/* Audio Library for Teensy 3.X * Copyright (c) 2018, Paul Stoffregen, paul@pjrc.com * * Development of this audio library was funded by PJRC.COM, LLC by sales of * Teensy and Audio Adaptor boards. Please support PJRC's efforts to develop * open source software by purchasing Teensy or other PJRC products. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice, development funding notice, and this permission * notice shall be included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include #include "synth_waveform.h" #include "arm_math.h" #include "utility/dspinst.h" // uncomment for more accurate but more computationally expensive frequency modulation //#define IMPROVE_EXPONENTIAL_ACCURACY void AudioSynthWaveform::update(void) { audio_block_t *block; int16_t *bp, *end; int32_t val1, val2; int16_t magnitude15; uint32_t i, ph, index, index2, scale; const uint32_t inc = phase_increment; ph = phase_accumulator + phase_offset; if (magnitude == 0) { phase_accumulator += inc * AUDIO_BLOCK_SAMPLES; return; } block = allocate(); if (!block) { phase_accumulator += inc * AUDIO_BLOCK_SAMPLES; return; } bp = block->data; switch(tone_type) { case WAVEFORM_SINE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { index = ph >> 24; val1 = AudioWaveformSine[index]; val2 = AudioWaveformSine[index+1]; scale = (ph >> 8) & 0xFFFF; val2 *= scale; val1 *= 0x10000 - scale; *bp++ = multiply_32x32_rshift32(val1 + val2, magnitude); ph += inc; } break; case WAVEFORM_ARBITRARY: if (!arbdata) { release(block); phase_accumulator += inc * AUDIO_BLOCK_SAMPLES; return; } // len = 256 for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { index = ph >> 24; index2 = index + 1; if (index2 >= 256) index2 = 0; val1 = *(arbdata + index); val2 = *(arbdata + index2); scale = (ph >> 8) & 0xFFFF; val2 *= scale; val1 *= 0x10000 - scale; *bp++ = multiply_32x32_rshift32(val1 + val2, magnitude); ph += inc; } break; case WAVEFORM_SQUARE: magnitude15 = signed_saturate_rshift(magnitude, 16, 1); for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { if (ph & 0x80000000) { *bp++ = -magnitude15; } else { *bp++ = magnitude15; } ph += inc; } break; case WAVEFORM_SAWTOOTH: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { *bp++ = signed_multiply_32x16t(magnitude, ph); ph += inc; } break; case WAVEFORM_SAWTOOTH_REVERSE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { *bp++ = signed_multiply_32x16t(0xFFFFFFFFu - magnitude, ph); ph += inc; } break; case WAVEFORM_TRIANGLE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { uint32_t phtop = ph >> 30; if (phtop == 1 || phtop == 2) { *bp++ = ((0xFFFF - (ph >> 15)) * magnitude) >> 16; } else { *bp++ = (((int32_t)ph >> 15) * magnitude) >> 16; } ph += inc; } break; case WAVEFORM_TRIANGLE_VARIABLE: do { uint32_t rise = 0xFFFFFFFF / (pulse_width >> 16); uint32_t fall = 0xFFFFFFFF / (0xFFFF - (pulse_width >> 16)); for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { if (ph < pulse_width/2) { uint32_t n = (ph >> 16) * rise; *bp++ = ((n >> 16) * magnitude) >> 16; } else if (ph < 0xFFFFFFFF - pulse_width/2) { uint32_t n = 0x7FFFFFFF - (((ph - pulse_width/2) >> 16) * fall); *bp++ = (((int32_t)n >> 16) * magnitude) >> 16; } else { uint32_t n = ((ph + pulse_width/2) >> 16) * rise + 0x80000000; *bp++ = (((int32_t)n >> 16) * magnitude) >> 16; } ph += inc; } } while (0); break; case WAVEFORM_PULSE: magnitude15 = signed_saturate_rshift(magnitude, 16, 1); for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { if (ph < pulse_width) { *bp++ = magnitude15; } else { *bp++ = -magnitude15; } ph += inc; } break; case WAVEFORM_SAMPLE_HOLD: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { *bp++ = sample; uint32_t newph = ph + inc; if (newph < ph) { sample = random(magnitude) - (magnitude >> 1); } ph = newph; } break; } phase_accumulator = ph - phase_offset; if (tone_offset) { bp = block->data; end = bp + AUDIO_BLOCK_SAMPLES; do { val1 = *bp; *bp++ = signed_saturate_rshift(val1 + tone_offset, 16, 0); } while (bp < end); } transmit(block, 0); release(block); } //-------------------------------------------------------------------------------- void AudioSynthWaveformModulated::update(void) { audio_block_t *block, *moddata, *shapedata; int16_t *bp, *end; int32_t val1, val2; int16_t magnitude15; uint32_t i, ph, index, index2, scale, priorphase; const uint32_t inc = phase_increment; moddata = receiveReadOnly(0); shapedata = receiveReadOnly(1); // Pre-compute the phase angle for every output sample of this update ph = phase_accumulator; priorphase = phasedata[AUDIO_BLOCK_SAMPLES-1]; if (moddata && modulation_type == 0) { // Frequency Modulation bp = moddata->data; for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { int32_t n = (*bp++) * modulation_factor; // n is # of octaves to mod int32_t ipart = n >> 27; // 4 integer bits n &= 0x7FFFFFF; // 27 fractional bits #ifdef