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// Copyright 2019 The libgav1 Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "src/dsp/intra_edge.h"
#include "src/utils/cpu.h"
#if LIBGAV1_ENABLE_NEON
#include <arm_neon.h>
#include <algorithm>
#include <cassert>
#include "src/dsp/arm/common_neon.h"
#include "src/dsp/constants.h"
#include "src/dsp/dsp.h"
#include "src/utils/common.h" // RightShiftWithRounding()
namespace libgav1 {
namespace dsp {
namespace {
// Simplified version of intra_edge.cc:kKernels[][]. Only |strength| 1 and 2 are
// required.
constexpr int kKernelsNEON[3][2] = {{4, 8}, {5, 6}};
void IntraEdgeFilter_NEON(void* buffer, const int size, const int strength) {
assert(strength == 1 || strength == 2 || strength == 3);
const int kernel_index = strength - 1;
auto* const dst_buffer = static_cast<uint8_t*>(buffer);
// The first element is not written out (but it is input) so the number of
// elements written is |size| - 1.
if (size == 1) return;
// |strength| 1 and 2 use a 3 tap filter.
if (strength < 3) {
// The last value requires extending the buffer (duplicating
// |dst_buffer[size - 1]). Calculate it here to avoid extra processing in
// neon.
const uint8_t last_val = RightShiftWithRounding(
kKernelsNEON[kernel_index][0] * dst_buffer[size - 2] +
kKernelsNEON[kernel_index][1] * dst_buffer[size - 1] +
kKernelsNEON[kernel_index][0] * dst_buffer[size - 1],
4);
const uint8x8_t krn1 = vdup_n_u8(kKernelsNEON[kernel_index][1]);
// The first value we need gets overwritten by the output from the
// previous iteration.
uint8x16_t src_0 = vld1q_u8(dst_buffer);
int i = 1;
// Process blocks until there are less than 16 values remaining.
for (; i < size - 15; i += 16) {
// Loading these at the end of the block with |src_0| will read past the
// end of |top_row_data[160]|, the source of |buffer|.
const uint8x16_t src_1 = vld1q_u8(dst_buffer + i);
const uint8x16_t src_2 = vld1q_u8(dst_buffer + i + 1);
uint16x8_t sum_lo = vaddl_u8(vget_low_u8(src_0), vget_low_u8(src_2));
sum_lo = vmulq_n_u16(sum_lo, kKernelsNEON[kernel_index][0]);
sum_lo = vmlal_u8(sum_lo, vget_low_u8(src_1), krn1);
uint16x8_t sum_hi = vaddl_u8(vget_high_u8(src_0), vget_high_u8(src_2));
sum_hi = vmulq_n_u16(sum_hi, kKernelsNEON[kernel_index][0]);
sum_hi = vmlal_u8(sum_hi, vget_high_u8(src_1), krn1);
const uint8x16_t result =
vcombine_u8(vrshrn_n_u16(sum_lo, 4), vrshrn_n_u16(sum_hi, 4));
// Load the next row before overwriting. This loads an extra 15 values
// past |size| on the trailing iteration.
src_0 = vld1q_u8(dst_buffer + i + 15);
vst1q_u8(dst_buffer + i, result);
}
// The last output value |last_val| was already calculated so if
// |remainder| == 1 then we don't have to do anything.
const int remainder = (size - 1) & 0xf;
if (remainder > 1) {
uint8_t temp[16];
const uint8x16_t src_1 = vld1q_u8(dst_buffer + i);
const uint8x16_t src_2 = vld1q_u8(dst_buffer + i + 1);
uint16x8_t sum_lo = vaddl_u8(vget_low_u8(src_0), vget_low_u8(src_2));
sum_lo = vmulq_n_u16(sum_lo, kKernelsNEON[kernel_index][0]);
sum_lo = vmlal_u8(sum_lo, vget_low_u8(src_1), krn1);
uint16x8_t sum_hi = vaddl_u8(vget_high_u8(src_0), vget_high_u8(src_2));
sum_hi = vmulq_n_u16(sum_hi, kKernelsNEON[kernel_index][0]);
sum_hi = vmlal_u8(sum_hi, vget_high_u8(src_1), krn1);
const uint8x16_t result =
vcombine_u8(vrshrn_n_u16(sum_lo, 4), vrshrn_n_u16(sum_hi, 4));
vst1q_u8(temp, result);
memcpy(dst_buffer + i, temp, remainder);
}
dst_buffer[size - 1] = last_val;
return;
}
assert(strength == 3);
// 5 tap filter. The first element requires duplicating |buffer[0]| and the
// last two elements require duplicating |buffer[size - 1]|.
