int, head_elem_num_per_partition>(
                    [&](int head_elem_idx) {
                      if (head_elem_idx % 2 == 0) {
                        vec_op::prefetch(next_v_block_cache_ptr +
                                         BLOCK_SIZE * head_elem_idx);
                      }
                    });
              }
            }
            vec_op::unroll_loop<int, head_elem_num_per_partition>(
                [&](int head_elem_idx) {
                  float value = accums[head_elem_idx].reduce_sum();
                  vec_op::storeFP32(value, out_ptr + head_elem_idx);
                });
          }
        }
      }
    }
    // Rescale partition softmax and store the factors to exp_sums
 #pragma omp parallel for collapse(2) schedule(static, 1)
    for (int seq_idx = 0; seq_idx < num_seqs; ++seq_idx) {
      for (int head_idx = 0; head_idx < num_heads; ++head_idx) {
        const int seq_len = seq_lens[seq_idx];
        const int partition_num =
            (seq_len + PARTITION_SIZE - 1) / PARTITION_SIZE;
        if (partition_num == 1) continue;
        reducePartitonSoftmax(
            max_logits + seq_idx * num_heads * max_num_partitions +
                head_idx * max_num_partitions,
            exp_sums + seq_idx * num_heads * max_num_partitions +
                head_idx * max_num_partitions,
            partition_num);
      }
    }
    // Reduce values
    using v_load_vec_type = typename KernelVecType<scalar_t>::v_load_vec_type;
    static_assert(v_load_vec_type::get_elem_num() == BLOCK_SIZE);
    constexpr int head_elem_num_per_group =
        16;  // Note: didn't align with the cacheline size, due to some
             // HEAD_SIZE didn't align with 64 bytes
    static_assert(HEAD_SIZE % head_elem_num_per_group == 0);
    constexpr int head_group_num = HEAD_SIZE / head_elem_num_per_group;
    const float* __restrict__ rescale_factors = exp_sums;
 #pragma omp parallel for collapse(3) schedule(static, 1)
    for (int seq_idx = 0; seq_idx < num_seqs; ++seq_idx) {
      for (int head_idx = 0; head_idx < num_heads; ++head_idx) {
        for (int group_idx = 0; group_idx < head_group_num; ++group_idx) {
          const int seq_len = seq_lens[seq_idx];
          const int partition_num =
              (seq_len + PARTITION_SIZE - 1) / PARTITION_SIZE;
          if (partition_num == 1) continue;
          const float* __restrict__ seq_head_rescale_factors =
              rescale_factors + seq_idx * num_heads * max_num_partitions +
              head_idx * max_num_partitions;
          const scalar_t* __restrict__ seq_head_tmp_out =
              tmp_out + seq_idx * num_heads * max_num_partitions * HEAD_SIZE +
              head_idx * max_num_partitions * HEAD_SIZE +
              group_idx * head_elem_num_per_group;
          scalar_t* __restrict__ seq_head_output =
              out + seq_idx * num_heads * HEAD_SIZE + head_idx * HEAD_SIZE +
              group_idx * head_elem_num_per_group;
          vec_op::FP32Vec16 acc;
          for (int i = 0; i < partition_num; ++i) {
            vec_op::FP32Vec16 rescale_factor(seq_head_rescale_factors[i]);
            v_load_vec_type value(seq_head_tmp_out + i * HEAD_SIZE);
            vec_op::FP32Vec16 fp32_value(value);
            acc = acc + fp32_value * rescale_factor;
          }
          v_load_vec_type cast_acc(acc);
          cast_acc.save(seq_head_output);
        }
      }
    }
  }
 };
 #define LAUNCH_V2_ATTENTION_KERNEL(T, HEAD_SIZE, BLOCK_SIZE)                 \
  paged_attention_v2_impl<T, HEAD_SIZE, BLOCK_SIZE, PARTITION_SIZE>::call(   \
      out_ptr, exp_sums_ptr, max_logits_ptr, tmp_out_ptr, query_ptr,         \
      key_cache_ptr, value_cache_ptr, num_kv_heads, scale, block_tables_ptr, \
      seq_lens_ptr, max_num_blocks_per_seq, alibi_slopes_ptr, q_stride,      \
      kv_block_stride, kv_head_stride, num_seqs, num_heads,                  \
      max_num_partitions);
 template <typename T, int BLOCK_SIZE, int PARTITION_SIZE = 512>
 void paged_attention_v2_impl_launcher(
    torch::Tensor& out, torch::Tensor& exp_sums, torch::Tensor& max_logits,
    torch::Tensor& tmp_out, torch::Tensor& query, torch::Tensor& key_cache,
    torch::Tensor& value_cache, int num_kv_heads, float scale,
    torch::Tensor& block_tables, torch::Tensor& seq_lens, int block_size,
    int max_seq_len, const c10::optional<torch::Tensor>& alibi_slopes) {
  int num_seqs = query.size(0);
  int num_heads = query.size(1);
  int head_size = query.size(2);
  int max_num_blocks_per_seq = block_tables.size(1);
  int q_stride = query.stride(0);
  int kv_block_stride = key_cache.stride(0);
  int kv_head_stride = key_cache.stride(1);
  int max_num_partitions = exp_sums.size(-1);
  // NOTE: alibi_slopes is optional.
  const float* alibi_slopes_ptr =
      alibi_slopes
          ? reinterpret_cast<const float*>(alibi_slopes.value().data_ptr())
          : nullptr;
  T* out_ptr = reinterpret_cast<T*>(out.data_ptr());
  float* exp_sums_ptr = reinterpret_cast<float*>(exp_sums.data_ptr());
  float* max_logits_ptr = reinterpret_cast<float*>(max_logits.data_ptr());
  T* tmp_out_ptr = reinterpret_cast<T*>(tmp_out.data_ptr());
  T* query_ptr = reinterpret_cast<T*>(query.data_ptr());
  T* key_cache_ptr = reinterpret_cast<T*>(key_cache.data_ptr());
  T* value_cache_ptr = reinterpret_cast<T*>(value_cache.data_ptr());
  int* block_tables_ptr = block_tables.data_ptr<int>();
  int* seq_lens_ptr = seq_lens.data_ptr<int>();
  switch (head_size) {
    case 64:
      LAUNCH_V2_ATTENTION_KERNEL(T, 64, BLOCK_SIZE);
      break;
    case 80:
      LAUNCH_V2_ATTENTION_KERNEL(T, 80, BLOCK_SIZE);
      break;
    case 96:
      LAUNCH_V2_ATTENTION_KERNEL(T, 96, BLOCK_SIZE);
      break;
    case 112:
      LAUNCH_V2_ATTENTION_KERNEL(T, 112, BLOCK_SIZE);
      break;
    case 128:
      LAUNCH_V2_ATTENTION_KERNEL(T, 128, BLOCK_SIZE);
      break;
    case 192:
      LAUNCH_V2_ATTENTION_KERNEL(T, 192, BLOCK_SIZE);
      break;
    case 256:
      LAUNCH_V2_ATTENTION_KERNEL(T, 256, BLOCK_SIZE);
      break;
    default:
      TORCH_CHECK(false, "Unsupported head size: ", head_size);
      break;
  }
 }
 #define CALL_V2_KERNEL_LAUNCHER(T, BLOCK_SIZE)                              \
  paged_attention_v2_impl_launcher<T, BLOCK_SIZE>(                          \
      out, exp_sums, max_logits, tmp_out, query, key_cache, value_cache,    \
      num_kv_heads, scale, block_tables, seq_lens, block_size, max_seq_len, \
      alibi_slopes);
 #define CALL_V2_KERNEL_LAUNCHER_BLOCK_SIZE(T)                     \
  switch (block_size) {                                           \
    case 16:                                                      \
      CALL_V2_KERNEL_LAUNCHER(T, 16);                             \
      break;                                                      \
    default:                                                      \
      TORCH_CHECK(false, "Unsupported block size: ", block_size); \
      break;                                                      \
  }
 }  // namespace
 void paged_attention_v2(
    torch::Tensor& out, torch::Tensor& exp_sums, torch::Tensor& max_logits,
    torch::Tensor& tmp_out, torch::Tensor& query, torch::Tensor& key_cache,
    torch::Tensor& value_cache, int64_t num_kv_heads, double scale,
    torch::Tensor& block_tables, torch::Tensor& seq_lens, int64_t block_size,
    int64_t max_seq_len, const c10::optional<torch::Tensor>& alibi_slopes,
    const std::string& kv_cache_dtype, double kv_scale, const int64_t tp_rank,
    const int64_t blocksparse_local_blocks,
    const int64_t blocksparse_vert_stride, const int64_t blocksparse_block_size,
    const int64_t blocksparse_head_sliding_step) {
  TORCH_CHECK(kv_scale == 1.0f);
  TORCH_CHECK(blocksparse_vert_stride <= 1,
              "CPU backend does not support blocksparse attention yet.");
  VLLM_DISPATCH_FLOATING_TYPES(query.scalar_type(), "paged_attention_v2_impl",
                               [&] {
                                 CPU_KERNEL_GUARD_IN(paged_attention_v2_impl)
                                 CALL_V2_KERNEL_LAUNCHER_BLOCK_SIZE(scalar_t);
                                 CPU_KERNEL_GUARD_OUT(paged_attention_v2_impl)
                               });
 }
--- a/csrc/cpu/cache.cpp
+++ b/csrc/cpu/cache.cpp
@@ -0,0 +1,137 @@
 #include <map>
 #include <vector>
 #include "cpu_types.hpp"
 namespace {
 template <typename scalar_t>
 void copy_blocks_cpu_impl(std::vector<torch::Tensor> const& key_caches,
                          std::vector<torch::Tensor> const& value_caches,
                          const torch::Tensor& mapping_pairs,
                          const int element_num_per_block,
                          const int layer_num) {
  const size_t pair_num = mapping_pairs.size(0);
  const size_t block_bytes = sizeof(scalar_t) * element_num_per_block;
 #pragma omp parallel for collapse(2)
  for (int layer = 0; layer < layer_num; ++layer) {
    for (size_t pair = 0; pair < pair_num; ++pair) {
      int64_t source_offset =
          element_num_per_block * mapping_pairs[pair][0].item<int64_t>();
      int64_t target_offset =
          element_num_per_block * mapping_pairs[pair][1].item<int64_t>();
      scalar_t* key_cache_ptr = key_caches[layer].data_ptr<scalar_t>();
      scalar_t* source_ptr = key_cache_ptr + source_offset;
      scalar_t* target_ptr = key_cache_ptr + target_offset;
      std::memcpy(target_ptr, source_ptr, block_bytes);
      scalar_t* value_cache_ptr = value_caches[layer].data_ptr<scalar_t>();
      source_ptr = value_cache_ptr + source_offset;
      target_ptr = value_cache_ptr + target_offset;
      std::memcpy(target_ptr, source_ptr, block_bytes);
    }
  }
 }
 template <typename scalar_t>
 void reshape_and_cache_cpu_impl(
    const scalar_t* __restrict__ key, const scalar_t* __restrict__ value,
    scalar_t* __restrict__ key_cache, scalar_t* __restrict__ value_cache,
    const int64_t* __restrict__ slot_mapping, const int num_tokens,
    const int key_stride, const int value_stride, const int num_heads,
    const int head_size, const int block_size, const int x) {
  const int block_elem_num = num_heads * head_size * block_size;
 #pragma omp parallel for collapse(2)
  for (int token_idx = 0; token_idx < num_tokens; ++token_idx) {
    for (int head_idx = 0; head_idx < num_heads; ++head_idx) {
      const int64_t slot_idx = slot_mapping[token_idx];
      if (slot_idx >= 0) {
        int src_key_head_idx = token_idx * key_stride + head_idx * head_size;
        int src_value_head_idx =
            token_idx * value_stride + head_idx * head_size;
        const scalar_t* src_key_head_ptr = key + src_key_head_idx;
        const scalar_t* src_value_head_ptr = value + src_value_head_idx;
        const int64_t block_index = slot_idx / block_size;
        const int64_t block_offset = slot_idx % block_size;
        scalar_t* target_key_head_ptr = key_cache +
                                        block_elem_num * block_index +
                                        head_idx * block_size * head_size;
        scalar_t* target_value_head_ptr = value_cache +
                                          block_elem_num * block_index +
                                          head_idx * block_size * head_size;
        for (int src_key_idx = 0; src_key_idx < head_size; src_key_idx += x) {
          const int64_t target_offset =
              src_key_idx * block_size + block_offset * x;
          for (int i = 0; i < x; ++i) {
            target_key_head_ptr[target_offset + i] =
                src_key_head_ptr[src_key_idx + i];
          }
        }
        for (int src_value_idx = 0; src_value_idx < head_size;
             ++src_value_idx) {
          const int64_t target_offset =
              src_value_idx * block_size + block_offset;
          target_value_head_ptr[target_offset] =
              src_value_head_ptr[src_value_idx];
        }
      }
    }
  }
 }
 };  // namespace
 // Note: the key_caches and value_caches vectors are constant but
 // not the Tensors they contain. The vectors need to be const refs
 // in order to satisfy pytorch's C++ operator registration code.
 void copy_blocks(std::vector<torch::Tensor> const& key_caches,
                 std::vector<torch::Tensor> const& value_caches,
                 const torch::Tensor& block_mapping) {
  unsigned num_layers = key_caches.size();
  TORCH_CHECK(num_layers == value_caches.size());
  if (num_layers == 0) {
    return;
  }
  const int element_num_per_block = key_caches[0][0].numel();
  VLLM_DISPATCH_FLOATING_TYPES(
      key_caches[0].scalar_type(), "copy_blocks_cpu_impl", [&] {
        CPU_KERNEL_GUARD_IN(copy_blocks_cpu_impl)
        copy_blocks_cpu_impl<scalar_t>(key_caches, value_caches, block_mapping,
                                       element_num_per_block, num_layers);
        CPU_KERNEL_GUARD_OUT(copy_blocks_cpu_impl)
      });
 }
 void reshape_and_cache(torch::Tensor& key, torch::Tensor& value,
                       torch::Tensor& key_cache, torch::Tensor& value_cache,
                       torch::Tensor& slot_mapping,
                       const std::string& kv_cache_dtype, double kv_scale) {
  TORCH_CHECK(kv_scale == 1.0f);
  int num_tokens = key.size(0);
  int num_heads = key.size(1);
  int head_size = key.size(2);
  int block_size = key_cache.size(3);
  int x = key_cache.size(4);
  int key_stride = key.stride(0);
  int value_stride = value.stride(0);
  VLLM_DISPATCH_FLOATING_TYPES(
      key.scalar_type(), "reshape_and_cache_cpu_impl", [&] {
        CPU_KERNEL_GUARD_IN(reshape_and_cache_cpu_impl)
        reshape_and_cache_cpu_impl<scalar_t>(
            key.data_ptr<scalar_t>(), value.data_ptr<scalar_t>(),
            key_cache.data_ptr<scalar_t>(), value_cache.data_ptr<scalar_t>(),
            slot_mapping.data_ptr<int64_t>(), num_tokens, key_stride,
            value_stride, num_heads, head_size, block_size, x);
        CPU_KERNEL_GUARD_OUT(reshape_and_cache_cpu_impl)
      });
 }
 void swap_blocks(torch::Tensor& src, torch::Tensor& dst,
                 const torch::Tensor& block_mapping) {
  TORCH_CHECK(false, "swap_blocks is unsupported on CPU.")
