Files
unslothai--unsloth/unsloth/kernels/utils.py
T
wehub-resource-sync e93507a09c
Lockfile supply-chain audit / lockfile supply-chain audit (push) Has been cancelled
Windows Studio GGUF CI / GPU prebuilt resolves without Visual Studio (push) Has been cancelled
Windows Studio GGUF CI / setup.ps1 unit tests (VS 2026 / CMake guard) (push) Has been cancelled
Windows Studio GGUF CI / real-VS detection (VS 2022) (push) Has been cancelled
Windows Studio GGUF CI / real-VS detection (VS 2026) (push) Has been cancelled
Windows Studio GGUF CI / VC++ runtime detect + install round-trip (windows-2025-vs2026) (push) Has been cancelled
Windows Studio GGUF CI / VC++ runtime detect + install round-trip (windows-latest) (push) Has been cancelled
Windows Studio Update CI / Studio Updating Tests (push) Has been cancelled
Wheel CI / Wheel build + content sanity + import smoke (push) Has been cancelled
Lint CI / Source lint (Python + shell + YAML + JSON + safety nets) (push) Has been cancelled
MLX CI on Mac M1 / dispatch (push) Has been cancelled
Security audit / advisory audit (pip + npm + cargo) (push) Has been cancelled
Security audit / pip scan-packages :: extras (push) Has been cancelled
Security audit / pip scan-packages :: studio (push) Has been cancelled
Security audit / pip scan-packages :: hf-stack (push) Has been cancelled
Security audit / npm scan-packages (Studio frontend tarballs) (push) Has been cancelled
Security audit / workflow-trigger lint (pull_request_target / cache-poisoning) (push) Has been cancelled
Security audit / pytest tests/security (push) Has been cancelled
Security audit / npm provenance + new install-script diff (push) Has been cancelled
Studio API CI / Studio API & Auth Tests (push) Has been cancelled
Backend CI / (Python 3.10) (push) Has been cancelled
Backend CI / (Python 3.11) (push) Has been cancelled
Backend CI / (Python 3.12) (push) Has been cancelled
Backend CI / (Python 3.13) (push) Has been cancelled
Backend CI / Repo tests (CPU) (push) Has been cancelled
Frontend CI / Frontend build + bundle sanity (push) Has been cancelled
Studio GGUF CI / OpenAI, Anthropic API tests (push) Has been cancelled
Studio GGUF CI / Tool calling Tests (push) Has been cancelled
Studio GGUF CI / JSON, images (push) Has been cancelled
Mac Studio GGUF CI / OpenAI, Anthropic API tests (push) Has been cancelled
Mac Studio GGUF CI / Tool calling Tests (push) Has been cancelled
Mac Studio GGUF CI / JSON, images (push) Has been cancelled
Mac Studio Install Matrix CI / Install + load (macos-14) (push) Has been cancelled
Mac Studio Install Matrix CI / Install + load (macos-15) (push) Has been cancelled
Mac Studio Install Matrix CI / Install + load (macos-26) (push) Has been cancelled
Mac Studio Install Matrix CI / Install + load (macos-15-intel) (push) Has been cancelled
Mac Studio API CI / Studio API & Auth Tests (push) Has been cancelled
Mac Studio Install Matrix CI / Install + load (macos-26-intel) (push) Has been cancelled
Mac Studio UI CI / Chat UI Tests (push) Has been cancelled
Studio Tauri CI / Tauri Linux debug build (no codesign) (push) Has been cancelled
Mac Studio Update CI / Studio Updating Tests (push) Has been cancelled
Studio UI CI / Chat UI Tests (push) Has been cancelled
Windows Studio API CI / Studio API & Auth Tests (push) Has been cancelled
Windows Studio UI CI / Chat UI Tests (push) Has been cancelled
Studio Update CI / Studio Updating Tests (push) Has been cancelled
Core / Core (HF=default + TRL=default) (push) Has been cancelled
Core / Core (HF=4.57.6 + TRL<1) (push) Has been cancelled
Core / Core (HF=latest + TRL=latest) (push) Has been cancelled
Core / llama.cpp build + smoke (push) Has been cancelled
Windows Studio GGUF CI / OpenAI, Anthropic API tests (push) Has been cancelled
Windows Studio GGUF CI / Tool calling Tests (push) Has been cancelled
Windows Studio GGUF CI / JSON, images (push) Has been cancelled
Windows Studio GGUF CI / Studio install + inference without Visual Studio (push) Has been cancelled
Studio export capability / capability (macos-latest) (push) Has been cancelled
