vtx: fix VTX_SETTINGS_POWER_COUNT and add dummy entries to saPowerNames
[inav.git] / src / main / io / ledstrip.c
blob62c41683f021993d9aae95adf2edb5b24c223ef2
1 /*
2 * This file is part of Cleanflight.
4 * Cleanflight is free software: you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation, either version 3 of the License, or
7 * (at your option) any later version.
9 * Cleanflight is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
14 * You should have received a copy of the GNU General Public License
15 * along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
18 #include <stdbool.h>
19 #include <stdlib.h>
20 #include <stdint.h>
21 #include <string.h>
22 #include <stdarg.h>
24 #include <platform.h>
26 #ifdef USE_LED_STRIP
28 #include "build/build_config.h"
30 #include "common/axis.h"
31 #include "common/maths.h"
32 #include "common/printf.h"
33 #include "common/typeconversion.h"
34 #include "common/string_light.h"
35 #include "common/utils.h"
37 #include "config/feature.h"
38 #include "config/parameter_group.h"
39 #include "config/parameter_group_ids.h"
41 #include "drivers/light_ws2811strip.h"
42 #include "drivers/serial.h"
43 #include "drivers/time.h"
45 #include "fc/config.h"
46 #include "fc/rc_controls.h"
47 #include "fc/rc_modes.h"
48 #include "fc/runtime_config.h"
50 #include "flight/failsafe.h"
51 #include "flight/mixer.h"
52 #include "flight/servos.h"
53 #include "flight/pid.h"
54 #include "flight/imu.h"
56 #include "io/ledstrip.h"
57 #include "io/beeper.h"
58 #include "io/serial.h"
59 #include "io/gps.h"
61 #include "navigation/navigation.h"
63 #include "rx/rx.h"
64 #include "sensors/acceleration.h"
65 #include "sensors/diagnostics.h"
66 #include "sensors/barometer.h"
67 #include "sensors/battery.h"
68 #include "sensors/boardalignment.h"
69 #include "sensors/gyro.h"
70 #include "sensors/sensors.h"
71 #include "sensors/pitotmeter.h"
73 #include "telemetry/telemetry.h"
76 PG_REGISTER_WITH_RESET_FN(ledStripConfig_t, ledStripConfig, PG_LED_STRIP_CONFIG, 2);
78 static bool ledStripInitialised = false;
79 static bool ledStripEnabled = true;
81 static void ledStripDisable(void);
83 //#define USE_LED_ANIMATION
85 #define LED_STRIP_HZ(hz) ((int32_t)((1000 * 1000) / (hz)))
86 #define LED_STRIP_MS(ms) ((int32_t)(1000 * (ms)))
88 #if LED_MAX_STRIP_LENGTH > WS2811_LED_STRIP_LENGTH
89 # error "Led strip length must match driver"
90 #endif
92 const hsvColor_t hsv[] = {
93 // H S V
94 [COLOR_BLACK] = { 0, 0, 0},
95 [COLOR_WHITE] = { 0, 255, 255},
96 [COLOR_RED] = { 0, 0, 255},
97 [COLOR_ORANGE] = { 30, 0, 255},
98 [COLOR_YELLOW] = { 60, 0, 255},
99 [COLOR_LIME_GREEN] = { 90, 0, 255},
100 [COLOR_GREEN] = {120, 0, 255},
101 [COLOR_MINT_GREEN] = {150, 0, 255},
102 [COLOR_CYAN] = {180, 0, 255},
103 [COLOR_LIGHT_BLUE] = {210, 0, 255},
104 [COLOR_BLUE] = {240, 0, 255},
105 [COLOR_DARK_VIOLET] = {270, 0, 255},
106 [COLOR_MAGENTA] = {300, 0, 255},
107 [COLOR_DEEP_PINK] = {330, 0, 255},
109 // macro to save typing on default colors
110 #define HSV(color) (hsv[COLOR_ ## color])
112 STATIC_UNIT_TESTED uint8_t ledGridWidth;
113 STATIC_UNIT_TESTED uint8_t ledGridHeight;
114 // grid offsets
115 STATIC_UNIT_TESTED uint8_t highestYValueForNorth;
116 STATIC_UNIT_TESTED uint8_t lowestYValueForSouth;
117 STATIC_UNIT_TESTED uint8_t highestXValueForWest;