 }
--- a/csrc/cpu/cpu_types.hpp
+++ b/csrc/cpu/cpu_types.hpp
@@ -0,0 +1,352 @@
 #ifndef CPU_TYPES_HPP
 #define CPU_TYPES_HPP
 #include <immintrin.h>
 #include <torch/all.h>
 namespace vec_op {
 // FIXME: FP16 is not fully supported in Torch-CPU
 #define VLLM_DISPATCH_CASE_FLOATING_TYPES(...)                                 \
  AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__)                         \
  AT_DISPATCH_CASE(at::ScalarType::BFloat16, __VA_ARGS__)
 #define VLLM_DISPATCH_FLOATING_TYPES(TYPE, NAME, ...)                          \
  AT_DISPATCH_SWITCH(TYPE, NAME, VLLM_DISPATCH_CASE_FLOATING_TYPES(__VA_ARGS__))
 #ifndef CPU_OP_GUARD
 #define CPU_KERNEL_GUARD_IN(NAME)
 #define CPU_KERNEL_GUARD_OUT(NAME)
 #else
 #define CPU_KERNEL_GUARD_IN(NAME)                                              \
  std::cout << #NAME << " invoked." << std::endl;
 #define CPU_KERNEL_GUARD_OUT(NAME) std::cout << #NAME << " exit." << std::endl;
 #endif
 #define FORCE_INLINE __attribute__((always_inline)) inline
 namespace {
 template <typename T, T... indexes, typename F>
 constexpr void unroll_loop_item(std::integer_sequence<T, indexes...>, F &&f) {
  (f(std::integral_constant<T, indexes>{}), ...);
 }
 }; // namespace
 template <typename T, T count, typename F,
          typename = std::enable_if_t<std::is_invocable_v<F, T>>>
 constexpr void unroll_loop(F &&f) {
  unroll_loop_item(std::make_integer_sequence<T, count>{}, std::forward<F>(f));
 }
 template <typename T> struct Vec {
  constexpr static int get_elem_num() { return T::VEC_ELEM_NUM; }
 };
 struct FP32Vec8;
 struct FP32Vec16;
 #ifdef __AVX512FP16__
 struct FP16Vec8 : public Vec<FP16Vec8> {
  constexpr static int VEC_ELEM_NUM = 8;
  __m128h reg;
  explicit FP16Vec8(_Float16 v) : reg(_mm_set1_ph(v)) {}
  explicit FP16Vec8(const void *ptr) : reg(_mm_loadu_ph(ptr)) {}
  explicit FP16Vec8(__m128h data) : reg(data) {}
  FP16Vec8 operator*(const FP16Vec8 &b) const {
    return FP16Vec8(_mm_mul_ph(reg, b.reg));
  }
  FP16Vec8 operator+(const FP16Vec8 &b) const {
    return FP16Vec8(_mm_add_ph(reg, b.reg));
  }
  FP16Vec8 operator-(const FP16Vec8 &b) const {
    return FP16Vec8(_mm_sub_ph(reg, b.reg));
  }
  FP16Vec8 operator/(const FP16Vec8 &b) const {
    return FP16Vec8(_mm_div_ph(reg, b.reg));
  }
  void save(void *ptr) const { _mm_storeu_ph(ptr, reg); }
 };
 #endif
 struct BF16Vec8 : public Vec<BF16Vec8> {
  constexpr static int VEC_ELEM_NUM = 8;
  __m128i reg;
  explicit BF16Vec8(const void *ptr)
      : reg((__m128i)_mm_loadu_si128((__m128i *)ptr)) {}
  explicit BF16Vec8(const FP32Vec8 &);
  void save(void *ptr) const { *reinterpret_cast<__m128i *>(ptr) = reg; }
 };
 struct BF16Vec16 : public Vec<BF16Vec16> {
  constexpr static int VEC_ELEM_NUM = 16;
  __m256i reg;
  explicit BF16Vec16(const void *ptr)
      : reg((__m256i)_mm256_loadu_si256((__m256i *)ptr)) {}
  explicit BF16Vec16(const FP32Vec16 &);
  void save(void *ptr) const { *reinterpret_cast<__m256i *>(ptr) = reg; }
 };
 struct BF16Vec32 : public Vec<BF16Vec32> {
  constexpr static int VEC_ELEM_NUM = 32;
  __m512i reg;
  explicit BF16Vec32(const void *ptr) : reg((__m512i)_mm512_loadu_si512(ptr)) {}
  explicit BF16Vec32(__m512i data) : reg(data) {}
  explicit BF16Vec32(BF16Vec8 &vec8_data)
      : reg((__m512i)_mm512_inserti32x4(
            _mm512_inserti32x4(_mm512_inserti32x4(_mm512_castsi128_si512(
                                                      (__m128i)vec8_data.reg),
                                                  (__m128i)vec8_data.reg, 1),
                               (__m128i)vec8_data.reg, 2),
            (__m128i)vec8_data.reg, 3)) {}
  void save(void *ptr) const { *reinterpret_cast<__m512i *>(ptr) = reg; }
 };
 struct FP32Vec4 : public Vec<FP32Vec4> {
  constexpr static int VEC_ELEM_NUM = 4;
  union AliasReg {
    __m128 reg;
    float values[VEC_ELEM_NUM];
  };
  __m128 reg;
  explicit FP32Vec4(float v) : reg(_mm_set1_ps(v)) {}
  explicit FP32Vec4() : reg(_mm_set1_ps(0.0)) {}
  explicit FP32Vec4(const float *ptr) : reg(_mm_loadu_ps(ptr)) {}
  explicit FP32Vec4(__m128 data) : reg(data) {}
  explicit FP32Vec4(const FP32Vec4 &data) : reg(data.reg) {}
 };
 struct FP32Vec8 : public Vec<FP32Vec8> {
  constexpr static int VEC_ELEM_NUM = 8;
  union AliasReg {
    __m256 reg;
    float values[VEC_ELEM_NUM];
  };
  __m256 reg;
  explicit FP32Vec8(float v) : reg(_mm256_set1_ps(v)) {}
  explicit FP32Vec8() : reg(_mm256_set1_ps(0.0)) {}
  explicit FP32Vec8(const float *ptr) : reg(_mm256_loadu_ps(ptr)) {}
  explicit FP32Vec8(__m256 data) : reg(data) {}
  explicit FP32Vec8(const FP32Vec8 &data) : reg(data.reg) {}
 #ifdef __AVX512FP16__
  explicit FP32Vec8(__m128h v) : reg(_mm256_cvtph_ps(_mm_castph_si128(v))) {}
 #endif
  explicit FP32Vec8(const BF16Vec8 &v)
      : reg(_mm256_castsi256_ps(
            _mm256_bslli_epi128(_mm256_cvtepu16_epi32(v.reg), 2))) {}
  float reduce_sum() const {
    AliasReg ar;
    ar.reg = reg;
    float result = 0;
    unroll_loop<int, VEC_ELEM_NUM>([&result, &ar](int i) { result += ar.values[i]; });
    return result;
  }
  FP32Vec8 exp() const {
    AliasReg ar;
    ar.reg = reg;
    return FP32Vec8(_mm256_set_ps(expf(ar.values[7]), expf(ar.values[6]),
                                  expf(ar.values[5]), expf(ar.values[4]),
                                  expf(ar.values[3]), expf(ar.values[2]),
                                  expf(ar.values[1]), expf(ar.values[0])));
  }
  FP32Vec8 tanh() const {
    AliasReg ar;
    ar.reg = reg;
    return FP32Vec8(_mm256_set_ps(tanhf(ar.values[7]), tanhf(ar.values[6]),
                                  tanhf(ar.values[5]), tanhf(ar.values[4]),
                                  tanhf(ar.values[3]), tanhf(ar.values[2]),
                                  tanhf(ar.values[1]), tanhf(ar.values[0])));
  }
  FP32Vec8 er() const {
    AliasReg ar;
    ar.reg = reg;
    return FP32Vec8(_mm256_set_ps(erf(ar.values[7]), erf(ar.values[6]),
                                  erf(ar.values[5]), erf(ar.values[4]),
                                  erf(ar.values[3]), erf(ar.values[2]),
                                  erf(ar.values[1]), erf(ar.values[0])));
  }
  FP32Vec8 operator*(const FP32Vec8 &b) const {
    return FP32Vec8(_mm256_mul_ps(reg, b.reg));
  }
  FP32Vec8 operator+(const FP32Vec8 &b) const {
    return FP32Vec8(_mm256_add_ps(reg, b.reg));
  }
  FP32Vec8 operator-(const FP32Vec8 &b) const {
    return FP32Vec8(_mm256_sub_ps(reg, b.reg));
  }
  FP32Vec8 operator/(const FP32Vec8 &b) const {
    return FP32Vec8(_mm256_div_ps(reg, b.reg));
  }
  void save(float *ptr) const { _mm256_storeu_ps(ptr, reg); }
 };
 struct FP32Vec16 : public Vec<FP32Vec16> {
  constexpr static int VEC_ELEM_NUM = 16;
  union AliasReg {
    __m512 reg;
    float values[VEC_ELEM_NUM];
  };
  __m512 reg;
  explicit FP32Vec16(float v) : reg(_mm512_set1_ps(v)) {}
  explicit FP32Vec16() : reg(_mm512_set1_ps(0.0)) {}
  explicit FP32Vec16(const float *ptr) : reg(_mm512_loadu_ps(ptr)) {}
  explicit FP32Vec16(__m512 data) : reg(data) {}
  explicit FP32Vec16(const FP32Vec16 &data) : reg(data.reg) {}
  explicit FP32Vec16(const FP32Vec4 &data)
      : reg((__m512)_mm512_inserti32x4(
            _mm512_inserti32x4(
                _mm512_inserti32x4(_mm512_castsi128_si512((__m128i)data.reg),
                                   (__m128i)data.reg, 1),
                (__m128i)data.reg, 2),
            (__m128i)data.reg, 3)) {}
  explicit FP32Vec16(const FP32Vec8 &data)
      : reg((__m512)_mm512_inserti32x8(
            _mm512_castsi256_si512((__m256i)data.reg), (__m256i)data.reg, 1)) {}
  explicit FP32Vec16(const BF16Vec16 &v)
      : reg(_mm512_castsi512_ps(
            _mm512_bslli_epi128(_mm512_cvtepu16_epi32(v.reg), 2))) {}
  explicit FP32Vec16(const BF16Vec8 &v) : FP32Vec16(FP32Vec8(v)) {}
  FP32Vec16 operator*(const FP32Vec16 &b) const {
    return FP32Vec16(_mm512_mul_ps(reg, b.reg));
  }
  FP32Vec16 operator+(const FP32Vec16 &b) const {
    return FP32Vec16(_mm512_add_ps(reg, b.reg));
  }
  FP32Vec16 operator-(const FP32Vec16 &b) const {
    return FP32Vec16(_mm512_sub_ps(reg, b.reg));
  }
  FP32Vec16 operator/(const FP32Vec16 &b) const {
    return FP32Vec16(_mm512_div_ps(reg, b.reg));
  }
  float reduce_sum() const { return _mm512_reduce_add_ps(reg); }
  template <int group_size> float reduce_sub_sum(int idx) {
    static_assert(VEC_ELEM_NUM % group_size == 0);
    constexpr uint32_t base_mask = (0xFFFF >> (16 - group_size));
    __mmask16 mask = _cvtu32_mask16(base_mask << (idx * group_size));
    return _mm512_mask_reduce_add_ps(mask, reg);
  }
  void save(float *ptr) const { _mm512_storeu_ps(ptr, reg); }
 };
 template <typename T> struct VecType { using vec_type = void; };
 template <typename T> using vec_t = typename VecType<T>::vec_type;
 template <> struct VecType<float> { using vec_type = FP32Vec8; };
 #ifdef __AVX512FP16__
 template <> struct VecType<c10::Half> { using vec_type = FP16Vec16; };
 #endif
 template <> struct VecType<c10::BFloat16> { using vec_type = BF16Vec8; };
 template <typename T> void storeFP32(float v, T *ptr) { *ptr = v; }
 #ifdef __AVX512FP16__
 template <> inline void storeFP32<c10::Half>(float v, c10::Half *ptr) {
  *reinterpret_cast<_Float16 *>(ptr) = v;
 }
 #endif
 inline void fma(FP32Vec16 &acc, FP32Vec16 &a, FP32Vec16 &b) {
  acc = acc + a * b;
 }
 #ifdef __AVX512BF16__
 template <> inline void storeFP32<c10::BFloat16>(float v, c10::BFloat16 *ptr) {
  *reinterpret_cast<__bfloat16 *>(ptr) = _mm_cvtness_sbh(v);
 }
 inline BF16Vec8::BF16Vec8(const FP32Vec8 &v)
    : reg((__m128i)_mm256_cvtneps_pbh(v.reg)) {}
 inline BF16Vec16::BF16Vec16(const FP32Vec16 &v)
    : reg((__m256i)_mm512_cvtneps_pbh(v.reg)) {}
 inline void fma(FP32Vec16 &acc, BF16Vec32 &a, BF16Vec32 &b) {
  acc.reg = _mm512_dpbf16_ps(acc.reg, (__m512bh)a.reg, (__m512bh)b.reg);
 }
 #else
 template <> inline void storeFP32<c10::BFloat16>(float v, c10::BFloat16 *ptr) {
  c10::BFloat16 __attribute__((__may_alias__)) *v_ptr =
      reinterpret_cast<c10::BFloat16 *>(&v);
  *ptr = *(v_ptr + 1);
 }
 inline BF16Vec8::BF16Vec8(const FP32Vec8 &v)
    : reg(_mm256_cvtepi32_epi16(
          _mm256_bsrli_epi128(_mm256_castps_si256(v.reg), 2))) {}
 inline BF16Vec16::BF16Vec16(const FP32Vec16 &v)
    : reg(_mm512_cvtepi32_epi16(
          _mm512_bsrli_epi128(_mm512_castps_si512(v.reg), 2))) {}
 #endif
 inline void prefetch(const void *addr) { _mm_prefetch(addr, _MM_HINT_T1); }
 }; // namespace vec_op
 #endif
--- a/csrc/cpu/layernorm.cpp
+++ b/csrc/cpu/layernorm.cpp
@@ -0,0 +1,117 @@
 #include "cpu_types.hpp"
 namespace {
 template <typename scalar_t>
 void rms_norm_impl(scalar_t* __restrict__ out,
                   const scalar_t* __restrict__ input,
                   const scalar_t* __restrict__ weight, const float epsilon,
                   const int num_tokens, const int hidden_size) {
  using scalar_vec_t = vec_op::vec_t<scalar_t>;
  constexpr int VEC_ELEM_NUM = scalar_vec_t::get_elem_num();
  TORCH_CHECK(hidden_size % VEC_ELEM_NUM == 0);
 #pragma omp parallel for
  for (int i = 0; i < num_tokens; ++i) {
    vec_op::FP32Vec8 variance(0.0);
    auto input_p = input + i * hidden_size;
    auto output_p = out + i * hidden_size;
    for (int j = 0; j < hidden_size; j += VEC_ELEM_NUM) {
      scalar_vec_t x(input_p + j);
      vec_op::FP32Vec8 fp32_x(x);
      variance = variance + fp32_x * fp32_x;
    }
    float s_variance =
        1.0f / sqrtf(variance.reduce_sum() / (float)hidden_size + epsilon);
    vec_op::FP32Vec8 fp32_s_variance(s_variance);
    for (int j = 0; j < hidden_size; j += VEC_ELEM_NUM) {
      scalar_vec_t x(input_p + j);
      scalar_vec_t w(weight + j);
      vec_op::FP32Vec8 fp32_x(x);
      vec_op::FP32Vec8 fp32_w(w);
      vec_op::FP32Vec8 fp32_out = fp32_x * fp32_s_variance * fp32_w;
      scalar_vec_t out(fp32_out);
      out.save(output_p + j);
    }
  }
 }
 template <typename scalar_t>
 void fused_add_rms_norm_impl(scalar_t* __restrict__ input,
                             scalar_t* __restrict__ residual,
                             const scalar_t* __restrict__ weight,
                             const float epsilon, const int num_tokens,
                             const int hidden_size) {
  using scalar_vec_t = vec_op::vec_t<scalar_t>;
  constexpr int VEC_ELEM_NUM = scalar_vec_t::get_elem_num();
  TORCH_CHECK(hidden_size % VEC_ELEM_NUM == 0);
 #pragma omp parallel for
  for (int i = 0; i < num_tokens; ++i) {
    vec_op::FP32Vec8 variance(0.0);
    auto input_p = input + i * hidden_size;
    auto residual_p = residual + i * hidden_size;
    for (int j = 0; j < hidden_size; j += VEC_ELEM_NUM) {
      scalar_vec_t x(input_p + j);
      scalar_vec_t res(residual_p + j);
      vec_op::FP32Vec8 fp32_x(x);
      vec_op::FP32Vec8 fp32_res(res);
      fp32_x = fp32_x + fp32_res;
      variance = variance + fp32_x * fp32_x;
      scalar_vec_t out(fp32_x);
      out.save(residual_p + j);
    }
    float s_variance =
        1.0f / sqrtf(variance.reduce_sum() / (float)hidden_size + epsilon);
    vec_op::FP32Vec8 fp32_s_variance(s_variance);
    for (int j = 0; j < hidden_size; j += VEC_ELEM_NUM) {
      scalar_vec_t w(weight + j);
      scalar_vec_t res(residual_p + j);
      vec_op::FP32Vec8 fp32_w(w);
      vec_op::FP32Vec8 fp32_res(res);
      vec_op::FP32Vec8 fp32_out = fp32_res * fp32_s_variance * fp32_w;
      scalar_vec_t out(fp32_out);
      out.save(input_p + j);
    }
  }
 }
 }  // namespace
 void rms_norm(torch::Tensor& out, torch::Tensor& input, torch::Tensor& weight,
              double epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "rms_norm_impl", [&] {
    CPU_KERNEL_GUARD_IN(rms_norm_impl)
    rms_norm_impl(out.data_ptr<scalar_t>(), input.data_ptr<scalar_t>(),
                  weight.data_ptr<scalar_t>(), epsilon, num_tokens,
                  hidden_size);
    CPU_KERNEL_GUARD_OUT(rms_norm_impl)
  });
 }
 void fused_add_rms_norm(torch::Tensor& input, torch::Tensor& residual,
                        torch::Tensor& weight, double epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
  VLLM_DISPATCH_FLOATING_TYPES(
      input.scalar_type(), "fused_add_rms_norm_impl", [&] {
        CPU_KERNEL_GUARD_IN(fused_add_rms_norm_impl)
        fused_add_rms_norm_impl(
            input.data_ptr<scalar_t>(), residual.data_ptr<scalar_t>(),
            weight.data_ptr<scalar_t>(), epsilon, num_tokens, hidden_size);
        CPU_KERNEL_GUARD_OUT(fused_add_rms_norm_impl)
      });
 }
--- a/csrc/cpu/pos_encoding.cpp
+++ b/csrc/cpu/pos_encoding.cpp
@@ -0,0 +1,199 @@
 #include "cpu_types.hpp"
 namespace {
 template <typename scalar_t>
 void rotary_embedding_impl(
    const int64_t* __restrict__ positions,  // [batch_size, seq_len] or
                                            // [num_tokens]
    scalar_t* __restrict__ query,           /// [batch_size, seq_len, num_heads,
                                   /// head_size] or [num_tokens, num_heads,
                                   /// head_size]
    scalar_t* __restrict__ key,  // [batch_size, seq_len, num_kv_heads,
                                 // head_size] or [num_tokens, num_kv_heads,
                                 // head_size]
    const scalar_t* __restrict__ cos_sin_cache,  // [max_position, 2, rot_dim //
                                                 // 2]
    const int rot_dim, const int64_t query_stride, const int64_t key_stride,
    const int num_heads, const int num_kv_heads, const int head_size,
    const int num_tokens) {
  using scalar_vec_t = vec_op::vec_t<scalar_t>;
  constexpr int VEC_ELEM_NUM = scalar_vec_t::get_elem_num();
  const int embed_dim = rot_dim / 2;
  bool flag = (embed_dim % VEC_ELEM_NUM == 0);
  const int loop_upper = flag ? embed_dim : embed_dim - VEC_ELEM_NUM;
  auto compute_loop = [&](const int64_t token_head, const scalar_t* cache_ptr,
                          scalar_t* qk) {
    int j = 0;
    for (; j < loop_upper; j += VEC_ELEM_NUM) {
      const int rot_offset = j;
      const int x_index = rot_offset;
      const int y_index = embed_dim + rot_offset;
      const int64_t out_x = token_head + x_index;
      const int64_t out_y = token_head + y_index;
      const scalar_vec_t cos(cache_ptr + x_index);
      const scalar_vec_t sin(cache_ptr + y_index);
      const scalar_vec_t q_x(qk + out_x);
      const scalar_vec_t q_y(qk + out_y);
      vec_op::FP32Vec8 fp32_cos(cos);
      vec_op::FP32Vec8 fp32_sin(sin);
      vec_op::FP32Vec8 fp32_q_x(q_x);
      vec_op::FP32Vec8 fp32_q_y(q_y);
      auto out1 = fp32_q_x * fp32_cos - fp32_q_y * fp32_sin;
      scalar_vec_t(out1).save(qk + out_x);
      auto out2 = fp32_q_y * fp32_cos + fp32_q_x * fp32_sin;
      scalar_vec_t(out2).save(qk + out_y);
    }
    if (!flag) {
      for (; j < embed_dim; ++j) {
        const int x_index = j;
        const int y_index = embed_dim + j;
        const int64_t out_x = token_head + x_index;
        const int64_t out_y = token_head + y_index;
        const float fp32_cos = cache_ptr[x_index];
        const float fp32_sin = cache_ptr[y_index];
        const float fp32_q_x = qk[out_x];
        const float fp32_q_y = qk[out_y];
        qk[out_x] = fp32_q_x * fp32_cos - fp32_q_y * fp32_sin;
        qk[out_y] = fp32_q_y * fp32_cos + fp32_q_x * fp32_sin;
      }
    }
  };
 #pragma omp parallel for
  for (int token_idx = 0; token_idx < num_tokens; ++token_idx) {
    int64_t pos = positions[token_idx];
    const scalar_t* cache_ptr = cos_sin_cache + pos * rot_dim;
    for (int i = 0; i < num_heads; ++i) {
      const int head_idx = i;
      const int64_t token_head =
          token_idx * query_stride + head_idx * head_size;
      compute_loop(token_head, cache_ptr, query);
    }
    for (int i = 0; i < num_kv_heads; ++i) {
      const int head_idx = i;
      const int64_t token_head = token_idx * key_stride + head_idx * head_size;
      compute_loop(token_head, cache_ptr, key);
    }
  }
 }
 template <typename scalar_t>
 void rotary_embedding_gptj_impl(
    const int64_t* __restrict__ positions,  // [batch_size, seq_len] or
                                            // [num_tokens]
    scalar_t* __restrict__ query,           /// [batch_size, seq_len, num_heads,
                                   /// head_size] or [num_tokens, num_heads,
                                   /// head_size]
    scalar_t* __restrict__ key,  // [batch_size, seq_len, num_kv_heads,
                                 // head_size] or [num_tokens, num_kv_heads,
                                 // head_size]
    const scalar_t* __restrict__ cos_sin_cache,  // [max_position, 2, rot_dim //
                                                 // 2]
    const int rot_dim, const int64_t query_stride, const int64_t key_stride,
    const int num_heads, const int num_kv_heads, const int head_size,
    const int num_tokens) {
  const int embed_dim = rot_dim / 2;
 #pragma omp parallel for collapse(2)
  for (int token_idx = 0; token_idx < num_tokens; ++token_idx) {
    for (int i = 0; i < num_heads; ++i) {
      int64_t pos = positions[token_idx];
      const scalar_t* cache_ptr = cos_sin_cache + pos * rot_dim;
      const scalar_t* cos_cache_ptr = cache_ptr;
      const scalar_t* sin_cache_ptr = cache_ptr + embed_dim;
      const int head_idx = i;
      const int64_t token_head =
          token_idx * query_stride + head_idx * head_size;
      scalar_t* head_query = token_head + query;
      for (int j = 0; j < embed_dim; j += 1) {
        const int rot_offset = j;
        const int x_index = 2 * rot_offset;
        const int y_index = 2 * rot_offset + 1;
        const float cos = cos_cache_ptr[rot_offset];
        const float sin = sin_cache_ptr[rot_offset];
        const float x = head_query[x_index];
        const float y = head_query[y_index];
        head_query[x_index] = x * cos - y * sin;
        head_query[y_index] = y * cos + x * sin;
      }
    }
  }
 #pragma omp parallel for collapse(2)
  for (int token_idx = 0; token_idx < num_tokens; ++token_idx) {
    for (int i = 0; i < num_kv_heads; ++i) {
      int64_t pos = positions[token_idx];
      const scalar_t* cache_ptr = cos_sin_cache + pos * rot_dim;
      const scalar_t* cos_cache_ptr = cache_ptr;
      const scalar_t* sin_cache_ptr = cache_ptr + embed_dim;
      const int head_idx = i;
      const int64_t token_head = token_idx * key_stride + head_idx * head_size;
      scalar_t* head_key = key + token_head;
      for (int j = 0; j < embed_dim; j += 1) {
        const int rot_offset = j;
        const int x_index = 2 * rot_offset;
        const int y_index = 2 * rot_offset + 1;
        const float cos = cos_cache_ptr[rot_offset];
        const float sin = sin_cache_ptr[rot_offset];
        const float x = head_key[x_index];
        const float y = head_key[y_index];
        head_key[x_index] = x * cos - y * sin;
        head_key[y_index] = y * cos + x * sin;
      }
    }
  }
 }
 };  // namespace
 void rotary_embedding(torch::Tensor& positions, torch::Tensor& query,
                      torch::Tensor& key, int64_t head_size,
                      torch::Tensor& cos_sin_cache, bool is_neox) {
  int num_tokens = query.numel() / query.size(-1);
  int rot_dim = cos_sin_cache.size(1);
  int num_heads = query.size(-1) / head_size;
  int num_kv_heads = key.size(-1) / head_size;
  int64_t key_stride = key.stride(-2);
  int64_t query_stride = query.stride(-2);
  VLLM_DISPATCH_FLOATING_TYPES(
      query.scalar_type(), "rotary_embedding_impl", [&] {
        CPU_KERNEL_GUARD_IN(rotary_embedding_impl)
        if (is_neox) {
          rotary_embedding_impl(
              positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
              key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(),
              rot_dim, query_stride, key_stride, num_heads, num_kv_heads,
              head_size, num_tokens);
        } else {
          rotary_embedding_gptj_impl(
              positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
              key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(),
              rot_dim, query_stride, key_stride, num_heads, num_kv_heads,
              head_size, num_tokens);
        }
        CPU_KERNEL_GUARD_OUT(rotary_embedding_impl)
      });
 }
--- a/csrc/cpu/torch_bindings.cpp
+++ b/csrc/cpu/torch_bindings.cpp
@@ -0,0 +1,106 @@
 #include "cache.h"
 #include "ops.h"
 #include "registration.h"
 #include <torch/library.h>
 TORCH_LIBRARY_EXPAND(TORCH_EXTENSION_NAME, ops) {
  // vLLM custom ops
  // Attention ops
  // Compute the attention between an input query and the cached keys/values
  // using PagedAttention.
