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Add Support for 2/3/8-bit GPTQ Quantization Models (#2330)

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CHU Tianxiang 2024-02-29 13:52:23 +08:00 committed by GitHub
parent 929b4f2973
commit 01a5d18a53
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GPG Key ID: B5690EEEBB952194
8 changed files with 1663 additions and 156 deletions
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6
csrc/ops.h
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@ -98,11 +98,13 @@ torch::Tensor gptq_gemm(
torch::Tensor b_gptq_qzeros,
torch::Tensor b_gptq_scales,
torch::Tensor b_g_idx,
bool use_exllama);
bool use_exllama,
int bit);
void gptq_shuffle(
torch::Tensor q_weight,
torch::Tensor q_perm);
torch::Tensor q_perm,
int bit);
void moe_align_block_size(
torch::Tensor topk_ids,

123
csrc/quantization/gptq/matrix_view.cuh
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@ -146,6 +146,129 @@ public:
__device__ __forceinline__ const uint32_t* item_uint32_ptr(int row, int column) { return &data[row / 8 * width + column]; }
};
class MatrixView_q2_row
{
public:
const uint32_t* data;
const int height;
const int width;
__device__ __forceinline__ MatrixView_q2_row(const uint32_t* data, const int height, const int width)
: data(data), height(height), width(width)
{ }
__device__ __forceinline__ int item(int row, int column) const
{
int shift = (column & 0x0f) * 2;
return (data[row * width / 16 + column / 16] >> shift) & 0x03;
}
__device__ __forceinline__ void item2(int (&items)[2], int row, int column) const
{
int shift = (column & 0x0f) * 2;
uint32_t d = data[row * width / 16 + column / 16] >> shift;
items[0] = d & 0x03;
items[1] = (d >> 2) & 0x03;
}
__device__ __forceinline__ void item4(int (&items)[4], int row, int column) const
{
int shift = (column & 0x0f) * 2;
uint32_t d = data[row * width / 16 + column / 16] >> shift;
items[0] = d & 0x03;
items[1] = (d >> 2) & 0x03;
items[2] = (d >> 4) & 0x03;
items[3] = (d >> 6) & 0x03;
}
};
class MatrixView_q3_row
{
public:
const uint32_t* data;
const int height;
const int width;
__device__ __forceinline__ MatrixView_q3_row(const uint32_t* data, const int height, const int width)
: data(data), height(height), width(width)
{ }
__device__ __forceinline__ int item(int row, int column) const
{
int z_w = column * 3 / 32;
int z_mod = column & 0x1f;
if (z_mod == 10) {
return (data[row * width * 3 / 32 + z_w] >> 30) | ((data[row * width * 3 / 32 + (z_w + 1)] << 2) & 0x4);
} else if (z_mod == 21) {
return (data[row * width * 3 / 32 + z_w] >> 31) | ((data[row * width * 3 / 32 + (z_w + 1)] << 1) & 0x6);
} else if (z_mod < 10) {
return (data[row * width * 3 / 32 + z_w] >> (z_mod * 3)) & 0x07;
} else if (z_mod < 21) {
return (data[row * width * 3 / 32 + z_w] >> (z_mod * 3 - 32)) & 0x07;
} else {
