mirror of
https://github.com/ggerganov/llama.cpp.git
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9bc6db28d0
* ggml-quants : 1.625 bpw ternary packing for BitNet 1.58b * ggml-quants : faster 1.625 bpw AVX2 vec_dot Not using a lookup table anymore makes it match q4_0 speed. * gguf-py : fix formatting * llama : remove spaces on empty line * ggml-quants : subtract 1 when back in epi8 This makes the 1.625 bpw type go faster than q4_0. Still not the fastest. * ggml-quants : Q2_2 now faster than Q4_K on with AVX2 * ggml-quants : cleanup Q1_3 code formatting * ggml-quants : ARM NEON vec_dot for q2_2 and q1_3 * ggml-quants : use ceiling division when quantizing q1_3 * convert-hf : simplify BitNet pre-quantization This still results in the exact same tensor weights and scales, but it reveals some weirdness in the current algorithm. * convert-hf : allow converting the weird BitNet 1.3B Its FFN size is 5460 which is not convenient. The offending tensors are kept in F16, which makes the final model 5.01 bpw. * bitnet : replace 1.58b with b1.58, as in the paper * ggml-quants : fix build failure on Windows * ggml-quants : attempt to fix Arm 32-bit support * ggml : add some informative comments in q1_3 vec_dot * ggml : add TQ1_0 and TQ2_0 ternary quantization types * ggml : even faster TQ2_0 * ggml : also faster TQ1_0 Same optimization as for TQ2_0 by offsetting the sum instead of the weights. This makes TQ1_0 almost as fast as Q8_0 on AVX2. * ggml : fix build issues in certain environments * ggml : add NEON vec_dot implementation for TQ1_0 and TQ2_0 * ggml : avoid directly using vmlal_high_s8, for 32-bit ARM compat The compiler seems smart enough to use the same instruction even when using vget_high_s8 instead. * ggml : remove q1_3 and q2_2 No more 1.625 bpw and 2.000 bpw, now instead using 1.6875 bpw and 2.0625 bpw with TQ1_0 and TQ2_0, respectively. * llama : remove the separate scale tensors of BitNet b1.58 They won't be needed, since the remaining ternary quant types have built-in scales. * ggml-quants : rename fields of TQ1_0 and TQ2_0 structs for consistency * ggml-quants : allow using vdotq_s32 in TQ2_0 vec_dot Not yet tested on hardware which supports it, might not work or might not even compile. But also it might. It should make the performance better on recent ARM CPUs. * ggml-quants : remove comment about possible format change of TQ2_0 Making it slightly more convenient for AVX512 but less convenient for everything else is not worth the trouble. * gguf-py : Numpy (de)quantization for TQ1_0 and TQ2_0 * ggml-quants : use roundf instead of nearest_int for TQ1_0 and TQ2_0 This does not change anything for ternary models, since their values should never end up being in halfway cases anyway. * convert : allow direct conversion to TQ1_0 and TQ2_0 The token embeddings and output tensors are kept in F16 to allow quantizing them to Q4_K and Q6_K with llama-quantize. * llama : handle fallback for TQ1_0 and TQ2_0 with Q4_0 Q4_0 is not completely symmetric (so not lossless for ternary models), but it should be good enough. * ggml-quants : allow using ARM dot product instructions for TQ1_0 * ggml-quants : deduplicate TQ1_0 and TQ2_0 __ARM_FEATURE_DOTPROD support * ggml : remove unused ggml_mul special case It would otherwise conflict with the more general optimization coming with Mamba-2. * ggml : handle TQ1_0 and TQ2_0 in dequantization-based operators * test-backend-ops : add TQ1_0 and TQ2_0 comments for later Not yet adding uncommented, because some backends like SYCL and Metal do not properly handle unknown types in supports_op for GGML_OP_MUL_MAT. (and Metal also doesn't handle it with GGML_OP_GET_ROWS) Support for TQ1_0 and TQ2_0 for other backends than CPU will be added in follow-up pull requests.
239 lines
9.8 KiB
Python
Executable File
239 lines
9.8 KiB
Python
Executable File
#!/usr/bin/env python3
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# Test gguf.quants so that it exactly matches the C implementation of the (de)quantization
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# NOTE: this is kind of a mess, but at least it worked for initially testing the Python implementations.
