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chore: import upstream snapshot with attribution
2026-07-13 12:32:31 +08:00

545 lines
21 KiB
Python

# Copyright (c) 2026 LightSeek Foundation
#
# Permission is hereby granted, free of charge, to any person obtaining a copy
# of this software and associated documentation files (the "Software"), to deal
# in the Software without restriction, including without limitation the rights
# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
# copies of the Software, and to permit persons to whom the Software is
# furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included in
# all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
# SOFTWARE.
from __future__ import annotations
from dataclasses import dataclass
from typing import TYPE_CHECKING, Any
import torch
from tokenspeed_kernel.ops.sampling import argmax as sampling_argmax
from typing_extensions import override
from tokenspeed.runtime.execution.cache_loc_kernel import (
compute_out_cache_loc_uniform,
)
from tokenspeed.runtime.execution.context import ForwardContext
from tokenspeed.runtime.execution.drafter.base import BaseDrafter
from tokenspeed.runtime.execution.forward_batch_info import (
CaptureHiddenMode,
ForwardMode,
)
from tokenspeed.runtime.multimodal.inputs import maybe_substitute_mm_pad
from tokenspeed.runtime.utils.nvtx import nvtx_range
DsaTopKState = tuple[Any | None, Any | None]
if TYPE_CHECKING:
from tokenspeed.runtime.execution.input_buffer import InputBuffers
from tokenspeed.runtime.execution.model_runner import ModelRunner
from tokenspeed.runtime.execution.runtime_states import RuntimeStates
from tokenspeed.runtime.layers.attention.backends.base import AttentionBackend
from tokenspeed.runtime.layers.attention.kv_cache.base import BaseTokenToKVPool
from tokenspeed.runtime.layers.logits_processor import LogitsProcessorOutput
def _advance_draft_forward_metadata_if_supported(attn_backend, seq_lens) -> None:
advance = getattr(attn_backend, "advance_draft_forward_metadata", None)
if advance is not None:
advance(seq_lens)
@dataclass
class EagleDraftInput:
input_num_tokens: int
num_extends: int
forward_mode: ForwardMode
base_model_output: torch.Tensor # [bs]
accept_lengths: torch.Tensor # [bs]
base_out_hidden_states: torch.Tensor
global_num_tokens: list[int] | None = None
global_bs: list[int] | None = None
all_decode_or_idle: bool = False
dsa_topk: DsaTopKState = (None, None)
class Eagle(BaseDrafter):
"""
Draft model runner that implements the Eagle/Eagle3 algorithm.
"""
def __init__(
self,
spec_num_tokens: int,
spec_num_steps: int,
page_size: int,
draft_model_runner: ModelRunner,
req_to_page: torch.Tensor,
attn_backend: AttentionBackend | None = None,
token_to_kv_pool: BaseTokenToKVPool | None = None,
runtime_states: RuntimeStates | None = None,
input_buffers: InputBuffers | None = None,
vocab_size: int | None = None,
) -> None:
super().__init__(
spec_num_tokens,
spec_num_steps,
draft_model_runner,
runtime_states=runtime_states,
input_buffers=input_buffers,
page_size=page_size,
req_to_page=req_to_page,
attn_backend=attn_backend,
token_to_kv_pool=token_to_kv_pool,
vocab_size=vocab_size,
)
self.device = draft_model_runner.device
hot_token_ids = draft_model_runner.model.get_hot_token_id()
if hot_token_ids is not None:
self.hot_token_ids = hot_token_ids.to(self.device)
else:
self.hot_token_ids = None
# For constructing fallback global_num_tokens during CUDA graph capture.
self.dp_size = draft_model_runner.mapping.attn.dp_size
self.world_size = draft_model_runner.mapping.world_size
# Drafter-owned alias source for the draft attn backend; advanced in
# place during multi-step decode.
self.draft_seq_lens_buf = torch.zeros_like(self.input_buffers.seq_lens_buf)
# Persistent output buffer for the draft step's compute_out_cache_loc.
self.draft_out_cache_loc_buf = torch.empty(
(self.input_buffers.max_bs * (spec_num_steps - 1),),
dtype=torch.int32,
device=self.device,
)
# Precomputed `arange(max_bs) * spec_num_tokens - 1`
# gather_ids = gather_ids_offsets + accept_lengths
self.padded_gather_ids_offsets_buf = (
torch.arange(
self.input_buffers.max_bs, dtype=torch.int64, device=self.device
)
* spec_num_tokens
- 1
)
# VLM placeholder id plumbed by ModelExecutor; None for text-only targets.
self.mm_pad_substitute_id: int | None = None
hf_config = getattr(draft_model_runner.model_config, "hf_config", None)
self._dsa_reuse_mtp_topk = bool(
getattr(hf_config, "index_share_for_mtp_iteration", False)
)
def _accepted_output_indices(
self,
accept_lengths: torch.Tensor,
row_count: int,
*,
base_offset: int = 0,
) -> torch.Tensor:
"""Return safe flat output-token indices for each decode request.
