/* * Copyright (C) 2016 BlueKitchen GmbH * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the copyright holders nor the names of * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * 4. Any redistribution, use, or modification is done solely for * personal benefit and not for any commercial purpose or for * monetary gain. * * THIS SOFTWARE IS PROVIDED BY BLUEKITCHEN GMBH AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL BLUEKITCHEN * GMBH OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF * THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * Please inquire about commercial licensing options at * contact@bluekitchen-gmbh.com * */ #define BTSTACK_FILE__ "btstack_cvsd_plc.c" /* * btstack_CVSD_plc.c * */ #include #include #include #ifdef OCTAVE_OUTPUT #include #endif #include "btstack_cvsd_plc.h" #include "btstack_debug.h" // static float rcos[CVSD_OLAL] = { // 0.99148655f,0.96623611f,0.92510857f,0.86950446f, // 0.80131732f,0.72286918f,0.63683150f,0.54613418f, // 0.45386582f,0.36316850f,0.27713082f,0.19868268f, // 0.13049554f,0.07489143f,0.03376389f,0.00851345f}; static float rcos[CVSD_OLAL] = { 0.99148655f,0.92510857f, 0.80131732f,0.63683150f, 0.45386582f,0.27713082f, 0.13049554f,0.03376389f}; float btstack_cvsd_plc_rcos(int index){ if (index >= CVSD_OLAL) return 0; return rcos[index]; } // taken from http://www.codeproject.com/Articles/69941/Best-Square-Root-Method-Algorithm-Function-Precisi // Algorithm: Babylonian Method + some manipulations on IEEE 32 bit floating point representation static float sqrt3(const float x){ union { int i; float x; } u; u.x = x; u.i = (1<<29) + (u.i >> 1) - (1<<22); // Two Babylonian Steps (simplified from:) // u.x = 0.5f * (u.x + x/u.x); // u.x = 0.5f * (u.x + x/u.x); u.x = u.x + (x/u.x); u.x = (0.25f*u.x) + (x/u.x); return u.x; } static float btstack_cvsd_plc_absolute(float x){ if (x < 0) x = -x; return x; } static float btstack_cvsd_plc_cross_correlation(BTSTACK_CVSD_PLC_SAMPLE_FORMAT *x, BTSTACK_CVSD_PLC_SAMPLE_FORMAT *y){ float num = 0.f; float den = 0.f; float x2 = 0.f; float y2 = 0.f; int m; for (m=0;mmaxCn){ bestmatch=n; maxCn = Cn; } } return bestmatch; } float btstack_cvsd_plc_amplitude_match(btstack_cvsd_plc_state_t *plc_state, uint16_t num_samples, BTSTACK_CVSD_PLC_SAMPLE_FORMAT *y, BTSTACK_CVSD_PLC_SAMPLE_FORMAT bestmatch){ UNUSED(plc_state); int i; float sumx = 0.f; float sumy = 0.000001f; float sf; for (i=0;i1.f) sf=1.f; return sf; } BTSTACK_CVSD_PLC_SAMPLE_FORMAT btstack_cvsd_plc_crop_sample(float val){ float croped_val = val; if (croped_val > 32767.f) croped_val= 32767.f; if (croped_val < -32768.f) croped_val=-32768.f; return (BTSTACK_CVSD_PLC_SAMPLE_FORMAT) croped_val; } void btstack_cvsd_plc_init(btstack_cvsd_plc_state_t *plc_state){ memset(plc_state, 0, sizeof(btstack_cvsd_plc_state_t)); } #ifdef OCTAVE_OUTPUT typedef enum { OCTAVE_FRAME_TYPE_UNKNOWN = 0, OCTAVE_FRAME_TYPE_GOOD, OCTAVE_FRAME_TYPE_BAD } octave_frame_type_t; static const char * octave_frame_type_name[] = { "unknown", "good", "bad" }; static octave_frame_type_t octave_frame_type; static char octave_base_name[1000]; const char * octave_frame_type2str(int index){ if (index <= 0 || index >= sizeof(octave_frame_type_t)) return octave_frame_type_name[0]; return octave_frame_type_name[index]; } void btstack_cvsd_plc_octave_set_base_name(const char * base_name){ strcpy(octave_base_name, base_name); printf("OCTAVE: base name set to %s\n", octave_base_name); } static void octave_fprintf_array_int16(FILE * oct_file, char * name, int data_len, int16_t * data){ fprintf(oct_file, "%s = [", name); int i; for (i = 0; i < data_len - 1; i++){ fprintf(oct_file, "%d, ", data[i]); } fprintf(oct_file, "%d", data[i]); fprintf(oct_file, "%s", "];\n"); } static FILE * open_octave_file(btstack_cvsd_plc_state_t *plc_state, octave_frame_type_t frame_type){ char oct_file_name[1200]; octave_frame_type = frame_type; snprintf(oct_file_name, sizeof(oct_file_name), "%s_octave_plc_%d_%s.m", octave_base_name, plc_state->frame_count, octave_frame_type2str(octave_frame_type)); oct_file_name[sizeof(oct_file_name) - 1] = 0; FILE * oct_file = fopen(oct_file_name, "wb"); if (oct_file == NULL){ printf("OCTAVE: could not open file %s\n", oct_file_name); return NULL; } printf("OCTAVE: opened file %s\n", oct_file_name); return oct_file; } static void octave_fprintf_plot_history_frame(btstack_cvsd_plc_state_t *plc_state, FILE * oct_file, int frame_nr){ char title[100]; char hist_name[10]; snprintf(hist_name, sizeof(hist_name), "hist%d", plc_state->nbf); hist_name[sizeof(hist_name) - 1] = 0; octave_fprintf_array_int16(oct_file, hist_name, CVSD_LHIST, plc_state->hist); fprintf(oct_file, "y = [min(%s):1000:max(%s)];\n", hist_name, hist_name); fprintf(oct_file, "x = zeros(1, size(y,2));\n"); fprintf(oct_file, "b = [0: %d];\n", CVSD_LHIST+CVSD_FS+CVSD_RT+CVSD_OLAL); int pos = CVSD_FS; fprintf(oct_file, "shift_x = x + %d;\n", pos); pos = CVSD_LHIST - 1; fprintf(oct_file, "lhist_x = x + %d;\n", pos); pos += CVSD_OLAL; fprintf(oct_file, "lhist_olal1_x = x + %d;\n", pos); pos += CVSD_FS - CVSD_OLAL; fprintf(oct_file, "lhist_fs_x = x + %d;\n", pos); pos += CVSD_OLAL; fprintf(oct_file, "lhist_olal2_x = x + %d;\n", pos); pos += CVSD_RT; fprintf(oct_file, "lhist_rt_x = x + %d;\n", pos); fprintf(oct_file, "pattern_window_x = x + %d;\n", CVSD_LHIST - CVSD_M); fprintf(oct_file, "hf = figure();\n"); snprintf(title, sizeof(title), "PLC %s frame %d", octave_frame_type2str(octave_frame_type), frame_nr); title[sizeof(title) - 1] = 0; fprintf(oct_file, "hold on;\n"); fprintf(oct_file, "h1 = plot(%s); \n", hist_name); fprintf(oct_file, "title(\"%s\");\n", title); fprintf(oct_file, "plot(lhist_x, y, 'k'); \n"); fprintf(oct_file, "text(max(lhist_x) - 10, max(y)+1000, 'lhist'); \n"); fprintf(oct_file, "plot(lhist_olal1_x, y, 'k'); \n"); fprintf(oct_file, "text(max(lhist_olal1_x) - 10, max(y)+1000, 'OLAL'); \n"); fprintf(oct_file, "plot(lhist_fs_x, y, 'k'); \n"); fprintf(oct_file, "text(max(lhist_fs_x) - 10, max(y)+1000, 'FS'); \n"); fprintf(oct_file, "plot(lhist_olal2_x, y, 'k'); \n"); fprintf(oct_file, "text(max(lhist_olal2_x) - 10, max(y)+1000, 'OLAL'); \n"); fprintf(oct_file, "plot(lhist_rt_x, y, 'k');\n"); fprintf(oct_file, "text(max(lhist_rt_x) - 10, max(y)+1000, 'RT'); \n"); if (octave_frame_type == OCTAVE_FRAME_TYPE_GOOD) return; int x0 = plc_state->bestlag; int x1 = plc_state->bestlag + CVSD_M - 1; fprintf(oct_file, "plot(b(%d:%d), %s(%d:%d), 'rd'); \n", x0, x1, hist_name, x0, x1); fprintf(oct_file, "text(%d - 10, -10, 'bestlag'); \n", x0); x0 = plc_state->bestlag + CVSD_M ; x1 = plc_state->bestlag + CVSD_M + CVSD_FS - 1; fprintf(oct_file, "plot(b(%d:%d), %s(%d:%d), 'kd'); \n", x0, x1, hist_name, x0, x1); x0 = CVSD_LHIST - CVSD_M; x1 = CVSD_LHIST - 1; fprintf(oct_file, "plot(b(%d:%d), %s(%d:%d), 'rd'); \n", x0, x1, hist_name, x0, x1); fprintf(oct_file, "plot(pattern_window_x, y, 