return (data[row * width * 3 / 32 + z_w] >> (z_mod * 3 - 64)) & 0x07;
}
}
__device__ __forceinline__ void item4(int (&items)[4], int row, int column) const
{
int shift = (column & 0x1f);
uint32_t d;
if (shift <= 4) {
d = data[row * width / 32 * 3 + column * 3 / 32] >> (shift * 3);
} else if (shift == 8) {
d = (data[row * width / 32 * 3 + column * 3 / 32] >> 24) | ((data[row * width / 32 * 3 + column * 3 / 32 + 1] & 0x0f) << 8);
} else if (shift <= 16) {
d = data[row * width / 32 * 3 + column * 3 / 32] >> (shift * 3 - 32);
} else if (shift == 20) {
d = (data[row * width / 32 * 3 + column * 3 / 32] >> 28) | ((data[row * width / 32 * 3 + column * 3 / 32 + 1] & 0xff) << 4);
} else {
d = data[row * width / 32 * 3 + column * 3 / 32] >> (shift * 3 - 64);
}
items[0] = d & 0x07;
items[1] = (d >> 3) & 0x07;
items[2] = (d >> 6) & 0x07;
items[3] = (d >> 9) & 0x07;
}
};
class MatrixView_q8_row
{
public:
const uint32_t* data;
const int height;
const int width;
__device__ __forceinline__ MatrixView_q8_row(const uint32_t* data, const int height, const int width)
: data(data), height(height), width(width)
{ }
__device__ __forceinline__ int item(int row, int column) const
{
int shift = (column & 0x03) * 8;
return (data[row * width / 4 + column / 4] >> shift) & 0xff;
}
__device__ __forceinline__ void item2(int (&items)[2], int row, int column) const
{
int shift = (column & 0x03) * 8;
uint32_t d = data[row * width / 4 + column / 4] >> shift;
items[0] = d & 0xff;
items[1] = (d >> 8) & 0xff;
}
__device__ __forceinline__ void item4(int (&items)[4], int row, int column) const
{
int shift = (column & 0x03) * 2;
uint32_t d = data[row * width / 4 + column / 4] >> shift;
items[0] = d & 0xff;
items[1] = (d >> 8) & 0xff;
items[2] = (d >> 16) & 0xff;
items[3] = (d >> 24) & 0xff;
}
};
} // namespace gptq
} // namespace vllm
#endif

1306
csrc/quantization/gptq/q_gemm.cu
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87
csrc/quantization/gptq/qdq_2.cuh Normal file
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@ -0,0 +1,87 @@
/*
Copied from https://github.com/turboderp/exllamav2
*/
#ifndef _qdq_2_cuh
#define _qdq_2_cuh
#include "qdq_util.cuh"
namespace vllm {
namespace gptq {
// Permutation:
//
// ffddbb99 77553311 eeccaa88 66442200
__forceinline__ __device__ void shuffle_2bit_16
(
uint32_t* q,
int stride
)
{
uint32_t qa = q[0];
uint32_t qb = 0;
#pragma unroll
for (int i = 0; i < 8; i++)
{
uint32_t qa0 = qa & 0x03;
uint32_t qa1 = (qa & 0x0c) >> 2;
qa >>= 4;
qb |= (qa1 << (i * 2 + 16));
qb |= (qa0 << (i * 2));
}
q[0] = qb;
}
__forceinline__ __device__ void dequant_2bit_16
(
const uint32_t q_0,
half2 (&dq)[8],
int stride,
const uint32_t zero
)
{
const uint32_t c0 = 0x64006400;
const half y4_ = __float2half_rn(1.0f / 4.0f);
const half y16_ = __float2half_rn(1.0f / 16.0f);
const half y64_ = __float2half_rn(1.0f / 64.0f);
