/* * This file is part of the MicroPython project, http://micropython.org/ * * The MIT License (MIT) * * Copyright (c) 2019 Jeff Epler for Adafruit Industries * * 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 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 "common-hal/audiopwmio/PWMAudioOut.h" #include #include #include #include "extmod/vfs_fat.h" #include "py/gc.h" #include "py/mperrno.h" #include "py/runtime.h" #include "shared-bindings/pwmio/PWMOut.h" #include "shared-bindings/audiopwmio/PWMAudioOut.h" #include "shared-bindings/microcontroller/__init__.h" #include "shared-bindings/microcontroller/Pin.h" #include "shared-bindings/microcontroller/Processor.h" #include "src/rp2040/hardware_structs/include/hardware/structs/dma.h" #include "src/rp2_common/hardware_pwm/include/hardware/pwm.h" // The PWM clock frequency is base_clock_rate / PWM_TOP, typically 125_000_000 / PWM_TOP. // We pick BITS_PER_SAMPLE so we get a clock frequency that is above what would cause aliasing. #define BITS_PER_SAMPLE 10 #define SAMPLE_BITS_TO_DISCARD (16 - BITS_PER_SAMPLE) #define PWM_TOP ((1 << BITS_PER_SAMPLE) - 1) static uint32_t gcd(uint32_t a, uint32_t b) { while (b) { uint32_t tmp = a % b; a = b; b = tmp; } return a; } static uint32_t limit_denominator(uint32_t max_denominator, uint32_t num_in, uint32_t den_in, uint32_t *den_out) { // Algorithm based on Python's limit_denominator uint32_t p0 = 0, q0 = 1, p1 = 1, q1 = 0; uint32_t d = den_in, n = num_in; uint32_t g = gcd(n, d); d /= g; n /= g; if (d < max_denominator) { *den_out = d; return n; } while (1) { uint32_t a = n / d; uint32_t q2 = q0 + a * q1; if (q2 > max_denominator) { break; } uint32_t p_tmp = p0 + a * p1; p0 = p1; q0 = q1; p1 = p_tmp; q1 = q2; uint32_t d_tmp = n - a * d; n = d; d = d_tmp; } uint32_t k = (max_denominator - q0) / q1; uint32_t bound1_num = p0 + k * p1, bound1_den = q0 + k * q1; uint32_t bound2_num = p1, bound2_den = q1; if (fabsf((float)bound1_num / bound1_den - (float)num_in / den_in) <= fabsf((float)bound2_num / bound2_den - (float)num_in / den_in)) { *den_out = bound2_den; return bound2_num; } *den_out = bound1_den; return bound1_num; } void audiopwmout_reset() { for (size_t i = 0; i < NUM_DMA_TIMERS; i++) { dma_hw->timer[i] = 0; } } // Caller validates that pins are free. void common_hal_audiopwmio_pwmaudioout_construct(audiopwmio_pwmaudioout_obj_t *self, const mcu_pin_obj_t *left_channel, const mcu_pin_obj_t *right_channel, uint16_t quiescent_value) { self->stereo = right_channel != NULL; if (self->stereo) { if (pwm_gpio_to_slice_num(left_channel->number) != pwm_gpio_to_slice_num(right_channel->number)) { mp_raise_ValueError(translate("Pins must share PWM slice")); } if (pwm_gpio_to_channel(left_channel->number) != 0) { mp_raise_ValueError(translate("Stereo left must be on PWM channel A")); } if (pwm_gpio_to_channel(right_channel->number) != 1) { mp_raise_ValueError(translate("Stereo right must be on PWM channel B")); } } // Typically pwmout doesn't let us change frequency with two objects on the // same PWM slice. However, we have private access to it so we can do what // we want. ;-) We mark ourselves variable only if we're a mono output to // prevent other PWM use on the other channel. If stereo, we say fixed // frequency so we can allocate with ourselves. // We don't actually know our frequency yet. It is set when // pwmio_pwmout_set_top() is called. This value is unimportant; it just needs to be valid. const uint32_t frequency = 12000000; // Make sure the PWMOut's are "deinited" by default. self->left_pwm.pin = NULL; self->right_pwm.pin = NULL; pwmout_result_t result = common_hal_pwmio_pwmout_construct(&self->left_pwm, left_channel, 0, frequency, !self->stereo); if (result == PWMOUT_OK && right_channel != NULL) { result = common_hal_pwmio_pwmout_construct(&self->right_pwm, right_channel, 0, frequency, false); if (result != PWMOUT_OK) { common_hal_pwmio_pwmout_deinit(&self->left_pwm); } } if (result != PWMOUT_OK) { mp_raise_RuntimeError(translate("All timers in use")); } self->quiescent_value = quiescent_value >> SAMPLE_BITS_TO_DISCARD; common_hal_pwmio_pwmout_set_duty_cycle(&self->left_pwm, self->quiescent_value); pwmio_pwmout_set_top(&self->left_pwm, PWM_TOP); if (self->stereo) { common_hal_pwmio_pwmout_set_duty_cycle(&self->right_pwm, self->quiescent_value); pwmio_pwmout_set_top(&self->right_pwm, PWM_TOP); } audio_dma_init(&self->dma); self->pacing_timer = NUM_DMA_TIMERS; } bool common_hal_audiopwmio_pwmaudioout_deinited(audiopwmio_pwmaudioout_obj_t *self) { return common_hal_pwmio_pwmout_deinited(&self->left_pwm); } void common_hal_audiopwmio_pwmaudioout_deinit(audiopwmio_pwmaudioout_obj_t *self) { if (common_hal_audiopwmio_pwmaudioout_deinited(self)) { return; } if (common_hal_audiopwmio_pwmaudioout_get_playing(self)) { common_hal_audiopwmio_pwmaudioout_stop(self); } // TODO: ramp the pwm down from quiescent value to 0 common_hal_pwmio_pwmout_deinit(&self->left_pwm); common_hal_pwmio_pwmout_deinit(&self->right_pwm); audio_dma_deinit(&self->dma); } void common_hal_audiopwmio_pwmaudioout_play(audiopwmio_pwmaudioout_obj_t *self, mp_obj_t sample, bool loop) { if (common_hal_audiopwmio_pwmaudioout_get_playing(self)) { common_hal_audiopwmio_pwmaudioout_stop(self); } // TODO: Share pacing timers based on frequency. size_t pacing_timer = NUM_DMA_TIMERS; for (size_t i = 0; i < NUM_DMA_TIMERS; i++) { if (dma_hw->timer[i] == 0) { pacing_timer = i; break; } } if (pacing_timer == NUM_DMA_TIMERS) { mp_raise_RuntimeError(translate("No DMA pacing timer found")); } uint32_t tx_register = (uint32_t)&pwm_hw->slice[self->left_pwm.slice].cc; if (self->stereo) { // Shift the destination if we are outputting to both PWM channels. tx_register += self->left_pwm.ab_channel * sizeof(uint16_t); } self->pacing_timer = pacing_timer; // Playback with two independent clocks. One is the sample rate which // determines when we push a new sample to the PWM slice. The second is the // PWM frequency itself. // Determine the DMA divisor. The RP2040 has four pacing timers we can use // to trigger the DMA. Each has a 16 bit fractional divisor system clock * X / Y where X and Y // are 16-bit. uint32_t sample_rate = audiosample_sample_rate(sample); uint32_t system_clock = common_hal_mcu_processor_get_frequency(); uint32_t best_denominator; uint32_t best_numerator = limit_denominator(0xffff, sample_rate, system_clock, &best_denominator); dma_hw->timer[pacing_timer] = best_numerator << 16 | best_denominator; audio_dma_result result = audio_dma_setup_playback( &self->dma, sample, loop, false, // single channel 0, // audio channel false, // output signed BITS_PER_SAMPLE, (uint32_t)tx_register, // output register: PWM cc register 0x3b + pacing_timer); // data request line if (result == AUDIO_DMA_DMA_BUSY) { common_hal_audiopwmio_pwmaudioout_stop(self); mp_raise_RuntimeError(translate("No DMA channel found")); } if (result == AUDIO_DMA_MEMORY_ERROR) { common_hal_audiopwmio_pwmaudioout_stop(self); mp_raise_RuntimeError(translate("Unable to allocate buffers for signed conversion")); } // OK! We got all of the resources we need and dma is ready. } void common_hal_audiopwmio_pwmaudioout_stop(audiopwmio_pwmaudioout_obj_t *self) { if (self->pacing_timer < NUM_DMA_TIMERS) { dma_hw->timer[self->pacing_timer] = 0; self->pacing_timer = NUM_DMA_TIMERS; } audio_dma_stop(&self->dma); // Set to quiescent level. common_hal_pwmio_pwmout_set_duty_cycle(&self->left_pwm, self->quiescent_value); pwmio_pwmout_set_top(&self->left_pwm, PWM_TOP); if (self->stereo) { common_hal_pwmio_pwmout_set_duty_cycle(&self->right_pwm, self->quiescent_value); pwmio_pwmout_set_top(&self->right_pwm, PWM_TOP); } } bool common_hal_audiopwmio_pwmaudioout_get_playing(audiopwmio_pwmaudioout_obj_t *self) { bool playing = audio_dma_get_playing(&self->dma); if (!playing && self->pacing_timer < NUM_DMA_TIMERS) { common_hal_audiopwmio_pwmaudioout_stop(self); } return playing; } void common_hal_audiopwmio_pwmaudioout_pause(audiopwmio_pwmaudioout_obj_t *self) { audio_dma_pause(&self->dma); } void common_hal_audiopwmio_pwmaudioout_resume(audiopwmio_pwmaudioout_obj_t *self) { audio_dma_resume(&self->dma); } bool common_hal_audiopwmio_pwmaudioout_get_paused(audiopwmio_pwmaudioout_obj_t *self) { return audio_dma_get_paused(&self->dma); }