IMPROVE_EXPONENTIAL_ACCURACY // exp2 polynomial suggested by Stefan Stenzel on "music-dsp" // mail list, Wed, 3 Sep 2014 10:08:55 +0200 int32_t x = n << 3; n = multiply_accumulate_32x32_rshift32_rounded(536870912, x, 1494202713); int32_t sq = multiply_32x32_rshift32_rounded(x, x); n = multiply_accumulate_32x32_rshift32_rounded(n, sq, 1934101615); n = n + (multiply_32x32_rshift32_rounded(sq, multiply_32x32_rshift32_rounded(x, 1358044250)) << 1); n = n << 1; #else // exp2 algorithm by Laurent de Soras // http://www.musicdsp.org/showone.php?id=106 n = (n + 134217728) << 3; n = multiply_32x32_rshift32_rounded(n, n); n = multiply_32x32_rshift32_rounded(n, 715827883) << 3; n = n + 715827882; #endif uint32_t scale = n >> (14 - ipart); uint64_t phstep = (uint64_t)inc * scale; uint32_t phstep_msw = phstep >> 32; if (phstep_msw < 0x7FFE) { ph += phstep >> 16; } else { ph += 0x7FFE0000; } phasedata[i] = ph; } release(moddata); } else if (moddata) { // Phase Modulation bp = moddata->data; for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { // more than +/- 180 deg shift by 32 bit overflow of "n" uint32_t n = (uint16_t)(*bp++) * modulation_factor; phasedata[i] = ph + n; ph += inc; } release(moddata); } else { // No Modulation Input for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { phasedata[i] = ph; ph += inc; } } phase_accumulator = ph; // If the amplitude is zero, no output, but phase still increments properly if (magnitude == 0) { if (shapedata) release(shapedata); return; } block = allocate(); if (!block) { if (shapedata) release(shapedata); return; } bp = block->data; // Now generate the output samples using the pre-computed phase angles switch(tone_type) { case WAVEFORM_SINE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { ph = phasedata[i]; index = ph >> 24; val1 = AudioWaveformSine[index]; val2 = AudioWaveformSine[index+1]; scale = (ph >> 8) & 0xFFFF; val2 *= scale; val1 *= 0x10000 - scale; *bp++ = multiply_32x32_rshift32(val1 + val2, magnitude); } break; case WAVEFORM_ARBITRARY: if (!arbdata) { release(block); if (shapedata) release(shapedata); return; } // len = 256 for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { ph = phasedata[i]; index = ph >> 24; index2 = index + 1; if (index2 >= 256) index2 = 0; val1 = *(arbdata + index); val2 = *(arbdata + index2); scale = (ph >> 8) & 0xFFFF; val2 *= scale; val1 *= 0x10000 - scale; *bp++ = multiply_32x32_rshift32(val1 + val2, magnitude); } break; case WAVEFORM_PULSE: if (shapedata) { magnitude15 = signed_saturate_rshift(magnitude, 16, 1); for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { uint32_t width = ((shapedata->data[i] + 0x8000) & 0xFFFF) << 16; if (phasedata[i] < width) { *bp++ = magnitude15; } else { *bp++ = -magnitude15; } } break; } // else fall through to orginary square without shape modulation case WAVEFORM_SQUARE: magnitude15 = signed_saturate_rshift(magnitude, 16, 1); for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { if (phasedata[i] & 0x80000000) { *bp++ = -magnitude15; } else { *bp++ = magnitude15; } } break; case WAVEFORM_SAWTOOTH: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { *bp++ = signed_multiply_32x16t(magnitude, phasedata[i]); } break; case WAVEFORM_SAWTOOTH_REVERSE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { *bp++ = signed_multiply_32x16t(0xFFFFFFFFu - magnitude, phasedata[i]); } break; case WAVEFORM_TRIANGLE_VARIABLE: if (shapedata) { for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { uint32_t width = (shapedata->data[i] + 0x8000) & 0xFFFF; uint32_t rise = 0xFFFFFFFF / width; uint32_t fall = 0xFFFFFFFF / (0xFFFF - width); uint32_t halfwidth = width << 15; uint32_t n; ph = phasedata[i]; if (ph < halfwidth) { n = (ph >> 16) * rise; *bp++ = ((n >> 16) * magnitude) >> 16; } else if (ph < 0xFFFFFFFF - halfwidth) { n = 0x7FFFFFFF - (((ph - halfwidth) >> 16) * fall); *bp++ = (((int32_t)n >> 16) * magnitude) >> 16; } else { n = ((ph + halfwidth) >> 16) * rise + 0x80000000; *bp++ = (((int32_t)n >> 16) * magnitude) >> 16; } ph += inc; } break; } // else fall through to orginary triangle without shape modulation case WAVEFORM_TRIANGLE: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { ph = phasedata[i]; uint32_t phtop = ph >> 30; if (phtop == 1 || phtop == 2) { *bp++ = ((0xFFFF - (ph >> 15)) * magnitude) >> 16; } else { *bp++ = (((int32_t)ph >> 15) * magnitude) >> 16; } } break; case WAVEFORM_SAMPLE_HOLD: for (i=0; i < AUDIO_BLOCK_SAMPLES; i++) { ph = phasedata[i]; if (ph < priorphase) { // does not work for phase modulation sample = random(magnitude) - (magnitude >> 1); } priorphase = ph; *bp++ = sample; } break; } if (tone_offset) { bp = block->data; end = bp + AUDIO_BLOCK_SAMPLES; do { val1 = *bp; *bp++ = signed_saturate_rshift(val1 + tone_offset, 16, 0); } while (bp < end); } if (shapedata) release(shapedata); transmit(block, 0); release(block); }