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// Copyright 2022 The Pigweed Authors
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not
// use this file except in compliance with the License. You may obtain a copy of
// the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations under
// the License.
#include <cstdint>
#include "app_common/common.h"
#define LIB_CMSIS_CORE 0
#define LIB_PICO_STDIO_SEMIHOSTING 0
#include "hardware/gpio.h"
#include "hardware/i2c.h"
#include "hardware/pwm.h"
#include "hardware/vreg.h"
#include "pico/stdlib.h"
#include "pw_digital_io_rp2040/digital_io.h"
#include "pw_i2c_rp2040/initiator.h"
#include "pw_log/log.h"
#if USE_PIO
#include "pw_pixel_pusher_rp2040_pio/pixel_pusher.h"
#endif
#include "pw_spi/chip_selector_digital_out.h"
#include "pw_spi_rp2040/initiator.h"
#include "pw_status/status.h"
#include "pw_sync/borrow.h"
#include "pw_sync/mutex.h"
#if defined(DISPLAY_TYPE_ILI9341)
#include "pw_display_driver_ili9341/display_driver.h"
using DisplayDriver = pw::display_driver::DisplayDriverILI9341;
#elif defined(DISPLAY_TYPE_ST7735)
#include "pw_display_driver_st7735/display_driver.h"
using DisplayDriver = pw::display_driver::DisplayDriverST7735;
#elif defined(DISPLAY_TYPE_ST7789)
#include "pw_display_driver_st7789/display_driver.h"
using DisplayDriver = pw::display_driver::DisplayDriverST7789;
#elif defined(DISPLAY_TYPE_ST7789_PIO)
#include "pw_display_driver_st7789/display_driver.h"
using DisplayDriver = pw::display_driver::DisplayDriverST7789;
#else
#error "Undefined display type"
#endif
using pw::Status;
using pw::digital_io::Rp2040Config;
using pw::digital_io::Rp2040DigitalIn;
using pw::digital_io::Rp2040DigitalInOut;
using pw::display::Display;
using pw::framebuffer::Framebuffer;
using pw::framebuffer::PixelFormat;
using pw::framebuffer_pool::FramebufferPool;
using pw::spi::Device;
using pw::spi::DigitalOutChipSelector;
using pw::spi::Initiator;
using pw::spi::Rp2040Initiator;
using pw::sync::Borrowable;
using pw::sync::VirtualMutex;
namespace {
// Pico spi0 Pins
#define SPI_PORT spi0
struct SpiValues {
SpiValues(pw::spi::Config config,
pw::spi::ChipSelector& selector,
pw::sync::VirtualMutex& initiator_mutex);
pw::spi::Rp2040Initiator initiator;
pw::sync::Borrowable<pw::spi::Initiator> borrowable_initiator;
pw::spi::Device device;
};
static_assert(DISPLAY_WIDTH > 0);
static_assert(DISPLAY_HEIGHT > 0);
constexpr uint16_t kDisplayScaleFactor = 2;
constexpr uint16_t kFramebufferWidth =
FRAMEBUFFER_WIDTH >= 0 ? FRAMEBUFFER_WIDTH / kDisplayScaleFactor
: DISPLAY_WIDTH / kDisplayScaleFactor;
constexpr uint16_t kFramebufferHeight = DISPLAY_HEIGHT / kDisplayScaleFactor;
constexpr pw::math::Size<uint16_t> kDisplaySize{DISPLAY_WIDTH, DISPLAY_HEIGHT};
constexpr size_t kNumPixels = kFramebufferWidth * kFramebufferHeight;
constexpr uint16_t kFramebufferRowBytes = sizeof(uint16_t) * kFramebufferWidth;
constexpr uint32_t kBaudRate = 31'250'000;
constexpr pw::spi::Config kSpiConfig8Bit{
.polarity = pw::spi::ClockPolarity::kActiveHigh,
.phase = pw::spi::ClockPhase::kRisingEdge,
.bits_per_word = pw::spi::BitsPerWord(8),
.bit_order = pw::spi::BitOrder::kMsbFirst,
};
constexpr pw::spi::Config kSpiConfig16Bit{
.polarity = pw::spi::ClockPolarity::kActiveHigh,
.phase = pw::spi::ClockPhase::kRisingEdge,
.bits_per_word = pw::spi::BitsPerWord(16),
.bit_order = pw::spi::BitOrder::kMsbFirst,
};
Rp2040DigitalInOut s_display_dc_pin({
.pin = DISPLAY_DC_GPIO,
.polarity = pw::digital_io::Polarity::kActiveHigh,
});
#if DISPLAY_RESET_GPIO != -1
Rp2040DigitalInOut s_display_reset_pin({
.pin = DISPLAY_RESET_GPIO,
.polarity = pw::digital_io::Polarity::kActiveLow,
});
#endif
#if DISPLAY_TE_GPIO != -1
Rp2040DigitalIn s_display_tear_effect_pin({
.pin = DISPLAY_TE_GPIO,
