tf.raw_ops.QuantizeV2
Quantize the 'input' tensor of type float to 'output' tensor of type 'T'.
tf.raw_ops.QuantizeV2( input, min_range, max_range, T, mode='MIN_COMBINED', round_mode='HALF_AWAY_FROM_ZERO', narrow_range=False, axis=-1, ensure_minimum_range=0.01, name=None )
[min_range, max_range] are scalar floats that specify the range for the 'input' data. The 'mode' attribute controls exactly which calculations are used to convert the float values to their quantized equivalents. The 'round_mode' attribute controls which rounding tie-breaking algorithm is used when rounding float values to their quantized equivalents.
In 'MIN_COMBINED' mode, each value of the tensor will undergo the following:
out[i] = (in[i] - min_range) * range(T) / (max_range - min_range) if T == qint8: out[i] -= (range(T) + 1) / 2.0
here range(T) = numeric_limits<T>::max() - numeric_limits<T>::min()
MIN_COMBINED Mode Example
Assume the input is type float and has a possible range of [0.0, 6.0] and the output type is quint8 ([0, 255]). The min_range and max_range values should be specified as 0.0 and 6.0. Quantizing from float to quint8 will multiply each value of the input by 255/6 and cast to quint8.
If the output type was qint8 ([-128, 127]), the operation will additionally subtract each value by 128 prior to casting, so that the range of values aligns with the range of qint8.
If the mode is 'MIN_FIRST', then this approach is used:
num_discrete_values = 1 << (# of bits in T) range_adjust = num_discrete_values / (num_discrete_values - 1) range = (range_max - range_min) * range_adjust range_scale = num_discrete_values / range quantized = round(input * range_scale) - round(range_min * range_scale) + numeric_limits<T>::min() quantized = max(quantized, numeric_limits<T>::min()) quantized = min(quantized, numeric_limits<T>::max())
The biggest difference between this and MIN_COMBINED is that the minimum range is rounded first, before it's subtracted from the rounded value. With MIN_COMBINED, a small bias is introduced where repeated iterations of quantizing and dequantizing will introduce a larger and larger error.
SCALED mode Example
SCALED
mode matches the quantization approach used in QuantizeAndDequantize{V2|V3}
.
If the mode is SCALED
, the quantization is performed by multiplying each input value by a scaling_factor. The scaling_factor is determined from min_range
and max_range
to be as large as possible such that the range from min_range
to max_range
is representable within values of type T.
const int min_T = std::numeric_limits<T>::min(); const int max_T = std::numeric_limits<T>::max(); const float max_float = std::numeric_limits<float>::max(); const float scale_factor_from_min_side = (min_T * min_range > 0) ? min_T / min_range : max_float; const float scale_factor_from_max_side = (max_T * max_range > 0) ? max_T / max_range : max_float; const float scale_factor = std::min(scale_factor_from_min_side, scale_factor_from_max_side);
We next use the scale_factor to adjust min_range and max_range as follows:
min_range = min_T / scale_factor; max_range = max_T / scale_factor;
e.g. if T = qint8, and initially min_range = -10, and max_range = 9, we would compare -128/-10.0 = 12.8 to 127/9.0 = 14.11, and set scaling_factor = 12.8 In this case, min_range would remain -10, but max_range would be adjusted to 127 / 12.8 = 9.921875
So we will quantize input values in the range (-10, 9.921875) to (-128, 127).
The input tensor can now be quantized by clipping values to the range min_range
to max_range
, then multiplying by scale_factor as follows:
result = round(min(max_range, max(min_range, input)) * scale_factor)
The adjusted min_range
and max_range
are returned as outputs 2 and 3 of this operation. These outputs should be used as the range for any further calculations.
narrow_range (bool) attribute
If true, we do not use the minimum quantized value. i.e. for int8 the quantized output, it would be restricted to the range -127..127 instead of the full -128..127 range. This is provided for compatibility with certain inference backends. (Only applies to SCALED mode)
axis (int) attribute
An optional axis
attribute can specify a dimension index of the input tensor, such that quantization ranges will be calculated and applied separately for each slice of the tensor along that dimension. This is useful for per-channel quantization.
If axis is specified, min_range and max_range
if axis
=None, per-tensor quantization is performed as normal.
ensure_minimum_range (float) attribute
Ensures the minimum quantization range is at least this value. The legacy default value for this is 0.01, but it is strongly suggested to set it to 0 for new uses.
Args | |
---|---|
input | A Tensor of type float32 . |
min_range | A Tensor of type float32 . The minimum value of the quantization range. This value may be adjusted by the op depending on other parameters. The adjusted value is written to output_min . If the axis attribute is specified, this must be a 1-D tensor whose size matches the axis dimension of the input and output tensors. |
max_range | A Tensor of type float32 . The maximum value of the quantization range. This value may be adjusted by the op depending on other parameters. The adjusted value is written to output_max . If the axis attribute is specified, this must be a 1-D tensor whose size matches the axis dimension of the input and output tensors. |
T | A tf.DType from: tf.qint8, tf.quint8, tf.qint32, tf.qint16, tf.quint16 . |
mode | An optional string from: "MIN_COMBINED", "MIN_FIRST", "SCALED" . Defaults to "MIN_COMBINED" . |
round_mode | An optional string from: "HALF_AWAY_FROM_ZERO", "HALF_TO_EVEN" . Defaults to "HALF_AWAY_FROM_ZERO" . |
narrow_range | An optional bool . Defaults to False . |
axis | An optional int . Defaults to -1 . |
ensure_minimum_range | An optional float . Defaults to 0.01 . |
name | A name for the operation (optional). |
Returns | |
---|---|
A tuple of Tensor objects (output, output_min, output_max). | |
output | A Tensor of type T . |
output_min | A Tensor of type float32 . |
output_max | A Tensor of type float32 . |
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Licensed under the Creative Commons Attribution License 3.0.
Code samples licensed under the Apache 2.0 License.
https://www.tensorflow.org/versions/r2.4/api_docs/python/tf/raw_ops/QuantizeV2