``accept_lengths`` is the number of tokens that may be committed. When
the context-length cap reduces a row to 0 there is no real newly
committed output token, but the drafter still runs to preserve graph
shape. Use the row's first verify output as a valid dummy source rather
than producing ``row * N - 1``.
"""
safe_accept_lengths = (
accept_lengths[:row_count].to(torch.int64).clamp(1, self.spec_num_tokens)
)
return (
self.padded_gather_ids_offsets_buf[:row_count]
+ safe_accept_lengths
+ base_offset
)
def set_mm_pad_substitute_id(self, token_id: int) -> None:
self.mm_pad_substitute_id = token_id
# ------------------------------------------------------------------
# Internal helpers
# ------------------------------------------------------------------
def _attach_dsa_topk(
self,
ctx: ForwardContext,
dsa_topk: DsaTopKState,
) -> None:
if not self._dsa_reuse_mtp_topk:
return
ctx.dsa_prefill_topk, ctx.dsa_decode_topk = dsa_topk
def _extract_dsa_topk(
self,
ctx: ForwardContext,
dsa_topk: DsaTopKState,
) -> DsaTopKState:
if not self._dsa_reuse_mtp_topk:
return dsa_topk
return ctx.dsa_prefill_topk, ctx.dsa_decode_topk
def _map_hot(self, ids: torch.Tensor) -> torch.Tensor:
"""Map token ids through hot_token_ids if available, otherwise return as-is."""
return self.hot_token_ids[ids] if self.hot_token_ids is not None else ids
def _get_first_step_input(
self,
draft_input: EagleDraftInput,
bs: int,
input_num_tokens: int,
) -> tuple[torch.Tensor, torch.Tensor]:
"""Returns (input_ids, gather_ids) for the first draft step.
The first-step input shape matches the base model's: ragged
``[prefill_part || decode_part]`` under MIXED, full prefill chunks
under EXTEND, ``base_model_output`` directly under DECODE.
"""
num_extends = draft_input.num_extends
num_decodes = bs - num_extends
if num_extends > 0:
num_decode_tokens = num_decodes * self.spec_num_tokens
num_prefill_tokens = input_num_tokens - num_decode_tokens
input_ids = self.input_buffers.shifted_prefill_ids_buf[:input_num_tokens]
unpadded_input_lengths = self.input_buffers.input_lengths_buf[:bs]
if num_decodes > 0:
input_ids[num_prefill_tokens:].copy_(
draft_input.base_model_output[num_extends:]
)
unpadded_input_lengths[num_extends:].copy_(
draft_input.accept_lengths[num_extends:]
)
last_indices = unpadded_input_lengths[:num_extends].cumsum(0) - 1
last_input_ids = input_ids[last_indices]
input_ids[last_indices] = torch.where(
last_input_ids == -1,
draft_input.base_model_output[:num_extends],
last_input_ids,
)
gather_ids = last_indices
if num_decodes > 0:
gather_ids = torch.cat(
[
gather_ids,
self._accepted_output_indices(
draft_input.accept_lengths[num_extends:],
num_decodes,
base_offset=num_prefill_tokens,
),
]
)
else:
input_ids = draft_input.base_model_output
gather_ids = self._accepted_output_indices(
draft_input.accept_lengths,
bs,
)
return input_ids, gather_ids
@nvtx_range("draft_first_step", color="purple")
def _run_first_step(
self,
bs: int,
draft_input: EagleDraftInput,
) -> tuple[LogitsProcessorOutput, DsaTopKState]:
buffers = self.input_buffers
forward_mode = draft_input.forward_mode
input_ids, gather_ids = self._get_first_step_input(
draft_input, bs, draft_input.input_num_tokens
)
input_ids = maybe_substitute_mm_pad(input_ids, self.mm_pad_substitute_id)
draft_model = self.draft_model_runner.model
input_num_tokens = draft_input.input_num_tokens
ctx = ForwardContext(
attn_backend=self.attn_backend,
token_to_kv_pool=self.token_to_kv_pool,
req_to_page=self.req_to_page,
bs=bs,
num_extends=draft_input.num_extends,
input_num_tokens=input_num_tokens,
forward_mode=forward_mode,
capture_hidden_mode=CaptureHiddenMode.LAST,
gather_ids=gather_ids,
global_num_tokens=draft_input.global_num_tokens,
global_bs=draft_input.global_bs,
all_decode_or_idle=draft_input.all_decode_or_idle,
draft_seq_lens_buf=self.draft_seq_lens_buf,
accept_lengths=draft_input.accept_lengths,
)
dsa_topk = draft_input.dsa_topk
prepare_dsa_topk = getattr(draft_model, "prepare_dsa_topk_for_mtp_decode", None)
compute_dsa_topk_first_step = bool(
getattr(draft_model, "compute_dsa_topk_first_step", False)
)
if compute_dsa_topk_first_step:
# GLM NextN has its own indexer weights. Compute first-step top-k
# in the draft model, then select rows used by later MTP steps.
dsa_topk = (None, None)
elif draft_input.num_extends == 0 and prepare_dsa_topk is not None:
dsa_topk = prepare_dsa_topk(dsa_topk, gather_ids)
else:
dsa_topk = (None, None)
self._attach_dsa_topk(ctx, dsa_topk)
logits_output = self.draft_model_runner.forward(
ctx=ctx,
input_ids=input_ids,
positions=buffers.positions_buf[:input_num_tokens],
out_cache_loc=buffers.out_cache_loc_buf[:input_num_tokens],
captured_hidden_states=draft_input.base_out_hidden_states,
spec_step_idx=0,
)
dsa_topk = self._extract_dsa_topk(ctx, dsa_topk)
if compute_dsa_topk_first_step and prepare_dsa_topk is not None:
dsa_topk = prepare_dsa_topk(
dsa_topk,
gather_ids,
num_prefill_rows=draft_input.num_extends,
)
return logits_output, dsa_topk
@nvtx_range("draft_multi_step", color="purple")
def _run_multi_step_decode(
self,
bs: int,
draft_ids: torch.Tensor,
next_tokens: torch.Tensor,
logits_output: LogitsProcessorOutput,
draft_input: EagleDraftInput,
dsa_topk: DsaTopKState,
) -> None:
num_extends = draft_input.num_extends
num_decodes = bs - num_extends
req_pool_indices = self.input_buffers.req_pool_indices_buf[:bs]
cache_start = self.input_buffers.seq_lens_buf[:bs].clone()
# Step 1's write position uses vc+accept_length after target verify so
# rotary/cache metadata stay on the accepted prefix, not rejected tail.
if num_decodes > 0:
cache_start[num_extends:] = (
self.runtime_states.valid_cache_lengths.index_select(
0, req_pool_indices[num_extends:]
)
+ draft_input.accept_lengths[num_extends:]
)
# Write cache slots for steps 1..N-1.
cache_locs = self.draft_out_cache_loc_buf[: bs * (self.spec_num_steps - 1)]
compute_out_cache_loc_uniform(
out_cache_loc_ptr=cache_locs,
req_pool_indices=req_pool_indices,
uniform_input_length=self.spec_num_steps - 1,
cache_start=cache_start,
req_to_pages=self.req_to_page,
page_size=self.page_size,
)
cache_locs = cache_locs.view(bs, self.spec_num_steps - 1)
# +1 is the kernel's read-inclusive convention; advanced per iter.
draft_seq_lens = self.draft_seq_lens_buf[:bs]
torch.add(cache_start, 1, out=draft_seq_lens)
positions = cache_start.clone()
for i in range(1, self.spec_num_steps):
# make a ctx every time model runner forward
# Multi-step decode is pure DECODE mode: one token per request.
# global_num_tokens must reflect each rank's batch size, not the
# target model's total tokens (which may be bs * spec_num_tokens).
global_num_tokens = draft_input.global_num_tokens
if self.dp_size > 1:
if draft_input.global_bs is not None:
global_num_tokens = draft_input.global_bs
else:
# CUDA graph capture path: uniform batch size across ranks.
global_num_tokens = [bs] * self.world_size
ctx = ForwardContext(
bs=bs,
num_extends=0,
attn_backend=self.attn_backend,
token_to_kv_pool=self.token_to_kv_pool,
req_to_page=self.req_to_page,
input_num_tokens=bs,
forward_mode=ForwardMode.DECODE,
capture_hidden_mode=CaptureHiddenMode.LAST,
global_num_tokens=global_num_tokens,
global_bs=draft_input.global_bs,
all_decode_or_idle=draft_input.all_decode_or_idle,
)
self._attach_dsa_topk(ctx, dsa_topk)
out_cache_loc = cache_locs[:, i - 1].contiguous()