  ops.def(
      "paged_attention_v1("
      "    Tensor! out, Tensor query, Tensor key_cache,"
      "    Tensor value_cache, int num_kv_heads, float scale,"
      "    Tensor block_tables, Tensor seq_lens, int block_size,"
      "    int max_seq_len, Tensor? alibi_slopes,"
      "    str kv_cache_dtype, float kv_scale, int tp_rank,"
      "    int blocksparse_local_blocks,"
      "    int blocksparse_vert_stride, int blocksparse_block_size,"
      "    int blocksparse_head_sliding_step) -> ()");
  ops.impl("paged_attention_v1", torch::kCPU, &paged_attention_v1);
  // PagedAttention V2.
  ops.def(
      "paged_attention_v2("
      "    Tensor! out, Tensor exp_sums, Tensor max_logits,"
      "    Tensor tmp_out, Tensor query, Tensor key_cache,"
      "    Tensor value_cache, int num_kv_heads, float scale,"
      "    Tensor block_tables, Tensor seq_lens, int block_size,"
      "    int max_seq_len, Tensor? alibi_slopes,"
      "    str kv_cache_dtype, float kv_scale, int tp_rank,"
      "    int blocksparse_local_blocks,"
      "    int blocksparse_vert_stride, int blocksparse_block_size,"
      "    int blocksparse_head_sliding_step) -> ()");
  ops.impl("paged_attention_v2", torch::kCPU, &paged_attention_v2);
  // Activation ops
  // Activation function used in SwiGLU.
  ops.def("silu_and_mul(Tensor! out, Tensor input) -> ()");
  ops.impl("silu_and_mul", torch::kCPU, &silu_and_mul);
  // Activation function used in GeGLU with `none` approximation.
  ops.def("gelu_and_mul(Tensor! out, Tensor input) -> ()");
  ops.impl("gelu_and_mul", torch::kCPU, &gelu_and_mul);
  // Activation function used in GeGLU with `tanh` approximation.
  ops.def("gelu_tanh_and_mul(Tensor! out, Tensor input) -> ()");
  ops.impl("gelu_tanh_and_mul", torch::kCPU, &gelu_tanh_and_mul);
  // GELU implementation used in GPT-2.
  ops.def("gelu_new(Tensor! out, Tensor input) -> ()");
  ops.impl("gelu_new", torch::kCPU, &gelu_new);
  // Approximate GELU implementation.
  ops.def("gelu_fast(Tensor! out, Tensor input) -> ()");
  ops.impl("gelu_fast", torch::kCPU, &gelu_fast);
  // Layernorm
  // Apply Root Mean Square (RMS) Normalization to the input tensor.
  ops.def(
      "rms_norm(Tensor! out, Tensor input, Tensor weight, float epsilon) -> "
      "()");
  ops.impl("rms_norm", torch::kCPU, &rms_norm);
  // In-place fused Add and RMS Normalization.
  ops.def(
      "fused_add_rms_norm(Tensor! input, Tensor! residual, Tensor weight, "
      "float epsilon) -> ()");
  ops.impl("fused_add_rms_norm", torch::kCPU, &fused_add_rms_norm);
  // Rotary embedding
  // Apply GPT-NeoX or GPT-J style rotary embedding to query and key.
  ops.def(
      "rotary_embedding(Tensor positions, Tensor! query,"
      "                 Tensor! key, int head_size,"
      "                 Tensor cos_sin_cache, bool is_neox) -> ()");
  ops.impl("rotary_embedding", torch::kCPU, &rotary_embedding);
 }
 TORCH_LIBRARY_EXPAND(CONCAT(TORCH_EXTENSION_NAME, _cache_ops), cache_ops) {
  // Cache ops
  // Swap in (out) the cache blocks from src to dst.
  cache_ops.def(
      "swap_blocks(Tensor src, Tensor! dst, Tensor block_mapping) -> ()");
  cache_ops.impl("swap_blocks", torch::kCPU, &swap_blocks);
  // Copy the cache blocks from src to dst.
  cache_ops.def(
      "copy_blocks(Tensor[]! key_caches, Tensor[]! value_caches, Tensor "
      "block_mapping) -> ()");
  cache_ops.impl("copy_blocks", torch::kCPU, &copy_blocks);
  // Reshape the key and value tensors and cache them.
  cache_ops.def(
      "reshape_and_cache(Tensor key, Tensor value,"
      "                  Tensor! key_cache, Tensor! value_cache,"
      "                  Tensor slot_mapping,"
      "                  str kv_cache_dtype,"
      "                  float kv_scale) -> ()");
  cache_ops.impl("reshape_and_cache", torch::kCPU, &reshape_and_cache);
 }
 REGISTER_EXTENSION(TORCH_EXTENSION_NAME)
--- a/csrc/cuda_compat.h
+++ b/csrc/cuda_compat.h
@@ -1,7 +1,7 @@
 #pragma once
 #ifdef USE_ROCM
-#include <hip/hip_runtime.h>
+  #include <hip/hip_runtime.h>
 #endif
 #ifndef USE_ROCM
@@ -17,9 +17,14 @@
 #endif
 #ifndef USE_ROCM
-  #define VLLM_SHFL_XOR_SYNC(var, lane_mask) __shfl_xor_sync(uint32_t(-1), var, lane_mask)
+  #define VLLM_SHFL_XOR_SYNC(var, lane_mask) \
    __shfl_xor_sync(uint32_t(-1), var, lane_mask)
  #define VLLM_SHFL_XOR_SYNC_WIDTH(var, lane_mask, width) \
    __shfl_xor_sync(uint32_t(-1), var, lane_mask, width)
 #else
  #define VLLM_SHFL_XOR_SYNC(var, lane_mask) __shfl_xor(var, lane_mask)
  #define VLLM_SHFL_XOR_SYNC_WIDTH(var, lane_mask, width) \
    __shfl_xor(var, lane_mask, width)
 #endif
 #ifndef USE_ROCM
@@ -28,6 +33,13 @@
  #define VLLM_SHFL_SYNC(var, src_lane) __shfl(var, src_lane)
 #endif
 #ifndef USE_ROCM
  #define VLLM_SHFL_DOWN_SYNC(var, lane_delta) \
    __shfl_down_sync(uint32_t(-1), var, lane_delta)
 #else
  #define VLLM_SHFL_DOWN_SYNC(var, lane_delta) __shfl_down(var, lane_delta)
 #endif
 #ifndef USE_ROCM
  #define VLLM_DevFuncAttribute_SET_MaxDynamicSharedMemorySize(FUNC, VAL) \
    cudaFuncSetAttribute(FUNC, cudaFuncAttributeMaxDynamicSharedMemorySize, VAL)
@@ -35,4 +47,3 @@
  #define VLLM_DevFuncAttribute_SET_MaxDynamicSharedMemorySize(FUNC, VAL) \
    hipFuncSetAttribute(FUNC, hipFuncAttributeMaxDynamicSharedMemorySize, VAL)
 #endif
--- a/csrc/cuda_utils.h
+++ b/csrc/cuda_utils.h
@@ -1,10 +1,5 @@
 #pragma once
-#include <torch/extension.h>
+int64_t get_device_attribute(int64_t attribute, int64_t device_id);
-int get_device_attribute(
+int64_t get_max_shared_memory_per_block_device_attribute(int64_t device_id);
    int attribute,
    int device_id);
 int get_max_shared_memory_per_block_device_attribute(
    int device_id);
--- a/csrc/cuda_utils_kernels.cu
+++ b/csrc/cuda_utils_kernels.cu
@@ -2,34 +2,28 @@
  #include <hip/hip_runtime.h>
  #include <hip/hip_runtime_api.h>
 #endif
-int get_device_attribute(
+int64_t get_device_attribute(int64_t attribute, int64_t device_id) {
-    int attribute,
+  int device, value;
-    int device_id)
+  if (device_id < 0) {
-{
+    cudaGetDevice(&device);
-    int device, value;
+  } else {
-    if (device_id < 0) {
+    device = device_id;
-        cudaGetDevice(&device);
+  }
-    }
+  cudaDeviceGetAttribute(&value, static_cast<cudaDeviceAttr>(attribute),
-    else {
+                         device);
-        device = device_id;
+  return value;
    }
    cudaDeviceGetAttribute(&value, static_cast<cudaDeviceAttr>(attribute), device);
    return value;
 }
-
+int64_t get_max_shared_memory_per_block_device_attribute(int64_t device_id) {
-int get_max_shared_memory_per_block_device_attribute(
+  int64_t attribute;
-    int device_id)
+  // https://docs.nvidia.com/cuda/cuda-runtime-api/group__CUDART__TYPES.html
-{
+  // cudaDevAttrMaxSharedMemoryPerBlockOptin = 97 if not is_hip() else 74
 int attribute;    
 // https://docs.nvidia.com/cuda/cuda-runtime-api/group__CUDART__TYPES.html
 // cudaDevAttrMaxSharedMemoryPerBlockOptin = 97 if not is_hip() else 74
 #ifdef USE_ROCM
-    attribute = hipDeviceAttributeMaxSharedMemoryPerBlock;
+  attribute = hipDeviceAttributeMaxSharedMemoryPerBlock;
 #else
-    attribute = cudaDevAttrMaxSharedMemoryPerBlockOptin;
+  attribute = cudaDevAttrMaxSharedMemoryPerBlockOptin;
 #endif
-    return get_device_attribute(attribute, device_id);
+  return get_device_attribute(attribute, device_id);
 }
--- a/csrc/custom_all_reduce.cu
+++ b/csrc/custom_all_reduce.cu
@@ -1,17 +1,17 @@
 #include <ATen/cuda/Exceptions.h>
 #include <c10/cuda/CUDAGuard.h>
 #include <c10/cuda/CUDAStream.h>
-#include <torch/extension.h>
+#include <torch/all.h>
 #include "custom_all_reduce.cuh"
-// fake pointer type
+// fake pointer type, must match fptr_t type in ops.h
-using fptr_t = uint64_t;
+using fptr_t = int64_t;
-static_assert(sizeof(void *) == sizeof(fptr_t));
+static_assert(sizeof(void*) == sizeof(fptr_t));
-fptr_t init_custom_ar(torch::Tensor &meta, torch::Tensor &rank_data,
+fptr_t init_custom_ar(torch::Tensor& meta, torch::Tensor& rank_data,
-                      const std::vector<std::string> &handles,
+                      const std::vector<std::string>& handles,
-                      const std::vector<int64_t> &offsets, int rank,
+                      const std::vector<int64_t>& offsets, int64_t rank,
                      bool full_nvlink) {
  int world_size = offsets.size();
  if (world_size > 8)
@@ -29,7 +29,7 @@ fptr_t init_custom_ar(torch::Tensor &meta, torch::Tensor &rank_data,
    std::memcpy(&ipc_handles[i], handles[i].data(), sizeof(cudaIpcMemHandle_t));
  }
  return (fptr_t) new vllm::CustomAllreduce(
-      reinterpret_cast<vllm::Signal *>(meta.data_ptr()), rank_data.data_ptr(),
+      reinterpret_cast<vllm::Signal*>(meta.data_ptr()), rank_data.data_ptr(),
      rank_data.numel(), ipc_handles, offsets, rank, full_nvlink);
 }
@@ -49,13 +49,13 @@ fptr_t init_custom_ar(torch::Tensor &meta, torch::Tensor &rank_data,
 * 5. A[None].expand(2, -1, -1, -1): Not OK
 * 6. A[:, 1:, 1:]: Not OK
 */
-bool _is_weak_contiguous(torch::Tensor &t) {
+bool _is_weak_contiguous(torch::Tensor& t) {
  return t.is_contiguous() ||
         (t.storage().nbytes() - t.storage_offset() * t.element_size() ==
          t.numel() * t.element_size());
 }
-bool should_custom_ar(torch::Tensor &inp, int max_size, int world_size,
+bool should_custom_ar(torch::Tensor& inp, int64_t max_size, int64_t world_size,
                      bool full_nvlink) {
  auto inp_size = inp.numel() * inp.element_size();
  // custom allreduce requires input byte size to be multiples of 16
@@ -67,28 +67,27 @@ bool should_custom_ar(torch::Tensor &inp, int max_size, int world_size,
  return false;
 }
-void _all_reduce(fptr_t _fa, torch::Tensor &inp, torch::Tensor &out,
+void _all_reduce(fptr_t _fa, torch::Tensor& inp, torch::Tensor& out,
                 cudaStream_t stream) {
-  auto fa = reinterpret_cast<vllm::CustomAllreduce *>(_fa);
+  auto fa = reinterpret_cast<vllm::CustomAllreduce*>(_fa);
  TORCH_CHECK(_is_weak_contiguous(out));
  switch (out.scalar_type()) {
    case at::ScalarType::Float: {
-      fa->allreduce<float>(stream, reinterpret_cast<float *>(inp.data_ptr()),
+      fa->allreduce<float>(stream, reinterpret_cast<float*>(inp.data_ptr()),
-                           reinterpret_cast<float *>(out.data_ptr()),
+                           reinterpret_cast<float*>(out.data_ptr()),
                           out.numel());
      break;
    }
    case at::ScalarType::Half: {
-      fa->allreduce<half>(stream, reinterpret_cast<half *>(inp.data_ptr()),
+      fa->allreduce<half>(stream, reinterpret_cast<half*>(inp.data_ptr()),
-                          reinterpret_cast<half *>(out.data_ptr()),
+                          reinterpret_cast<half*>(out.data_ptr()), out.numel());
                          out.numel());
      break;
    }
 #if (__CUDA_ARCH__ >= 800 || !defined(__CUDA_ARCH__))
    case at::ScalarType::BFloat16: {
      fa->allreduce<nv_bfloat16>(
-          stream, reinterpret_cast<nv_bfloat16 *>(inp.data_ptr()),
+          stream, reinterpret_cast<nv_bfloat16*>(inp.data_ptr()),
-          reinterpret_cast<nv_bfloat16 *>(out.data_ptr()), out.numel());
+          reinterpret_cast<nv_bfloat16*>(out.data_ptr()), out.numel());
      break;
    }
 #endif
@@ -98,7 +97,7 @@ void _all_reduce(fptr_t _fa, torch::Tensor &inp, torch::Tensor &out,
  }
 }
-void all_reduce_reg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &out) {
+void all_reduce_reg(fptr_t _fa, torch::Tensor& inp, torch::Tensor& out) {
  const at::cuda::OptionalCUDAGuard device_guard(device_of(inp));
  auto stream = c10::cuda::getCurrentCUDAStream().stream();
  TORCH_CHECK_EQ(inp.scalar_type(), out.scalar_type());
@@ -106,8 +105,8 @@ void all_reduce_reg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &out) {
  _all_reduce(_fa, inp, out, stream);
 }
-void all_reduce_unreg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &reg_buffer,
+void all_reduce_unreg(fptr_t _fa, torch::Tensor& inp, torch::Tensor& reg_buffer,
-                      torch::Tensor &out) {
+                      torch::Tensor& out) {
  const at::cuda::OptionalCUDAGuard device_guard(device_of(inp));
  auto stream = c10::cuda::getCurrentCUDAStream().stream();
@@ -122,27 +121,33 @@ void all_reduce_unreg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &reg_buffer,
 }
 void dispose(fptr_t _fa) {
-  auto fa = reinterpret_cast<vllm::CustomAllreduce *>(_fa);
+  auto fa = reinterpret_cast<vllm::CustomAllreduce*>(_fa);
  delete fa;
 }
-int meta_size() { return sizeof(vllm::Signal); }
+int64_t meta_size() { return sizeof(vllm::Signal); }
-void register_buffer(fptr_t _fa, torch::Tensor &t,
+void register_buffer(fptr_t _fa, torch::Tensor& t,
-                     const std::vector<std::string> &handles,
+                     const std::vector<std::string>& handles,
-                     const std::vector<int64_t> &offsets) {
+                     const std::vector<int64_t>& offsets) {
-  auto fa = reinterpret_cast<vllm::CustomAllreduce *>(_fa);
+  auto fa = reinterpret_cast<vllm::CustomAllreduce*>(_fa);
  fa->register_buffer(handles, offsets, t.data_ptr());
 }
-std::pair<std::vector<uint8_t>, std::vector<int64_t>> get_graph_buffer_ipc_meta(
+std::tuple<torch::Tensor, std::vector<int64_t>> get_graph_buffer_ipc_meta(
    fptr_t _fa) {
-  auto fa = reinterpret_cast<vllm::CustomAllreduce *>(_fa);
+  auto fa = reinterpret_cast<vllm::CustomAllreduce*>(_fa);
-  return fa->get_graph_buffer_ipc_meta();
+  auto [handle_bytes, offsets] = fa->get_graph_buffer_ipc_meta();
  auto options =
      torch::TensorOptions().dtype(torch::kUInt8).device(torch::kCPU);
  auto handles =
      torch::empty({static_cast<int64_t>(handle_bytes.size())}, options);
  std::memcpy(handles.data_ptr(), handle_bytes.data(), handle_bytes.size());
  return {handles, std::move(offsets)};
 }
-void register_graph_buffers(fptr_t _fa, const std::vector<std::string> &handles,
+void register_graph_buffers(fptr_t _fa, const std::vector<std::string>& handles,
-                            const std::vector<std::vector<int64_t>> &offsets) {
+                            const std::vector<std::vector<int64_t>>& offsets) {
-  auto fa = reinterpret_cast<vllm::CustomAllreduce *>(_fa);
+  auto fa = reinterpret_cast<vllm::CustomAllreduce*>(_fa);
  fa->register_graph_buffers(handles, offsets);
 }
--- a/csrc/custom_all_reduce.cuh
+++ b/csrc/custom_all_reduce.cuh
@@ -31,9 +31,9 @@ struct Signal {
  alignas(128) uint32_t end[kMaxBlocks][8];
 };
-struct __align__(16) RankData { const void *__restrict__ ptrs[8]; };
+struct __align__(16) RankData { const void* __restrict__ ptrs[8]; };
-struct __align__(16) RankSignals { volatile Signal *signals[8]; };
+struct __align__(16) RankSignals { volatile Signal* signals[8]; };
 // like std::array, but aligned
 template <typename T, int sz>
@@ -68,11 +68,11 @@ DINLINE half downcast_s(float val) {
 // scalar add functions
 // for some reason when compiling with Pytorch, the + operator for half and
 // bfloat is disabled so we call the intrinsics directly
-DINLINE half &assign_add(half &a, half b) {
+DINLINE half& assign_add(half& a, half b) {
  a = __hadd(a, b);
  return a;
 }
-DINLINE float &assign_add(float &a, float b) { return a += b; }
+DINLINE float& assign_add(float& a, float b) { return a += b; }
 #if (__CUDA_ARCH__ >= 800 || !defined(__CUDA_ARCH__))
 DINLINE float upcast_s(nv_bfloat16 val) { return __bfloat162float(val); }
@@ -80,14 +80,14 @@ template <>
 DINLINE nv_bfloat16 downcast_s(float val) {
  return __float2bfloat16(val);
 }
-DINLINE nv_bfloat16 &assign_add(nv_bfloat16 &a, nv_bfloat16 b) {
+DINLINE nv_bfloat16& assign_add(nv_bfloat16& a, nv_bfloat16 b) {
  a = __hadd(a, b);
  return a;
 }
 #endif
 template <typename T, int N>
-DINLINE array_t<T, N> &packed_assign_add(array_t<T, N> &a, array_t<T, N> b) {
+DINLINE array_t<T, N>& packed_assign_add(array_t<T, N>& a, array_t<T, N> b) {
 #pragma unroll
  for (int i = 0; i < N; i++) {
    assign_add(a.data[i], b.data[i]);
@@ -128,7 +128,7 @@ DINLINE O downcast(array_t<float, O::size> val) {
 // prior memory accesses. Note: volatile writes will not be reordered against
 // other volatile writes.
