- Separate the cases with PA_RESAMPLER_NO_REMAP or PA_RESAMPLER_NO_REMIX set and remove redundant if-conditions. - Fix C90 compiler warning due to mixing code and variable declaration. - Do not repeatedly count number of left, right and center channels in the input channel map. The logic of calc_map_table() remains unaltered. --- src/pulsecore/resampler.c | 365 +++++++++++++++++++++------------------------ 1 file changed, 170 insertions(+), 195 deletions(-) diff --git a/src/pulsecore/resampler.c b/src/pulsecore/resampler.c index 6332bf1..88e74e0 100644 --- a/src/pulsecore/resampler.c +++ b/src/pulsecore/resampler.c @@ -668,228 +668,206 @@ static void calc_map_table(pa_resampler *r) { memset(m->map_table_i, 0, sizeof(m->map_table_i)); memset(ic_connected, 0, sizeof(ic_connected)); - remix = (r->flags & (PA_RESAMPLER_NO_REMAP|PA_RESAMPLER_NO_REMIX)) == 0; + remix = (r->flags & (PA_RESAMPLER_NO_REMAP | PA_RESAMPLER_NO_REMIX)) == 0; - for (oc = 0; oc < n_oc; oc++) { - bool oc_connected = false; - pa_channel_position_t b = r->o_cm.map[oc]; - - for (ic = 0; ic < n_ic; ic++) { - pa_channel_position_t a = r->i_cm.map[ic]; + if (r->flags & PA_RESAMPLER_NO_REMAP) { + pa_assert(!remix); - if (r->flags & PA_RESAMPLER_NO_REMAP) { - /* We shall not do any remapping. Hence, just check by index */ + for (oc = 0; oc < PA_MIN(n_ic, n_oc); oc++) + m->map_table_f[oc][oc] = 1.0f; - if (ic == oc) - m->map_table_f[oc][ic] = 1.0; + } else if (r->flags & PA_RESAMPLER_NO_REMIX) { + pa_assert(!remix); + for (oc = 0; oc < n_oc; oc++) { + pa_channel_position_t b = r->o_cm.map[oc]; - continue; - } + for (ic = 0; ic < n_ic; ic++) { + pa_channel_position_t a = r->i_cm.map[ic]; - if (r->flags & PA_RESAMPLER_NO_REMIX) { /* We shall not do any remixing. Hence, just check by name */ - if (a == b) - m->map_table_f[oc][ic] = 1.0; - - continue; + m->map_table_f[oc][ic] = 1.0f; } + } + } else { - pa_assert(remix); - - /* OK, we shall do the full monty: upmixing and - * downmixing. Our algorithm is relatively simple, does - * not do spacialization, delay elements or apply lowpass - * filters for LFE. Patches are always welcome, - * though. Oh, and it doesn't do any matrix - * decoding. (Which probably wouldn't make any sense - * anyway.) - * - * This code is not idempotent: downmixing an upmixed - * stereo stream is not identical to the original. The - * volume will not match, and the two channels will be a - * linear combination of both. - * - * This is loosely based on random suggestions found on the - * Internet, such as this: - * http://www.halfgaar.net/surround-sound-in-linux and the - * alsa upmix plugin. - * - * The algorithm works basically like this: - * - * 1) Connect all channels with matching names. - * - * 2) Mono Handling: - * S:Mono: Copy into all D:channels - * D:Mono: Avg all S:channels - * - * 3) Mix D:Left, D:Right: - * D:Left: If not connected, avg all S:Left - * D:Right: If not connected, avg all S:Right - * - * 4) Mix D:Center - * If not connected, avg all S:Center - * If still not connected, avg all S:Left, S:Right - * - * 5) Mix D:LFE - * If not connected, avg all S:* - * - * 6) Make sure S:Left/S:Right is used: S:Left/S:Right: If - * not connected, mix into all D:left and all D:right - * channels. Gain is 0.1, the current left and right - * should be multiplied by 0.9. - * - * 7) Make sure S:Center, S:LFE is used: - * - * S:Center, S:LFE: If not connected, mix into all - * D:left, all D:right, all D:center channels, gain is - * 0.375. The current (as result of 1..6) factors - * should be multiplied by 0.75. (Alt. suggestion: 0.25 - * vs. 0.5) If C-front is only mixed into - * L-front/R-front if available, otherwise into all L/R - * channels. Similarly for C-rear. - * - * S: and D: shall relate to the source