uint8_t special_vals[3];
special_vals[0] = RightShiftWithRounding(
(dst_buffer[0] << 1) + (dst_buffer[0] << 2) + (dst_buffer[1] << 2) +
(dst_buffer[2] << 2) + (dst_buffer[3] << 1),
4);
// Clamp index for very small |size| values.
const int first_index_min = std::max(size - 4, 0);
const int second_index_min = std::max(size - 3, 0);
const int third_index_min = std::max(size - 2, 0);
special_vals[1] = RightShiftWithRounding(
(dst_buffer[first_index_min] << 1) + (dst_buffer[second_index_min] << 2) +
(dst_buffer[third_index_min] << 2) + (dst_buffer[size - 1] << 2) +
(dst_buffer[size - 1] << 1),
4);
special_vals[2] = RightShiftWithRounding(
(dst_buffer[second_index_min] << 1) + (dst_buffer[third_index_min] << 2) +
// x << 2 + x << 2 == x << 3
(dst_buffer[size - 1] << 3) + (dst_buffer[size - 1] << 1),
4);
// The first two values we need get overwritten by the output from the
// previous iteration.
uint8x16_t src_0 = vld1q_u8(dst_buffer - 1);
uint8x16_t src_1 = vld1q_u8(dst_buffer);
int i = 1;
for (; i < size - 15; i += 16) {
// Loading these at the end of the block with |src_[01]| will read past
// the end of |top_row_data[160]|, the source of |buffer|.
const uint8x16_t src_2 = vld1q_u8(dst_buffer + i);
const uint8x16_t src_3 = vld1q_u8(dst_buffer + i + 1);
const uint8x16_t src_4 = vld1q_u8(dst_buffer + i + 2);
uint16x8_t sum_lo =
vshlq_n_u16(vaddl_u8(vget_low_u8(src_0), vget_low_u8(src_4)), 1);
const uint16x8_t sum_123_lo = vaddw_u8(
vaddl_u8(vget_low_u8(src_1), vget_low_u8(src_2)), vget_low_u8(src_3));
sum_lo = vaddq_u16(sum_lo, vshlq_n_u16(sum_123_lo, 2));
uint16x8_t sum_hi =
vshlq_n_u16(vaddl_u8(vget_high_u8(src_0), vget_high_u8(src_4)), 1);
const uint16x8_t sum_123_hi =
vaddw_u8(vaddl_u8(vget_high_u8(src_1), vget_high_u8(src_2)),
vget_high_u8(src_3));
sum_hi = vaddq_u16(sum_hi, vshlq_n_u16(sum_123_hi, 2));
const uint8x16_t result =
vcombine_u8(vrshrn_n_u16(sum_lo, 4), vrshrn_n_u16(sum_hi, 4));
src_0 = vld1q_u8(dst_buffer + i + 14);
src_1 = vld1q_u8(dst_buffer + i + 15);
vst1q_u8(dst_buffer + i, result);
}
const int remainder = (size - 1) & 0xf;
// Like the 3 tap but if there are two remaining values we have already
// calculated them.
if (remainder > 2) {
uint8_t temp[16];
const uint8x16_t src_2 = vld1q_u8(dst_buffer + i);
const uint8x16_t src_3 = vld1q_u8(dst_buffer + i + 1);
const uint8x16_t src_4 = vld1q_u8(dst_buffer + i + 2);
uint16x8_t sum_lo =
vshlq_n_u16(vaddl_u8(vget_low_u8(src_0), vget_low_u8(src_4)), 1);
const uint16x8_t sum_123_lo = vaddw_u8(
vaddl_u8(vget_low_u8(src_1), vget_low_u8(src_2)), vget_low_u8(src_3));
sum_lo = vaddq_u16(sum_lo, vshlq_n_u16(sum_123_lo, 2));
uint16x8_t sum_hi =
vshlq_n_u16(vaddl_u8(vget_high_u8(src_0), vget_high_u8(src_4)), 1);
const uint16x8_t sum_123_hi =
vaddw_u8(vaddl_u8(vget_high_u8(src_1), vget_high_u8(src_2)),
vget_high_u8(src_3));
sum_hi = vaddq_u16(sum_hi, vshlq_n_u16(sum_123_hi, 2));
const uint8x16_t result =
vcombine_u8(vrshrn_n_u16(sum_lo, 4), vrshrn_n_u16(sum_hi, 4));
vst1q_u8(temp, result);
memcpy(dst_buffer + i, temp, remainder);
}
dst_buffer[1] = special_vals[0];
// Avoid overwriting |dst_buffer[0]|.
