db49a22cfa
googletest imports tuple into testing to allow for compatibility across c++ versions where tuple may be in std::tr1 or std. fixes deprecation warnings under visual studio 2017 Change-Id: Id78b372d5478b12d8c8f63fd3f2166fec25aa8be
578 lines
22 KiB
C++
578 lines
22 KiB
C++
/*
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* Copyright (c) 2014 The WebM project authors. All Rights Reserved.
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*
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* Use of this source code is governed by a BSD-style license
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* that can be found in the LICENSE file in the root of the source
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* tree. An additional intellectual property rights grant can be found
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* in the file PATENTS. All contributing project authors may
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* be found in the AUTHORS file in the root of the source tree.
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*/
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#include <math.h>
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#include <stdlib.h>
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#include <string.h>
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#include "third_party/googletest/src/include/gtest/gtest.h"
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#include "./vp9_rtcd.h"
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#include "./vpx_config.h"
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#include "./vpx_dsp_rtcd.h"
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#include "test/acm_random.h"
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#include "test/buffer.h"
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#include "test/clear_system_state.h"
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#include "test/register_state_check.h"
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#include "test/util.h"
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#include "vp9/common/vp9_entropy.h"
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#include "vp9/common/vp9_scan.h"
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#include "vpx/vpx_codec.h"
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#include "vpx/vpx_integer.h"
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#include "vpx_ports/vpx_timer.h"
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using libvpx_test::ACMRandom;
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using libvpx_test::Buffer;
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namespace {
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const int number_of_iterations = 100;
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typedef void (*QuantizeFunc)(const tran_low_t *coeff, intptr_t count,
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int skip_block, const int16_t *zbin,
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const int16_t *round, const int16_t *quant,
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const int16_t *quant_shift, tran_low_t *qcoeff,
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tran_low_t *dqcoeff, const int16_t *dequant,
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uint16_t *eob, const int16_t *scan,
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const int16_t *iscan);
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typedef ::testing::tuple<QuantizeFunc, QuantizeFunc, vpx_bit_depth_t,
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int /*max_size*/, bool /*is_fp*/>
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QuantizeParam;
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// Wrapper for FP version which does not use zbin or quant_shift.
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typedef void (*QuantizeFPFunc)(const tran_low_t *coeff, intptr_t count,
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int skip_block, const int16_t *round,
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const int16_t *quant, tran_low_t *qcoeff,
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tran_low_t *dqcoeff, const int16_t *dequant,
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uint16_t *eob, const int16_t *scan,
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const int16_t *iscan);
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template <QuantizeFPFunc fn>
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void QuantFPWrapper(const tran_low_t *coeff, intptr_t count, int skip_block,
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const int16_t *zbin, const int16_t *round,
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const int16_t *quant, const int16_t *quant_shift,
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tran_low_t *qcoeff, tran_low_t *dqcoeff,
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const int16_t *dequant, uint16_t *eob, const int16_t *scan,
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const int16_t *iscan) {
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(void)zbin;
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(void)quant_shift;
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fn(coeff, count, skip_block, round, quant, qcoeff, dqcoeff, dequant, eob,
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scan, iscan);
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}
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class VP9QuantizeBase {
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public:
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VP9QuantizeBase(vpx_bit_depth_t bit_depth, int max_size, bool is_fp)
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: bit_depth_(bit_depth), max_size_(max_size), is_fp_(is_fp) {
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max_value_ = (1 << bit_depth_) - 1;
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zbin_ptr_ =
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reinterpret_cast<int16_t *>(vpx_memalign(16, 8 * sizeof(*zbin_ptr_)));
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round_fp_ptr_ = reinterpret_cast<int16_t *>(
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vpx_memalign(16, 8 * sizeof(*round_fp_ptr_)));
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quant_fp_ptr_ = reinterpret_cast<int16_t *>(
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vpx_memalign(16, 8 * sizeof(*quant_fp_ptr_)));
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round_ptr_ =
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reinterpret_cast<int16_t *>(vpx_memalign(16, 8 * sizeof(*round_ptr_)));
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quant_ptr_ =
