kopia lustrzana https://github.com/Aircoookie/WLED
595 wiersze
24 KiB
C++
595 wiersze
24 KiB
C++
/*
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FX_2Dfcn.cpp contains all 2D utility functions
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LICENSE
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The MIT License (MIT)
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Copyright (c) 2022 Blaz Kristan (https://blaz.at/home)
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Permission is hereby granted, free of charge, to any person obtaining a copy
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of this software and associated documentation files (the "Software"), to deal
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in the Software without restriction, including without limitation the rights
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to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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copies of the Software, and to permit persons to whom the Software is
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furnished to do so, subject to the following conditions:
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The above copyright notice and this permission notice shall be included in
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all copies or substantial portions of the Software.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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THE SOFTWARE.
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Parts of the code adapted from WLED Sound Reactive
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*/
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#include "wled.h"
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#include "FX.h"
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#include "palettes.h"
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// setUpMatrix() - constructs ledmap array from matrix of panels with WxH pixels
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// this converts physical (possibly irregular) LED arrangement into well defined
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// array of logical pixels: fist entry corresponds to left-topmost logical pixel
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// followed by horizontal pixels, when Segment::maxWidth logical pixels are added they
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// are followed by next row (down) of Segment::maxWidth pixels (and so forth)
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// note: matrix may be comprised of multiple panels each with different orientation
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// but ledmap takes care of that. ledmap is constructed upon initialization
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// so matrix should disable regular ledmap processing
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void WS2812FX::setUpMatrix() {
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#ifndef WLED_DISABLE_2D
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// erase old ledmap, just in case.
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if (customMappingTable != nullptr) delete[] customMappingTable;
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customMappingTable = nullptr;
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customMappingSize = 0;
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// isMatrix is set in cfg.cpp or set.cpp
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if (isMatrix) {
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// calculate width dynamically because it will have gaps
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Segment::maxWidth = 1;
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Segment::maxHeight = 1;
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for (size_t i = 0; i < panel.size(); i++) {
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Panel &p = panel[i];
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if (p.xOffset + p.width > Segment::maxWidth) {
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Segment::maxWidth = p.xOffset + p.width;
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}
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if (p.yOffset + p.height > Segment::maxHeight) {
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Segment::maxHeight = p.yOffset + p.height;
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}
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}
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// safety check
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if (Segment::maxWidth * Segment::maxHeight > MAX_LEDS || Segment::maxWidth <= 1 || Segment::maxHeight <= 1) {
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DEBUG_PRINTLN(F("2D Bounds error."));
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isMatrix = false;
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Segment::maxWidth = _length;
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Segment::maxHeight = 1;
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panels = 0;
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panel.clear(); // release memory allocated by panels
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resetSegments();
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return;
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}
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customMappingTable = new uint16_t[Segment::maxWidth * Segment::maxHeight];
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if (customMappingTable != nullptr) {
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customMappingSize = Segment::maxWidth * Segment::maxHeight;
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// fill with empty in case we don't fill the entire matrix
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for (size_t i = 0; i< customMappingSize; i++) {
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customMappingTable[i] = (uint16_t)-1;
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}
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// we will try to load a "gap" array (a JSON file)
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// the array has to have the same amount of values as mapping array (or larger)
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// "gap" array is used while building ledmap (mapping array)
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// and discarded afterwards as it has no meaning after the process
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// content of the file is just raw JSON array in the form of [val1,val2,val3,...]
