/* GStreamer * Copyright (C) <1999> Erik Walthinsen * * gstlevel.c: signals RMS, peak and decaying peak levels * Copyright (C) 2000,2001,2002,2003 * Thomas Vander Stichele * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include "gstlevel.h" #include "math.h" GST_DEBUG_CATEGORY (level_debug); #define GST_CAT_DEFAULT level_debug static GstElementDetails level_details = { "Level", "Filter/Analyzer/Audio", "RMS/Peak/Decaying Peak Level signaller for audio/raw", "Thomas " }; static GstStaticPadTemplate sink_template_factory = GST_STATIC_PAD_TEMPLATE ("sink", GST_PAD_SINK, GST_PAD_ALWAYS, GST_STATIC_CAPS ("audio/x-raw-int, " "rate = (int) [ 1, MAX ], " "channels = (int) [ 1, 2 ], " "endianness = (int) BYTE_ORDER, " "width = (int) { 8, 16 }, " "depth = (int) { 8, 16 }, " "signed = (boolean) true") ); static GstStaticPadTemplate src_template_factory = GST_STATIC_PAD_TEMPLATE ("src", GST_PAD_SRC, GST_PAD_ALWAYS, GST_STATIC_CAPS ("audio/x-raw-int, " "rate = (int) [ 1, MAX ], " "channels = (int) [ 1, 2 ], " "endianness = (int) BYTE_ORDER, " "width = (int) { 8, 16 }, " "depth = (int) { 8, 16 }, " "signed = (boolean) true") ); enum { PROP_0, PROP_SIGNAL_LEVEL, PROP_SIGNAL_INTERVAL, PROP_PEAK_TTL, PROP_PEAK_FALLOFF }; GST_BOILERPLATE (GstLevel, gst_level, GstBaseTransform, GST_TYPE_BASE_TRANSFORM); static void gst_level_set_property (GObject * object, guint prop_id, const GValue * value, GParamSpec * pspec); static void gst_level_get_property (GObject * object, guint prop_id, GValue * value, GParamSpec * pspec); static gboolean gst_level_set_caps (GstBaseTransform * trans, GstCaps * in, GstCaps * out); static GstFlowReturn gst_level_transform (GstBaseTransform * trans, GstBuffer * in, GstBuffer * out); static void gst_level_base_init (gpointer g_class) { GstElementClass *element_class = g_class; gst_element_class_add_pad_template (element_class, gst_static_pad_template_get (&sink_template_factory)); gst_element_class_add_pad_template (element_class, gst_static_pad_template_get (&src_template_factory)); gst_element_class_set_details (element_class, &level_details); } static void gst_level_class_init (GstLevelClass * klass) { GObjectClass *gobject_class; GstBaseTransformClass *trans_class; gobject_class = (GObjectClass *) klass; trans_class = (GstBaseTransformClass *) klass; gobject_class->set_property = gst_level_set_property; gobject_class->get_property = gst_level_get_property; g_object_class_install_property (G_OBJECT_CLASS (klass), PROP_SIGNAL_LEVEL, g_param_spec_boolean ("signal", "Signal", "Emit level signals for each interval", TRUE, G_PARAM_READWRITE)); g_object_class_install_property (G_OBJECT_CLASS (klass), PROP_SIGNAL_INTERVAL, g_param_spec_double ("interval", "Interval", "Interval between emissions (in seconds)", 0.01, 100.0, 0.1, G_PARAM_READWRITE)); g_object_class_install_property (G_OBJECT_CLASS (klass), PROP_PEAK_TTL, g_param_spec_double ("peak_ttl", "Peak TTL", "Time To Live of decay peak before it falls back", 0, 100.0, 0.3, G_PARAM_READWRITE)); g_object_class_install_property (G_OBJECT_CLASS (klass), PROP_PEAK_FALLOFF, g_param_spec_double ("peak_falloff", "Peak Falloff", "Decay rate of decay peak after TTL (in dB/sec)", 0.0, G_MAXDOUBLE, 10.0, G_PARAM_READWRITE)); GST_DEBUG_CATEGORY_INIT (level_debug, "level", 0, "Level calculation"); trans_class->set_caps = gst_level_set_caps; trans_class->transform = gst_level_transform; } static void gst_level_init (GstLevel * filter, GstLevelClass * g_class) { filter->CS = NULL; filter->peak = NULL; filter->RMS_dB = NULL; filter->rate = 0; filter->width = 0; filter->channels = 0; filter->interval = 0.1; filter->decay_peak_ttl = 0.4; filter->decay_peak_falloff = 10.0; /* dB falloff (/sec) */ } static void gst_level_set_property (GObject * object, guint prop_id, const GValue * value, GParamSpec * pspec) { GstLevel *filter = GST_LEVEL (object); switch (prop_id) { case PROP_SIGNAL_LEVEL: filter->signal = g_value_get_boolean (value); break; case PROP_SIGNAL_INTERVAL: filter->interval = g_value_get_double (value); break; case PROP_PEAK_TTL: filter->decay_peak_ttl = g_value_get_double (value); break; case