 template <int ngpus>
-DINLINE void start_sync(const RankSignals &sg, volatile Signal *self_sg,
+DINLINE void start_sync(const RankSignals& sg, volatile Signal* self_sg,
                        int rank) {
  if (threadIdx.x < ngpus) {
    // reset flag for next time
@@ -137,8 +137,7 @@ DINLINE void start_sync(const RankSignals &sg, volatile Signal *self_sg,
    // Latency = 1 p2p write
    sg.signals[threadIdx.x]->start[blockIdx.x][rank] = 1;
    // wait until we got true from all ranks
-    while (!self_sg->start[blockIdx.x][threadIdx.x])
+    while (!self_sg->start[blockIdx.x][threadIdx.x]);
      ;
  }
  __syncthreads();
 }
@@ -147,7 +146,7 @@ DINLINE void start_sync(const RankSignals &sg, volatile Signal *self_sg,
 // barrier in the all reduce kernel. If it's the final synchronization barrier,
 // we don't need to make any visibility guarantees for prior memory accesses.
 template <int ngpus, bool final_sync = false>
-DINLINE void end_sync(const RankSignals &sg, volatile Signal *self_sg,
+DINLINE void end_sync(const RankSignals& sg, volatile Signal* self_sg,
                      int rank) {
  __syncthreads();
  // eliminate the case that prior writes are not visible after signals become
@@ -162,14 +161,13 @@ DINLINE void end_sync(const RankSignals &sg, volatile Signal *self_sg,
    // Latency = 1 p2p write
    sg.signals[threadIdx.x]->end[blockIdx.x][rank] = 1;
    // wait until we got true from all ranks
-    while (!self_sg->end[blockIdx.x][threadIdx.x])
+    while (!self_sg->end[blockIdx.x][threadIdx.x]);
      ;
  }
  if constexpr (!final_sync) __syncthreads();
 }
 template <typename P, int ngpus, typename A>
-DINLINE P packed_reduce(const P *ptrs[], int idx) {
+DINLINE P packed_reduce(const P* ptrs[], int idx) {
  A tmp = upcast(ptrs[0][idx]);
 #pragma unroll
  for (int i = 1; i < ngpus; i++) {
@@ -180,8 +178,8 @@ DINLINE P packed_reduce(const P *ptrs[], int idx) {
 template <typename T, int ngpus>
 __global__ void __launch_bounds__(512, 1)
-    cross_device_reduce_1stage(RankData *_dp, RankSignals sg,
+    cross_device_reduce_1stage(RankData* _dp, RankSignals sg,
-                               volatile Signal *self_sg, T *__restrict__ result,
+                               volatile Signal* self_sg, T* __restrict__ result,
                               int rank, int size) {
  using P = typename packed_t<T>::P;
  using A = typename packed_t<T>::A;
@@ -192,21 +190,20 @@ __global__ void __launch_bounds__(512, 1)
  // do the actual reduction
  for (int idx = blockIdx.x * blockDim.x + threadIdx.x; idx < size;
       idx += gridDim.x * blockDim.x) {
-    ((P *)result)[idx] =
+    ((P*)result)[idx] = packed_reduce<P, ngpus, A>((const P**)&dp.ptrs[0], idx);
        packed_reduce<P, ngpus, A>((const P **)&dp.ptrs[0], idx);
  }
  end_sync<ngpus, true>(sg, self_sg, rank);
 }
 template <typename P>
-DINLINE P *get_tmp_buf(volatile Signal *sg) {
+DINLINE P* get_tmp_buf(volatile Signal* sg) {
-  return (P *)(((Signal *)sg) + 1);
+  return (P*)(((Signal*)sg) + 1);
 }
 template <typename T, int ngpus>
 __global__ void __launch_bounds__(512, 1)
-    cross_device_reduce_2stage(RankData *_dp, RankSignals sg,
+    cross_device_reduce_2stage(RankData* _dp, RankSignals sg,
-                               volatile Signal *self_sg, T *__restrict__ result,
+                               volatile Signal* self_sg, T* __restrict__ result,
                               int rank, int size) {
  int tid = blockIdx.x * blockDim.x + threadIdx.x;
  int stride = gridDim.x * blockDim.x;
@@ -216,12 +213,12 @@ __global__ void __launch_bounds__(512, 1)
  int start = rank * part;
  int end = rank == ngpus - 1 ? size : start + part;
  int largest_part = part + size % ngpus;
-  const P *ptrs[ngpus];
+  const P* ptrs[ngpus];
-  P *tmps[ngpus];
+  P* tmps[ngpus];
 #pragma unroll
  for (int i = 0; i < ngpus; i++) {
    int target = (rank + i) % ngpus;
-    ptrs[i] = (const P *)_dp->ptrs[target];
+    ptrs[i] = (const P*)_dp->ptrs[target];
    tmps[i] = get_tmp_buf<P>(sg.signals[target]);
  }
  auto tmp_out = tmps[0];
@@ -243,7 +240,7 @@ __global__ void __launch_bounds__(512, 1)
      int gather_from_rank = ((rank + i) % ngpus);
      if (gather_from_rank == ngpus - 1 || idx < part) {
        int dst_idx = gather_from_rank * part + idx;
-        ((P *)result)[dst_idx] = tmps[i][idx];
+        ((P*)result)[dst_idx] = tmps[i][idx];
      }
    }
  }
@@ -261,14 +258,14 @@ class CustomAllreduce {
  // below are device pointers
  RankSignals sg_;
-  std::unordered_map<void *, RankData *> buffers_;
+  std::unordered_map<void*, RankData*> buffers_;
-  Signal *self_sg_;
+  Signal* self_sg_;
  // stores the registered device pointers from all ranks
  RankData *d_rank_data_base_, *d_rank_data_end_;
-  std::vector<void *> graph_unreg_buffers_;
+  std::vector<void*> graph_unreg_buffers_;
  // a map from IPC handles to opened IPC pointers
-  std::map<IPC_KEY, char *> ipc_handles_;
+  std::map<IPC_KEY, char*> ipc_handles_;
  /**
   * meta is a pointer to device metadata and temporary buffer for allreduce.
@@ -279,22 +276,22 @@ class CustomAllreduce {
   * note: this class does not own any device memory. Any required buffers
   * are passed in from the constructor
   */
-  CustomAllreduce(Signal *meta, void *rank_data, size_t rank_data_sz,
+  CustomAllreduce(Signal* meta, void* rank_data, size_t rank_data_sz,
-                  const cudaIpcMemHandle_t *handles,
+                  const cudaIpcMemHandle_t* handles,
-                  const std::vector<int64_t> &offsets, int rank,
+                  const std::vector<int64_t>& offsets, int rank,
                  bool full_nvlink = true)
      : rank_(rank),
        world_size_(offsets.size()),
        full_nvlink_(full_nvlink),
        self_sg_(meta),
-        d_rank_data_base_(reinterpret_cast<RankData *>(rank_data)),
+        d_rank_data_base_(reinterpret_cast<RankData*>(rank_data)),
        d_rank_data_end_(d_rank_data_base_ + rank_data_sz / sizeof(RankData)) {
    for (int i = 0; i < world_size_; i++) {
-      Signal *rank_sg;
+      Signal* rank_sg;
      if (i != rank_) {
-        char *handle = open_ipc_handle(&handles[i]);
+        char* handle = open_ipc_handle(&handles[i]);
        handle += offsets[i];
-        rank_sg = (Signal *)handle;
+        rank_sg = (Signal*)handle;
      } else {
        rank_sg = self_sg_;
      }
@@ -302,13 +299,13 @@ class CustomAllreduce {
    }
  }
-  char *open_ipc_handle(const void *ipc_handle) {
+  char* open_ipc_handle(const void* ipc_handle) {
    auto [it, new_handle] =
-        ipc_handles_.insert({*((IPC_KEY *)ipc_handle), nullptr});
+        ipc_handles_.insert({*((IPC_KEY*)ipc_handle), nullptr});
    if (new_handle) {
-      char *ipc_ptr;
+      char* ipc_ptr;
-      CUDACHECK(cudaIpcOpenMemHandle((void **)&ipc_ptr,
+      CUDACHECK(cudaIpcOpenMemHandle((void**)&ipc_ptr,
-                                     *((const cudaIpcMemHandle_t *)ipc_handle),
+                                     *((const cudaIpcMemHandle_t*)ipc_handle),
                                     cudaIpcMemLazyEnablePeerAccess));
      it->second = ipc_ptr;
    }
@@ -323,7 +320,7 @@ class CustomAllreduce {
    std::vector<int64_t> offsets(num_buffers);
    for (int i = 0; i < num_buffers; i++) {
      auto ptr = graph_unreg_buffers_[i];
-      void *base_ptr;
+      void* base_ptr;
      // note: must share the base address of each allocation, or we get wrong
      // address
      if (cuPointerGetAttribute(&base_ptr,
@@ -331,8 +328,8 @@ class CustomAllreduce {
                                (CUdeviceptr)ptr) != CUDA_SUCCESS)
        throw std::runtime_error("failed to get pointer attr");
      CUDACHECK(cudaIpcGetMemHandle(
-          (cudaIpcMemHandle_t *)&handles[i * handle_sz], base_ptr));
+          (cudaIpcMemHandle_t*)&handles[i * handle_sz], base_ptr));
-      offsets[i] = ((char *)ptr) - ((char *)base_ptr);
+      offsets[i] = ((char*)ptr) - ((char*)base_ptr);
    }
    return std::make_pair(handles, offsets);
  }
@@ -344,13 +341,13 @@ class CustomAllreduce {
          std::to_string(d_rank_data_base_ + num - d_rank_data_end_));
  }
-  void register_buffer(const std::vector<std::string> &handles,
+  void register_buffer(const std::vector<std::string>& handles,
-                       const std::vector<int64_t> &offsets, void *self) {
+                       const std::vector<int64_t>& offsets, void* self) {
    check_rank_data_capacity();
    RankData data;
    for (int i = 0; i < world_size_; i++) {
      if (i != rank_) {
-        char *handle = open_ipc_handle(handles[i].data());
+        char* handle = open_ipc_handle(handles[i].data());
        handle += offsets[i];
        data.ptrs[i] = handle;
      } else {
@@ -371,17 +368,17 @@ class CustomAllreduce {
  // got a different address. IPC handles have internal reference counting
  // mechanism so overhead should be small.
  void register_graph_buffers(
-      const std::vector<std::string> &handles,
+      const std::vector<std::string>& handles,
-      const std::vector<std::vector<int64_t>> &offsets) {
+      const std::vector<std::vector<int64_t>>& offsets) {
    auto num_buffers = graph_unreg_buffers_.size();
    check_rank_data_capacity(num_buffers);
    std::vector<RankData> rank_data(num_buffers);
    for (int i = 0; i < num_buffers; i++) {
      auto self_ptr = graph_unreg_buffers_[i];
-      auto &rd = rank_data[i];
+      auto& rd = rank_data[i];
      for (int j = 0; j < world_size_; j++) {
        if (j != rank_) {
-          char *handle =
+          char* handle =
              open_ipc_handle(&handles[j][i * sizeof(cudaIpcMemHandle_t)]);
          handle += offsets[j][i];
          rd.ptrs[j] = handle;
@@ -405,7 +402,7 @@ class CustomAllreduce {
   * will cause contention on NVLink bus.
