/* * Copyright (c) 2016, Alliance for Open Media. All rights reserved * * This source code is subject to the terms of the BSD 2 Clause License and * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License * was not distributed with this source code in the LICENSE file, you can * obtain it at www.aomedia.org/license/software. If the Alliance for Open * Media Patent License 1.0 was not distributed with this source code in the * PATENTS file, you can obtain it at www.aomedia.org/license/patent. */ #include #include #include #include "third_party/googletest/src/googletest/include/gtest/gtest.h" #include "./av1_rtcd.h" #include "./aom_dsp_rtcd.h" #include "test/acm_random.h" #include "test/av1_txfm_test.h" #include "test/clear_system_state.h" #include "test/register_state_check.h" #include "test/util.h" #include "av1/common/blockd.h" #include "av1/common/scan.h" #include "aom/aom_integer.h" #include "aom_dsp/inv_txfm.h" using libaom_test::ACMRandom; namespace { typedef void (*IdctFunc)(const tran_low_t *in, tran_low_t *out); class TransTestBase { public: virtual ~TransTestBase() {} protected: void RunInvAccuracyCheck() { tran_low_t input[64]; tran_low_t output[64]; double ref_input[64]; double ref_output[64]; ACMRandom rnd(ACMRandom::DeterministicSeed()); const int count_test_block = 5000; for (int ti = 0; ti < count_test_block; ++ti) { for (int ni = 0; ni < txfm_size_; ++ni) { input[ni] = rnd.Rand8() - rnd.Rand8(); ref_input[ni] = static_cast(input[ni]); } inv_txfm_(input, output); libaom_test::reference_idct_1d(ref_input, ref_output, txfm_size_); for (int ni = 0; ni < txfm_size_; ++ni) { EXPECT_LE( abs(output[ni] - static_cast(round(ref_output[ni]))), max_error_); } } } double max_error_; int txfm_size_; IdctFunc inv_txfm_; }; typedef std::tr1::tuple IdctParam; class AV1InvTxfm : public TransTestBase, public ::testing::TestWithParam { public: virtual void SetUp() { inv_txfm_ = GET_PARAM(0); txfm_size_ = GET_PARAM(1); max_error_ = GET_PARAM(2); } virtual void TearDown() {} }; TEST_P(AV1InvTxfm, RunInvAccuracyCheck) { RunInvAccuracyCheck(); } INSTANTIATE_TEST_CASE_P(C, AV1InvTxfm, ::testing::Values(IdctParam(&aom_idct4_c, 4, 1), IdctParam(&aom_idct8_c, 8, 2), IdctParam(&aom_idct16_c, 16, 4), IdctParam(&aom_idct32_c, 32, 6))); #if CONFIG_AV1_ENCODER typedef void (*FwdTxfmFunc)(const int16_t *in, tran_low_t *out, int stride); typedef void (*InvTxfmFunc)(const tran_low_t *in, uint8_t *out, int stride); typedef std::tr1::tuple PartialInvTxfmParam; #if !CONFIG_ADAPT_SCAN const int kMaxNumCoeffs = 1024; #endif class AV1PartialIDctTest : public ::testing::TestWithParam { public: virtual ~AV1PartialIDctTest() {} virtual void SetUp() { ftxfm_ = GET_PARAM(0); full_itxfm_ = GET_PARAM(1); partial_itxfm_ = GET_PARAM(2); tx_size_ = GET_PARAM(3); last_nonzero_ = GET_PARAM(4); } virtual void TearDown() { libaom_test::ClearSystemState(); } protected: int last_nonzero_; TX_SIZE tx_size_; FwdTxfmFunc ftxfm_; InvTxfmFunc full_itxfm_; InvTxfmFunc partial_itxfm_; }; #if !CONFIG_ADAPT_SCAN static MB_MODE_INFO get_mbmi() { MB_MODE_INFO mbmi; mbmi.ref_frame[0] = LAST_FRAME; assert(is_inter_block(&mbmi)); return mbmi; } TEST_P(AV1PartialIDctTest, RunQuantCheck) { int size; switch (tx_size_) { case TX_4X4: size = 4; break; case TX_8X8: size = 8; break; case TX_16X16: size = 16; break; case TX_32X32: size = 32; break; default: FAIL() << "Wrong Size!"; break; } DECLARE_ALIGNED(16, tran_low_t, test_coef_block1[kMaxNumCoeffs]); DECLARE_ALIGNED(16, tran_low_t, test_coef_block2[kMaxNumCoeffs]); DECLARE_ALIGNED(16, uint8_t, dst1[kMaxNumCoeffs]); DECLARE_ALIGNED(16, uint8_t, dst2[kMaxNumCoeffs]); const int count_test_block = 1000; const int block_size = size * size; DECLARE_ALIGNED(16, int16_t, input_extreme_block[kMaxNumCoeffs]); DECLARE_ALIGNED(16, tran_low_t, output_ref_block[kMaxNumCoeffs]); int max_error = 0; for (int m = 0; m < count_test_block; ++m) { // clear out destination buffer memset(dst1, 0, sizeof(*dst1) * block_size); memset(dst2, 0, sizeof(*dst2) * block_size); memset(test_coef_block1, 0, sizeof(*test_coef_block1) * block_size); memset(test_coef_block2, 0, sizeof(*test_coef_block2) * block_size); ACMRandom rnd(ACMRandom::DeterministicSeed()); for (int n = 0; n < count_test_block; ++n) { // Initialize a test block with input range [-255, 255]. if (n == 0) { for (int j = 0; j < block_size; ++j) input_extreme_block[j] = 255; } else if (n == 1) { for (int j = 0; j < block_size; ++j) input_extreme_block[j] = -255; } else { for (int j = 0; j < block_size; ++j) { input_extreme_block[j] = rnd.Rand8() % 2 ? 