# Keep attention metadata on the accepted prefix; rejected verify
# tail slots may still contain stale draft KV.
_advance_draft_forward_metadata_if_supported(
ctx.attn_backend,
draft_seq_lens,
)
with nvtx_range("draft_forward", color="red"):
logits_output = self.draft_model_runner.forward(
ctx=ctx,
input_ids=self._map_hot(draft_ids),
positions=positions,
out_cache_loc=out_cache_loc,
captured_hidden_states=logits_output.hidden_states,
spec_step_idx=i,
)
dsa_topk = self._extract_dsa_topk(ctx, dsa_topk)
with nvtx_range("draft_sample", color="yellow"):
if logits_output.next_token_ids is not None:
draft_ids = logits_output.next_token_ids
else:
draft_ids = sampling_argmax(logits_output.next_token_logits)
# Column 0 holds last_verified_ids; drafter writes step `i` into column `i + 1`.
next_tokens[:, i + 1] = self._map_hot(draft_ids)
if i + 1 < self.spec_num_steps:
positions.add_(1)
draft_seq_lens.add_(1)
# ------------------------------------------------------------------
# Public entry point (type-based dispatch from ModelExecutor)
# ------------------------------------------------------------------
@override
def get_candidates(
self,
base_ctx: ForwardContext,
) -> torch.Tensor | None:
num_extends = base_ctx.num_extends
num_decodes = base_ctx.bs - num_extends
if num_decodes == 0:
return None
num_decode_tokens = num_decodes * self.spec_num_tokens
num_prefill_tokens = base_ctx.input_num_tokens - num_decode_tokens
return self.input_buffers.input_ids_buf[
num_prefill_tokens : base_ctx.input_num_tokens
].reshape(num_decodes, self.spec_num_tokens)
@override
def draft(
self,
draft_input: EagleDraftInput,
) -> torch.Tensor:
bs = draft_input.accept_lengths.shape[0]
# Layout: column 0 holds the last verified id (the base model's accepted token);
# columns 1..spec_num_steps hold the drafter's speculative tokens.
next_tokens = torch.empty(
(bs, self.spec_num_steps + 1),
dtype=torch.int32,
device=self.device,
)
# Last verified id per request → next_tokens[:, 0].
num_extends = draft_input.num_extends
num_decodes = bs - num_extends
if num_extends > 0:
next_tokens[:num_extends, 0] = draft_input.base_model_output[:num_extends]
if num_decodes > 0:
indices = self._accepted_output_indices(
draft_input.accept_lengths[num_extends:],
num_decodes,
)
if num_extends > 0:
indices.add_(num_extends)
torch.index_select(
draft_input.base_model_output,
0,
indices,
out=next_tokens[num_extends:, 0],
)
if self.spec_num_steps > 0:
next_tokens[:, 1:] = next_tokens[:, :1]
# Seed the draft attn backend's aliased seq_lens for the first step.
self.draft_seq_lens_buf[:bs].copy_(self.input_buffers.seq_lens_buf[:bs])
# First draft step. LogitsProcessor prunes `[num_prefill_tokens + num_decodes * spec_num_tokens, ...]`
# down to `[bs, ...]`, so logits/hidden_states arrive here already aligned to one row per request.
logits_output, dsa_topk = self._run_first_step(bs, draft_input)
if logits_output.next_token_ids is not None:
draft_ids = logits_output.next_token_ids
else:
draft_ids = sampling_argmax(logits_output.next_token_logits)
next_tokens[:, 1] = self._map_hot(draft_ids)
if self.spec_num_steps <= 1:
return next_tokens
if self.input_buffers.all_extends_mid_chunk and self.dp_size == 1:
# Skip multi-step when the whole batch is mid-chunk EXTEND:
# no request completes a target-side speculative verification
# after this forward, so any speculative tokens would be discarded.
#
# In DP we still run, because peer ranks may have completing
# extends or decodes; diverging here would desync the drafter's
# dense-TP / MoE-EP collectives (NCCL hang or RSAG mismatch).
return next_tokens
# Draft step 2+ (multi-step decode).
# Multi-step decode operates on full bs; drop the [num_extends:]
# slice that step 0 may have set up for MIXED target. No-op on
# backends that fill separate prefill/decode metadata at init
# time.
with self.attn_backend.override_num_extends(0):
self._run_multi_step_decode(
bs,
draft_ids,
next_tokens,
logits_output,
draft_input,
dsa_topk,
)
return next_tokens
@override
@nvtx_range("drafter", color="purple")
def run(
self,
base_ctx: ForwardContext,
logits_output: LogitsProcessorOutput,
output_tokens: torch.Tensor,
accept_lengths: torch.Tensor,
) -> torch.Tensor:
draft_input = EagleDraftInput(
input_num_tokens=base_ctx.input_num_tokens,
num_extends=base_ctx.num_extends,
forward_mode=base_ctx.forward_mode,
base_model_output=output_tokens,
accept_lengths=accept_lengths,
base_out_hidden_states=logits_output.hidden_states,
global_num_tokens=base_ctx.global_num_tokens,
global_bs=base_ctx.global_bs,
all_decode_or_idle=base_ctx.all_decode_or_idle,
dsa_topk=(base_ctx.dsa_prefill_topk, base_ctx.dsa_decode_topk),
)
# next_tokens layout: column 0 = last verified id, columns 1.. = drafter tokens.
return self.draft(draft_input)