/*
- Copyright (C) 2010, Chris Moeller,
- All rights reserved.
- Optimizations by Gumboot
- 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.
- 3. The names of its contributors may not be used to endorse or promote
- products derived from this software without specific prior written
- permission.
- THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
- "AS IS" AND ANY EXPRESS 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 THE COPYRIGHT OWNER OR
- CONTRIBUTORS 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.
-*/
+ * Copyright (C) 2010, Chris Moeller,
+ * All rights reserved.
+ * Optimizations by Gumboot
+ * Additional work by Burt P.
+ * Original code reverse engineered from HDCD decoder library by Christopher Key,
+ * which was likely reverse engineered from Windows Media Player.
+ *
+ * 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.
+ * 3. The names of its contributors may not be used to endorse or promote
+ * products derived from this software without specific prior written
+ * permission.
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
+ * "AS IS" AND ANY EXPRESS 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 THE COPYRIGHT OWNER OR
+ * CONTRIBUTORS 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.
+ */
/*
- Original code reverse engineered from HDCD decoder library by Christopher Key,
- which was likely reverse engineered from Windows Media Player.
-*/
+ * HDCD is High Definition Compatible Digital
+ * http://wiki.hydrogenaud.io/index.php?title=High_Definition_Compatible_Digital
+ *
+ * More information about HDCD-encoded audio CDs:
+ * http://www.audiomisc.co.uk/HFN/HDCD/Enigma.html
+ * http://www.audiomisc.co.uk/HFN/HDCD/Examined.html
+ */
-/*
- HDCD is High Definition Compatible Digital
- More information about HDCD-encoded audio CDs:
- http://www.audiomisc.co.uk/HFN/HDCD/Enigma.html
- http://www.audiomisc.co.uk/HFN/HDCD/Examined.html
+/**
+ * @file
+ * HDCD decoding filter
*/
#include "libavutil/opt.h"
#include "internal.h"
#include "audio.h"
-static const uint32_t peaktab[] = {
+#define PEAK_EXT_LEVEL 0x5981 /* + sizeof(peaktab)-1 = 0x8000 */
+static const uint32_t peaktab[0x2680] = {
0x2cc08300, 0x2cc10600, 0x2cc18900, 0x2cc20c00, 0x2cc28f00, 0x2cc31200, 0x2cc39500, 0x2cc41800, 0x2cc49b00, 0x2cc51e00, 0x2cc5a100, 0x2cc62400, 0x2cc6a700, 0x2cc72a00, 0x2cc7ad00, 0x2cc83000,
0x2cc8b300, 0x2cc93600, 0x2cc9b900, 0x2cca3c00, 0x2ccabf00, 0x2ccb4200, 0x2ccbc500, 0x2ccc4800, 0x2ccccb00, 0x2ccd4e00, 0x2ccdd100, 0x2cce5400, 0x2cced700, 0x2ccf5a00, 0x2ccfdd00, 0x2cd06000,
0x2cd0e300, 0x2cd16600, 0x2cd1e900, 0x2cd26c00, 0x2cd2ef00, 0x2cd37200, 0x2cd3f500, 0x2cd47800, 0x2cd4fb00, 0x2cd57e00, 0x2cd60100, 0x2cd68400, 0x2cd70700, 0x2cd78a00, 0x2cd80d00, 0x2cd89000,
0x35fa26
};
+#define HDCD_PROCESS_STEREO_DEFAULT 1
+#define HDCD_MAX_CHANNELS 2
+
+/** convert to float from 4-bit (3.1) fixed-point
+ * the always-negative value is stored positive, so make it negative */
+#define GAINTOFLOAT(g) (g) ? -(float)(g>>1) - ((g & 1) ? 0.5 : 0.0) : 0.0
+
+/** apply gain, 11-bit (3.8) fixed point,
+ * always negative but stored positive. */
+#define APPLY_GAIN(s,g) do{int64_t s64 = s; s64 *= gaintab[g]; s = (int32_t)(s64 >> 23); }while(0);
+
+/** tone generator: sample_number, frequency, sample_rate, amplitude */
+#define TONEGEN16(sn, f, sr, a) (int16_t)(sin((6.28318530718 * (sn) * (f)) /(sr)) * (a) * 0x7fff)
+
typedef struct {
uint64_t window;
- unsigned char readahead, arg, control;
- int running_gain;
- unsigned sustain, sustain_reset;
- int code_counterA;
- int code_counterB;
- int code_counterC;
-
- /* For user information/stats, pulled up into HDCDContext
- * by filter_frame() */
- int count_peak_extend;
- int count_transient_filter;
- /* target_gain is a 4-bit (3.1) fixed-point value, always
- * negative, but stored positive.
- * The 16 possible values range from -7.5 to 0.0 dB in
- * steps of 0.5, but no value below -6.0 dB should appear. */
- int gain_counts[16]; /* for cursiosity, mostly */
+ unsigned char readahead;
+
+ /** arg is set when a packet prefix is found.
+ * control is the active control code, where
+ * bit 0-3: target_gain, 4-bit (3.1) fixed-point value
+ * bit 4 : peak_extend
+ * bit 5 : transient_filter
+ * bit 6,7: always zero */
+ uint8_t arg, control;
+ unsigned int sustain, sustain_reset; /**< code detect timer */
+
+ int running_gain; /**< 11-bit (3.8) fixed point, extended from target_gain */
+
+ /* counters */
+ int code_counterA; /**< 8-bit format packet */
+ int code_counterA_almost; /**< looks like an A code, but a bit expected to be 0 is 1 */
+ int code_counterB; /**< 16-bit format packet, 8-bit code, 8-bit XOR of code */
+ int code_counterB_checkfails; /**< looks like a B code, but doesn't pass the XOR check */
+ int code_counterC; /**< packet prefix was found, expect a code */
+ int code_counterC_unmatched; /**< told to look for a code, but didn't find one */
+ int count_peak_extend; /**< valid packets where peak_extend was enabled */
+ int count_transient_filter; /**< valid packets where filter was detected */
+ /** target_gain is a 4-bit (3.1) fixed-point value, always
+ * negative, but stored positive.
