mirror of
https://github.com/qmk/qmk_firmware.git
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1f2b1dedcc
* Install dependencies before executing unit tests. * Split out UTF-8 decoder. * Fixup python formatting rules. * Add documentation for QGF/QFF and the RLE format used. * Add CLI commands for converting images and fonts. * Add stub rules.mk for QP. * Add stream type. * Add base driver and comms interfaces. * Add support for SPI, SPI+D/C comms drivers. * Include <qp.h> when enabled. * Add base support for SPI+D/C+RST panels, as well as concrete implementation of ST7789. * Add support for GC9A01. * Add support for ILI9341. * Add support for ILI9163. * Add support for SSD1351. * Implement qp_setpixel, including pixdata buffer management. * Implement qp_line. * Implement qp_rect. * Implement qp_circle. * Implement qp_ellipse. * Implement palette interpolation. * Allow for streams to work with either flash or RAM. * Image loading. * Font loading. * QGF palette loading. * Progressive decoder of pixel data supporting Raw+RLE, 1-,2-,4-,8-bpp monochrome and palette-based images. * Image drawing. * Animations. * Font rendering. * Check against 256 colours, dump out the loaded palette if debugging enabled. * Fix build. * AVR is not the intended audience. * `qmk format-c` * Generation fix. * First batch of docs. * More docs and examples. * Review comments. * Public API documentation.
295 lines
13 KiB
C
295 lines
13 KiB
C
// Copyright 2021-2022 Nick Brassel (@tzarc)
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// Copyright 2021 Paul Cotter (@gr1mr3aver)
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// SPDX-License-Identifier: GPL-2.0-or-later
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#include "qp_internal.h"
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#include "qp_comms.h"
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#include "qp_draw.h"
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#include "qgf.h"
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_Static_assert((QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE > 0) && (QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE % 16) == 0, "QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE needs to be a non-zero multiple of 16");
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Global variables
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//
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// NOTE: The variables in this section are intentionally outside a stack frame. They are able to be defined with larger
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// sizes than the normal stack frames would allow, and as such need to be external.
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//
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// **** DO NOT refactor this and decide to place the variables inside the function calling them -- you will ****
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// **** very likely get artifacts rendered to the screen as a result. ****
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//
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// Buffer used for transmitting native pixel data to the downstream device.
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uint8_t qp_internal_global_pixdata_buffer[QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE];
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// Static buffer to contain a generated color palette
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static bool generated_palette = false;
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static int16_t generated_steps = -1;
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static qp_pixel_t interpolated_fg_hsv888;
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static qp_pixel_t interpolated_bg_hsv888;
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#if QUANTUM_PAINTER_SUPPORTS_256_PALETTE
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qp_pixel_t qp_internal_global_pixel_lookup_table[256];
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#else
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qp_pixel_t qp_internal_global_pixel_lookup_table[16];
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#endif
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Helpers
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uint32_t qp_internal_num_pixels_in_buffer(painter_device_t device) {
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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return ((QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE * 8) / driver->native_bits_per_pixel);
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}
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// qp_setpixel internal implementation, but accepts a buffer with pre-converted native pixel. Only the first pixel is used.
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bool qp_internal_setpixel_impl(painter_device_t device, uint16_t x, uint16_t y) {
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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return driver->driver_vtable->viewport(device, x, y, x, y) && driver->driver_vtable->pixdata(device, qp_internal_global_pixdata_buffer, 1);
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}
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// Fills the global native pixel buffer with equivalent pixels matching the supplied HSV
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void qp_internal_fill_pixdata(painter_device_t device, uint32_t num_pixels, uint8_t hue, uint8_t sat, uint8_t val) {
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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uint32_t pixels_in_pixdata = qp_internal_num_pixels_in_buffer(device);
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num_pixels = QP_MIN(pixels_in_pixdata, num_pixels);
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// Convert the color to native pixel format
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qp_pixel_t color = {.hsv888 = {.h = hue, .s = sat, .v = val}};
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driver->driver_vtable->palette_convert(device, 1, &color);
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// Append the required number of pixels
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uint8_t palette_idx = 0;
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for (uint32_t i = 0; i < num_pixels; ++i) {
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driver->driver_vtable->append_pixels(device, qp_internal_global_pixdata_buffer, &color, i, 1, &palette_idx);
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}
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}
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// Resets the global palette so that it can be regenerated. Only needed if the colors are identical, but a different display is used with a different internal pixel format.
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void qp_internal_invalidate_palette(void) {
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generated_palette = false;
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generated_steps = -1;
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}
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// Interpolates between two colors to generate a palette
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bool qp_internal_interpolate_palette(qp_pixel_t fg_hsv888, qp_pixel_t bg_hsv888, int16_t steps) {
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// Check if we need to generate a new palette -- if the input parameters match then assume the palette can stay unchanged.
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// This may present a problem if using the same parameters but a different screen converts pixels -- use qp_internal_invalidate_palette() to reset.
