/* * Asterisk -- An open source telephony toolkit. * * Copyright (C) 1999 - 2006, Digium, Inc. * * Mark Spencer * * See http://www.asterisk.org for more information about * the Asterisk project. Please do not directly contact * any of the maintainers of this project for assistance; * the project provides a web site, mailing lists and IRC * channels for your use. * * This program is free software, distributed under the terms of * the GNU General Public License Version 2. See the LICENSE file * at the top of the source tree. */ /*! \file * * \brief Translate via the use of pseudo channels * * \author Mark Spencer */ #include "asterisk.h" ASTERISK_FILE_VERSION(__FILE__, "$Revision$") #include #include #include #include "asterisk/lock.h" #include "asterisk/channel.h" #include "asterisk/translate.h" #include "asterisk/module.h" #include "asterisk/frame.h" #include "asterisk/sched.h" #include "asterisk/cli.h" #include "asterisk/term.h" #define MAX_RECALC 1000 /* max sample recalc */ /*! \brief the list of translators */ static AST_RWLIST_HEAD_STATIC(translators, ast_translator); /*! \brief these values indicate how a translation path will affect the sample rate * * \note These must stay in this order. They are ordered by most optimal selection first. */ enum path_samp_change { RATE_CHANGE_NONE = 0, /*!< path uses the same sample rate consistently */ RATE_CHANGE_UPSAMP = 1, /*!< path will up the sample rate during a translation */ RATE_CHANGE_DOWNSAMP = 2, /*!< path will have to down the sample rate during a translation. */ RATE_CHANGE_UPSAMP_DOWNSAMP = 3, /*!< path will both up and down the sample rate during translation */ }; struct translator_path { struct ast_translator *step; /*!< Next step translator */ unsigned int cost; /*!< Complete cost to destination */ unsigned int multistep; /*!< Multiple conversions required for this translation */ enum path_samp_change rate_change; /*!< does this path require a sample rate change, if so what kind. */ }; /*! \brief a matrix that, for any pair of supported formats, * indicates the total cost of translation and the first step. * The full path can be reconstricted iterating on the matrix * until step->dstfmt == desired_format. * * Array indexes are 'src' and 'dest', in that order. * * Note: the lock in the 'translators' list is also used to protect * this structure. */ static struct translator_path tr_matrix[MAX_FORMAT][MAX_FORMAT]; /*! \todo * TODO: sample frames for each supported input format. * We build this on the fly, by taking an SLIN frame and using * the existing converter to play with it. */ /*! \brief returns the index of the lowest bit set */ static force_inline int powerof(format_t d) { int x = ffsll(d); if (x) return x - 1; ast_log(LOG_WARNING, "No bits set? %llu\n", (unsigned long long) d); return -1; } /* * wrappers around the translator routines. */ /*! * \brief Allocate the descriptor, required outbuf space, * and possibly desc. */ static void *newpvt(struct ast_translator *t) { struct ast_trans_pvt *pvt; int len; char *ofs; /* * compute the required size adding private descriptor, * buffer, AST_FRIENDLY_OFFSET. */ len = sizeof(*pvt) + t->desc_size; if (t->buf_size) len += AST_FRIENDLY_OFFSET + t->buf_size; pvt = ast_calloc(1, len); if (!pvt) return NULL; pvt->t = t; ofs = (char *)(pvt + 1); /* pointer to data space */ if (t->desc_size) { /* first comes the descriptor */ pvt->pvt = ofs; ofs += t->desc_size; } if (t->buf_size) /* finally buffer and header */ pvt->outbuf.c = ofs + AST_FRIENDLY_OFFSET; /* call local init routine, if present */ if (t->newpvt && t->newpvt(pvt)) { ast_free(pvt); return NULL; } ast_module_ref(t->module); return pvt; } static void destroy(struct ast_trans_pvt *pvt) { struct ast_translator *t = pvt->t; if (t->destroy) t->destroy(pvt); ast_free(pvt); ast_module_unref(t->module); } /*! \brief framein wrapper, deals with bound checks. */ static int framein(struct ast_trans_pvt *pvt, struct ast_frame *f) { int ret; int samples = pvt->samples; /* initial value */ /* Copy the last in jb timing info to the pvt */ ast_copy_flags(&pvt->f, f, AST_FRFLAG_HAS_TIMING_INFO); pvt->f.ts = f->ts; pvt->f.len = f->len; pvt->f.seqno = f->seqno; if (f->samples == 0) { ast_log(LOG_WARNING, "no samples for %s\n", pvt->t->name); } if (pvt->t->buffer_samples) { /* do not pass empty frames to callback */ if (f->datalen == 0) { /* perform native PLC if available */ /* If the codec has native PLC, then do that */ if (!pvt->t->native_plc) return 0; } if (pvt->samples + f->samples > pvt->t->buffer_samples) { ast_log(LOG_WARNING, "Out of buffer space\n"); return -1; } } /* we require a framein routine, wouldn't know how to do * it otherwise. */ ret = pvt->t->framein(pvt, f); /* diagnostic ... */ if (pvt->samples == samples) ast_log(LOG_WARNING, "%s did not update samples %d\n", pvt->t->name, pvt->samples); return ret; } /*! \brief generic frameout routine. * If samples and datalen are 0, take whatever is in pvt * and reset them, otherwise take the values in the caller and * leave alone the pvt values. */ struct ast_frame *ast_trans_frameout(struct ast_trans_pvt *pvt, int datalen, int samples) { struct ast_frame *f = &pvt->f; if (samples) f->samples = samples; else { if (pvt->samples == 0) return NULL; f->samples = pvt->samples; pvt->samples = 0; } if (datalen) f->datalen = datalen; else { f->datalen = pvt->datalen; pvt->datalen = 0; } f->frametype = AST_FRAME_VOICE; f->subclass.codec = 1LL << (pvt->t->dstfmt); f->mallocd = 0; f->offset = AST_FRIENDLY_OFFSET; f->src = pvt->t->name; f->data.ptr = pvt->outbuf.c; return ast_frisolate(f); } static struct ast_frame *default_frameout(struct ast_trans_pvt *pvt) { return ast_trans_frameout(pvt, 0, 0); } /* end of callback wrappers and helpers */ void ast_translator_free_path(struct ast_trans_pvt *p) { struct ast_trans_pvt *pn = p; while ( (p = pn) ) { pn = p->next; destroy(p); } } /*! \brief Build a chain of translators based upon the given source and dest formats */ struct ast_trans_pvt *ast_translator_build_path(format_t dest, format_t source) { struct ast_trans_pvt *head = NULL, *tail = NULL; source = powerof(source); dest = powerof(dest); if (source == -1 || dest == -1) { ast_log(LOG_WARNING, "No translator path: (%s codec is not valid)\n", source == -1 ? "starting" : "ending"); return NULL; } AST_RWLIST_RDLOCK(&translators); while (source != dest) { struct ast_trans_pvt *cur; struct ast_translator *t = tr_matrix[source][dest].step; if (!t) { ast_log(LOG_WARNING, "No translator path from %s to %s\n", ast_getformatname(source), ast_getformatname(dest)); AST_RWLIST_UNLOCK(&translators); return NULL; } if (!(cur = newpvt(t))) { ast_log(LOG_WARNING, "Failed to build translator step from %s to %s\n", ast_getformatname(source), ast_getformatname(dest)); if (head) ast_translator_free_path(head); AST_RWLIST_UNLOCK(&translators); return NULL; } if (!head) head = cur; else tail->next = cur; tail = cur; cur->nextin = cur->nextout = ast_tv(0, 0); /* Keep going if this isn't the final destination */ source = cur->t->dstfmt; } AST_RWLIST_UNLOCK(&translators); return head; } /*! \brief do the actual translation */ struct ast_frame *ast_translate(struct ast_trans_pvt *path, struct ast_frame *f, int consume) { struct ast_trans_pvt *p = path; struct ast_frame *out = f; struct timeval delivery; int has_timing_info; long ts; long len; int seqno; has_timing_info = ast_test_flag(f, AST_FRFLAG_HAS_TIMING_INFO); ts = f->ts; len = f->len; seqno = f->seqno; /* XXX hmmm... check this below */ if (!ast_tvzero(f->delivery)) { if (!ast_tvzero(path->nextin)) { /* Make sure this is in line with what we were expecting */ if (!ast_tveq(path->nextin, f->delivery)) { /* The time has changed between what we expected and this most recent time on the new packet. If we have a valid prediction adjust our output time appropriately */ if (!ast_tvzero(path->nextout)) { path->nextout = ast_tvadd(path->nextout, ast_tvsub(f->delivery, path->nextin)); } path->nextin = f->delivery; } } else { /* This is our first pass. Make sure the timing looks good */ path->nextin = f->delivery; path->nextout = f->delivery; } /* Predict next incoming sample */ path->nextin = ast_tvadd(path->nextin, ast_samp2tv(f->samples, ast_format_rate(f->subclass.codec))); } delivery = f->delivery; for ( ; out && p ; p = p->next) { framein(p, out); if (out != f) ast_frfree(out); out = p->t->frameout(p); } if (consume) ast_frfree(f); if (out == NULL) return NULL; /* we have a frame, play with times */ if (!ast_tvzero(delivery)) { /* Regenerate prediction after a discontinuity */ if (ast_tvzero(path->nextout)) path->nextout = ast_tvnow(); /* Use next predicted outgoing timestamp */ out->delivery = path->nextout; /* Predict next outgoing timestamp from samples in this frame. */ path->nextout = ast_tvadd(path->nextout, ast_samp2tv(out->samples, ast_format_rate(out->subclass.codec))); } else { out->delivery = ast_tv(0, 0); ast_set2_flag(out, has_timing_info, AST_FRFLAG_HAS_TIMING_INFO); if (has_timing_info) { out->ts = ts; out->len = len; out->seqno = seqno; } } /* Invalidate prediction if we're entering a silence period */ if (out->frametype == AST_FRAME_CNG) path->nextout = ast_tv(0, 0); return out; } /*! \brief compute the cost of a single translation step */ static void calc_cost(struct ast_translator *t, int seconds) { int num_samples = 0; struct ast_trans_pvt *pvt; struct rusage start; struct rusage end; int cost; int out_rate = ast_format_rate(t->dstfmt); if (!seconds) seconds = 1; /* If they don't make samples, give them a terrible score */ if (!t->sample) { ast_log(LOG_WARNING, "Translator '%s' does not produce sample frames.\n", t->name); t->cost = 999999; return; } pvt = newpvt(t); if (!pvt) { ast_log(LOG_WARNING, "Translator '%s' appears to be broken and will probably fail.\n", t->name); t->cost = 999999; return; } getrusage(RUSAGE_SELF, &start); /* Call the encoder until we've processed the required number of samples */ while (num_samples < seconds * out_rate) { struct ast_frame *f = t->sample(); if (!f) { ast_log(LOG_WARNING, "Translator '%s' failed to produce a sample frame.\n", t->name); destroy(pvt); t->cost = 999999; return; } framein(pvt, f); ast_frfree(f); while ((f = t->frameout(pvt))) { num_samples += f->samples; ast_frfree(f); } } getrusage(RUSAGE_SELF, &end); cost = ((end.ru_utime.tv_sec - start.ru_utime.tv_sec) * 1000000) + end.ru_utime.tv_usec - start.ru_utime.tv_usec; cost += ((end.ru_stime.tv_sec - start.ru_stime.tv_sec) * 1000000) + end.ru_stime.tv_usec - start.ru_stime.tv_usec; destroy(pvt); t->cost = cost / seconds; if (!t->cost) t->cost = 1; } static enum path_samp_change get_rate_change_result(format_t src, format_t dst) { int src_rate = ast_format_rate(src); int dst_rate = ast_format_rate(dst); /* if src rate is less than dst rate, a sample upgrade is required */ if (src_rate < dst_rate) { return RATE_CHANGE_UPSAMP; } /* if src rate is larger than dst rate, a downgrade is required */ if (src_rate > dst_rate) { return RATE_CHANGE_DOWNSAMP; } return RATE_CHANGE_NONE; } /*! * \brief rebuild a translation matrix. * \note This function expects the list