PROP_PEAK_FALLOFF: filter->decay_peak_falloff = g_value_get_double (value); break; default: break; } } static void gst_level_get_property (GObject * object, guint prop_id, GValue * value, GParamSpec * pspec) { GstLevel *filter = GST_LEVEL (object); switch (prop_id) { case PROP_SIGNAL_LEVEL: g_value_set_boolean (value, filter->signal); break; case PROP_SIGNAL_INTERVAL: g_value_set_double (value, filter->interval); break; case PROP_PEAK_TTL: g_value_set_double (value, filter->decay_peak_ttl); break; case PROP_PEAK_FALLOFF: g_value_set_double (value, filter->decay_peak_falloff); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } } static gint structure_get_int (GstStructure * structure, const gchar * field) { gint ret; if (!gst_structure_get_int (structure, field, &ret)) g_assert_not_reached (); return ret; } static gboolean gst_level_set_caps (GstBaseTransform * trans, GstCaps * in, GstCaps * out) { GstLevel *filter; GstStructure *structure; int i; filter = GST_LEVEL (trans); filter->num_samples = 0; structure = gst_caps_get_structure (in, 0); filter->rate = structure_get_int (structure, "rate"); filter->width = structure_get_int (structure, "width"); filter->channels = structure_get_int (structure, "channels"); /* allocate channel variable arrays */ g_free (filter->CS); g_free (filter->peak); g_free (filter->last_peak); g_free (filter->decay_peak); g_free (filter->decay_peak_age); g_free (filter->RMS_dB); filter->CS = g_new (double, filter->channels); filter->peak = g_new (double, filter->channels); filter->last_peak = g_new (double, filter->channels); filter->decay_peak = g_new (double, filter->channels); filter->decay_peak_age = g_new (double, filter->channels); filter->RMS_dB = g_new (double, filter->channels); for (i = 0; i < filter->channels; ++i) { filter->CS[i] = filter->peak[i] = filter->last_peak[i] = filter->decay_peak[i] = filter->decay_peak_age[i] = filter->RMS_dB[i] = 0.0; } return TRUE; } /* process one (interleaved) channel of incoming samples * calculate square sum of samples * normalize and average over number of samples * returns a normalized average power value as CS, as a double between 0 and 1 * also returns the normalized peak power (square of the highest amplitude) * * caller must assure num is a multiple of channels * samples for multiple channels are interleaved * input sample data enters in *in_data as 8 or 16 bit data * this filter only accepts signed audio data, so mid level is always 0 */ #define DEFINE_LEVEL_CALCULATOR(TYPE) \ static void inline \ gst_level_calculate_##TYPE (TYPE * in, guint num, gint channels, \ gint resolution, double *CS, double *peak) \ { \ register int j; \ double squaresum = 0.0; /* square sum of the integer samples */ \ register double square = 0.0; /* Square */ \ register double PSS = 0.0; /* Peak Square Sample */ \ gdouble normalizer; /* divisor to get a [-1, - 1] range */ \ \ *CS = 0.0; /* Cumulative Square for this block */ \ \ normalizer = (double) (1 << resolution); \ \ for (j = 0; j < num; j += channels) \ { \ square = ((double) in[j]) * in[j]; \ if (square > PSS) PSS = square; \ squaresum += square; \ } \ \ *CS = squaresum / (normalizer * normalizer); \ *peak = PSS / (normalizer * normalizer); \ } DEFINE_LEVEL_CALCULATOR (gint16); DEFINE_LEVEL_CALCULATOR (gint8); static GstMessage * gst_level_message_new (GstLevel * l, gdouble endtime) { GstStructure *s; GValue v = { 0, }; g_value_init (&v, GST_TYPE_LIST); s = gst_structure_new ("level", "endtime", G_TYPE_DOUBLE, endtime, NULL); /* will copy-by-value */ gst_structure_set_value (s, "rms", &v); gst_structure_set_value (s, "peak", &v); gst_structure_set_value (s, "decay", &v); return gst_message_new_application (GST_OBJECT (l), s); } static void gst_level_message_append_channel (GstMessage * m, gdouble rms, gdouble peak, gdouble decay) { GstStructure *s; GValue v = { 0, }; GValue *l; g_value_init (&v, G_TYPE_DOUBLE); s = (GstStructure *) gst_message_get_structure (m); l = (GValue *) gst_structure_get_value (s, "rms"); g_value_set_double (&v, rms); gst_value_list_append_value (l, &v); /* copies by value */ l = (GValue *) gst_structure_get_value (s, "peak"); g_value_set_double (&v, peak); gst_value_list_append_value (l, &v); /* copies by value */ l = (GValue *) gst_structure_get_value (s, "decay"); g_value_set_double (&v, decay); gst_value_list_append_value (l, &v); /* copies by value */ } static GstFlowReturn gst_level_transform (GstBaseTransform * trans, GstBuffer * in, GstBuffer * out) { GstLevel *filter; gpointer in_data; double CS = 0.0; gint num_int_samples = 0; /* number of samples for all channels combined */ gint i; filter = GST_LEVEL (trans); for (i = 0; i < filter->channels; ++i) filter->peak[i] = filter->RMS_dB[i] = 0.0; in_data = GST_BUFFER_DATA (in); num_int_samples = GST_BUFFER_SIZE (in) / (filter->width / 8); g_return_val_if_fail (num_int_samples % filter->channels == 0, GST_FLOW_ERROR); for (i = 0; i < filter->channels; ++i) { CS = 0.0; switch (filter->width) { case 16: gst_level_calculate_gint16 (in_data + i, num_int_samples, filter->channels, filter->width - 1, &CS, &filter->peak[i]); break; case 8: gst_level_calculate_gint8 (((gint8 *) in_data) + i, num_int_samples, filter->channels, filter->width - 1, &CS, &filter->peak[i]); break; } GST_LOG_OBJECT (filter, "channel %d, cumulative sum %f, peak %f, over %d channels/%d samples", i, CS, filter->peak[i], num_int_samples, filter->channels); filter->CS[i] += CS; } filter->num_samples += num_int_samples / filter->channels; for (i = 0; i < filter->channels; ++i) { filter->decay_peak_age[i] += num_int_samples / filter->channels; GST_LOG_OBJECT (filter, "filter peak info [%d]: peak %f, age %f\n", i, filter->last_peak[i], filter->decay_peak_age[i]); /* update running peak */ if (filter->peak[i] > filter->last_peak[i]) filter->last_peak[i] = filter->peak[i]; /* update decay peak */ if (filter->peak[i] >= filter->decay_peak[i]) { GST_LOG_OBJECT (filter, "new peak, %f\n", filter->peak[i]); filter->decay_peak[i] = filter->peak[i]; filter->decay_peak_age[i] = 0; } else { /* make decay peak fall off if too old */ if (filter->decay_peak_age[i] > filter->rate * filter->decay_peak_ttl) { double falloff_dB; double falloff; double length; /* length of buffer in seconds */ length = (double) num_int_samples / (filter->channels * filter->rate); falloff_dB = filter->decay_peak_falloff * length; falloff = pow (10, falloff_dB / -20.0); GST_LOG_OBJECT (filter, "falloff: length %f, dB falloff %f, falloff factor %e\n", length, falloff_dB, falloff); filter->decay_peak[i] *= falloff; GST_LOG_OBJECT (filter, "peak is %f samples old, decayed with factor %e to %f\n", filter->decay_peak_age[i], falloff, filter->decay_peak[i]); } else { GST_LOG_OBJECT (filter, "peak not old enough, not decaying"); } } } /* do we need to emit ? */ if (filter->num_samples >= filter->interval * (gdouble) filter->rate) { if (filter->signal) { GstMessage *m; double endtime, RMS; double RMSdB, lastdB, decaydB; /* FIXME: convert to a GstClockTime instead */ endtime = (double) GST_BUFFER_TIMESTAMP (in) / GST_SECOND + (double) num_int_samples / (filter->rate * filter->channels); m = gst_level_message_new (filter, endtime); for (i = 0; i < filter->channels; ++i) { RMS = sqrt (filter->CS[i] / filter->num_samples); GST_LOG_OBJECT (filter, "CS: %f, num_samples %f, channel %d, RMS %f", filter->CS[i], filter->num_samples, i, RMS); /* RMS values are calculated in amplitude, so 20 * log 10 */ RMSdB = 20 * log10 (RMS); /* peak values are square sums, ie. power, so 10 * log 10 */ lastdB = 10 * log10 (filter->last_peak[i]); decaydB = 10 * log10 (filter->decay_peak[i]); GST_LOG_OBJECT (filter, "time %f, channel %d, RMS %f dB, peak %f dB, decay %f dB", endtime, i, RMSdB, lastdB, decaydB); gst_level_message_append_channel (m, RMSdB, lastdB, decaydB); /* reset cumulative and normal peak */ filter->CS[i] = 0.0; filter->last_peak[i] = 0.0; } gst_element_post_message (GST_ELEMENT (filter), m); } filter->num_samples = 0; } return GST_FLOW_OK; } static gboolean plugin_init (GstPlugin * plugin) { return gst_element_register (plugin, "level", GST_RANK_NONE, GST_TYPE_LEVEL); } GST_PLUGIN_DEFINE (GST_VERSION_MAJOR, GST_VERSION_MINOR, "level", "Audio level plugin", plugin_init, VERSION, GST_LICENSE, GST_PACKAGE, GST_ORIGIN)