const half2 y4 = __halves2half2(y4_, y4_);
const half2 y16 = __halves2half2(y16_, y16_);
const half2 y64 = __halves2half2(y64_, y64_);
const half_uint16 z1_(0xe400 | zero); // half(-1024.0f - zero);
const half z4_ = __hsub(__int2half_rn(-256), __int2half_rn(zero));
const half z16_ = __hsub(__int2half_rn(-64), __int2half_rn(zero));
const half z64_ = __hsub(__int2half_rn(-16), __int2half_rn(zero));
const half2 z1 = __half2half2(z1_.as_half);
const half2 z4 = __half2half2(z4_);
const half2 z16 = __half2half2(z16_);
const half2 z64 = __half2half2(z64_);
uint32_t qa = q_0;
half2_uint32 q0((qa & 0x00030003) | c0); // half2(q[ 0], q[ 1]) + 1024
half2_uint32 q1((qa & 0x000c000c) | c0); // half2(q[ 2], q[ 3]) * 4 + 1024
half2_uint32 q2((qa & 0x00300030) | c0); // half2(q[ 4], q[ 5]) * 16 + 1024
half2_uint32 q3((qa & 0x00c000c0) | c0); // half2(q[ 6], q[ 7]) * 64 + 1024
qa >>= 8;
half2_uint32 q4((qa & 0x00030003) | c0); // half2(q[ 8], q[ 8]) + 1024
half2_uint32 q5((qa & 0x000c000c) | c0); // half2(q[10], q[11]) * 4 + 1024
half2_uint32 q6((qa & 0x00300030) | c0); // half2(q[12], q[13]) * 16 + 1024
half2_uint32 q7((qa & 0x00c000c0) | c0); // half2(q[14], q[15]) * 64 + 1024
dq[0] = __hadd2(q0.as_half2, z1);
dq[1] = __hfma2(q1.as_half2, y4, z4);
dq[2] = __hfma2(q2.as_half2, y16, z16);
dq[3] = __hfma2(q3.as_half2, y64, z64);
dq[4] = __hadd2(q4.as_half2, z1);
dq[5] = __hfma2(q5.as_half2, y4, z4);
dq[6] = __hfma2(q6.as_half2, y16, z16);
dq[7] = __hfma2(q7.as_half2, y64, z64);
}
} // namespace gptq
} // namespace vllm
#endif

141
csrc/quantization/gptq/qdq_3.cuh Normal file
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@ -0,0 +1,141 @@
#ifndef _qdq_3_cuh
#define _qdq_3_cuh
#include "qdq_util.cuh"
namespace vllm {
namespace gptq {
// Permutation:
//
// v9997775 55333111 u8886664 44222000 (u, v lsb)
// vjjjhhhf ffdddbbb uiiiggge eecccaaa
// vtttrrrp ppnnnlll usssqqqo oommmkkk
__forceinline__ __device__ void shuffle_3bit_32
(
uint32_t* q,
int stride
)
{
uint32_t qa = q[0 * stride];
uint32_t qb = q[1 * stride];
uint32_t qc = q[2 * stride];
// qa: aa999888 77766655 54443332 22111000
// qb: lkkkjjji iihhhggg fffeeedd dcccbbba
// qc: vvvuuutt tsssrrrq qqpppooo nnnmmmll
uint32_t qd = qc >> 26;
qc <<= 4;
qc |= qb >> 28;
qb <<= 2;
qb |= qa >> 30;
// qa: ..999888 77766655 54443332 22111000
// qb: ..jjjiii hhhgggff feeedddc ccbbbaaa
// qc: ..tttsss rrrqqqpp pooonnnm mmlllkkk
// qd: vvvuuu
uint32_t za = 0;
uint32_t zb = 0;
uint32_t zc = 0;
for (int i = 0; i < 5; i++) { uint32_t t0 = qa & 0x07; uint32_t t1 = (qa & 0x38) >> 3; qa >>= 6; za |= (t0 << (i * 3)); za |= (t1 << (i * 3 + 16)); }
for (int i = 0; i < 5; i++) { uint32_t t0 = qb & 0x07; uint32_t t1 = (qb & 0x38) >> 3; qb >>= 6; zb |= (t0 << (i * 3)); zb |= (t1 << (i * 3 + 16)); }
for (int i = 0; i < 5; i++) { uint32_t t0 = qc & 0x07; uint32_t t1 = (qc & 0x38) >> 3; qc >>= 6; zc |= (t0 << (i * 3)); zc |= (t1 << (i * 3 + 16)); }