118 STATIC_UNIT_TESTED uint8_t lowestXValueForEast;
120 STATIC_UNIT_TESTED ledCounts_t ledCounts;
122 static const modeColorIndexes_t defaultModeColors[] = {
123 // NORTH EAST SOUTH WEST UP DOWN
124 [LED_MODE_ORIENTATION] = {{ COLOR_WHITE, COLOR_DARK_VIOLET, COLOR_RED, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
125 [LED_MODE_HEADFREE] = {{ COLOR_LIME_GREEN, COLOR_DARK_VIOLET, COLOR_ORANGE, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
126 [LED_MODE_HORIZON] = {{ COLOR_BLUE, COLOR_DARK_VIOLET, COLOR_YELLOW, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
127 [LED_MODE_ANGLE] = {{ COLOR_CYAN, COLOR_DARK_VIOLET, COLOR_YELLOW, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
128 [LED_MODE_MAG] = {{ COLOR_MINT_GREEN, COLOR_DARK_VIOLET, COLOR_ORANGE, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
129 [LED_MODE_BARO] = {{ COLOR_LIGHT_BLUE, COLOR_DARK_VIOLET, COLOR_RED, COLOR_DEEP_PINK, COLOR_BLUE, COLOR_ORANGE }},
132 static const specialColorIndexes_t defaultSpecialColors[] = {
133 {{ [LED_SCOLOR_DISARMED] = COLOR_GREEN,
134 [LED_SCOLOR_ARMED] = COLOR_BLUE,
135 [LED_SCOLOR_ANIMATION] = COLOR_WHITE,
136 [LED_SCOLOR_BACKGROUND] = COLOR_BLACK,
137 [LED_SCOLOR_BLINKBACKGROUND] = COLOR_BLACK,
138 [LED_SCOLOR_GPSNOSATS] = COLOR_RED,
139 [LED_SCOLOR_GPSNOLOCK] = COLOR_ORANGE,
140 [LED_SCOLOR_GPSLOCKED] = COLOR_GREEN,
141 [LED_SCOLOR_STROBE] = COLOR_WHITE,
145 void pgResetFn_ledStripConfig(ledStripConfig_t *instance)
147 memset(instance->ledConfigs, 0, LED_MAX_STRIP_LENGTH * sizeof(ledConfig_t));
148 // copy hsv colors as default
149 memset(instance->colors, 0, ARRAYLEN(hsv) * sizeof(hsvColor_t));
150 BUILD_BUG_ON(LED_CONFIGURABLE_COLOR_COUNT < ARRAYLEN(hsv));
151 for (unsigned colorIndex = 0; colorIndex < ARRAYLEN(hsv); colorIndex++) {
152 instance->colors[colorIndex] = hsv[colorIndex];
154 memcpy_fn(&instance->modeColors, &defaultModeColors, sizeof(defaultModeColors));
155 memcpy_fn(&instance->specialColors, &defaultSpecialColors, sizeof(defaultSpecialColors));
158 static int scaledThrottle;
160 static void updateLedRingCounts(void);
162 STATIC_UNIT_TESTED void determineLedStripDimensions(void)
164 int maxX = 0;
165 int maxY = 0;
167 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
168 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
170 maxX = MAX(ledGetX(ledConfig), maxX);
171 maxY = MAX(ledGetY(ledConfig), maxY);
173 ledGridWidth = maxX + 1;
174 ledGridHeight = maxY + 1;
177 STATIC_UNIT_TESTED void determineOrientationLimits(void)
179 highestYValueForNorth = MIN((ledGridHeight / 2) - 1, 0);
180 lowestYValueForSouth = (ledGridHeight + 1) / 2;
181 highestXValueForWest = MIN((ledGridWidth / 2) - 1, 0);
182 lowestXValueForEast = (ledGridWidth + 1) / 2;
185 STATIC_UNIT_TESTED void updateLedCount(void)
187 int count = 0, countRing = 0, countScanner= 0;
189 const ledConfig_t configNotSet = {};
190 for (int ledIndex = 0; ledIndex < LED_MAX_STRIP_LENGTH; ledIndex++) {
191 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
193 if (!memcmp(ledConfig, &configNotSet, sizeof(ledConfig_t)))
194 break;
196 count++;
198 if (ledGetFunction(ledConfig) == LED_FUNCTION_THRUST_RING)
199 countRing++;
201 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_LARSON_SCANNER))
202 countScanner++;
205 ledCounts.count = count;
206 ledCounts.ring = countRing;