Studio export capability / capability (ubuntu-latest) (push) Has been cancelled
Studio export capability / capability (windows-latest) (push) Has been cancelled
Cross-platform parity / parity (macos-latest) (push) Has been cancelled
Cross-platform parity / parity (windows-latest) (push) Has been cancelled
Scorecard supply-chain security / Scorecard analysis (push) Has been cancelled
Studio load-orchestrator CI / test (push) Has been cancelled
chore: import upstream snapshot with attribution
2026-07-13 12:59:56 +08:00

1130 lines
35 KiB
Python

# Copyright 2023-present Daniel Han-Chen & the Unsloth team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import importlib
import triton
import ctypes
MAX_FUSED_SIZE: int = 65536
next_power_of_2 = triton.next_power_of_2
import functools
from typing import Optional
from ..device_type import (
is_hip,
get_device_type,
DEVICE_TYPE,
DEVICE_TYPE_TORCH,
DEVICE_COUNT,
ALLOW_PREQUANTIZED_MODELS,
)
from .fp8 import weight_dequant, fp8_linear
import functools
# torch.cuda.amp.custom_fwd is deprecated >= 2.4
import torch
torch_Tensor = torch.Tensor
from unsloth_zoo.utils import Version
if DEVICE_TYPE == "xpu" and Version(torch.__version__) < Version("2.6.0"):
raise RuntimeError("Intel xpu currently supports unsloth with torch.version >= 2.6.0")
if Version(torch.__version__) < Version("2.4.0"):
torch_amp_custom_fwd = torch.cuda.amp.custom_fwd
torch_amp_custom_bwd = torch.cuda.amp.custom_bwd
else:
torch_amp_custom_fwd = torch.amp.custom_fwd(device_type = "cuda")
torch_amp_custom_bwd = torch.amp.custom_bwd(device_type = "cuda")
if DEVICE_TYPE == "xpu":
torch_amp_custom_fwd = torch.amp.custom_fwd(device_type = "xpu")
torch_amp_custom_bwd = torch.amp.custom_bwd(device_type = "xpu")
# tl.math.tanh now is libdevice.tanh
import triton
import triton.language as tl
if Version(triton.__version__) >= Version("3.0.0"):
if DEVICE_TYPE == "xpu":
triton_tanh = tl.extra.intel.libdevice.tanh
else:
from triton.language.extra import libdevice
triton_tanh = libdevice.tanh
triton_cast = tl.cast
else:
triton_tanh = tl.math.tanh
# No casting in old Triton versions
@triton.jit
def triton_cast(x, dtype):
return x.to(dtype)
@functools.lru_cache(1)
def is_cdna():
return is_hip() and triton.runtime.driver.active.get_current_target().arch in (
"gfx940",
"gfx941",
"gfx942",
"gfx950", # CDNA4 (MI350/MI355X)
)
@functools.lru_cache(1)
def is_rdna():
"""Detect ROCm-supported RDNA consumer/workstation GPUs (RDNA2, RDNA3, RDNA3.5, RDNA4)."""
return is_hip() and triton.runtime.driver.active.get_current_target().arch in (
# RDNA2 (Navi 21-24)
"gfx1030",
"gfx1031",
"gfx1032",
"gfx1033",
"gfx1034",
"gfx1035",
"gfx1036",
# RDNA3 (Navi 31-33)
"gfx1100",
"gfx1101",
"gfx1102",
"gfx1103",
# RDNA3.5 (Strix Point / Strix Halo)
"gfx1150",
"gfx1151",
"gfx1152",
# RDNA4 (Navi 48-44)
"gfx1200",
"gfx1201",
)
def calculate_settings(
n: int,
) -> (
int,
int,
):
BLOCK_SIZE: int = next_power_of_2(n)
if BLOCK_SIZE > MAX_FUSED_SIZE:
raise RuntimeError(
f"Cannot launch Triton kernel since n = {n} exceeds "
f"the maximum CUDA blocksize = {MAX_FUSED_SIZE}."
)
num_warps: int = 4
if BLOCK_SIZE >= 32768:
num_warps = 32
elif BLOCK_SIZE >= 8192:
num_warps = 16
elif BLOCK_SIZE >= 2048:
num_warps = 8
return BLOCK_SIZE, num_warps
HAS_CUDA_STREAM = False
import bitsandbytes as bnb
# https://github.com/bitsandbytes-foundation/bitsandbytes/pull/1330/files
HAS_CUDA_STREAM = Version(bnb.__version__) > Version("0.43.3")
get_ptr = bnb.functional.get_ptr
if DEVICE_TYPE == "xpu":
HAS_XPU_STREAM = True
if DEVICE_COUNT > 1:
if DEVICE_TYPE in ("cuda", "hip"):
torch_gpu_device = torch.cuda.device
elif DEVICE_TYPE == "xpu":
torch_gpu_device = torch.xpu.device
else:
from contextlib import nullcontext
def torch_gpu_device(device):
return nullcontext()
# INTEL GPU Specific Logic
if DEVICE_TYPE == "xpu":
_gpu_getCurrentRawStream = torch._C._xpu_getCurrentRawStream
elif DEVICE_TYPE == "mlx":
def _gpu_getCurrentRawStream(_index = 0):
return 0
# NVIDIA GPU Default Logic
elif hasattr(torch._C, "_cuda_getCurrentRawStream"):
_gpu_getCurrentRawStream = torch._C._cuda_getCurrentRawStream
else:
# CPU-only torch wheel (no compiled CUDA backend). _get_tensor_stream
# is only invoked during real GPU work, so a no-op binding is safe.
def _gpu_getCurrentRawStream(_index = 0):
return 0
c_void_p = ctypes.c_void_p
def _get_tensor_stream(tensor: torch_Tensor) -> c_void_p:
return c_void_p(_gpu_getCurrentRawStream(tensor.device.index))
# Get array of CUDA streams and other buffers
global CUDA_STREAMS
global XPU_STREAMS
global WEIGHT_BUFFERS
global ABSMAX_BUFFERS
# DEVICE_COUNT == 0 = no visible accelerator (e.g. CPU-only CI runner).
# The consumer functions below only index these arrays during real GPU
# work, so empty containers are safe -- they just need to be defined so
# the module imports cleanly.
if DEVICE_TYPE == "xpu":
if DEVICE_COUNT > 0:
_XPU_STREAMS = {
(index := torch.xpu.device(i).idx): ctypes.c_void_p(
torch._C._xpu_getCurrentRawStream(index)
)
for i in range(DEVICE_COUNT)
}
XPU_STREAMS = [None] * (max(_XPU_STREAMS.keys()) + 1)
WEIGHT_BUFFERS = [None] * (max(_XPU_STREAMS.keys()) + 1)
ABSMAX_BUFFERS = [None] * (max(_XPU_STREAMS.keys()) + 1)
for k, v in _XPU_STREAMS.items():
XPU_STREAMS[k] = v
XPU_STREAMS = tuple(XPU_STREAMS)
del _XPU_STREAMS
else:
XPU_STREAMS = ()
WEIGHT_BUFFERS = []
ABSMAX_BUFFERS = []
elif DEVICE_TYPE == "mlx":
CUDA_STREAMS = ()
XPU_STREAMS = ()
WEIGHT_BUFFERS = []
ABSMAX_BUFFERS = []
else:
# NVIDIA GPU Default Logic
if DEVICE_COUNT > 0:
_CUDA_STREAMS = {
(index := torch.cuda.device(i).idx): ctypes.c_void_p(
torch._C._cuda_getCurrentRawStream(index)
)
for i in range(DEVICE_COUNT)
}
CUDA_STREAMS = [None] * (max(_CUDA_STREAMS.keys()) + 1)
WEIGHT_BUFFERS = [None] * (max(_CUDA_STREAMS.keys()) + 1)
ABSMAX_BUFFERS = [None] * (max(_CUDA_STREAMS.keys()) + 1)
for k, v in _CUDA_STREAMS.items():
CUDA_STREAMS[k] = v
CUDA_STREAMS = tuple(CUDA_STREAMS)
del _CUDA_STREAMS
else:
CUDA_STREAMS = ()
WEIGHT_BUFFERS = []
ABSMAX_BUFFERS = []
# Bitsandbytes operations
ctypes_c_int = ctypes.c_int
ctypes_c_int32 = ctypes.c_int32
cdequantize_blockwise_fp32 = bnb.functional.lib.cdequantize_blockwise_fp32
cdequantize_blockwise_fp16_nf4 = bnb.functional.lib.cdequantize_blockwise_fp16_nf4
cdequantize_blockwise_bf16_nf4 = bnb.functional.lib.cdequantize_blockwise_bf16_nf4
if DEVICE_TYPE == "xpu":
# https://github.com/bitsandbytes-foundation/bitsandbytes/blob/c3b8de268fdb55a88f92feada23fc811a1e6877a/bitsandbytes/backends/xpu/ops.py#L115
# for xpu, inference gemv using above link
cgemm_4bit_inference_naive_fp16 = bnb.functional.lib.cgemv_4bit_inference_fp16
cgemm_4bit_inference_naive_bf16 = bnb.functional.lib.cgemv_4bit_inference_bf16
else:
cgemm_4bit_inference_naive_fp16 = bnb.functional.lib.cgemm_4bit_inference_naive_fp16
cgemm_4bit_inference_naive_bf16 = bnb.functional.lib.cgemm_4bit_inference_naive_bf16
torch_device_stream = (
torch.xpu.current_stream if DEVICE_TYPE == "xpu" else torch.cuda.current_stream
)
torch_mm = torch.mm
torch_mv = torch.mv
torch_matmul = torch.matmul
torch_addmm = torch.addmm
torch_empty = torch.empty
torch_float32 = torch.float32
torch_float16 = torch.float16
torch_bfloat16 = torch.bfloat16
# Check whether torchao can be imported to get Float8Tensor
if importlib.util.find_spec("torchao") is not None:
try:
from torchao.quantization import Float8Tensor
except:
import torchao
if Version(torchao.__version__) >= Version("0.15.0"):
print(
f"Unsloth: `from torchao.quantization import Float8Tensor` failed on version={torchao.__version__}"
)
Float8Tensor = type(None)
else:
Float8Tensor = type(None)
def QUANT_STATE(W):
return getattr(W, "quant_state", None)