resp. destination channels. - * - * Rationale: 1, 2 are probably obvious. For 3: this - * copies front to rear if needed. For 4: we try to find - * some suitable C source for C, if we don't find any, we - * avg L and R. For 5: LFE is mixed from all channels. For - * 6: the rear channels should not be dropped entirely, - * however have only minimal impact. For 7: movies usually - * encode speech on the center channel. Thus we have to - * make sure this channel is distributed to L and R if not - * available in the output. Also, LFE is used to achieve a - * greater dynamic range, and thus we should try to do our - * best to pass it to L+R. - */ - - if (a == b || a == PA_CHANNEL_POSITION_MONO) { - m->map_table_f[oc][ic] = 1.0; - - oc_connected = true; - ic_connected[ic] = true; - } - else if (b == PA_CHANNEL_POSITION_MONO) { - if (n_ic) - m->map_table_f[oc][ic] = 1.0f / (float) n_ic; + /* OK, we shall do the full monty: upmixing and downmixing. Our + * algorithm is relatively simple, does not do spacialization, delay + * elements or apply lowpass filters for LFE. Patches are always + * welcome, though. Oh, and it doesn't do any matrix decoding. (Which + * probably wouldn't make any sense anyway.) + * + * This code is not idempotent: downmixing an upmixed stereo stream is + * not identical to the original. The volume will not match, and the + * two channels will be a linear combination of both. + * + * This is loosely based on random suggestions found on the Internet, + * such as this: + * http://www.halfgaar.net/surround-sound-in-linux and the alsa upmix + * plugin. + * + * The algorithm works basically like this: + * + * 1) Connect all channels with matching names. + * + * 2) Mono Handling: + * S:Mono: Copy into all D:channels + * D:Mono: Avg all S:channels + * + * 3) Mix D:Left, D:Right: + * D:Left: If not connected, avg all S:Left + * D:Right: If not connected, avg all S:Right + * + * 4) Mix D:Center + * If not connected, avg all S:Center + * If still not connected, avg all S:Left, S:Right + * + * 5) Mix D:LFE + * If not connected, avg all S:* + * + * 6) Make sure S:Left/S:Right is used: S:Left/S:Right: If not + * connected, mix into all D:left and all D:right channels. Gain is + * 0.1, the current left and right should be multiplied by 0.9. + * + * 7) Make sure S:Center, S:LFE is used: + * + * S:Center, S:LFE: If not connected, mix into all D:left, all + * D:right, all D:center channels, gain is 0.375. The current (as + * result of 1..6) factors should be multiplied by 0.75. (Alt. + * suggestion: 0.25 vs. 0.5) If C-front is only mixed into + * L-front/R-front if available, otherwise into all L/R channels. + * Similarly for C-rear. + * + * S: and D: shall relate to the source resp. destination channels. + * + * Rationale: 1, 2 are probably obvious. For 3: this copies front to + * rear if needed. For 4: we try to find some suitable C source for C, + * if we don't find any, we avg L and R. For 5: LFE is mixed from all + * channels. For 6: the rear channels should not be dropped entirely, + * however have only minimal impact. For 7: movies usually encode + * speech on the center channel. Thus we have to make sure this channel + * is distributed to L and R if not available in the output. Also, LFE + * is used to achieve a greater dynamic range, and thus we should try + * to do our best to pass it to L+R. + */ - oc_connected = true; - ic_connected[ic] = true; - } + unsigned + ic_left = 0, + ic_right = 0, + ic_center = 0, + ic_unconnected_left = 0, + ic_unconnected_right = 0, + ic_unconnected_center = 0, + ic_unconnected_lfe = 0; + + pa_assert(remix); + + for (ic = 0; ic < n_ic; ic++) { + if (on_left(r->i_cm.map[ic])) + ic_left++; + if (on_right(r->i_cm.map[ic])) + ic_right++; + if (on_center(r->i_cm.map[ic])) + ic_center++; } - if (!oc_connected && remix) { - /* OK, we shall remix */ + for (oc = 0; oc < n_oc; oc++) { + bool oc_connected = false; + pa_channel_position_t b = r->o_cm.map[oc]; - /* Try to find matching input ports for this output port */ + for (ic = 0; ic < n_ic; ic++) { + pa_channel_position_t a = r->i_cm.map[ic]; - if (on_left(b)) { - unsigned n = 0; + if (a == b || a == PA_CHANNEL_POSITION_MONO) { + m->map_table_f[oc][ic] = 1.0f; - /* We are not connected and on the left side, let's - * average all left side input channels. */ + oc_connected = true; + ic_connected[ic] = true; + } + else if (b == PA_CHANNEL_POSITION_MONO) { + m->map_table_f[oc][ic] = 1.0f / (float) n_ic; - for (ic = 0; ic < n_ic; ic++) - if (on_left(r->i_cm.map[ic])) - n++; + oc_connected = true; + ic_connected[ic] = true; + } + } - if (n > 0) - for (ic = 0; ic < n_ic; ic++) - if (on_left(r->i_cm.map[ic])) { - m->map_table_f[oc][ic] = 1.0f / (float) n; - ic_connected[ic] = true; - } + if (!oc_connected) { + /* Try to find matching input ports for this output port */ - /* We ignore the case where there is no left input - * channel. Something is really wrong in this case - * anyway. */ + if (on_left(b)) { - } else if (on_right(b)) { - unsigned n = 0; + /* We are not connected and on the left side, let's + * average all left side input channels. */ - /* We are not connected and on the right side, let's - * average all right side input channels. */ + if (ic_left > 0) + for (ic = 0; ic < n_ic; ic++) + if (on_left(r->i_cm.map[ic])) { + m->map_table_f[oc][ic] = 1.0f / (float) ic_left; + ic_connected[ic] = true; + } - for (ic = 0; ic < n_ic; ic++) - if (on_right(r->i_cm.map[ic])) - n++; + /* We ignore the case where there is no left input channel. + * Something is really wrong in this case anyway. */ - if (n > 0) - for (ic = 0; ic < n_ic; ic++) - if (on_right(r->i_cm.map[ic])) { - m->map_table_f[oc][ic] = 1.0f / (float) n; - ic_connected[ic] = true; - } + } else if (on_right(b)) { - /* We ignore the case where there is no right input - * channel. Something is really wrong in this case - * anyway. */ + /* We are not connected and on the right side, let's + * average all right side input channels. */ - } else if (on_center(b)) { - unsigned n = 0; + if (ic_right > 0) + for (ic = 0; ic < n_ic; ic++) + if (on_right(r->i_cm.map[ic])) { + m->map_table_f[oc][ic] = 1.0f / (float) ic_right; + ic_connected[ic] = true; + } - /* We are not connected and at the center. Let's - * average all center input channels. */ + /* We ignore the case where there is no right input + * channel. Something is really wrong in this case anyway. + * */ - for (ic = 0; ic < n_ic; ic++) - if (on_center(r->i_cm.map[ic])) - n++; + } else if (on_center(b)) { - if (n > 0) { - for (ic = 0; ic < n_ic; ic++) - if (on_center(r->i_cm.map[ic])) { - m->map_table_f[oc][ic] = 1.0f / (float) n; - ic_connected[ic] = true; - } - } else { + if (ic_center > 0) { - /* Hmm, no center channel around, let's synthesize - * it by mixing L and R.*/ + /* We are not connected and at the center. Let's average + * all center input channels. */ + + for (ic = 0; ic < n_ic; ic++) + if (on_center(r->i_cm.map[ic])) { + m->map_table_f[oc][ic] = 1.0f / (float) ic_center; + ic_connected[ic] = true; + } - n = 0; + } else if (ic_left + ic_right > 0) { - for (ic = 0; ic < n_ic; ic++) - if (on_left(r->i_cm.map[ic]) || on_right(r->i_cm.map[ic])) - n++; + /* Hmm, no center channel around, let's synthesize it + * by mixing L and R.