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reinterpret_cast<int16_t *>(vpx_memalign(16, 8 * sizeof(*quant_ptr_)));
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quant_shift_ptr_ = reinterpret_cast<int16_t *>(
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vpx_memalign(16, 8 * sizeof(*quant_shift_ptr_)));
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dequant_ptr_ = reinterpret_cast<int16_t *>(
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vpx_memalign(16, 8 * sizeof(*dequant_ptr_)));
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}
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~VP9QuantizeBase() {
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vpx_free(zbin_ptr_);
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vpx_free(round_fp_ptr_);
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vpx_free(quant_fp_ptr_);
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vpx_free(round_ptr_);
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vpx_free(quant_ptr_);
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vpx_free(quant_shift_ptr_);
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vpx_free(dequant_ptr_);
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zbin_ptr_ = NULL;
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round_fp_ptr_ = NULL;
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quant_fp_ptr_ = NULL;
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round_ptr_ = NULL;
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quant_ptr_ = NULL;
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quant_shift_ptr_ = NULL;
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dequant_ptr_ = NULL;
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libvpx_test::ClearSystemState();
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}
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protected:
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int16_t *zbin_ptr_;
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int16_t *round_fp_ptr_;
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int16_t *quant_fp_ptr_;
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int16_t *round_ptr_;
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int16_t *quant_ptr_;
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int16_t *quant_shift_ptr_;
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int16_t *dequant_ptr_;
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const vpx_bit_depth_t bit_depth_;
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int max_value_;
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const int max_size_;
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const bool is_fp_;
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};
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class VP9QuantizeTest : public VP9QuantizeBase,
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public ::testing::TestWithParam<QuantizeParam> {
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public:
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VP9QuantizeTest()
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: VP9QuantizeBase(GET_PARAM(2), GET_PARAM(3), GET_PARAM(4)),
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quantize_op_(GET_PARAM(0)), ref_quantize_op_(GET_PARAM(1)) {}
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protected:
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const QuantizeFunc quantize_op_;
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const QuantizeFunc ref_quantize_op_;
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};
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// This quantizer compares the AC coefficients to the quantization step size to
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// determine if further multiplication operations are needed.
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// Based on vp9_quantize_fp_sse2().
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inline void quant_fp_nz(const tran_low_t *coeff_ptr, intptr_t n_coeffs,
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int skip_block, const int16_t *round_ptr,
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const int16_t *quant_ptr, tran_low_t *qcoeff_ptr,
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tran_low_t *dqcoeff_ptr, const int16_t *dequant_ptr,
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uint16_t *eob_ptr, const int16_t *scan,
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const int16_t *iscan, int is_32x32) {
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int i, eob = -1;
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const int thr = dequant_ptr[1] >> (1 + is_32x32);
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(void)iscan;
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(void)skip_block;
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assert(!skip_block);
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// Quantization pass: All coefficients with index >= zero_flag are
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// skippable. Note: zero_flag can be zero.
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for (i = 0; i < n_coeffs; i += 16) {
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int y;
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int nzflag_cnt = 0;
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int abs_coeff[16];
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int coeff_sign[16];
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// count nzflag for each row (16 tran_low_t)
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for (y = 0; y < 16; ++y) {
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const int rc = i + y;
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const int coeff = coeff_ptr[rc];
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coeff_sign[y] = (coeff >> 31);
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abs_coeff[y] = (coeff ^ coeff_sign[y]) - coeff_sign[y];
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// The first 16 are skipped in the sse2 code. Do the same here to match.
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if (i >= 16 && (abs_coeff[y] <= thr)) {
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nzflag_cnt++;
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}
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}
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for (y = 0; y < 16; ++y) {
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const int rc = i + y;
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// If all of the AC coeffs in a row has magnitude less than the
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// quantization step_size/2, quantize to zero.