255 : -255; } } ftxfm_(input_extreme_block, output_ref_block, size); // quantization with maximum allowed step sizes test_coef_block1[0] = (output_ref_block[0] / 1336) * 1336; MB_MODE_INFO mbmi = get_mbmi(); for (int j = 1; j < last_nonzero_; ++j) test_coef_block1[get_scan((const AV1_COMMON *)NULL, tx_size_, DCT_DCT, &mbmi) ->scan[j]] = (output_ref_block[j] / 1828) * 1828; } ASM_REGISTER_STATE_CHECK(full_itxfm_(test_coef_block1, dst1, size)); ASM_REGISTER_STATE_CHECK(partial_itxfm_(test_coef_block1, dst2, size)); for (int j = 0; j < block_size; ++j) { const int diff = dst1[j] - dst2[j]; const int error = diff * diff; if (max_error < error) max_error = error; } } EXPECT_EQ(0, max_error) << "Error: partial inverse transform produces different results"; } TEST_P(AV1PartialIDctTest, ResultsMatch) { ACMRandom rnd(ACMRandom::DeterministicSeed()); int size; switch (tx_size_) { case TX_4X4: size = 4; break; case TX_8X8: size = 8; break; case TX_16X16: size = 16; break; case TX_32X32: size = 32; break; default: FAIL() << "Wrong Size!"; break; } DECLARE_ALIGNED(16, tran_low_t, test_coef_block1[kMaxNumCoeffs]); DECLARE_ALIGNED(16, tran_low_t, test_coef_block2[kMaxNumCoeffs]); DECLARE_ALIGNED(16, uint8_t, dst1[kMaxNumCoeffs]); DECLARE_ALIGNED(16, uint8_t, dst2[kMaxNumCoeffs]); const int count_test_block = 1000; const int max_coeff = 32766 / 4; const int block_size = size * size; int max_error = 0; for (int i = 0; i < count_test_block; ++i) { // clear out destination buffer memset(dst1, 0, sizeof(*dst1) * block_size); memset(dst2, 0, sizeof(*dst2) * block_size); memset(test_coef_block1, 0, sizeof(*test_coef_block1) * block_size); memset(test_coef_block2, 0, sizeof(*test_coef_block2) * block_size); int max_energy_leftover = max_coeff * max_coeff; for (int j = 0; j < last_nonzero_; ++j) { int16_t coef = static_cast(sqrt(1.0 * max_energy_leftover) * (rnd.Rand16() - 32768) / 65536); max_energy_leftover -= coef * coef; if (max_energy_leftover < 0) { max_energy_leftover = 0; coef = 0; } MB_MODE_INFO mbmi = get_mbmi(); test_coef_block1[get_scan((const AV1_COMMON *)NULL, tx_size_, DCT_DCT, &mbmi) ->scan[j]] = coef; } memcpy(test_coef_block2, test_coef_block1, sizeof(*test_coef_block2) * block_size); ASM_REGISTER_STATE_CHECK(full_itxfm_(test_coef_block1, dst1, size)); ASM_REGISTER_STATE_CHECK(partial_itxfm_(test_coef_block2, dst2, size)); for (int j = 0; j < block_size; ++j) { const int diff = dst1[j] - dst2[j]; const int error = diff * diff; if (max_error < error) max_error = error; } } EXPECT_EQ(0, max_error) << "Error: partial inverse transform produces different results"; } #endif using std::tr1::make_tuple; INSTANTIATE_TEST_CASE_P( C, AV1PartialIDctTest, ::testing::Values(make_tuple(&aom_fdct32x32_c, &aom_idct32x32_1024_add_c, &aom_idct32x32_34_add_c, TX_32X32, 34), make_tuple(&aom_fdct32x32_c, &aom_idct32x32_1024_add_c, &aom_idct32x32_1_add_c, TX_32X32, 1), make_tuple(&aom_fdct16x16_c, &aom_idct16x16_256_add_c, &aom_idct16x16_10_add_c, TX_16X16, 10), make_tuple(&aom_fdct16x16_c, &aom_idct16x16_256_add_c, &aom_idct16x16_1_add_c, TX_16X16, 1), make_tuple(&aom_fdct8x8_c, &aom_idct8x8_64_add_c, &aom_idct8x8_12_add_c, TX_8X8, 12), make_tuple(&aom_fdct8x8_c, &aom_idct8x8_64_add_c, &aom_idct8x8_1_add_c, TX_8X8, 1), make_tuple(&aom_fdct4x4_c, &aom_idct4x4_16_add_c, &aom_idct4x4_1_add_c, TX_4X4, 1))); #endif // CONFIG_AV1_ENCODER } // namespace