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// there are no other "key":"value" pairs in it
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// allowed values are: -1 (missing pixel/no LED attached), 0 (inactive/unused pixel), 1 (active/used pixel)
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char fileName[32]; strcpy_P(fileName, PSTR("/2d-gaps.json")); // reduce flash footprint
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bool isFile = WLED_FS.exists(fileName);
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size_t gapSize = 0;
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int8_t *gapTable = nullptr;
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if (isFile && requestJSONBufferLock(20)) {
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DEBUG_PRINT(F("Reading LED gap from "));
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DEBUG_PRINTLN(fileName);
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// read the array into global JSON buffer
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if (readObjectFromFile(fileName, nullptr, &doc)) {
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// the array is similar to ledmap, except it has only 3 values:
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// -1 ... missing pixel (do not increase pixel count)
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// 0 ... inactive pixel (it does count, but should be mapped out (-1))
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// 1 ... active pixel (it will count and will be mapped)
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JsonArray map = doc.as<JsonArray>();
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gapSize = map.size();
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if (!map.isNull() && gapSize >= customMappingSize) { // not an empty map
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gapTable = new int8_t[gapSize];
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if (gapTable) for (size_t i = 0; i < gapSize; i++) {
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gapTable[i] = constrain(map[i], -1, 1);
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}
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}
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}
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DEBUG_PRINTLN(F("Gaps loaded."));
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releaseJSONBufferLock();
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}
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uint16_t x, y, pix=0; //pixel
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for (size_t pan = 0; pan < panel.size(); pan++) {
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Panel &p = panel[pan];
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uint16_t h = p.vertical ? p.height : p.width;
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uint16_t v = p.vertical ? p.width : p.height;
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for (size_t j = 0; j < v; j++){
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for(size_t i = 0; i < h; i++) {
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y = (p.vertical?p.rightStart:p.bottomStart) ? v-j-1 : j;
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x = (p.vertical?p.bottomStart:p.rightStart) ? h-i-1 : i;
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x = p.serpentine && j%2 ? h-x-1 : x;
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size_t index = (p.yOffset + (p.vertical?x:y)) * Segment::maxWidth + p.xOffset + (p.vertical?y:x);
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if (!gapTable || (gapTable && gapTable[index] > 0)) customMappingTable[index] = pix; // a useful pixel (otherwise -1 is retained)
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if (!gapTable || (gapTable && gapTable[index] >= 0)) pix++; // not a missing pixel
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}
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}
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}
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// delete gap array as we no longer need it
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if (gapTable) delete[] gapTable;
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#ifdef WLED_DEBUG
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DEBUG_PRINT(F("Matrix ledmap:"));
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for (unsigned i=0; i<customMappingSize; i++) {
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if (!(i%Segment::maxWidth)) DEBUG_PRINTLN();
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DEBUG_PRINTF("%4d,", customMappingTable[i]);
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}
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DEBUG_PRINTLN();
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#endif
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} else { // memory allocation error
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DEBUG_PRINTLN(F("Ledmap alloc error."));
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isMatrix = false;
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panels = 0;
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panel.clear();
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Segment::maxWidth = _length;
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Segment::maxHeight = 1;
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resetSegments();
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}
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}
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#else
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isMatrix = false; // no matter what config says
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#endif
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}
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///////////////////////////////////////////////////////////
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// Segment:: routines
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///////////////////////////////////////////////////////////
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#ifndef WLED_DISABLE_2D
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// XY(x,y) - gets pixel index within current segment (often used to reference leds[] array element)
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uint16_t IRAM_ATTR Segment::XY(uint16_t x, uint16_t y)
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{
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uint16_t width = virtualWidth(); // segment width in logical pixels (can be 0 if segment is inactive)
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uint16_t height = virtualHeight(); // segment height in logical pixels (is always >= 1)
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return isActive() ? (x%width) + (y%height) * width : 0;
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}
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void IRAM_ATTR Segment::setPixelColorXY(int x, int y, uint32_t col)
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{
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if (!isActive()) return; // not active
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if (x >= virtualWidth() || y >= virtualHeight() || x<0 || y<0) return; // if pixel would fall out of virtual segment just exit
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uint8_t _bri_t = currentBri();
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if (_bri_t < 255) {
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byte r = scale8(R(col), _bri_t);
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byte g = scale8(G(col), _bri_t);
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byte b = scale8(B(col), _bri_t);
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byte w = scale8(W(col), _bri_t);
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col = RGBW32(r, g, b, w);
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}
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if (reverse ) x = virtualWidth() - x - 1;