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if (nzflag_cnt < 16) {
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int tmp;
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int _round;
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if (is_32x32) {
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_round = ROUND_POWER_OF_TWO(round_ptr[rc != 0], 1);
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} else {
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_round = round_ptr[rc != 0];
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}
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tmp = clamp(abs_coeff[y] + _round, INT16_MIN, INT16_MAX);
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tmp = (tmp * quant_ptr[rc != 0]) >> (16 - is_32x32);
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qcoeff_ptr[rc] = (tmp ^ coeff_sign[y]) - coeff_sign[y];
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dqcoeff_ptr[rc] = qcoeff_ptr[rc] * dequant_ptr[rc != 0];
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if (is_32x32) {
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dqcoeff_ptr[rc] = qcoeff_ptr[rc] * dequant_ptr[rc != 0] / 2;
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} else {
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dqcoeff_ptr[rc] = qcoeff_ptr[rc] * dequant_ptr[rc != 0];
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}
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} else {
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qcoeff_ptr[rc] = 0;
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dqcoeff_ptr[rc] = 0;
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}
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}
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}
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// Scan for eob.
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for (i = 0; i < n_coeffs; i++) {
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// Use the scan order to find the correct eob.
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const int rc = scan[i];
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if (qcoeff_ptr[rc]) {
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eob = i;
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}
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}
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*eob_ptr = eob + 1;
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}
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void quantize_fp_nz_c(const tran_low_t *coeff_ptr, intptr_t n_coeffs,
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int skip_block, const int16_t *round_ptr,
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const int16_t *quant_ptr, tran_low_t *qcoeff_ptr,
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tran_low_t *dqcoeff_ptr, const int16_t *dequant_ptr,
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uint16_t *eob_ptr, const int16_t *scan,
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const int16_t *iscan) {
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quant_fp_nz(coeff_ptr, n_coeffs, skip_block, round_ptr, quant_ptr, qcoeff_ptr,
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dqcoeff_ptr, dequant_ptr, eob_ptr, scan, iscan, 0);
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}
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void quantize_fp_32x32_nz_c(const tran_low_t *coeff_ptr, intptr_t n_coeffs,
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int skip_block, const int16_t *round_ptr,
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const int16_t *quant_ptr, tran_low_t *qcoeff_ptr,
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tran_low_t *dqcoeff_ptr, const int16_t *dequant_ptr,
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uint16_t *eob_ptr, const int16_t *scan,
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const int16_t *iscan) {
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quant_fp_nz(coeff_ptr, n_coeffs, skip_block, round_ptr, quant_ptr, qcoeff_ptr,
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dqcoeff_ptr, dequant_ptr, eob_ptr, scan, iscan, 1);
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}
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void GenerateHelperArrays(ACMRandom *rnd, int16_t *zbin, int16_t *round,
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int16_t *quant, int16_t *quant_shift,
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int16_t *dequant, int16_t *round_fp,
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int16_t *quant_fp) {
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// Max when q == 0. Otherwise, it is 48 for Y and 42 for U/V.
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const int max_qrounding_factor_fp = 64;
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for (int j = 0; j < 2; j++) {
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// The range is 4 to 1828 in the VP9 tables.
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const int qlookup = rnd->RandRange(1825) + 4;
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round_fp[j] = (max_qrounding_factor_fp * qlookup) >> 7;
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quant_fp[j] = (1 << 16) / qlookup;
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// Values determined by deconstructing vp9_init_quantizer().
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// zbin may be up to 1143 for 8 and 10 bit Y values, or 1200 for 12 bit Y
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// values or U/V values of any bit depth. This is because y_delta is not
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// factored into the vp9_ac_quant() call.
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zbin[j] = rnd->RandRange(1200);
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// round may be up to 685 for Y values or 914 for U/V.
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round[j] = rnd->RandRange(914);
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// quant ranges from 1 to -32703
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quant[j] = static_cast<int>(rnd->RandRange(32704)) - 32703;
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// quant_shift goes up to 1 << 16.
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quant_shift[j] = rnd->RandRange(16384);
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// dequant maxes out at 1828 for all cases.
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dequant[j] = rnd->RandRange(1828);
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}
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for (int j = 2; j < 8; j++) {
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zbin[j] = zbin[1];
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round_fp[j] = round_fp[1];
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quant_fp[j] = quant_fp[1];
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round[j] = round[1];
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quant[j] = quant[1];
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quant_shift[j] = quant_shift[1];
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dequant[j] = dequant[1];
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}
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}
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TEST_P(VP9QuantizeTest, OperationCheck) {
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ACMRandom rnd(ACMRandom::DeterministicSeed());
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Buffer<tran_low_t> coeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 16);
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ASSERT_TRUE(coeff.Init());
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Buffer<tran_low_t> qcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(qcoeff.Init());
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Buffer<tran_low_t> dqcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(dqcoeff.Init());
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Buffer<tran_low_t> ref_qcoeff =
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Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(ref_qcoeff.Init());
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Buffer<tran_low_t> ref_dqcoeff =
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Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(ref_dqcoeff.Init());
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uint16_t eob, ref_eob;
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for (int i = 0; i < number_of_iterations; ++i) {
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// Test skip block for the first three iterations to catch all the different
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// sizes.
