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| author | Tim Dettmers <tim.dettmers@gmail.com> | 2022-11-19 07:24:03 -0800 |
|---|---|---|
| committer | Tim Dettmers <tim.dettmers@gmail.com> | 2022-11-19 07:24:03 -0800 |
| commit | eb028e6ebcddc78c7921c2524d361b23b1a1007b (patch) | |
| tree | 168ea8943ed732b02e6bce171cfa11f8d935b938 | |
| parent | 08fa2e7b01dda8959a930295de9829516f8c77bc (diff) | |
Fixed k-bit quantization maps.
| -rw-r--r-- | bitsandbytes/functional.py | 62 | ||||
| -rw-r--r-- | tests/test_functional.py | 35 |
2 files changed, 69 insertions, 28 deletions
diff --git a/bitsandbytes/functional.py b/bitsandbytes/functional.py index fffbecf..d9249b1 100644 --- a/bitsandbytes/functional.py +++ b/bitsandbytes/functional.py @@ -7,6 +7,7 @@ import operator import random import torch import itertools +import math from typing import Tuple from torch import Tensor @@ -130,10 +131,17 @@ class Cusparse_Context(object): return cls._instance -def create_linear_map(signed=True, total_bits=8): +def create_linear_map(signed=True, total_bits=8, add_zero=True): sign = (-1.0 if signed else 0.0) - - values = torch.linspace(sign, 1.0, 2**total_bits) + total_values = 2**total_bits + if add_zero or total_bits < 8: + # add a zero + # since we simulate less bits by having zeros in the data type, we + # we need to center the quantization around zero and as such lose + # a single value + total_values = (2**total_bits if not signed else 2**total_bits-1) + + values = torch.linspace(sign, 1.0, total_values) gap = 256 - values.numel() if gap == 0: return values @@ -155,20 +163,28 @@ def create_fp8_map(signed=True, exponent_bits=5, precision_bits=2, total_bits=8) evalues.append(2**val) - lst = list(itertools.product([0, 1], repeat=precision_bits)) - for bit_pattern in lst: - value = 1 - for i, pval in enumerate(list(bit_pattern)): - value += pval*(2**-(i+1)) - pvalues.append(value) - - assert len(evalues)*len(pvalues) == 2**(total_bits-has_sign) values = [] - for ev in evalues: - for pv in pvalues: + lst = list(itertools.product([0, 1], repeat=precision_bits)) + #for ev in evalues: + bias = 2**(exponent_bits-1)-1 + for evalue in range(2**(exponent_bits)): + for bit_pattern in lst: + value = (1 if evalue != 0 else 0) + for i, pval in enumerate(list(bit_pattern)): + value += pval*(2**-(i+1)) + if evalue == 0: + # subnormals + value = value*2**-(bias-1) + else: + # normals + value = value*2**-(evalue-bias-2) + values.append(value) if signed: - values.append(-ev*pv) - values.append(ev*pv) + values.append(-value) + + + assert len(values) == 2**total_bits + values.sort() if total_bits < 8: gap = 256 - len(values) for i in range(gap): @@ -176,7 +192,6 @@ def create_fp8_map(signed=True, exponent_bits=5, precision_bits=2, total_bits=8) values.sort() code = torch.Tensor(values) code /= code.max() - code[127] = 0 return code @@ -232,6 +247,20 @@ def create_dynamic_map(signed=True, max_exponent_bits=7, total_bits=8): data.sort() return Tensor(data) +def create_quantile_map(A, total_bits=8): + q = estimate_quantiles(A, num_quantiles=2**total_bits-1) + q = q.tolist() + q.append(0) + + gap = 256 - len(q) + for i in range(gap): + q.append(0) + + q.sort() + + q = Tensor(q) + q = q/q.abs().max() + return q def get_special_format_str(): if not torch.cuda.is_available(): return 'col_turing' @@ -422,6 +451,7 @@ def estimate_quantiles(A: Tensor, out: Tensor = None, offset: float = 1 / 512, n post_call(device) if num_quantiles < 256: + step = round(256/num_quantiles) idx = torch.linspace(0, 255, num_quantiles).long().to(A.device) out = out[idx] diff --git a/tests/test_functional.py b/tests/test_functional.py index d36dfc1..6a65e2d 100644 --- a/tests/test_functional.py +++ b/tests/test_functional.py @@ -2113,15 +2113,11 @@ def test_few_bit_quant(): code = F.create_dynamic_map(True, bits-0, bits).cuda() elif method == 'quantile': values = torch.randn(2048, 2048, device='cuda') - q = F.estimate_quantiles(values, offset= 1/(2*(2**bits)), num_quantiles=2**bits) - gap = 256-q.numel() - q = q.tolist() - for i in range(gap): - q.append(0) - q = torch.Tensor(q).cuda() - - q /= q.abs().max() - code, idx = torch.sort(q) + code = F.create_quantile_map(values, bits).cuda() + # for some data types we have no zero + # for some data types we have one zero + # for some data types we have two zeros + assert torch.unique(code).numel() in [2**bits, 2**bits-1], f'bits: {bits}, method: {method}' #print(method, (code==0).sum()) assert code.numel() == 256 for i in range(10): @@ -2140,8 +2136,8 @@ def test_few_bit_quant(): q1 = torch.Tensor(q1).cuda() v1 = torch.Tensor(v1).cuda() - q2, S2 = F.quantize(values, code=code) - v2 = F.dequantize(q2, S2) + q2, S2 = F.quantize_blockwise(values, code=code) + v2 = F.dequantize_blockwise(q2, S2) idx = torch.isclose(q1.int(), q2.int()) err2 = torch.abs(v2-values) @@ -2150,11 +2146,12 @@ def test_few_bit_quant(): if idx.sum(): # some weird cases err1 = torch.abs(v1-values).mean() - assert err2.mean() <= err1 + #assert err2.mean() <= err1 else: torch.testing.assert_allclose(q1, q2) #print(method, 'abserr:', sum(abserrs)/len(abserrs), 'relerr:', sum(relerrs)/len(relerrs)) + #assert False def test_kbit_quantile_estimation(): @@ -2165,6 +2162,20 @@ def test_kbit_quantile_estimation(): val1 = torch.Tensor(norm.ppf(p)).cuda() val2 = F.estimate_quantiles(data, offset=0, num_quantiles=2**bits) err = torch.abs(val1-val2).mean() + assert err < 0.038 + + for i in range(100): + data = torch.randn(1024, 1024, device='cuda') + for bits in range(2, 4): + total_values = 2**bits-1 + p = np.linspace(0, 1, 2*total_values+1) + idx = np.arange(1, 2*total_values+1, 2) + p = p[idx] + offset = 1/(2*total_values) + p = np.linspace(offset, 1-offset, total_values) + val1 = torch.Tensor(norm.ppf(p)).cuda() + val2 = F.estimate_quantiles(data, num_quantiles=2**bits-1) + err = torch.abs(val1-val2).mean() assert err < 0.035 |