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/*
* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
// This class provides a generator for DTMF tones. The tone generation is based
// on a sinusoid recursion. Each sinusoid is generated using a recursion
// formula; x[n] = a * x[n-1] - x[n-2], where the coefficient
// a = 2*cos(2*pi*f/fs). The recursion is started with x[-1] = 0 and
// x[-2] = sin(2*pi*f/fs). (Note that with this initialization, the resulting
// sinusoid gets a "negative" rotation; x[n] = sin(-2*pi*f/fs * n + phi), but
// kept this way due to historical reasons.)
// TODO(hlundin): Change to positive rotation?
//
// Each key on the telephone keypad corresponds to an "event", 0-15. Each event
// is mapped to a tone pair, with a low and a high frequency. There are four
// low and four high frequencies, each corresponding to a row and column,
// respectively, on the keypad as illustrated below.
//
// 1209 Hz 1336 Hz 1477 Hz 1633 Hz
// 697 Hz 1 2 3 12
// 770 Hz 4 5 6 13
// 852 Hz 7 8 9 14
// 941 Hz 10 0 11 15
#include "webrtc/modules/audio_coding/neteq/dtmf_tone_generator.h"
#include "webrtc/rtc_base/arraysize.h"
#include "webrtc/rtc_base/checks.h"
namespace webrtc {
// The filter coefficient a = 2*cos(2*pi*f/fs) for the low frequency tone, for
// sample rates fs = {8000, 16000, 32000, 48000} Hz, and events 0 through 15.
// Values are in Q14.
const int DtmfToneGenerator::kCoeff1[4][16] = {
{ 24219, 27980, 27980, 27980, 26956, 26956, 26956, 25701, 25701, 25701,
24219, 24219, 27980, 26956, 25701, 24219 },
{ 30556, 31548, 31548, 31548, 31281, 31281, 31281, 30951, 30951, 30951,
30556, 30556, 31548, 31281, 30951, 30556 },
{ 32210, 32462, 32462, 32462, 32394, 32394, 32394, 32311, 32311, 32311,
32210, 32210, 32462, 32394, 32311, 32210 },
{ 32520, 32632, 32632, 32632, 32602, 32602, 32602, 32564, 32564, 32564,
32520, 32520, 32632, 32602, 32564, 32520 } };
// The filter coefficient a = 2*cos(2*pi*f/fs) for the high frequency tone, for
// sample rates fs = {8000, 16000, 32000, 48000} Hz, and events 0 through 15.
// Values are in Q14.
const int DtmfToneGenerator::kCoeff2[4][16] = {
{ 16325, 19073, 16325, 13085, 19073, 16325, 13085, 19073, 16325, 13085,
19073, 13085, 9315, 9315, 9315, 9315},
{ 28361, 29144, 28361, 27409, 29144, 28361, 27409, 29144, 28361, 27409,
29144, 27409, 26258, 26258, 26258, 26258},
{ 31647, 31849, 31647, 31400, 31849, 31647, 31400, 31849, 31647, 31400,
31849, 31400, 31098, 31098, 31098, 31098},
{ 32268, 32359, 32268, 32157, 32359, 32268, 32157, 32359, 32268, 32157,
32359, 32157, 32022, 32022, 32022, 32022} };
// The initialization value x[-2] = sin(2*pi*f/fs) for the low frequency tone,
// for sample rates fs = {8000, 16000, 32000, 48000} Hz, and events 0-15.
// Values are in Q14.
const int DtmfToneGenerator::kInitValue1[4][16] = {
{ 11036, 8528, 8528, 8528, 9315, 9315, 9315, 10163, 10163, 10163, 11036,
11036, 8528, 9315, 10163, 11036},
{ 5918, 4429, 4429, 4429, 4879, 4879, 4879, 5380, 5380, 5380, 5918, 5918,
4429, 4879, 5380, 5918},
{ 3010, 2235, 2235, 2235, 2468, 2468, 2468, 2728, 2728, 2728, 3010, 3010,
2235, 2468, 2728, 3010},
{ 2013, 1493, 1493, 1493, 1649, 1649, 1649, 1823, 1823, 1823, 2013, 2013,
1493, 1649, 1823, 2013 } };
// The initialization value x[-2] = sin(2*pi*f/fs) for the high frequency tone,
// for sample rates fs = {8000, 16000, 32000, 48000} Hz, and events 0-15.
// Values are in Q14.
const int DtmfToneGenerator::kInitValue2[4][16] = {
{ 14206, 13323, 14206, 15021, 13323, 14206, 15021, 13323, 14206, 15021,
13323, 15021, 15708, 15708, 15708, 15708},
{ 8207, 7490, 8207, 8979, 7490, 8207, 8979, 7490, 8207, 8979, 7490, 8979,
9801, 9801, 9801, 9801},
{ 4249, 3853, 4249, 4685, 3853, 4249, 4685, 3853, 4249, 4685, 3853, 4685,
5164, 5164, 5164, 5164},
{ 2851, 2582, 2851, 3148, 2582, 2851, 3148, 2582, 2851, 3148, 2582, 3148,
3476, 3476, 3476, 3476} };
// Amplitude multipliers for volume values 0 through 63, corresponding to
// 0 dBm0 through -63 dBm0. Values are in Q14.