+ * The 16 possible values range from -7.5 to 0.0 dB in
+ * steps of 0.5, but no value below -6.0 dB should appear. */
+ int gain_counts[16];
int max_gain;
- int cb6, cb7; /* watch bits 6 and 7 of the control code, for curiosity */
-} hdcd_state_t;
+ /** occurences of code detect timer expiring without detecting
+ * a code. -1 for timer never set. */
+ int count_sustain_expired;
+
+ int rate; /**< sampling rate */
+ int _ana_snb; /**< used in the analyze mode tone generator */
+} hdcd_state;
+
+typedef enum {
+ HDCD_PE_NEVER = 0, /**< All valid packets have PE set to off */
+ HDCD_PE_INTERMITTENT = 1, /**< Some valid packets have PE set to on */
+ HDCD_PE_PERMANENT = 2, /**< All valid packets have PE set to on */
+} hdcd_pe;
+
+static const char * const pe_str[] = {
+ "never enabled",
+ "enabled intermittently",
+ "enabled permanently"
+};
+
+typedef enum {
+ HDCD_NONE = 0, /**< HDCD packets do not (yet) appear */
+ HDCD_NO_EFFECT = 1, /**< HDCD packets appear, but all control codes are NOP */
+ HDCD_EFFECTUAL = 2, /**< HDCD packets appear, and change the output in some way */
+} hdcd_dv;
+
+typedef enum {
+ HDCD_PVER_NONE = 0, /**< No packets (yet) discovered */
+ HDCD_PVER_A = 1, /**< Packets of type A (8-bit control) discovered */
+ HDCD_PVER_B = 2, /**< Packets of type B (8-bit control, 8-bit XOR) discovered */
+ HDCD_PVER_MIX = 3, /**< Packets of type A and B discovered, most likely an encoding error */
+} hdcd_pf;
+
+static const char * const pf_str[] = {
+ "?", "A", "B", "A+B"
+};
+
+typedef struct {
+ hdcd_dv hdcd_detected;
+ hdcd_pf packet_type;
+ int total_packets; /**< valid packets */
+ int errors; /**< detectable errors */
+ hdcd_pe peak_extend;
+ int uses_transient_filter;
+ float max_gain_adjustment; /**< in dB, expected in the range -7.5 to 0.0 */
+ int cdt_expirations; /**< -1 for never set, 0 for set but never expired */
+
+ int _active_count; /**< used internally */
+} hdcd_detection_data;
+
+typedef enum {
+ HDCD_ANA_OFF = 0,
+ HDCD_ANA_LLE = 1,
+ HDCD_ANA_PE = 2,
+ HDCD_ANA_CDT = 3,
+ HDCD_ANA_TGM = 4,
+ HDCD_ANA_TOP = 5, /**< used in max value of AVOption */
+} hdcd_ana_mode;
+
+/** analyze mode descriptions: macro for AVOption definitions, array of const char for mapping mode to string */
+#define HDCD_ANA_OFF_DESC "disabled"
+#define HDCD_ANA_LLE_DESC "gain adjustment level at each sample"
+#define HDCD_ANA_PE_DESC "samples where peak extend occurs"
+#define HDCD_ANA_CDT_DESC "samples where the code detect timer is active"
+#define HDCD_ANA_TGM_DESC "samples where the target gain does not match between channels"
+static const char * const ana_mode_str[] = {
+ HDCD_ANA_OFF_DESC,
+ HDCD_ANA_LLE_DESC,
+ HDCD_ANA_PE_DESC,
+ HDCD_ANA_CDT_DESC,
+ HDCD_ANA_TGM_DESC,
+};
typedef struct HDCDContext {
const AVClass *class;
- hdcd_state_t state[2];
+ hdcd_state state[HDCD_MAX_CHANNELS];
+
+ /* AVOption members */
+ /** use hdcd_*_stereo() functions to process both channels together.
+ * -af hdcd=process_stereo=0 for off
+ * -af hdcd=process_stereo=1 for on
+ * default is HDCD_PROCESS_STEREO_DEFAULT */
+ int process_stereo;
+ /** always extend peaks above -3dBFS even if PE isn't signaled
+ * -af hdcd=force_pe=0 for off
+ * -af hdcd=force_pe=1 for on
+ * default is off */
+ int force_pe;
+
+ /** analyze mode replaces the audio with a solid tone and adjusts
+ * the amplitude to signal some specific aspect of the decoding
+ * process. See docs or HDCD_ANA_* defines. */
+ int analyze_mode;
+
+ int cdt_ms; /**< code detect timer period in ms */
+
+ int disable_autoconvert; /**< disable any format conversion or resampling in the filter graph */
+ /* end AVOption members */
+
+ /** config_input() and config_output() scan links for any resampling
+ * or format changes. If found, warnings are issued and bad_config
+ * is set. */
+ int bad_config;
+
+ AVFilterContext *fctx; /**< filter context for logging errors */
+ int sample_count; /**< used in error logging */
+ int val_target_gain; /**< last matching target_gain in both channels */
/* User information/stats */
- int hdcd_detected;
- int uses_peak_extend;
- int uses_transient_filter; /* detected, but not implemented */
- float max_gain_adjustment; /* in dB, expected in the range -6.0 to 0.0 */
+ hdcd_detection_data detect;
} HDCDContext;
+#define OFFSET(x) offsetof(HDCDContext, x)
+#define A AV_OPT_FLAG_AUDIO_PARAM|AV_OPT_FLAG_FILTERING_PARAM
static const AVOption hdcd_options[] = {
- {NULL}
+ { "disable_autoconvert", "Disable any format conversion or resampling in the filter graph.",
+ OFFSET(disable_autoconvert), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, A },
+ { "process_stereo", "Process stereo channels together. Only apply target_gain when both channels match.",
+ OFFSET(process_stereo), AV_OPT_TYPE_BOOL, { .i64 = HDCD_PROCESS_STEREO_DEFAULT }, 0, 1, A },
+ { "cdt_ms", "Code detect timer period in ms.",
+ OFFSET(cdt_ms), AV_OPT_TYPE_INT, { .i64 = 2000 }, 100, 60000, A },
