#include "MFCCF32.h" #include #include "Error.h" #include "mfccdata.h" #define SNR_THRESHOLD 115 /* Reference patterns are generated with a double precision computation. */ #define REL_ERROR (1.2e-3) void MFCCF32::test_mfcc_f32() { const float32_t *inp1=input1.ptr(); float32_t *tmpinp=tmpin.ptr(); float32_t *outp=output.ptr(); float32_t *tmpp=tmp.ptr(); memcpy((void*)tmpinp,(void*)inp1,sizeof(float32_t)*this->fftLen); arm_mfcc_f32(&mfcc,tmpinp,outp,tmpp); ASSERT_EMPTY_TAIL(output); ASSERT_SNR(output,ref,(float32_t)SNR_THRESHOLD); ASSERT_REL_ERROR(output,ref,REL_ERROR); } void MFCCF32::setUp(Testing::testID_t id,std::vector& params,Client::PatternMgr *mgr) { (void)params; Testing::nbSamples_t nb=MAX_NB_SAMPLES; switch(id) { case MFCCF32::TEST_MFCC_F32_1: { nb = 256; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_NOISE_256_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_NOISE_256_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config3_f32,mfcc_filter_len_config3_f32, mfcc_filter_coefs_config3_f32, mfcc_window_coefs_config3_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; case MFCCF32::TEST_MFCC_F32_2: { nb = 512; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_NOISE_512_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_NOISE_512_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config2_f32,mfcc_filter_len_config2_f32, mfcc_filter_coefs_config2_f32, mfcc_window_coefs_config2_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; case MFCCF32::TEST_MFCC_F32_3: { nb = 1024; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_NOISE_1024_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_NOISE_1024_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config1_f32,mfcc_filter_len_config1_f32, mfcc_filter_coefs_config1_f32, mfcc_window_coefs_config1_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; case MFCCF32::TEST_MFCC_F32_4: { nb = 256; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_SINE_256_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_SINE_256_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config3_f32,mfcc_filter_len_config3_f32, mfcc_filter_coefs_config3_f32, mfcc_window_coefs_config3_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; case MFCCF32::TEST_MFCC_F32_5: { nb = 512; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_SINE_512_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_SINE_512_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config2_f32,mfcc_filter_len_config2_f32, mfcc_filter_coefs_config2_f32, mfcc_window_coefs_config2_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; case MFCCF32::TEST_MFCC_F32_6: { nb = 1024; this->fftLen = nb; ref.reload(MFCCF32::REF_MFCC_SINE_1024_F32_ID,mgr,nb); input1.reload(MFCCF32::INPUTS_MFCC_SINE_1024_F32_ID,mgr,nb); arm_mfcc_init_f32(&mfcc, nb,20,13,mfcc_dct_coefs_config1_f32, mfcc_filter_pos_config1_f32,mfcc_filter_len_config1_f32, mfcc_filter_coefs_config1_f32, mfcc_window_coefs_config1_f32); tmp.create(2*nb,MFCCF32::TMP_MFCC_F32_ID,mgr); tmpin.create(nb,MFCCF32::TMPIN_MFCC_F32_ID,mgr); } break; } output.create(ref.nbSamples(),MFCCF32::OUTPUT_MFCC_F32_ID,mgr); } void MFCCF32::tearDown(Testing::testID_t id,Client::PatternMgr *mgr) { (void)id; (void)mgr; //output.dump(mgr); }