// SPDX-License-Identifier: BSD-3-Clause // // Copyright(c) 2022 Intel Corporation. All rights reserved. // // Author: Adrian Bonislawski // Jyri Sarha (restructured and moved to this file) #include #include #include #include #include #include #include #include #include #include #include #include "wave.h" #define APP_NAME "sof-probes" #define PACKET_MAX_SIZE 4096 /**< Size limit for probe data packet */ #define DATA_READ_LIMIT 4096 /**< Data limit for file read */ #define FILES_LIMIT 32 /**< Maximum num of probe output files */ #define FILE_PATH_LIMIT 128 /**< Path limit for probe output files */ struct wave_files { FILE *fd; uint32_t buffer_id; uint32_t fmt; uint32_t size; struct wave header; }; enum p_state { READY = 0, /**< At this stage app is looking for a SYNC word */ SYNC, /**< SYNC received, copying data */ CHECK /**< Check crc and save packet if valid */ }; struct dma_frame_parser { bool log_to_stdout; enum p_state state; struct probe_data_packet *packet; size_t packet_size; uint8_t *w_ptr; /* Write pointer to copy data to */ uint32_t total_data_to_copy; /* Total bytes left to copy */ int start; /* Start of unfilled data */ int len; /* Data buffer fill level */ uint8_t data[DATA_READ_LIMIT]; struct wave_files files[FILES_LIMIT]; }; static uint32_t sample_rate[] = { 8000, 11025, 12000, 16000, 22050, 24000, 32000, 44100, 48000, 64000, 88200, 96000, 128000, 176400, 192000 }; int get_buffer_file(struct wave_files *files, uint32_t buffer_id) { int i; for (i = 0; i < FILES_LIMIT; i++) { if (files[i].fd != NULL && files[i].buffer_id == buffer_id) return i; } return -1; } int get_buffer_file_free(struct wave_files *files) { int i; for (i = 0; i < FILES_LIMIT; i++) { if (files[i].fd == NULL) return i; } return -1; } bool is_audio_format(uint32_t format) { return (format & PROBE_MASK_FMT_TYPE) != 0 && (format & PROBE_MASK_AUDIO_FMT) == 0; } int init_wave(struct dma_frame_parser *p, uint32_t buffer_id, uint32_t format) { bool audio = is_audio_format(format); char path[FILE_PATH_LIMIT]; int i; i = get_buffer_file_free(p->files); if (i == -1) { fprintf(stderr, "error: too many buffers\n"); exit(0); } sprintf(path, "buffer_%d.%s", buffer_id, audio ? "wav" : "bin"); fprintf(stderr, "%s:\t Creating file %s\n", APP_NAME, path); if (!audio && p->log_to_stdout) { p->files[i].fd = stdout; } else { p->files[i].fd = fopen(path, "wb"); if (!p->files[i].fd) { fprintf(stderr, "error: unable to create file %s, error %d\n", path, errno); exit(0); } } p->files[i].buffer_id = buffer_id; p->files[i].fmt = format; if (!audio) return i; p->files[i].header.riff.chunk_id = HEADER_RIFF; p->files[i].header.riff.format = HEADER_WAVE; p->files[i].header.fmt.subchunk_id = HEADER_FMT; p->files[i].header.fmt.subchunk_size = 16; p->files[i].header.fmt.audio_format = 1; p->files[i].header.fmt.num_channels = ((format & PROBE_MASK_NB_CHANNELS) >> PROBE_SHIFT_NB_CHANNELS) + 1; p->files[i].header.fmt.sample_rate = sample_rate[(format & PROBE_MASK_SAMPLE_RATE) >> PROBE_SHIFT_SAMPLE_RATE]; p->files[i].header.fmt.bits_per_sample = (((format & PROBE_MASK_CONTAINER_SIZE) >> PROBE_SHIFT_CONTAINER_SIZE) + 1) * 8; p->files[i].header.fmt.byte_rate = p->files[i].header.fmt.sample_rate * p->files[i].header.fmt.num_channels * p->files[i].header.fmt.bits_per_sample / 8; p->files[i].header.fmt.block_align = p->files[i].header.fmt.num_channels * p->files[i].header.fmt.bits_per_sample / 8; p->files[i].header.data.subchunk_id = HEADER_DATA; fwrite(&p->files[i].header, sizeof(struct wave), 1, p->files[i].fd); return i; } void finalize_wave_files(struct wave_files *files) { uint32_t i, chunk_size; /* fill the header at the beginning of each file */ /* and close all opened files */ /* check wave struct to understand the offsets */ for (i = 0; i < FILES_LIMIT; i++) { if (!is_audio_format(files[i].fmt)) continue; if (files[i].fd) { chunk_size = files[i].size + sizeof(struct wave) - offsetof(struct riff_chunk, format); fseek(files[i].fd, sizeof(uint32_t), SEEK_SET); fwrite(&chunk_size, sizeof(uint32_t), 1, files[i].fd); fseek(files[i].fd, sizeof(struct wave) - offsetof(struct data_subchunk, subchunk_size), SEEK_SET); fwrite(&files[i].size, sizeof(uint32_t), 1, files[i].fd); fclose(files[i].fd); } } } int validate_data_packet(struct probe_data_packet *packet) { uint64_t *checksump; uint64_t sum; sum = (uint32_t) (packet->sync_word + packet->buffer_id + packet->format + packet->timestamp_high + packet->timestamp_low + packet->data_size_bytes); checksump = (uint64_t *) (packet->data + packet->data_size_bytes); if (sum != *checksump) { fprintf(stderr, "Checksum error 0x%016" PRIx64 " != 0x%016" PRIx64 "\n", sum, *checksump); return -EINVAL; } return 0; } int process_sync(struct dma_frame_parser *p) { struct probe_data_packet *temp_packet; /* request to copy data_size from probe packet and 64-bit checksum */ p->total_data_to_copy = p->packet->data_size_bytes + sizeof(uint64_t); if (sizeof(struct probe_data_packet) + p->total_data_to_copy > p->packet_size) { p->packet_size = sizeof(struct probe_data_packet) + p->total_data_to_copy; temp_packet = realloc(p->packet, p->packet_size); if (!temp_packet) return -ENOMEM; p->packet = temp_packet; } p->w_ptr = (uint8_t *)p->packet->data; return 0; } struct dma_frame_parser *parser_init(void) { struct dma_frame_parser *p = malloc(sizeof(*p)); if (!p) { fprintf(stderr, "error: allocation failed, err %d\n", errno); return NULL; } memset(p, 0, sizeof(*p)); p->packet = malloc(PACKET_MAX_SIZE); if (!p) { fprintf(stderr, "error: allocation failed, err %d\n", errno); free(p); return NULL; } memset(p->packet, 0, PACKET_MAX_SIZE); p->packet_size = PACKET_MAX_SIZE; return p; } void parser_free(struct dma_frame_parser *p) { free(p->packet); free(p); } void parser_log_to_stdout(struct dma_frame_parser *p) { p->log_to_stdout = true; } void parser_fetch_free_buffer(struct dma_frame_parser *p, uint8_t **d, size_t *len) { *d = &p->data[p->start]; *len = sizeof(p->data) - p->start; } int parser_parse_data(struct dma_frame_parser *p, size_t d_len) { uint i = 0; p->len = p->start + d_len; /* processing all loaded bytes */ while (i < p->len) { if (p->total_data_to_copy == 0) { switch (p->state) { case READY: /* check for SYNC */ if (p->len - i < sizeof(p->packet->sync_word)) { p->start = p->len - i; memmove(&p->data[0], &p->data[i], p->start); i += p->start; } else if (*((uint32_t *)&p->data[i]) == PROBE_EXTRACT_SYNC_WORD) { memset(p->packet, 0, p->packet_size); /* request to copy full data packet */ p->total_data_to_copy = sizeof(struct probe_data_packet); p->w_ptr = (uint8_t *)p->packet; p->state = SYNC; p->start = 0; } else { i++; } break; case SYNC: /* SYNC -> CHECK */ if (process_sync(p) < 0) { fprintf(stderr, "OOM, quitting\n"); return -ENOMEM; } p->state = CHECK; break; case CHECK: /* CHECK -> READY */ /* find corresponding file and save data if valid */ if (validate_data_packet(p->packet) == 0) { int file = get_buffer_file(p->files, p->packet->buffer_id); if (file < 0) file = init_wave(p, p->packet->buffer_id, p->packet->format); if (file < 0) { fprintf(stderr, "unable to open file for %u\n", p->packet->buffer_id); return -EIO; } fwrite(p->packet->data, 1, p->packet->data_size_bytes, p->files[file].fd); p->files[file].size += p->packet->data_size_bytes; } p->state = READY; break; } } /* data copying section */ if (p->total_data_to_copy > 0) { uint data_to_copy; /* check if there is enough bytes loaded */ /* or copy partially if not */ if (i + p->total_data_to_copy > p->len) { data_to_copy = p->len - i; p->total_data_to_copy -= data_to_copy; } else { data_to_copy = p->total_data_to_copy; p->total_data_to_copy = 0; } memcpy(p->w_ptr, &p->data[i], data_to_copy); p->w_ptr += data_to_copy; i += data_to_copy; } } return 0; }