of translators to be locked */ static void rebuild_matrix(int samples) { struct ast_translator *t; int new_rate_change; int newcost; int x; /* source format index */ int y; /* intermediate format index */ int z; /* destination format index */ ast_debug(1, "Resetting translation matrix\n"); memset(tr_matrix, '\0', sizeof(tr_matrix)); /* first, compute all direct costs */ AST_RWLIST_TRAVERSE(&translators, t, list) { if (!t->active) continue; x = t->srcfmt; z = t->dstfmt; if (samples) calc_cost(t, samples); new_rate_change = get_rate_change_result(1LL << t->srcfmt, 1LL << t->dstfmt); /* this translator is the best choice if any of the below are true. * 1. no translation path is set between x and z yet. * 2. the new translation costs less and sample rate is no worse than old one. * 3. the new translation has a better sample rate conversion than the old one. */ if (!tr_matrix[x][z].step || ((t->cost < tr_matrix[x][z].cost) && (new_rate_change <= tr_matrix[x][z].rate_change)) || (new_rate_change < tr_matrix[x][z].rate_change)) { tr_matrix[x][z].step = t; tr_matrix[x][z].cost = t->cost; tr_matrix[x][z].rate_change = new_rate_change; } } /* * For each triple x, y, z of distinct formats, check if there is * a path from x to z through y which is cheaper than what is * currently known, and in case, update the matrix. * Repeat until the matrix is stable. */ for (;;) { int changed = 0; int better_choice = 0; for (x = 0; x < MAX_FORMAT; x++) { /* source format */ for (y = 0; y < MAX_FORMAT; y++) { /* intermediate format */ if (x == y) /* skip ourselves */ continue; for (z = 0; z < MAX_FORMAT; z++) { /* dst format */ if (z == x || z == y) /* skip null conversions */ continue; if (!tr_matrix[x][y].step) /* no path from x to y */ continue; if (!tr_matrix[y][z].step) /* no path from y to z */ continue; /* Does x->y->z result in a less optimal sample rate change? * Never downgrade the sample rate conversion quality regardless * of any cost improvements */ if (tr_matrix[x][z].step && ((tr_matrix[x][z].rate_change < tr_matrix[x][y].rate_change) || (tr_matrix[x][z].rate_change < tr_matrix[y][z].rate_change))) { continue; } /* is x->y->z a better sample rate confersion that the current x->z? */ new_rate_change = tr_matrix[x][y].rate_change + tr_matrix[y][z].rate_change; /* calculate cost from x->y->z */ newcost = tr_matrix[x][y].cost + tr_matrix[y][z].cost; /* Is x->y->z a better choice than x->z? * There are three conditions for x->y->z to be a better choice than x->z * 1. if there is no step directly between x->z then x->y->z is the best and only current option. * 2. if x->y->z costs less and the sample rate conversion is no less optimal. * 3. if x->y->z results in a more optimal sample rate conversion. */ if (!tr_matrix[x][z].step) { better_choice = 1; } else if ((newcost < tr_matrix[x][z].cost) && (new_rate_change <= tr_matrix[x][z].rate_change)) { better_choice = 1; } else if (new_rate_change < tr_matrix[x][z].rate_change) { better_choice = 1; } else { better_choice = 0; } if (!better_choice) { continue; } /* ok, we can get from x to z via y with a cost that is the sum of the transition from x to y and from y to z */ tr_matrix[x][z].step = tr_matrix[x][y].step; tr_matrix[x][z].cost = newcost; tr_matrix[x][z].multistep = 1; /* now calculate what kind of sample rate change is required for this multi-step path * * if both paths require a change in rate, and they are not in the same direction * then this is a up sample down sample conversion scenario. */ if ((tr_matrix[x][y].rate_change > RATE_CHANGE_NONE) && (tr_matrix[y][z].rate_change > RATE_CHANGE_NONE) && (tr_matrix[x][y].rate_change != tr_matrix[y][z].rate_change)) { tr_matrix[x][z].rate_change = RATE_CHANGE_UPSAMP_DOWNSAMP; } else { /* else just set the rate change to whichever is worse */ tr_matrix[x][z].rate_change = tr_matrix[x][y].rate_change > tr_matrix[y][z].rate_change ? tr_matrix[x][y].rate_change : tr_matrix[y][z].rate_change; } ast_debug(3, "Discovered %d cost path from %s to %s, via %s\n", tr_matrix[x][z].cost, ast_getformatname(1LL << x), ast_getformatname(1LL << z), ast_getformatname(1LL << y)); changed++; } } } if (!changed) break; } } const char *ast_translate_path_to_str(struct ast_trans_pvt *p, struct ast_str **str) { struct ast_trans_pvt *pn = p; if (!p || !p->t) { return ""; } ast_str_set(str, 0, "%s", ast_getformatname(1LL << p->t->srcfmt)); while ( (p = pn) ) { pn = p->next; ast_str_append(str, 0, "->%s", ast_getformatname(1LL << p->t->dstfmt)); } return ast_str_buffer(*str); } static char *complete_trans_path_choice(const char *line, const char *word, int pos, int state) { int which = 0; int wordlen = strlen(word); int i; char *ret = NULL; size_t len = 0; const struct ast_format_list *format_list = ast_get_format_list(&len); for (i = 0; i < len; i++) { if (!(format_list[i].bits & AST_FORMAT_AUDIO_MASK)) { continue; } if (!strncasecmp(word, format_list[i].name, wordlen) && ++which > state) { ret = ast_strdup(format_list[i].name); break; } } return ret; } static char *handle_cli_core_show_translation(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a) { #define SHOW_TRANS 64 static const char * const option1[] = { "recalc", "paths", NULL }; int x, y, z; int curlen = 0, longest = 0, magnitude[SHOW_TRANS] = { 0, }; switch (cmd) { case CLI_INIT: e->command = "core show translation"; e->usage = "Usage: 'core show translation' can be used in two ways.\n" " 1. 'core show translation [recalc []]\n" " Displays known codec translators and the cost associated\n" " with each conversion. If the argument 'recalc' is supplied along\n" " with optional number of seconds to test a new test will be performed\n" " as the chart is being displayed.\n" " 2. 'core show translation paths [codec]'\n" " This will display all the translation paths associated with a codec\n"; return NULL; case CLI_GENERATE: if (a->pos == 3) { return ast_cli_complete(a->word, option1, a->n); } if (a->pos == 4 && !strcasecmp(a->argv[3], option1[1])) { return complete_trans_path_choice(a->line, a->word, a->pos, a->n); } return NULL; } if (a->argc > 5) return CLI_SHOWUSAGE; if (a->argv[3] && !strcasecmp(a->argv[3], option1[1]) && a->argc == 5) { format_t input_src = 0; format_t src = 0; size_t len = 0; int dst; int i; const struct ast_format_list *format_list = ast_get_format_list(&len); struct ast_str *str = ast_str_alloca(256); struct ast_translator *step; for (i = 0; i < len; i++) { if (!(format_list[i].bits & AST_FORMAT_AUDIO_MASK)) { continue; } if (!strncasecmp(format_list[i].name, a->argv[4], strlen(format_list[i].name))) { input_src = format_list[i].bits; } } if (!input_src) { ast_cli(a->fd, "Source codec \"%s\" is not found.\n", a->argv[4]); return CLI_FAILURE; } AST_RWLIST_RDLOCK(&translators); ast_cli(a->fd, "--- Translation paths SRC Codec \"%s\" sample rate %d ---\n", a->argv[4], ast_format_rate(input_src)); for (i = 0; i < len; i++) { if (!(format_list[i].bits & AST_FORMAT_AUDIO_MASK) || (format_list[i].bits == input_src)) { continue; } dst = powerof(format_list[i].bits); src = powerof(input_src); ast_str_reset(str); if (tr_matrix[src][dst].step) { ast_str_append(&str, 0, "%s", ast_getformatname(1LL << tr_matrix[src][dst].step->srcfmt)); while (src != dst) { step = tr_matrix[src][dst].step; if (!step) { ast_str_reset(str); break; } ast_str_append(&str, 0, "->%s", ast_getformatname(1LL << step->dstfmt)); src = step->dstfmt; } } if (ast_strlen_zero(ast_str_buffer(str))) { ast_str_set(&str, 0, "No Translation Path"); } ast_cli(a->fd, "\t%-10.10s To %-10.10s: %-60.60s\n", a->argv[4], format_list[i].name, ast_str_buffer(str)); } AST_RWLIST_UNLOCK(&translators); return CLI_SUCCESS; } else if (a->argv[3] && !strcasecmp(a->argv[3], "recalc")) { z = a->argv[4] ? atoi(a->argv[4]) : 1; if (z <= 0) { ast_cli(a->fd, " Recalc must be greater than 0. Defaulting to 1.