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author | Moonchild <moonchild@palemoon.org> | 2020-05-20 10:19:04 +0000 |
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committer | Moonchild <moonchild@palemoon.org> | 2020-05-20 14:04:17 +0000 |
commit | 99c2e698d2a3c56649e42d8d2133706cd8c9501e (patch) | |
tree | 85be449d772eb57860f0f386efb4bc1e790fd498 /media/pocketsphinx/src/fsg_lextree.c | |
parent | 15ac4021b06d549e47c9e2efc9364a9eb96bfe82 (diff) | |
download | UXP-99c2e698d2a3c56649e42d8d2133706cd8c9501e.tar UXP-99c2e698d2a3c56649e42d8d2133706cd8c9501e.tar.gz UXP-99c2e698d2a3c56649e42d8d2133706cd8c9501e.tar.lz UXP-99c2e698d2a3c56649e42d8d2133706cd8c9501e.tar.xz UXP-99c2e698d2a3c56649e42d8d2133706cd8c9501e.zip |
Issue #1538 - remove speech recognition engine
This removes speech recognition, pocketsphinx, training models
and the speech automated test interface.
This also re-establishes proper use of MOZ_WEBSPEECH to work
for the speech API (synthesis part only) that was a broken mess
before, with some synth parts being always built, some parts
being built only with it enabled and recognition parts being
dependent on it. I'm pretty sure it'd be totally busted if you'd
ever have tried building without MOZ_WEBPEECH before.
Tested that synthesis still works as-intended.
This resolves #1538
Diffstat (limited to 'media/pocketsphinx/src/fsg_lextree.c')
-rw-r--r-- | media/pocketsphinx/src/fsg_lextree.c | 835 |
1 files changed, 0 insertions, 835 deletions
diff --git a/media/pocketsphinx/src/fsg_lextree.c b/media/pocketsphinx/src/fsg_lextree.c deleted file mode 100644 index 573f06b2f..000000000 --- a/media/pocketsphinx/src/fsg_lextree.c +++ /dev/null @@ -1,835 +0,0 @@ -/* -*- c-basic-offset: 4; indent-tabs-mode: nil -*- */ -/* ==================================================================== - * Copyright (c) 1999-2010 Carnegie Mellon University. All rights - * reserved. - * - * 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. - * - * - * THIS SOFTWARE IS PROVIDED BY CARNEGIE MELLON UNIVERSITY ``AS IS'' AND - * ANY EXPRESSED 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 CARNEGIE MELLON UNIVERSITY - * NOR ITS EMPLOYEES 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. - * - * ==================================================================== - * - */ -/** - * @file fsg_lextree.c - * @brief The collection of all the lextrees for the entire FSM. - * @author M K Ravishankar <rkm@cs.cmu.edu> - * @author Bhiksha Raj <bhiksha@cs.cmu.edu> - */ - -/* System headers. */ -#include <stdio.h> -#include <string.h> -#include <assert.h> - -/* SphinxBase headers. */ -#include <sphinxbase/ckd_alloc.h> -#include <sphinxbase/err.h> - -/* Local headers. */ -#include "fsg_lextree.h" - -#define __FSG_DBG__ 0 - -/* A linklist structure that is actually used to build local lextrees at grammar nodes */ -typedef struct fsg_glist_linklist_t { - int32 ci, rc; - glist_t glist; - struct fsg_glist_linklist_t *next; -} fsg_glist_linklist_t; - -/** - * Build the phone lextree for all transitions out of state from_state. - * Return the root node of this tree. - * Also, return a linear linked list of all allocated