// za: 9997775 55333111 8886664 44222000
// zb: jjjhhhf ffdddbbb iiiggge eecccaaa
// zc: tttrrrp ppnnnlll sssqqqo oommmkkk
// qd: vvvuuu
za |= ((qd & 0x01) >> 0) << 15;
zb |= ((qd & 0x02) >> 1) << 15;
zc |= ((qd & 0x04) >> 2) << 15;
za |= ((qd & 0x08) >> 3) << 31;
zb |= ((qd & 0x10) >> 4) << 31;
zc |= ((qd & 0x20) >> 5) << 31;
// za: v9997775 55333111 u8886664 44222000 (u, v lsb)
// zb: vjjjhhhf ffdddbbb uiiiggge eecccaaa
// zc: vtttrrrp ppnnnlll usssqqqo oommmkkk
q[0 * stride] = za;
q[1 * stride] = zb;
q[2 * stride] = zc;
}
__forceinline__ __device__ void dequant_3bit_32
(
const uint32_t q_0,
const uint32_t q_1,
const uint32_t q_2,
half2 (&dq)[16],
int stride,
const uint32_t zero
)
{
const uint32_t c0 = 0x64006400;
const half y8_ = __float2half_rn(1.0f / 8.0f);
const half y64_ = __float2half_rn(1.0f / 64.0f);
const half2 y8 = __halves2half2(y8_, y8_);
const half2 y64 = __halves2half2(y64_, y64_);
const half_uint16 z1_(0xe400 | zero); // half(-1024.0f - zero);
const half z8_ = __hsub(__int2half_rn(-128), __int2half_rn(zero));
const half z64_ = __hsub(__int2half_rn(-16), __int2half_rn(zero));
const half2 z1 = __halves2half2(z1_.as_half, z1_.as_half);
const half2 z8 = __halves2half2(z8_, z8_);
const half2 z64 = __halves2half2(z64_, z64_);
uint32_t qa = q_0;
uint32_t qb = q_1;
uint32_t qc = q_2;
half2_uint32 q0((qa & 0x00070007) | c0); // half2(q[ 0], q[ 1]) + 1024
half2_uint32 q1((qa & 0x00380038) | c0); // half2(q[ 2], q[ 3]) * 8 + 1024
qa >>= 6;
half2_uint32 q2((qa & 0x00070007) | c0); // half2(q[ 4], q[ 5]) + 1024
half2_uint32 q3((qa & 0x00380038) | c0); // half2(q[ 6], q[ 7]) * 8 + 1024
half2_uint32 q4((qa & 0x01c001c0) | c0); // half2(q[ 8], q[ 9]) * 64 + 1024
qa >>= 9;
qa &= 0x00010001;
half2_uint32 q5((qb & 0x00070007) | c0); // half2(q[10], q[11]) + 1024
half2_uint32 q6((qb & 0x00380038) | c0); // half2(q[12], q[13]) * 8 + 1024
qb >>= 6;
half2_uint32 q7((qb & 0x00070007) | c0); // half2(q[14], q[15]) + 1024
half2_uint32 q8((qb & 0x00380038) | c0); // half2(q[16], q[17]) * 8 + 1024
half2_uint32 q9((qb & 0x01c001c0) | c0); // half2(q[18], q[19]) * 64 + 1024
qb >>= 8;
qb &= 0x00020002;
half2_uint32 q10((qc & 0x00070007) | c0); // half2(q[20], q[21]) + 1024
half2_uint32 q11((qc & 0x00380038) | c0); // half2(q[22], q[23]) * 8 + 1024
qc >>= 6;
half2_uint32 q12((qc & 0x00070007) | c0); // half2(q[24], q[25]) + 1024
half2_uint32 q13((qc & 0x00380038) | c0); // half2(q[26], q[27]) * 8 + 1024
half2_uint32 q14((qc & 0x01c001c0) | c0); // half2(q[28], q[29]) * 64 + 1024
qc >>= 7;
qc &= 0x00040004;
half2_uint32 q15((qa | qb | qc) | c0);
dq[ 0] = __hadd2( q0.as_half2, z1);
dq[ 1] = __hfma2( q1.as_half2, y8, z8);
dq[ 2] = __hadd2( q2.as_half2, z1);
dq[ 3] = __hfma2( q3.as_half2, y8, z8);
dq[ 4] = __hfma2( q4.as_half2, y64, z64);
