vllm-ascend/vllm_ascend/compilation/acl_graph.py

# SPDX-License-Identifier: Apache-2.0
# SPDX-FileCopyrightText: Copyright contributors to the vLLM project

import dataclasses
from contextlib import ExitStack
from dataclasses import dataclass
from typing import Any, Callable, Optional
from unittest.mock import patch

import torch
import torch_npu
import vllm.envs as envs
from vllm.compilation.counter import compilation_counter
from vllm.compilation.cuda_graph import CUDAGraphOptions
from vllm.compilation.monitor import validate_cudagraph_capturing_enabled
from vllm.config import CUDAGraphMode, VllmConfig
from vllm.forward_context import BatchDescriptor, get_forward_context
from vllm.logger import logger
from vllm.platforms import current_platform

from vllm_ascend.attention.utils import version_check

from ..utils import weak_ref_tensors


@dataclasses.dataclass
class ACLGraphEntry:
    batch_descriptor: BatchDescriptor
    aclgraph: Optional[torch.npu.NPUGraph] = None
    output: Optional[Any] = None

    # for aclgraph debugging, track the input addresses
    # during capture, and check if they are the same during replay
    input_addresses: Optional[list[int]] = None


class ACLGraphWrapper:
    """Wraps a runnable to add acl graph capturing and replaying ability. And
    provide attribute access to the underlying `runnable` via `__getattr__`.

    The workflow of this wrapper in the aclgraph dispatching is as follows:
    1. At initialization, a runtime mode is assigned to the wrapper (FULL or
    PIECEWISE).
    2. At runtime, the wrapper receives a runtime_mode and a
    batch_descriptor(key) from the forward context and blindly trust them
    for aclgraph dispatching.
    3. If runtime_mode is NONE or runtime_mode does not match the mode of the
    wrapper, just call the runnable directly.
    4. Otherwise, i.e., the runtime_mode matches the mode of the wrapper,
    the wrapper will perform aclgraph capture(if key does not exist, create
    a new entry and cache it) or replay (if key exists in the cache).

    Note: ACLGraphWrapper does not store persistent buffers or copy any
    runtime inputs into that buffers for replay. We assume implementing them
    is done outside of the wrapper. That is because we do not make any
    assumption on the dynamic shape (batch size) of the runtime inputs, as a
    trade-off for staying orthogonal to compilation logic. Nevertheless,
    tracing and checking the input addresses to be consistent during replay is
    guaranteed when VLLM_LOGGING_LEVEL == "DEBUG".
    """

    def __init__(self,
                 runnable: Callable,
                 vllm_config: VllmConfig,
                 runtime_mode: CUDAGraphMode,
                 graph_pool: Any = None,
                 cudagraph_options: Optional[CUDAGraphOptions] = None):
        self.runnable = runnable
        self.vllm_config = vllm_config
        self.graph_pool = graph_pool
        self.runtime_mode = runtime_mode
        self.compilation_config = vllm_config.compilation_config

        self.first_run_finished = False
        self.is_debugging_mode = envs.VLLM_LOGGING_LEVEL == "DEBUG"

        # assert runtime_mode is not NONE(no aclgraph), otherwise, we don't
        # need to initialize a ACLGraphWrapper.
        assert self.runtime_mode != CUDAGraphMode.NONE
        if self.graph_pool is None:
            self.graph_pool = current_platform.get_global_graph_pool()

        if cudagraph_options is None:
            cudagraph_options = CUDAGraphOptions()
        self.aclgraph_options = cudagraph_options
        # the entries for different batch descriptors that we need to capture
        # aclgraphs for.
        self.concrete_aclgraph_entries: dict[BatchDescriptor, ACLGraphEntry]\
                                                                        = {}

    def __getattr__(self, key: str):
        # allow accessing the attributes of the runnable.
        if hasattr(self.runnable, key):
            return getattr(self.runnable, key)
        raise AttributeError(f"Attribute {key} not exists in the runnable of "
                             f"aclgraph wrapper: {self.runnable}")

    def unwrap(self) -> Callable:
        # in case we need to access the original runnable.
        return self.runnable

