[Kernel] Refactor FP8 kv-cache with NVIDIA float8_e4m3 support (vllm-…

…project#4535)

.buildkite/check-wheel-size.py

@@ -1,7 +1,7 @@
 import os
 import zipfile
 
-MAX_SIZE_MB = 100
+MAX_SIZE_MB = 150
 
 
 def print_top_10_largest_files(zip_file):

CMakeLists.txt

@@ -167,7 +167,7 @@ set(VLLM_EXT_SRC
   "csrc/layernorm_kernels.cu"
   "csrc/quantization/squeezellm/quant_cuda_kernel.cu"
   "csrc/quantization/gptq/q_gemm.cu"
-  "csrc/quantization/fp8/fp8_cuda_kernels.cu"
+  "csrc/quantization/fp8/common.cu"
   "csrc/cuda_utils_kernels.cu"
   "csrc/moe_align_block_size_kernels.cu"
   "csrc/pybind.cpp")

cmake/utils.cmake

@@ -99,7 +99,7 @@ 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
@@ -119,7 +119,7 @@ function (get_torch_gpu_compiler_flags OUT_GPU_FLAGS GPU_LANG)
 
     list(APPEND GPU_FLAGS
       "-DUSE_ROCM"
-      "-DENABLE_FP8_E4M3"
+      "-DENABLE_FP8"
       "-U__HIP_NO_HALF_CONVERSIONS__"
       "-U__HIP_NO_HALF_OPERATORS__"
       "-fno-gpu-rdc")

csrc/attention/dtype_fp8.cuh

@@ -3,14 +3,21 @@
 #include "attention_generic.cuh"
 
 #include <stdint.h>
-#ifdef ENABLE_FP8_E5M2
+#ifdef ENABLE_FP8
+#ifndef USE_ROCM 
 #include <cuda_fp8.h>
-#endif
+#endif // USE_ROCM
+#endif // ENABLE_FP8
 
 namespace vllm {
-#if defined(ENABLE_FP8_E5M2) || defined(ENABLE_FP8_E4M3)
-// fp8 vector types for quantization of kv cache
 
+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;
@@ -30,6 +37,5 @@ template<>
 struct Vec<uint8_t, 8> {
     using Type = uint2;
 };
-#endif // ENABLE_FP8_E5M2
 
 } // namespace vllm

csrc/cache.h

@@ -34,5 +34,7 @@ void reshape_and_cache_flash(
 
 // Just for unittest
 void convert_fp8(
+  torch::Tensor& dst_cache,
   torch::Tensor& src_cache,
-  torch::Tensor& dst_cache);
+  const float scale,
+  const std::string& kv_cache_dtype);

csrc/cache_kernels.cu

@@ -4,10 +4,11 @@
 
 #include "cuda_compat.h"
 #include "dispatch_utils.h"
-#if defined(ENABLE_FP8_E5M2)
-#include "quantization/fp8_e5m2_kvcache/quant_utils.cuh"
-#elif defined(ENABLE_FP8_E4M3)
-#include "quantization/fp8/amd_detail/quant_utils.cuh"
+
+#ifdef USE_ROCM
+#include "quantization/fp8/amd/quant_utils.cuh"
+#else
+#include "quantization/fp8/nvidia/quant_utils.cuh"
 #endif
 
 #include <algorithm>
@@ -149,7 +150,7 @@ void copy_blocks(
 
 namespace vllm {
 
-template<typename scalar_t, typename cache_t, bool is_fp8_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__ value,         // [num_tokens, num_heads, head_size]
@@ -194,19 +195,12 @@ __global__ void reshape_and_cache_kernel(
                                   + block_offset;
     scalar_t tgt_key = key[src_key_idx];
     scalar_t tgt_value = value[src_value_idx];
-    if constexpr (is_fp8_kv_cache) {
-#if defined(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);
-#elif defined(ENABLE_FP8_E4M3)
-      key_cache[tgt_key_idx] = fp8_e4m3::scaled_vec_conversion<uint8_t, scalar_t>(tgt_key, kv_scale);
-      value_cache[tgt_value_idx] = fp8_e4m3::scaled_vec_conversion<uint8_t, scalar_t>(tgt_value, kv_scale);
-#else
-      assert(false);
-#endif
-    } else {
+    if constexpr (kv_dt == Fp8KVCacheDataType::kAuto) {
       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);
     }
   }
 }
@@ -248,19 +242,22 @@ __global__ void reshape_and_cache_flash_kernel(
 }
 } // namespace vllm
 