# fp8 weight dtypes. A `weight_scale` / `weight_scale_inv` should only be treated as a
# quant state when the weight itself is still fp8. compressed-tensors layers expose an
# already-dequantized bf16 weight at forward time while keeping a `weight_scale` around;
# reading that as a quant state routes a bf16 weight into the bitsandbytes fast_gemv /
# fast_dequantize path, which then reads a missing `absmax` and crashes.
_FP8_WEIGHT_DTYPES = tuple(
dtype
for dtype in (
getattr(torch, "float8_e4m3fn", None),
getattr(torch, "float8_e5m2", None),
)
if dtype is not None
)
def get_lora_parameters(proj):
"""Return (weight, weight quant_state, lora A, lora B, lora scale).
With QAT enabled, also fake-quantizes the base layer and lora weights.
"""
# For DPO or disabled adapters
base_layer = getattr(
proj, "base_layer", proj
) # (proj.base_layer if hasattr(proj, "base_layer") else proj)
W = base_layer.weight
# Optionally apply fake quantization to base layer weights for QAT
if hasattr(base_layer, "weight_fake_quantizer"):
weight_fake_quantizer = getattr(base_layer, "weight_fake_quantizer", None)
if weight_fake_quantizer is not None:
W = weight_fake_quantizer(W)
# Get quant state for 4bit or FP8. Only fall back to a weight_scale(_inv) when the
# weight is still fp8; a bf16 weight (e.g. a decompressed compressed-tensors layer)
# must not carry a scale as its quant state or fast_gemv will crash on it.
W_quant = getattr(W, "quant_state", None)
if W_quant is None and W.dtype in _FP8_WEIGHT_DTYPES:
W_quant = getattr(base_layer, "weight_scale_inv", None)
if W_quant is None:
W_quant = getattr(base_layer, "weight_scale", None)
if getattr(base_layer, "quant_method", None) == "fp8":
# we need to somehow store and pass this information :)
W.block_size = getattr(base_layer, "block_size", [128, 128])
W_quant.block_size = W.block_size
# if not hasattr(proj, "disable_adapters") or proj.disable_adapters or proj.merged:
if getattr(proj, "disable_adapters", True) or proj.merged:
return W, W_quant, None, None, None
adapter = getattr(proj, "active_adapters", None)
if adapter is None:
adapter = getattr(proj, "active_adapter", ("default"))
adapter = adapter[0]
# Optionally apply fake quantization to lora weights for QAT
lora_A_linear = proj.lora_A[adapter]
lora_B_linear = proj.lora_B[adapter]
A = lora_A_linear.weight
B = lora_B_linear.weight
if hasattr(lora_A_linear, "weight_fake_quantizer"):
lora_A_fake_quantizer = getattr(lora_A_linear, "weight_fake_quantizer", None)
if lora_A_fake_quantizer is not None:
A = lora_A_fake_quantizer(A)
if hasattr(lora_B_linear, "weight_fake_quantizer"):
lora_B_fake_quantizer = getattr(lora_B_linear, "weight_fake_quantizer", None)
if lora_B_fake_quantizer is not None:
B = lora_B_fake_quantizer(B)
return (
W,
W_quant,
A,
B,
proj.scaling[adapter],
)
def get_lora_parameters_bias(proj):
# For DPO or disabled adapters
base_layer = getattr(
proj, "base_layer", proj
) # (proj.base_layer if hasattr(proj, "base_layer") else proj)