    def __call__(self, *args, **kwargs):
        forward_context = get_forward_context()
        batch_descriptor = forward_context.batch_descriptor
        aclgraph_runtime_mode = forward_context.cudagraph_runtime_mode

        if aclgraph_runtime_mode == CUDAGraphMode.NONE or \
                            aclgraph_runtime_mode != self.runtime_mode:
            # CUDAGraphMode.NONE could mean the profile run, a warmup run, or
            # running without aclgraphs.
            # We do not trigger capture/replay if the runtime mode is not
            # matches. This enables properly dispatching to the correct
            # CUDAGraphWrapper when nesting multiple instances with different
            # runtime modes.
            return self.runnable(*args, **kwargs)

        if batch_descriptor not in self.concrete_aclgraph_entries:
            # create a new entry for this batch descriptor
            self.concrete_aclgraph_entries[batch_descriptor] = \
                ACLGraphEntry(batch_descriptor=batch_descriptor)

        entry = self.concrete_aclgraph_entries[batch_descriptor]

        if entry.aclgraph is None:
            if self.aclgraph_options.debug_log_enable:
                # Since we capture aclgraph for many different shapes and
                # capturing is fast, we don't need to log it for every
                # shape. E.g. we only log it for the first subgraph in
                # piecewise mode.
                logger.debug("Capturing a aclgraph on (%s,%s)",
                             self.runtime_mode.name, entry.batch_descriptor)
            # validate that aclgraph capturing is legal at this point.
            validate_cudagraph_capturing_enabled()

            input_addresses = [
                x.data_ptr() for x in args if isinstance(x, torch.Tensor)
            ]
            entry.input_addresses = input_addresses
            aclgraph = torch.npu.NPUGraph()

            with ExitStack() as stack:
                if self.aclgraph_options.gc_disable:
                    # during every model forward for piecewise aclgraph
                    # mode, we will capture many pieces of aclgraphs
                    # (roughly one per layer). running gc again and again
                    # across layers will make the aclgraph capture very slow.
                    # therefore, we only run gc for the first graph,
                    # and disable gc for the rest of the graphs.
                    stack.enter_context(patch("gc.collect", lambda: None))
                    stack.enter_context(
                        patch("torch.npu.empty_cache", lambda: None))

                # mind-exploding: carefully manage the reference and memory.
                forward_context.capturing = True
                with torch.npu.graph(aclgraph, pool=self.graph_pool):
                    # `output` is managed by pytorch's aclgraph pool
                    output = self.runnable(*args, **kwargs)
                    if self.aclgraph_options.weak_ref_output:
                        # by converting it to weak ref,
                        # the original `output` will immediately be released
                        # to save memory. It is only safe to do this for
                        # the last graph in piecewise aclgraph mode, because
                        # the output of the last graph will not be used by
                        # any other acl graph.
                        output = weak_ref_tensors(output)

            # here we always use weak ref for the output
            # to save memory
            entry.output = weak_ref_tensors(output)
            entry.aclgraph = aclgraph

            compilation_counter.num_cudagraph_captured += 1

            # important: we need to return the output, rather than
            # the weak ref of the output, so that pytorch can correctly
            # manage the memory during acl graph capture
            return output

        if self.is_debugging_mode:
            # check if the input addresses are the same
            new_input_addresses = [
                x.data_ptr() for x in args if isinstance(x, torch.Tensor)
            ]
            assert new_input_addresses == entry.input_addresses, (
                f"Input addresses for aclgraphs are different "
                f"during replay. Expected {entry.input_addresses}, "
                f"got {new_input_addresses}")

        logger.info_once("Replaying aclgraph")
        entry.aclgraph.replay()
        return entry.output


def update_attn_params(update_stream, forward_context, runtime_shape):
    graph_params = get_graph_params()
    # FIXME: Behold! We are using a temporary hack here to update the args
    # for each layer's attention op in the graph.
    for key, param, handle, event in zip(
            forward_context.attn_metadata,
            graph_params.attn_params[runtime_shape],
            graph_params.handles[runtime_shape],
            graph_params.events[runtime_shape],
    ):
        (
            query,
            key_cache,
            value_cache,
            num_kv_heads,
            num_heads,
            scale,
            block_table,
            seq_lens,
            output,
        ) = param
        # block_table = forward_context.attn_metadata[key].block_tables
        seq_lens = forward_context.attn_metadata[key].seq_lens
        torch_npu_check = version_check()