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from __future__ import annotations
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import argparse
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from math import prod
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import os
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import sys
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from pathlib import Path
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import ctypes
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import logging
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import numpy as np
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# Necessary to load the local gguf package
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if "NO_LOCAL_GGUF" not in os.environ and (Path(__file__).parent.parent.parent / 'gguf-py').exists():
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sys.path.insert(0, str(Path(__file__).parent.parent))
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import gguf
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from gguf.constants import GGMLQuantizationType
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logger = logging.getLogger("test-quants")
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c_float_p = ctypes.POINTER(ctypes.c_float)
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class ggml_init_params(ctypes.Structure):
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_fields_ = [
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("mem_size", ctypes.c_size_t),
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("mem_buffer", ctypes.c_void_p),
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("no_alloc", ctypes.c_bool),
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]
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class GGMLQuants:
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libggml: ctypes.CDLL
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def __init__(self, libggml: Path):
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self.libggml = ctypes.CDLL(str(libggml))
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self.libggml.ggml_quantize_chunk.restype = ctypes.c_size_t
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# enum ggml_type type,
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# const float * src,
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# void * dst,
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# int64_t start,
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# int64_t nrows,
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# int64_t n_per_row,
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# const float * imatrix) {
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self.libggml.ggml_quantize_chunk.argtypes = (
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ctypes.c_int,
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ctypes.POINTER(ctypes.c_float),
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ctypes.c_void_p,
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ctypes.c_int64,
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ctypes.c_int64,
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ctypes.c_int64,
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ctypes.POINTER(ctypes.c_float),
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)
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self.libggml.ggml_quantize_requires_imatrix.restype = ctypes.c_bool
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self.libggml.ggml_quantize_requires_imatrix.argtypes = (ctypes.c_int,)
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for t in (
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"q4_0", "q4_1", "q5_0", "q5_1", "q8_0",
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"q2_K", "q3_K", "q4_K", "q5_K", "q6_K",
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"tq1_0", "tq2_0",
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"iq2_xxs", "iq2_xs", "iq2_s", "iq3_xxs", "iq3_s", "iq1_s", "iq1_m",
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"iq4_nl", "iq4_xs",
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):
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dequant_func: ctypes._NamedFuncPointer = getattr(self.libggml, "dequantize_row_" + t)
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dequant_func.restype = None
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dequant_func.argtypes = (ctypes.c_void_p, ctypes.POINTER(ctypes.c_float), ctypes.c_int64)
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self.libggml.ggml_fp16_to_fp32_row.restype = None
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self.libggml.ggml_fp16_to_fp32_row.argtypes = (ctypes.POINTER(ctypes.c_uint16), ctypes.POINTER(ctypes.c_float), ctypes.c_int64)
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self.libggml.ggml_bf16_to_fp32_row.restype = None
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self.libggml.ggml_bf16_to_fp32_row.argtypes = (ctypes.POINTER(ctypes.c_uint16), ctypes.POINTER(ctypes.c_float), ctypes.c_int64)
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self.libggml.ggml_init.argtypes = (ggml_init_params,)
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self.libggml.ggml_init(ggml_init_params(1 * 1024 * 1024, 0, False))
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def dequantize(self, tensor: np.ndarray, qtype: GGMLQuantizationType) -> np.ndarray:
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result = np.zeros(gguf.quant_shape_from_byte_shape(tensor.shape, qtype), dtype=np.float32, order="C")
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if qtype == GGMLQuantizationType.F32:
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# no-op
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result = tensor.view(np.float32)
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elif qtype == GGMLQuantizationType.F16:
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self.libggml.ggml_fp16_to_fp32_row(tensor.ctypes.data_as(ctypes.POINTER(ctypes.c_uint16)), result.ctypes.data_as(c_float_p), result.size)
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elif qtype == GGMLQuantizationType.BF16:
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self.libggml.ggml_bf16_to_fp32_row(tensor.ctypes.data_as(ctypes.POINTER(ctypes.c_uint16)), result.ctypes.data_as(c_float_p), result.size)
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else:
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lw_qname = qtype.name.lower()
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if lw_qname[-1] == "k":
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lw_qname = lw_qname[:-1] + "K"
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dequant_func: ctypes._NamedFuncPointer = getattr(self.libggml, "dequantize_row_" + lw_qname)
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dequant_func(tensor.ctypes.data_as(ctypes.c_void_p), result.ctypes.data_as(c_float_p), result.size)
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return result
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def quantize(self, data: np.ndarray, qtype: GGMLQuantizationType) -> np.ndarray:
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result = np.zeros(gguf.quant_shape_to_byte_shape(data.shape, qtype), dtype=np.uint8, order="C")
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if self.libggml.ggml_quantize_requires_imatrix(qtype.value):
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# TODO: is a column-wise sum of squares appropriate?