   */
  template <typename T>
-  void allreduce(cudaStream_t stream, T *input, T *output, int size,
+  void allreduce(cudaStream_t stream, T* input, T* output, int size,
                 int threads = 512, int block_limit = 36) {
    auto d = packed_t<T>::P::size;
    if (size % d != 0)
@@ -418,7 +415,7 @@ class CustomAllreduce {
                               std::to_string(kMaxBlocks) + ". Got " +
                               std::to_string(block_limit));
-    RankData *ptrs;
+    RankData* ptrs;
    cudaStreamCaptureStatus status;
    CUDACHECK(cudaStreamIsCapturing(stream, &status));
    if (status == cudaStreamCaptureStatusActive) {
--- a/csrc/custom_all_reduce_test.cu
+++ b/csrc/custom_all_reduce_test.cu
@@ -48,7 +48,7 @@ __global__ void dummy_kernel() {
 }
 template <typename T>
-__global__ void set_data(T *data, int size, int myRank) {
+__global__ void set_data(T* data, int size, int myRank) {
  for (int idx = blockIdx.x * blockDim.x + threadIdx.x; idx < size;
       idx += gridDim.x * blockDim.x) {
    data[idx] = myRank * 0.11f;
@@ -56,8 +56,8 @@ __global__ void set_data(T *data, int size, int myRank) {
 }
 template <typename T>
-__global__ void convert_data(const T *data1, const T *data2, double *fdata1,
+__global__ void convert_data(const T* data1, const T* data2, double* fdata1,
-                             double *fdata2, int size) {
+                             double* fdata2, int size) {
  for (int idx = blockIdx.x * blockDim.x + threadIdx.x; idx < size;
       idx += gridDim.x * blockDim.x) {
    fdata1[idx] = data1[idx];
@@ -65,7 +65,7 @@ __global__ void convert_data(const T *data1, const T *data2, double *fdata1,
  }
 }
-__global__ void init_rand(curandState_t *state, int size, int nRanks) {
+__global__ void init_rand(curandState_t* state, int size, int nRanks) {
  for (int idx = blockIdx.x * blockDim.x + threadIdx.x; idx < size;
       idx += gridDim.x * blockDim.x) {
    for (int i = 0; i < nRanks; i++) {
@@ -75,7 +75,7 @@ __global__ void init_rand(curandState_t *state, int size, int nRanks) {
 }
 template <typename T>
-__global__ void gen_data(curandState_t *state, T *data, double *ground_truth,
+__global__ void gen_data(curandState_t* state, T* data, double* ground_truth,
                         int myRank, int nRanks, int size) {
  for (int idx = blockIdx.x * blockDim.x + threadIdx.x; idx < size;
       idx += gridDim.x * blockDim.x) {
@@ -91,9 +91,9 @@ __global__ void gen_data(curandState_t *state, T *data, double *ground_truth,
 }
 template <typename T>
-void run(int myRank, int nRanks, ncclComm_t &comm, int threads, int block_limit,
+void run(int myRank, int nRanks, ncclComm_t& comm, int threads, int block_limit,
         int data_size, bool performance_test) {
-  T *result;
+  T* result;
  cudaStream_t stream;
  CUDACHECK(cudaStreamCreateWithFlags(&stream, cudaStreamNonBlocking));
  CUDACHECK(cudaMalloc(&result, data_size * sizeof(T)));
@@ -101,8 +101,8 @@ void run(int myRank, int nRanks, ncclComm_t &comm, int threads, int block_limit,
  cudaIpcMemHandle_t self_data_handle;
  cudaIpcMemHandle_t data_handles[8];
-  vllm::Signal *buffer;
+  vllm::Signal* buffer;
-  T *self_data_copy;
+  T* self_data_copy;
  /**
   * Allocate IPC buffer
   *
@@ -125,22 +125,22 @@ void run(int myRank, int nRanks, ncclComm_t &comm, int threads, int block_limit,
                         MPI_BYTE, data_handles, sizeof(cudaIpcMemHandle_t),
                         MPI_BYTE, MPI_COMM_WORLD));
-  void *rank_data;
+  void* rank_data;
  size_t rank_data_sz = 16 * 1024 * 1024;
  CUDACHECK(cudaMalloc(&rank_data, rank_data_sz));
  std::vector<int64_t> offsets(nRanks, 0);
  vllm::CustomAllreduce fa(buffer, rank_data, rank_data_sz, data_handles,
                           offsets, myRank);
-  auto *self_data =
+  auto* self_data =
-      reinterpret_cast<T *>(reinterpret_cast<char *>(buffer) +
+      reinterpret_cast<T*>(reinterpret_cast<char*>(buffer) +
-                            sizeof(vllm::Signal) + data_size * sizeof(T));
+                           sizeof(vllm::Signal) + data_size * sizeof(T));
  // hack buffer registration
  {
    std::vector<std::string> handles;
    handles.reserve(nRanks);
    for (int i = 0; i < nRanks; i++) {
-      char *begin = (char *)&data_handles[i];
+      char* begin = (char*)&data_handles[i];
-      char *end = (char *)&data_handles[i + 1];
+      char* end = (char*)&data_handles[i + 1];
      handles.emplace_back(begin, end);
    }
    std::vector<int64_t> offsets(nRanks,
@@ -148,9 +148,9 @@ void run(int myRank, int nRanks, ncclComm_t &comm, int threads, int block_limit,
    fa.register_buffer(handles, offsets, self_data);
  }
-  double *ground_truth;
+  double* ground_truth;
  CUDACHECK(cudaMallocHost(&ground_truth, data_size * sizeof(double)));
-  curandState_t *states;
+  curandState_t* states;
  CUDACHECK(cudaMalloc(&states, sizeof(curandState_t) * nRanks * data_size));
  init_rand<<<108, 1024, 0, stream>>>(states, data_size, nRanks);
  gen_data<T><<<108, 1024, 0, stream>>>(states, self_data, ground_truth, myRank,
@@ -287,7 +287,7 @@ void run(int myRank, int nRanks, ncclComm_t &comm, int threads, int block_limit,
  CUDACHECK(cudaStreamDestroy(stream));
 }
-int main(int argc, char **argv) {
+int main(int argc, char** argv) {
  int nRanks, myRank;
  MPICHECK(MPI_Init(&argc, &argv));
  MPICHECK(MPI_Comm_rank(MPI_COMM_WORLD, &myRank));
@@ -296,7 +296,7 @@ int main(int argc, char **argv) {
  ncclUniqueId id;
  ncclComm_t comm;
  if (myRank == 0) ncclGetUniqueId(&id);
-  MPICHECK(MPI_Bcast(static_cast<void *>(&id), sizeof(id), MPI_BYTE, 0,
+  MPICHECK(MPI_Bcast(static_cast<void*>(&id), sizeof(id), MPI_BYTE, 0,
                     MPI_COMM_WORLD));
  NCCLCHECK(ncclCommInitRank(&comm, nRanks, id, myRank));
--- a/csrc/dispatch_utils.h
+++ b/csrc/dispatch_utils.h
@@ -4,34 +4,32 @@
 */
 #pragma once
-#include <torch/extension.h>
+#include <torch/all.h>
-#define VLLM_DISPATCH_CASE_FLOATING_TYPES(...)              \
+#define VLLM_DISPATCH_CASE_FLOATING_TYPES(...)         \
-  AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__)      \
+  AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__) \
-  AT_DISPATCH_CASE(at::ScalarType::Half, __VA_ARGS__)       \
+  AT_DISPATCH_CASE(at::ScalarType::Half, __VA_ARGS__)  \
  AT_DISPATCH_CASE(at::ScalarType::BFloat16, __VA_ARGS__)
-#define VLLM_DISPATCH_FLOATING_TYPES(TYPE, NAME, ...)             \
+#define VLLM_DISPATCH_FLOATING_TYPES(TYPE, NAME, ...) \
-  AT_DISPATCH_SWITCH(                                             \
+  AT_DISPATCH_SWITCH(TYPE, NAME, VLLM_DISPATCH_CASE_FLOATING_TYPES(__VA_ARGS__))
    TYPE, NAME, VLLM_DISPATCH_CASE_FLOATING_TYPES(__VA_ARGS__))
-#define VLLM_DISPATCH_CASE_FLOATING_AND_BYTE_TYPES(...)     \
+#define VLLM_DISPATCH_CASE_FLOATING_AND_BYTE_TYPES(...)   \
-  AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__)      \
+  AT_DISPATCH_CASE(at::ScalarType::Float, __VA_ARGS__)    \
-  AT_DISPATCH_CASE(at::ScalarType::Half, __VA_ARGS__)       \
+  AT_DISPATCH_CASE(at::ScalarType::Half, __VA_ARGS__)     \
-  AT_DISPATCH_CASE(at::ScalarType::BFloat16, __VA_ARGS__)   \
+  AT_DISPATCH_CASE(at::ScalarType::BFloat16, __VA_ARGS__) \
  AT_DISPATCH_CASE(at::ScalarType::Byte, __VA_ARGS__)
-#define VLLM_DISPATCH_FLOATING_AND_BYTE_TYPES(TYPE, NAME, ...)           \
+#define VLLM_DISPATCH_FLOATING_AND_BYTE_TYPES(TYPE, NAME, ...) \
-  AT_DISPATCH_SWITCH(                                                    \
+  AT_DISPATCH_SWITCH(TYPE, NAME,                               \
-    TYPE, NAME, VLLM_DISPATCH_CASE_FLOATING_AND_BYTE_TYPES(__VA_ARGS__))
+                     VLLM_DISPATCH_CASE_FLOATING_AND_BYTE_TYPES(__VA_ARGS__))
-#define VLLM_DISPATCH_CASE_INTEGRAL_TYPES(...)             \
+#define VLLM_DISPATCH_CASE_INTEGRAL_TYPES(...)         \
-  AT_DISPATCH_CASE(at::ScalarType::Byte, __VA_ARGS__)      \
+  AT_DISPATCH_CASE(at::ScalarType::Byte, __VA_ARGS__)  \
-  AT_DISPATCH_CASE(at::ScalarType::Char, __VA_ARGS__)      \
+  AT_DISPATCH_CASE(at::ScalarType::Char, __VA_ARGS__)  \
-  AT_DISPATCH_CASE(at::ScalarType::Short, __VA_ARGS__)     \
+  AT_DISPATCH_CASE(at::ScalarType::Short, __VA_ARGS__) \
-  AT_DISPATCH_CASE(at::ScalarType::Int, __VA_ARGS__)       \
+  AT_DISPATCH_CASE(at::ScalarType::Int, __VA_ARGS__)   \
  AT_DISPATCH_CASE(at::ScalarType::Long, __VA_ARGS__)
-#define VLLM_DISPATCH_INTEGRAL_TYPES(TYPE, NAME, ...)             \
+#define VLLM_DISPATCH_INTEGRAL_TYPES(TYPE, NAME, ...) \
-  AT_DISPATCH_SWITCH(                                             \
+  AT_DISPATCH_SWITCH(TYPE, NAME, VLLM_DISPATCH_CASE_INTEGRAL_TYPES(__VA_ARGS__))
    TYPE, NAME, VLLM_DISPATCH_CASE_INTEGRAL_TYPES(__VA_ARGS__))
--- a/csrc/layernorm_kernels.cu
+++ b/csrc/layernorm_kernels.cu
@@ -1,26 +1,34 @@
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <ATen/cuda/CUDAContext.h>
 #include <c10/cuda/CUDAGuard.h>
 #include "dispatch_utils.h"
 #include "reduction_utils.cuh"
 #ifndef USE_ROCM
  #include <cuda_bf16.h>
  #include <cuda_fp16.h>
 #else
  #include <hip/hip_bf16.h>
  #include <hip/hip_fp16.h>
 using __nv_bfloat16 = __hip_bfloat16;
 using __nv_bfloat162 = __hip_bfloat162;
 #endif
 namespace vllm {
 // TODO(woosuk): Further optimize this kernel.
-template<typename scalar_t>
+template <typename scalar_t>
 __global__ void rms_norm_kernel(
-  scalar_t* __restrict__ out,             // [..., hidden_size]
+    scalar_t* __restrict__ out,           // [..., hidden_size]
-  const scalar_t* __restrict__ input,     // [..., hidden_size]
+    const scalar_t* __restrict__ input,   // [..., hidden_size]
-  const scalar_t* __restrict__ weight,    // [hidden_size]
+    const scalar_t* __restrict__ weight,  // [hidden_size]
-  const float epsilon,
+    const float epsilon, const int num_tokens, const int hidden_size) {
  const int num_tokens,
  const int hidden_size) {
  __shared__ float s_variance;
  float variance = 0.0f;
  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
-    const float x = (float) input[blockIdx.x * hidden_size + idx];
+    const float x = (float)input[blockIdx.x * hidden_size + idx];
    variance += x * x;
  }
  variance = blockReduceSum<float>(variance);
@@ -30,48 +38,260 @@ __global__ void rms_norm_kernel(
  __syncthreads();
  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
-    float x = (float) input[blockIdx.x * hidden_size + idx];
+    float x = (float)input[blockIdx.x * hidden_size + idx];
-    out[blockIdx.x * hidden_size + idx] = ((scalar_t) (x * s_variance)) * weight[idx];
+    out[blockIdx.x * hidden_size + idx] =
        ((scalar_t)(x * s_variance)) * weight[idx];
  }
 }
-// TODO: Further optimize this kernel.
+/* Converter structs for the conversion from torch types to HIP/CUDA types,
-template<typename scalar_t>
+   and the associated type conversions within HIP/CUDA. These helpers need
-__global__ void fused_add_rms_norm_kernel(
+   to be implemented for now because the relevant type conversion
-  scalar_t* __restrict__ input,           // [..., hidden_size]
+   operators/constructors are not consistently implemented by HIP/CUDA, so
-  scalar_t* __restrict__ residual,        // [..., hidden_size]
+   a generic conversion via type casts cannot be implemented.
-  const scalar_t* __restrict__ weight,    // [hidden_size]
+
-  const float epsilon,
+   Each struct should have the member static constexpr bool `exists`:
-  const int num_tokens,
+   If false, the optimized kernel is not used for the corresponding torch type.
-  const int hidden_size) {
+   If true, the struct should be fully defined as shown in the examples below.
 */
 template <typename torch_type>
 struct _typeConvert {
  static constexpr bool exists = false;
 };
 #if defined(USE_ROCM) || (defined(CUDA_VERSION) && (CUDA_VERSION >= 12000))
 // CUDA < 12.0 runs into issues with packed type conversion
 template <>
 struct _typeConvert<c10::Half> {
  static constexpr bool exists = true;
  using hip_type = __half;
  using packed_hip_type = __half2;
  __device__ static inline float convert(hip_type x) { return __half2float(x); }
  __device__ static inline float2 convert(packed_hip_type x) {
    return __half22float2(x);
  }
  __device__ static inline hip_type convert(float x) {
    return __float2half_rn(x);
  }
  __device__ static inline packed_hip_type convert(float2 x) {
    return __float22half2_rn(x);
  }
 };
  #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
 // CUDA_ARCH < 800 does not have BF16 support
 // TODO: Add in ROCm support once public headers handle bf16 maturely
 template <>
 struct _typeConvert<c10::BFloat16> {
  static constexpr bool exists = true;
  using hip_type = __nv_bfloat16;
  using packed_hip_type = __nv_bfloat162;
  __device__ static inline float convert(hip_type x) {
    return __bfloat162float(x);
  }
  __device__ static inline float2 convert(packed_hip_type x) {
    return __bfloat1622float2(x);
  }
  __device__ static inline hip_type convert(float x) {
    return __float2bfloat16(x);
  }
  __device__ static inline packed_hip_type convert(float2 x) {
    return __float22bfloat162_rn(x);
  }
 };
  #endif  // defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
 #endif    // defined(USE_ROCM) || (defined(CUDA_VERSION) && (CUDA_VERSION >=
          // 12000))
 /* Vector POD struct to generate vectorized and packed FP16/BF16 ops
   for appropriate specializations of fused_add_rms_norm_kernel.
   Only functions that are necessary in that kernel are implemented.
   Alignment to 16 bytes is required to use 128-bit global memory ops.
 */
 template <typename scalar_t, int width>
 struct alignas(16) _f16Vec {
  /* Not theoretically necessary that width is a power of 2 but should
     almost always be the case for optimization purposes */
  static_assert(width > 0 && (width & (width - 1)) == 0,
                "Width is not a positive power of 2!");
  using Converter = _typeConvert<scalar_t>;
  using T1 = typename Converter::hip_type;
  using T2 = typename Converter::packed_hip_type;
  T1 data[width];
  __device__ _f16Vec& operator+=(const _f16Vec<scalar_t, width>& other) {
    if constexpr (width % 2 == 0) {
 #pragma unroll
      for (int i = 0; i < width; i += 2) {
        T2 temp{data[i], data[i + 1]};
        temp += T2{other.data[i], other.data[i + 1]};
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
 #pragma unroll
      for (int i = 0; i < width; ++i) data[i] += other.data[i];
    }
    return *this;
  }
  __device__ _f16Vec& operator*=(const _f16Vec<scalar_t, width>& other) {
    if constexpr (width % 2 == 0) {
 #pragma unroll
      for (int i = 0; i < width; i += 2) {
        T2 temp{data[i], data[i + 1]};
        temp *= T2{other.data[i], other.data[i + 1]};
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
 #pragma unroll
      for (int i = 0; i < width; ++i) data[i] *= other.data[i];
    }
    return *this;
  }
  __device__ _f16Vec& operator*=(const float scale) {
    if constexpr (width % 2 == 0) {
 #pragma unroll
      for (int i = 0; i < width; i += 2) {
        float2 temp_f = Converter::convert(T2{data[i], data[i + 1]});
        temp_f.x *= scale;
        temp_f.y *= scale;
        T2 temp = Converter::convert(temp_f);
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
 #pragma unroll
      for (int i = 0; i < width; ++i) {
        float temp = Converter::convert(data[i]) * scale;
        data[i] = Converter::convert(temp);
      }
    }
    return *this;
  }
  __device__ float sum_squares() const {
    float result = 0.0f;
    if constexpr (width % 2 == 0) {
 #pragma unroll
      for (int i = 0; i < width; i += 2) {
        float2 z = Converter::convert(T2{data[i], data[i + 1]});
        result += z.x * z.x + z.y * z.y;
      }
    } else {
 #pragma unroll
      for (int i = 0; i < width; ++i) {
        float x = Converter::convert(data[i]);
        result += x * x;
      }
    }
    return result;
  }
 };
 /* Function specialization in the case of FP16/BF16 tensors.
   Additional optimizations we can make in this case are
   packed and vectorized operations, which help with the
   memory latency bottleneck. */
 template <typename scalar_t, int width>
 __global__ std::enable_if_t<(width > 0) && _typeConvert<scalar_t>::exists>
 fused_add_rms_norm_kernel(
    scalar_t* __restrict__ input,         // [..., hidden_size]
    scalar_t* __restrict__ residual,      // [..., hidden_size]
    const scalar_t* __restrict__ weight,  // [hidden_size]
    const float epsilon, const int num_tokens, const int hidden_size) {
  // Sanity checks on our vector struct and type-punned pointer arithmetic
  static_assert(std::is_pod_v<_f16Vec<scalar_t, width>>);
  static_assert(sizeof(_f16Vec<scalar_t, width>) == sizeof(scalar_t) * width);
  const int vec_hidden_size = hidden_size / width;
  __shared__ float s_variance;
  float variance = 0.0f;
  /* These and the argument pointers are all declared `restrict` as they are
     not aliased in practice. Argument pointers should not be dereferenced
     in this kernel as that would be undefined behavior */
  auto* __restrict__ input_v =
      reinterpret_cast<_f16Vec<scalar_t, width>*>(input);
  auto* __restrict__ residual_v =
      reinterpret_cast<_f16Vec<scalar_t, width>*>(residual);
  auto* __restrict__ weight_v =
      reinterpret_cast<const _f16Vec<scalar_t, width>*>(weight);
  for (int idx = threadIdx.x; idx < vec_hidden_size; idx += blockDim.x) {
    int id = blockIdx.x * vec_hidden_size + idx;
    _f16Vec<scalar_t, width> temp = input_v[id];
    temp += residual_v[id];
    variance += temp.sum_squares();
    residual_v[id] = temp;
  }
  /* Keep the following if-else block in sync with the
     calculation of max_block_size in fused_add_rms_norm */
  if (num_tokens < 256) {
    variance = blockReduceSum<float, 1024>(variance);
  } else
    variance = blockReduceSum<float, 256>(variance);
  if (threadIdx.x == 0) {
    s_variance = rsqrtf(variance / hidden_size + epsilon);
  }
  __syncthreads();
  for (int idx = threadIdx.x; idx < vec_hidden_size; idx += blockDim.x) {
    int id = blockIdx.x * vec_hidden_size + idx;
    _f16Vec<scalar_t, width> temp = residual_v[id];
    temp *= s_variance;
    temp *= weight_v[idx];
    input_v[id] = temp;
  }
 }
 /* Generic fused_add_rms_norm_kernel
   The width field is not used here but necessary for other specializations.
 */
 template <typename scalar_t, int width>
 __global__ std::enable_if_t<(width == 0) || !_typeConvert<scalar_t>::exists>
 fused_add_rms_norm_kernel(
    scalar_t* __restrict__ input,         // [..., hidden_size]
    scalar_t* __restrict__ residual,      // [..., hidden_size]
    const scalar_t* __restrict__ weight,  // [hidden_size]
    const float epsilon, const int num_tokens, const int hidden_size) {
  __shared__ float s_variance;
  float variance = 0.0f;
  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
-    float x = (float) input[blockIdx.x * hidden_size + idx];
+    scalar_t z = input[blockIdx.x * hidden_size + idx];
-    x += (float) residual[blockIdx.x * hidden_size + idx];
+    z += residual[blockIdx.x * hidden_size + idx];
    float x = (float)z;
    variance += x * x;
-    residual[blockIdx.x * hidden_size + idx] = (scalar_t) x;
+    residual[blockIdx.x * hidden_size + idx] = z;
  }
-  variance = blockReduceSum<float>(variance);
+  /* Keep the following if-else block in sync with the
     calculation of max_block_size in fused_add_rms_norm */
  if (num_tokens < 256) {
    variance = blockReduceSum<float, 1024>(variance);
  } else
    variance = blockReduceSum<float, 256>(variance);
  if (threadIdx.x == 0) {
    s_variance = rsqrtf(variance / hidden_size + epsilon);
  }
  __syncthreads();
  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
-    float x = (float) residual[blockIdx.x * hidden_size + idx];
+    float x = (float)residual[blockIdx.x * hidden_size + idx];
-    input[blockIdx.x * hidden_size + idx] = ((scalar_t) (x * s_variance)) * weight[idx];
+    input[blockIdx.x * hidden_size + idx] =
        ((scalar_t)(x * s_variance)) * weight[idx];
  }
 }
-} // namespace vllm
+}  // namespace vllm
-void rms_norm(
+void rms_norm(torch::Tensor& out,     // [..., hidden_size]
-  torch::Tensor& out,      // [..., hidden_size]
+              torch::Tensor& input,   // [..., hidden_size]
-  torch::Tensor& input,    // [..., hidden_size]
+              torch::Tensor& weight,  // [hidden_size]
-  torch::Tensor& weight,   // [hidden_size]
+              double epsilon) {
  float epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
@@ -79,42 +299,54 @@ void rms_norm(
  dim3 block(std::min(hidden_size, 1024));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  VLLM_DISPATCH_FLOATING_TYPES(
+  VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "rms_norm_kernel", [&] {
-    input.scalar_type(),
+    vllm::rms_norm_kernel<scalar_t><<<grid, block, 0, stream>>>(
-    "rms_norm_kernel",
+        out.data_ptr<scalar_t>(), input.data_ptr<scalar_t>(),
-    [&] {
+        weight.data_ptr<scalar_t>(), epsilon, num_tokens, hidden_size);
-      vllm::rms_norm_kernel<scalar_t><<<grid, block, 0, stream>>>(
+  });
        out.data_ptr<scalar_t>(),
        input.data_ptr<scalar_t>(),
        weight.data_ptr<scalar_t>(),
        epsilon,
        num_tokens,
        hidden_size);
    });
 }
-void fused_add_rms_norm(
+#define LAUNCH_FUSED_ADD_RMS_NORM(width)                                       \
-  torch::Tensor& input,    // [..., hidden_size]
+  VLLM_DISPATCH_FLOATING_TYPES(                                                \
-  torch::Tensor& residual, // [..., hidden_size]
+      input.scalar_type(), "fused_add_rms_norm_kernel", [&] {                  \
-  torch::Tensor& weight,   // [hidden_size]
+        vllm::fused_add_rms_norm_kernel<scalar_t, width>                       \
-  float epsilon) {
+            <<<grid, block, 0, stream>>>(input.data_ptr<scalar_t>(),           \
                                         residual.data_ptr<scalar_t>(),        \
                                         weight.data_ptr<scalar_t>(), epsilon, \
                                         num_tokens, hidden_size);             \
      });
 void fused_add_rms_norm(torch::Tensor& input,     // [..., hidden_size]
                        torch::Tensor& residual,  // [..., hidden_size]
                        torch::Tensor& weight,    // [hidden_size]
                        double epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
  dim3 grid(num_tokens);
-  dim3 block(std::min(hidden_size, 1024));
+  /* This kernel is memory-latency bound in many scenarios.