*/ - if (n > 0) for (ic = 0; ic < n_ic; ic++) if (on_left(r->i_cm.map[ic]) || on_right(r->i_cm.map[ic])) { - m->map_table_f[oc][ic] = 1.0f / (float) n; + m->map_table_f[oc][ic] = 1.0f / (float) (ic_left + ic_right); ic_connected[ic] = true; } + } - /* We ignore the case where there is not even a - * left or right input channel. Something is - * really wrong in this case anyway. */ - } - - } else if (on_lfe(b)) { + /* We ignore the case where there is not even a left or + * right input channel. Something is really wrong in this + * case anyway. */ - /* We are not connected and an LFE. Let's average all - * channels for LFE. */ + } else if (on_lfe(b) && !(r->flags & PA_RESAMPLER_NO_LFE)) { - for (ic = 0; ic < n_ic; ic++) { + /* We are not connected and an LFE. Let's average all + * channels for LFE. */ - if (!(r->flags & PA_RESAMPLER_NO_LFE)) + for (ic = 0; ic < n_ic; ic++) m->map_table_f[oc][ic] = 1.0f / (float) n_ic; - else - m->map_table_f[oc][ic] = 0; - /* Please note that a channel connected to LFE - * doesn't really count as connected. */ + /* Please note that a channel connected to LFE doesn't + * really count as connected. */ } } } - } - - if (remix) { - unsigned - ic_unconnected_left = 0, - ic_unconnected_right = 0, - ic_unconnected_center = 0, - ic_unconnected_lfe = 0; for (ic = 0; ic < n_ic; ic++) { pa_channel_position_t a = r->i_cm.map[ic]; @@ -909,10 +887,9 @@ static void calc_map_table(pa_resampler *r) { if (ic_unconnected_left > 0) { - /* OK, so there are unconnected input channels on the - * left. Let's multiply all already connected channels on - * the left side by .9 and add in our averaged unconnected - * channels multiplied by .1 */ + /* OK, so there are unconnected input channels on the left. Let's + * multiply all already connected channels on the left side by .9 + * and add in our averaged unconnected channels multiplied by .1 */ for (oc = 0; oc < n_oc; oc++) { @@ -934,10 +911,9 @@ static void calc_map_table(pa_resampler *r) { if (ic_unconnected_right > 0) { - /* OK, so there are unconnected input channels on the - * right. Let's multiply all already connected channels on - * the right side by .9 and add in our averaged unconnected - * channels multiplied by .1 */ + /* OK, so there are unconnected input channels on the right. Let's + * multiply all already connected channels on the right side by .9 + * and add in our averaged unconnected channels multiplied by .1 */ for (oc = 0; oc < n_oc; oc++) { @@ -960,10 +936,9 @@ static void calc_map_table(pa_resampler *r) { if (ic_unconnected_center > 0) { bool mixed_in = false; - /* OK, so there are unconnected input channels on the - * center. Let's multiply all already connected channels on - * the center side by .9 and add in our averaged unconnected - * channels multiplied by .1 */ + /* OK, so there are unconnected input channels on the center. Let's + * multiply all already connected channels on the center side by .9 + * and add in our averaged unconnected channels multiplied by .1 */ for (oc = 0; oc < n_oc; oc++) { @@ -992,9 +967,8 @@ static void calc_map_table(pa_resampler *r) { memset(found_frs, 0, sizeof(found_frs)); /* Hmm, as it appears there was no center channel we - could mix our center channel in. In this case, mix - it into left and right. Using .375 and 0.75 as - factors. */ + could mix our center channel in. In this case, mix it into + left and right. Using .375 and 0.75 as factors. */ for (ic = 0; ic < n_ic; ic++) { @@ -1052,8 +1026,8 @@ static void calc_map_table(pa_resampler *r) { if (ic_unconnected_lfe > 0 && !(r->flags & PA_RESAMPLER_NO_LFE)) { - /* OK, so there is an unconnected LFE channel. Let's mix - * it into all channels, with factor 0.375 */ + /* OK, so there is an unconnected LFE channel. Let's mix it into + * all channels, with factor 0.375 */ for (ic = 0; ic < n_ic; ic++) { @@ -1065,6 +1039,7 @@ static void calc_map_table(pa_resampler *r) { } } } + /* make an 16:16 int version of the matrix */ for (oc = 0; oc < n_oc; oc++) for (ic = 0; ic < n_ic; ic++) -- 1.7.9.5