W = base_layer.weight
# Get quant state for 4bit or FP8. Only fall back to a weight_scale(_inv) when the
# weight is still fp8; a bf16 weight (e.g. a decompressed compressed-tensors layer)
# must not carry a scale as its quant state or fast_gemv will crash on it.
W_quant = getattr(W, "quant_state", None)
if W_quant is None and W.dtype in _FP8_WEIGHT_DTYPES:
W_quant = getattr(base_layer, "weight_scale_inv", None)
if W_quant is None:
W_quant = getattr(base_layer, "weight_scale", None)
# if not hasattr(proj, "disable_adapters") or proj.disable_adapters or proj.merged:
if getattr(proj, "disable_adapters", True) or proj.merged:
return W, W_quant, None, None, None, base_layer.bias
if getattr(base_layer, "quant_method", None) == "fp8":
# we need to somehow store and pass this information :)
W.block_size = getattr(base_layer, "block_size", [128, 128])
W_quant.block_size = W.block_size
adapter = getattr(proj, "active_adapters", None)
if adapter is None:
adapter = getattr(proj, "active_adapter", ("default"))
adapter = adapter[0]
return (
W,
W_quant,
proj.lora_A[adapter].weight,
proj.lora_B[adapter].weight,
proj.scaling[adapter],
base_layer.bias,
)
def _maybe_fake_quantize_activations(X: torch.Tensor, proj: torch.nn.Module) -> torch.Tensor:
"""Fake-quantize input activations if QAT is enabled, else return as-is.
Weights are fake-quantized separately in `get_lora_parameters`.
"""
base_layer = getattr(proj, "base_layer", proj)
activation_fake_quantizer = getattr(base_layer, "activation_fake_quantizer", None)
if activation_fake_quantizer is not None:
X = activation_fake_quantizer(X)
return X
# INTEL GPU Specific Logic
if DEVICE_TYPE == "xpu" and HAS_XPU_STREAM:
@torch.inference_mode
def fast_dequantize(
W,
quant_state = None,
out = None,
use_global_buffer = False,
):
# TODO: After adding XPU BNB support, check this function
if isinstance(W, Float8Tensor):
return W.dequantize()
if quant_state is None:
return W
if W.dtype == torch.float8_e4m3fn:
return weight_dequant(W, quant_state)
if type(quant_state) is not list:
# New quant_state as a class
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
# Old quant_state as a list of lists
absmax, shape, dtype, blocksize, compressed_stats, _, _ = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
global XPU_STREAMS
device = W.device
device_index = device.index
XPU_STREAM = XPU_STREAMS[device_index]
n_elements_absmax = absmax.numel()
# Create weight matrix
if use_global_buffer:
# Use same buffers for faster inference
size = shape[0] * shape[1]
global WEIGHT_BUFFERS
global ABSMAX_BUFFERS
WEIGHT_BUFFER = WEIGHT_BUFFERS[device_index]
ABSMAX_BUFFER = ABSMAX_BUFFERS[device_index]
if WEIGHT_BUFFER is None or WEIGHT_BUFFER.dtype != dtype:
WEIGHT_BUFFERS[device_index] = WEIGHT_BUFFER = torch_empty(
size, dtype = dtype, device = device, requires_grad = False
)
ABSMAX_BUFFERS[device_index] = ABSMAX_BUFFER = torch_empty(
n_elements_absmax,
dtype = torch.float32,
device = device,
requires_grad = False,
)
if size > WEIGHT_BUFFER.numel():
WEIGHT_BUFFER.resize_(size)
if n_elements_absmax > ABSMAX_BUFFER.numel():
ABSMAX_BUFFER.resize_(n_elements_absmax)
out = WEIGHT_BUFFER[:size].view(shape)
out_absmax = ABSMAX_BUFFER[:n_elements_absmax]
else:
if out is None:
out = torch_empty(shape, dtype = dtype, device = device, requires_grad = False)
else:
assert out.shape == shape
assert out.dtype == dtype
out_absmax = torch_empty(
n_elements_absmax,
dtype = torch_float32,
device = device,
requires_grad = False,
)
# NF4 dequantization of statistics
ptr_out_absmax = get_ptr(out_absmax)
with torch_gpu_device(device):
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
ptr_out_absmax,
ctypes_c_int(blocksize2),
ctypes_c_int(n_elements_absmax),
XPU_STREAM,
)
out_absmax += offset
# Dequantize W
fx = (
cdequantize_blockwise_fp16_nf4
if dtype == torch_float16