207 ledCounts.larson = countScanner;
210 void reevaluateLedConfig(void)
212 updateLedCount();
213 determineLedStripDimensions();
214 determineOrientationLimits();
215 updateLedRingCounts();
218 // get specialColor by index
219 static const hsvColor_t* getSC(ledSpecialColorIds_e index)
221 return &ledStripConfig()->colors[ledStripConfig()->specialColors.color[index]];
224 static const char directionCodes[LED_DIRECTION_COUNT] = { 'N', 'E', 'S', 'W', 'U', 'D' };
225 static const char baseFunctionCodes[LED_BASEFUNCTION_COUNT] = { 'C', 'F', 'A', 'L', 'S', 'G', 'R', 'H' };
226 static const char overlayCodes[LED_OVERLAY_COUNT] = { 'T', 'O', 'B', 'N', 'I', 'W', 'E' };
228 #define CHUNK_BUFFER_SIZE 11
230 bool parseLedStripConfig(int ledIndex, const char *config)
232 if (ledIndex >= LED_MAX_STRIP_LENGTH)
233 return false;
235 enum parseState_e {
236 X_COORDINATE,
237 Y_COORDINATE,
238 DIRECTIONS,
239 FUNCTIONS,
240 RING_COLORS,
241 PARSE_STATE_COUNT
243 static const char chunkSeparators[PARSE_STATE_COUNT] = {',', ':', ':',':', '\0'};
245 ledConfig_t *ledConfig = &ledStripConfigMutable()->ledConfigs[ledIndex];
246 memset(ledConfig, 0, sizeof(ledConfig_t));
248 int x = 0, y = 0, color = 0; // initialize to prevent warnings
249 int baseFunction = 0;
250 int overlay_flags = 0;
251 int direction_flags = 0;
253 for (enum parseState_e parseState = 0; parseState < PARSE_STATE_COUNT; parseState++) {
254 char chunk[CHUNK_BUFFER_SIZE];
256 char chunkSeparator = chunkSeparators[parseState];
257 int chunkIndex = 0;
258 while (*config && *config != chunkSeparator && chunkIndex < (CHUNK_BUFFER_SIZE - 1)) {
259 chunk[chunkIndex++] = *config++;
261 chunk[chunkIndex++] = 0; // zero-terminate chunk
262 if (*config != chunkSeparator) {
263 return false;
265 config++; // skip separator
267 switch (parseState) {
268 case X_COORDINATE:
269 x = fastA2I(chunk);
270 break;
271 case Y_COORDINATE:
272 y = fastA2I(chunk);
273 break;
274 case DIRECTIONS:
275 for (char *ch = chunk; *ch; ch++) {
276 for (ledDirectionId_e dir = 0; dir < LED_DIRECTION_COUNT; dir++) {
277 if (directionCodes[dir] == *ch) {
278 direction_flags |= LED_FLAG_DIRECTION(dir);
279 break;
283 break;
284 case FUNCTIONS:
285 for (char *ch = chunk; *ch; ch++) {
286 for (ledBaseFunctionId_e fn = 0; fn < LED_BASEFUNCTION_COUNT; fn++) {
287 if (baseFunctionCodes[fn] == *ch) {
288 baseFunction = fn;
289 break;
293 for (ledOverlayId_e ol = 0; ol < LED_OVERLAY_COUNT; ol++) {
294 if (overlayCodes[ol] == *ch) {
295 overlay_flags |= LED_FLAG_OVERLAY(ol);
296 break;
300 break;
301 case RING_COLORS:
302 color = fastA2I(chunk);
303 if (color >= LED_CONFIGURABLE_COLOR_COUNT)
304 color = 0;
305 break;
306 case PARSE_STATE_COUNT:; // prevent warning
310 DEFINE_LED(ledConfig, x, y, color, direction_flags, baseFunction, overlay_flags, 0);
312 reevaluateLedConfig();
314 return true;
317 void generateLedConfig(ledConfig_t *ledConfig, char *ledConfigBuffer, size_t bufferSize)
319 char directions[LED_DIRECTION_COUNT + 1];
320 char baseFunctionOverlays[LED_OVERLAY_COUNT + 2];
322 memset(ledConfigBuffer, 0, bufferSize);
324 char *dptr = directions;
325 for (ledDirectionId_e dir = 0; dir < LED_DIRECTION_COUNT; dir++) {
326 if (ledGetDirectionBit(ledConfig, dir)) {
327 *dptr++ = directionCodes[dir];
330 *dptr = 0;
332 char *fptr = baseFunctionOverlays;