dq[ 5] = __hadd2( q5.as_half2, z1);
dq[ 6] = __hfma2( q6.as_half2, y8, z8);
dq[ 7] = __hadd2( q7.as_half2, z1);
dq[ 8] = __hfma2( q8.as_half2, y8, z8);
dq[ 9] = __hfma2( q9.as_half2, y64, z64);
dq[10] = __hadd2(q10.as_half2, z1);
dq[11] = __hfma2(q11.as_half2, y8, z8);
dq[12] = __hadd2(q12.as_half2, z1);
dq[13] = __hfma2(q13.as_half2, y8, z8);
dq[14] = __hfma2(q14.as_half2, y64, z64);
dq[15] = __hadd2(q15.as_half2, z1);
}
} // namespace gptq
} // namespace vllm
#endif

100
csrc/quantization/gptq/qdq_4.cuh
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@ -38,16 +38,17 @@ __forceinline__ __device__ void dequant_4bit_8
(
const uint32_t q_0,
half2 (&dq)[4],
int stride
int stride,
const uint32_t zero
)
{
const uint32_t c0 = 0x64006400;
const half y16_ = __float2half_rn(1.0f / 16.0f);
const half2 y16 = __halves2half2(y16_, y16_);
const half z1_ = __float2half_rn(-1024.0f - 8.0f);
const half z16_ = __float2half_rn(-1024.0f / 16.0f - 8.0f);
const half2 z1 = __halves2half2(z1_, z1_);
const half2 z16 = __halves2half2(z16_, z16_);
const half_uint16 z1_(0xe400 | zero); // half(-1024.0f - zero);
const half z16_ = __hsub(__int2half_rn(-64), __int2half_rn(zero));
const half2 z1 = __half2half2(z1_.as_half);
const half2 z16 = __half2half2(z16_);
uint32_t qa = q_0;
half2_uint32 q0((qa & 0x000f000f) | c0); // half2(q[ 0], q[ 1]) + 1024
@ -143,93 +144,4 @@ __forceinline__ __device__ void dequant_4bit_8_gptq
} // namespace gptq
} // namespace vllm
#else
namespace vllm {
namespace gptq {
__forceinline__ __device__ void shuffle_4bit_8
(
uint32_t* q,
int stride
)
{
}
__forceinline__ __device__ void dequant_4bit_8
(
const uint32_t q_0,
half2 (&dq)[4],
int stride
)
{
half dqh[8];
for (int i = 0; i < 8; i++) dqh[i] = dq_ns(exb(q_0, i * 4, 0x0f), 8);
for (int i = 0; i < 4; i++) dq[i] = __halves2half2(dqh[i * 2], dqh[i * 2 + 1]);
}
__forceinline__ __device__ void dequant_4bit_8_prep_zero_scale
(
const uint32_t zero,
const half scale,
half2 (&z1)[2],
half2 (&y1)[2]
)
{
half z = __int2half_rn(-((int)zero));
z = __hmul(z, scale);
z1[0] = __half2half2(z);
y1[0] = __half2half2(scale);
}
__forceinline__ __device__ void dequant_4bit_8_prep_zero
(
const uint32_t zero,
half2(&z1)[2],
half2(&y1)[2]
)
{
half z = __int2half_rn(-((int)zero));
z1[0] = __half2half2(z);
}
__forceinline__ __device__ void dequant_4bit_8_gptq
(
const uint32_t q_0,
half2 (&dq)[4],
half2 (&z1)[2],
half2 (&y1)[2],
int stride,
bool scaled
)
{
half2 dqh2[8];
uint32_t qa = q_0;
for (int i = 0; i < 4; i++)
{
half d0 = __int2half_rn(qa & 0x0f); qa >>= 4;
half d1 = __int2half_rn(qa & 0x0f); qa >>= 4;
dqh2[i] = __halves2half2(d0, d1);
}
if (scaled)
{
dq[0] = __hfma2(dqh2[0], y1[0], z1[0]);
dq[1] = __hfma2(dqh2[1], y1[0], z1[0]);
dq[2] = __hfma2(dqh2[2], y1[0], z1[0]);
dq[3] = __hfma2(dqh2[3], y1[0], z1[0]);
}
else
{
dq[0] = __hadd2(dqh2[0], z1[0]);