     When num_tokens is large, a smaller block size allows
     for increased block occupancy on CUs and better latency
     hiding on global mem ops. */
  const int max_block_size = (num_tokens < 256) ? 1024 : 256;
  dim3 block(std::min(hidden_size, max_block_size));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  VLLM_DISPATCH_FLOATING_TYPES(
+  /*If the tensor types are FP16/BF16, try to use the optimized kernel
-    input.scalar_type(),
+    with packed + vectorized ops.
-    "fused_add_rms_norm_kernel",
+    Max optimization is achieved with a width-8 vector of FP16/BF16s
-    [&] {
+    since we can load at most 128 bits at once in a global memory op.
-      vllm::fused_add_rms_norm_kernel<scalar_t><<<grid, block, 0, stream>>>(
+    However, this requires each tensor's data to be aligned to 16
-        input.data_ptr<scalar_t>(),
+    bytes.
-        residual.data_ptr<scalar_t>(),
+   */
-        weight.data_ptr<scalar_t>(),
+  auto inp_ptr = reinterpret_cast<std::uintptr_t>(input.data_ptr());
-        epsilon,
+  auto res_ptr = reinterpret_cast<std::uintptr_t>(residual.data_ptr());
-        num_tokens,
+  auto wt_ptr = reinterpret_cast<std::uintptr_t>(weight.data_ptr());
-        hidden_size);
+  bool ptrs_are_aligned =
-    });
+      inp_ptr % 16 == 0 && res_ptr % 16 == 0 && wt_ptr % 16 == 0;
  if (ptrs_are_aligned && hidden_size % 8 == 0) {
    LAUNCH_FUSED_ADD_RMS_NORM(8);
  } else {
    LAUNCH_FUSED_ADD_RMS_NORM(0);
  }
 }
--- a/csrc/moe/moe_ops.cpp
+++ b/csrc/moe/moe_ops.cpp
@@ -1,7 +0,0 @@
 #include "moe_ops.h"
 #include <torch/extension.h>
 PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
  m.def("topk_softmax", &topk_softmax, "Apply topk softmax to the gating outputs.");
 }
--- a/csrc/moe/moe_ops.h
+++ b/csrc/moe/moe_ops.h
@@ -1,9 +1,7 @@
 #pragma once
-#include <torch/extension.h>
+#include <torch/all.h>
-void topk_softmax(
+void topk_softmax(torch::Tensor& topk_weights, torch::Tensor& topk_indices,
-  torch::Tensor& topk_weights,
+                  torch::Tensor& token_expert_indices,
-  torch::Tensor& topk_indices,
+                  torch::Tensor& gating_output);
  torch::Tensor& token_expert_indices,
  torch::Tensor& gating_output);
--- a/csrc/moe/topk_softmax_kernels.cu
+++ b/csrc/moe/topk_softmax_kernels.cu
@@ -16,18 +16,25 @@
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <ATen/cuda/CUDAContext.h>
 #include <c10/cuda/CUDAGuard.h>
 #include "../cuda_compat.h"
-#include <cub/cub.cuh>
+#ifndef USE_ROCM
-#include <cub/util_type.cuh>
+    #include <cub/util_type.cuh>
    #include <cub/cub.cuh>
 #else
    #include <hipcub/util_type.hpp>
    #include <hipcub/hipcub.hpp>
 #endif
 #define MAX(a, b) ((a) > (b) ? (a) : (b))
 #define MIN(a, b) ((a) < (b) ? (a) : (b))
 namespace vllm {
 namespace moe {
 static constexpr int WARP_SIZE = 32;
 /// Aligned array type
 template <
    typename T,
@@ -265,7 +272,7 @@ __launch_bounds__(WARPS_PER_CTA* WARP_SIZE) __global__
 #pragma unroll
    for (int mask = THREADS_PER_ROW / 2; mask > 0; mask /= 2)
    {
-        thread_max = max(thread_max, __shfl_xor_sync(0xFFFFFFFF, thread_max, mask, THREADS_PER_ROW));
+        thread_max = max(thread_max, VLLM_SHFL_XOR_SYNC_WIDTH(thread_max, mask, THREADS_PER_ROW));
    }
    // From this point, thread max in all the threads have the max within the row.
@@ -282,7 +289,7 @@ __launch_bounds__(WARPS_PER_CTA* WARP_SIZE) __global__
 #pragma unroll
    for (int mask = THREADS_PER_ROW / 2; mask > 0; mask /= 2)
    {
-        row_sum += __shfl_xor_sync(0xFFFFFFFF, row_sum, mask, THREADS_PER_ROW);
+        row_sum += VLLM_SHFL_XOR_SYNC_WIDTH(row_sum, mask, THREADS_PER_ROW);
    }
    // From this point, all threads have the max and the sum for their rows in the thread_max and thread_sum variables
@@ -332,8 +339,8 @@ __launch_bounds__(WARPS_PER_CTA* WARP_SIZE) __global__
 #pragma unroll
        for (int mask = THREADS_PER_ROW / 2; mask > 0; mask /= 2)
        {
-            float other_max = __shfl_xor_sync(0xFFFFFFFF, max_val, mask, THREADS_PER_ROW);
+            float other_max = VLLM_SHFL_XOR_SYNC_WIDTH(max_val, mask, THREADS_PER_ROW);
-            int other_expert = __shfl_xor_sync(0xFFFFFFFF, expert, mask, THREADS_PER_ROW);
+            int other_expert = VLLM_SHFL_XOR_SYNC_WIDTH(expert, mask, THREADS_PER_ROW);
            // We want lower indices to "win" in every thread so we break ties this way
            if (other_max > max_val || (other_max == max_val && other_expert < expert))
@@ -383,7 +390,7 @@ struct TopkConstants
 {
    static constexpr int ELTS_PER_LDG = BYTES_PER_LDG / sizeof(float);
    static_assert(EXPERTS / (ELTS_PER_LDG * WARP_SIZE) == 0 || EXPERTS % (ELTS_PER_LDG * WARP_SIZE) == 0, "");
-    static constexpr int VECs_PER_THREAD = std::max(1, EXPERTS / (ELTS_PER_LDG * WARP_SIZE));
+    static constexpr int VECs_PER_THREAD = MAX(1, EXPERTS / (ELTS_PER_LDG * WARP_SIZE));
    static constexpr int VPT = VECs_PER_THREAD * ELTS_PER_LDG;
    static constexpr int THREADS_PER_ROW = EXPERTS / VPT;
    static constexpr int ROWS_PER_WARP = WARP_SIZE / THREADS_PER_ROW;
@@ -396,7 +403,7 @@ void topkGatingSoftmaxLauncherHelper(const float* input, const bool* finished, f
 {
    static constexpr std::size_t MAX_BYTES_PER_LDG = 16;
-    static constexpr int BYTES_PER_LDG = std::min(MAX_BYTES_PER_LDG, sizeof(float) * EXPERTS);
+    static constexpr int BYTES_PER_LDG = MIN(MAX_BYTES_PER_LDG, sizeof(float) * EXPERTS);
    using Constants = detail::TopkConstants<EXPERTS, BYTES_PER_LDG>;
    static constexpr int VPT = Constants::VPT;
    static constexpr int ROWS_PER_WARP = Constants::ROWS_PER_WARP;
--- a/csrc/moe/torch_bindings.cpp
+++ b/csrc/moe/torch_bindings.cpp
@@ -0,0 +1,12 @@
 #include "registration.h"
 #include "moe_ops.h"
 TORCH_LIBRARY_EXPAND(TORCH_EXTENSION_NAME, m) {
  // Apply topk softmax to the gating outputs.
  m.def(
      "topk_softmax(Tensor! topk_weights, Tensor! topk_indices, Tensor! "
      "token_expert_indices, Tensor gating_output) -> ()");
  m.impl("topk_softmax", torch::kCUDA, &topk_softmax);
 }
 REGISTER_EXTENSION(TORCH_EXTENSION_NAME)
--- a/csrc/moe_align_block_size_kernels.cu
+++ b/csrc/moe_align_block_size_kernels.cu
@@ -1,4 +1,4 @@
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <ATen/cuda/CUDAContext.h>
 #include <ATen/ATen.h>
@@ -7,119 +7,128 @@
 #include "cuda_compat.h"
 #include "dispatch_utils.h"
-#define CEILDIV(x,y) (((x) + (y) - 1) / (y))
+#define CEILDIV(x, y) (((x) + (y) - 1) / (y))
 namespace vllm {
 namespace {
-__device__ __forceinline__ int32_t index(int32_t total_col, int32_t row, int32_t col) {
+__device__ __forceinline__ int32_t index(int32_t total_col, int32_t row,
-    // don't worry about overflow because num_experts is relatively small
+                                         int32_t col) {
-    return row * total_col + col;
+  // don't worry about overflow because num_experts is relatively small
-}
+  return row * total_col + col;
 }
 }  // namespace
 template <typename scalar_t>
-__global__ void moe_align_block_size_kernel(scalar_t *__restrict__ topk_ids, 
+__global__ void moe_align_block_size_kernel(scalar_t* __restrict__ topk_ids,
-                                int32_t *sorted_token_ids, 
+                                            int32_t* sorted_token_ids,
-                                int32_t *expert_ids, 
+                                            int32_t* expert_ids,
-                                int32_t *total_tokens_post_pad,
+                                            int32_t* total_tokens_post_pad,
-                                int32_t num_experts, 
+                                            int32_t num_experts,
-                                int32_t block_size, 
+                                            int32_t block_size, size_t numel) {
-                                size_t numel) {
+  const size_t tokens_per_thread = CEILDIV(numel, blockDim.x);
-    const size_t tokens_per_thread = CEILDIV(numel, blockDim.x);
+  const size_t start_idx = threadIdx.x * tokens_per_thread;
    const size_t start_idx = threadIdx.x * tokens_per_thread;
-    extern __shared__ int32_t shared_mem[];
+  extern __shared__ int32_t shared_mem[];
-    int32_t* tokens_cnts = shared_mem; // 2d tensor with shape (num_experts + 1, num_experts)
+  int32_t* tokens_cnts =
-    int32_t* cumsum = shared_mem + (num_experts + 1) * num_experts; // 1d tensor with shape (num_experts + 1)
+      shared_mem;  // 2d tensor with shape (num_experts + 1, num_experts)
  int32_t* cumsum =
      shared_mem + (num_experts + 1) *
                       num_experts;  // 1d tensor with shape (num_experts + 1)
-    for (int i = 0; i < num_experts; ++i) {
+  for (int i = 0; i < num_experts; ++i) {
-        tokens_cnts[index(num_experts, threadIdx.x + 1, i)] = 0;
+    tokens_cnts[index(num_experts, threadIdx.x + 1, i)] = 0;
  }
  /**
   * In the first step we compute token_cnts[thread_index + 1][expert_index],
   * which counts how many tokens in the token shard of thread_index are
   * assigned to expert expert_index.
   */
  for (int i = start_idx; i < numel && i < start_idx + tokens_per_thread; ++i) {
    ++tokens_cnts[index(num_experts, threadIdx.x + 1, topk_ids[i])];
  }
  __syncthreads();
  // For each expert we accumulate the token counts from the different threads.
  tokens_cnts[index(num_experts, 0, threadIdx.x)] = 0;
  for (int i = 1; i <= blockDim.x; ++i) {
    tokens_cnts[index(num_experts, i, threadIdx.x)] +=
        tokens_cnts[index(num_experts, i - 1, threadIdx.x)];
  }
  __syncthreads();
  // We accumulate the token counts of all experts in thread 0.
  if (threadIdx.x == 0) {
    cumsum[0] = 0;
    for (int i = 1; i <= num_experts; ++i) {
      cumsum[i] = cumsum[i - 1] +
                  CEILDIV(tokens_cnts[index(num_experts, blockDim.x, i - 1)],
                          block_size) *
                      block_size;
    }
    *total_tokens_post_pad = cumsum[num_experts];
  }
-    /**
+  __syncthreads();
    * In the first step we compute token_cnts[thread_index + 1][expert_index],
    * which counts how many tokens in the token shard of thread_index are assigned
    * to expert expert_index.
    */
    for (int i = start_idx; i < numel && i < start_idx + tokens_per_thread; ++i) {
        ++tokens_cnts[index(num_experts, threadIdx.x + 1, topk_ids[i])]; 
    }
-    __syncthreads();
+  /**
   * For each expert, each thread processes the tokens of the corresponding
   * blocks and stores the corresponding expert_id for each block.
   */
  for (int i = cumsum[threadIdx.x]; i < cumsum[threadIdx.x + 1];
       i += block_size) {
    expert_ids[i / block_size] = threadIdx.x;
  }
-    // For each expert we accumulate the token counts from the different threads.
+  /**
-    tokens_cnts[index(num_experts, 0, threadIdx.x)] = 0;
+   * Each thread processes a token shard, calculating the index of each token
-    for (int i = 1; i <= blockDim.x; ++i) {
+   * after sorting by expert number. Given the example topk_ids =
-        tokens_cnts[index(num_experts, i, threadIdx.x)] += tokens_cnts[index(num_experts, i-1, threadIdx.x)];
+   * [0,1,2,1,2,3,0,3,4] and block_size = 4, then the output would be [0, 6, *,
-    }
+   * *, 1, 3, *, *, 2, 4, *, *, 5, 7, *, *, 8, *, *, *], where * represents a
-
+   * padding value(preset in python).
-    __syncthreads();
+   */
-    
+  for (int i = start_idx; i < numel && i < start_idx + tokens_per_thread; ++i) {
-    // We accumulate the token counts of all experts in thread 0.
+    int32_t expert_id = topk_ids[i];
-    if (threadIdx.x == 0) {
+    /** The cumsum[expert_id] stores the starting index of the tokens that the
-        cumsum[0] = 0;
+     * expert with expert_id needs to process, and
-        for (int i = 1; i <= num_experts; ++i) {
+     * tokens_cnts[threadIdx.x][expert_id] stores the indices of the tokens
-            cumsum[i] = cumsum[i-1] + CEILDIV(tokens_cnts[index(num_experts, blockDim.x, i - 1)], block_size) * block_size;
+     * processed by the expert with expert_id within the current thread's token
-        }
+     * shard.
-        *total_tokens_post_pad = cumsum[num_experts];
+     */
-    }
+    int32_t rank_post_pad =
-
+        tokens_cnts[index(num_experts, threadIdx.x, expert_id)] +
-    __syncthreads();
+        cumsum[expert_id];
-
+    sorted_token_ids[rank_post_pad] = i;
-    /**
+    ++tokens_cnts[index(num_experts, threadIdx.x, expert_id)];
-    * For each expert, each thread processes the tokens of the corresponding blocks
+  }
    * and stores the corresponding expert_id for each block.
    */
    for (int i = cumsum[threadIdx.x];i < cumsum[threadIdx.x + 1];i += block_size) {
        expert_ids[i / block_size] = threadIdx.x;
    }
    /**
    * Each thread processes a token shard, calculating the index of each token after
    * sorting by expert number. Given the example topk_ids = [0,1,2,1,2,3,0,3,4] and
    * block_size = 4, then the output would be [0, 6, *, *, 1, 3, *, *, 2, 4, *, *, 5, 7, *, *, 8, *, *, *],
    * where * represents a padding value(preset in python).
    */
    for (int i = start_idx; i < numel && i < start_idx + tokens_per_thread; ++i) {
        int32_t expert_id = topk_ids[i];
        /** The cumsum[expert_id] stores the starting index of the tokens that the
        * expert with expert_id needs to process, and tokens_cnts[threadIdx.x][expert_id]
        * stores the indices of the tokens processed by the expert with expert_id within
        * the current thread's token shard.