.polarity = pw::digital_io::Polarity::kActiveHigh,
});
#endif
Rp2040DigitalInOut s_display_cs_pin({
.pin = DISPLAY_CS_GPIO,
.polarity = pw::digital_io::Polarity::kActiveLow,
});
DigitalOutChipSelector s_spi_chip_selector(s_display_cs_pin);
Rp2040Initiator s_spi_initiator(SPI_PORT);
VirtualMutex s_spi_initiator_mutex;
Borrowable<Initiator> s_borrowable_spi_initiator(s_spi_initiator,
s_spi_initiator_mutex);
SpiValues s_spi_8_bit(kSpiConfig8Bit,
s_spi_chip_selector,
s_spi_initiator_mutex);
SpiValues s_spi_16_bit(kSpiConfig16Bit,
s_spi_chip_selector,
s_spi_initiator_mutex);
#if USE_PIO
pw::pixel_pusher::PixelPusherRp2040Pio s_pixel_pusher(DISPLAY_DC_GPIO,
DISPLAY_CS_GPIO,
SPI_MOSI_GPIO,
SPI_CLOCK_GPIO,
DISPLAY_TE_GPIO,
pio0);
#endif
uint16_t s_pixel_data1[kNumPixels];
uint16_t s_pixel_data2[kNumPixels];
const pw::Vector<void*, 2> s_pixel_buffers{s_pixel_data1, s_pixel_data2};
pw::framebuffer_pool::FramebufferPool s_fb_pool({
.fb_addr = s_pixel_buffers,
.dimensions = {kFramebufferWidth, kFramebufferHeight},
.row_bytes = kFramebufferRowBytes,
.pixel_format = PixelFormat::RGB565,
});
DisplayDriver s_display_driver({
.data_cmd_gpio = s_display_dc_pin.as<pw::digital_io::DigitalOut>(),
.spi_cs_gpio = s_display_cs_pin.as<pw::digital_io::DigitalOut>(),
#if DISPLAY_RESET_GPIO != -1
.reset_gpio = &s_display_reset_pin.as<pw::digital_io::DigitalOut>(),
#else
.reset_gpio = nullptr,
#endif
#if DISPLAY_TE_GPIO != -1
.tear_effect_gpio = &s_display_tear_effect_pin,
#else
.tear_effect_gpio = nullptr,
#endif
.spi_device_8_bit = s_spi_8_bit.device,
.spi_device_16_bit = s_spi_16_bit.device,
#if USE_PIO
.pixel_pusher = &s_pixel_pusher,
#endif
});
Display s_display(s_display_driver, kDisplaySize, s_fb_pool);
#if BACKLIGHT_GPIO != -1
void SetBacklight(uint16_t brightness) {
pwm_config cfg = pwm_get_default_config();
pwm_set_wrap(pwm_gpio_to_slice_num(BACKLIGHT_GPIO), 65535);
pwm_init(pwm_gpio_to_slice_num(BACKLIGHT_GPIO), &cfg, true);
gpio_set_function(BACKLIGHT_GPIO, GPIO_FUNC_PWM);
pwm_set_gpio_level(BACKLIGHT_GPIO, brightness);
}
#endif
SpiValues::SpiValues(pw::spi::Config config,
pw::spi::ChipSelector& selector,
pw::sync::VirtualMutex& initiator_mutex)
: initiator(SPI_PORT),
borrowable_initiator(initiator, initiator_mutex),
device(borrowable_initiator, config, selector) {}
constexpr pw::i2c::Rp2040Initiator::Config ki2cConfig{
.clock_frequency = 400'000,
.sda_pin = 4,
.scl_pin = 5,
};
pw::i2c::Rp2040Initiator i2c_bus(ki2cConfig, i2c0);
} // namespace
// static
Status Common::Init() {
#if OVERCLOCK_250
// Overvolt for a stable 250MHz on some RP2040s
vreg_set_voltage(VREG_VOLTAGE_1_20);
sleep_ms(10);
set_sys_clock_khz(250000, false);
#endif
// Initialize all of the present standard stdio types that are linked into the
// binary.
stdio_init_all();
// Set up the default UART and assign it to the default GPIO's.
setup_default_uart();
s_display_cs_pin.Enable();
s_display_dc_pin.Enable();
#if DISPLAY_RESET_GPIO != -1
s_display_reset_pin.Enable();
#endif
#if DISPLAY_TE_GPIO != -1
s_display_tear_effect_pin.Enable();
#endif
i2c_bus.Enable();
#if BACKLIGHT_GPIO != -1
SetBacklight(0xffff); // Full brightness.
#endif
unsigned actual_baudrate = spi_init(SPI_PORT, kBaudRate);
PW_LOG_DEBUG("Actual Baudrate: %u", actual_baudrate);
#if SPI_MISO_GPIO != -1
gpio_set_function(SPI_MISO_GPIO, GPIO_FUNC_SPI);
#endif
gpio_set_function(SPI_CLOCK_GPIO, GPIO_FUNC_SPI);
gpio_set_function(SPI_MOSI_GPIO, GPIO_FUNC_SPI);
#if USE_PIO
// Init the display before the pixel pusher.
s_display_driver.Init();
auto result = s_pixel_pusher.Init(s_fb_pool);
s_pixel_pusher.SetPixelDouble(true);
return result;
#else
return s_display_driver.Init();
#endif
}
// static
pw::display::Display& Common::GetDisplay() { return s_display; }