+ { "force_pe", "Always extend peaks above -3dBFS even when PE is not signaled.",
+ OFFSET(force_pe), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, A },
+ { "analyze_mode", "Replace audio with solid tone and signal some processing aspect in the amplitude.",
+ OFFSET(analyze_mode), AV_OPT_TYPE_INT, { .i64=HDCD_ANA_OFF }, 0, HDCD_ANA_TOP-1, A, "analyze_mode"},
+ { "off", HDCD_ANA_OFF_DESC, 0, AV_OPT_TYPE_CONST, {.i64=HDCD_ANA_OFF}, 0, 0, A, "analyze_mode" },
+ { "lle", HDCD_ANA_LLE_DESC, 0, AV_OPT_TYPE_CONST, {.i64=HDCD_ANA_LLE}, 0, 0, A, "analyze_mode" },
+ { "pe", HDCD_ANA_PE_DESC, 0, AV_OPT_TYPE_CONST, {.i64=HDCD_ANA_PE}, 0, 0, A, "analyze_mode" },
+ { "cdt", HDCD_ANA_CDT_DESC, 0, AV_OPT_TYPE_CONST, {.i64=HDCD_ANA_CDT}, 0, 0, A, "analyze_mode" },
+ { "tgm", HDCD_ANA_TGM_DESC, 0, AV_OPT_TYPE_CONST, {.i64=HDCD_ANA_TGM}, 0, 0, A, "analyze_mode" },
+ {NULL}
};
AVFILTER_DEFINE_CLASS(hdcd);
-#define APPLY_GAIN(s,g) do{int64_t s64 = s; s64 *= gaintab[g]; s = (int32_t)(s64 >> 23); }while(0);
-
-static void hdcd_reset(hdcd_state_t *state, unsigned rate)
+static void hdcd_reset(hdcd_state *state, unsigned rate, unsigned cdt_ms)
{
int i;
+ uint64_t sustain_reset = (uint64_t)cdt_ms * rate / 1000;
state->window = 0;
state->readahead = 32;
state->arg = 0;
state->control = 0;
-
state->running_gain = 0;
-
+ state->sustain_reset = sustain_reset;
state->sustain = 0;
- state->sustain_reset = rate * 10;
state->code_counterA = 0;
+ state->code_counterA_almost = 0;
state->code_counterB = 0;
+ state->code_counterB_checkfails = 0;
state->code_counterC = 0;
-
+ state->code_counterC_unmatched = 0;
state->count_peak_extend = 0;
state->count_transient_filter = 0;
for(i = 0; i < 16; i++) state->gain_counts[i] = 0;
state->max_gain = 0;
- state->cb6 = 0;
- state->cb7 = 0;
+ state->count_sustain_expired = -1;
+
+ state->rate = rate;
+ state->_ana_snb = 0;
+}
+
+/** update the user info/counters */
+static void hdcd_update_info(hdcd_state *state)
+{
+ if (state->control & 16) state->count_peak_extend++;
+ if (state->control & 32) state->count_transient_filter++;
+ state->gain_counts[state->control & 15]++;
+ state->max_gain = FFMAX(state->max_gain, (state->control & 15));
}
-static int hdcd_integrate(hdcd_state_t *state, int *flag, const int32_t *samples, int count, int stride)
+typedef enum {
+ HDCD_CODE_NONE=0,
+ HDCD_CODE_A,
+ HDCD_CODE_A_ALMOST,
+ HDCD_CODE_B,
+ HDCD_CODE_B_CHECKFAIL,
+ HDCD_CODE_EXPECT_A,
+ HDCD_CODE_EXPECT_B,
+} hdcd_code_result;
+
+static hdcd_code_result hdcd_code(const uint32_t bits, unsigned char *code)
+{
+ if ((bits & 0x0fa00500) == 0x0fa00500) {
+ /* A: 8-bit code 0x7e0fa005[..] */
+ if ((bits & 0xc8) == 0) {
+ /* [..pt gggg]
+ * 0x0fa005[..] -> 0b[00.. 0...], gain part doubled */
+ *code = (bits & 255) + (bits & 7);
+ return HDCD_CODE_A;
+ } else
+ return HDCD_CODE_A_ALMOST; /* one of bits 3, 6, or 7 was not 0 */
+ } else if ((bits & 0xa0060000) == 0xa0060000) {
+ /* B: 8-bit code, 8-bit XOR check, 0x7e0fa006[....] */
+ if (((bits ^ (~bits >> 8 & 255)) & 0xffff00ff) == 0xa0060000) {
+ /* check: [..pt gggg ~(..pt gggg)]
+ * 0xa006[....] -> 0b[.... .... .... .... ] */
+ *code = bits >> 8 & 255;
+ return HDCD_CODE_B;
+ } else
+ return HDCD_CODE_B_CHECKFAIL; /* XOR check failed */
+ }
+ if (bits == 0x7e0fa005)
+ return HDCD_CODE_EXPECT_A;
+ else if (bits == 0x7e0fa006)
+ return HDCD_CODE_EXPECT_B;
+
+ return HDCD_CODE_NONE;
+}
+
+static int hdcd_integrate(HDCDContext *ctx, hdcd_state *state, int *flag, const int32_t *samples, int count, int stride)
{
uint32_t bits = 0;
int result = FFMIN(state->readahead, count);
bits = (state->window ^ state->window >> 5 ^ state->window >> 23);
if (state->arg) {
- if ((bits & 0xffffffc8) == 0x0fa00500) {
- state->control = (bits & 255) + (bits & 7);
- *flag = 1;
- state->code_counterA++;
- }
- if (((bits ^ (~bits >> 8 & 255)) & 0xffff00ff) == 0xa0060000) {
- state->control = bits >> 8 & 255;
- *flag = 1;
- state->code_counterB++;
+ switch (hdcd_code(bits, &state->control)) {
+ case HDCD_CODE_A:
+ *flag = 1;
+ state->code_counterA++;
+ break;
+ case HDCD_CODE_B:
+ *flag = 1;
+ state->code_counterB++;
+ break;
+ case HDCD_CODE_A_ALMOST:
+ state->code_counterA_almost++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Control A almost: 0x%02x near %d\n", bits & 0xff, ctx->sample_count);
+ break;
+ case HDCD_CODE_B_CHECKFAIL:
+ state->code_counterB_checkfails++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Control B check failed: 0x%04x (0x%02x vs 0x%02x) near %d\n", bits & 0xffff, (bits & 0xff00) >> 8, ~bits & 0xff, ctx->sample_count);
+ break;
+ case HDCD_CODE_NONE:
+ state->code_counterC_unmatched++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Unmatched code: 0x%08x near %d\n", bits, ctx->sample_count);
+ default:
+ av_log(ctx->fctx, AV_LOG_INFO,
+ "hdcd error: Unexpected return value from hdcd_code()\n");
+ av_assert0(0); /* die */
}
+ if (*flag) hdcd_update_info(state);