        with torch.npu.stream(update_stream):
            torch.npu.graph_task_update_begin(update_stream, handle)
            if torch_npu_check:
                torch_npu._npu_paged_attention(
                    query=query,
                    key_cache=key_cache,
                    value_cache=value_cache,
                    num_kv_heads=num_kv_heads,
                    num_heads=num_heads,
                    scale_value=scale,
                    block_table=block_table,
                    context_lens=seq_lens,
                    out=output,
                    workspace=graph_params.workspaces.get(runtime_shape))
            else:
                torch_npu._npu_paged_attention(query=query,
                                               key_cache=key_cache,
                                               value_cache=value_cache,
                                               num_kv_heads=num_kv_heads,
                                               num_heads=num_heads,
                                               scale_value=scale,
                                               block_table=block_table,
                                               context_lens=seq_lens,
                                               out=output)
            torch.npu.graph_task_update_end(update_stream)

            event.record(update_stream)


def update_mla_attn_params(update_stream, forward_context, runtime_shape):
    graph_params = get_graph_params()
    # FIXME: Behold! We are using a temporary hack here to update the args
    # for each layer's attention op in the graph.
    for key, param, handle, event in zip(
            forward_context.attn_metadata,
            graph_params.attn_params[runtime_shape],
            graph_params.handles[runtime_shape],
            graph_params.events[runtime_shape],
    ):
        (q_nope, k_nope, q_pe, k_pe, num_heads, num_kv_heads, input_layout,
         spec_attn_mask, sparse_mode, scale, block_table, block_size,
         seq_lens_list, actual_seq_lengths, workspace, attn_output,
         softmax_lse) = param
        seq_lens_list = forward_context.attn_metadata[key].decode.seq_lens_list
        seq_lens_list = seq_lens_list + [0] * (runtime_shape -
                                               len(seq_lens_list))

        with torch.npu.stream(update_stream):
            torch.npu.graph_task_update_begin(update_stream, handle)

            torch_npu.npu_fused_infer_attention_score.out(
                q_nope,
                k_nope,
                k_nope,
                query_rope=q_pe,
                key_rope=k_pe,
                num_heads=num_heads,
                num_key_value_heads=num_kv_heads,
                input_layout=input_layout,
                atten_mask=spec_attn_mask,
                sparse_mode=sparse_mode,
                scale=scale,
                antiquant_mode=0,
                antiquant_scale=None,
                block_table=block_table,
                block_size=block_size,
                actual_seq_lengths_kv=seq_lens_list,
                actual_seq_lengths=actual_seq_lengths,
                workspace=workspace,
                out=[attn_output, softmax_lse])
            torch.npu.graph_task_update_end(update_stream)

            event.record(update_stream)


@dataclass
class GraphParams:
    events: dict[int, list[torch.npu.ExternalEvent]]
    workspaces: dict[int, torch.Tensor]
    handles: dict[int, list[torch_npu._C._NPUTaskGroupHandle]]
    attn_params: dict[int, list[tuple]]


_graph_params: Optional[GraphParams] = None


def set_graph_params(aclgraph_capture_sizes: set[int]):
    global _graph_params
    if _graph_params is not None:
        raise ValueError("Graph parameters have already been set!")
    _graph_params = GraphParams(
        {size: []
         for size in aclgraph_capture_sizes},
        {size: None
         for size in aclgraph_capture_sizes},
        {size: []
         for size in aclgraph_capture_sizes},
        {size: []
         for size in aclgraph_capture_sizes},
    )


def update_graph_params_workspaces(num_tokens: int, workspace: int):
    global _graph_params
    if _graph_params is not None:
        _graph_params.workspaces[num_tokens] = workspace


def get_graph_params():
    return _graph_params