\n"); z = 1; } if (z > MAX_RECALC) { ast_cli(a->fd, " Maximum limit of recalc exceeded by %d, truncating value to %d\n", z - MAX_RECALC, MAX_RECALC); z = MAX_RECALC; } ast_cli(a->fd, " Recalculating Codec Translation (number of sample seconds: %d)\n\n", z); AST_RWLIST_WRLOCK(&translators); rebuild_matrix(z); AST_RWLIST_UNLOCK(&translators); } else if (a->argc > 3) return CLI_SHOWUSAGE; AST_RWLIST_RDLOCK(&translators); ast_cli(a->fd, " Translation times between formats (in microseconds) for one second of data\n"); ast_cli(a->fd, " Source Format (Rows) Destination Format (Columns)\n\n"); /* Get the length of the longest (usable?) codec name, so we know how wide the left side should be */ for (x = 0; x < SHOW_TRANS; x++) { /* translation only applies to audio right now. */ if (!(AST_FORMAT_AUDIO_MASK & (1LL << (x)))) continue; curlen = strlen(ast_getformatname(1LL << (x))); if (curlen > longest) longest = curlen; for (y = 0; y < SHOW_TRANS; y++) { if (!(AST_FORMAT_AUDIO_MASK & (1LL << (y)))) continue; if (tr_matrix[x][y].cost > pow(10, magnitude[x])) { magnitude[y] = floor(log10(tr_matrix[x][y].cost)); } } } for (x = -1; x < SHOW_TRANS; x++) { struct ast_str *out = ast_str_alloca(256); /* translation only applies to audio right now. */ if (x >= 0 && !(AST_FORMAT_AUDIO_MASK & (1LL << (x)))) continue; /*Go ahead and move to next iteration if dealing with an unknown codec*/ if(x >= 0 && !strcmp(ast_getformatname(1LL << (x)), "unknown")) continue; ast_str_set(&out, -1, " "); for (y = -1; y < SHOW_TRANS; y++) { /* translation only applies to audio right now. */ if (y >= 0 && !(AST_FORMAT_AUDIO_MASK & (1LL << (y)))) continue; /*Go ahead and move to next iteration if dealing with an unknown codec*/ if (y >= 0 && !strcmp(ast_getformatname(1LL << (y)), "unknown")) continue; if (y >= 0) curlen = strlen(ast_getformatname(1LL << (y))); if (y >= 0 && magnitude[y] + 1 > curlen) { curlen = magnitude[y] + 1; } if (curlen < 5) curlen = 5; if (x >= 0 && y >= 0 && tr_matrix[x][y].step) { /* Actual codec output */ ast_str_append(&out, -1, "%*d", curlen + 1, tr_matrix[x][y].cost); } else if (x == -1 && y >= 0) { /* Top row - use a dynamic size */ ast_str_append(&out, -1, "%*s", curlen + 1, ast_getformatname(1LL << (y)) ); } else if (y == -1 && x >= 0) { /* Left column - use a static size. */ ast_str_append(&out, -1, "%*s", longest, ast_getformatname(1LL << (x)) ); } else if (x >= 0 && y >= 0) { /* Codec not supported */ ast_str_append(&out, -1, "%*s", curlen + 1, "-"); } else { /* Upper left hand corner */ ast_str_append(&out, -1, "%*s", longest, ""); } } ast_str_append(&out, -1, "\n"); ast_cli(a->fd, "%s", ast_str_buffer(out)); } AST_RWLIST_UNLOCK(&translators); return CLI_SUCCESS; } static struct ast_cli_entry cli_translate[] = { AST_CLI_DEFINE(handle_cli_core_show_translation, "Display translation matrix") }; /*! \brief register codec translator */ int __ast_register_translator(struct ast_translator *t, struct ast_module *mod) { static int added_cli = 0; struct ast_translator *u; char tmp[80]; if (!mod) { ast_log(LOG_WARNING, "Missing module pointer, you need to supply one\n"); return -1; } if (!t->buf_size) { ast_log(LOG_WARNING, "empty buf size, you need to supply one\n"); return -1; } t->module = mod; t->srcfmt = powerof(t->srcfmt); t->dstfmt = powerof(t->dstfmt); t->active = 1; if (t->srcfmt == -1 || t->dstfmt == -1) { ast_log(LOG_WARNING, "Invalid translator path: (%s codec is not valid)\n", t->srcfmt == -1 ? "starting" : "ending"); return -1; } if (t->srcfmt >= MAX_FORMAT) { ast_log(LOG_WARNING, "Source format %s is larger than MAX_FORMAT\n", ast_getformatname(t->srcfmt)); return -1; } if (t->dstfmt >= MAX_FORMAT) { ast_log(LOG_WARNING, "Destination format %s is larger than MAX_FORMAT\n", ast_getformatname(t->dstfmt)); return -1; } if (t->buf_size) { /* * Align buf_size properly, rounding up to the machine-specific * alignment for pointers. */ struct _test_align { void *a, *b; } p; int align = (char *)&p.b - (char *)&p.a; t->buf_size = ((t->buf_size + align - 1) / align) * align; } if (t->frameout == NULL) t->frameout = default_frameout; calc_cost(t, 1); ast_verb(2, "Registered translator '%s' from format %s to %s, cost %d\n", term_color(tmp, t->name, COLOR_MAGENTA, COLOR_BLACK, sizeof(tmp)), ast_getformatname(1LL << t->srcfmt), ast_getformatname(1LL << t->dstfmt), t->cost); if (!added_cli) { ast_cli_register_multiple(cli_translate, ARRAY_LEN(cli_translate)); added_cli++; } AST_RWLIST_WRLOCK(&translators); /* find any existing translators that provide this same srcfmt/dstfmt, and put this one in order based on cost */ AST_RWLIST_TRAVERSE_SAFE_BEGIN(&translators, u, list) { if ((u->srcfmt == t->srcfmt) && (u->dstfmt == t->dstfmt) && (u->cost > t->cost)) { AST_RWLIST_INSERT_BEFORE_CURRENT(t, list); t = NULL; break; } } AST_RWLIST_TRAVERSE_SAFE_END; /* if no existing translator was found for this format combination, add it to the beginning of the list */ if (t) AST_RWLIST_INSERT_HEAD(&translators, t, list); rebuild_matrix(0); AST_RWLIST_UNLOCK(&translators); return 0; } /*! \brief unregister codec translator */ int ast_unregister_translator(struct ast_translator *t) { char tmp[80]; struct ast_translator *u; int found = 0; AST_RWLIST_WRLOCK(&translators); AST_RWLIST_TRAVERSE_SAFE_BEGIN(&translators, u, list) { if (u == t) { AST_RWLIST_REMOVE_CURRENT(list); ast_verb(2, "Unregistered translator '%s' from format %s to %s\n", term_color(tmp, t->name, COLOR_MAGENTA, COLOR_BLACK, sizeof(tmp)), ast_getformatname(1LL << t->srcfmt), ast_getformatname(1LL << t->dstfmt)); found = 1; break; } } AST_RWLIST_TRAVERSE_SAFE_END; if (found) rebuild_matrix(0); AST_RWLIST_UNLOCK(&translators); return (u ? 0 : -1); } void ast_translator_activate(struct ast_translator *t) { AST_RWLIST_WRLOCK(&translators); t->active = 1; rebuild_matrix(0); AST_RWLIST_UNLOCK(&translators); } void ast_translator_deactivate(struct ast_translator *t) { AST_RWLIST_WRLOCK(&translators); t->active = 0; rebuild_matrix(0); AST_RWLIST_UNLOCK(&translators); } /*! \brief Calculate our best translator source format, given costs, and a desired destination */ format_t ast_translator_best_choice(format_t *dst, format_t *srcs) { int x,y; int better = 0; int besttime = INT_MAX; int beststeps = INT_MAX; unsigned int best_rate_change = INT_MAX; format_t best = -1; format_t bestdst = 0; format_t cur, cursrc; format_t common = ((*dst) & (*srcs)) & AST_FORMAT_AUDIO_MASK; /* are there common formats ? */ if (common) { /* yes, pick one and return */ for (cur = 1, y = 0; y <= MAX_AUDIO_FORMAT; cur <<= 1, y++) { if (!(cur & common)) { continue; } /* We are guaranteed to find one common format. */ if (best == -1) { best = cur; continue; } /* If there are multiple common formats, pick the one with the highest sample rate */ if (ast_format_rate(best) < ast_format_rate(cur)) { best = cur; continue; } } /* We are done, this is a common format to both. */ *srcs = *dst = best; return 0; } else { /* No, we will need to translate */ AST_RWLIST_RDLOCK(&translators); for (cur = 1, y = 0; y <= MAX_AUDIO_FORMAT; cur <<= 1, y++) { if (! (cur & *dst)) { continue; } for (cursrc = 1, x = 0; x <= MAX_AUDIO_FORMAT; cursrc <<= 1, x++) { if (!