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const int skip_block = 0;
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TX_SIZE sz;
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if (max_size_ == 16) {
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sz = static_cast<TX_SIZE>(i % 3); // TX_4X4, TX_8X8 TX_16X16
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} else {
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sz = TX_32X32;
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}
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const TX_TYPE tx_type = static_cast<TX_TYPE>((i >> 2) % 3);
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const scan_order *scan_order = &vp9_scan_orders[sz][tx_type];
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const int count = (4 << sz) * (4 << sz);
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coeff.Set(&rnd, -max_value_, max_value_);
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GenerateHelperArrays(&rnd, zbin_ptr_, round_ptr_, quant_ptr_,
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quant_shift_ptr_, dequant_ptr_, round_fp_ptr_,
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quant_fp_ptr_);
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int16_t *r_ptr = (is_fp_) ? round_fp_ptr_ : round_ptr_;
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int16_t *q_ptr = (is_fp_) ? quant_fp_ptr_ : quant_ptr_;
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ref_quantize_op_(coeff.TopLeftPixel(), count, skip_block, zbin_ptr_, r_ptr,
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q_ptr, quant_shift_ptr_, ref_qcoeff.TopLeftPixel(),
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ref_dqcoeff.TopLeftPixel(), dequant_ptr_, &ref_eob,
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scan_order->scan, scan_order->iscan);
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ASM_REGISTER_STATE_CHECK(quantize_op_(
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coeff.TopLeftPixel(), count, skip_block, zbin_ptr_, r_ptr, q_ptr,
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quant_shift_ptr_, qcoeff.TopLeftPixel(), dqcoeff.TopLeftPixel(),
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dequant_ptr_, &eob, scan_order->scan, scan_order->iscan));
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EXPECT_TRUE(qcoeff.CheckValues(ref_qcoeff));
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EXPECT_TRUE(dqcoeff.CheckValues(ref_dqcoeff));
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EXPECT_EQ(eob, ref_eob);
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if (HasFailure()) {
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printf("Failure on iteration %d.\n", i);
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qcoeff.PrintDifference(ref_qcoeff);
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dqcoeff.PrintDifference(ref_dqcoeff);
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return;
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}
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}
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}
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TEST_P(VP9QuantizeTest, EOBCheck) {
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ACMRandom rnd(ACMRandom::DeterministicSeed());
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Buffer<tran_low_t> coeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 16);
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ASSERT_TRUE(coeff.Init());
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Buffer<tran_low_t> qcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(qcoeff.Init());
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Buffer<tran_low_t> dqcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(dqcoeff.Init());
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Buffer<tran_low_t> ref_qcoeff =
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Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(ref_qcoeff.Init());
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Buffer<tran_low_t> ref_dqcoeff =
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Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(ref_dqcoeff.Init());
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uint16_t eob, ref_eob;
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for (int i = 0; i < number_of_iterations; ++i) {
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const int skip_block = 0;
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TX_SIZE sz;
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if (max_size_ == 16) {
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sz = static_cast<TX_SIZE>(i % 3); // TX_4X4, TX_8X8 TX_16X16
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} else {
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sz = TX_32X32;
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}
