qmk_firmware/drivers/painter/tft_panel/qp_tft_panel.c

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// Copyright 2021 Nick Brassel (@tzarc)
// SPDX-License-Identifier: GPL-2.0-or-later
#include "color.h"
#include "qp_internal.h"
#include "qp_comms.h"
#include "qp_draw.h"
#include "qp_tft_panel.h"
#define BYTE_SWAP(x) (((((uint16_t)(x)) >> 8) & 0x00FF) | ((((uint16_t)(x)) << 8) & 0xFF00))
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Quantum Painter API implementations
// Power control
bool qp_tft_panel_power(painter_device_t device, bool power_on) {
struct painter_driver_t * driver = (struct painter_driver_t *)device;
struct tft_panel_dc_reset_painter_driver_vtable_t *vtable = (struct tft_panel_dc_reset_painter_driver_vtable_t *)driver->driver_vtable;
qp_comms_command(device, power_on ? vtable->opcodes.display_on : vtable->opcodes.display_off);
return true;
}
// Screen clear
bool qp_tft_panel_clear(painter_device_t device) {
struct painter_driver_t *driver = (struct painter_driver_t *)device;
driver->driver_vtable->init(device, driver->rotation); // Re-init the LCD
return true;
}
// Screen flush
bool qp_tft_panel_flush(painter_device_t device) {
// No-op, as there's no framebuffer in RAM for this device.
return true;
}
// Viewport to draw to
bool qp_tft_panel_viewport(painter_device_t device, uint16_t left, uint16_t top, uint16_t right, uint16_t bottom) {
struct painter_driver_t * driver = (struct painter_driver_t *)device;
struct tft_panel_dc_reset_painter_driver_vtable_t *vtable = (struct tft_panel_dc_reset_painter_driver_vtable_t *)driver->driver_vtable;
// Fix up the drawing location if required
left += driver->offset_x;
right += driver->offset_x;
top += driver->offset_y;
bottom += driver->offset_y;
// Check if we need to manually swap the window coordinates based on whether or not we're in a sideways rotation
if (vtable->swap_window_coords && (driver->rotation == QP_ROTATION_90 || driver->rotation == QP_ROTATION_270)) {
uint16_t temp;
temp = left;
left = top;
top = temp;
temp = right;
right = bottom;
bottom = temp;
}
if (vtable->num_window_bytes == 1) {
// Set up the x-window
uint8_t xbuf[2] = {left & 0xFF, right & 0xFF};
qp_comms_command_databuf(device, vtable->opcodes.set_column_address, xbuf, sizeof(xbuf));
// Set up the y-window
uint8_t ybuf[2] = {top & 0xFF, bottom & 0xFF};
qp_comms_command_databuf(device, vtable->opcodes.set_row_address, ybuf, sizeof(ybuf));
} else if (vtable->num_window_bytes == 2) {
// Set up the x-window
uint8_t xbuf[4] = {left >> 8, left & 0xFF, right >> 8, right & 0xFF};
qp_comms_command_databuf(device, vtable->opcodes.set_column_address, xbuf, sizeof(xbuf));
// Set up the y-window
uint8_t ybuf[4] = {top >> 8, top & 0xFF, bottom >> 8, bottom & 0xFF};
qp_comms_command_databuf(device, vtable->opcodes.set_row_address, ybuf, sizeof(ybuf));
}
// Lock in the window
qp_comms_command(device, vtable->opcodes.enable_writes);
return true;
}
// Stream pixel data to the current write position in GRAM
bool qp_tft_panel_pixdata(painter_device_t device, const void *pixel_data, uint32_t native_pixel_count) {
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
qp_comms_send(device, pixel_data, native_pixel_count * driver->native_bits_per_pixel / 8);
return true;
}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Convert supplied palette entries into their native equivalents
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bool qp_tft_panel_palette_convert_rgb565_swapped(painter_device_t device, int16_t palette_size, qp_pixel_t *palette) {
for (int16_t i = 0; i < palette_size; ++i) {
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RGB rgb = hsv_to_rgb_nocie((HSV){palette[i].hsv888.h, palette[i].hsv888.s, palette[i].hsv888.v});
uint16_t rgb565 = (((uint16_t)rgb.r) >> 3) << 11 | (((uint16_t)rgb.g) >> 2) << 5 | (((uint16_t)rgb.b) >> 3);
palette[i].rgb565 = BYTE_SWAP(rgb565);
}
return true;
}
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bool qp_tft_panel_palette_convert_rgb888(painter_device_t device, int16_t palette_size, qp_pixel_t *palette) {
for (int16_t i = 0; i < palette_size; ++i) {
RGB rgb = hsv_to_rgb_nocie((HSV){palette[i].hsv888.h, palette[i].hsv888.s, palette[i].hsv888.v});
palette[i].rgb888.r = rgb.r;
palette[i].rgb888.g = rgb.g;
palette[i].rgb888.b = rgb.b;
}
return true;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Append pixels to the target location, keyed by the pixel index
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bool qp_tft_panel_append_pixels_rgb565(painter_device_t device, uint8_t *target_buffer, qp_pixel_t *palette, uint32_t pixel_offset, uint32_t pixel_count, uint8_t *palette_indices) {
uint16_t *buf = (uint16_t *)target_buffer;
for (uint32_t i = 0; i < pixel_count; ++i) {
buf[pixel_offset + i] = palette[palette_indices[i]].rgb565;
}
return true;
}
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bool qp_tft_panel_append_pixels_rgb888(painter_device_t device, uint8_t *target_buffer, qp_pixel_t *palette, uint32_t pixel_offset, uint32_t pixel_count, uint8_t *palette_indices) {
for (uint32_t i = 0; i < pixel_count; ++i) {
target_buffer[(pixel_offset + i) * 3 + 0] = palette[palette_indices[i]].rgb888.r;
target_buffer[(pixel_offset + i) * 3 + 1] = palette[palette_indices[i]].rgb888.g;
target_buffer[(pixel_offset + i) * 3 + 2] = palette[palette_indices[i]].rgb888.b;
}
return true;
}