333 *fptr++ = baseFunctionCodes[ledGetFunction(ledConfig)];
335 for (ledOverlayId_e ol = 0; ol < LED_OVERLAY_COUNT; ol++) {
336 if (ledGetOverlayBit(ledConfig, ol)) {
337 *fptr++ = overlayCodes[ol];
340 *fptr = 0;
342 // TODO - check buffer length
343 tfp_sprintf(ledConfigBuffer, "%u,%u:%s:%s:%u", ledGetX(ledConfig), ledGetY(ledConfig), directions, baseFunctionOverlays, ledGetColor(ledConfig));
346 typedef enum {
347 // the ordering is important, see below how NSEW is mapped to NE/SE/NW/SW
348 QUADRANT_NORTH = 1 << 0,
349 QUADRANT_SOUTH = 1 << 1,
350 QUADRANT_EAST = 1 << 2,
351 QUADRANT_WEST = 1 << 3,
352 QUADRANT_NORTH_EAST = 1 << 4,
353 QUADRANT_SOUTH_EAST = 1 << 5,
354 QUADRANT_NORTH_WEST = 1 << 6,
355 QUADRANT_SOUTH_WEST = 1 << 7,
356 QUADRANT_NONE = 1 << 8,
357 QUADRANT_NOTDIAG = 1 << 9, // not in NE/SE/NW/SW
358 // values for test
359 QUADRANT_ANY = QUADRANT_NORTH | QUADRANT_SOUTH | QUADRANT_EAST | QUADRANT_WEST | QUADRANT_NONE,
360 } quadrant_e;
362 static quadrant_e getLedQuadrant(const int ledIndex)
364 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
366 int x = ledGetX(ledConfig);
367 int y = ledGetY(ledConfig);
369 int quad = 0;
370 if (y <= highestYValueForNorth)
371 quad |= QUADRANT_NORTH;
372 else if (y >= lowestYValueForSouth)
373 quad |= QUADRANT_SOUTH;
374 if (x >= lowestXValueForEast)
375 quad |= QUADRANT_EAST;
376 else if (x <= highestXValueForWest)
377 quad |= QUADRANT_WEST;
379 if ((quad & (QUADRANT_NORTH | QUADRANT_SOUTH))
380 && (quad & (QUADRANT_EAST | QUADRANT_WEST)) ) { // is led in one of NE/SE/NW/SW?
381 quad |= 1 << (4 + ((quad & QUADRANT_SOUTH) ? 1 : 0) + ((quad & QUADRANT_WEST) ? 2 : 0));
382 } else {
383 quad |= QUADRANT_NOTDIAG;
386 if ((quad & (QUADRANT_NORTH | QUADRANT_SOUTH | QUADRANT_EAST | QUADRANT_WEST)) == 0)
387 quad |= QUADRANT_NONE;
389 return quad;
392 static const struct {
393 uint8_t dir; // ledDirectionId_e
394 uint16_t quadrantMask; // quadrant_e
395 } directionQuadrantMap[] = {
396 {LED_DIRECTION_SOUTH, QUADRANT_SOUTH},
397 {LED_DIRECTION_NORTH, QUADRANT_NORTH},
398 {LED_DIRECTION_EAST, QUADRANT_EAST},
399 {LED_DIRECTION_WEST, QUADRANT_WEST},
400 {LED_DIRECTION_DOWN, QUADRANT_ANY},
401 {LED_DIRECTION_UP, QUADRANT_ANY},
404 static const hsvColor_t* getDirectionalModeColor(const int ledIndex, const modeColorIndexes_t *modeColors)
406 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
408 quadrant_e quad = getLedQuadrant(ledIndex);
409 for (unsigned i = 0; i < ARRAYLEN(directionQuadrantMap); i++) {
410 ledDirectionId_e dir = directionQuadrantMap[i].dir;
411 quadrant_e quadMask = directionQuadrantMap[i].quadrantMask;
413 if (ledGetDirectionBit(ledConfig, dir) && (quad & quadMask))
414 return &ledStripConfig()->colors[modeColors->color[dir]];
416 return NULL;
419 // map flight mode to led mode, in order of priority
420 // flightMode == 0 is always active
421 static const struct {
422 uint16_t flightMode;
423 uint8_t ledMode;
424 } flightModeToLed[] = {
425 {HEADFREE_MODE, LED_MODE_HEADFREE},
426 {HEADING_MODE, LED_MODE_MAG},
427 #ifdef USE_BARO
428 {NAV_ALTHOLD_MODE, LED_MODE_BARO},
429 #endif
430 {HORIZON_MODE, LED_MODE_HORIZON},
431 {ANGLE_MODE, LED_MODE_ANGLE},
432 {0, LED_MODE_ORIENTATION},
435 static void applyLedFixedLayers(void)
437 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