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if (generated_palette == true && generated_steps == steps && memcmp(&interpolated_fg_hsv888, &fg_hsv888, sizeof(fg_hsv888)) == 0 && memcmp(&interpolated_bg_hsv888, &bg_hsv888, sizeof(bg_hsv888)) == 0) {
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// We already have the correct palette, no point regenerating it.
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return false;
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}
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// Save the parameters so we know whether we can skip generation
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generated_palette = true;
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generated_steps = steps;
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interpolated_fg_hsv888 = fg_hsv888;
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interpolated_bg_hsv888 = bg_hsv888;
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int16_t hue_fg = fg_hsv888.hsv888.h;
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int16_t hue_bg = bg_hsv888.hsv888.h;
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// Make sure we take the "shortest" route from one hue to the other
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if ((hue_fg - hue_bg) >= 128) {
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hue_bg += 256;
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} else if ((hue_fg - hue_bg) <= -128) {
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hue_bg -= 256;
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}
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// Interpolate each of the lookup table entries
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for (int16_t i = 0; i < steps; ++i) {
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qp_internal_global_pixel_lookup_table[i].hsv888.h = (uint8_t)((hue_fg - hue_bg) * i / (steps - 1) + hue_bg);
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qp_internal_global_pixel_lookup_table[i].hsv888.s = (uint8_t)((fg_hsv888.hsv888.s - bg_hsv888.hsv888.s) * i / (steps - 1) + bg_hsv888.hsv888.s);
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qp_internal_global_pixel_lookup_table[i].hsv888.v = (uint8_t)((fg_hsv888.hsv888.v - bg_hsv888.hsv888.v) * i / (steps - 1) + bg_hsv888.hsv888.v);
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qp_dprintf("qp_internal_interpolate_palette: %3d of %d -- H: %3d, S: %3d, V: %3d\n", (int)(i + 1), (int)steps, (int)qp_internal_global_pixel_lookup_table[i].hsv888.h, (int)qp_internal_global_pixel_lookup_table[i].hsv888.s, (int)qp_internal_global_pixel_lookup_table[i].hsv888.v);
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}
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return true;
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}
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// Helper shared between image and font rendering -- sets up the global palette to match the palette block specified in the asset. Expects the stream to be positioned at the start of the block header.
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bool qp_internal_load_qgf_palette(qp_stream_t *stream, uint8_t bpp) {
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qgf_palette_v1_t palette_descriptor;
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if (qp_stream_read(&palette_descriptor, sizeof(qgf_palette_v1_t), 1, stream) != 1) {
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qp_dprintf("Failed to read palette_descriptor, expected length was not %d\n", (int)sizeof(qgf_palette_v1_t));
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return false;
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}
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// BPP determines the number of palette entries, each entry is a HSV888 triplet.
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const uint16_t palette_entries = 1u << bpp;
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// Ensure we aren't reusing any palette
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qp_internal_invalidate_palette();
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// Read the palette entries
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for (uint16_t i = 0; i < palette_entries; ++i) {
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// Read the palette entry
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qgf_palette_entry_v1_t entry;
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if (qp_stream_read(&entry, sizeof(qgf_palette_entry_v1_t), 1, stream) != 1) {
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return false;
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}
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// Update the lookup table
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qp_internal_global_pixel_lookup_table[i].hsv888.h = entry.h;
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qp_internal_global_pixel_lookup_table[i].hsv888.s = entry.s;
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qp_internal_global_pixel_lookup_table[i].hsv888.v = entry.v;
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qp_dprintf("qp_internal_load_qgf_palette: %3d of %d -- H: %3d, S: %3d, V: %3d\n", (int)(i + 1), (int)palette_entries, (int)qp_internal_global_pixel_lookup_table[i].hsv888.h, (int)qp_internal_global_pixel_lookup_table[i].hsv888.s, (int)qp_internal_global_pixel_lookup_table[i].hsv888.v);
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}
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return true;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Quantum Painter External API: qp_setpixel
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bool qp_setpixel(painter_device_t device, uint16_t x, uint16_t y, uint8_t hue, uint8_t sat, uint8_t val) {
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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if (!driver->validate_ok) {
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qp_dprintf("qp_setpixel: fail (validation_ok == false)\n");
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return false;
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}
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if (!qp_comms_start(device)) {
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qp_dprintf("Failed to start comms in qp_setpixel\n");
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return false;
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}
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qp_internal_fill_pixdata(device, 1, hue, sat, val);
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bool ret = qp_internal_setpixel_impl(device, x, y);
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qp_comms_stop(device);
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qp_dprintf("qp_setpixel: %s\n", ret ? "ok" : "fail");
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return ret;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Quantum Painter External API: qp_line
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bool qp_line(painter_device_t device, uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, uint8_t hue, uint8_t sat, uint8_t val) {
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if (x0 == x1 || y0 == y1) {
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qp_dprintf("qp_line(%d, %d, %d, %d): entry (deferring to qp_rect)\n", (int)x0, (int)y0, (int)x1, (int)y1);
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bool ret = qp_rect(device, x0, y0, x1, y1, hue, sat, val, true);
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qp_dprintf("qp_line(%d, %d, %d, %d): %s (deferred to qp_rect)\n", (int)x0, (int)y0, (int)x1, (int)y1, ret ? "ok" : "fail");
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return ret;
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}
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qp_dprintf("qp_line(%d, %d, %d, %d): entry\n", (int)x0, (int)y0, (int)x1, (int)y1);
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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if (!driver->validate_ok) {
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qp_dprintf("qp_line: fail (validation_ok == false)\n");
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return false;
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}