(*srcs & cursrc) || !tr_matrix[x][y].step) { continue; } /* This is a better choice if any of the following are true. * 1. The sample rate conversion is better than the current pick. * 2. the sample rate conversion is no worse than the current pick and the cost or multistep is better */ better = 0; if (tr_matrix[x][y].rate_change < best_rate_change) { better = 1; /* this match has a better rate conversion */ } if ((tr_matrix[x][y].rate_change <= best_rate_change) && (tr_matrix[x][y].cost < besttime || tr_matrix[x][y].multistep < beststeps)) { better = 1; /* this match has no worse rate conversion and the conversion cost is less */ } if (better) { /* better than what we have so far */ best = cursrc; bestdst = cur; besttime = tr_matrix[x][y].cost; beststeps = tr_matrix[x][y].multistep; best_rate_change = tr_matrix[x][y].rate_change; } } } AST_RWLIST_UNLOCK(&translators); if (best > -1) { *srcs = best; *dst = bestdst; best = 0; } return best; } } unsigned int ast_translate_path_steps(format_t dest, format_t src) { unsigned int res = -1; /* convert bitwise format numbers into array indices */ src = powerof(src); dest = powerof(dest); if (src == -1 || dest == -1) { ast_log(LOG_WARNING, "No translator path: (%s codec is not valid)\n", src == -1 ? "starting" : "ending"); return -1; } AST_RWLIST_RDLOCK(&translators); if (tr_matrix[src][dest].step) res = tr_matrix[src][dest].multistep + 1; AST_RWLIST_UNLOCK(&translators); return res; } format_t ast_translate_available_formats(format_t dest, format_t src) { format_t res = dest; format_t x; format_t src_audio = src & AST_FORMAT_AUDIO_MASK; format_t src_video = src & AST_FORMAT_VIDEO_MASK; /* if we don't have a source format, we just have to try all possible destination formats */ if (!src) return dest; /* If we have a source audio format, get its format index */ if (src_audio) src_audio = powerof(src_audio); /* If we have a source video format, get its format index */ if (src_video) src_video = powerof(src_video); AST_RWLIST_RDLOCK(&translators); /* For a given source audio format, traverse the list of known audio formats to determine whether there exists a translation path from the source format to the destination format. */ for (x = 1LL; src_audio && x > 0; x <<= 1) { if (!(x & AST_FORMAT_AUDIO_MASK)) { continue; } /* if this is not a desired format, nothing to do */ if (!(dest & x)) continue; /* if the source is supplying this format, then we can leave it in the result */ if (src & x) continue; /* if we don't have a translation path from the src to this format, remove it from the result */ if (!tr_matrix[src_audio][powerof(x)].step) { res &= ~x; continue; } /* now check the opposite direction */ if (!tr_matrix[powerof(x)][src_audio].step) res &= ~x; } /* For a given source video format, traverse the list of known video formats to determine whether there exists a translation path from the source format to the destination format. */ for (x = 1LL; src_video && x > 0; x <<= 1) { if (!(x & AST_FORMAT_VIDEO_MASK)) { continue; } /* if this is not a desired format, nothing to do */ if (!(dest & x)) continue; /* if the source is supplying this format, then we can leave it in the result */ if (src & x) continue; /* if we don't have a translation path from the src to this format, remove it from the result */ if (!tr_matrix[src_video][powerof(x)].step) { res &= ~x; continue; } /* now check the opposite direction */ if (!tr_matrix[powerof(x)][src_video].step) res &= ~x; } AST_RWLIST_UNLOCK(&translators); return res; }