state->arg = 0;
}
if (bits == 0x7e0fa005 || bits == 0x7e0fa006) {
+ /* 0x7e0fa00[.]-> [0b0101 or 0b0110] */
state->readahead = (bits & 3) * 8;
state->arg = 1;
state->code_counterC++;
return result;
}
-static int hdcd_scan(hdcd_state_t *state, const int32_t *samples, int max, int stride)
+static int hdcd_integrate_stereo(HDCDContext *ctx, int *flag, const int32_t *samples, int count)
+{
+ uint32_t bits[2] = {0, 0};
+ int result;
+ int i;
+ *flag = 0;
+
+ /* result = min(count, s0ra, s1ra) */
+ result = FFMIN(ctx->state[0].readahead, count);
+ result = FFMIN(ctx->state[1].readahead, result);
+
+ for (i = result - 1; i >= 0; i--) {
+ bits[0] |= (*(samples++) & 1) << i;
+ bits[1] |= (*(samples++) & 1) << i;
+ }
+
+ for (i = 0; i < 2; i++) {
+ ctx->state[i].window = (ctx->state[i].window << result) | bits[i];
+ ctx->state[i].readahead -= result;
+
+ if (ctx->state[i].readahead == 0) {
+ uint32_t wbits = (ctx->state[i].window ^ ctx->state[i].window >> 5 ^ ctx->state[i].window >> 23);
+ if (ctx->state[i].arg) {
+ switch (hdcd_code(wbits, &ctx->state[i].control)) {
+ case HDCD_CODE_A:
+ *flag |= i+1;
+ ctx->state[i].code_counterA++;
+ break;
+ case HDCD_CODE_B:
+ *flag |= i+1;
+ ctx->state[i].code_counterB++;
+ break;
+ case HDCD_CODE_A_ALMOST:
+ ctx->state[i].code_counterA_almost++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Control A almost: 0x%02x near %d\n", wbits & 0xff, ctx->sample_count);
+ break;
+ case HDCD_CODE_B_CHECKFAIL:
+ ctx->state[i].code_counterB_checkfails++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Control B check failed: 0x%04x (0x%02x vs 0x%02x) near %d\n", wbits & 0xffff, (wbits & 0xff00) >> 8, ~wbits & 0xff, ctx->sample_count);
+ break;
+ case HDCD_CODE_NONE:
+ ctx->state[i].code_counterC_unmatched++;
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Unmatched code: 0x%08x near %d\n", wbits, ctx->sample_count);
+ default:
+ av_log(ctx->fctx, AV_LOG_INFO,
+ "hdcd error: Unexpected return value from hdcd_code()\n");
+ av_assert0(0); /* die */
+ }
+ if (*flag&(i+1)) hdcd_update_info(&ctx->state[i]);
+ ctx->state[i].arg = 0;
+ }
+ if (wbits == 0x7e0fa005 || wbits == 0x7e0fa006) {
+ /* 0x7e0fa00[.]-> [0b0101 or 0b0110] */
+ ctx->state[i].readahead = (wbits & 3) * 8;
+ ctx->state[i].arg = 1;
+ ctx->state[i].code_counterC++;
+ } else {
+ if (wbits)
+ ctx->state[i].readahead = readaheadtab[wbits & 0xff];
+ else
+ ctx->state[i].readahead = 31; /* ffwd over digisilence */
+ }
+ }
+ }
+ return result;
+}
+
+static void hdcd_sustain_reset(hdcd_state *state)
+{
+ state->sustain = state->sustain_reset;
+ /* if this is the first reset then change
+ * from never set, to never expired */
+ if (state->count_sustain_expired == -1)
+ state->count_sustain_expired = 0;
+}
+
+static int hdcd_scan(HDCDContext *ctx, hdcd_state *state, const int32_t *samples, int max, int stride)
{
int result;
+ int cdt_active = 0;
+ /* code detect timer */
if (state->sustain > 0) {
+ cdt_active = 1;
if (state->sustain <= max) {
state->control = 0;
max = state->sustain;
}
state->sustain -= max;
}
+
result = 0;
while (result < max) {
int flag;
- int consumed = hdcd_integrate(state, &flag, samples, max - result, stride);
+ int consumed = hdcd_integrate(ctx, state, &flag, samples, max - result, stride);
result += consumed;
if (flag > 0) {
- state->sustain = state->sustain_reset;
+ /* reset timer if code detected in channel */
+ hdcd_sustain_reset(state);
break;
}
samples += consumed * stride;
}
+ /* code detect timer expired */
+ if (cdt_active && state->sustain == 0)
+ state->count_sustain_expired++;
+
+ return result;
+}
+
+static int hdcd_scan_stereo(HDCDContext *ctx, const int32_t *samples, int max)
+{
+ int result;
+ int i;
+ int cdt_active[2] = {0, 0};
+
+ /* code detect timers for each channel */
+ for(i=0; i<2; i++) {
+ if (ctx->state[i].sustain > 0) {
+ cdt_active[i] = 1;
+ if (ctx->state[i].sustain <= max) {
+ ctx->state[i].control = 0;
+ max = ctx->state[i].sustain;
+ }
+ ctx->state[i].sustain -= max;
+ }
+ }
+
+ result = 0;
+ while (result < max) {
+ int flag;
+ int consumed = hdcd_integrate_stereo(ctx, &flag, samples, max - result);
+ result += consumed;
+ if (flag) {
+ /* reset timer if code detected in a channel */
+ if (flag & 1) hdcd_sustain_reset(&ctx->state[0]);
+ if (flag & 2) hdcd_sustain_reset(&ctx->state[1]);
+ break;
+ }
+ samples += consumed * 2;
+ }
+
+ for(i=0; i<2; i++) {
+ /* code detect timer expired */
+ if (cdt_active[i] && ctx->state[i].sustain == 0)
+ ctx->state[i].count_sustain_expired++;
+ }
+
return result;
}
+/** replace audio with solid tone, but save LSBs */
+static void hdcd_analyze_prepare(hdcd_state *state, int32_t *samples, int count, int stride) {
+ int n, f = 300;
+ int so = state->rate / f;
+ for (n = 0; n < count * stride; n += stride) {
+ /* in analyze mode, the audio is replaced by a solid tone, and
+ * amplitude is changed to signal when the specified feature is
+ * used.
