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// Copyright 2021 Google LLC
//
// This source code is licensed under the BSD-style license found in the
// LICENSE file in the root directory of this source tree.
$assert BATCH_TILE >= 1
#include <assert.h>
#include <math.h>
#include <xnnpack/common.h>
#include <xnnpack/math.h>
#include <xnnpack/vcvt.h>
void xnn_f32_f16_vcvt_ukernel__scalar_fabsf_x${BATCH_TILE}(
size_t batch,
const float* input,
void* output,
const union xnn_f32_f16_cvt_params params[restrict XNN_MIN_ELEMENTS(1)])
{
assert(batch != 0);
assert(batch % sizeof(float) == 0);
assert(input != NULL);
assert(output != NULL);
const float vscale_to_inf = params->scalar_fabsf.scale_to_inf;
const uint32_t vexp_bias = params->scalar_fabsf.exp_bias;
const float vscale_to_zero = params->scalar_fabsf.scale_to_zero;
const uint32_t vexpw_max = params->scalar_fabsf.expw_max;
const uint32_t vbias_min = params->scalar_fabsf.bias_min;
const uint16_t vexph_mask = params->scalar_fabsf.exph_mask;
const uint16_t vmanth_mask = params->scalar_fabsf.manth_mask;
const uint16_t vnanh = params->scalar_fabsf.nanh;
uint16_t* o = (uint16_t*) output;
$if BATCH_TILE == 1:
do {
const float vx = *input++;
const float vabsx = fabsf(vx);
uint32_t vsignw = float_as_uint32(vx);
const uint32_t vnonsignw = float_as_uint32(vabsx);
float vf = vabsx * vscale_to_inf;
uint32_t vbias = vnonsignw + vexp_bias;
vsignw ^= vnonsignw;
vf *= vscale_to_zero;
vbias &= vexpw_max;
vbias = math_max_u32(vbias, vbias_min);
vf += uint32_as_float(vbias);
const uint32_t vbits = float_as_uint32(vf);
const uint16_t vexph = (uint16_t) (vbits >> 13) & vexph_mask;
const uint16_t vmanth = (uint16_t) vbits & vmanth_mask;
const uint16_t vsignh = (uint16_t) (vsignw >> 16);
uint16_t vh = vexph + vmanth;
if XNN_UNPREDICTABLE(vnonsignw > vexpw_max) {
vh = vnanh;
}
vh |= vsignh;
*o++ = vh;
batch -= sizeof(float);
} while (batch != 0);
$else:
for (; batch >= ${BATCH_TILE} * sizeof(float); batch -= ${BATCH_TILE} * sizeof(float)) {
$for N in range(BATCH_TILE):
const float vx${N} = input[${N}];
input += ${BATCH_TILE};
$for N in range(BATCH_TILE):
const float vabsx${N} = fabsf(vx${N});
$for N in range(BATCH_TILE):
uint32_t vsignw${N} = float_as_uint32(vx${N});
$for N in range(BATCH_TILE):
const uint32_t vnonsignw${N} = float_as_uint32(vabsx${N});
$for N in range(BATCH_TILE):
float vf${N} = vabsx${N} * vscale_to_inf;
$for N in range(BATCH_TILE):
uint32_t vbias${N} = vnonsignw${N} + vexp_bias;
$for N in range(BATCH_TILE):
vsignw${N} ^= vnonsignw${N};
$for N in range(BATCH_TILE):
vf${N} *= vscale_to_zero;
$for N in range(BATCH_TILE):
vbias${N} &= vexpw_max;
$for N in range(BATCH_TILE):
vbias${N} = math_max_u32(vbias${N}, vbias_min);
$for N in range(BATCH_TILE):
vf${N} += uint32_as_float(vbias${N});
$for N in range(BATCH_TILE):
const uint32_t vbits${N} = float_as_uint32(vf${N});
$for N in range(BATCH_TILE):
const uint16_t vexph${N} = (uint16_t) (vbits${N} >> 13) & vexph_mask;
$for N in range(BATCH_TILE):
const uint16_t vmanth${N} = (uint16_t) vbits${N} & vmanth_mask;
$for N in range(BATCH_TILE):
const uint16_t vsignh${N} = (uint16_t) (vsignw${N} >> 16);
$for N in range(BATCH_TILE):
uint16_t vh${N} = vexph${N} + vmanth${N};
$for N in range(BATCH_TILE):
if XNN_UNPREDICTABLE(vnonsignw${N} > vexpw_max) {
vh${N} = vnanh;
}
$for N in range(BATCH_TILE):
vh${N} |= vsignh${N};
$for N in range(BATCH_TILE):
o[${N}] = vh${N};
o += ${BATCH_TILE};
}
$if BATCH_TILE == 2:
if XNN_UNLIKELY(batch != 0) {
const float vx = *input;
const float vabsx = fabsf(vx);
uint32_t vsignw = float_as_uint32(vx);
const uint32_t vnonsignw = float_as_uint32(vabsx);
float vf = vabsx * vscale_to_inf;
uint32_t vbias = vnonsignw + vexp_bias;
vsignw ^= vnonsignw;
vf *= vscale_to_zero;
vbias &= vexpw_max;
vbias = math_max_u32(vbias, vbias_min);
vf += uint32_as_float(vbias);
const uint32_t vbits = float_as_uint32(vf);
const uint16_t vexph = (uint16_t) (vbits >> 13) & vexph_mask;
const uint16_t vmanth = (uint16_t) vbits & vmanth_mask;
const uint16_t vsignh = (uint16_t) (vsignw >> 16);
uint16_t vh = vexph + vmanth;
if XNN_UNPREDICTABLE(vnonsignw > vexpw_max) {
vh = vnanh;
}
vh |= vsignh;
*o = vh;
}
$else:
if XNN_UNLIKELY(batch != 0) {
do {
const float vx = *input++;
const float vabsx = fabsf(vx);
uint32_t vsignw = float_as_uint32(vx);
const uint32_t vnonsignw = float_as_uint32(vabsx);
float vf = vabsx * vscale_to_inf;
uint32_t vbias = vnonsignw + vexp_bias;
vsignw ^= vnonsignw;
vf *= vscale_to_zero;
vbias &= vexpw_max;
vbias = math_max_u32(vbias, vbias_min);
vf += uint32_as_float(vbias);
const uint32_t vbits = float_as_uint32(vf);
const uint16_t vexph = (uint16_t) (vbits >> 13) & vexph_mask;
const uint16_t vmanth = (uint16_t) vbits & vmanth_mask;
const uint16_t vsignh = (uint16_t) (vsignw >> 16);
uint16_t vh = vexph + vmanth;
if XNN_UNPREDICTABLE(vnonsignw > vexpw_max) {
vh = vnanh;
}
vh |= vsignh;
*o++ = vh;
batch -= sizeof(float);
} while (batch != 0);
}
}
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