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chore: import upstream snapshot with attribution
2026-07-13 13:23:58 +08:00

286 lines
11 KiB
Python

"""The pass that attaches logit processor functions to the IRModule."""
import tvm
from tvm import IRModule
from tvm.script import tirx as T
from ..support.max_thread_check import (
check_thread_limits,
get_max_num_threads_per_block,
)
@tvm.transform.module_pass(opt_level=0, name="AttachLogitProcessFunc")
class AttachLogitProcessFunc:
"""Attach logit processing TIR functions to IRModule."""
def __init__(self, target: tvm.target.Target):
"""Initializer.
Parameters
----------
target : tvm.target.Target
The target of the model compilation.
"""
self.target = target
def transform_module(self, mod: IRModule, _ctx: tvm.transform.PassContext) -> IRModule:
"""Entrypoint"""
mod = mod.clone()
if self.target.kind.name == "llvm":
mod["apply_logit_bias_inplace"] = _get_apply_logit_bias_inplace_cpu()
mod["apply_penalty_inplace"] = _get_apply_penalty_inplace_cpu()
mod["apply_bitmask_inplace"] = _get_apply_bitmask_inplace_cpu()
else:
mod["apply_logit_bias_inplace"] = _get_apply_logit_bias_inplace(self.target)
mod["apply_penalty_inplace"] = _get_apply_penalty_inplace(self.target)
mod["apply_bitmask_inplace"] = _get_apply_bitmask_inplace(self.target)
return mod
def _get_apply_logit_bias_inplace_cpu():
@T.prim_func(s_tir=True)
def _apply_logit_bias_inplace(
var_logits: T.handle,
var_pos2seq_id: T.handle,
var_token_ids: T.handle,
var_logit_bias: T.handle,
) -> None:
"""Function that applies logit bias in place."""
T.func_attr(
{
"global_symbol": "apply_logit_bias_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_token = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
# seq_ids
pos2seq_id = T.match_buffer(var_pos2seq_id, (num_token,), "int32")
token_ids = T.match_buffer(var_token_ids, (num_token,), "int32")
logit_bias = T.match_buffer(var_logit_bias, (num_token,), "float32")
for i in range(num_token):
logits[pos2seq_id[i], token_ids[i]] += logit_bias[i]
return _apply_logit_bias_inplace
def _get_apply_logit_bias_inplace(target: tvm.target.Target):
tx = 1024 # default
max_num_threads_per_block = get_max_num_threads_per_block(target)
tx = min(tx, max_num_threads_per_block)
check_thread_limits(target, bdx=tx, bdy=1, bdz=1, gdz=1)
@T.prim_func(s_tir=True)
def _apply_logit_bias_inplace(
var_logits: T.handle,
var_pos2seq_id: T.handle,
var_token_ids: T.handle,
var_logit_bias: T.handle,
) -> None:
"""Function that applies logit bias in place."""
T.func_attr(
{
"global_symbol": "apply_logit_bias_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_token = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
# seq_ids
pos2seq_id = T.match_buffer(var_pos2seq_id, (num_token,), "int32")
token_ids = T.match_buffer(var_token_ids, (num_token,), "int32")
logit_bias = T.match_buffer(var_logit_bias, (num_token,), "float32")
for p0 in T.thread_binding(0, (num_token + tx - 1) // tx, "blockIdx.x"):
for p1 in T.thread_binding(0, tx, "threadIdx.x"):
with T.sblock("block"):
vp = T.axis.spatial(num_token, p0 * tx + p1)
T.where(p0 * tx + p1 < num_token)
logits[pos2seq_id[vp], token_ids[vp]] += logit_bias[vp]
return _apply_logit_bias_inplace
def _get_apply_penalty_inplace_cpu():
@T.prim_func(s_tir=True)
def _apply_penalty_inplace(
var_logits: T.handle,
var_seq_ids: T.handle,
var_pos2seq_id: T.handle,
var_token_ids: T.handle,
var_token_cnt: T.handle,
var_penalties: T.handle,
) -> None:
"""Function that applies penalties in place."""
T.func_attr(
{
"global_symbol": "apply_penalty_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_token = T.int32()
num_seq = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
seq_ids = T.match_buffer(var_seq_ids, (num_seq,), "int32")
pos2seq_id = T.match_buffer(var_pos2seq_id, (num_token,), "int32")
token_ids = T.match_buffer(var_token_ids, (num_token,), "int32")
token_cnt = T.match_buffer(var_token_cnt, (num_token,), "int32")
penalties = T.match_buffer(var_penalties, (num_seq, 3), "float32")
for token in T.serial(num_token):
with T.sblock("block"):
vp = T.axis.spatial(num_token, token)
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] -= (
penalties[pos2seq_id[vp], 0] + token_cnt[vp] * penalties[pos2seq_id[vp], 1]
)
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] = T.if_then_else(
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] < T.float32(0),
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] * penalties[pos2seq_id[vp], 2],
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] / penalties[pos2seq_id[vp], 2],
)
return _apply_penalty_inplace
def _get_apply_penalty_inplace(target: tvm.target.Target):
tx = 1024 # default
max_num_threads_per_block = get_max_num_threads_per_block(target)
tx = min(tx, max_num_threads_per_block)
check_thread_limits(target, bdx=tx, bdy=1, bdz=1, gdz=1)
@T.prim_func(s_tir=True)
def _apply_penalty_inplace(
var_logits: T.handle,
var_seq_ids: T.handle,
var_pos2seq_id: T.handle,
var_token_ids: T.handle,
var_token_cnt: T.handle,
var_penalties: T.handle,
) -> None:
"""Function that applies penalties in place."""
