ref: ceffff92190351bc83dc94fbfb72dc31a481ceea
dir: /src/splice.c/
/* libSoX effect: splice audio Copyright (c) 2008-9 robs@users.sourceforge.net * * This library is free software; you can redistribute it and/or modify it * under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation; either version 2.1 of the License, or (at * your option) any later version. * * This library is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser * General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this library; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "sox_i.h" static double difference( const sox_sample_t * a, const sox_sample_t * b, size_t length) { double diff = 0; size_t i = 0; #define _ diff += sqr((double)a[i] - b[i]), ++i; /* Loop optimisation */ do {_ _ _ _ _ _ _ _} while (i < length); /* N.B. length ≡ 0 (mod 8) */ #undef _ return diff; } /* Find where the two segments are most alike over the overlap period. */ static size_t best_overlap_position(sox_sample_t const * f1, sox_sample_t const * f2, uint64_t overlap, uint64_t search, size_t channels) { size_t i, best_pos = 0; double diff, least_diff = difference(f2, f1, (size_t) (channels * overlap)); for (i = 1; i < search; ++i) { /* linear search */ diff = difference(f2 + channels * i, f1, (size_t) (channels * overlap)); if (diff < least_diff) least_diff = diff, best_pos = i; } return best_pos; } typedef struct { enum {Cosine_2, Cosine_4, Triangular} fade_type; unsigned nsplices; /* Number of splices requested */ struct { char * str; /* Command-line argument to parse for this splice */ uint64_t overlap; /* Number of samples to overlap */ uint64_t search; /* Number of samples to search */ uint64_t start; /* Start splicing when in_pos equals this */ } * splices; uint64_t in_pos; /* Number of samples read from the input stream */ unsigned splices_pos; /* Number of splices completed so far */ size_t buffer_pos; /* Number of samples through the current splice */ size_t max_buffer_size; sox_sample_t * buffer; unsigned state; } priv_t; static void splice(sox_effect_t * effp, const sox_sample_t * in1, const sox_sample_t * in2, sox_sample_t * output, uint64_t overlap, size_t channels) { priv_t * p = (priv_t *)effp->priv; size_t i, j, k = 0; if (p->fade_type == Cosine_4) { double fade_step = M_PI_2 / overlap; for (i = 0; i < overlap; ++i) { double fade_in = sin(i * fade_step); double fade_out = cos(i * fade_step); /* constant RMS level (`power') */ for (j = 0; j < channels; ++j, ++k) { double d = in1[k] * fade_out + in2[k] * fade_in; output[k] = SOX_ROUND_CLIP_COUNT(d, effp->clips); /* Might clip */ } } } else if (p->fade_type == Cosine_2) { double fade_step = M_PI / overlap; for (i = 0; i < overlap; ++i) { double fade_in = .5 - .5 * cos(i * fade_step); double fade_out = 1 - fade_in; /* constant peak level (`gain') */ for (j = 0; j < channels; ++j, ++k) { double d = in1[k] * fade_out + in2[k] * fade_in; output[k] = SOX_ROUND_CLIP_COUNT(d, effp->clips); /* Should not clip */ } } } else /* Triangular */ { double fade_step = 1. / overlap; for (i = 0; i < overlap; ++i) { double fade_in = fade_step * i; double fade_out = 1 - fade_in; /* constant peak level (`gain') */ for (j = 0; j < channels; ++j, ++k) { double d = in1[k] * fade_out + in2[k] * fade_in; output[k] = SOX_ROUND_CLIP_COUNT(d, effp->clips); /* Should not clip */ } } } } static uint64_t do_splice(sox_effect_t * effp, sox_sample_t * f, uint64_t overlap, uint64_t search, size_t channels) { uint64_t offset = search? best_overlap_position( f, f + overlap * channels, overlap, search, channels) : 0; splice(effp, f, f + (overlap + offset) * channels, f + (overlap + offset) * channels, overlap, channels); return overlap + offset; } static int parse(sox_effect_t * effp, char * * argv, sox_rate_t rate) { priv_t * p = (priv_t *)effp->priv; char const * next; size_t i, buffer_size; uint64_t last_seen = 0; const uint64_t in_length = argv ? 0 : (effp->in_signal.length != SOX_UNKNOWN_LEN ? effp->in_signal.length / effp->in_signal.channels : SOX_UNKNOWN_LEN); p->max_buffer_size = 0; for (i = 0; i < p->nsplices; ++i) { if (argv) /* 1st parse only */ p->splices[i].str = lsx_strdup(argv[i]); p->splices[i].overlap = rate * 0.01 + .5; p->splices[i].search = p->fade_type == Cosine_4? 