235 lines
7.2 KiB
Python
235 lines
7.2 KiB
Python
# Adapted from turboderp exllama: https://github.com/turboderp/exllamav2
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import torch
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import torch.nn as nn
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from loguru import logger
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try:
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from exllamav2_kernels import make_q_matrix, gemm_half_q_half
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except ImportError:
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logger.error("exllamav2_kernels not installed.")
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raise
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# Dummy tensor to pass instead of g_idx since there is no way to pass "None" to a C++ extension
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none_tensor = torch.empty((1, 1), device="meta")
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def ext_gemm_half_q_half(x, q_handle, q4_width, force_cuda):
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"""Matrix multiplication, returns x @ q4"""
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output_shape = x.shape[:-1] + (q4_width,)
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x = x.view(-1, x.shape[-1])
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output = torch.empty((x.shape[0], q4_width), dtype=torch.half, device=x.device)
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gemm_half_q_half(x, q_handle, output, force_cuda)
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return output.view(output_shape)
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# Group map needed for irregular group sizes
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def make_group_map(q_groups, num_qrows):
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gr = q_groups.tolist()
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group_map = []
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num_groups = len(gr) // 2
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for i in range(num_groups):
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bits = gr[i * 2]
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if i < num_groups - 1:
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qrows = gr[i * 2 + 3] - gr[i * 2 + 1]
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else:
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qrows = num_qrows - gr[i * 2 + 1]
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rows = qrows * 32 // bits
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for j in range(rows):
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group_map += [i]
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group_map += [rows - j]
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return torch.tensor(group_map, dtype=torch.short, device=q_groups.device)
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# Create Q matrix
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def ext_make_q_matrix(w: dict, temp_dq, key: str = None):
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"""
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Create Q matrix
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"""
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# EXL2
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# won't work as the moment because the tensors are not the same.
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if "q_weight" in w:
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w["q_scale_max"] /= 256
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w["q_perm"] = w["q_perm"].short()
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w["q_invperm"] = w["q_invperm"].short()
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if "q_group_map" not in w:
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w["q_group_map"] = make_group_map(w["q_groups"], w["q_weight"].shape[0])
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return make_q_matrix(
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w["q_weight"],
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w["q_perm"],
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w["q_invperm"],
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w["q_scale"],
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w["q_scale_max"],
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w["q_groups"],
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w["q_group_map"],
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none_tensor,
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none_tensor,
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none_tensor,
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temp_dq,
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)
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# GPTQ
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elif "qweight" in w:
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if w["scales"].dtype == torch.float:
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w["scales"] = w["scales"].half()
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# GPTQ with g_idx (act_order)
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if w.get("g_idx", None) is not None and not (w["g_idx"] == 0).all().item():
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w["q_perm"] = torch.empty(
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(w["qweight"].shape[0] * 8,),
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dtype=torch.short,
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device=w["qweight"].device,
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)
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w["q_invperm"] = torch.empty_like(w["q_perm"])
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# make_q4 segfaults if g_idx is not on cpu in the act-order case. In the non act-order case, None needs to be passed for g_idx.
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return make_q_matrix(
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w["qweight"],
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w["q_perm"],
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w["q_invperm"],
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none_tensor,
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none_tensor,
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none_tensor,
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none_tensor,
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w["qzeros"],
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w["scales"],
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w["g_idx"].cpu(),
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temp_dq,
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)
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# GPTQ without g_idx
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else:
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return make_q_matrix(
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w["qweight"],
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none_tensor,
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none_tensor,
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none_tensor,
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none_tensor,
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none_tensor,
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none_tensor,
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w["qzeros"],
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w["scales"],
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none_tensor,
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temp_dq,
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)
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else:
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RuntimeError("Cannot create handle")
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DEVICE = None
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FIXED_BYTES = 0
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LAYERS = []
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def set_device(device):
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global DEVICE
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DEVICE = device
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def create_exllama_buffers(max_total_tokens: int):
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global FIXED_BYTES, LAYERS, DEVICE
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temp_dq = ExLlamaV2DeviceTensors(DEVICE, FIXED_BYTES)
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for layer in LAYERS:
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layer.post_init(temp_dq)
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class QuantLinear(nn.Module):
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QUANT_TYPE = "exllamav2"
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"""Linear layer implementation with per-group 4-bit quantization of the weights"""
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# def __init__(self, bits, group_size, infeatures, outfeatures, bias, trainable=False, **kwargs):
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def __init__(self, qweight, qzeros, scales, g_idx, bias, bits, groupsize):
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super().__init__()
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if bits != 4:
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raise ValueError(
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f"Exllamav2 kernel supports only bits=4, requested bits={bits}. Something is wrong in the model initialization."
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)
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self.q_handle = None
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self.q_tensors = None
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self.bits = bits
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self.maxq = 2**self.bits - 1
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self.infeatures = qweight.shape[0] // self.bits * 32
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self.outfeatures = qweight.shape[1]
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self.padding = -self.outfeatures % 32
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self.outfeatures = self.outfeatures + self.padding
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self.device = qweight.device
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self.qweight = qweight
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self.qzeros = qzeros
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self.scales = scales
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self.g_idx = g_idx
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self.bias = bias if bias is not None else None
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self.group_size = groupsize
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global FIXED_BYTES, LAYERS
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FIXED_BYTES = max(FIXED_BYTES, self.scratch_space_fixed())
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LAYERS.append(self)
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def post_init(self, temp_dq):
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assert self.qweight.device.type == "cuda"
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assert self.qweight.device.index is not None
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self.q_tensors = {
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"qweight": self.qweight,
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"qzeros": self.qzeros,
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"scales": self.scales,
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"g_idx": self.g_idx,
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}
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temp_dq = temp_dq.get_scratch_slice(self.temp_dq_size())
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# We NEED to keep a pointer on Python side, otherwise the garbage collector will mess with us,
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# and `Memory access fault by GPU node-2` will EAT you.
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self.temp_dq = temp_dq
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self.q_handle = ext_make_q_matrix(self.q_tensors, temp_dq)
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def forward(self, x, force_cuda=False):
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output = ext_gemm_half_q_half(x, self.q_handle, self.outfeatures, force_cuda)
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if self.bias is not None:
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output.add_(self.bias)
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return output
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def temp_dq_size(self):
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return self.infeatures * self.outfeatures * 2 + 128
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def temp_fwd_size(self, max_input_len, max_batch_size):
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return self.outfeatures * max_input_len * max_batch_size * 4 + 128
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def scratch_space_fixed(self, max_input_len=4096, max_batch_size=16):
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return self.temp_dq_size() + self.temp_fwd_size(max_input_len, max_batch_size)
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class ExLlamaV2DeviceTensors:
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device_idx: int
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scratch_bytes: int
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scratch_idx: int
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scratch: torch.tensor = None
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def __init__(self, device, scratch_bytes):
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self.device = device
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self.scratch_bytes = scratch_bytes
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def prepare(self):
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self.scratch = torch.empty(
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(self.scratch_bytes // 2,), dtype=torch.half, device=self.device
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)
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def get_scratch_slice(self, size_bytes):
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if self.scratch is None:
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self.prepare()
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size_bytes = ((size_bytes + 127) // 128) * 128
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size_half = size_bytes // 2
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scratch_slice = self.scratch.narrow(0, 0, size_half)
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return scratch_slice
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