T.func_attr(
{
"global_symbol": "apply_penalty_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_token = T.int32()
num_seq = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
seq_ids = T.match_buffer(var_seq_ids, (num_seq,), "int32")
pos2seq_id = T.match_buffer(var_pos2seq_id, (num_token,), "int32")
token_ids = T.match_buffer(var_token_ids, (num_token,), "int32")
token_cnt = T.match_buffer(var_token_cnt, (num_token,), "int32")
penalties = T.match_buffer(var_penalties, (num_seq, 3), "float32")
for p0 in T.thread_binding(0, (num_token + tx - 1) // tx, "blockIdx.x"):
for p1 in T.thread_binding(0, tx, "threadIdx.x"):
with T.sblock("block"):
vp = T.axis.spatial(num_token, p0 * tx + p1)
T.where(p0 * tx + p1 < num_token)
# Penalties: (presence_penalty, frequency_penalty, repetition_penalty)
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] -= (
penalties[pos2seq_id[vp], 0] + token_cnt[vp] * penalties[pos2seq_id[vp], 1]
)
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] = T.if_then_else(
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]] < T.float32(0),
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]]
* penalties[pos2seq_id[vp], 2],
logits[seq_ids[pos2seq_id[vp]], token_ids[vp]]
/ penalties[pos2seq_id[vp], 2],
)
return _apply_penalty_inplace
def _get_apply_bitmask_inplace_cpu():
@T.prim_func(s_tir=True)
def _apply_bitmask_inplace(
var_logits: T.handle,
var_seq_ids: T.handle,
var_bitmask: T.handle,
) -> None:
"""Function that applies vocabulary masking in place."""
T.func_attr(
{
"global_symbol": "apply_bitmask_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_seq = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
seq_ids = T.match_buffer(var_seq_ids, (num_seq,), "int32")
bitmask = T.match_buffer(var_bitmask, (batch_size, (vocab_size + 31) // 32), "int32")
for token in T.serial(num_seq * vocab_size):
with T.sblock("block"):
vs = T.axis.spatial(num_seq, (token) // vocab_size)
vv = T.axis.spatial(vocab_size, (token) % vocab_size)
logits[seq_ids[vs], vv] = T.if_then_else(
(bitmask[seq_ids[vs], vv // 32] >> (vv % 32)) & 1 == 1,
logits[seq_ids[vs], vv],
T.min_value("float32"),
)
return _apply_bitmask_inplace
def _get_apply_bitmask_inplace(target: tvm.target.Target):
tx = 1024 # default
max_num_threads_per_block = get_max_num_threads_per_block(target)
tx = min(tx, max_num_threads_per_block)
check_thread_limits(target, bdx=tx, bdy=1, bdz=1, gdz=1)
@T.prim_func(s_tir=True)
def _apply_bitmask_inplace(
var_logits: T.handle,
var_seq_ids: T.handle,
var_bitmask: T.handle,
) -> None:
"""Function that applies vocabulary masking in place."""
T.func_attr(
{
"global_symbol": "apply_bitmask_inplace",
"tirx.noalias": True,
"tirx.is_scheduled": True,
}
)
batch_size = T.int32()
vocab_size = T.int32()
num_seq = T.int32()
logits = T.match_buffer(var_logits, (batch_size, vocab_size), "float32")
seq_ids = T.match_buffer(var_seq_ids, (num_seq,), "int32")
bitmask = T.match_buffer(var_bitmask, (batch_size, (vocab_size + 31) // 32), "int32")
for fused_s_v_0 in T.thread_binding(0, (num_seq * vocab_size + tx - 1) // tx, "blockIdx.x"):
for fused_s_v_1 in T.thread_binding(0, tx, "threadIdx.x"):
with T.sblock("block"):
vs = T.axis.spatial(num_seq, (fused_s_v_0 * tx + fused_s_v_1) // vocab_size)
vv = T.axis.spatial(vocab_size, (fused_s_v_0 * tx + fused_s_v_1) % vocab_size)
T.where(fused_s_v_0 * tx + fused_s_v_1 < num_seq * vocab_size)
logits[seq_ids[vs], vv] = T.if_then_else(
(bitmask[seq_ids[vs], vv // 32] >> (vv % 32)) & 1 == 1,
logits[seq_ids[vs], vv],
T.min_value("float32"),
)
return _apply_bitmask_inplace