        */
        int32_t rank_post_pad = tokens_cnts[index(num_experts, threadIdx.x, expert_id)] + cumsum[expert_id];
        sorted_token_ids[rank_post_pad] = i;
        ++tokens_cnts[index(num_experts, threadIdx.x, expert_id)];
    }
 }
 }
 }  // namespace vllm
-void moe_align_block_size(
+void moe_align_block_size(torch::Tensor topk_ids, int64_t num_experts,
-    torch::Tensor topk_ids,
+                          int64_t block_size, torch::Tensor sorted_token_ids,
-    int num_experts,
+                          torch::Tensor experts_ids,
-    int block_size,
+                          torch::Tensor num_tokens_post_pad) {
-    torch::Tensor sorted_token_ids,
+  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-    torch::Tensor experts_ids,
+  VLLM_DISPATCH_INTEGRAL_TYPES(
-    torch::Tensor num_tokens_post_pad) {
+      topk_ids.scalar_type(), "moe_align_block_size_kernel", [&] {
-    const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
+        // calc needed amount of shared mem for `tokens_cnts` and `cumsum`
-    VLLM_DISPATCH_INTEGRAL_TYPES(
+        // tensors
-        topk_ids.scalar_type(), "moe_align_block_size_kernel", [&] {
+        const int32_t shared_mem =
-        // calc needed amount of shared mem for `tokens_cnts` and `cumsum` tensors
+            ((num_experts + 1) * num_experts + (num_experts + 1)) *
-        const int32_t shared_mem = ((num_experts + 1) * num_experts + (num_experts + 1)) * sizeof(int32_t);
+            sizeof(int32_t);
        // set dynamic shared mem
        auto kernel = vllm::moe_align_block_size_kernel<scalar_t>;
-        AT_CUDA_CHECK(
+        AT_CUDA_CHECK(VLLM_DevFuncAttribute_SET_MaxDynamicSharedMemorySize(
-            VLLM_DevFuncAttribute_SET_MaxDynamicSharedMemorySize((void *)kernel, shared_mem));
+            (void*)kernel, shared_mem));
        kernel<<<1, num_experts, shared_mem, stream>>>(
-            topk_ids.data_ptr<scalar_t>(),
+            topk_ids.data_ptr<scalar_t>(), sorted_token_ids.data_ptr<int32_t>(),
            sorted_token_ids.data_ptr<int32_t>(), 
            experts_ids.data_ptr<int32_t>(),
-            num_tokens_post_pad.data_ptr<int32_t>(), 
+            num_tokens_post_pad.data_ptr<int32_t>(), num_experts, block_size,
            num_experts,
            block_size,
            topk_ids.numel());
-    });
+      });
 }
--- a/csrc/ops.h
+++ b/csrc/ops.h
@@ -1,159 +1,146 @@
 #pragma once
-#include <torch/extension.h>
+#include <torch/library.h>
 void paged_attention_v1(
-  torch::Tensor& out,
+    torch::Tensor& out, torch::Tensor& query, torch::Tensor& key_cache,
-  torch::Tensor& query,
+    torch::Tensor& value_cache, int64_t num_kv_heads, double scale,
-  torch::Tensor& key_cache,
+    torch::Tensor& block_tables, torch::Tensor& seq_lens, int64_t block_size,
-  torch::Tensor& value_cache,
+    int64_t max_seq_len, const c10::optional<torch::Tensor>& alibi_slopes,
-  int num_kv_heads,
+    const std::string& kv_cache_dtype, double kv_scale, const int64_t tp_rank,
-  float scale,
+    const int64_t blocksparse_local_blocks,
-  torch::Tensor& block_tables,
+    const int64_t blocksparse_vert_stride, const int64_t blocksparse_block_size,
-  torch::Tensor& context_lens,
+    const int64_t blocksparse_head_sliding_step);
  int block_size,
  int max_context_len,
  const c10::optional<torch::Tensor>& alibi_slopes,
  const std::string& kv_cache_dtype);
 void paged_attention_v2(
-  torch::Tensor& out,
+    torch::Tensor& out, torch::Tensor& exp_sums, torch::Tensor& max_logits,
-  torch::Tensor& exp_sums,
+    torch::Tensor& tmp_out, torch::Tensor& query, torch::Tensor& key_cache,
-  torch::Tensor& max_logits,
+    torch::Tensor& value_cache, int64_t num_kv_heads, double scale,
-  torch::Tensor& tmp_out,
+    torch::Tensor& block_tables, torch::Tensor& seq_lens, int64_t block_size,
-  torch::Tensor& query,
+    int64_t max_seq_len, const c10::optional<torch::Tensor>& alibi_slopes,
-  torch::Tensor& key_cache,
+    const std::string& kv_cache_dtype, double kv_scale, const int64_t tp_rank,
-  torch::Tensor& value_cache,
+    const int64_t blocksparse_local_blocks,
-  int num_kv_heads,
+    const int64_t blocksparse_vert_stride, const int64_t blocksparse_block_size,
-  float scale,
+    const int64_t blocksparse_head_sliding_step);
  torch::Tensor& block_tables,
  torch::Tensor& context_lens,
  int block_size,
  int max_context_len,
  const c10::optional<torch::Tensor>& alibi_slopes,
  const std::string& kv_cache_dtype);
-void rms_norm(
+void rms_norm(torch::Tensor& out, torch::Tensor& input, torch::Tensor& weight,
-  torch::Tensor& out,
+              double epsilon);
  torch::Tensor& input,
  torch::Tensor& weight,
  float epsilon);
-void fused_add_rms_norm(
+void fused_add_rms_norm(torch::Tensor& input, torch::Tensor& residual,
-  torch::Tensor& input,
+                        torch::Tensor& weight, double epsilon);
  torch::Tensor& residual,
  torch::Tensor& weight,
  float epsilon);
-void rotary_embedding(
+void rotary_embedding(torch::Tensor& positions, torch::Tensor& query,
-  torch::Tensor& positions,
+                      torch::Tensor& key, int64_t head_size,
-  torch::Tensor& query,
+                      torch::Tensor& cos_sin_cache, bool is_neox);
  torch::Tensor& key,
  int head_size,
  torch::Tensor& cos_sin_cache,
  bool is_neox);
-void batched_rotary_embedding(
+void batched_rotary_embedding(torch::Tensor& positions, torch::Tensor& query,
-  torch::Tensor& positions,
+                              torch::Tensor& key, int64_t head_size,
-  torch::Tensor& query,
+                              torch::Tensor& cos_sin_cache, bool is_neox,
-  torch::Tensor& key,
+                              int64_t rot_dim,
-  int head_size,
+                              torch::Tensor& cos_sin_cache_offsets);
  torch::Tensor& cos_sin_cache,
  bool is_neox,
  int rot_dim,
  torch::Tensor& cos_sin_cache_offsets);
-void silu_and_mul(
+void silu_and_mul(torch::Tensor& out, torch::Tensor& input);
  torch::Tensor& out,
  torch::Tensor& input);
-void gelu_and_mul(
+void gelu_and_mul(torch::Tensor& out, torch::Tensor& input);
  torch::Tensor& out,
  torch::Tensor& input);
-void gelu_tanh_and_mul(
+void gelu_tanh_and_mul(torch::Tensor& out, torch::Tensor& input);
  torch::Tensor& out,
  torch::Tensor& input);
-void gelu_new(
+void gelu_new(torch::Tensor& out, torch::Tensor& input);
  torch::Tensor& out,
  torch::Tensor& input);
-void gelu_fast(
+void gelu_fast(torch::Tensor& out, torch::Tensor& input);
  torch::Tensor& out,
  torch::Tensor& input);
 #ifndef USE_ROCM
-torch::Tensor awq_gemm(
+torch::Tensor aqlm_gemm(const torch::Tensor& input, const torch::Tensor& codes,
-  torch::Tensor _in_feats,
+                        const torch::Tensor& codebooks,
-  torch::Tensor _kernel,
+                        const torch::Tensor& scales,
-  torch::Tensor _scaling_factors,
+                        const torch::Tensor& codebook_partition_sizes,
-  torch::Tensor _zeros,
+                        const std::optional<torch::Tensor>& bias);
  int split_k_iters);
-torch::Tensor awq_dequantize(
+torch::Tensor aqlm_dequant(const torch::Tensor& codes,
-    torch::Tensor _kernel,
+                           const torch::Tensor& codebooks,
-    torch::Tensor _scaling_factors,
+                           const torch::Tensor& codebook_partition_sizes);
-    torch::Tensor _zeros,
+
-    int split_k_iters,
+torch::Tensor awq_gemm(torch::Tensor _in_feats, torch::Tensor _kernel,
-    int thx,
+                       torch::Tensor _scaling_factors, torch::Tensor _zeros,
-    int thy);
+                       int64_t split_k_iters);
 torch::Tensor awq_dequantize(torch::Tensor _kernel,
                             torch::Tensor _scaling_factors,
                             torch::Tensor _zeros, int64_t split_k_iters,
                             int64_t thx, int64_t thy);
 torch::Tensor marlin_gemm(torch::Tensor& a, torch::Tensor& b_q_weight,
                          torch::Tensor& b_scales, torch::Tensor& workspace,
                          int64_t size_m, int64_t size_n, int64_t size_k);
 torch::Tensor gptq_marlin_24_gemm(torch::Tensor& a, torch::Tensor& b_q_weight,
                                  torch::Tensor& b_meta,
                                  torch::Tensor& b_scales,
                                  torch::Tensor& workspace, int64_t num_bits,
                                  int64_t size_m, int64_t size_n,
                                  int64_t size_k);
 torch::Tensor gptq_marlin_gemm(torch::Tensor& a, torch::Tensor& b_q_weight,
                               torch::Tensor& b_scales, torch::Tensor& g_idx,
                               torch::Tensor& perm, torch::Tensor& workspace,
                               int64_t num_bits, int64_t size_m, int64_t size_n,
                               int64_t size_k, bool is_k_full);
 torch::Tensor gptq_marlin_repack(torch::Tensor& b_q_weight, torch::Tensor& perm,
                                 int64_t size_k, int64_t size_n,
                                 int64_t num_bits);
 void cutlass_scaled_mm(torch::Tensor& out, torch::Tensor const& a,
                       torch::Tensor const& b, torch::Tensor const& a_scales,
                       torch::Tensor const& b_scales);
 torch::Tensor marlin_gemm(
    torch::Tensor& a, 
    torch::Tensor& b_q_weight,
    torch::Tensor& b_scales, 
    torch::Tensor& workspace,
    int64_t size_m, 
    int64_t size_n, 
    int64_t size_k);
 #endif
-void squeezellm_gemm(
+void static_scaled_int8_quant(torch::Tensor& out, torch::Tensor const& input,
-  torch::Tensor vec,
+                              torch::Tensor const& scale);
  torch::Tensor mat,
  torch::Tensor mul,
  torch::Tensor lookup_table);
-torch::Tensor gptq_gemm(
+void dynamic_scaled_int8_quant(torch::Tensor& out, torch::Tensor const& input,
-  torch::Tensor a,
+                               torch::Tensor& scales);
  torch::Tensor b_q_weight,
  torch::Tensor b_gptq_qzeros,
  torch::Tensor b_gptq_scales,
  torch::Tensor b_g_idx,
  bool use_exllama,
  int bit);
-void gptq_shuffle(
+void squeezellm_gemm(torch::Tensor vec, torch::Tensor mat, torch::Tensor mul,
-  torch::Tensor q_weight,
+                     torch::Tensor lookup_table);
  torch::Tensor q_perm,
  int bit);
-void moe_align_block_size(
+torch::Tensor gptq_gemm(torch::Tensor a, torch::Tensor b_q_weight,
-  torch::Tensor topk_ids,
+                        torch::Tensor b_gptq_qzeros,
-  int num_experts,
+                        torch::Tensor b_gptq_scales, torch::Tensor b_g_idx,
-  int block_size,
+                        bool use_exllama, int64_t bit);
-  torch::Tensor sorted_token_ids,
+
-  torch::Tensor experts_ids,
+void gptq_shuffle(torch::Tensor q_weight, torch::Tensor q_perm, int64_t bit);
-  torch::Tensor num_tokens_post_pad);
+
 void static_scaled_fp8_quant(torch::Tensor& out, torch::Tensor& input,
                             torch::Tensor& scale);
 void dynamic_scaled_fp8_quant(torch::Tensor& out, torch::Tensor& input,
                              torch::Tensor& scale);
 void moe_align_block_size(torch::Tensor topk_ids, int64_t num_experts,
                          int64_t block_size, torch::Tensor sorted_token_ids,
                          torch::Tensor experts_ids,
                          torch::Tensor num_tokens_post_pad);
 #ifndef USE_ROCM
-using fptr_t = uint64_t;
+using fptr_t = int64_t;
-fptr_t init_custom_ar(torch::Tensor &meta, torch::Tensor &rank_data,
+fptr_t init_custom_ar(torch::Tensor& meta, torch::Tensor& rank_data,
-                    const std::vector<std::string> &handles,
+                      const std::vector<std::string>& handles,
-                    const std::vector<int64_t> &offsets, int rank,
+                      const std::vector<int64_t>& offsets, int64_t rank,
                    bool full_nvlink);
 bool should_custom_ar(torch::Tensor &inp, int max_size, int world_size,
                      bool full_nvlink);
-void all_reduce_reg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &out);
+bool should_custom_ar(torch::Tensor& inp, int64_t max_size, int64_t world_size,
-void all_reduce_unreg(fptr_t _fa, torch::Tensor &inp, torch::Tensor &reg_buffer,
+                      bool full_nvlink);
-                      torch::Tensor &out);
+void all_reduce_reg(fptr_t _fa, torch::Tensor& inp, torch::Tensor& out);
 void all_reduce_unreg(fptr_t _fa, torch::Tensor& inp, torch::Tensor& reg_buffer,
                      torch::Tensor& out);
 void dispose(fptr_t _fa);
-int meta_size();
+int64_t meta_size();
-void register_buffer(fptr_t _fa, torch::Tensor &t,
+void register_buffer(fptr_t _fa, torch::Tensor& t,
-                     const std::vector<std::string> &handles,
+                     const std::vector<std::string>& handles,
-                     const std::vector<int64_t> &offsets);
+                     const std::vector<int64_t>& offsets);
-std::pair<std::vector<uint8_t>, std::vector<int64_t>> get_graph_buffer_ipc_meta(fptr_t _fa);
+std::tuple<torch::Tensor, std::vector<int64_t>> get_graph_buffer_ipc_meta(
-void register_graph_buffers(fptr_t _fa, const std::vector<std::string> &handles,
+    fptr_t _fa);
-                            const std::vector<std::vector<int64_t>> &offsets);
+void register_graph_buffers(fptr_t _fa, const std::vector<std::string>& handles,
                            const std::vector<std::vector<int64_t>>& offsets);
 #endif
--- a/csrc/pos_encoding_kernels.cu
+++ b/csrc/pos_encoding_kernels.cu
@@ -1,4 +1,4 @@
-#include <torch/extension.h>
+#include <torch/all.h>
 #include <ATen/cuda/CUDAContext.h>
 #include <c10/cuda/CUDAGuard.h>
@@ -7,14 +7,10 @@
 namespace vllm {
-template<typename scalar_t, bool IS_NEOX>
+template <typename scalar_t, bool IS_NEOX>
 inline __device__ void apply_token_rotary_embedding(
-  scalar_t* __restrict__ arr,
+    scalar_t* __restrict__ arr, const scalar_t* __restrict__ cos_ptr,
-  const scalar_t* __restrict__ cos_ptr,
+    const scalar_t* __restrict__ sin_ptr, int rot_offset, int embed_dim) {
  const scalar_t* __restrict__ sin_ptr,
  int rot_offset,
  int embed_dim)
 {
  int x_index, y_index;
  scalar_t cos, sin;
  if (IS_NEOX) {
@@ -37,19 +33,17 @@ inline __device__ void apply_token_rotary_embedding(
  arr[y_index] = y * cos + x * sin;
 }
-template<typename scalar_t, bool IS_NEOX>
+template <typename scalar_t, bool IS_NEOX>
 inline __device__ void apply_rotary_embedding(
-  scalar_t* __restrict__ query,                 // [batch_size, seq_len, num_heads, head_size] or [num_tokens, num_heads, head_size]
+    scalar_t* __restrict__ query,  // [batch_size, seq_len, num_heads,
-  scalar_t* __restrict__ key,                   // [batch_size, seq_len, num_kv_heads, head_size] or [num_tokens, num_kv_heads, head_size]
+                                   // head_size] or [num_tokens, num_heads,
-  const scalar_t* cache_ptr,
+                                   // head_size]
-  const int head_size,
+    scalar_t* __restrict__ key,    // [batch_size, seq_len, num_kv_heads,
-  const int num_heads,
+                                   // head_size] or [num_tokens, num_kv_heads,
-  const int num_kv_heads,
+                                   // head_size]
-  const int rot_dim,
+    const scalar_t* cache_ptr, const int head_size, const int num_heads,
-  const int token_idx,
+    const int num_kv_heads, const int rot_dim, const int token_idx,
-  const int64_t query_stride,
+    const int64_t query_stride, const int64_t key_stride) {
  const int64_t key_stride)
 {
  const int embed_dim = rot_dim / 2;
  const scalar_t* cos_ptr = cache_ptr;
  const scalar_t* sin_ptr = cache_ptr + embed_dim;
@@ -59,8 +53,8 @@ inline __device__ void apply_rotary_embedding(
    const int head_idx = i / embed_dim;
    const int64_t token_head = token_idx * query_stride + head_idx * head_size;
    const int rot_offset = i % embed_dim;
-    apply_token_rotary_embedding<scalar_t, IS_NEOX>(query + token_head, cos_ptr,
+    apply_token_rotary_embedding<scalar_t, IS_NEOX>(
-                                              sin_ptr, rot_offset, embed_dim);
+        query + token_head, cos_ptr, sin_ptr, rot_offset, embed_dim);
  }
  const int nk = num_kv_heads * embed_dim;
@@ -68,62 +62,74 @@ inline __device__ void apply_rotary_embedding(
    const int head_idx = i / embed_dim;
    const int64_t token_head = token_idx * key_stride + head_idx * head_size;
    const int rot_offset = i % embed_dim;
-    apply_token_rotary_embedding<scalar_t, IS_NEOX>(key + token_head, cos_ptr,
+    apply_token_rotary_embedding<scalar_t, IS_NEOX>(
-                                              sin_ptr, rot_offset, embed_dim);
+        key + token_head, cos_ptr, sin_ptr, rot_offset, embed_dim);
  }
 }
-template<typename scalar_t, bool IS_NEOX>
+template <typename scalar_t, bool IS_NEOX>
 __global__ void rotary_embedding_kernel(
-  const int64_t* __restrict__ positions,        // [batch_size, seq_len] or [num_tokens]
+    const int64_t* __restrict__ positions,  // [batch_size, seq_len] or
-  scalar_t* __restrict__ query,                 // [batch_size, seq_len, num_heads, head_size] or [num_tokens, num_heads, head_size]
+                                            // [num_tokens]
-  scalar_t* __restrict__ key,                   // [batch_size, seq_len, num_kv_heads, head_size] or [num_tokens, num_kv_heads, head_size]
+    scalar_t* __restrict__ query,           // [batch_size, seq_len, num_heads,
-  const scalar_t* __restrict__ cos_sin_cache,   // [max_position, 2, rot_dim // 2]
+                                   // head_size] or [num_tokens, num_heads,
-  const int rot_dim,
+                                   // head_size]
-  const int64_t query_stride,
+    scalar_t* __restrict__ key,  // [batch_size, seq_len, num_kv_heads,
-  const int64_t key_stride,
+                                 // head_size] or [num_tokens, num_kv_heads,
-  const int num_heads,
+                                 // head_size]
-  const int num_kv_heads,
+    const scalar_t* __restrict__ cos_sin_cache,  // [max_position, 2, rot_dim //
-  const int head_size) {
+                                                 // 2]
    const int rot_dim, const int64_t query_stride, const int64_t key_stride,
    const int num_heads, const int num_kv_heads, const int head_size) {
  // Each thread block is responsible for one token.
  const int token_idx = blockIdx.x;
  int64_t pos = positions[token_idx];
  const scalar_t* cache_ptr = cos_sin_cache + pos * rot_dim;
-  apply_rotary_embedding<scalar_t, IS_NEOX>(query, key, cache_ptr, head_size, num_heads, num_kv_heads, rot_dim, token_idx, query_stride, key_stride);
+  apply_rotary_embedding<scalar_t, IS_NEOX>(
      query, key, cache_ptr, head_size, num_heads, num_kv_heads, rot_dim,
      token_idx, query_stride, key_stride);
 }
-template<typename scalar_t, bool IS_NEOX>
+template <typename scalar_t, bool IS_NEOX>
 __global__ void batched_rotary_embedding_kernel(
-  const int64_t* __restrict__ positions,              // [batch_size, seq_len] or [num_tokens]
+    const int64_t* __restrict__ positions,  // [batch_size, seq_len] or
-  scalar_t* __restrict__ query,                       // [batch_size, seq_len, num_heads, head_size] or [num_tokens, num_heads, head_size]
+                                            // [num_tokens]
-  scalar_t* __restrict__ key,                         // [batch_size, seq_len, num_kv_heads, head_size] or [num_tokens, num_kv_heads, head_size]
+    scalar_t* __restrict__ query,           // [batch_size, seq_len, num_heads,
-  const scalar_t* __restrict__ cos_sin_cache,         // [max_position, 2, rot_dim // 2]
+                                   // head_size] or [num_tokens, num_heads,
-  const int64_t* __restrict__ cos_sin_cache_offsets,  // [batch_size, seq_len] or [num_tokens]
+                                   // head_size]
-  const int rot_dim,
+    scalar_t* __restrict__ key,  // [batch_size, seq_len, num_kv_heads,
-  const int64_t query_stride,
+                                 // head_size] or [num_tokens, num_kv_heads,
-  const int64_t key_stride,
+                                 // head_size]
-  const int num_heads,
+    const scalar_t* __restrict__ cos_sin_cache,  // [max_position, 2, rot_dim //
-  const int num_kv_heads,
+                                                 // 2]
-  const int head_size) {
+    const int64_t* __restrict__ cos_sin_cache_offsets,  // [batch_size, seq_len]
                                                        // or [num_tokens]
    const int rot_dim, const int64_t query_stride, const int64_t key_stride,
    const int num_heads, const int num_kv_heads, const int head_size) {
  // Each thread block is responsible for one token.