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if (reverse_y) y = virtualHeight() - y - 1;
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if (transpose) { uint16_t t = x; x = y; y = t; } // swap X & Y if segment transposed
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x *= groupLength(); // expand to physical pixels
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y *= groupLength(); // expand to physical pixels
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if (x >= width() || y >= height()) return; // if pixel would fall out of segment just exit
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uint32_t tmpCol = col;
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for (int j = 0; j < grouping; j++) { // groupping vertically
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for (int g = 0; g < grouping; g++) { // groupping horizontally
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uint16_t xX = (x+g), yY = (y+j);
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if (xX >= width() || yY >= height()) continue; // we have reached one dimension's end
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#ifndef WLED_DISABLE_MODE_BLEND
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// if blending modes, blend with underlying pixel
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if (_modeBlend) tmpCol = color_blend(strip.getPixelColorXY(start + xX, startY + yY), col, 0xFFFFU - progress(), true);
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#endif
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strip.setPixelColorXY(start + xX, startY + yY, tmpCol);
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if (mirror) { //set the corresponding horizontally mirrored pixel
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if (transpose) strip.setPixelColorXY(start + xX, startY + height() - yY - 1, tmpCol);
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else strip.setPixelColorXY(start + width() - xX - 1, startY + yY, tmpCol);
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}
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if (mirror_y) { //set the corresponding vertically mirrored pixel
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if (transpose) strip.setPixelColorXY(start + width() - xX - 1, startY + yY, tmpCol);
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else strip.setPixelColorXY(start + xX, startY + height() - yY - 1, tmpCol);
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}
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if (mirror_y && mirror) { //set the corresponding vertically AND horizontally mirrored pixel
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strip.setPixelColorXY(width() - xX - 1, height() - yY - 1, tmpCol);
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}
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}
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}
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}
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// anti-aliased version of setPixelColorXY()
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void Segment::setPixelColorXY(float x, float y, uint32_t col, bool aa)
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{
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if (!isActive()) return; // not active
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if (x<0.0f || x>1.0f || y<0.0f || y>1.0f) return; // not normalized
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const uint16_t cols = virtualWidth();
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const uint16_t rows = virtualHeight();
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float fX = x * (cols-1);
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float fY = y * (rows-1);
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if (aa) {
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uint16_t xL = roundf(fX-0.49f);
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uint16_t xR = roundf(fX+0.49f);
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uint16_t yT = roundf(fY-0.49f);
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uint16_t yB = roundf(fY+0.49f);
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float dL = (fX - xL)*(fX - xL);
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float dR = (xR - fX)*(xR - fX);
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float dT = (fY - yT)*(fY - yT);
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float dB = (yB - fY)*(yB - fY);
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uint32_t cXLYT = getPixelColorXY(xL, yT);
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uint32_t cXRYT = getPixelColorXY(xR, yT);
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uint32_t cXLYB = getPixelColorXY(xL, yB);
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uint32_t cXRYB = getPixelColorXY(xR, yB);
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if (xL!=xR && yT!=yB) {
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setPixelColorXY(xL, yT, color_blend(col, cXLYT, uint8_t(sqrtf(dL*dT)*255.0f))); // blend TL pixel
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setPixelColorXY(xR, yT, color_blend(col, cXRYT, uint8_t(sqrtf(dR*dT)*255.0f))); // blend TR pixel
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setPixelColorXY(xL, yB, color_blend(col, cXLYB, uint8_t(sqrtf(dL*dB)*255.0f))); // blend BL pixel
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setPixelColorXY(xR, yB, color_blend(col, cXRYB, uint8_t(sqrtf(dR*dB)*255.0f))); // blend BR pixel
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} else if (xR!=xL && yT==yB) {
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setPixelColorXY(xR, yT, color_blend(col, cXLYT, uint8_t(dL*255.0f))); // blend L pixel
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setPixelColorXY(xR, yT, color_blend(col, cXRYT, uint8_t(dR*255.0f))); // blend R pixel
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} else if (xR==xL && yT!=yB) {
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setPixelColorXY(xR, yT, color_blend(col, cXLYT, uint8_t(dT*255.0f))); // blend T pixel
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setPixelColorXY(xL, yB, color_blend(col, cXLYB, uint8_t(dB*255.0f))); // blend B pixel
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} else {
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setPixelColorXY(xL, yT, col); // exact match (x & y land on a pixel)
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}
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} else {
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setPixelColorXY(uint16_t(roundf(fX)), uint16_t(roundf(fY)), col);
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}
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}
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// returns RGBW values of pixel
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uint32_t Segment::getPixelColorXY(uint16_t x, uint16_t y) {
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if (!isActive()) return 0; // not active
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if (x >= virtualWidth() || y >= virtualHeight() || x<0 || y<0) return 0; // if pixel would fall out of virtual segment just exit
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if (reverse ) x = virtualWidth() - x - 1;
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if (reverse_y) y = virtualHeight() - y - 1;
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if (transpose) { uint16_t t = x; x = y; y = t; } // swap X & Y if segment transposed
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x *= groupLength(); // expand to physical pixels
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y *= groupLength(); // expand to physical pixels
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if (x >= width() || y >= height()) return 0;
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return strip.getPixelColorXY(start + x, startY + y);
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}
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// Blends the specified color with the existing pixel color.