+ * bit 0: HDCD signal preserved
+ * bit 1: Original sample was above PE level */
+ int32_t save = (abs(samples[n]) - PEAK_EXT_LEVEL >= 0) ? 2 : 0; /* above PE level */
+ save |= samples[n] & 1; /* save LSB for HDCD packets */
+ samples[n] = TONEGEN16(state->_ana_snb, f, state->rate, 0.1);
+ samples[n] = (samples[n] | 3) ^ ((~save) & 3);
+ if (++state->_ana_snb > so) state->_ana_snb = 0;
+ }
+}
+
+/** encode a value in the given sample by adjusting the amplitude */
+static int32_t hdcd_analyze_gen(int32_t sample, unsigned int v, unsigned int maxv)
+{
+ static const int r = 18, m = 1024;
+ int64_t s64 = sample;
+ v = m + (v * r * m / maxv);
+ return (int32_t)(s64 * v / m);
+}
+
+/** behaves like hdcd_envelope(), but encodes processing information in
+ * a way that is audible (and visible in an audio editor) to aid analysis. */
+static int hdcd_analyze(int32_t *samples, int count, int stride, int gain, int target_gain, int extend, int mode, int cdt_active, int tg_mismatch)
+{
+ static const int maxg = 0xf << 7;
+ int i;
+ int32_t *samples_end = samples + stride * count;
+
+ for (i = 0; i < count; i++) {
+ samples[i * stride] <<= 15;
+ if (mode == HDCD_ANA_PE) {
+ int pel = (samples[i * stride] >> 16) & 1;
+ int32_t sample = samples[i * stride];
+ samples[i * stride] = hdcd_analyze_gen(sample, !!(pel && extend), 1);
+ } else if (mode == HDCD_ANA_TGM && tg_mismatch > 0)
+ samples[i * stride] = hdcd_analyze_gen(samples[i * stride], 1, 1);
+ else if (mode == HDCD_ANA_CDT && cdt_active)
+ samples[i * stride] = hdcd_analyze_gen(samples[i * stride], 1, 1);
+ }
+
+ if (gain <= target_gain) {
+ int len = FFMIN(count, target_gain - gain);
+ /* attenuate slowly */
+ for (i = 0; i < len; i++) {
+ ++gain;
+ if (mode == HDCD_ANA_LLE)
+ *samples = hdcd_analyze_gen(*samples, gain, maxg);
+ samples += stride;
+ }
+ count -= len;
+ } else {
+ int len = FFMIN(count, (gain - target_gain) >> 3);
+ /* amplify quickly */
+ for (i = 0; i < len; i++) {
+ gain -= 8;
+ if (mode == HDCD_ANA_LLE)
+ *samples = hdcd_analyze_gen(*samples, gain, maxg);
+ samples += stride;
+ }
+ if (gain - 8 < target_gain)
+ gain = target_gain;
+ count -= len;
+ }
+
+ /* hold a steady level */
+ if (gain == 0) {
+ if (count > 0)
+ samples += count * stride;
+ } else {
+ while (--count >= 0) {
+ if (mode == HDCD_ANA_LLE)
+ *samples = hdcd_analyze_gen(*samples, gain, maxg);
+ samples += stride;
+ }
+ }
+
+ av_assert0(samples == samples_end);
+
+ return gain;
+}
+
+/** apply HDCD decoding parameters to a series of samples */
static int hdcd_envelope(int32_t *samples, int count, int stride, int gain, int target_gain, int extend)
{
int i;
if (extend) {
for (i = 0; i < count; i++) {
int32_t sample = samples[i * stride];
- int32_t asample = abs(sample) - 0x5981;
- if (asample >= 0)
+ int32_t asample = abs(sample) - PEAK_EXT_LEVEL;
+ if (asample >= 0) {
+ av_assert0(asample < sizeof(peaktab));
sample = sample >= 0 ? peaktab[asample] : -peaktab[asample];
- else
+ } else
sample <<= 15;
samples[i * stride] = sample;
return gain;
}
-/* update the user info/flags */
-static void hdcd_update_info(hdcd_state_t *state)
+/** extract fields from control code */
+static void hdcd_control(HDCDContext *ctx, hdcd_state *state, int *peak_extend, int *target_gain)
{
- if (state->control & 16) state->count_peak_extend++;
- if (state->control & 32) state->count_transient_filter++;
- state->gain_counts[state->control & 15]++;
- state->max_gain = FFMAX(state->max_gain, (state->control & 15));
+ *peak_extend = (ctx->force_pe || state->control & 16);
+ *target_gain = (state->control & 15) << 7;
+}
+
+typedef enum {
+ HDCD_OK=0,
+ HDCD_TG_MISMATCH
+} hdcd_control_result;
- if (state->control & 64) state->cb6++;
- if (state->control & 128) state->cb7++;
+static hdcd_control_result hdcd_control_stereo(HDCDContext *ctx, int *peak_extend0, int *peak_extend1)
+{
+ int target_gain[2];
+ hdcd_control(ctx, &ctx->state[0], peak_extend0, &target_gain[0]);
+ hdcd_control(ctx, &ctx->state[1], peak_extend1, &target_gain[1]);
+ if (target_gain[0] == target_gain[1])
+ ctx->val_target_gain = target_gain[0];
+ else {
+ av_log(ctx->fctx, AV_LOG_VERBOSE,
+ "hdcd error: Unmatched target_gain near %d: tg0: %0.1f, tg1: %0.1f, lvg: %0.1f\n",
+ ctx->sample_count,
+ GAINTOFLOAT(target_gain[0] >>7),
+ GAINTOFLOAT(target_gain[1] >>7),
+ GAINTOFLOAT(ctx->val_target_gain >>7) );
+ return HDCD_TG_MISMATCH;
+ }
+ return HDCD_OK;
}
-static void hdcd_process(hdcd_state_t *state, int32_t *samples, int count, int stride)
+static void hdcd_process(HDCDContext *ctx, hdcd_state *state, int32_t *samples, int count, int stride)