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const TX_TYPE tx_type = static_cast<TX_TYPE>((i >> 2) % 3);
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const scan_order *scan_order = &vp9_scan_orders[sz][tx_type];
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int count = (4 << sz) * (4 << sz);
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// Two random entries
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coeff.Set(0);
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coeff.TopLeftPixel()[rnd(count)] =
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static_cast<int>(rnd.RandRange(max_value_ * 2)) - max_value_;
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coeff.TopLeftPixel()[rnd(count)] =
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static_cast<int>(rnd.RandRange(max_value_ * 2)) - max_value_;
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GenerateHelperArrays(&rnd, zbin_ptr_, round_ptr_, quant_ptr_,
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quant_shift_ptr_, dequant_ptr_, round_fp_ptr_,
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quant_fp_ptr_);
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int16_t *r_ptr = (is_fp_) ? round_fp_ptr_ : round_ptr_;
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int16_t *q_ptr = (is_fp_) ? quant_fp_ptr_ : quant_ptr_;
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ref_quantize_op_(coeff.TopLeftPixel(), count, skip_block, zbin_ptr_, r_ptr,
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q_ptr, quant_shift_ptr_, ref_qcoeff.TopLeftPixel(),
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ref_dqcoeff.TopLeftPixel(), dequant_ptr_, &ref_eob,
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scan_order->scan, scan_order->iscan);
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ASM_REGISTER_STATE_CHECK(quantize_op_(
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coeff.TopLeftPixel(), count, skip_block, zbin_ptr_, r_ptr, q_ptr,
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quant_shift_ptr_, qcoeff.TopLeftPixel(), dqcoeff.TopLeftPixel(),
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dequant_ptr_, &eob, scan_order->scan, scan_order->iscan));
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EXPECT_TRUE(qcoeff.CheckValues(ref_qcoeff));
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EXPECT_TRUE(dqcoeff.CheckValues(ref_dqcoeff));
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EXPECT_EQ(eob, ref_eob);
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if (HasFailure()) {
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printf("Failure on iteration %d.\n", i);
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qcoeff.PrintDifference(ref_qcoeff);
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dqcoeff.PrintDifference(ref_dqcoeff);
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return;
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}
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}
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}
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TEST_P(VP9QuantizeTest, DISABLED_Speed) {
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ACMRandom rnd(ACMRandom::DeterministicSeed());
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Buffer<tran_low_t> coeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 16);
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ASSERT_TRUE(coeff.Init());
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Buffer<tran_low_t> qcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(qcoeff.Init());
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Buffer<tran_low_t> dqcoeff = Buffer<tran_low_t>(max_size_, max_size_, 0, 32);
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ASSERT_TRUE(dqcoeff.Init());
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uint16_t eob;
|
|
TX_SIZE starting_sz, ending_sz;
|
|
|
|
if (max_size_ == 16) {
|
|
starting_sz = TX_4X4;
|
|
ending_sz = TX_16X16;
|
|
} else {
|
|
starting_sz = TX_32X32;
|
|
ending_sz = TX_32X32;
|
|
}
|
|
|
|
for (TX_SIZE sz = starting_sz; sz <= ending_sz; ++sz) {
|
|
// zbin > coeff, zbin < coeff.
|
|
for (int i = 0; i < 2; ++i) {
|
|
const int skip_block = 0;
|
|
// TX_TYPE defines the scan order. That is not relevant to the speed test.
|
|
// Pick the first one.
|
|
const TX_TYPE tx_type = DCT_DCT;
|
|
const scan_order *scan_order = &vp9_scan_orders[sz][tx_type];
|
|
const int count = (4 << sz) * (4 << sz);
|
|
|
|
GenerateHelperArrays(&rnd, zbin_ptr_, round_ptr_, quant_ptr_,
|
|
quant_shift_ptr_, dequant_ptr_, round_fp_ptr_,
|
|
quant_fp_ptr_);
|
|
int16_t *r_ptr = (is_fp_) ? round_fp_ptr_ : round_ptr_;
|
|
int16_t *q_ptr = (is_fp_) ? quant_fp_ptr_ : quant_ptr_;
|
|
|
|
if (i == 0) {
|
|
// When |coeff values| are less than zbin the results are 0.
|
|
int threshold = 100;
|
|
if (max_size_ == 32) {
|
|
// For 32x32, the threshold is halved. Double it to keep the values
|
|
// from clearing it.