438 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
439 hsvColor_t color = *getSC(LED_SCOLOR_BACKGROUND);
441 int fn = ledGetFunction(ledConfig);
442 int hOffset = HSV_HUE_MAX;
443 uint8_t channel = 0;
445 switch (fn) {
446 case LED_FUNCTION_COLOR:
447 color = ledStripConfig()->colors[ledGetColor(ledConfig)];
448 break;
450 case LED_FUNCTION_FLIGHT_MODE:
451 for (unsigned i = 0; i < ARRAYLEN(flightModeToLed); i++)
452 if (!flightModeToLed[i].flightMode || FLIGHT_MODE(flightModeToLed[i].flightMode)) {
453 const hsvColor_t *directionalColor = getDirectionalModeColor(ledIndex, &ledStripConfig()->modeColors[flightModeToLed[i].ledMode]);
454 if (directionalColor) {
455 color = *directionalColor;
458 break; // stop on first match
460 break;
462 case LED_FUNCTION_ARM_STATE:
463 color = ARMING_FLAG(ARMED) ? *getSC(LED_SCOLOR_ARMED) : *getSC(LED_SCOLOR_DISARMED);
464 break;
466 case LED_FUNCTION_BATTERY:
467 color = HSV(RED);
468 hOffset += scaleRange(calculateBatteryPercentage(), 0, 100, -30, 120);
469 break;
471 case LED_FUNCTION_RSSI:
472 color = HSV(RED);
473 hOffset += scaleRange(getRSSI() * 100, 0, 1023, -30, 120);
474 break;
476 case LED_FUNCTION_CHANNEL:
477 channel = ledGetColor(ledConfig) - 1;
478 color = HSV(RED);
479 hOffset = scaleRange(rxGetChannelValue(channel), PWM_RANGE_MIN, PWM_RANGE_MAX, -1, 360);
480 // add black and white to range of colors
481 if (hOffset < 0) {
482 color = HSV(BLACK);
483 } else if (hOffset > HSV_HUE_MAX) {
484 color = HSV(WHITE);
486 break;
488 default:
489 break;
492 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_THROTTLE)) {
493 hOffset += ((scaledThrottle - 10) * 4) / 3;
496 color.h = (color.h + hOffset) % (HSV_HUE_MAX + 1);
498 setLedHsv(ledIndex, &color);
503 static void applyLedHsv(uint32_t mask, uint32_t ledOperation, const hsvColor_t *color)
505 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
506 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
507 if ((*((uint32_t *)ledConfig) & mask) == ledOperation)
508 setLedHsv(ledIndex, color);
512 typedef enum {
513 WARNING_ARMING_DISABLED,
514 WARNING_LOW_BATTERY,
515 WARNING_FAILSAFE,
516 WARNING_HW_ERROR,
517 } warningFlags_e;
519 static void applyLedWarningLayer(bool updateNow, timeUs_t *timer)
521 static uint8_t warningFlashCounter = 0;
522 static uint8_t warningFlags = 0; // non-zero during blinks
524 if (updateNow) {
525 // keep counter running, so it stays in sync with blink
526 warningFlashCounter++;
527 warningFlashCounter &= 0xF;
529 if (warningFlashCounter == 0) { // update when old flags was processed
530 warningFlags = 0;
531 if (feature(FEATURE_VBAT) && getBatteryState() != BATTERY_OK)
532 warningFlags |= 1 << WARNING_LOW_BATTERY;
533 if (failsafeIsActive())
534 warningFlags |= 1 << WARNING_FAILSAFE;
535 if (!ARMING_FLAG(ARMED) && isArmingDisabled())
536 warningFlags |= 1 << WARNING_ARMING_DISABLED;
537 if (!isHardwareHealthy())
538 warningFlags |= 1 << WARNING_HW_ERROR;
540 *timer += LED_STRIP_HZ(10);
543 if (warningFlags) {
544 const hsvColor_t *warningColor = NULL;
546 bool colorOn = (warningFlashCounter % 2) == 0; // w_w_
547 warningFlags_e warningId = warningFlashCounter / 4;
548 if (warningFlags & (1 << warningId)) {
549 switch (warningId) {
550 case WARNING_ARMING_DISABLED:
551 warningColor = colorOn ? &HSV(GREEN) : &HSV(BLACK);
552 break;