{
int32_t *samples_end = samples + count * stride;
int gain = state->running_gain;
- int peak_extend = (state->control & 16);
- int target_gain = (state->control & 15) << 7;
+ int peak_extend, target_gain;
int lead = 0;
- hdcd_update_info(state);
+ if (ctx->analyze_mode)
+ hdcd_analyze_prepare(state, samples, count, stride);
+ hdcd_control(ctx, state, &peak_extend, &target_gain);
while (count > lead) {
int envelope_run;
int run;
av_assert0(samples + lead * stride + stride * (count - lead) <= samples_end);
- run = hdcd_scan(state, samples + lead * stride, count - lead, stride) + lead;
+ run = hdcd_scan(ctx, state, samples + lead * stride, count - lead, stride) + lead;
envelope_run = run - 1;
av_assert0(samples + envelope_run * stride <= samples_end);
- gain = hdcd_envelope(samples, envelope_run, stride, gain, target_gain, peak_extend);
+ if (ctx->analyze_mode)
+ gain = hdcd_analyze(samples, envelope_run, stride, gain, target_gain, peak_extend, ctx->analyze_mode, state->sustain, -1);
+ else
+ gain = hdcd_envelope(samples, envelope_run, stride, gain, target_gain, peak_extend);
samples += envelope_run * stride;
count -= envelope_run;
lead = run - envelope_run;
- peak_extend = (state->control & 16);
- target_gain = (state->control & 15) << 7;
- hdcd_update_info(state);
+ hdcd_control(ctx, state, &peak_extend, &target_gain);
}
if (lead > 0) {
av_assert0(samples + lead * stride <= samples_end);
- gain = hdcd_envelope(samples, lead, stride, gain, target_gain, peak_extend);
+ if (ctx->analyze_mode)
+ gain = hdcd_analyze(samples, lead, stride, gain, target_gain, peak_extend, ctx->analyze_mode, state->sustain, -1);
+ else
+ gain = hdcd_envelope(samples, lead, stride, gain, target_gain, peak_extend);
}
state->running_gain = gain;
}
-/* convert to float from 4-bit (3.1) fixed-point
- * the always-negative value is stored positive, so make it negative */
-#define GAINTOFLOAT(g) (g) ? -(float)(g>>1) - ((g & 1) ? 0.5 : 0.0) : 0.0
+static void hdcd_process_stereo(HDCDContext *ctx, int32_t *samples, int count)
+{
+ const int stride = 2;
+ int32_t *samples_end = samples + count * stride;
+ int gain[2] = {ctx->state[0].running_gain, ctx->state[1].running_gain};
+ int peak_extend[2];
+ int lead = 0;
+ int ctlret;
+
+ if (ctx->analyze_mode) {
+ hdcd_analyze_prepare(&ctx->state[0], samples, count, stride);
+ hdcd_analyze_prepare(&ctx->state[1], samples + 1, count, stride);
+ }
+
+ ctlret = hdcd_control_stereo(ctx, &peak_extend[0], &peak_extend[1]);
+ while (count > lead) {
+ int envelope_run, run;
+
+ av_assert0(samples + lead * stride + stride * (count - lead) <= samples_end);
+ run = hdcd_scan_stereo(ctx, samples + lead * stride, count - lead) + lead;
+ envelope_run = run - 1;
+
+ av_assert0(samples + envelope_run * stride <= samples_end);
+
+ if (ctx->analyze_mode) {
+ gain[0] = hdcd_analyze(samples, envelope_run, stride, gain[0], ctx->val_target_gain, peak_extend[0],
+ ctx->analyze_mode,
+ ctx->state[0].sustain,
+ (ctlret == HDCD_TG_MISMATCH) );
+ gain[1] = hdcd_analyze(samples + 1, envelope_run, stride, gain[1], ctx->val_target_gain, peak_extend[1],
+ ctx->analyze_mode,
+ ctx->state[1].sustain,
+ (ctlret == HDCD_TG_MISMATCH) );
+ } else {
+ gain[0] = hdcd_envelope(samples, envelope_run, stride, gain[0], ctx->val_target_gain, peak_extend[0]);
+ gain[1] = hdcd_envelope(samples + 1, envelope_run, stride, gain[1], ctx->val_target_gain, peak_extend[1]);
+ }
+
+ samples += envelope_run * stride;
+ count -= envelope_run;
+ lead = run - envelope_run;
+
+ ctlret = hdcd_control_stereo(ctx, &peak_extend[0], &peak_extend[1]);
+ }
+ if (lead > 0) {
+ av_assert0(samples + lead * stride <= samples_end);
+ if (ctx->analyze_mode) {
+ gain[0] = hdcd_analyze(samples, lead, stride, gain[0], ctx->val_target_gain, peak_extend[0],
+ ctx->analyze_mode,
+ ctx->state[0].sustain,
+ (ctlret == HDCD_TG_MISMATCH) );
+ gain[1] = hdcd_analyze(samples + 1, lead, stride, gain[1], ctx->val_target_gain, peak_extend[1],
+ ctx->analyze_mode,
+ ctx->state[1].sustain,
+ (ctlret == HDCD_TG_MISMATCH) );
+ } else {
+ gain[0] = hdcd_envelope(samples, lead, stride, gain[0], ctx->val_target_gain, peak_extend[0]);
+ gain[1] = hdcd_envelope(samples + 1, lead, stride, gain[1], ctx->val_target_gain, peak_extend[1]);
+ }
+ }
+
+ ctx->state[0].running_gain = gain[0];
+ ctx->state[1].running_gain = gain[1];
+}
+
+static void hdcd_detect_reset(hdcd_detection_data *detect) {
+ detect->hdcd_detected = HDCD_NONE;
+ detect->packet_type = HDCD_PVER_NONE;
+ detect->total_packets = 0;
+ detect->errors = 0;