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void Segment::blendPixelColorXY(uint16_t x, uint16_t y, uint32_t color, uint8_t blend) {
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setPixelColorXY(x, y, color_blend(getPixelColorXY(x,y), color, blend));
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}
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// Adds the specified color with the existing pixel color perserving color balance.
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void Segment::addPixelColorXY(int x, int y, uint32_t color, bool fast) {
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if (!isActive()) return; // not active
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if (x >= virtualWidth() || y >= virtualHeight() || x<0 || y<0) return; // if pixel would fall out of virtual segment just exit
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setPixelColorXY(x, y, color_add(getPixelColorXY(x,y), color, fast));
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}
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void Segment::fadePixelColorXY(uint16_t x, uint16_t y, uint8_t fade) {
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if (!isActive()) return; // not active
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setPixelColorXY(x, y, color_fade(getPixelColorXY(x,y), fade, true));
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}
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// blurRow: perform a blur on a row of a rectangular matrix
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void Segment::blurRow(uint16_t row, fract8 blur_amount) {
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if (!isActive() || blur_amount == 0) return; // not active
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const uint_fast16_t cols = virtualWidth();
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const uint_fast16_t rows = virtualHeight();
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if (row >= rows) return;
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// blur one row
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uint8_t keep = 255 - blur_amount;
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uint8_t seep = blur_amount >> 1;
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CRGB carryover = CRGB::Black;
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for (unsigned x = 0; x < cols; x++) {
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CRGB cur = getPixelColorXY(x, row);
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CRGB before = cur; // remember color before blur
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CRGB part = cur;
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part.nscale8(seep);
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cur.nscale8(keep);
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cur += carryover;
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if (x>0) {
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CRGB prev = CRGB(getPixelColorXY(x-1, row)) + part;
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setPixelColorXY(x-1, row, prev);
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}
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if (before != cur) // optimization: only set pixel if color has changed
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setPixelColorXY(x, row, cur);
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carryover = part;
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}
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}
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// blurCol: perform a blur on a column of a rectangular matrix
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void Segment::blurCol(uint16_t col, fract8 blur_amount) {
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if (!isActive() || blur_amount == 0) return; // not active
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const uint_fast16_t cols = virtualWidth();
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const uint_fast16_t rows = virtualHeight();
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if (col >= cols) return;
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// blur one column
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uint8_t keep = 255 - blur_amount;
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uint8_t seep = blur_amount >> 1;
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CRGB carryover = CRGB::Black;
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for (unsigned y = 0; y < rows; y++) {
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CRGB cur = getPixelColorXY(col, y);
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CRGB part = cur;
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CRGB before = cur; // remember color before blur
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part.nscale8(seep);
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cur.nscale8(keep);
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cur += carryover;
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if (y>0) {
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CRGB prev = CRGB(getPixelColorXY(col, y-1)) + part;
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setPixelColorXY(col, y-1, prev);
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}
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if (before != cur) // optimization: only set pixel if color has changed
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setPixelColorXY(col, y, cur);
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carryover = part;
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}
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}
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// 1D Box blur (with added weight - blur_amount: [0=no blur, 255=max blur])
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void Segment::box_blur(uint16_t i, bool vertical, fract8 blur_amount) {
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if (!isActive() || blur_amount == 0) return; // not active
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const uint16_t cols = virtualWidth();
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const uint16_t rows = virtualHeight();
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const uint16_t dim1 = vertical ? rows : cols;
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const uint16_t dim2 = vertical ? cols : rows;
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if (i >= dim2) return;
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const float seep = blur_amount/255.f;
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const float keep = 3.f - 2.f*seep;
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// 1D box blur
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CRGB tmp[dim1];
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for (int j = 0; j < dim1; j++) {
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uint16_t x = vertical ? i : j;
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uint16_t y = vertical ? j : i;
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int16_t xp = vertical ? x : x-1; // "signed" to prevent underflow
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int16_t yp = vertical ? y-1 : y; // "signed" to prevent underflow
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uint16_t xn = vertical ? x : x+1;
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uint16_t yn = vertical ? y+1 : y;
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CRGB curr = getPixelColorXY(x,y);
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CRGB prev = (xp<0 || yp<0) ? CRGB::Black : getPixelColorXY(xp,yp);
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CRGB next = ((vertical && yn>=dim1) || (!vertical && xn>=dim1)) ? CRGB::Black : getPixelColorXY(xn,yn);
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uint16_t r, g, b;
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r = (curr.r*keep + (prev.r + next.r)*seep) / 3;
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g = (curr.g*keep + (prev.g + next.g)*seep) / 3;
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b = (curr.b*keep + (prev.b + next.b)*seep) / 3;
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tmp[j] = CRGB(r,g,b);
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}
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for (int j = 0; j < dim1; j++) {
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uint16_t x = vertical ? i : j;
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uint16_t y = vertical ? j : i;
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setPixelColorXY(x, y, tmp[j]);
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}
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}
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// blur1d: one-dimensional blur filter. Spreads light to 2 line neighbors.