else cdequantize_blockwise_bf16_nf4
)
fx(
get_ptr(None),
get_ptr(W),
ptr_out_absmax,
get_ptr(out),
ctypes_c_int(blocksize),
ctypes_c_int(out.numel()),
XPU_STREAM,
)
# Careful returning transposed data
is_transposed = True if W.shape[0] == 1 else False
return out.t() if is_transposed else out
# NVIDIA GPU Default Logic
elif DEVICE_TYPE in ("cuda", "hip") and HAS_CUDA_STREAM:
@torch.inference_mode
def fast_dequantize(
W,
quant_state = None,
out = None,
use_global_buffer = False,
):
if isinstance(W, Float8Tensor):
return W.dequantize()
if quant_state is None:
return W
if W.dtype == torch.float8_e4m3fn:
return weight_dequant(W, quant_state)
if type(quant_state) is not list:
# New quant_state as a class
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
# Old quant_state as a list of lists
absmax, shape, dtype, blocksize, compressed_stats, _, _ = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
pass
global CUDA_STREAMS
device = W.device
device_index = device.index
CUDA_STREAM = CUDA_STREAMS[device_index]
n_elements_absmax = absmax.numel()
# Create weight matrix
if use_global_buffer:
# Use same buffers for faster inference
size = shape[0] * shape[1]
global WEIGHT_BUFFERS
global ABSMAX_BUFFERS
WEIGHT_BUFFER = WEIGHT_BUFFERS[device_index]
ABSMAX_BUFFER = ABSMAX_BUFFERS[device_index]
if WEIGHT_BUFFER is None or WEIGHT_BUFFER.dtype != dtype:
WEIGHT_BUFFERS[device_index] = WEIGHT_BUFFER = torch_empty(
size, dtype = dtype, device = device, requires_grad = False
)
ABSMAX_BUFFERS[device_index] = ABSMAX_BUFFER = torch_empty(
n_elements_absmax,
dtype = torch_float32,
device = device,
requires_grad = False,
)
if size > WEIGHT_BUFFER.numel():
WEIGHT_BUFFER.resize_(size)
if n_elements_absmax > ABSMAX_BUFFER.numel():
ABSMAX_BUFFER.resize_(n_elements_absmax)
out = WEIGHT_BUFFER[:size].view(shape)
out_absmax = ABSMAX_BUFFER[:n_elements_absmax]
else:
if out is None:
out = torch_empty(shape, dtype = dtype, device = device, requires_grad = False)
else:
assert out.shape == shape
assert out.dtype == dtype
out_absmax = torch_empty(
n_elements_absmax,
dtype = torch_float32,
device = device,
requires_grad = False,
)
pass
# NF4 dequantization of statistics
ptr_out_absmax = get_ptr(out_absmax)
with torch_gpu_device(device):
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
ptr_out_absmax,
ctypes_c_int(blocksize2),
ctypes_c_int(n_elements_absmax),
CUDA_STREAM,
)
out_absmax += offset
# Dequantize W
fx = (
cdequantize_blockwise_fp16_nf4
if dtype == torch_float16
else cdequantize_blockwise_bf16_nf4
)
fx(
get_ptr(None),
get_ptr(W),
ptr_out_absmax,
get_ptr(out),
ctypes_c_int(blocksize),
ctypes_c_int(out.numel()),
CUDA_STREAM,
)
pass
# Careful returning transposed data
is_transposed = True if W.shape[0] == 1 else False
return out.t() if is_transposed else out
pass
else:
@torch.inference_mode
def fast_dequantize(
W,
quant_state = None,
out = None,
use_global_buffer = False,
):
if isinstance(W, Float8Tensor):
return W.dequantize()
if quant_state is None:
return W
if W.dtype == torch.float8_e4m3fn:
return weight_dequant(W, quant_state)
if type(quant_state) is not list:
# New quant_state as a class
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
# Old quant_state as a list of lists
absmax, shape, dtype, blocksize, compressed_stats, _, _ = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
pass
n_elements_absmax = absmax.numel()
device = W.device
# Create weight matrix
if out is None:
out = torch_empty(shape, dtype = dtype, device = device, requires_grad = False)
else:
assert out.shape == shape
assert out.dtype == dtype
out_absmax = torch_empty(
n_elements_absmax, dtype = torch_float32, device = device, requires_grad = False
)
# Do dequantization
ptr_out_absmax = get_ptr(out_absmax)
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
ptr_out_absmax,
ctypes_c_int(blocksize2),
ctypes_c_int(n_elements_absmax),
)