-#define CALL_RESHAPE_AND_CACHE(KV_T, CACHE_T, IS_FP8_KV_CACHE)                                     \
-  vllm::reshape_and_cache_kernel<KV_T, CACHE_T, IS_FP8_KV_CACHE><<<grid, block, 0, stream>>>(      \
-    reinterpret_cast<KV_T*>(key.data_ptr()),                                                       \
-    reinterpret_cast<KV_T*>(value.data_ptr()),                                                     \
-    reinterpret_cast<CACHE_T*>(key_cache.data_ptr()),                                              \
-    reinterpret_cast<CACHE_T*>(value_cache.data_ptr()),                                            \
-    slot_mapping.data_ptr<int64_t>(),                                                              \
-    key_stride,                                                                                    \
-    value_stride,                                                                                  \
-    num_heads,                                                                                     \
-    head_size,                                                                                     \
-    block_size,                                                                                    \
-    x,                                                                                             \
+// KV_T is the stored data type of kv-cache.
+// CACHE_T is the data type of key and value tensors.
+// KV_DTYPE is the real data type of kv-cache.
+#define CALL_RESHAPE_AND_CACHE(KV_T, CACHE_T, KV_DTYPE)                                     \
+  vllm::reshape_and_cache_kernel<KV_T, CACHE_T, KV_DTYPE><<<grid, block, 0, stream>>>(      \
+    reinterpret_cast<KV_T*>(key.data_ptr()),                                                \
+    reinterpret_cast<KV_T*>(value.data_ptr()),                                              \
+    reinterpret_cast<CACHE_T*>(key_cache.data_ptr()),                                       \
+    reinterpret_cast<CACHE_T*>(value_cache.data_ptr()),                                     \
+    slot_mapping.data_ptr<int64_t>(),                                                       \
+    key_stride,                                                                             \
+    value_stride,                                                                           \
+    num_heads,                                                                              \
+    head_size,                                                                              \
+    block_size,                                                                             \
+    x,                                                                                      \
     kv_scale);
 
 void reshape_and_cache(
@@ -285,25 +282,8 @@ 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) {
-      CALL_RESHAPE_AND_CACHE(float, float, false);
-    } else if (key.dtype() == at::ScalarType::Half) {
-      CALL_RESHAPE_AND_CACHE(uint16_t, uint16_t, false);
-    } else if (key.dtype() == at::ScalarType::BFloat16) {
-      CALL_RESHAPE_AND_CACHE(__nv_bfloat16, __nv_bfloat16, false);
-    }
-  } else if (kv_cache_dtype == "fp8") {
-    if (key.dtype() == at::ScalarType::Float) {
-      CALL_RESHAPE_AND_CACHE(float, uint8_t, true);
-    } else if (key.dtype() == at::ScalarType::Half) {
-      CALL_RESHAPE_AND_CACHE(uint16_t, uint8_t, true);
-    } else if (key.dtype() == at::ScalarType::BFloat16) {
-      CALL_RESHAPE_AND_CACHE(__nv_bfloat16, uint8_t, true);
-    }
-  } else {
-    TORCH_CHECK(false, "Unsupported data type of kv cache: ", kv_cache_dtype);
-  }
+
+  DISPATCH_BY_KV_CACHE_DTYPE(key.dtype(), kv_cache_dtype, CALL_RESHAPE_AND_CACHE)
 }
 
 void reshape_and_cache_flash(
@@ -353,35 +333,34 @@ void reshape_and_cache_flash(
 