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// blur2d: two-dimensional blur filter. Spreads light to 8 XY neighbors.
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//
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// 0 = no spread at all
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// 64 = moderate spreading
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// 172 = maximum smooth, even spreading
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//
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// 173..255 = wider spreading, but increasing flicker
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//
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// Total light is NOT entirely conserved, so many repeated
|
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// calls to 'blur' will also result in the light fading,
|
||
// eventually all the way to black; this is by design so that
|
||
// it can be used to (slowly) clear the LEDs to black.
|
||
|
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void Segment::blur1d(fract8 blur_amount) {
|
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const uint16_t rows = virtualHeight();
|
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for (unsigned y = 0; y < rows; y++) blurRow(y, blur_amount);
|
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}
|
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|
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void Segment::moveX(int8_t delta, bool wrap) {
|
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if (!isActive()) return; // not active
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
if (!delta || abs(delta) >= cols) return;
|
||
uint32_t newPxCol[cols];
|
||
for (int y = 0; y < rows; y++) {
|
||
if (delta > 0) {
|
||
for (int x = 0; x < cols-delta; x++) newPxCol[x] = getPixelColorXY((x + delta), y);
|
||
for (int x = cols-delta; x < cols; x++) newPxCol[x] = getPixelColorXY(wrap ? (x + delta) - cols : x, y);
|
||
} else {
|
||
for (int x = cols-1; x >= -delta; x--) newPxCol[x] = getPixelColorXY((x + delta), y);
|
||
for (int x = -delta-1; x >= 0; x--) newPxCol[x] = getPixelColorXY(wrap ? (x + delta) + cols : x, y);
|
||
}
|
||
for (int x = 0; x < cols; x++) setPixelColorXY(x, y, newPxCol[x]);
|
||
}
|
||
}
|
||
|
||
void Segment::moveY(int8_t delta, bool wrap) {
|
||
if (!isActive()) return; // not active
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
if (!delta || abs(delta) >= rows) return;
|
||
uint32_t newPxCol[rows];
|
||
for (int x = 0; x < cols; x++) {
|
||
if (delta > 0) {
|
||
for (int y = 0; y < rows-delta; y++) newPxCol[y] = getPixelColorXY(x, (y + delta));
|
||
for (int y = rows-delta; y < rows; y++) newPxCol[y] = getPixelColorXY(x, wrap ? (y + delta) - rows : y);
|
||
} else {
|
||
for (int y = rows-1; y >= -delta; y--) newPxCol[y] = getPixelColorXY(x, (y + delta));
|
||
for (int y = -delta-1; y >= 0; y--) newPxCol[y] = getPixelColorXY(x, wrap ? (y + delta) + rows : y);
|
||
}
|
||
for (int y = 0; y < rows; y++) setPixelColorXY(x, y, newPxCol[y]);
|
||
}
|
