# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import math import random import time from collections.abc import Callable import pytest import torch from xformers import ops as xops from xformers.ops.fmha.attn_bias import BlockDiagonalCausalFromBottomRightMask from vllm.attention.backends.xformers import _make_alibi_bias from vllm.attention.ops.chunked_prefill_paged_decode import ( chunked_prefill_paged_decode) from vllm.attention.ops.prefix_prefill import context_attention_fwd from vllm.platforms import current_platform from vllm.utils import STR_DTYPE_TO_TORCH_DTYPE NUM_HEADS = [64] NUM_QUERIES_PER_KV = [1, 64] HEAD_SIZES = [24, 128] DTYPES = [torch.float16] CUDA_DEVICES = [ f"cuda:{i}" for i in range(1 if torch.cuda.device_count() == 1 else 2) ] SLIDING_WINDOW = [0, 16, 2048] KV_CACHE_DTYPES = ["auto", "fp8", "fp8_e5m2"] OPS = [chunked_prefill_paged_decode, context_attention_fwd] @pytest.mark.parametrize("num_heads", NUM_HEADS) @pytest.mark.parametrize("num_queries_per_kv", NUM_QUERIES_PER_KV) @pytest.mark.parametrize("head_size", HEAD_SIZES) @pytest.mark.parametrize("dtype", DTYPES) @pytest.mark.parametrize("kv_cache_dtype", KV_CACHE_DTYPES) @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("sliding_window", SLIDING_WINDOW) @pytest.mark.parametrize("op", OPS) @torch.inference_mode() def test_contexted_kv_attention( num_heads: int, num_queries_per_kv: int, head_size: int, sliding_window: int, dtype: torch.dtype, kv_cache_dtype: str, device: str, op: Callable, ) -> None: if 'fp8' in kv_cache_dtype and not current_platform.has_device_capability( 89): pytest.skip( 'Triton limitation: fp8e4nv data type is not supported on CUDA' ' arch < 89') current_platform.seed_everything(0) torch.set_default_device(device) # Need this, otherwise when we capture the graph the process # for GPU 1 would run on both GPU0 and GPU1 and things would hang # # see also similar issue: https://github.com/Dao-AILab/flash-attention/issues/523 torch.cuda.set_device(device) MAX_SEQ_LEN = 1024 MAX_CTX_LEN = 1024 BS = 10 cache_size = 640 block_size = 32 max_block_per_request = 64 query_lens = [random.randint(16, MAX_SEQ_LEN) for _ in range(BS)] # ensure one sequence in batch is a decode query_lens[-1] = 1 ctx_lens = [random.randint(16, MAX_CTX_LEN) for _ in range(BS)] seq_lens = [a + b for a, b in zip(query_lens, ctx_lens)] num_kv_heads = num_heads // num_queries_per_kv num_tokens = sum(query_lens) query = torch.empty(num_tokens, num_heads, head_size, dtype=dtype) query.uniform_(-1e-3, 1e-3) output = torch.empty(num_tokens, num_heads, head_size, dtype=dtype) kv = torch.empty(sum(seq_lens), 2, num_kv_heads, head_size, dtype=dtype) kv.uniform_(-1e-3, 1e-3) key, value = kv.unbind(dim=1) if kv_cache_dtype == "auto": cache_dtype = dtype else: cache_dtype = STR_DTYPE_TO_TORCH_DTYPE[kv_cache_dtype] k_cache = torch.zeros(cache_size, block_size, num_kv_heads, head_size, dtype=cache_dtype) v_cache = torch.zeros(cache_size, block_size, num_kv_heads, head_size, dtype=cache_dtype) k = torch.zeros(sum(query_lens), num_kv_heads, head_size, dtype=dtype) v = torch.zeros(sum(query_lens), num_kv_heads, head_size, dtype=dtype) values = torch.arange(0, cache_size, dtype=torch.long) values = values[torch.randperm(cache_size)] block_table = values[:BS * max_block_per_request].view( BS, max_block_per_request) b_seq_len = torch.tensor(seq_lens, dtype=torch.long) b_ctx_len = torch.tensor(ctx_lens, dtype=torch.long) b_start_loc = torch.cumsum(torch.tensor([0] + query_lens, dtype=torch.long), dim=0) max_input_len = MAX_SEQ_LEN # copy kv to cache b_seq_start_loc = torch.cumsum(torch.tensor([0] + seq_lens[:-1], dtype=torch.long), dim=0) for i in range(BS): for j in range(query_lens[i]): k[b_start_loc[i] + j].copy_(key[b_seq_start_loc[i] + b_ctx_len[i] + j]) v[b_start_loc[i] + j].copy_(value[b_seq_start_loc[i] + b_ctx_len[i] + j]) cur_ctx = 0 block_id = 0 while cur_ctx < b_ctx_len[i]: start_loc = b_seq_start_loc[i] + cur_ctx if cur_ctx + block_size > b_ctx_len[i]: end_loc = b_seq_start_loc[i] + b_ctx_len[i] else: end_loc = start_loc + block_size start_slot = block_table[i, block_id] * block_size end_slot = start_slot + end_loc - start_loc k_cache.view(-1, num_kv_heads, head_size)[start_slot:end_slot].copy_( key[start_loc:end_loc]) v_cache.view(-1, num_kv_heads, head_size)[start_slot:end_slot].copy_( value[start_loc:end_loc]) cur_ctx += block_size block_id += 1 # transpose K_cache[num_blocks, block_size, num_kv_heads, head_size] # to K_cache[num_blocks, num_kv_heads, head_size/8, block_size, 8] k_cache = k_cache.view(-1, block_size, num_kv_heads, head_size // 8, 8).permute(0, 2, 3, 1, 4).contiguous() # transpose V_cache[num_blocks, block_size, num_kv_heads, head_size] # to V_cache[num_blocks, num_kv_heads, head_size, block_size] v_cache = v_cache.view(-1, block_size, num_kv_heads, head_size).permute(0, 2, 3, 1).contiguous() k_scale = v_scale = torch.tensor(1.0, dtype=torch.float32, device=device) # Warm up the Triton kernel by calling it once before actually measuring # generation time op(query, k, v, output, kv_cache_dtype, k_cache, v_cache, block_table, b_start_loc, b_seq_len, MAX_CTX_LEN, max_input_len, k_scale, v_scale, sliding_window=sliding_window) torch.cuda.synchronize() start_time = time.time() op(query, k, v, output, kv_cache_dtype, k_cache, v_cache, block_table, b_start_loc, b_seq_len, MAX_CTX_LEN, max_input_len, k_scale, v_scale, sliding_window=sliding_window) torch.cuda.synchronize() end_time = time.time() print(f"triton Time: {(end_time - start_time)*1000:.2f} ms") scale = float(1.0 / (head_size**0.5)) attn_op = xops.fmha.cutlass.FwOp() if num_kv_heads != num_heads: # As of Nov 2023, xformers only supports MHA. For MQA/GQA, # project the key and value tensors to the desired number of # heads. # # see also: vllm/model_executor/layers/attention.py query = query.view(query.shape[0], num_kv_heads, num_queries_per_kv, query.shape[-1]) key = key[:, :, None, :].expand(key.shape[0], num_kv_heads, num_queries_per_kv, key.shape[-1]) value = value[:, :, None, :].expand(value.shape[0], num_kv_heads, num_queries_per_kv, value.shape[-1]) query = query.unsqueeze(0) key = key.unsqueeze(0) value = value.unsqueeze(0) attn_bias = BlockDiagonalCausalFromBottomRightMask.from_seqlens( query_lens, seq_lens) if sliding_window > 0: attn_bias = attn_bias.make_local_attention_from_bottomright( sliding_window) output_ref = xops.memory_efficient_attention_forward( query, key, value, attn_bias=attn_bias, p=0.0, scale=scale, op=attn_op, ) torch.cuda.synchronize() start_time = time.time() output_ref = xops.memory_efficient_attention_forward( query, key, value, attn_bias=attn_bias, p=0.0, scale=scale, op=attn_op, ) torch.cuda.synchronize() end_time = time.time() print(f"xformers Time: {(end_time - start_time)*1000:.2f} ms") output_ref = output_ref.reshape(output.shape) atol = 1e-3 if "fp8" in kv_cache_dtype else 1e-4 torch.testing.assert_close(output, output_ref, atol=atol, rtol=0) @pytest.mark.parametrize("num_heads", NUM_HEADS) @pytest.mark.parametrize("num_queries_per_kv", NUM_QUERIES_PER_KV) @pytest.mark.parametrize("head_size", HEAD_SIZES) @pytest.mark.parametrize("dtype", DTYPES) @pytest.mark.parametrize("kv_cache_dtype", KV_CACHE_DTYPES) @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("op", OPS) @torch.inference_mode() def test_contexted_kv_attention_alibi( num_heads: int, num_queries_per_kv: int, head_size: int, dtype: torch.dtype, kv_cache_dtype: str, device: str, op: Callable, ) -> None: if 'fp8' in kv_cache_dtype and not current_platform.has_device_capability( 89): pytest.skip( 'Triton limitation: fp8e4nv data type is not supported on CUDA' ' arch < 89') current_platform.seed_everything(0) torch.set_default_device(device) # Need this, otherwise when we capture the graph the process # for GPU 1 would run on both GPU0 and GPU1 and things would hang # # see also similar issue: https://github.com/Dao-AILab/flash-attention/issues/523 torch.cuda.set_device(device) def _get_alibi_slopes(total_num_heads: int) -> torch.Tensor: # Fork from: vllm/vllm/model_executor/models/bloom.py#L44 closest_power_of_2 = 2**math.floor(math.log2(total_num_heads)) base = torch.tensor( 2**(-(2**-(math.log2(closest_power_of_2) - 3))), dtype=torch.float32, ) powers = torch.arange(1, 1 + closest_power_of_2, dtype=torch.int32) slopes = torch.pow(base, powers) if closest_power_of_2 != total_num_heads: extra_base = torch.tensor( 2**(-(2**-(math.log2(2 * closest_power_of_2) - 3))), dtype=torch.float32, ) num_remaining_heads = min(closest_power_of_2, total_num_heads - closest_power_of_2) extra_powers = torch.arange(start=1, end=1 + 2 * num_remaining_heads, step=2, dtype=torch.int32) slopes = torch.cat( [slopes, torch.pow(extra_base, extra_powers)], dim=0) return slopes alibi_slopes = _get_alibi_slopes(num_heads).to(device) MAX_SEQ_LEN = 1024 MAX_CTX_LEN = 1024 BS = 10 cache_size = 640 block_size = 32 max_block_per_request = 64 query_lens = [random.randint(16, MAX_SEQ_LEN) for _ in range(BS)] ctx_lens = [random.randint(16, MAX_CTX_LEN) for _ in range(BS)] seq_lens = [a + b for a, b in zip(query_lens, ctx_lens)] num_kv_heads = num_heads // num_queries_per_kv num_tokens = sum(query_lens) query = torch.empty(num_tokens, num_heads, head_size, dtype=dtype) query.uniform_(-1e-3, 1e-3) output = torch.empty(num_tokens, num_heads, head_size, dtype=dtype) kv = torch.empty(sum(seq_lens), 2, num_kv_heads, head_size, dtype=dtype) kv.uniform_(-1e-3, 1e-3) key, value = kv.unbind(dim=1) if kv_cache_dtype == "auto": cache_dtype = dtype else: cache_dtype = STR_DTYPE_TO_TORCH_DTYPE[kv_cache_dtype] k_cache = torch.zeros(cache_size, block_size, num_kv_heads, head_size, dtype=cache_dtype) v_cache = torch.zeros(cache_size, block_size, num_kv_heads, head_size, dtype=cache_dtype) k = torch.zeros(sum(query_lens), num_kv_heads, head_size, dtype=dtype) v = torch.zeros(sum(query_lens), num_kv_heads, head_size, dtype=dtype) values = torch.arange(0, cache_size, dtype=torch.long) values = values[torch.randperm(cache_size)] block_table = values[:BS * max_block_per_request].view( BS, max_block_per_request) b_seq_len = torch.tensor(seq_lens, dtype=torch.long) b_ctx_len = torch.tensor(ctx_lens, dtype=torch.long) b_start_loc = torch.cumsum(torch.tensor([0] + query_lens, dtype=torch.long), dim=0) max_input_len = MAX_SEQ_LEN # copy kv to cache b_seq_start_loc = torch.cumsum(torch.tensor([0] + seq_lens[:-1], dtype=torch.long), dim=0) for i in range(BS): for j in range(query_lens[i]): k[b_start_loc[i] + j].copy_(key[b_seq_start_loc[i] + b_ctx_len[i] + j]) v[b_start_loc[i] + j].copy_(value[b_seq_start_loc[i] + b_ctx_len[i] + j]) cur_ctx = 0 block_id = 0 while cur_ctx < b_ctx_len[i]: start_loc = b_seq_start_loc[i] + cur_ctx if cur_ctx + block_size > b_ctx_len[i]: end_loc = b_seq_start_loc[i] + b_ctx_len[i] else: end_loc = start_loc + block_size start_slot = block_table[i, block_id] * block_size end_slot = start_slot + end_loc - start_loc k_cache.view(-1, num_kv_heads, head_size)[start_slot:end_slot].copy_( key[start_loc:end_loc]) v_cache.view(-1, num_kv_heads, head_size)[start_slot:end_slot].copy_( value[start_loc:end_loc]) cur_ctx += block_size block_id += 1 # transpose K_cache[num_blocks, block_size, num_kv_heads, head_size] # to K_cache[num_blocks, num_kv_heads, head_size/8, block_size, 8] k_cache = k_cache.view(-1, block_size, num_kv_heads, head_size // 8, 8).permute(0, 2, 3, 1, 4).contiguous() # transpose V_cache[num_blocks, block_size, num_kv_heads, head_size] # to V_cache[num_blocks, num_kv_heads, head_size, block_size] v_cache = v_cache.view(-1, block_size, num_kv_heads, head_size).permute(0, 2, 3, 1).contiguous() k_scale = v_scale = torch.tensor(1.0, dtype=torch.float32, device=device) # Warm up the Triton kernel by calling it once before actually measuring # generation time op(query, k, v, output, kv_cache_dtype, k_cache, v_cache, block_table, b_start_loc, b_seq_len, MAX_CTX_LEN, max_input_len, k_scale, v_scale, alibi_slopes=alibi_slopes) torch.cuda.synchronize() start_time = time.time() op(query, k, v, output, kv_cache_dtype, k_cache, v_cache, block_table, b_start_loc, b_seq_len, MAX_CTX_LEN, max_input_len, k_scale, v_scale, alibi_slopes=alibi_slopes) torch.cuda.synchronize() end_time = time.time() print(f"triton Time: {(end_time - start_time)*1000:.2f} ms") scale = float(1.0 / (head_size**0.5)) # NOTE(DefTruth): In order to reuse _make_alibi_bias function, # we have to pad query tensor before MQA/GQA expanding. if query.shape[0] != key.shape[0]: query_pad = torch.empty(sum(seq_lens), num_heads, head_size, dtype=dtype) query_pad.uniform_(-1e-3, 1e-3) seq_start = 0 query_start = 0 for i, (query_len, seq_len) in enumerate(zip(query_lens, seq_lens)): seq_end = seq_start + seq_len query_end = query_start + query_len query_pad[seq_start:seq_end, ...] = torch.cat([ torch.zeros( seq_len - query_len, num_heads, head_size, dtype=dtype), query[query_start:query_end, ...] ], dim=0) seq_start += seq_len query_start += query_len query = query_pad if num_kv_heads != num_heads: # As of Nov 2023, xformers only supports MHA. For MQA/GQA, # project the key and value tensors to the desired number of # heads. # # see also: vllm/model_executor/layers/attention.py key = key[:, :, None, :].expand(key.shape[0], num_kv_heads, num_queries_per_kv, key.shape[-1]) value = value[:, :, None, :].expand(value.shape[0], num_kv_heads, num_queries_per_kv, value.shape[-1]) # [seq, num_kv_heads, num_queries_per_kv, dk]=> # [seq, num_kv_heads*num_queries_per_kv, dk] to comply with rest of the # codebase. We save some time reshaping alibi matrix at runtime. key = key.reshape(key.shape[0], -1, key.shape[-1]) value = value.reshape(value.shape[0], -1, value.shape[-1]) query = query.unsqueeze(0) key = key.unsqueeze(0) value = value.unsqueeze(0) attn_bias = _make_alibi_bias(alibi_slopes, num_kv_heads, dtype, seq_lens) output_ref = torch.empty_like(output) seq_start = 0 query_start = 0 start_time = time.time() # Attention with alibi slopes. # FIXME(DefTruth): Because xformers does not support dynamic sequence # lengths with custom attention bias, we process each prompt one by # one. This is inefficient, especially when we have many short prompts. # modified from: vllm/attention/backends/xformers.py#L343 for i, (query_len, seq_len) in enumerate(zip(query_lens, seq_lens)): seq_end = seq_start + seq_len query_end = query_start + query_len out = xops.memory_efficient_attention_forward(query[:, seq_start:seq_end], key[:, seq_start:seq_end], value[:, seq_start:seq_end], attn_bias=attn_bias[i], p=0.0, scale=scale) out = out.view_as(query[:, seq_start:seq_end]).view( seq_len, num_heads, head_size) output_ref[query_start:query_end, ...].copy_(out[seq_len - query_len:, ...]) seq_start += seq_len query_start += query_len torch.cuda.synchronize() end_time = time.time() print(f"xformers Time: {(end_time - start_time)*1000:.2f} ms") atol = 1e-3 if "fp8" in kv_cache_dtype else 1e-6 torch.testing.assert_close(output, output_ref, atol=atol, rtol=0) # These tests are optional to only run when explicitly invoked # # pytest -v -s --optional \ # tests/kernels/test_prefix_prefill.py::test_contexted_kv_attention_f32 # # These tests are useful to test model dtype float32 on Turing devices. # We skip them to not increase the time when running tests on CI @pytest.mark.optional @pytest.mark.parametrize("num_heads", NUM_HEADS) @pytest.mark.parametrize("num_queries_per_kv", NUM_QUERIES_PER_KV) @pytest.mark.parametrize("head_size", HEAD_SIZES) @pytest.mark.parametrize("dtype", [torch.float32]) @pytest.mark.parametrize("kv_cache_dtype", KV_CACHE_DTYPES) @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("sliding_window", SLIDING_WINDOW) @pytest.mark.parametrize("op", OPS) @torch.inference_mode() def test_contexted_kv_attention_f32( num_heads: int, num_queries_per_kv: int, head_size: int, sliding_window: int, dtype: torch.dtype, kv_cache_dtype: str, device: str, op: Callable, ) -> None: test_contexted_kv_attention(num_heads, num_queries_per_kv, head_size, sliding_window, dtype, kv_cache_dtype, device, op) @pytest.mark.optional @pytest.mark.parametrize("num_heads", NUM_HEADS) @pytest.mark.parametrize("num_queries_per_kv", NUM_QUERIES_PER_KV) @pytest.mark.parametrize("head_size", HEAD_SIZES) @pytest.mark.parametrize("dtype", [torch.float32]) @pytest.mark.parametrize("kv_cache_dtype", KV_CACHE_DTYPES) @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("op", OPS) @torch.inference_mode() def test_contexted_kv_attention_alibi_f32( num_heads: int, num_queries_per_kv: int, head_size: int, dtype: torch.dtype, kv_cache_dtype: str, device: str, op: Callable, ) -> None: test_contexted_kv_attention_alibi(num_heads, num_queries_per_kv, head_size, dtype, kv_cache_dtype, device, op)