553 case WARNING_LOW_BATTERY:
554 warningColor = colorOn ? &HSV(RED) : &HSV(BLACK);
555 break;
556 case WARNING_FAILSAFE:
557 warningColor = colorOn ? &HSV(YELLOW) : &HSV(BLUE);
558 break;
559 case WARNING_HW_ERROR:
560 warningColor = colorOn ? &HSV(BLUE) : &HSV(BLACK);
561 break;
562 default:;
565 if (warningColor)
566 applyLedHsv(LED_OVERLAY_MASK, LED_MOV_OVERLAY(LED_FLAG_OVERLAY(LED_OVERLAY_WARNING)), warningColor);
570 static void applyLedBatteryLayer(bool updateNow, timeUs_t *timer)
572 static bool flash = false;
574 int state;
575 int timeOffset = 1;
577 if (updateNow) {
578 state = getBatteryState();
580 switch (state) {
581 case BATTERY_OK:
582 flash = false;
583 timeOffset = 1;
584 break;
585 case BATTERY_WARNING:
586 timeOffset = 2;
587 break;
588 default:
589 timeOffset = 8;
590 break;
592 flash = !flash;
594 *timer += LED_STRIP_HZ(timeOffset);
598 if (!flash) {
599 const hsvColor_t *bgc = getSC(LED_SCOLOR_BACKGROUND);
600 applyLedHsv(LED_FUNCTION_MASK, LED_MOV_FUNCTION(LED_FUNCTION_BATTERY), bgc);
604 static void applyLedRssiLayer(bool updateNow, timeUs_t *timer)
606 static bool flash = false;
608 int state;
609 int timeOffset = 1;
611 if (updateNow) {
612 state = (getRSSI() * 100) / 1023;
614 if (state > 50) {
615 flash = false;
616 timeOffset = 1;
617 } else if (state > 20) {
618 timeOffset = 2;
619 } else {
620 timeOffset = 8;
622 flash = !flash;
624 *timer += LED_STRIP_HZ(timeOffset);
628 if (!flash) {
629 const hsvColor_t *bgc = getSC(LED_SCOLOR_BACKGROUND);
630 applyLedHsv(LED_FUNCTION_MASK, LED_MOV_FUNCTION(LED_FUNCTION_RSSI), bgc);
634 #ifdef USE_GPS
635 static void applyLedGpsLayer(bool updateNow, timeUs_t *timer)
637 static uint8_t gpsFlashCounter = 0;
638 static uint8_t gpsPauseCounter = 0;
639 const uint8_t blinkPauseLength = 4;
641 if (updateNow) {
642 if (gpsPauseCounter > 0) {
643 gpsPauseCounter--;
644 } else if (gpsFlashCounter >= (gpsSol.numSat - 1)) {
645 gpsFlashCounter = 0;
646 gpsPauseCounter = blinkPauseLength;
647 } else {
648 gpsFlashCounter++;
649 gpsPauseCounter = 1;
651 *timer += LED_STRIP_HZ(2.5);
654 const hsvColor_t *gpsColor;
656 if (gpsSol.numSat == 0 || !sensors(SENSOR_GPS)) {
657 gpsColor = getSC(LED_SCOLOR_GPSNOSATS);
658 } else {
659 bool colorOn = gpsPauseCounter == 0; // each interval starts with pause
660 if (STATE(GPS_FIX)) {
661 gpsColor = colorOn ? getSC(LED_SCOLOR_GPSLOCKED) : getSC(LED_SCOLOR_BACKGROUND);
662 } else {
663 gpsColor = colorOn ? getSC(LED_SCOLOR_GPSNOLOCK) : getSC(LED_SCOLOR_GPSNOSATS);
667 applyLedHsv(LED_FUNCTION_MASK, LED_MOV_FUNCTION(LED_FUNCTION_GPS), gpsColor);
670 #endif
672 #define INDICATOR_DEADBAND 25
674 static void applyLedIndicatorLayer(bool updateNow, timeUs_t *timer)
676 static bool flash = 0;
678 if (updateNow) {
679 if (rxIsReceivingSignal()) {
680 // calculate update frequency
681 int scale = (STATE(AIRPLANE) || STATE(ROVER)) ? ABS(rcCommand[ROLL]) : MAX(ABS(rcCommand[ROLL]), ABS(rcCommand[PITCH])); // 0 - 500
682 scale += (50 - INDICATOR_DEADBAND); // start increasing frequency right after deadband
683 *timer += LED_STRIP_HZ(5) * 50 / MAX(50, scale); // 5 - 50Hz update, 2.5 - 25Hz blink
685 flash = !flash;
686 } else {
687 *timer += LED_STRIP_HZ(5); // try again soon
691 if (!flash)
692 return;
694 const hsvColor_t *flashColor = &HSV(ORANGE); // TODO - use user color?
