# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import pytest import torch import vllm.config from vllm.compilation.fusion import FUSED_OPS, FusedRMSQuantKey, RMSNormQuantFusionPass from vllm.compilation.fx_utils import find_op_nodes from vllm.compilation.matcher_utils import QUANT_OPS from vllm.compilation.noop_elimination import NoOpEliminationPass from vllm.compilation.post_cleanup import PostCleanupPass from vllm.config import ( CompilationConfig, CompilationMode, ModelConfig, PassConfig, VllmConfig, ) from vllm.model_executor.layers.layernorm import RMSNorm from vllm.model_executor.layers.quantization.kernels.scaled_mm.cutlass import ( CutlassFP8ScaledMMLinearKernel, ) from vllm.model_executor.layers.quantization.kernels.scaled_mm.flashinfer import ( FlashInferScaledMMLinearKernel, ) from vllm.model_executor.layers.quantization.kernels.scaled_mm.pytorch import ( ChannelWiseTorchScaledMMLinearKernel, PerTensorTorchScaledMMLinearKernel, RowWiseTorchScaledMMLinearKernel, ) from vllm.model_executor.layers.quantization.kernels.scaled_mm.rocm import ( ROCmScaledMMLinearKernel, ) from vllm.model_executor.layers.quantization.kernels.scaled_mm.ScaledMMLinearKernel import ( # noqa: E501 FP8ScaledMMLinearKernel, ) from vllm.model_executor.layers.quantization.utils.quant_utils import ( GroupShape, QuantKey, ScaleDesc, ) from vllm.model_executor.layers.quantization.utils.w8a8_utils import ( cutlass_block_fp8_supported, ) from vllm.platforms import current_platform from vllm.utils.deep_gemm import is_deep_gemm_supported from ..utils import TestBlockFP8Layer, TestFP8Layer from .backend import TestBackend FP8_DTYPE = current_platform.fp8_dtype() RMS_OP = torch.ops._C.rms_norm.default RMS_ADD_OP = torch.ops._C.fused_add_rms_norm.default class TestModel(torch.nn.Module): def __init__( self, hidden_size: int, eps: float, force_kernel: FP8ScaledMMLinearKernel | None, group_shape: GroupShape, *args, **kwargs, ): super().__init__(*args, **kwargs) self.group_shape = group_shape self.norm = [RMSNorm(hidden_size, eps) for _ in range(4)] self.enable_rms_norm_custom_op = self.norm[0].enabled() is_static = group_shape == GroupShape.PER_TENSOR act_quant_scale_desc = ScaleDesc(torch.float32, is_static, group_shape) w_quant_scale_desc = ScaleDesc(torch.float32, True, group_shape) self.activation_quant_key = QuantKey( dtype=FP8_DTYPE, scale=act_quant_scale_desc, symmetric=True ) self.weight_quant_key = QuantKey( dtype=FP8_DTYPE, scale=w_quant_scale_desc, symmetric=True ) if group_shape.is_per_tensor(): self.wscale = [torch.rand(1, dtype=torch.float32) for _ in range(3)] elif group_shape.is_per_group(): self.wscale = [ torch.rand( (hidden_size // group_shape[1], hidden_size // group_shape[1]), dtype=torch.float32, ) for _ in range(3) ] else: # PER_TOKEN self.wscale = [ torch.rand((hidden_size, 1), dtype=torch.float32) for _ in range(3) ] self.act_scale = ( [torch.rand(1, dtype=torch.float32) for _ in range(3)] if is_static else [None for _ in range(3)] ) # Initialize weights self.w = [ torch.rand(hidden_size, hidden_size).to(dtype=FP8_DTYPE) for _ in range(3) ] if not group_shape.is_per_group(): self.w = [self.w[0].t() for _ in range(3)] if group_shape.is_per_group(): self.fp8_linear_layers = [ TestBlockFP8Layer( group_shape=group_shape, weight=self.w[i], weight_scale=self.wscale[i], input_scale=self.act_scale[i], ) for i in range(3) ] else: self.fp8_linear_layers = [ TestFP8Layer( self.activation_quant_key, self.weight_quant_key, self.w[i], self.wscale[i], input_scale=self.act_scale[i], force_kernel=force_kernel, ) for i in range(3) ] self.enable_quant_fp8_custom_op = self.fp8_linear_layers[ 0 ].is_quant_fp8_enabled() def forward(self, x): # avoid having graph input be an arg to a pattern directly x = resid = torch.relu(x) y = self.norm[0](x) x2 = self.fp8_linear_layers[0](y) # make sure resid is used for replacement to work y2, resid = self.norm[1](x2, resid) x3 = self.fp8_linear_layers[1](y2) y3, resid = self.norm[2](x3, resid) # use resid here x4 = self.fp8_linear_layers[2](y3) y4, resid = self.norm[3](x4, resid) # use resid here return y4 def ops_in_model_after(self): return [ FUSED_OPS[FusedRMSQuantKey(self.activation_quant_key, True)], FUSED_OPS[FusedRMSQuantKey(self.activation_quant_key, False)], ] def ops_in_model_before(self): return ( [QUANT_OPS[self.activation_quant_key]] if self.enable_quant_fp8_custom_op else [torch.ops.aten.reciprocal] ) def ops_in_model_before_partial(self): return ( [RMS_OP, RMS_ADD_OP] if self.enable_rms_norm_custom_op else [torch.ops.aten.rsqrt] ) ROCM_FP8_KERNELS = [ ROCmScaledMMLinearKernel, PerTensorTorchScaledMMLinearKernel, RowWiseTorchScaledMMLinearKernel, ChannelWiseTorchScaledMMLinearKernel, ] CUDA_FP8_KERNELS = [ FlashInferScaledMMLinearKernel, CutlassFP8ScaledMMLinearKernel, PerTensorTorchScaledMMLinearKernel, ChannelWiseTorchScaledMMLinearKernel, ] BLOCKWISE_GROUP_SHAPES = [ GroupShape(1, 128), GroupShape(1, 64), ] NON_BLOCKWISE_GROUP_SHAPES = [ GroupShape.PER_TOKEN, GroupShape.PER_TENSOR, ] def _generate_kernel_groupshape_combinations(): """ Generate valid (kernel, group_shape) combinations for testing. """ combinations = [] kernels = CUDA_FP8_KERNELS if current_platform.is_cuda() else ROCM_FP8_KERNELS for kernel in kernels: for group_shape in NON_BLOCKWISE_GROUP_SHAPES: if ( kernel == PerTensorTorchScaledMMLinearKernel and group_shape != GroupShape.PER_TENSOR ): continue if ( kernel == ChannelWiseTorchScaledMMLinearKernel and group_shape != GroupShape.PER_TOKEN ): continue if ( kernel == RowWiseTorchScaledMMLinearKernel and group_shape != GroupShape.PER_TOKEN ): continue combinations.append((kernel, group_shape)) # Blockwise group shapes don't use FP8ScaledMMLinearKernel, so kernel is None for group_shape in BLOCKWISE_GROUP_SHAPES: combinations.append((None, group_shape)) return combinations KERNEL_GROUPSHAPE_COMBINATIONS = _generate_kernel_groupshape_combinations() @pytest.mark.parametrize("dtype", [torch.float16, torch.bfloat16]) @pytest.mark.parametrize("hidden_size", [256]) @pytest.mark.parametrize("num_tokens", [257]) @pytest.mark.parametrize("eps", [1e-5, 1e-6]) @pytest.mark.parametrize("kernel_groupshape", KERNEL_GROUPSHAPE_COMBINATIONS) @pytest.mark.parametrize("enable_rms_norm_custom_op", [True, False]) @pytest.mark.parametrize("enable_quant_fp8_custom_op", [True, False]) @pytest.mark.skipif( not current_platform.is_cuda_alike(), reason="Only test on CUDA and ROCm" ) def test_fusion_rmsnorm_quant( dtype, hidden_size, num_tokens, eps, kernel_groupshape, enable_rms_norm_custom_op, enable_quant_fp8_custom_op, ): torch.set_default_device("cuda") torch.set_default_dtype(dtype) torch.manual_seed(1) # Unpack the (kernel, group_shape) combination force_kernel, group_shape = kernel_groupshape if not enable_quant_fp8_custom_op and group_shape.is_per_group(): pytest.skip("Unsupported unwrapped quant fp8 op for blockwise quantization") # Skip test for 64-bit group shape when running with cutlass or deepgemm if group_shape == GroupShape(1, 64) and ( cutlass_block_fp8_supported() or is_deep_gemm_supported() ): pytest.skip("Unsupported group shape 64 for CUTLASS/DeepGemm") custom_ops = [] if enable_rms_norm_custom_op: custom_ops.append("+rms_norm") if enable_quant_fp8_custom_op: custom_ops.append("+quant_fp8") vllm_config = VllmConfig( model_config=ModelConfig(dtype=dtype), compilation_config=CompilationConfig( mode=CompilationMode.VLLM_COMPILE, custom_ops=custom_ops, pass_config=PassConfig( fuse_norm_quant=True, fuse_act_quant=True, eliminate_noops=True ), ), ) with vllm.config.set_current_vllm_config(vllm_config): # Reshape pass is needed for the fusion pass to work noop_pass = NoOpEliminationPass(vllm_config) fusion_pass = RMSNormQuantFusionPass(vllm_config) cleanup_pass = PostCleanupPass(vllm_config) backend = TestBackend(noop_pass, fusion_pass, cleanup_pass) backend2 = TestBackend(noop_pass, cleanup_pass) model = TestModel(hidden_size, eps, force_kernel, group_shape) # First dimension dynamic x = torch.rand(num_tokens, hidden_size) torch._dynamo.mark_dynamic(x, 0) model_fused = torch.compile(model, backend=backend) result_fused = model_fused(x) model_unfused = torch.compile(model, backend=backend2) result_unfused = model_unfused(x) if dtype == torch.float16: ATOL, RTOL = (2e-3, 2e-3) else: ATOL, RTOL = (1e-2, 1e-2) torch.testing.assert_close(result_fused, result_unfused, atol=ATOL, rtol=RTOL) assert fusion_pass.matched_count == 3 backend.check_before_ops(model.ops_in_model_before()) backend.check_before_ops( model.ops_in_model_before_partial(), fully_replaced=False ) backend.check_after_ops(model.ops_in_model_after()) # If RMSNorm custom op is disabled (native/torch impl used), # there's a risk that the fused add doesn't get included in the # replacement and only the rms part gets fused with quant. # Hence, we check only 2 add nodes are left (final fused rmsnorm add). if not enable_rms_norm_custom_op: n_add_nodes = lambda g: sum(1 for _ in find_op_nodes(torch.ops.aten.add, g)) # 7 = 1 (RMS) + 3x2 (3xRMS_ADD, 2 each) assert n_add_nodes(backend.graph_pre_pass) == 7 assert n_add_nodes(backend.graph_post_pass) == 2