||
}
|
||
|
||
// move() - move all pixels in desired direction delta number of pixels
|
||
// @param dir direction: 0=left, 1=left-up, 2=up, 3=right-up, 4=right, 5=right-down, 6=down, 7=left-down
|
||
// @param delta number of pixels to move
|
||
// @param wrap around
|
||
void Segment::move(uint8_t dir, uint8_t delta, bool wrap) {
|
||
if (delta==0) return;
|
||
switch (dir) {
|
||
case 0: moveX( delta, wrap); break;
|
||
case 1: moveX( delta, wrap); moveY( delta, wrap); break;
|
||
case 2: moveY( delta, wrap); break;
|
||
case 3: moveX(-delta, wrap); moveY( delta, wrap); break;
|
||
case 4: moveX(-delta, wrap); break;
|
||
case 5: moveX(-delta, wrap); moveY(-delta, wrap); break;
|
||
case 6: moveY(-delta, wrap); break;
|
||
case 7: moveX( delta, wrap); moveY(-delta, wrap); break;
|
||
}
|
||
}
|
||
|
||
void Segment::draw_circle(uint16_t cx, uint16_t cy, uint8_t radius, CRGB col) {
|
||
if (!isActive() || radius == 0) return; // not active
|
||
// Bresenham’s Algorithm
|
||
int d = 3 - (2*radius);
|
||
int y = radius, x = 0;
|
||
while (y >= x) {
|
||
setPixelColorXY(cx+x, cy+y, col);
|
||
setPixelColorXY(cx-x, cy+y, col);
|
||
setPixelColorXY(cx+x, cy-y, col);
|
||
setPixelColorXY(cx-x, cy-y, col);
|
||
setPixelColorXY(cx+y, cy+x, col);
|
||
setPixelColorXY(cx-y, cy+x, col);
|
||
setPixelColorXY(cx+y, cy-x, col);
|
||
setPixelColorXY(cx-y, cy-x, col);
|
||
x++;
|
||
if (d > 0) {
|
||
y--;
|
||
d += 4 * (x - y) + 10;
|
||
} else {
|
||
d += 4 * x + 6;
|
||
}
|
||
}
|
||
}
|
||
|
||
// by stepko, taken from https://editor.soulmatelights.com/gallery/573-blobs
|
||
void Segment::fill_circle(uint16_t cx, uint16_t cy, uint8_t radius, CRGB col) {
|
||
if (!isActive() || radius == 0) return; // not active
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
for (int16_t y = -radius; y <= radius; y++) {
|
||
for (int16_t x = -radius; x <= radius; x++) {
|
||
if (x * x + y * y <= radius * radius &&
|
||
int16_t(cx)+x>=0 && int16_t(cy)+y>=0 &&
|
||
int16_t(cx)+x<cols && int16_t(cy)+y<rows)
|
||
setPixelColorXY(cx + x, cy + y, col);
|
||
}
|
||
}
|
||
}
|
||
|
||
void Segment::nscale8(uint8_t scale) {
|
||
if (!isActive()) return; // not active
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
for (int y = 0; y < rows; y++) for (int x = 0; x < cols; x++) {
|
||
setPixelColorXY(x, y, CRGB(getPixelColorXY(x, y)).nscale8(scale));
|
||
}
|
||
}
|
||
|
||
//line function
|
||
void Segment::drawLine(uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, uint32_t c) {
|
||
if (!isActive()) return; // not active
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
if (x0 >= cols || x1 >= cols || y0 >= rows || y1 >= rows) return;
|
||
const int16_t dx = abs(x1-x0), sx = x0<x1 ? 1 : -1;
|
||
const int16_t dy = abs(y1-y0), sy = y0<y1 ? 1 : -1;
|
||
int16_t err = (dx>dy ? dx : -dy)/2, e2;
|
||
for (;;) {
|
||
setPixelColorXY(x0,y0,c);
|
||
if (x0==x1 && y0==y1) break;
|
||
e2 = err;
|
||
if (e2 >-dx) { err -= dy; x0 += sx; }
|
||
if (e2 < dy) { err += dx; y0 += sy; }
|
||
}
|
||
}
|
||
|
||
#include "src/font/console_font_4x6.h"
|
||
#include "src/font/console_font_5x8.h"