'g'); \n"); fprintf(oct_file, "text(max(pattern_window_x) - 10, max(y)+1000, 'M'); \n"); } static void octave_fprintf_plot_output(btstack_cvsd_plc_state_t *plc_state, FILE * oct_file){ if (!oct_file) return; char out_name[10]; snprintf(out_name, sizeof(out_name), "out%d", plc_state->nbf); out_name[sizeof(out_name) - 1] = 0; int x0 = CVSD_LHIST; int x1 = x0 + CVSD_FS - 1; octave_fprintf_array_int16(oct_file, out_name, CVSD_FS, plc_state->hist+x0); fprintf(oct_file, "h2 = plot(b(%d:%d), %s, 'cd'); \n", x0, x1, out_name); char rest_hist_name[10]; snprintf(rest_hist_name, sizeof(rest_hist_name), "rest%d", plc_state->nbf); rest_hist_name[sizeof(rest_hist_name) - 1] = 0; x0 = CVSD_LHIST + CVSD_FS; x1 = x0 + CVSD_OLAL + CVSD_RT - 1; octave_fprintf_array_int16(oct_file, rest_hist_name, CVSD_OLAL + CVSD_RT, plc_state->hist+x0); fprintf(oct_file, "h3 = plot(b(%d:%d), %s, 'kd'); \n", x0, x1, rest_hist_name); char new_hist_name[10]; snprintf(new_hist_name, sizeof(new_hist_name), "hist%d", plc_state->nbf); new_hist_name[sizeof(new_hist_name) - 1] = 0; octave_fprintf_array_int16(oct_file, new_hist_name, CVSD_LHIST, plc_state->hist); fprintf(oct_file, "h4 = plot(%s, 'r--'); \n", new_hist_name); fprintf(oct_file, "legend ([h1, h2, h3, h4], {\"hist\", \"out\", \"rest\", \"new hist\"}, \"location\", \"northeast\");\n "); char fig_name[1200]; snprintf(fig_name, sizeof(fig_name), "../%s_octave_plc_%d_%s", octave_base_name, plc_state->frame_count, octave_frame_type2str(octave_frame_type)); fig_name[sizeof(fig_name) - 1] = 0; fprintf(oct_file, "print(hf, \"%s.jpg\", \"-djpg\");", fig_name); } #endif void btstack_cvsd_plc_bad_frame(btstack_cvsd_plc_state_t *plc_state, uint16_t num_samples, BTSTACK_CVSD_PLC_SAMPLE_FORMAT *out){ float val; int i; float sf = 1; plc_state->nbf++; if (plc_state->max_consecutive_bad_frames_nr < plc_state->nbf){ plc_state->max_consecutive_bad_frames_nr = plc_state->nbf; } if (plc_state->nbf==1){ // printf("first bad frame\n"); // Perform pattern matching to find where to replicate plc_state->bestlag = btstack_cvsd_plc_pattern_match(plc_state->hist); } #ifdef OCTAVE_OUTPUT FILE * oct_file = open_octave_file(plc_state, OCTAVE_FRAME_TYPE_BAD); if (oct_file){ octave_fprintf_plot_history_frame(plc_state, oct_file, plc_state->frame_count); } #endif if (plc_state->nbf==1){ // the replication begins after the template match plc_state->bestlag += CVSD_M; // Compute Scale Factor to Match Amplitude of Substitution Packet to that of Preceding Packet sf = btstack_cvsd_plc_amplitude_match(plc_state, num_samples, plc_state->hist, plc_state->bestlag); for (i=0; ihist[plc_state->bestlag+i]; plc_state->hist[CVSD_LHIST+i] = btstack_cvsd_plc_crop_sample(val); } for (i=CVSD_OLAL; ihist[plc_state->bestlag+i]; plc_state->hist[CVSD_LHIST+i] = btstack_cvsd_plc_crop_sample(val); } for (i=num_samples; i<(num_samples+CVSD_OLAL); i++){ float left = sf*plc_state->hist[plc_state->bestlag+i]; float right = plc_state->hist[plc_state->bestlag+i]; val = (left*rcos[i-num_samples]) + (right*rcos[CVSD_OLAL-1-i+num_samples]); plc_state->hist[CVSD_LHIST+i] = btstack_cvsd_plc_crop_sample(val); } for (i=(num_samples+CVSD_OLAL); i<(num_samples+CVSD_RT+CVSD_OLAL); i++){ plc_state->hist[CVSD_LHIST+i] = plc_state->hist[plc_state->bestlag+i]; } } else { for (i=0; i<(num_samples+CVSD_RT+CVSD_OLAL); i++){ plc_state->hist[CVSD_LHIST+i] = plc_state->hist[plc_state->bestlag+i]; } } for (i=0; ihist[CVSD_LHIST+i]; } // shift the history buffer for (i=0; i<(CVSD_LHIST+CVSD_RT+CVSD_OLAL); i++){ plc_state->hist[i] = plc_state->hist[i+num_samples]; } #ifdef OCTAVE_OUTPUT if (oct_file){ octave_fprintf_plot_output(plc_state, oct_file); fclose(oct_file); } #endif } void btstack_cvsd_plc_good_frame(btstack_cvsd_plc_state_t *plc_state, uint16_t num_samples, BTSTACK_CVSD_PLC_SAMPLE_FORMAT *in, BTSTACK_CVSD_PLC_SAMPLE_FORMAT *out){ float val; int i = 0; #ifdef OCTAVE_OUTPUT FILE * oct_file = NULL; if (plc_state->nbf>0){ oct_file = open_octave_file(plc_state, OCTAVE_FRAME_TYPE_GOOD); if (oct_file){ octave_fprintf_plot_history_frame(plc_state, oct_file, plc_state->frame_count); } } #endif if (plc_state->nbf>0){ for (i=0;ihist[CVSD_LHIST+i]; } for (i=CVSD_RT;i<(CVSD_RT+CVSD_OLAL);i++){ float left = plc_state->hist[CVSD_LHIST+i]; float right = in[i]; val = (left * rcos[i-CVSD_RT]) + (right *rcos[CVSD_OLAL+CVSD_RT-1-i]); out[i] = btstack_cvsd_plc_crop_sample((BTSTACK_CVSD_PLC_SAMPLE_FORMAT)val); } } for (;ihist[CVSD_LHIST+i] = out[i]; } // shift the history buffer for (i=0;ihist[i] = plc_state->hist[i+num_samples]; } #ifdef OCTAVE_OUTPUT if (oct_file){ octave_fprintf_plot_output(plc_state, oct_file); fclose(oct_file); } #endif plc_state->nbf=0; } static int count_equal_samples(BTSTACK_CVSD_PLC_SAMPLE_FORMAT * packet, uint16_t size){ int count = 0; int temp_count = 1; int i; for (i = 0; i < (size-1); i++){ if (packet[i] == packet[i+1]){ temp_count++; continue; } if (count < temp_count){ count = temp_count; } temp_count = 1; } if (temp_count > (count + 1)){ count = temp_count; } return count; } static int count_zeros(BTSTACK_CVSD_PLC_SAMPLE_FORMAT * frame, uint16_t size){ int nr_zeros = 0; int i; for (i = 0; i < (size-1); i++){ if (frame[i] == 0){ nr_zeros++; } } return nr_zeros; } static int zero_frame(BTSTACK_CVSD_PLC_SAMPLE_FORMAT * frame, uint16_t size){ return count_zeros(frame, size) == size; } // more than half the samples are the same -> bad frame static int bad_frame(btstack_cvsd_plc_state_t *plc_state, BTSTACK_CVSD_PLC_SAMPLE_FORMAT * frame, uint16_t size){ UNUSED(plc_state); return count_equal_samples(frame, size) >= (size / 2); } void btstack_cvsd_plc_process_data(btstack_cvsd_plc_state_t * plc_state, bool is_bad_frame, BTSTACK_CVSD_PLC_SAMPLE_FORMAT * in, uint16_t num_samples, BTSTACK_CVSD_PLC_SAMPLE_FORMAT * out){ if (num_samples == 0) return; plc_state->frame_count++; if (!is_bad_frame) { bool is_zero_frame = zero_frame(in, num_samples); if (is_zero_frame){ plc_state->zero_frames_nr++; } else { is_bad_frame = bad_frame(plc_state, in, num_samples); } } if (is_bad_frame){ (void)memcpy(out, in, num_samples * 2); if (plc_state->good_samples > CVSD_LHIST){ btstack_cvsd_plc_bad_frame(plc_state, num_samples, out); plc_state->bad_frames_nr++; } else { memset(out, 0, num_samples * 2); } } else { btstack_cvsd_plc_good_frame(plc_state, num_samples, in, out); plc_state->good_frames_nr++; if (plc_state->good_frames_nr == 1){ log_info("First good frame at index %d\n", plc_state->frame_count-1); } plc_state->good_samples += num_samples; } } void btstack_cvsd_dump_statistics(btstack_cvsd_plc_state_t * state){ UNUSED(state); log_info("Good frames: %d\n", state->good_frames_nr); log_info("Bad frames: %d\n", state->bad_frames_nr); log_info("Zero frames: %d\n", state->zero_frames_nr); log_info("Max Consecutive bad frames: %d\n", state->max_consecutive_bad_frames_nr); }