out_absmax += offset
fx = (
cdequantize_blockwise_fp16_nf4
if dtype == torch_float16
else cdequantize_blockwise_bf16_nf4
)
fx(
get_ptr(None),
get_ptr(W),
ptr_out_absmax,
get_ptr(out),
ctypes_c_int(blocksize),
ctypes_c_int(out.numel()),
)
# Careful returning transposed data
is_transposed = True if W.shape[0] == 1 else False
return out.t() if is_transposed else out
pass
# INTEL GPU Specific Logic
if DEVICE_TYPE == "xpu" and HAS_XPU_STREAM:
def fast_gemv(
X,
W,
quant_state,
out = None,
):
if quant_state is None:
return torch_matmul(X, W, out = out)
# For fast X @ W where seq_len == 1
# From https://github.com/TimDettmers/bitsandbytes/blob/main/bitsandbytes/functional.py#L1469
_, q_len, hd = X.shape
# assert(q_len == 1)
if type(quant_state) is not list:
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
stats = quant_state.code
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
absmax, shape, dtype, blocksize, compressed_stats, quant_type, stats = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
global XPU_STREAMS
device = W.device
device_index = device.index
XPU_STREAM = XPU_STREAMS[device_index]
# assert(dtype == X.dtype)
bout = shape[0]
if out is None:
out = torch_empty(
(
1,
1,
bout,
),
dtype = dtype,
device = device,
)
# else:
# assert(out.shape == (1, 1, bout,))
# pass
if DEVICE_TYPE == "xpu":
m = 1
n = shape[0]
else:
n = 1
m = shape[0]
k = shape[1]
lda = shape[0]
ldc = shape[0]
ldb = (hd + 1) // 2
m = ctypes_c_int32(m)
n = ctypes_c_int32(n)
k = ctypes_c_int32(k)
lda = ctypes_c_int32(lda)
ldb = ctypes_c_int32(ldb)
ldc = ctypes_c_int32(ldc)
df = torch_empty(absmax.shape, dtype = torch_float32, device = device)
with torch_gpu_device(device):
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
get_ptr(df),
ctypes_c_int(blocksize2),
ctypes_c_int(df.numel()),
XPU_STREAM,
)
df += offset
absmax = df
fx = (
cgemm_4bit_inference_naive_fp16
if dtype == torch_float16
else cgemm_4bit_inference_naive_bf16
)
blocksize = ctypes_c_int32(blocksize)
fx(
m,
n,
k,
get_ptr(X),
get_ptr(W),
get_ptr(absmax),
get_ptr(stats),
get_ptr(out),
lda,
ldb,
ldc,
blocksize,
XPU_STREAM,
)
return out
elif DEVICE_TYPE in ("cuda", "hip") and HAS_CUDA_STREAM:
def fast_gemv(
X,
W,
quant_state,
out = None,
):
if quant_state is None:
return torch_matmul(X, W, out = out)
# For fast X @ W where seq_len == 1
# From https://github.com/TimDettmers/bitsandbytes/blob/main/bitsandbytes/functional.py#L1469
_, q_len, hd = X.shape
# assert(q_len == 1)
if type(quant_state) is not list:
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
stats = quant_state.code
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
absmax, shape, dtype, blocksize, compressed_stats, quant_type, stats = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
pass
global CUDA_STREAMS
device = W.device
device_index = device.index
CUDA_STREAM = CUDA_STREAMS[device_index]
# assert(dtype == X.dtype)
bout = shape[0]
if out is None:
out = torch_empty(
(
1,
1,
bout,
),
dtype = dtype,
device = device,
)
# else:
# assert(out.shape == (1, 1, bout,))
# pass
n = 1
m = shape[0]
k = shape[1]
lda = shape[0]
ldc = shape[0]
ldb = (hd + 1) // 2
m = ctypes_c_int32(m)
n = ctypes_c_int32(n)
k = ctypes_c_int32(k)
lda = ctypes_c_int32(lda)
ldb = ctypes_c_int32(ldb)
ldc = ctypes_c_int32(ldc)
df = torch_empty(absmax.shape, dtype = torch_float32, device = device)
with torch_gpu_device(device):
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
get_ptr(df),
ctypes_c_int(blocksize2),
ctypes_c_int(df.numel()),
CUDA_STREAM,
)
df += offset
absmax = df
fx = (
cgemm_4bit_inference_naive_fp16
if dtype == torch_float16
else cgemm_4bit_inference_naive_bf16
)
blocksize = ctypes_c_int32(blocksize)
fx(
m,
n,
k,
get_ptr(X),
get_ptr(W),
get_ptr(absmax),
get_ptr(stats),
get_ptr(out),
lda,
ldb,
ldc,
blocksize,
CUDA_STREAM,
)
pass
return out
pass
else:
def fast_gemv(
X,
W,