|
||
#include "src/font/console_font_5x12.h"
|
||
#include "src/font/console_font_6x8.h"
|
||
#include "src/font/console_font_7x9.h"
|
||
|
||
// draws a raster font character on canvas
|
||
// only supports: 4x6=24, 5x8=40, 5x12=60, 6x8=48 and 7x9=63 fonts ATM
|
||
void Segment::drawCharacter(unsigned char chr, int16_t x, int16_t y, uint8_t w, uint8_t h, uint32_t color, uint32_t col2, int8_t rotate) {
|
||
if (!isActive()) return; // not active
|
||
if (chr < 32 || chr > 126) return; // only ASCII 32-126 supported
|
||
chr -= 32; // align with font table entries
|
||
const uint16_t cols = virtualWidth();
|
||
const uint16_t rows = virtualHeight();
|
||
const int font = w*h;
|
||
|
||
CRGB col = CRGB(color);
|
||
CRGBPalette16 grad = CRGBPalette16(col, col2 ? CRGB(col2) : col);
|
||
|
||
//if (w<5 || w>6 || h!=8) return;
|
||
for (int i = 0; i<h; i++) { // character height
|
||
uint8_t bits = 0;
|
||
switch (font) {
|
||
case 24: bits = pgm_read_byte_near(&console_font_4x6[(chr * h) + i]); break; // 5x8 font
|
||
case 40: bits = pgm_read_byte_near(&console_font_5x8[(chr * h) + i]); break; // 5x8 font
|
||
case 48: bits = pgm_read_byte_near(&console_font_6x8[(chr * h) + i]); break; // 6x8 font
|
||
case 63: bits = pgm_read_byte_near(&console_font_7x9[(chr * h) + i]); break; // 7x9 font
|
||
case 60: bits = pgm_read_byte_near(&console_font_5x12[(chr * h) + i]); break; // 5x12 font
|
||
default: return;
|
||
}
|
||
col = ColorFromPalette(grad, (i+1)*255/h, 255, NOBLEND);
|
||
for (int j = 0; j<w; j++) { // character width
|
||
int x0, y0;
|
||
switch (rotate) {
|
||
case -1: x0 = x + (h-1) - i; y0 = y + (w-1) - j; break; // -90 deg
|
||
case -2:
|
||
case 2: x0 = x + j; y0 = y + (h-1) - i; break; // 180 deg
|
||
case 1: x0 = x + i; y0 = y + j; break; // +90 deg
|
||
default: x0 = x + (w-1) - j; y0 = y + i; break; // no rotation
|
||
}
|
||
if (x0 < 0 || x0 >= cols || y0 < 0 || y0 >= rows) continue; // drawing off-screen
|
||
if (((bits>>(j+(8-w))) & 0x01)) { // bit set
|
||
setPixelColorXY(x0, y0, col);
|
||
}
|
||
}
|
||
}
|
||
}
|
||
|
||
#define WU_WEIGHT(a,b) ((uint8_t) (((a)*(b)+(a)+(b))>>8))
|
||
void Segment::wu_pixel(uint32_t x, uint32_t y, CRGB c) { //awesome wu_pixel procedure by reddit u/sutaburosu
|
||
if (!isActive()) return; // not active
|
||
// extract the fractional parts and derive their inverses
|
||
uint8_t xx = x & 0xff, yy = y & 0xff, ix = 255 - xx, iy = 255 - yy;
|
||
// calculate the intensities for each affected pixel
|
||
uint8_t wu[4] = {WU_WEIGHT(ix, iy), WU_WEIGHT(xx, iy),
|
||
WU_WEIGHT(ix, yy), WU_WEIGHT(xx, yy)};
|
||
// multiply the intensities by the colour, and saturating-add them to the pixels
|
||
for (int i = 0; i < 4; i++) {
|
||
CRGB led = getPixelColorXY((x >> 8) + (i & 1), (y >> 8) + ((i >> 1) & 1));
|
||
led.r = qadd8(led.r, c.r * wu[i] >> 8);
|
||
led.g = qadd8(led.g, c.g * wu[i] >> 8);
|
||
led.b = qadd8(led.b, c.b * wu[i] >> 8);
|
||
setPixelColorXY(int((x >> 8) + (i & 1)), int((y >> 8) + ((i >> 1) & 1)), led);
|
||
}
|
||
}
|
||
#undef WU_WEIGHT
|
||
|
||
#endif // WLED_DISABLE_2D
|