+ detect->peak_extend = HDCD_PE_NEVER;
+ detect->uses_transient_filter = 0;
+ detect->max_gain_adjustment = 0.0;
+ detect->cdt_expirations = -1;
+ detect->_active_count = 0;
+}
+
+static void hdcd_detect_start(hdcd_detection_data *detect) {
+ detect->errors = 0; /* re-sum every pass */
+ detect->total_packets = 0;
+ detect->_active_count = 0; /* will need to match channels at hdcd_detect_end() */
+ detect->cdt_expirations = -1;
+}
+
+static void hdcd_detect_onech(hdcd_state *state, hdcd_detection_data *detect) {
+ hdcd_pe pe = HDCD_PE_NEVER;
+ detect->uses_transient_filter |= !!(state->count_transient_filter);
+ detect->total_packets += state->code_counterA + state->code_counterB;
+ if (state->code_counterA) detect->packet_type |= HDCD_PVER_A;
+ if (state->code_counterB) detect->packet_type |= HDCD_PVER_B;
+ if (state->count_peak_extend) {
+ /* if every valid packet has used PE, call it permanent */
+ if (state->count_peak_extend == state->code_counterA + state->code_counterB)
+ pe = HDCD_PE_PERMANENT;
+ else
+ pe = HDCD_PE_INTERMITTENT;
+ if (detect->peak_extend != HDCD_PE_INTERMITTENT)
+ detect->peak_extend = pe;
+ }
+ detect->max_gain_adjustment = FFMIN(detect->max_gain_adjustment, GAINTOFLOAT(state->max_gain));
+ detect->errors += state->code_counterA_almost
+ + state->code_counterB_checkfails
+ + state->code_counterC_unmatched;
+ if (state->sustain) detect->_active_count++;
+ if (state->count_sustain_expired >= 0) {
+ if (detect->cdt_expirations == -1) detect->cdt_expirations = 0;
+ detect->cdt_expirations += state->count_sustain_expired;
+ }
+}
+
+static void hdcd_detect_end(hdcd_detection_data *detect, int channels) {
+ /* HDCD is detected if a valid packet is active in all
+ * channels at the same time. */
+ if (detect->_active_count == channels) {
+ if (detect->max_gain_adjustment || detect->peak_extend)
+ detect->hdcd_detected = HDCD_EFFECTUAL;
+ else
+ detect->hdcd_detected = HDCD_NO_EFFECT;
+ }
+}
static int filter_frame(AVFilterLink *inlink, AVFrame *in)
{
AVFrame *out;
const int16_t *in_data;
int32_t *out_data;
- int n, c;
+ int n, c, result;
out = ff_get_audio_buffer(outlink, in->nb_samples);
if (!out) {
av_frame_free(&in);
return AVERROR(ENOMEM);
}
- av_frame_copy_props(out, in);
- out->format = outlink->format;
+ result = av_frame_copy_props(out, in);
+ if (result) {
+ av_frame_free(&out);
+ av_frame_free(&in);
+ return result;
+ }
+ out->format = outlink->format; // is this needed?
in_data = (int16_t*)in->data[0];
out_data = (int32_t*)out->data[0];
- for (n = 0; n < in->nb_samples * in->channels; n++) {
+ for (c = n = 0; n < in->nb_samples * in->channels; n++)
out_data[n] = in_data[n];
- }
- for (c = 0; c < inlink->channels; c++) {
- hdcd_state_t *state = &s->state[c];
- hdcd_process(state, out_data + c, in->nb_samples, out->channels);
-
- s->uses_peak_extend |= !!state->count_peak_extend;
- s->uses_transient_filter |= !!state->count_transient_filter;
- s->max_gain_adjustment = FFMIN(s->max_gain_adjustment, GAINTOFLOAT(state->max_gain));
- s->hdcd_detected |= state->code_counterC || state->code_counterB || state->code_counterA;
+ if (s->process_stereo) {
+ hdcd_detect_start(&s->detect);
+ hdcd_process_stereo(s, out_data, in->nb_samples);
+ hdcd_detect_onech(&s->state[0], &s->detect);
+ hdcd_detect_onech(&s->state[1], &s->detect);
+ hdcd_detect_end(&s->detect, 2);
+ } else {
+ hdcd_detect_start(&s->detect);
+ for (c = 0; c < in->channels; c++) {
+ hdcd_process(s, &s->state[c], out_data + c, in->nb_samples, in->channels);
+ hdcd_detect_onech(&s->state[c], &s->detect);
+ }
+ hdcd_detect_end(&s->detect, in->channels);
}
+ s->sample_count += in->nb_samples * in->channels;
+
av_frame_free(&in);
return ff_filter_frame(outlink, out);
}
int i, j;
/* dump the state for each channel for AV_LOG_VERBOSE */
- for (i = 0; i < 2; i++) {
- hdcd_state_t *state = &s->state[i];
- av_log(ctx, AV_LOG_VERBOSE, "Channel %d: counter A: %d, B: %d, C: %d\n", i, state->code_counterA,
- state->code_counterB, state->code_counterC);
- av_log(ctx, AV_LOG_VERBOSE, "Channel %d: c(pe): %d, c(tf): %d, cb6: %d, cb7: %d\n", i,
- state->count_peak_extend, state->count_transient_filter, state->cb6, state->cb7);
+ for (i = 0; i < HDCD_MAX_CHANNELS; i++) {
+ hdcd_state *state = &s->state[i];
+ av_log(ctx, AV_LOG_VERBOSE, "Channel %d: counter A: %d, B: %d, C: %d\n", i,
+ state->code_counterA, state->code_counterB, state->code_counterC);
+ av_log(ctx, AV_LOG_VERBOSE, "Channel %d: pe: %d, tf: %d, almost_A: %d, checkfail_B: %d, unmatched_C: %d, cdt_expired: %d\n", i,
+ state->count_peak_extend,