|
|
threshold = 200;
|
|
}
|
|
for (int j = 0; j < 8; ++j) zbin_ptr_[j] = threshold;
|
|
coeff.Set(&rnd, -99, 99);
|
|
} else if (i == 1) {
|
|
for (int j = 0; j < 8; ++j) zbin_ptr_[j] = 50;
|
|
coeff.Set(&rnd, -500, 500);
|
|
}
|
|
|
|
vpx_usec_timer timer;
|
|
vpx_usec_timer_start(&timer);
|
|
for (int j = 0; j < 100000000 / count; ++j) {
|
|
quantize_op_(coeff.TopLeftPixel(), count, skip_block, zbin_ptr_, r_ptr,
|
|
q_ptr, quant_shift_ptr_, qcoeff.TopLeftPixel(),
|
|
dqcoeff.TopLeftPixel(), dequant_ptr_, &eob,
|
|
scan_order->scan, scan_order->iscan);
|
|
}
|
|
vpx_usec_timer_mark(&timer);
|
|
const int elapsed_time = static_cast<int>(vpx_usec_timer_elapsed(&timer));
|
|
if (i == 0) printf("Bypass calculations.\n");
|
|
if (i == 1) printf("Full calculations.\n");
|
|
printf("Quantize %dx%d time: %5d ms\n", 4 << sz, 4 << sz,
|
|
elapsed_time / 1000);
|
|
}
|
|
printf("\n");
|
|
}
|
|
}
|
|
|
|
using ::testing::make_tuple;
|
|
|
|
#if HAVE_SSE2
|
|
#if CONFIG_VP9_HIGHBITDEPTH
|
|
// TODO(johannkoenig): Fix vpx_quantize_b_sse2 in highbitdepth builds.
|
|
// make_tuple(&vpx_quantize_b_sse2, &vpx_highbd_quantize_b_c, VPX_BITS_8),
|
|
INSTANTIATE_TEST_CASE_P(
|
|
SSE2, VP9QuantizeTest,
|
|
::testing::Values(
|
|
make_tuple(&vpx_highbd_quantize_b_sse2, &vpx_highbd_quantize_b_c,
|
|
VPX_BITS_8, 16, false),
|
|
make_tuple(&vpx_highbd_quantize_b_sse2, &vpx_highbd_quantize_b_c,
|
|
VPX_BITS_10, 16, false),
|
|
make_tuple(&vpx_highbd_quantize_b_sse2, &vpx_highbd_quantize_b_c,
|
|
VPX_BITS_12, 16, false),
|
|
make_tuple(&vpx_highbd_quantize_b_32x32_sse2,
|
|
&vpx_highbd_quantize_b_32x32_c, VPX_BITS_8, 32, false),
|
|
make_tuple(&vpx_highbd_quantize_b_32x32_sse2,
|
|
&vpx_highbd_quantize_b_32x32_c, VPX_BITS_10, 32, false),
|
|
make_tuple(&vpx_highbd_quantize_b_32x32_sse2,
|
|
&vpx_highbd_quantize_b_32x32_c, VPX_BITS_12, 32, false)));
|
|
|
|
#else
|
|
INSTANTIATE_TEST_CASE_P(
|
|
SSE2, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&vpx_quantize_b_sse2, &vpx_quantize_b_c,
|
|
VPX_BITS_8, 16, false),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_sse2>,
|
|
&QuantFPWrapper<quantize_fp_nz_c>, VPX_BITS_8,
|
|
16, true)));
|
|
#endif // CONFIG_VP9_HIGHBITDEPTH
|
|
#endif // HAVE_SSE2
|
|
|
|
#if HAVE_SSSE3 && !CONFIG_VP9_HIGHBITDEPTH
|
|
#if ARCH_X86_64
|
|
INSTANTIATE_TEST_CASE_P(
|
|
SSSE3, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&vpx_quantize_b_ssse3, &vpx_quantize_b_c,
|
|
VPX_BITS_8, 16, false),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_ssse3>,
|
|
&QuantFPWrapper<quantize_fp_nz_c>, VPX_BITS_8,
|
|
16, true),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_32x32_ssse3>,
|
|
&QuantFPWrapper<quantize_fp_32x32_nz_c>,
|
|
VPX_BITS_8, 32, true)));
|
|
#else
|
|
INSTANTIATE_TEST_CASE_P(SSSE3, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&vpx_quantize_b_ssse3,
|
|
&vpx_quantize_b_c,
|
|
VPX_BITS_8, 16, false)));
|
|
#endif
|
|
|
|
#if ARCH_X86_64
|
|
// TODO(johannkoenig): SSSE3 optimizations do not yet pass this test.