// for a in range(0, 64):
// print round(16141.0 * 10**(-float(a)/20))
const int DtmfToneGenerator::kAmplitude[64] = {
16141, 14386, 12821, 11427, 10184, 9077, 8090, 7210, 6426, 5727, 5104, 4549,
4054, 3614, 3221, 2870, 2558, 2280, 2032, 1811, 1614, 1439, 1282, 1143,
1018, 908, 809, 721, 643, 573, 510, 455, 405, 361, 322, 287, 256, 228, 203,
181, 161, 144, 128, 114, 102, 91, 81, 72, 64, 57, 51, 45, 41, 36, 32, 29,
26, 23, 20, 18, 16, 14, 13, 11 };
// Constructor.
DtmfToneGenerator::DtmfToneGenerator()
: initialized_(false),
coeff1_(0),
coeff2_(0),
amplitude_(0) {
}
// Initialize the DTMF generator with sample rate fs Hz (8000, 16000, 32000,
// 48000), event (0-15) and attenuation (0-36 dB).
// Returns 0 on success, otherwise an error code.
int DtmfToneGenerator::Init(int fs, int event, int attenuation) {
initialized_ = false;
size_t fs_index;
if (fs == 8000) {
fs_index = 0;
} else if (fs == 16000) {
fs_index = 1;
} else if (fs == 32000) {
fs_index = 2;
} else if (fs == 48000) {
fs_index = 3;
} else {
RTC_NOTREACHED();
fs_index = 1; // Default to 8000 Hz.
}
if (event < 0 || event > 15) {
return kParameterError; // Invalid event number.
}
if (attenuation < 0 || attenuation > 63) {
return kParameterError; // Invalid attenuation.
}
// Look up oscillator coefficient for low and high frequencies.
RTC_DCHECK_LE(0, fs_index);
RTC_DCHECK_GT(arraysize(kCoeff1), fs_index);
RTC_DCHECK_GT(arraysize(kCoeff2), fs_index);
RTC_DCHECK_LE(0, event);
RTC_DCHECK_GT(arraysize(kCoeff1[fs_index]), event);
RTC_DCHECK_GT(arraysize(kCoeff2[fs_index]), event);
coeff1_ = kCoeff1[fs_index][event];
coeff2_ = kCoeff2[fs_index][event];
// Look up amplitude multiplier.
RTC_DCHECK_LE(0, attenuation);
RTC_DCHECK_GT(arraysize(kAmplitude), attenuation);
amplitude_ = kAmplitude[attenuation];
// Initialize sample history.
RTC_DCHECK_LE(0, fs_index);
RTC_DCHECK_GT(arraysize(kInitValue1), fs_index);
RTC_DCHECK_GT(arraysize(kInitValue2), fs_index);
RTC_DCHECK_LE(0, event);
RTC_DCHECK_GT(arraysize(kInitValue1[fs_index]), event);
RTC_DCHECK_GT(arraysize(kInitValue2[fs_index]), event);
sample_history1_[0] = kInitValue1[fs_index][event];
sample_history1_[1] = 0;
sample_history2_[0] = kInitValue2[fs_index][event];
sample_history2_[1] = 0;
initialized_ = true;
return 0;
}
// Reset tone generator to uninitialized state.
void DtmfToneGenerator::Reset() {
initialized_ = false;
}
// Generate num_samples of DTMF signal and write to |output|.
int DtmfToneGenerator::Generate(size_t num_samples,
AudioMultiVector* output) {
if (!initialized_) {
return kNotInitialized;
}
if (!output) {
return kParameterError;
}
output->AssertSize(num_samples);
for (size_t i = 0; i < num_samples; ++i) {
// Use recursion formula y[n] = a * y[n - 1] - y[n - 2].
int16_t temp_val_low = ((coeff1_ * sample_history1_[1] + 8192) >> 14)
- sample_history1_[0];
int16_t temp_val_high = ((coeff2_ * sample_history2_[1] + 8192) >> 14)
- sample_history2_[0];
// Update recursion memory.
sample_history1_[0] = sample_history1_[1];
sample_history1_[1] = temp_val_low;
sample_history2_[0] = sample_history2_[1];
sample_history2_[1] = temp_val_high;
// Attenuate the low frequency tone 3 dB.
int32_t temp_val =
kAmpMultiplier * temp_val_low + temp_val_high * (1 << 15);
// Normalize the signal to Q14 with proper rounding.
temp_val = (temp_val + 16384) >> 15;
// Scale the signal to correct volume.
(*output)[0][i] =
static_cast<int16_t>((temp_val * amplitude_ + 8192) >> 14);
}
// Copy first channel to all other channels.
for (size_t channel = 1; channel < output->Channels(); ++channel) {
output->CopyChannel(0, channel);
}
return static_cast<int>(num_samples);
}
bool DtmfToneGenerator::initialized() const {
return initialized_;
}
} // namespace webrtc