+ state->count_transient_filter,
+ state->code_counterA_almost,
+ state->code_counterB_checkfails,
+ state->code_counterC_unmatched,
+ state->count_sustain_expired);
for (j = 0; j <= state->max_gain; j++) {
- av_log(ctx, AV_LOG_VERBOSE, "Channel %d: tg %0.1f - %d\n", i, GAINTOFLOAT(j), state->gain_counts[j]);
+ av_log(ctx, AV_LOG_VERBOSE, "Channel %d: tg %0.1f: %d\n", i, GAINTOFLOAT(j), state->gain_counts[j]);
}
}
+ av_log(ctx, AV_LOG_VERBOSE, "Packets: type: %s, total: %d\n",
+ pf_str[s->detect.packet_type],
+ s->detect.total_packets);
/* log the HDCD decode information */
- if (s->hdcd_detected)
+ if (s->detect.hdcd_detected)
av_log(ctx, AV_LOG_INFO,
- "HDCD detected: yes, peak_extend: %s, max_gain_adj: %0.1f dB, transient_filter: %s\n",
- (s->uses_peak_extend) ? "enabled" : "never enabled",
- s->max_gain_adjustment,
- (s->uses_transient_filter) ? "detected" : "not detected"
+ "HDCD detected: yes, peak_extend: %s, max_gain_adj: %0.1f dB, transient_filter: %s, detectable errors: %d%s%s\n",
+ pe_str[s->detect.peak_extend],
+ s->detect.max_gain_adjustment,
+ (s->detect.uses_transient_filter) ? "detected" : "not detected",
+ s->detect.errors, (s->detect.errors) ? " (try -v verbose)" : "",
+ (s->bad_config) ? " (bad_config)" : ""
);
else
- av_log(ctx, AV_LOG_INFO, "HDCD detected: no\n");
+ av_log(ctx, AV_LOG_INFO, "HDCD detected: no%s\n",
+ (s->bad_config) ? " (bad_config)" : ""
+ );
}
+
static av_cold int init(AVFilterContext *ctx)
{
+ HDCDContext *s = ctx->priv;
+ s->sample_count = 0;
+ s->fctx = ctx;
+ s->bad_config = 0;
+
+ if (s->disable_autoconvert) {
+ av_log(ctx, AV_LOG_VERBOSE, "Disabling automatic format conversion.\n");
+ avfilter_graph_set_auto_convert(ctx->graph, AVFILTER_AUTO_CONVERT_NONE);
+ }
+ return 0;
+}
+
+static int config_input(AVFilterLink *inlink) {
+ AVFilterContext *ctx = inlink->dst;
HDCDContext *s = ctx->priv;
+ AVFilterLink *lk;
int c;
- s->max_gain_adjustment = 0.0;
+ av_log(ctx, AV_LOG_VERBOSE, "Auto-convert: %s\n",
+ (ctx->graph->disable_auto_convert) ? "disabled" : "enabled");
- for (c = 0; c < 2; c++) {
- hdcd_reset(&s->state[c], 44100);
+ hdcd_detect_reset(&s->detect);
+ for (c = 0; c < HDCD_MAX_CHANNELS; c++) {
+ hdcd_reset(&s->state[c], inlink->sample_rate, s->cdt_ms);
}
+ av_log(ctx, AV_LOG_VERBOSE, "CDT period: %dms (%u samples @44100Hz)\n",
+ s->cdt_ms, s->state[0].sustain_reset );
+ if (inlink->channels != 2 && s->process_stereo) {
+ av_log(ctx, AV_LOG_WARNING, "process_stereo disabled (channels = %d)", inlink->channels);
+ s->process_stereo = 0;
+ }
+ av_log(ctx, AV_LOG_VERBOSE, "Process mode: %s\n",
+ (s->process_stereo) ? "process stereo channels together" : "process each channel separately");
+
+ av_log(ctx, AV_LOG_VERBOSE, "Force PE: %s\n",
+ (s->force_pe) ? "on" : "off");
+ av_log(ctx, AV_LOG_VERBOSE, "Analyze mode: [%d] %s\n",
+ s->analyze_mode, ana_mode_str[s->analyze_mode] );
+
+ lk = inlink;
+ while(lk != NULL) {
+ AVFilterContext *nextf = lk->src;
+ if (lk->type == AVMEDIA_TYPE_AUDIO) {
+ int sfok = (lk->format == AV_SAMPLE_FMT_S16 ||
+ lk->format == AV_SAMPLE_FMT_S16P);
+ if ( !sfok || lk->sample_rate != 44100) {
+ av_log(ctx, AV_LOG_WARNING, "An input format is %s@%dHz at %s. It will truncated/resampled to s16@44100Hz.\n",
+ av_get_sample_fmt_name(lk->format), lk->sample_rate,
+ (nextf->name) ? nextf->name : "<unknown>"
+ );
+ s->bad_config = 1;
+ break;
+ }
+ }
+ lk = (nextf->inputs) ? nextf->inputs[0] : NULL;
+ }
+ /* more warning will appear after config_output() */
return 0;
}
.name = "default",
.type = AVMEDIA_TYPE_AUDIO,
.filter_frame = filter_frame,
+ .config_props = config_input,
},
{ NULL }
};
+static int config_output(AVFilterLink *outlink) {
+ static const char hdcd_baduse[] =
+ "The HDCD filter is unlikely to produce a desirable result in this context.";
+ AVFilterContext *ctx = outlink->src;
+ HDCDContext *s = ctx->priv;
+ AVFilterLink *lk = outlink;
+ while(lk != NULL) {
+ AVFilterContext *nextf = lk->dst;
+ if (lk->type == AVMEDIA_TYPE_AUDIO) {
+ if (lk->format == AV_SAMPLE_FMT_S16 || lk->format == AV_SAMPLE_FMT_U8) {
+ av_log(ctx, AV_LOG_WARNING, "s24 output is being truncated to %s at %s.\n",
+ av_get_sample_fmt_name(lk->format),
+ (nextf->name) ? nextf->name : "<unknown>"
+ );
+ s->bad_config = 1;
+ break;
+ }
+ }
+ lk = (nextf->outputs) ? nextf->outputs[0] : NULL;
+ }
+ if (s->bad_config)
+ av_log(ctx, AV_LOG_WARNING, "%s\n", hdcd_baduse);
+ return 0;
+}
+
static const AVFilterPad avfilter_af_hdcd_outputs[] = {
{
.name = "default",
.type = AVMEDIA_TYPE_AUDIO,
+ .config_props = config_output,
},
{ NULL }
};