|
|
INSTANTIATE_TEST_CASE_P(DISABLED_SSSE3, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(
|
|
&vpx_quantize_b_32x32_ssse3,
|
|
&vpx_quantize_b_32x32_c, VPX_BITS_8, 32, false)));
|
|
#endif // ARCH_X86_64
|
|
#endif // HAVE_SSSE3 && !CONFIG_VP9_HIGHBITDEPTH
|
|
|
|
// TODO(johannkoenig): AVX optimizations do not yet pass the 32x32 test or
|
|
// highbitdepth configurations.
|
|
#if HAVE_AVX && !CONFIG_VP9_HIGHBITDEPTH
|
|
INSTANTIATE_TEST_CASE_P(
|
|
AVX, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&vpx_quantize_b_avx, &vpx_quantize_b_c,
|
|
VPX_BITS_8, 16, false),
|
|
// Even though SSSE3 and AVX do not match the reference
|
|
// code, we can keep them in sync with each other.
|
|
make_tuple(&vpx_quantize_b_32x32_avx,
|
|
&vpx_quantize_b_32x32_ssse3, VPX_BITS_8, 32,
|
|
false)));
|
|
#endif // HAVE_AVX && !CONFIG_VP9_HIGHBITDEPTH
|
|
|
|
#if ARCH_X86_64 && HAVE_AVX2
|
|
INSTANTIATE_TEST_CASE_P(
|
|
AVX2, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&QuantFPWrapper<vp9_quantize_fp_avx2>,
|
|
&QuantFPWrapper<quantize_fp_nz_c>, VPX_BITS_8,
|
|
16, true)));
|
|
#endif // HAVE_AVX2 && !CONFIG_VP9_HIGHBITDEPTH
|
|
|
|
// TODO(webm:1448): dqcoeff is not handled correctly in HBD builds.
|
|
#if HAVE_NEON && !CONFIG_VP9_HIGHBITDEPTH
|
|
INSTANTIATE_TEST_CASE_P(
|
|
NEON, VP9QuantizeTest,
|
|
::testing::Values(make_tuple(&vpx_quantize_b_neon, &vpx_quantize_b_c,
|
|
VPX_BITS_8, 16, false),
|
|
make_tuple(&vpx_quantize_b_32x32_neon,
|
|
&vpx_quantize_b_32x32_c, VPX_BITS_8, 32,
|
|
false),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_neon>,
|
|
&QuantFPWrapper<vp9_quantize_fp_c>, VPX_BITS_8,
|
|
16, true),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_32x32_neon>,
|
|
&QuantFPWrapper<vp9_quantize_fp_32x32_c>,
|
|
VPX_BITS_8, 32, true)));
|
|
#endif // HAVE_NEON && !CONFIG_VP9_HIGHBITDEPTH
|
|
|
|
// Only useful to compare "Speed" test results.
|
|
INSTANTIATE_TEST_CASE_P(
|
|
DISABLED_C, VP9QuantizeTest,
|
|
::testing::Values(
|
|
make_tuple(&vpx_quantize_b_c, &vpx_quantize_b_c, VPX_BITS_8, 16, false),
|
|
make_tuple(&vpx_quantize_b_32x32_c, &vpx_quantize_b_32x32_c, VPX_BITS_8,
|
|
32, false),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_c>,
|
|
&QuantFPWrapper<vp9_quantize_fp_c>, VPX_BITS_8, 16, true),
|
|
make_tuple(&QuantFPWrapper<quantize_fp_nz_c>,
|
|
&QuantFPWrapper<quantize_fp_nz_c>, VPX_BITS_8, 16, true),
|
|
make_tuple(&QuantFPWrapper<quantize_fp_32x32_nz_c>,
|
|
&QuantFPWrapper<quantize_fp_32x32_nz_c>, VPX_BITS_8, 32,
|
|
true),
|
|
make_tuple(&QuantFPWrapper<vp9_quantize_fp_32x32_c>,
|
|
&QuantFPWrapper<vp9_quantize_fp_32x32_c>, VPX_BITS_8, 32,
|
|
true)));
|
|
} // namespace
|