0 : p->splices[i].overlap; next = lsx_parseposition(rate, p->splices[i].str, argv ? NULL : &p->splices[i].start, last_seen, in_length, '='); if (next == NULL) break; last_seen = p->splices[i].start; if (*next == ',') { next = lsx_parsesamples(rate, next + 1, &p->splices[i].overlap, 't'); if (next == NULL) break; p->splices[i].overlap *= 2; if (*next == ',') { next = lsx_parsesamples(rate, next + 1, &p->splices[i].search, 't'); if (next == NULL) break; p->splices[i].search *= 2; } } if (*next != '\0') break; p->splices[i].overlap = max(p->splices[i].overlap + 4, 16); p->splices[i].overlap &= ~7; /* Make divisible by 8 for loop optimisation */ if (!argv) { if (i > 0 && p->splices[i].start <= p->splices[i-1].start) break; if (p->splices[i].start < p->splices[i].overlap) break; p->splices[i].start -= p->splices[i].overlap; buffer_size = 2 * p->splices[i].overlap + p->splices[i].search; p->max_buffer_size = max(p->max_buffer_size, buffer_size); } } if (i < p->nsplices) return lsx_usage(effp); return SOX_SUCCESS; } static int create(sox_effect_t * effp, int argc, char * * argv) { priv_t * p = (priv_t *)effp->priv; --argc, ++argv; if (argc) { if (!strcmp(*argv, "-t")) p->fade_type = Triangular, --argc, ++argv; else if (!strcmp(*argv, "-q")) p->fade_type = Cosine_4 , --argc, ++argv; else if (!strcmp(*argv, "-h")) p->fade_type = Cosine_2 , --argc, ++argv; } p->nsplices = argc; p->splices = lsx_calloc(p->nsplices, sizeof(*p->splices)); return parse(effp, argv, 1e5); /* No rate yet; parse with dummy */ } static int start(sox_effect_t * effp) { priv_t * p = (priv_t *)effp->priv; unsigned i; parse(effp, 0, effp->in_signal.rate); /* Re-parse now rate is known */ p->buffer = lsx_calloc(p->max_buffer_size * effp->in_signal.channels, sizeof(*p->buffer)); p->in_pos = p->buffer_pos = p->splices_pos = 0; p->state = p->splices_pos != p->nsplices && p->in_pos == p->splices[p->splices_pos].start; effp->out_signal.length = SOX_UNKNOWN_LEN; /* depends on input data */ for (i = 0; i < p->nsplices; ++i) if (p->splices[i].overlap) { if (p->fade_type == Cosine_4 && effp->in_signal.mult) *effp->in_signal.mult *= pow(.5, .5); return SOX_SUCCESS; } return SOX_EFF_NULL; } static int flow(sox_effect_t * effp, const sox_sample_t * ibuf, sox_sample_t * obuf, size_t * isamp, size_t * osamp) { priv_t * p = (priv_t *)effp->priv; size_t c, idone = 0, odone = 0; *isamp /= effp->in_signal.channels; *osamp /= effp->in_signal.channels; while (sox_true) { copying: if (p->state == 0) { for (; idone < *isamp && odone < *osamp; ++idone, ++odone, ++p->in_pos) { if (p->splices_pos != p->nsplices && p->in_pos == p->splices[p->splices_pos].start) { p->state = 1; goto buffering; } for (c = 0; c < effp->in_signal.channels; ++c) *obuf++ = *ibuf++; } break; } buffering: if (p->state == 1) { size_t buffer_size = (2 * p->splices[p->splices_pos].overlap + p->splices[p->splices_pos].search) * effp->in_signal.channels; for (; idone < *isamp; ++idone, ++p->in_pos) { if (p->buffer_pos == buffer_size) { p->buffer_pos = do_splice(effp, p->buffer, p->splices[p->splices_pos].overlap, p->splices[p->splices_pos].search, (size_t)effp->in_signal.channels) * effp->in_signal.channels; p->state = 2; goto flushing; break; } for (c = 0; c < effp->in_signal.channels; ++c) p->buffer[p->buffer_pos++] = *ibuf++; } break; } flushing: if (p->state == 2) { size_t buffer_size = (2 * p->splices[p->splices_pos].overlap + p->splices[p->splices_pos].search) * effp->in_signal.channels; for (; odone < *osamp; ++odone) { if (p->buffer_pos == buffer_size) { p->buffer_pos = 0; ++p->splices_pos; p->state = p->splices_pos != p->nsplices && p->in_pos == p->splices[p->splices_pos].start; goto copying; } for (c = 0; c < effp->in_signal.channels; ++c) *obuf++ = p->buffer[p->buffer_pos++]; } break; } } *isamp = idone * effp->in_signal.channels; *osamp = odone * effp->in_signal.channels; return SOX_SUCCESS; } static int drain(sox_effect_t * effp, sox_sample_t * obuf, size_t * osamp) { size_t isamp = 0; return flow(effp, 0, obuf, &isamp, osamp); } static int stop(sox_effect_t * effp) { priv_t * p = (priv_t *)effp->priv; if (p->splices_pos != p->nsplices) lsx_warn("Input audio too short; splices not made: %u", p->nsplices - p->splices_pos); free(p->buffer); return SOX_SUCCESS; } static int lsx_kill(sox_effect_t * effp) { priv_t * p = (priv_t *)effp->priv; unsigned i; for (i = 0; i < p->nsplices; ++i) free(p->splices[i].str); free(p->splices); return SOX_SUCCESS; } sox_effect_handler_t const * lsx_splice_effect_fn(void) { static sox_effect_handler_t handler = { "splice", "[-h|-t|-q] {position[,excess[,leeway]]}" "\n -h Half sine fade (default); constant gain (for correlated audio)" "\n -t Triangular (linear) fade; constant gain (for correlated audio)" "\n -q Quarter sine fade; constant power (for correlated audio e.g. x-fade)" "\n position The length of part 1 (including the excess)" "\n excess At the end of part 1 & the start of part2 (default 0.005)" "\n leeway Before part2 (default 0.005; set to 0 for cross-fade)", SOX_EFF_MCHAN | SOX_EFF_LENGTH, create, start, flow, drain, stop, lsx_kill, sizeof(priv_t) }; return &handler; }