quant_state,
out = None,
):
if quant_state is None:
return torch_matmul(X, W, out = out)
# For fast X @ W where seq_len == 1
# From https://github.com/TimDettmers/bitsandbytes/blob/main/bitsandbytes/functional.py#L1469
_, q_len, hd = X.shape
# assert(q_len == 1)
if type(quant_state) is not list:
# https://github.com/TimDettmers/bitsandbytes/pull/763/files
absmax = quant_state.absmax
shape = quant_state.shape
dtype = quant_state.dtype
blocksize = quant_state.blocksize
stats = quant_state.code
offset = quant_state.offset
state2 = quant_state.state2
absmax2 = state2.absmax
code2 = state2.code
blocksize2 = state2.blocksize
else:
absmax, shape, dtype, blocksize, compressed_stats, quant_type, stats = quant_state
offset, state2 = compressed_stats
absmax2, code2, blocksize2, _, _, _, _ = state2
pass
# assert(dtype == X.dtype)
bout = shape[0]
device = W.device
if out is None:
out = torch_empty(
(
1,
1,
bout,
),
dtype = dtype,
device = device,
)
# else:
# assert(out.shape == (1, 1, bout,))
# pass
n = 1
m = shape[0]
k = shape[1]
lda = shape[0]
ldc = shape[0]
ldb = (hd + 1) // 2
m = ctypes_c_int32(m)
n = ctypes_c_int32(n)
k = ctypes_c_int32(k)
lda = ctypes_c_int32(lda)
ldb = ctypes_c_int32(ldb)
ldc = ctypes_c_int32(ldc)
df = torch_empty(absmax.shape, dtype = torch_float32, device = device)
cdequantize_blockwise_fp32(
get_ptr(code2),
get_ptr(absmax),
get_ptr(absmax2),
get_ptr(df),
ctypes_c_int(blocksize2),
ctypes_c_int(df.numel()),
)
df += offset
absmax = df
fx = (
cgemm_4bit_inference_naive_fp16
if dtype == torch_float16
else cgemm_4bit_inference_naive_bf16
)
blocksize = ctypes_c_int32(blocksize)
fx(
m,
n,
k,
get_ptr(X),
get_ptr(W),
get_ptr(absmax),
get_ptr(stats),
get_ptr(out),
lda,
ldb,
ldc,
blocksize,
)
return out
pass
def fast_linear_forward(
proj,
X,
temp_lora = None,
out = None,
):
W, W_quant, lora_A, lora_B, lora_S, bias = get_lora_parameters_bias(proj)
bsz, q_len, in_dim = X.shape
if q_len != 1:
return matmul_lora(X, W, W_quant, lora_A, lora_B, lora_S)
if W_quant is None:
out = torch_matmul(X, W.t(), out = out)
elif W.dtype == torch.float8_e4m3fn:
out = fp8_linear(X, W, W_quant, bias)
elif bsz == 1 and q_len == 1:
out = fast_gemv(X, W, W_quant, out = out)
else:
W = fast_dequantize(W.t(), W_quant, use_global_buffer = True)
out = torch_matmul(X, W, out = out)
# Add in LoRA weights
if lora_A is not None:
out_dim = out.shape[2]
dtype = X.dtype
if not hasattr(lora_A, "_fast_lora"):
lora_A._fast_lora = lora_A.to(dtype)
lora_B._fast_lora = lora_B.to(dtype)
if bsz == 1:
out = out.view(out_dim)
temp_lora = torch_mv(lora_A._fast_lora, X.ravel(), out = temp_lora)
out.addmv_(lora_B._fast_lora, temp_lora, alpha = lora_S)
else:
out = out.view(bsz, out_dim)
temp_lora = torch_mm(X.view(bsz, in_dim), lora_A._fast_lora.t(), out = temp_lora)
out.addmm_(temp_lora, lora_B._fast_lora.t(), alpha = lora_S)
out = out.view(bsz, 1, out_dim)
if bias is not None:
out += bias
return out
def matmul_lora(
X,
W,
W_quant,
A,
B,
s,
out = None,
):
dtype = X.dtype
if X.dim() == 3:
batch, seq_len, d = X.shape
X = X.view(-1, X.shape[-1])
reshape = True
else:
reshape = False
if isinstance(W, Float8Tensor):
assert W.ndim == 2
if W.block_size[0] == W.shape[0] and W.block_size[1] == 1:
# Rowwise scaling becomes colwise after transpose, so this detects
# the backward pass. TODO: avoid calling matmul_lora in backward.
W = W.dequantize()
else:
W = W.contiguous()
out = torch_matmul(X, W.t(), out = out)
elif W.dtype == torch.float8_e4m3fn:
out = fp8_linear(X, W, W_quant)
else:
W = fast_dequantize(W, W_quant, use_global_buffer = True)
out = torch_matmul(X, W.t(), out = out)
if W_quant is not None:
del W
if A is not None:
# LoRA is enabled
A, B = A.t(), B.t()
XA = torch_matmul(X, A.to(dtype))
out.addmm_(XA, B.to(dtype), alpha = s)
# out += (X @ A.to(dtype)) @ (s * B.to(dtype))
return out.view(batch, seq_len, -1) if reshape else out