  const int token_idx = blockIdx.x;
  int64_t pos = positions[token_idx];
  int64_t cos_sin_cache_offset = cos_sin_cache_offsets[token_idx];
-  const scalar_t* cache_ptr = cos_sin_cache + (cos_sin_cache_offset + pos) * rot_dim;
+  const scalar_t* cache_ptr =
      cos_sin_cache + (cos_sin_cache_offset + pos) * rot_dim;
-  apply_rotary_embedding<scalar_t, IS_NEOX>(query, key, cache_ptr, head_size, num_heads, num_kv_heads, rot_dim, token_idx, query_stride, key_stride);
+  apply_rotary_embedding<scalar_t, IS_NEOX>(
      query, key, cache_ptr, head_size, num_heads, num_kv_heads, rot_dim,
      token_idx, query_stride, key_stride);
 }
-} // namespace vllm
+}  // namespace vllm
 void rotary_embedding(
-  torch::Tensor& positions,         // [batch_size, seq_len] or [num_tokens]
+    torch::Tensor& positions,  // [batch_size, seq_len] or [num_tokens]
-  torch::Tensor& query,             // [batch_size, seq_len, num_heads * head_size] or [num_tokens, num_heads * head_size]
+    torch::Tensor& query,  // [batch_size, seq_len, num_heads * head_size] or
-  torch::Tensor& key,               // [batch_size, seq_len, num_kv_heads * head_size] or [num_tokens, num_kv_heads * head_size]
+                           // [num_tokens, num_heads * head_size]
-  int head_size,
+    torch::Tensor& key,    // [batch_size, seq_len, num_kv_heads * head_size] or
-  torch::Tensor& cos_sin_cache,     // [max_position, rot_dim]
+                           // [num_tokens, num_kv_heads * head_size]
-  bool is_neox) {
+    int64_t head_size,
    torch::Tensor& cos_sin_cache,  // [max_position, rot_dim]
    bool is_neox) {
  int64_t num_tokens = query.numel() / query.size(-1);
  int rot_dim = cos_sin_cache.size(1);
  int num_heads = query.size(-1) / head_size;
@@ -132,39 +138,24 @@ void rotary_embedding(
  int64_t key_stride = key.stride(-2);
  dim3 grid(num_tokens);
-  dim3 block(std::min(num_heads * rot_dim / 2, 512));
+  dim3 block(std::min<int64_t>(num_heads * rot_dim / 2, 512));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(query));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  VLLM_DISPATCH_FLOATING_TYPES(
+  VLLM_DISPATCH_FLOATING_TYPES(query.scalar_type(), "rotary_embedding", [&] {
-    query.scalar_type(),
+    if (is_neox) {
-    "rotary_embedding",
+      vllm::rotary_embedding_kernel<scalar_t, true><<<grid, block, 0, stream>>>(
-    [&] {
+          positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
-      if (is_neox) {
+          key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(), rot_dim,
-        vllm::rotary_embedding_kernel<scalar_t, true><<<grid, block, 0, stream>>>(
+          query_stride, key_stride, num_heads, num_kv_heads, head_size);
-          positions.data_ptr<int64_t>(),
+    } else {
-          query.data_ptr<scalar_t>(),
+      vllm::rotary_embedding_kernel<scalar_t, false>
-          key.data_ptr<scalar_t>(),
+          <<<grid, block, 0, stream>>>(
-          cos_sin_cache.data_ptr<scalar_t>(),
+              positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
-          rot_dim,
+              key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(),
-          query_stride,
+              rot_dim, query_stride, key_stride, num_heads, num_kv_heads,
-          key_stride,
+              head_size);
-          num_heads,
+    }
-          num_kv_heads,
+  });
          head_size);
      } else {
        vllm::rotary_embedding_kernel<scalar_t, false><<<grid, block, 0, stream>>>(
          positions.data_ptr<int64_t>(),
          query.data_ptr<scalar_t>(),
          key.data_ptr<scalar_t>(),
          cos_sin_cache.data_ptr<scalar_t>(),
          rot_dim,
          query_stride,
          key_stride,
          num_heads,
          num_kv_heads,
          head_size);
      }
    });
 }
 /*
@@ -172,14 +163,15 @@ Batched version of rotary embedding, pack multiple LoRAs together
 and process in batched manner.
 */
 void batched_rotary_embedding(
-  torch::Tensor& positions,         // [batch_size, seq_len] or [num_tokens]
+    torch::Tensor& positions,  // [batch_size, seq_len] or [num_tokens]
-  torch::Tensor& query,             // [batch_size, seq_len, num_heads * head_size] or [num_tokens, num_heads * head_size]
+    torch::Tensor& query,  // [batch_size, seq_len, num_heads * head_size] or
-  torch::Tensor& key,               // [batch_size, seq_len, num_kv_heads * head_size] or [num_tokens, num_kv_heads * head_size]
+                           // [num_tokens, num_heads * head_size]
-  int head_size,
+    torch::Tensor& key,    // [batch_size, seq_len, num_kv_heads * head_size] or
-  torch::Tensor& cos_sin_cache,     // [max_position, rot_dim]
+                           // [num_tokens, num_kv_heads * head_size]
-  bool is_neox,
+    int64_t head_size,
-  int rot_dim,
+    torch::Tensor& cos_sin_cache,  // [max_position, rot_dim]
-  torch::Tensor& cos_sin_cache_offsets // [num_tokens]
+    bool is_neox, int64_t rot_dim,
    torch::Tensor& cos_sin_cache_offsets  // [num_tokens]
 ) {
  int64_t num_tokens = cos_sin_cache_offsets.size(0);
  int num_heads = query.size(-1) / head_size;
@@ -188,39 +180,24 @@ void batched_rotary_embedding(
  int64_t key_stride = key.stride(-2);
  dim3 grid(num_tokens);
-  dim3 block(std::min(num_heads * rot_dim / 2, 512));
+  dim3 block(std::min<int64_t>(num_heads * rot_dim / 2, 512));
  const at::cuda::OptionalCUDAGuard device_guard(device_of(query));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
-  VLLM_DISPATCH_FLOATING_TYPES(
+  VLLM_DISPATCH_FLOATING_TYPES(query.scalar_type(), "rotary_embedding", [&] {
-    query.scalar_type(),
+    if (is_neox) {
-    "rotary_embedding",
+      vllm::batched_rotary_embedding_kernel<scalar_t, true>
-    [&] {
+          <<<grid, block, 0, stream>>>(
-      if (is_neox) {
+              positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
-        vllm::batched_rotary_embedding_kernel<scalar_t, true><<<grid, block, 0, stream>>>(
+              key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(),
-          positions.data_ptr<int64_t>(),
+              cos_sin_cache_offsets.data_ptr<int64_t>(), rot_dim, query_stride,
-          query.data_ptr<scalar_t>(),
+              key_stride, num_heads, num_kv_heads, head_size);
-          key.data_ptr<scalar_t>(),
+    } else {
-          cos_sin_cache.data_ptr<scalar_t>(),
+      vllm::batched_rotary_embedding_kernel<scalar_t, false>
-          cos_sin_cache_offsets.data_ptr<int64_t>(),
+          <<<grid, block, 0, stream>>>(
-          rot_dim,
+              positions.data_ptr<int64_t>(), query.data_ptr<scalar_t>(),
-          query_stride,
+              key.data_ptr<scalar_t>(), cos_sin_cache.data_ptr<scalar_t>(),
-          key_stride,
+              cos_sin_cache_offsets.data_ptr<int64_t>(), rot_dim, query_stride,
-          num_heads,
+              key_stride, num_heads, num_kv_heads, head_size);
-          num_kv_heads,
+    }
-          head_size);
+  });
      } else {
        vllm::batched_rotary_embedding_kernel<scalar_t, false><<<grid, block, 0, stream>>>(
          positions.data_ptr<int64_t>(),
          query.data_ptr<scalar_t>(),
          key.data_ptr<scalar_t>(),
          cos_sin_cache.data_ptr<scalar_t>(),
          cos_sin_cache_offsets.data_ptr<int64_t>(),
          rot_dim,
          query_stride,
          key_stride,
          num_heads,
          num_kv_heads,
          head_size);
      }
    });
 }
--- a/csrc/punica/bgmv/bgmv_bf16_bf16_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_bf16_bf16.cu
@@ -2,3 +2,4 @@
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, nv_bfloat16, nv_bfloat16)
 FOR_INST_BGMV_WIDE_NARROW(INST_BGMV_ONESIDE, nv_bfloat16, nv_bfloat16, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_bf16_bf16_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_bf16_fp16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, nv_bfloat16, nv_half)
--- a/csrc/punica/bgmv/bgmv_bf16_fp16_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_fp16_bf16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, nv_half, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_bf16_fp16_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_fp16_fp16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, nv_half, nv_half)
--- a/csrc/punica/bgmv/bgmv_bf16_fp32_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_fp32_bf16.cu
@@ -2,3 +2,4 @@
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, float, nv_bfloat16)
 FOR_INST_BGMV_WIDE_NARROW(INST_BGMV_ONESIDE, nv_bfloat16, float, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_bf16_fp32_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_bf16_fp32_fp16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_bfloat16, float, nv_half)
--- a/csrc/punica/bgmv/bgmv_config.h
+++ b/csrc/punica/bgmv/bgmv_config.h
@@ -14,6 +14,7 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    f(in_T, out_T, W_T, narrow, 128) \
    f(in_T, out_T, W_T, narrow, 256) \
    f(in_T, out_T, W_T, narrow, 512) \
    f(in_T, out_T, W_T, narrow, 640) \
    f(in_T, out_T, W_T, narrow, 768) \
    f(in_T, out_T, W_T, narrow, 1024) \
    f(in_T, out_T, W_T, narrow, 1152) \
@@ -27,6 +28,7 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    f(in_T, out_T, W_T, narrow, 2752) \
    f(in_T, out_T, W_T, narrow, 2816) \
    f(in_T, out_T, W_T, narrow, 3072) \
    f(in_T, out_T, W_T, narrow, 3328) \
    f(in_T, out_T, W_T, narrow, 3456) \
    f(in_T, out_T, W_T, narrow, 3584) \
    f(in_T, out_T, W_T, narrow, 4096) \
@@ -35,6 +37,7 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    f(in_T, out_T, W_T, narrow, 5504) \
    f(in_T, out_T, W_T, narrow, 5632) \
    f(in_T, out_T, W_T, narrow, 6144) \
    f(in_T, out_T, W_T, narrow, 6400) \
    f(in_T, out_T, W_T, narrow, 6848) \
    f(in_T, out_T, W_T, narrow, 6912) \
    f(in_T, out_T, W_T, narrow, 7168) \
@@ -46,11 +49,13 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    f(in_T, out_T, W_T, narrow, 13696) \
    f(in_T, out_T, W_T, narrow, 13824) \
    f(in_T, out_T, W_T, narrow, 14336) \
    f(in_T, out_T, W_T, narrow, 15360) \
    f(in_T, out_T, W_T, narrow, 16384) \
    f(in_T, out_T, W_T, narrow, 20480) \
    f(in_T, out_T, W_T, narrow, 22016) \
    f(in_T, out_T, W_T, narrow, 24576) \
    f(in_T, out_T, W_T, narrow, 27392) \
    f(in_T, out_T, W_T, narrow, 27648) \
    f(in_T, out_T, W_T, narrow, 28672) \
    f(in_T, out_T, W_T, narrow, 32000) \
    f(in_T, out_T, W_T, narrow, 32256) \
@@ -58,9 +63,91 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    f(in_T, out_T, W_T, narrow, 32768) \
    f(in_T, out_T, W_T, narrow, 33024) \
    f(in_T, out_T, W_T, narrow, 36864) \
    f(in_T, out_T, W_T, narrow, 43264) \
    f(in_T, out_T, W_T, narrow, 49152) \
    f(in_T, out_T, W_T, narrow, 64000) \
    f(in_T, out_T, W_T, narrow, 64256) \
    f(in_T, out_T, W_T, narrow, 64512) \
    f(in_T, out_T, W_T, narrow, 102400) \
    f(in_T, out_T, W_T, narrow, 102656) \
    f(in_T, out_T, W_T, narrow, 102912) \
    f(in_T, out_T, W_T, narrow, 128000) \
    f(in_T, out_T, W_T, narrow, 128256) \
    f(in_T, out_T, W_T, narrow, 128512) \
 // Keep above in sync with vllm/lora/layers::LogitsProcessorWithLoRA
 // and vllm/tests/lora/test_punica.py
 // Used for defining kernels going from the variety of 
 // dim in to the narrow dim out
    // Using it for the fully sharded column 
    // parallel LoRA A which splits the rank dim
 #define FOR_INST_BGMV_NARROW(f, in_T, out_T, W_T, narrow) \
    f(in_T, out_T, W_T, 128, narrow) \
    f(in_T, out_T, W_T, 256, narrow) \
    f(in_T, out_T, W_T, 512, narrow) \
    f(in_T, out_T, W_T, 640, narrow) \
    f(in_T, out_T, W_T, 768, narrow) \
    f(in_T, out_T, W_T, 1024, narrow) \
    f(in_T, out_T, W_T, 1152, narrow) \
    f(in_T, out_T, W_T, 1280, narrow) \
    f(in_T, out_T, W_T, 1536, narrow) \
    f(in_T, out_T, W_T, 1728, narrow) \
    f(in_T, out_T, W_T, 1792, narrow) \
    f(in_T, out_T, W_T, 2048, narrow) \
    f(in_T, out_T, W_T, 2304, narrow) \
    f(in_T, out_T, W_T, 2560, narrow) \
    f(in_T, out_T, W_T, 2752, narrow) \
    f(in_T, out_T, W_T, 2816, narrow) \
    f(in_T, out_T, W_T, 3072, narrow) \
    f(in_T, out_T, W_T, 3328, narrow) \
    f(in_T, out_T, W_T, 3456, narrow) \
    f(in_T, out_T, W_T, 3584, narrow) \
    f(in_T, out_T, W_T, 4096, narrow) \
    f(in_T, out_T, W_T, 4608, narrow) \
    f(in_T, out_T, W_T, 5120, narrow) \
    f(in_T, out_T, W_T, 5504, narrow) \
    f(in_T, out_T, W_T, 5632, narrow) \
    f(in_T, out_T, W_T, 6144, narrow) \
    f(in_T, out_T, W_T, 6400, narrow) \
    f(in_T, out_T, W_T, 6848, narrow) \
    f(in_T, out_T, W_T, 6912, narrow) \
    f(in_T, out_T, W_T, 7168, narrow) \
    f(in_T, out_T, W_T, 8192, narrow) \
    f(in_T, out_T, W_T, 9216, narrow) \
    f(in_T, out_T, W_T, 10240, narrow) \
    f(in_T, out_T, W_T, 11008, narrow) \
    f(in_T, out_T, W_T, 12288, narrow) \
    f(in_T, out_T, W_T, 13696, narrow) \
    f(in_T, out_T, W_T, 13824, narrow) \
    f(in_T, out_T, W_T, 14336, narrow) \
    f(in_T, out_T, W_T, 15360, narrow) \
    f(in_T, out_T, W_T, 16384, narrow) \
    f(in_T, out_T, W_T, 20480, narrow) \
    f(in_T, out_T, W_T, 22016, narrow) \
    f(in_T, out_T, W_T, 24576, narrow) \
    f(in_T, out_T, W_T, 27392, narrow) \
    f(in_T, out_T, W_T, 27648, narrow) \
    f(in_T, out_T, W_T, 28672, narrow) \
    f(in_T, out_T, W_T, 32000, narrow) \
    f(in_T, out_T, W_T, 32256, narrow) \
    f(in_T, out_T, W_T, 32512, narrow) \
    f(in_T, out_T, W_T, 32768, narrow) \
    f(in_T, out_T, W_T, 33024, narrow) \
    f(in_T, out_T, W_T, 36864, narrow) \
    f(in_T, out_T, W_T, 43264, narrow) \
    f(in_T, out_T, W_T, 49152, narrow) \
    f(in_T, out_T, W_T, 64000, narrow) \
    f(in_T, out_T, W_T, 64256, narrow) \
    f(in_T, out_T, W_T, 64512, narrow) \
    f(in_T, out_T, W_T, 102400, narrow) \
    f(in_T, out_T, W_T, 102656, narrow) \
    f(in_T, out_T, W_T, 102912, narrow) \
    f(in_T, out_T, W_T, 128000, narrow) \
    f(in_T, out_T, W_T, 128256, narrow) \
    f(in_T, out_T, W_T, 128512, narrow) \
 // Keep above in sync with vllm/lora/layers::SamplerWithLoRA
 // Keep this in sync with vllm/config::LoRAConfig
 #define FOR_BGMV_WIDE_NARROW(f, in_T, out_T, W_T) \
    FOR_BGMV_WIDE(f, in_T, out_T, W_T, 8)  \
@@ -68,4 +155,14 @@ void bgmv_kernel(out_T *__restrict__ Y, const in_T *__restrict__ X,
    FOR_BGMV_WIDE(f, in_T, out_T, W_T, 32) \
    FOR_BGMV_WIDE(f, in_T, out_T, W_T, 64)
 #define FOR_INST_BGMV_WIDE_NARROW(f, in_T, out_T, W_T) \
    FOR_INST_BGMV_NARROW(f, in_T, out_T, W_T, 1) \
    FOR_INST_BGMV_NARROW(f, in_T, out_T, W_T, 2) \
    FOR_INST_BGMV_NARROW(f, in_T, out_T, W_T, 4) \
    f(in_T, out_T, W_T, 8, 64) \
    f(in_T, out_T, W_T, 16, 64) \
    f(in_T, out_T, W_T, 32, 64) \
    f(in_T, out_T, W_T, 64, 64)
 // clang-format on
--- a/csrc/punica/bgmv/bgmv_fp16_bf16_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_bf16_bf16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, nv_bfloat16, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_fp16_bf16_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_bf16_fp16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, nv_bfloat16, nv_half)
--- a/csrc/punica/bgmv/bgmv_fp16_fp16_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_fp16_bf16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, nv_half, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_fp16_fp16_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_fp16_fp16.cu
@@ -2,3 +2,4 @@
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, nv_half, nv_half)
 FOR_INST_BGMV_WIDE_NARROW(INST_BGMV_ONESIDE, nv_half, nv_half, nv_half)
--- a/csrc/punica/bgmv/bgmv_fp16_fp32_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_fp32_bf16.cu
@@ -1,4 +0,0 @@
 #include "bgmv_config.h"
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, float, nv_bfloat16)
--- a/csrc/punica/bgmv/bgmv_fp16_fp32_fp16.cu
+++ b/csrc/punica/bgmv/bgmv_fp16_fp32_fp16.cu
@@ -2,3 +2,4 @@
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, nv_half, float, nv_half)
 FOR_INST_BGMV_WIDE_NARROW(INST_BGMV_ONESIDE, nv_half, float, nv_half)
--- a/csrc/punica/bgmv/bgmv_fp32_bf16_bf16.cu
+++ b/csrc/punica/bgmv/bgmv_fp32_bf16_bf16.cu
@@ -2,3 +2,4 @@
 #include "bgmv_impl.cuh"
 FOR_BGMV_WIDE_NARROW(INST_BGMV_TWOSIDE, float, nv_bfloat16, nv_bfloat16)
 FOR_INST_BGMV_WIDE_NARROW(INST_BGMV_ONESIDE, float, nv_bfloat16, nv_bfloat16)
--- a/Show More
+++ b/Show More