fsg_pnode_t nodes in - * *alloc_head (for memory management purposes). - */ -static fsg_pnode_t *fsg_psubtree_init(fsg_lextree_t *tree, - fsg_model_t *fsg, - int32 from_state, - fsg_pnode_t **alloc_head); - -/** - * Free the given lextree. alloc_head: head of linear list of allocated - * nodes updated by fsg_psubtree_init(). - */ -static void fsg_psubtree_free(fsg_pnode_t *alloc_head); - -/** - * Dump the list of nodes in the given lextree to the given file. alloc_head: - * head of linear list of allocated nodes updated by fsg_psubtree_init(). - */ -static void fsg_psubtree_dump(fsg_lextree_t *tree, fsg_pnode_t *root, FILE *fp); - -/** - * Compute the left and right context CIphone sets for each state. - */ -static void -fsg_lextree_lc_rc(fsg_lextree_t *lextree) -{ - int32 s, i, j; - int32 n_ci; - fsg_model_t *fsg; - int32 silcipid; - int32 len; - - silcipid = bin_mdef_silphone(lextree->mdef); - assert(silcipid >= 0); - n_ci = bin_mdef_n_ciphone(lextree->mdef); - - fsg = lextree->fsg; - /* - * lextree->lc[s] = set of left context CIphones for state s. Similarly, rc[s] - * for right context CIphones. - */ - lextree->lc = ckd_calloc_2d(fsg->n_state, n_ci + 1, sizeof(**lextree->lc)); - lextree->rc = ckd_calloc_2d(fsg->n_state, n_ci + 1, sizeof(**lextree->rc)); - E_INFO("Allocated %d bytes (%d KiB) for left and right context phones\n", - fsg->n_state * (n_ci + 1) * 2, - fsg->n_state * (n_ci + 1) * 2 / 1024); - - - for (s = 0; s < fsg->n_state; s++) { - fsg_arciter_t *itor; - for (itor = fsg_model_arcs(fsg, s); itor; itor = fsg_arciter_next(itor)) { - fsg_link_t *l = fsg_arciter_get(itor); - int32 dictwid; /**< Dictionary (not FSG) word ID!! */ - - if (fsg_link_wid(l) >= 0) { - dictwid = dict_wordid(lextree->dict, - fsg_model_word_str(lextree->fsg, l->wid)); - - /* - * Add the first CIphone of l->wid to the rclist of state s, and - * the last CIphone to lclist of state d. - * (Filler phones are a pain to deal with. There is no direct - * marking of a filler phone; but only filler words are supposed to - * use such phones, so we use that fact. HACK!! FRAGILE!!) - * - * UPD: tests carsh here if .fsg model used with wrong hmm and - * dictionary - */ - if (fsg_model_is_filler(fsg, fsg_link_wid(l))) { - /* Filler phone; use silence phone as context */ - lextree->rc[fsg_link_from_state(l)][silcipid] = 1; - lextree->lc[fsg_link_to_state(l)][silcipid] = 1; - } - else { - len = dict_pronlen(lextree->dict, dictwid); - lextree->rc[fsg_link_from_state(l)][dict_pron(lextree->dict, dictwid, 0)] = 1; - lextree->lc[fsg_link_to_state(l)][dict_pron(lextree->dict, dictwid, len - 1)] = 1; - } - } - } - } - - for (s = 0; s < fsg->n_state; s++) { - /* - * Add SIL phone to the lclist and rclist of each state. Strictly - * speaking, only needed at start and final states, respectively, but - * all states considered since the user may change the start and final - * states. In any case, most applications would have a silence self - * loop at each state, hence these would be needed anyway. - */ - lextree->lc[s][silcipid] = 1; - lextree->rc[s][silcipid] = 1; - } - - /* - * Propagate lc and rc lists past null transitions. (Since FSG