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if (!qp_comms_start(device)) {
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qp_dprintf("Failed to start comms in qp_line\n");
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return false;
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}
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qp_internal_fill_pixdata(device, 1, hue, sat, val);
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// draw angled line using Bresenham's algo
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int16_t x = ((int16_t)x0);
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int16_t y = ((int16_t)y0);
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int16_t slopex = ((int16_t)x0) < ((int16_t)x1) ? 1 : -1;
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int16_t slopey = ((int16_t)y0) < ((int16_t)y1) ? 1 : -1;
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int16_t dx = abs(((int16_t)x1) - ((int16_t)x0));
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int16_t dy = -abs(((int16_t)y1) - ((int16_t)y0));
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int16_t e = dx + dy;
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int16_t e2 = 2 * e;
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bool ret = true;
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while (x != x1 || y != y1) {
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if (!qp_internal_setpixel_impl(device, x, y)) {
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ret = false;
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break;
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}
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e2 = 2 * e;
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if (e2 >= dy) {
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e += dy;
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x += slopex;
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}
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if (e2 <= dx) {
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e += dx;
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y += slopey;
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}
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}
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// draw the last pixel
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if (!qp_internal_setpixel_impl(device, x, y)) {
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ret = false;
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}
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qp_comms_stop(device);
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qp_dprintf("qp_line(%d, %d, %d, %d): %s\n", (int)x0, (int)y0, (int)x1, (int)y1, ret ? "ok" : "fail");
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return ret;
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}
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////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
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// Quantum Painter External API: qp_rect
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bool qp_internal_fillrect_helper_impl(painter_device_t device, uint16_t left, uint16_t top, uint16_t right, uint16_t bottom) {
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uint32_t pixels_in_pixdata = qp_internal_num_pixels_in_buffer(device);
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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uint16_t l = QP_MIN(left, right);
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uint16_t r = QP_MAX(left, right);
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uint16_t t = QP_MIN(top, bottom);
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uint16_t b = QP_MAX(top, bottom);
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uint16_t w = r - l + 1;
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uint16_t h = b - t + 1;
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uint32_t remaining = w * h;
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driver->driver_vtable->viewport(device, l, t, r, b);
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while (remaining > 0) {
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uint32_t transmit = QP_MIN(remaining, pixels_in_pixdata);
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if (!driver->driver_vtable->pixdata(device, qp_internal_global_pixdata_buffer, transmit)) {
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return false;
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}
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remaining -= transmit;
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}
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return true;
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}
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bool qp_rect(painter_device_t device, uint16_t left, uint16_t top, uint16_t right, uint16_t bottom, uint8_t hue, uint8_t sat, uint8_t val, bool filled) {
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qp_dprintf("qp_rect(%d, %d, %d, %d): entry\n", (int)left, (int)top, (int)right, (int)bottom);
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struct painter_driver_t *driver = (struct painter_driver_t *)device;
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if (!driver->validate_ok) {
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qp_dprintf("qp_rect: fail (validation_ok == false)\n");
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return false;
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}
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// Cater for cases where people have submitted the coordinates backwards
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uint16_t l = QP_MIN(left, right);
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uint16_t r = QP_MAX(left, right);
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uint16_t t = QP_MIN(top, bottom);
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uint16_t b = QP_MAX(top, bottom);
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uint16_t w = r - l + 1;
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uint16_t h = b - t + 1;
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bool ret = true;
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if (!qp_comms_start(device)) {
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qp_dprintf("Failed to start comms in qp_rect\n");
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return false;
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}
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if (filled) {
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// Fill up the pixdata buffer with the required number of native pixels
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qp_internal_fill_pixdata(device, w * h, hue, sat, val);
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// Perform the draw
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ret = qp_internal_fillrect_helper_impl(device, l, t, r, b);
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} else {
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// Fill up the pixdata buffer with the required number of native pixels
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qp_internal_fill_pixdata(device, QP_MAX(w, h), hue, sat, val);
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// Draw 4x filled single-width rects to create an outline
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if (!qp_internal_fillrect_helper_impl(device, l, t, r, t) || !qp_internal_fillrect_helper_impl(device, l, b, r, b) || !qp_internal_fillrect_helper_impl(device, l, t + 1, l, b - 1) || !qp_internal_fillrect_helper_impl(device, r, t + 1, r, b - 1)) {
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ret = false;
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}
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}
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qp_comms_stop(device);
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qp_dprintf("qp_rect(%d, %d, %d, %d): %s\n", (int)l, (int)t, (int)r, (int)b, ret ? "ok" : "fail");
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return ret;
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}
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