696 if (STATE(AIRPLANE) || STATE(ROVER)) {
697 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
698 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
699 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_INDICATOR)) {
700 if (((rcCommand[ROLL] > INDICATOR_DEADBAND) && (ledGetX(ledConfig) >= 8)) || ((rcCommand[ROLL] < -INDICATOR_DEADBAND) && (ledGetX(ledConfig) < 8)))
701 setLedHsv(ledIndex, flashColor);
704 } else {
705 quadrant_e quadrants = 0;
706 if (rcCommand[ROLL] > INDICATOR_DEADBAND) {
707 quadrants |= QUADRANT_NORTH_EAST | QUADRANT_SOUTH_EAST;
708 } else if (rcCommand[ROLL] < -INDICATOR_DEADBAND) {
709 quadrants |= QUADRANT_NORTH_WEST | QUADRANT_SOUTH_WEST;
711 if (rcCommand[PITCH] > INDICATOR_DEADBAND) {
712 quadrants |= QUADRANT_NORTH_EAST | QUADRANT_NORTH_WEST;
713 } else if (rcCommand[PITCH] < -INDICATOR_DEADBAND) {
714 quadrants |= QUADRANT_SOUTH_EAST | QUADRANT_SOUTH_WEST;
717 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
718 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
719 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_INDICATOR)) {
720 if (getLedQuadrant(ledIndex) & quadrants)
721 setLedHsv(ledIndex, flashColor);
727 #define ROTATION_SEQUENCE_LED_COUNT 6 // 2 on, 4 off
728 #define ROTATION_SEQUENCE_LED_WIDTH 2 // 2 on
730 static void updateLedRingCounts(void)
732 int seqLen;
733 // try to split in segments/rings of exactly ROTATION_SEQUENCE_LED_COUNT leds
734 if ((ledCounts.ring % ROTATION_SEQUENCE_LED_COUNT) == 0) {
735 seqLen = ROTATION_SEQUENCE_LED_COUNT;
736 } else {
737 seqLen = ledCounts.ring;
738 // else split up in equal segments/rings of at most ROTATION_SEQUENCE_LED_COUNT leds
739 // TODO - improve partitioning (15 leds -> 3x5)
740 while ((seqLen > ROTATION_SEQUENCE_LED_COUNT) && ((seqLen % 2) == 0)) {
741 seqLen /= 2;
744 ledCounts.ringSeqLen = seqLen;
747 static void applyLedThrustRingLayer(bool updateNow, timeUs_t *timer)
749 static uint8_t rotationPhase;
750 int ledRingIndex = 0;
752 if (updateNow) {
753 rotationPhase = rotationPhase > 0 ? rotationPhase - 1 : ledCounts.ringSeqLen - 1;
755 int scale = scaledThrottle; // ARMING_FLAG(ARMED) ? scaleRange(rxGetChannelValue(THROTTLE), PWM_RANGE_MIN, PWM_RANGE_MAX, 10, 100) : 10;
756 *timer += LED_STRIP_HZ(5) * 10 / scale; // 5 - 50Hz update rate
759 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
760 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
761 if (ledGetFunction(ledConfig) == LED_FUNCTION_THRUST_RING) {
763 bool applyColor;
764 if (ARMING_FLAG(ARMED)) {
765 applyColor = (ledRingIndex + rotationPhase) % ledCounts.ringSeqLen < ROTATION_SEQUENCE_LED_WIDTH;
766 } else {
767 applyColor = !(ledRingIndex % 2); // alternating pattern
770 if (applyColor) {
771 const hsvColor_t *ringColor = &ledStripConfig()->colors[ledGetColor(ledConfig)];
772 setLedHsv(ledIndex, ringColor);
775 ledRingIndex++;
780 typedef struct larsonParameters_s {
781 uint8_t currentBrightness;
782 int8_t currentIndex;
783 int8_t direction;
784 } larsonParameters_t;
786 static int brightnessForLarsonIndex(larsonParameters_t *larsonParameters, uint8_t larsonIndex)
788 int offset = larsonIndex - larsonParameters->currentIndex;
789 static const int larsonLowValue = 8;
791 if (ABS(offset) > 1)
792 return (larsonLowValue);
794 if (offset == 0)
795 return (larsonParameters->currentBrightness);
797 if (larsonParameters->direction == offset) {
798 return (larsonParameters->currentBrightness - 127);
801 return (255 - larsonParameters->currentBrightness);
805 static void larsonScannerNextStep(larsonParameters_t *larsonParameters, int delta)
807 if (larsonParameters->currentBrightness > (255 - delta)) {
808 larsonParameters->currentBrightness = 127;