dq[1] = __hadd2(dqh2[1], z1[0]);
dq[2] = __hadd2(dqh2[2], z1[0]);
dq[3] = __hadd2(dqh2[3], z1[0]);
}
}
} // namespace gptq
} // namespace vllm
#endif

40
csrc/quantization/gptq/qdq_8.cuh Normal file
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@ -0,0 +1,40 @@
/*
Copied from https://github.com/turboderp/exllamav2
*/
#ifndef _qdq_8_cuh
#define _qdq_8_cuh
#include "qdq_util.cuh"
namespace vllm {
namespace gptq {
__forceinline__ __device__ void shuffle_8bit_4
(
uint32_t* q,
int stride
)
{
}
__forceinline__ __device__ void dequant_8bit_8
(
const uint32_t q_0,
const uint32_t q_1,
half2 (&dq)[4],
int stride,
const uint32_t zero
)
{
half dqh[8];
for (int i = 0; i < 4; i++) dqh[i ] = dq_ns(exb(q_0, i * 8, 0xff), zero);
for (int i = 0; i < 4; i++) dqh[i + 4] = dq_ns(exb(q_1, i * 8, 0xff), zero);
for (int i = 0; i < 4; i++) dq[i] = __halves2half2(dqh[i * 2], dqh[i * 2 + 1]);
}
} // namespace gptq
} // namespace vllm
#endif

16
vllm/model_executor/layers/quantization/gptq.py
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@ -1,6 +1,7 @@
import enum
from enum import Enum
from typing import Any, Dict, List, Optional
from fractions import Fraction
import torch
from torch.nn.parameter import Parameter
@ -27,11 +28,10 @@ class GPTQConfig(QuantizationConfig):
self.weight_bits = weight_bits
self.group_size = group_size
self.desc_act = desc_act
self.pack_factor = 32 // self.weight_bits
# exllama kernel v1 only supports 4 bit
if self.weight_bits != 4:
self.pack_factor = Fraction(32, self.weight_bits)
if self.weight_bits not in [2, 3, 4, 8]:
raise ValueError(
"Currently, only 4-bit weight quantization is supported for "
"Currently, only 2/3/4/8-bit weight quantization is supported for "
f"GPTQ, but got {self.weight_bits} bits.")
def __repr__(self) -> str:
@ -101,7 +101,7 @@ class GPTQLinearMethod(LinearMethodBase):
"The input size is not aligned with the quantized "
"weight shape. This can be caused by too large "
"tensor parallel size.")
if output_size_per_partition % self.quant_config.pack_factor != 0:
if output_size_per_partition % self.quant_config.pack_factor.numerator != 0:
raise ValueError(
"The output size is not aligned with the quantized "
"weight shape. This can be caused by too large "
@ -201,11 +201,13 @@ class GPTQLinearMethod(LinearMethodBase):
else:
weights["g_idx"] = torch.empty((1, 1), device="meta")
weights["exllama_state"] = ExllamaState.READY
ops.gptq_shuffle(weights["qweight"], weights["g_idx"])
ops.gptq_shuffle(weights["qweight"], weights["g_idx"],
self.quant_config.weight_bits)
output = ops.gptq_gemm(reshaped_x, weights["qweight"],
weights["qzeros"], weights["scales"],
weights["g_idx"],
weights["exllama_state"] == ExllamaState.READY)
weights["exllama_state"] == ExllamaState.READY,
self.quant_config.weight_bits)
if bias is not None:
output = output + bias
return output.reshape(out_shape)