 namespace vllm {
 
-template<typename Tout, typename Tin>
+template<typename Tout, typename Tin, Fp8KVCacheDataType kv_dt>
 __global__ void convert_fp8_kernel(
   const Tin* __restrict__ src_cache,
   Tout* __restrict__ dst_cache,
+  const float kv_scale,
   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;
-#if defined(ENABLE_FP8_E5M2)
-    dst_cache[idx] = fp8_e5m2_unscaled::vec_conversion<Tout, Tin>(src_cache[idx]);
-#elif defined(ENABLE_FP8_E4M3)
-    dst_cache[idx] = fp8_e4m3::vec_conversion<Tout, Tin>(src_cache[idx]);
-#else
-    assert(false);
-#endif
+    dst_cache[idx] = fp8::scaled_convert<Tout, Tin, kv_dt>(src_cache[idx], kv_scale);
   }
 }
 
 } // namespace vllm
 
-#define CALL_CONVERT_FP8(Tout, Tin)                                 \
-  vllm::convert_fp8_kernel<Tout, Tin><<<grid, block, 0, stream>>>(  \
-    reinterpret_cast<Tin*>(src_cache.data_ptr()),                   \
-    reinterpret_cast<Tout*>(dst_cache.data_ptr()),                  \
+#define CALL_CONVERT_FP8(Tout, Tin, KV_DTYPE)                                 \
+  vllm::convert_fp8_kernel<Tout, Tin, KV_DTYPE><<<grid, block, 0, stream>>>(  \
+    reinterpret_cast<Tin*>(src_cache.data_ptr()),                             \
+    reinterpret_cast<Tout*>(dst_cache.data_ptr()),                            \
+    kv_scale, \
     block_stride);
 
+// Only for testing.
 void convert_fp8(
+  torch::Tensor& dst_cache,
   torch::Tensor& src_cache,
-  torch::Tensor& dst_cache)
+  const float kv_scale,
+  const std::string& kv_cache_dtype)
 {
   torch::Device src_device = src_cache.device();
   torch::Device dst_device = dst_cache.device();
@@ -399,17 +378,35 @@ void convert_fp8(
   dim3 block(std::min(block_stride, int64_t(512)));
   const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
 
-  if (src_cache.dtype() == at::ScalarType::Float) {
-    CALL_CONVERT_FP8(uint8_t, float);
-  } else if (src_cache.dtype() == at::ScalarType::Half) {
-    CALL_CONVERT_FP8(uint8_t, uint16_t);
-  } else if (src_cache.dtype() == at::ScalarType::BFloat16) {
-    CALL_CONVERT_FP8(uint8_t, __nv_bfloat16);
-  } else if (dst_cache.dtype() == at::ScalarType::Float) {
-    CALL_CONVERT_FP8(float, uint8_t);
-  } else if (dst_cache.dtype() == at::ScalarType::Half) {
-    CALL_CONVERT_FP8(uint16_t, uint8_t);
-  } else if (dst_cache.dtype() == at::ScalarType::BFloat16) {
-    CALL_CONVERT_FP8(__nv_bfloat16, uint8_t);
+  if (kv_cache_dtype == "auto") {
+    if (src_cache.dtype() == at::ScalarType::Float) {
+      CALL_CONVERT_FP8(uint8_t, float, vllm::Fp8KVCacheDataType::kAuto);
+    } else if (src_cache.dtype() == at::ScalarType::Half) {
+      CALL_CONVERT_FP8(uint8_t, uint16_t, vllm::Fp8KVCacheDataType::kAuto);
+    } else if (src_cache.dtype() == at::ScalarType::BFloat16) {
+      CALL_CONVERT_FP8(uint8_t, __nv_bfloat16, vllm::Fp8KVCacheDataType::kAuto);
+    } else if (dst_cache.dtype() == at::ScalarType::Float) {
+      CALL_CONVERT_FP8(float, uint8_t, vllm::Fp8KVCacheDataType::kAuto);
+    } else if (dst_cache.dtype() == at::ScalarType::Half) {
+      CALL_CONVERT_FP8(uint16_t, uint8_t, vllm::Fp8KVCacheDataType::kAuto);
+    } 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);
   }
 }

csrc/quantization/fp8/amd_detail/quant_utils.cuh → csrc/quantization/fp8/amd/quant_utils.cuh