contains - * null transitions closure, no need to worry about a chain of successive - * null transitions. Right??) - * - * This can't be joined with the previous loop because we first calculate - * contexts and only then we can propagate them. - */ - for (s = 0; s < fsg->n_state; s++) { - fsg_arciter_t *itor; - for (itor = fsg_model_arcs(fsg, s); itor; itor = fsg_arciter_next(itor)) { - fsg_link_t *l = fsg_arciter_get(itor); - if (fsg_link_wid(l) < 0) { - /* - * lclist(d) |= lclist(s), because all the words ending up at s, can - * now also end at d, becoming the left context for words leaving d. - */ - for (i = 0; i < n_ci; i++) - lextree->lc[fsg_link_to_state(l)][i] |= lextree->lc[fsg_link_from_state(l)][i]; - /* - * Similarly, rclist(s) |= rclist(d), because all the words leaving d - * can equivalently leave s, becoming the right context for words - * ending up at s. - */ - for (i = 0; i < n_ci; i++) - lextree->rc[fsg_link_from_state(l)][i] |= lextree->rc[fsg_link_to_state(l)][i]; - } - } - } - - /* Convert the bit-vector representation into a list */ - for (s = 0; s < fsg->n_state; s++) { - j = 0; - for (i = 0; i < n_ci; i++) { - if (lextree->lc[s][i]) { - lextree->lc[s][j] = i; - j++; - } - } - lextree->lc[s][j] = -1; /* Terminate the list */ - - j = 0; - for (i = 0; i < n_ci; i++) { - if (lextree->rc[s][i]) { - lextree->rc[s][j] = i; - j++; - } - } - lextree->rc[s][j] = -1; /* Terminate the list */ - } -} - -/* - * For now, allocate the entire lextree statically. - */ -fsg_lextree_t * -fsg_lextree_init(fsg_model_t * fsg, dict_t *dict, dict2pid_t *d2p, - bin_mdef_t *mdef, hmm_context_t *ctx, - int32 wip, int32 pip) -{ - int32 s, n_leaves; - fsg_lextree_t *lextree; - fsg_pnode_t *pn; - - lextree = ckd_calloc(1, sizeof(fsg_lextree_t)); - lextree->fsg = fsg; - lextree->root = ckd_calloc(fsg_model_n_state(fsg), - sizeof(fsg_pnode_t *)); - lextree->alloc_head = ckd_calloc(fsg_model_n_state(fsg), - sizeof(fsg_pnode_t *)); - lextree->ctx = ctx; - lextree->dict = dict; - lextree->d2p = d2p; - lextree->mdef = mdef; - lextree->wip = wip; - lextree->pip = pip; - - /* Compute lc and rc for fsg. */ - fsg_lextree_lc_rc(lextree); - - /* Create lextree for each state, i.e. an HMM network that - * represents words for all arcs exiting that state. Note that - * for a dense grammar such as an N-gram model, this will - * rapidly exhaust all available memory. */ - lextree->n_pnode = 0; - n_leaves = 0; - for (s = 0; s < fsg_model_n_state(fsg); s++) { - lextree->root[s] = - fsg_psubtree_init(lextree, fsg, s, &(lextree->alloc_head[s])); - - for (pn = lextree->alloc_head[s]; pn; pn = pn->alloc_next) { - lextree->n_pnode++; - if (pn->leaf) - ++n_leaves; - } - } - E_INFO("%d HMM nodes in lextree (%d leaves)\n", - lextree->n_pnode, n_leaves); - E_INFO("Allocated %d bytes (%d KiB) for all lextree nodes\n", - lextree->n_pnode * sizeof(fsg_pnode_t), - lextree->n_pnode * sizeof(fsg_pnode_t) / 1024); - E_INFO("Allocated %d bytes (%d KiB) for lextree leafnodes\n", - n_leaves * sizeof(fsg_pnode_t), - n_leaves * sizeof(fsg_pnode_t) / 1024); - -#if __FSG_DBG__ - fsg_lextree_dump(lextree, stdout); -#endif - - return lextree; -} - - -void -fsg_lextree_dump(fsg_lextree_t * lextree, FILE * fp) -{ - int32 s; - - for (s = 0; s < fsg_model_n_state(lextree->fsg); s++) { - fprintf(fp, "State %5d root %p\n", s, lextree->root[s]); - fsg_psubtree_dump(lextree, lextree->root[s], fp); - } - fflush(fp); -} - - -void -fsg_lextree_free(fsg_lextree_t * lextree) -{ - int32 s; - - if (lextree == NULL) - return; - - if (lextree->fsg) - for (s = 0; s < fsg_model_n_state(lextree->fsg); s++) - fsg_psubtree_free(lextree->alloc_head[s]); - - ckd_free_2d(lextree->lc); - ckd_free_2d(lextree->rc); - ckd_free(lextree->root); - ckd_free(lextree->alloc_head); - ckd_free(lextree); -} - -/****************************** - * psubtree stuff starts here * - ******************************/ - -void fsg_glist_linklist_free(fsg_glist_linklist_t *glist) -{ - if (glist) { - fsg_glist_linklist_t *nxtglist; - if (glist->glist) - glist_free(glist->glist); - nxtglist = glist->next; - while (nxtglist) { - ckd_free(glist); - glist = nxtglist; - if (glist->glist) - glist_free(glist->glist); - nxtglist = glist->next; - } - ckd_free(glist); - } - return; -} - -void -fsg_pnode_add_all_ctxt(fsg_pnode_ctxt_t * ctxt) -{ - int32 i; - - for (i = 0; i < FSG_PNODE_CTXT_BVSZ; i++) - ctxt->bv[i] = 0xffffffff; -} - -uint32 fsg_pnode_ctxt_sub_generic(fsg_pnode_ctxt_t *src, fsg_pnode_ctxt_t *sub) -{ - int32 i; - uint32 res = 0; - - for (i = 0; i < FSG_PNODE_CTXT_BVSZ; i++) - res |= (src->bv[i] = ~(sub->bv[i]) & src->bv[i]); - return res; -} - - -/* - * fsg_pnode_ctxt_sub(fsg_pnode_ctxt_t * src, fsg_pnode_ctxt_t * sub) - * This has been moved into a macro in fsg_psubtree.h - * because it is called so frequently! - */ - - -/* - * Add the word emitted by the given transition (fsglink) to the given lextree - * (rooted at root), and return the new lextree root. (There may actually be - * several root nodes, maintained in a linked list via fsg_pnode_t.sibling. - * "root" is the head of this list.) - * lclist, rclist: sets of left and right context phones for this link. - * alloc_head: head of a linear list of all allocated pnodes for the parent - * FSG state, kept elsewhere and updated by this routine. - */ -static fsg_pnode_t * -psubtree_add_trans(fsg_lextree_t *lextree, - fsg_pnode_t * root, - fsg_glist_linklist_t **curglist, - fsg_link_t * fsglink, - int16 *lclist, int16 *rclist, - fsg_pnode_t ** alloc_head) -{ - int32 silcipid; /* Silence CI phone ID */ - int32 pronlen; /* Pronunciation length */ - int32 wid; /* FSG (not dictionary!!) word ID */ - int32 dictwid; /* Dictionary (not FSG!!) word ID */ - int32 ssid; /* Senone Sequence ID */ - int32 tmatid; - gnode_t *gn; - fsg_pnode_t *pnode, *pred, *head; - int32 n_ci, p, lc, rc; - glist_t lc_pnodelist; /* Temp pnodes list for different left contexts */ - glist_t rc_pnodelist; /* Temp pnodes list for different right contexts */ - int32 i, j; - int n_lc_alloc = 0, n_int_alloc = 0, n_rc_alloc = 0; - - silcipid = bin_mdef_silphone(lextree->mdef); - n_ci = bin_mdef_n_ciphone(lextree->mdef); - - wid = fsg_link_wid(fsglink); - assert(wid >= 0); /* Cannot be a null transition */ - dictwid = dict_wordid(lextree->dict, - fsg_model_word_str(lextree->fsg, wid)); - pronlen = dict_pronlen(lextree->dict, dictwid); - assert(pronlen >= 1); - - assert(lclist[0] >= 0); /* At least one phonetic context provided */ - assert(rclist[0] >= 0); - - head = *alloc_head; - pred = NULL; - - if (pronlen == 1) { /* Single-phone word */ - int ci = dict_first_phone(lextree->dict, dictwid); - /* Only non-filler words are mpx */ - if (!dict_filler_word(lextree->dict, dictwid)) { - /* - * Left diphone ID for single-phone words already assumes SIL is right - * context; only left contexts need to be handled. - */ - lc_pnodelist = NULL; - - for (i = 0; lclist[i] >= 0; i++) { - lc = lclist[i]; - ssid = dict2pid_lrdiph_rc(lextree->d2p, ci, lc, silcipid); - tmatid = bin_mdef_pid2tmatid(lextree->mdef, dict_first_phone(lextree->dict, dictwid)); - /* Check if this ssid already allocated for some other context */ - for (gn = lc_pnodelist; gn; gn = gnode_next(gn)) { - pnode = (fsg_pnode_t *) gnode_ptr(gn); - - if (hmm_nonmpx_ssid(&pnode->hmm) == ssid) { - /* already allocated; share it for this context phone */ - fsg_pnode_add_ctxt(pnode, lc); - break; - } - } - - if (!gn) { /* ssid not already allocated */ - pnode = - (fsg_pnode_t *) ckd_calloc(1, sizeof(fsg_pnode_t)); - pnode->ctx = lextree->ctx; - pnode->next.fsglink = fsglink; - pnode->logs2prob = - (fsg_link_logs2prob(fsglink) >> SENSCR_SHIFT) - + lextree->wip + lextree->pip; - pnode->ci_ext = dict_first_phone(lextree->dict, dictwid); - pnode->ppos = 0; - pnode->leaf = TRUE; - pnode->sibling = root; /* All root nodes linked together */ - fsg_pnode_add_ctxt(pnode, lc); /* Initially zeroed by calloc above */ - pnode->alloc_next = head; - head = pnode; - root = pnode; - ++n_lc_alloc; - - hmm_init(lextree->ctx, &pnode->hmm, FALSE, ssid, tmatid); - - lc_pnodelist = - glist_add_ptr(lc_pnodelist, (void *) pnode); - } - } - - glist_free(lc_pnodelist); - } - else { /* Filler word; no context modelled */ - ssid = bin_mdef_pid2ssid(lextree->mdef, ci); /* probably the same... */ - tmatid = bin_mdef_pid2tmatid(lextree->mdef, ci); - - pnode = (fsg_pnode_t *) ckd_calloc(1, sizeof(fsg_pnode_t)); - pnode->ctx = lextree->ctx; - pnode->next.fsglink = fsglink; - pnode->logs2prob = (fsg_link_logs2prob(fsglink) >> SENSCR_SHIFT) - + lextree->wip + lextree->pip; - pnode->ci_ext = silcipid; /* Presents SIL as context to neighbors */ - pnode->ppos = 0; - pnode->leaf = TRUE; - pnode->sibling = root; - fsg_pnode_add_all_ctxt(&(pnode->ctxt)); - pnode->alloc_next = head; - head = pnode; - root = pnode; - ++n_int_alloc; - - hmm_init(lextree->ctx, &pnode->hmm, FALSE, ssid, tmatid); - } - } - else { /* Multi-phone word */ - fsg_pnode_t **ssid_pnode_map; /* Temp array of ssid->pnode mapping */ - ssid_pnode_map = - (fsg_pnode_t **) ckd_calloc(n_ci, sizeof(fsg_pnode_t *)); - lc_pnodelist = NULL; - rc_pnodelist = NULL; - - for (p = 0; p < pronlen; p++) { - int ci = dict_pron(lextree->dict, dictwid, p); - if (p == 0) { /* Root phone, handle required left contexts */ - /* Find if we already have an lc_pnodelist for the first phone of this word */ - fsg_glist_linklist_t *glist; - - rc = dict_pron(lextree->dict, dictwid, 1); - for (glist = *curglist; - glist && glist->glist; - glist = glist->next) { - if (glist->ci == ci && glist->rc == rc) - break; - } - if (glist && glist->glist) { - assert(glist->ci == ci && glist->rc == rc); - /* We've found a valid glist. Hook to it and move to next phoneme */ - E_DEBUG(2,("Found match for (%d,%d)\n", ci, rc)); - lc_pnodelist = glist->glist; - /* Set the predecessor node for the future tree first */ - pred = (fsg_pnode_t *) gnode_ptr(lc_pnodelist); - continue; - } - else { - /* Two cases that can bring us here - * a. glist == NULL, i.e. end of current list. Create new entry. - * b. glist->glist == NULL, i.e. first entry into list. - */ - if (glist == NULL) { /* Case a; reduce it to case b by allocing glist */ - glist = (fsg_glist_linklist_t*) ckd_calloc(1, sizeof(fsg_glist_linklist_t)); - glist->next = *curglist; - *curglist = glist; - } - glist->ci = ci; - glist->rc = rc; - lc_pnodelist = glist->glist = NULL; /* Gets created below */ - } - - for (i = 0; lclist[i] >= 0; i++) { - lc = lclist[i]; - ssid = dict2pid_ldiph_lc(lextree->d2p, ci, rc, lc); - tmatid = bin_mdef_pid2tmatid(lextree->mdef, dict_first_phone(lextree->dict, dictwid)); - /* Compression is not done by d2p, so we do it - * here. This might be slow, but it might not - * be... we'll see. */ - pnode = ssid_pnode_map[0]; - for (j = 0; j < n_ci && ssid_pnode_map[j] != NULL; ++j) { - pnode = ssid_pnode_map[j]; - if (hmm_nonmpx_ssid(&pnode->hmm) == ssid) - break; - } - assert(j < n_ci); - if (!pnode) { /* Allocate pnode for this new ssid */ - pnode = - (fsg_pnode_t *) ckd_calloc(1, - sizeof - (fsg_pnode_t)); - pnode->ctx = lextree->ctx; - /* This bit is tricky! For now we'll put the prob in the final link only */ - /* pnode->logs2prob = (fsg_link_logs2prob(fsglink) >> SENSCR_SHIFT) - + lextree->wip + lextree->pip; */ - pnode->logs2prob = lextree->wip + lextree->pip; - pnode->ci_ext = dict_first_phone(lextree->dict, dictwid); - pnode->ppos = 0; - pnode->leaf = FALSE; - pnode->sibling = root; /* All root nodes linked together */ - pnode->alloc_next = head; - head = pnode; - root = pnode; - ++n_lc_alloc; - - hmm_init(lextree->ctx, &pnode->hmm, FALSE, ssid, tmatid); - - lc_pnodelist = - glist_add_ptr(lc_pnodelist, (void *) pnode); - ssid_pnode_map[j] = pnode; - } - fsg_pnode_add_ctxt(pnode, lc); - } - /* Put the lc_pnodelist back into glist */ - glist->glist = lc_pnodelist; - - /* The predecessor node for the future tree is the root */ - pred = root; - } - else if (p != pronlen - 1) { /* Word internal phone */ - fsg_pnode_t *pnodeyoungest; - - ssid = dict2pid_internal(lextree->d2p, dictwid, p); - tmatid = bin_mdef_pid2tmatid(lextree->mdef, dict_pron (lextree->dict, dictwid, p)); - /* First check if we already have this ssid in our tree */ - pnode = pred->next.succ; - pnodeyoungest = pnode; /* The youngest sibling */ - while (pnode && (hmm_nonmpx_ssid(&pnode->hmm) != ssid || pnode->leaf)) { - pnode = pnode->sibling; - } - if (pnode && (hmm_nonmpx_ssid(&pnode->hmm) == ssid && !pnode->leaf)) { - /* Found the ssid; go to next phoneme */ - E_DEBUG(2,("Found match for %d\n", ci)); - pred = pnode; - continue; - } - - /* pnode not found, allocate it */ - pnode = (fsg_pnode_t *) ckd_calloc(1, sizeof(fsg_pnode_t)); - pnode->ctx = lextree->ctx; - pnode->logs2prob = lextree->pip; - pnode->ci_ext = dict_pron(lextree->dict, dictwid, p); - pnode->ppos = p; - pnode->leaf = FALSE; - pnode->sibling = pnodeyoungest; /* May be NULL */ - if (p == 1) { /* Predecessor = set of root nodes for left ctxts */ - for (gn = lc_pnodelist; gn; gn = gnode_next(gn)) { - pred = (fsg_pnode_t *) gnode_ptr(gn); - pred->next.succ = pnode; - } - } - else { /* Predecessor = word internal node */ - pred->next.succ = pnode; - } - pnode->alloc_next = head; - head = pnode; - ++n_int_alloc; - - hmm_init(lextree->ctx, &pnode->hmm, FALSE, ssid, tmatid); - - pred = pnode; - } - else { /* Leaf phone, handle required right contexts */ - /* Note, leaf phones are not part of the tree */ - xwdssid_t *rssid; - memset((void *) ssid_pnode_map, 0, - n_ci * sizeof(fsg_pnode_t *)); - lc = dict_pron(lextree->dict, dictwid, p-1); - rssid = dict2pid_rssid(lextree->d2p, ci, lc); - tmatid = bin_mdef_pid2tmatid(lextree->mdef, dict_pron (lextree->dict, dictwid, p)); - - for (i = 0; rclist[i] >= 0; i++) { - rc = rclist[i]; - - j = rssid->cimap[rc]; - ssid = rssid->ssid[j]; - pnode = ssid_pnode_map[j]; - - if (!pnode) { /* Allocate pnode for this new ssid */ - pnode = - (fsg_pnode_t *) ckd_calloc(1, - sizeof - (fsg_pnode_t)); - pnode->ctx = lextree->ctx; - /* We are plugging the word prob here. Ugly */ - /* pnode->logs2prob = lextree->pip; */ - pnode->logs2prob = (fsg_link_logs2prob(fsglink) >> SENSCR_SHIFT) - + lextree->pip; - pnode->ci_ext = dict_pron(lextree->dict, dictwid, p); - pnode->ppos = p; - pnode->leaf = TRUE; - pnode->sibling = rc_pnodelist ? - (fsg_pnode_t *) gnode_ptr(rc_pnodelist) : NULL; - pnode->next.fsglink = fsglink; - pnode->alloc_next = head; - head = pnode; - ++n_rc_alloc; - - hmm_init(lextree->ctx, &pnode->hmm, FALSE, ssid, tmatid); - - rc_pnodelist = - glist_add_ptr(rc_pnodelist, (void *) pnode); - ssid_pnode_map[j] = pnode; - } - else { - assert(hmm_nonmpx_ssid(&pnode->hmm) == ssid); - } - fsg_pnode_add_ctxt(pnode, rc); - } - - if (p == 1) { /* Predecessor = set of root nodes for left ctxts */ - for (gn = lc_pnodelist; gn; gn = gnode_next(gn)) { - pred = (fsg_pnode_t *) gnode_ptr(gn); - if (!pred->next.succ) - pred->next.succ = (fsg_pnode_t *) gnode_ptr(rc_pnodelist); - else { - /* Link to the end of the sibling chain */ - fsg_pnode_t *succ = pred->next.succ; - while (succ->sibling) succ = succ->sibling; - succ->sibling = (fsg_pnode_t*) gnode_ptr(rc_pnodelist); - /* Since all entries of lc_pnodelist point - to the same array, sufficient to update it once */ - break; - } - } - } - else { /* Predecessor = word internal node */ - if (!pred->next.succ) - pred->next.succ = (fsg_pnode_t *) gnode_ptr(rc_pnodelist); - else { - /* Link to the end of the sibling chain */ - fsg_pnode_t *succ = pred->next.succ; - while (succ->sibling) succ = succ->sibling; - succ->sibling = (fsg_pnode_t *) gnode_ptr(rc_pnodelist); - } - } - } - } - - ckd_free((void *) ssid_pnode_map); - /* glist_free(lc_pnodelist); Nope; this gets freed outside */ - glist_free(rc_pnodelist); - } - - E_DEBUG(2,("Allocated %d HMMs (%d lc, %d rc, %d internal)\n", - n_lc_alloc + n_rc_alloc + n_int_alloc, - n_lc_alloc, n_rc_alloc, n_int_alloc)); - *alloc_head = head; - - return root; -} - - -static fsg_pnode_t * -fsg_psubtree_init(fsg_lextree_t *lextree, - fsg_model_t * fsg, int32 from_state, - fsg_pnode_t ** alloc_head) -{ - fsg_arciter_t *itor; - fsg_link_t *fsglink; - fsg_pnode_t *root; - int32 n_ci, n_arc; - fsg_glist_linklist_t *glist = NULL; - - root = NULL; - assert(*alloc_head == NULL); - - n_ci = bin_mdef_n_ciphone(lextree->mdef); - if (n_ci > (FSG_PNODE_CTXT_BVSZ * 32)) { - E_FATAL - ("#phones > %d; increase FSG_PNODE_CTXT_BVSZ and recompile\n", - FSG_PNODE_CTXT_BVSZ * 32); - } - - n_arc = 0; - for (itor = fsg_model_arcs(fsg, from_state); itor; - itor = fsg_arciter_next(itor)) { - int32 dst; - fsglink = fsg_arciter_get(itor); - dst = fsglink->to_state; - - if (fsg_link_wid(fsglink) < 0) - continue; - - E_DEBUG(2,("Building lextree for arc from %d to %d: %s\n", - from_state, dst, fsg_model_word_str(fsg, fsg_link_wid(fsglink)))); - root = psubtree_add_trans(lextree, root, &glist, fsglink, - lextree->lc[from_state], - lextree->rc[dst], - alloc_head); - ++n_arc; - } - E_DEBUG(2,("State %d has %d outgoing arcs\n", from_state, n_arc)); - - fsg_glist_linklist_free(glist); - - return root; -} - - -static void -fsg_psubtree_free(fsg_pnode_t * head) -{ - fsg_pnode_t *next; - - while (head) { - next = head->alloc_next; - hmm_deinit(&head->hmm); - ckd_free(head); - head = next; - } -} - -void fsg_psubtree_dump_node(fsg_lextree_t *tree, fsg_pnode_t *node, FILE *fp) -{ - int32 i; - fsg_link_t *tl; - - /* Indentation */ - for (i = 0; i <= node->ppos; i++) - fprintf(fp, " "); - - fprintf(fp, "%p.@", node); /* Pointer used as node - * ID */ - fprintf(fp, " %5d.SS", hmm_nonmpx_ssid(&node->hmm)); - fprintf(fp, " %10d.LP", node->logs2prob); - fprintf(fp, " %p.SIB", node->sibling); - fprintf(fp, " %s.%d", bin_mdef_ciphone_str(tree->mdef, node->ci_ext), node->ppos); - if ((node->ppos == 0) || node->leaf) { - fprintf(fp, " ["); - for (i = 0; i < FSG_PNODE_CTXT_BVSZ; i++) - fprintf(fp, "%08x", node->ctxt.bv[i]); - fprintf(fp, "]"); - } - if (node->leaf) { - tl = node->next.fsglink; - fprintf(fp, " {%s[%d->%d](%d)}", - fsg_model_word_str(tree->fsg, tl->wid), - tl->from_state, tl->to_state, tl->logs2prob); - } else { - fprintf(fp, " %p.NXT", node->next.succ); - } - fprintf(fp, "\n"); - - return; -} - -void -fsg_psubtree_dump(fsg_lextree_t *tree, fsg_pnode_t *root, FILE * fp) -{ - fsg_pnode_t *succ; - - if (root == NULL) return; - if (root->ppos == 0) { - while(root->sibling && root->sibling->next.succ == root->next.succ) { - fsg_psubtree_dump_node(tree, root, fp); - root = root->sibling; - } - fflush(fp); - } - - fsg_psubtree_dump_node(tree, root, fp); - - if (root->leaf) { - if (root->ppos == 0 && root->sibling) { /* For single-phone words */ - fsg_psubtree_dump(tree, root->sibling,fp); - } - return; - } - - succ = root->next.succ; - while(succ) { - fsg_psubtree_dump(tree, succ,fp); - succ = succ->sibling; - } - - if (root->ppos == 0) { - fsg_psubtree_dump(tree, root->sibling,fp); - fflush(fp); - } - - return; -} - -void -fsg_psubtree_pnode_deactivate(fsg_pnode_t * pnode) -{ - hmm_clear(&pnode->hmm); -} |