if (size > 2) dst_buffer[size - 2] = special_vals[1];
dst_buffer[size - 1] = special_vals[2];
}
// (-|src0| + |src1| * 9 + |src2| * 9 - |src3|) >> 4
uint8x8_t Upsample(const uint8x8_t src0, const uint8x8_t src1,
const uint8x8_t src2, const uint8x8_t src3) {
const uint16x8_t middle = vmulq_n_u16(vaddl_u8(src1, src2), 9);
const uint16x8_t ends = vaddl_u8(src0, src3);
const int16x8_t sum =
vsubq_s16(vreinterpretq_s16_u16(middle), vreinterpretq_s16_u16(ends));
return vqrshrun_n_s16(sum, 4);
}
void IntraEdgeUpsampler_NEON(void* buffer, const int size) {
assert(size % 4 == 0 && size <= 16);
auto* const pixel_buffer = static_cast<uint8_t*>(buffer);
// This is OK because we don't read this value for |size| 4 or 8 but if we
// write |pixel_buffer[size]| and then vld() it, that seems to introduce
// some latency.
pixel_buffer[-2] = pixel_buffer[-1];
if (size == 4) {
// This uses one load and two vtbl() which is better than 4x Load{Lo,Hi}4().
const uint8x8_t src = vld1_u8(pixel_buffer - 1);
// The outside values are negated so put those in the same vector.
const uint8x8_t src03 = vtbl1_u8(src, vcreate_u8(0x0404030202010000));
// Reverse |src1| and |src2| so we can use |src2| for the interleave at the
// end.
const uint8x8_t src21 = vtbl1_u8(src, vcreate_u8(0x0302010004030201));
const uint16x8_t middle = vmull_u8(src21, vdup_n_u8(9));
const int16x8_t half_sum = vsubq_s16(
vreinterpretq_s16_u16(middle), vreinterpretq_s16_u16(vmovl_u8(src03)));
const int16x4_t sum =
vadd_s16(vget_low_s16(half_sum), vget_high_s16(half_sum));
const uint8x8_t result = vqrshrun_n_s16(vcombine_s16(sum, sum), 4);
vst1_u8(pixel_buffer - 1, InterleaveLow8(result, src21));
return;
} else if (size == 8) {
// Likewise, one load + multiple vtbls seems preferred to multiple loads.
const uint8x16_t src = vld1q_u8(pixel_buffer - 1);
const uint8x8_t src0 = VQTbl1U8(src, vcreate_u8(0x0605040302010000));
const uint8x8_t src1 = vget_low_u8(src);
const uint8x8_t src2 = VQTbl1U8(src, vcreate_u8(0x0807060504030201));
const uint8x8_t src3 = VQTbl1U8(src, vcreate_u8(0x0808070605040302));
const uint8x8x2_t output = {Upsample(src0, src1, src2, src3), src2};
vst2_u8(pixel_buffer - 1, output);
return;
}
assert(size == 12 || size == 16);
// Extend the input borders to avoid branching later.
pixel_buffer[size] = pixel_buffer[size - 1];
const uint8x16_t src0 = vld1q_u8(pixel_buffer - 2);
const uint8x16_t src1 = vld1q_u8(pixel_buffer - 1);
const uint8x16_t src2 = vld1q_u8(pixel_buffer);
const uint8x16_t src3 = vld1q_u8(pixel_buffer + 1);
const uint8x8_t result_lo = Upsample(vget_low_u8(src0), vget_low_u8(src1),
vget_low_u8(src2), vget_low_u8(src3));
const uint8x8x2_t output_lo = {result_lo, vget_low_u8(src2)};
vst2_u8(pixel_buffer - 1, output_lo);
const uint8x8_t result_hi = Upsample(vget_high_u8(src0), vget_high_u8(src1),
vget_high_u8(src2), vget_high_u8(src3));
if (size == 12) {
vst1_u8(pixel_buffer + 15, InterleaveLow8(result_hi, vget_high_u8(src2)));
} else /* size == 16 */ {
const uint8x8x2_t output_hi = {result_hi, vget_high_u8(src2)};
vst2_u8(pixel_buffer + 15, output_hi);
}
}
void Init8bpp() {
Dsp* const dsp = dsp_internal::GetWritableDspTable(kBitdepth8);
assert(dsp != nullptr);
dsp->intra_edge_filter = IntraEdgeFilter_NEON;
dsp->intra_edge_upsampler = IntraEdgeUpsampler_NEON;
}
} // namespace
void IntraEdgeInit_NEON() { Init8bpp(); }
} // namespace dsp
} // namespace libgav1
#else // !LIBGAV1_ENABLE_NEON
namespace libgav1 {
namespace dsp {
void IntraEdgeInit_NEON() {}
} // namespace dsp
} // namespace libgav1
#endif // LIBGAV1_ENABLE_NEON
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