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qw = np.sum((data * data).reshape((-1, data.shape[-1])), axis=0).ctypes.data_as(c_float_p)
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else:
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qw = ctypes.cast(0, c_float_p)
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result_size = self.libggml.ggml_quantize_chunk(qtype.value, data.ctypes.data_as(c_float_p), result.ctypes.data_as(ctypes.c_void_p), 0, prod(data.shape[:-1]), data.shape[-1], qw)
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assert result.size == result_size
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return result
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def compare_tensors(t1: np.ndarray, t2: np.ndarray, qtype: GGMLQuantizationType) -> bool:
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same = np.array_equal(t1, t2)
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if same:
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return True
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else:
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block_size, type_size = gguf.GGML_QUANT_SIZES[qtype]
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if t1.dtype == np.float32:
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t1 = t1.reshape((-1, block_size))
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t2 = t2.reshape((-1, block_size))
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else:
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t1 = t1.reshape((-1, type_size))
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t2 = t2.reshape((-1, type_size))
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x = t1.view(np.uint8) ^ t2.view(np.uint8)
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diff_bits = np.count_nonzero(np.unpackbits(x, axis=-1), axis=-1)
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num_bad_blocks = np.count_nonzero(diff_bits, axis=0)
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if num_bad_blocks == 0 and t1.shape == t2.shape:
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logger.debug("Bits are equal, but arrays don't match, likely contains NANs")
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return True
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logger.debug(f"{num_bad_blocks} bad blocks ({100 * num_bad_blocks / x.shape[0]:.6f}%)")
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bad_block_id = np.argmax(diff_bits, axis=0)
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logger.debug(f"Worst block id: {bad_block_id}")
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logger.debug(f"Sample bad block ({diff_bits[bad_block_id]} differing bits):\n{t1[bad_block_id]}\nReference:\n{t2[bad_block_id]}")
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sum_diff_bits = np.sum(diff_bits)
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logger.debug(f"{sum_diff_bits} bits differ ({100 * sum_diff_bits/(x.size * 8):.6f}%)")
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return False
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def do_test(libggml_path: Path, quick: bool = False):
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ggml_quants = GGMLQuants(libggml_path)
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np.set_printoptions(precision=None, threshold=(4 * 256) + 1, formatter={"int": lambda n: "0x%02X" % n})
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r = np.random.randn(8, 1024, 1024).astype(np.float32, copy=False)
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for qtype in (GGMLQuantizationType.F16, *gguf.quants._type_traits.keys()):
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has_dequantize = False
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has_quantize = False
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try:
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gguf.dequantize(np.zeros((gguf.GGML_QUANT_SIZES[qtype][1]), dtype=np.uint8), qtype)
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has_dequantize = True
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except (NotImplementedError, AssertionError) as e:
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if isinstance(e, AssertionError):
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logger.error(f"Error with {qtype.name}: {e}")
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raise e
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try:
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gguf.quantize(np.zeros((gguf.GGML_QUANT_SIZES[qtype][0]), dtype=np.float32), qtype)
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has_quantize = True
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except (NotImplementedError, AssertionError) as e:
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if isinstance(e, AssertionError):
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logger.error(f"Error with {qtype.name}: {e}")
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raise e
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if not has_dequantize and not has_quantize:
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continue
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logger.info(f"Testing {qtype.name}")
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rc = r.copy(order="C")
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pyq = None
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ggq = None
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if has_quantize:
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logger.debug(f"Quantizing to {qtype.name} with Python")
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pyq = gguf.quants.quantize(rc, qtype)
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logger.debug(f"Quantizing to {qtype.name} with C")
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ggq = ggml_quants.quantize(rc, qtype)
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if qtype == GGMLQuantizationType.F16:
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pyq = pyq.view(np.uint8)
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quant_equal = compare_tensors(pyq, ggq, qtype)
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if not quant_equal:
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logger.error(f"Quantization to {qtype.name} does not match ❌")
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else:
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logger.info(f"Quantization to {qtype.name} matches exactly ✅")
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if has_dequantize:
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if ggq is None and not quick:
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logger.debug(f"Quantizing to {qtype.name} with C")
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ggq = ggml_quants.quantize(rc, qtype)
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if ggq is not None:
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logger.debug(f"Dequantizing from {qtype.name} with Python")
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pydq = gguf.quants.dequantize(ggq, qtype)
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logger.debug(f"Dequantizing from {qtype.name} with C")
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ggdq = ggml_quants.dequantize(ggq, qtype)
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dequant_equal = compare_tensors(pydq, ggdq, qtype)
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if not dequant_equal:
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logger.error(f"Dequantization from {qtype.name} does not match ❌")
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else:
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logger.info(f"Dequantization from {qtype.name} matches exactly ✅")
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rq_shape = gguf.quants.quant_shape_to_byte_shape((8, 1024, 1024 // 2), qtype)
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rq = np.random.random(rq_shape).astype(np.float16).view(np.uint8)
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logger.debug(f"Dequantizing random f16 data as {qtype.name} with Python")
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pydq = gguf.quants.dequantize(rq, qtype)
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logger.debug(f"Dequantizing random f16 data as {qtype.name} with C")
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ggdq = ggml_quants.dequantize(rq, qtype)
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dequant_equal = compare_tensors(pydq, ggdq, qtype)
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if not dequant_equal:
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logger.error(f"Dequantization from random f16 data as {qtype.name} does not match ❌")
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else:
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logger.info(f"Dequantization from random f16 data as {qtype.name} matches exactly ✅")
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if __name__ == "__main__":
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parser = argparse.ArgumentParser(description="Test Python (de)quantization against the reference C implementation")
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parser.add_argument("--libggml", type=Path, default=Path(__file__).parent.parent.parent / "build" / "ggml" / "src" / "libggml.so", help="The path to libggml.so")
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parser.add_argument("--quick", action="store_true", help="Don't quantize with C when it's not strictly necessary")
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args = parser.parse_args()
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logging.basicConfig(level=logging.DEBUG)
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do_test(args.libggml, args.quick)
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