@@ -5,12 +5,17 @@
 #include <hip/hip_bf16.h>
 #include <hip/hip_bfloat16.h>
 
+#include "../../../attention/dtype_fp8.cuh"
 #include "../../../attention/dtype_float32.cuh"
 #include "../../../attention/dtype_bfloat16.cuh"
 
 namespace vllm
 {
-namespace fp8_e4m3 {
+#ifdef USE_ROCM
+
+namespace fp8 {
+#ifdef ENABLE_FP8
+
 template <typename Tout, typename Tin>
 __inline__ __device__ Tout vec_conversion(const Tin& x)
 {
@@ -512,6 +517,58 @@ __inline__ __device__ float4 scaled_vec_conversion<float4, uint32_t>(const uint3
     float4 res = make_float4(tmp.x.x, tmp.x.y, tmp.y.x, tmp.y.y);
     return res;
 }
+#endif // ENABLE_FP8
 
+template <typename Tout, typename Tin, Fp8KVCacheDataType kv_dt>
+__inline__ __device__ Tout convert(const Tin &x) {
+#ifdef ENABLE_FP8
+  if constexpr (kv_dt == Fp8KVCacheDataType::kFp8E4M3) {
+    return vec_conversion<Tout, Tin>(x);
+  }
+#endif
+  assert(false);
 }
+
+template <typename Tout, typename Tin, Fp8KVCacheDataType kv_dt>
+__inline__ __device__ Tout scaled_convert(const Tin &x, const float scale) {
+#ifdef ENABLE_FP8
+  if constexpr (kv_dt == Fp8KVCacheDataType::kFp8E4M3) {
+    return scaled_vec_conversion<Tout, Tin>(x, scale);
+  }
+#endif
+  assert(false);
+}
+
+// The following macro is used to dispatch the conversion function based on the
+// data type of the key and value cache. The FN is a macro that calls a function
+// with template<typename scalar_t, typename cache_t, Fp8KVCacheDataType kv_dt>.
+#define DISPATCH_BY_KV_CACHE_DTYPE(SRC_DTYPE, KV_DTYPE, FN)                    \
+  if (KV_DTYPE == "auto") {                                                    \
+    if (SRC_DTYPE == at::ScalarType::Float) {                                  \
+      FN(float, float, vllm::Fp8KVCacheDataType::kAuto);                       \
+    } else if (SRC_DTYPE == at::ScalarType::Half) {                            \
+      FN(uint16_t, uint16_t, vllm::Fp8KVCacheDataType::kAuto);                 \
+    } else if (SRC_DTYPE == at::ScalarType::BFloat16) {                        \
+      FN(__nv_bfloat16, __nv_bfloat16, vllm::Fp8KVCacheDataType::kAuto);       \
+    } else {                                                                   \
+      TORCH_CHECK(false, "Unsupported input type of kv cache: ", SRC_DTYPE);   \
+    }                                                                          \
+  } else {                                                                     \
+    if (KV_DTYPE == "fp8" || KV_DTYPE == "fp8_e4m3") {                         \
+      if (SRC_DTYPE == at::ScalarType::Float) {                                \
+        FN(float, uint8_t, vllm::Fp8KVCacheDataType::kFp8E4M3);                \
+      } else if (SRC_DTYPE == at::ScalarType::Half) {                          \
+        FN(uint16_t, uint8_t, vllm::Fp8KVCacheDataType::kFp8E4M3);             \
+      } else if (SRC_DTYPE == at::ScalarType::BFloat16) {                      \
+        FN(__nv_bfloat16, uint8_t, vllm::Fp8KVCacheDataType::kFp8E4M3);        \
+      } else {                                                                 \
+        TORCH_CHECK(false, "Unsupported input type of kv cache: ", SRC_DTYPE); \
+      }                                                                        \
+    } else {                                                                   \
+      TORCH_CHECK(false, "Unsupported data type of kv cache: ", KV_DTYPE);     \
+    }                                                                          \
+  }
+
+} // fp8
+#endif // USE_ROCM
 } // namespace vllm