809 if (larsonParameters->currentIndex >= ledCounts.larson || larsonParameters->currentIndex < 0) {
810 larsonParameters->direction = -larsonParameters->direction;
812 larsonParameters->currentIndex += larsonParameters->direction;
813 } else {
814 larsonParameters->currentBrightness += delta;
818 static void applyLarsonScannerLayer(bool updateNow, timeUs_t *timer)
820 static larsonParameters_t larsonParameters = { 0, 0, 1 };
822 if (updateNow) {
823 larsonScannerNextStep(&larsonParameters, 15);
824 *timer += LED_STRIP_HZ(60);
827 int scannerLedIndex = 0;
828 for (unsigned i = 0; i < ledCounts.count; i++) {
830 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[i];
832 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_LARSON_SCANNER)) {
833 hsvColor_t ledColor;
834 getLedHsv(i, &ledColor);
835 ledColor.v = brightnessForLarsonIndex(&larsonParameters, scannerLedIndex);
836 setLedHsv(i, &ledColor);
837 scannerLedIndex++;
842 // blink twice, then wait ; either always or just when landing
843 static void applyLedBlinkLayer(bool updateNow, timeUs_t *timer)
845 const uint16_t blinkPattern = 0x8005; // 0b1000000000000101;
846 static uint16_t blinkMask;
848 if (updateNow) {
849 blinkMask = blinkMask >> 1;
850 if (blinkMask <= 1)
851 blinkMask = blinkPattern;
853 *timer += LED_STRIP_HZ(10);
856 bool ledOn = (blinkMask & 1); // b_b_____...
857 for (int i = 0; i < ledCounts.count; ++i) {
858 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[i];
860 if (ledOn) {
861 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_STROBE)) {
862 setLedHsv(i, getSC(LED_SCOLOR_STROBE));
864 } else {
865 if (ledGetOverlayBit(ledConfig, LED_OVERLAY_BLINK) ||
866 (ledGetOverlayBit(ledConfig, LED_OVERLAY_LANDING_FLASH) && scaledThrottle < 55 && scaledThrottle > 10)) {
867 setLedHsv(i, getSC(LED_SCOLOR_BLINKBACKGROUND));
873 #ifdef USE_LED_ANIMATION
874 static void applyLedAnimationLayer(bool updateNow, timeUs_t *timer)
876 static uint8_t frameCounter = 0;
877 const int animationFrames = ledGridHeight;
878 if (updateNow) {
879 frameCounter = (frameCounter + 1 < animationFrames) ? frameCounter + 1 : 0;
880 *timer += LED_STRIP_HZ(20);
883 if (ARMING_FLAG(ARMED))
884 return;
886 int previousRow = frameCounter > 0 ? frameCounter - 1 : animationFrames - 1;
887 int currentRow = frameCounter;
888 int nextRow = (frameCounter + 1 < animationFrames) ? frameCounter + 1 : 0;
890 for (int ledIndex = 0; ledIndex < ledCounts.count; ledIndex++) {
891 const ledConfig_t *ledConfig = &ledStripConfig()->ledConfigs[ledIndex];
893 if (ledGetY(ledConfig) == previousRow) {
894 setLedHsv(ledIndex, getSC(LED_SCOLOR_ANIMATION));
895 scaleLedValue(ledIndex, 50);
896 } else if (ledGetY(ledConfig) == currentRow) {
897 setLedHsv(ledIndex, getSC(LED_SCOLOR_ANIMATION));
898 } else if (ledGetY(ledConfig) == nextRow) {
899 scaleLedValue(ledIndex, 50);
903 #endif
905 typedef enum {
906 timBlink = 0,
907 timLarson,
908 timBattery,
909 timRssi,
910 #ifdef USE_GPS
911 timGps,
912 #endif
913 timWarning,
914 timIndicator,
915 #ifdef USE_LED_ANIMATION
916 timAnimation,
917 #endif
918 timRing,
919 timTimerCount
920 } timId_e;
922 static timeUs_t timerVal[timTimerCount];
924 // function to apply layer.
925 // function must replan self using timer pointer
926 // when updateNow is true (timer triggered), state must be updated first,
927 // before calculating led state. Otherwise update started by different trigger
928 // may modify LED state.
929 typedef void applyLayerFn_timed(bool updateNow, timeUs_t *timer);
931 static applyLayerFn_timed* layerTable[timTimerCount] = {
932 [timBlink] = &applyLedBlinkLayer,
933 [timLarson] = &applyLarsonScannerLayer,
934 [timBattery] = &applyLedBatteryLayer,
935 [timRssi] = &applyLedRssiLayer,
936 #ifdef USE_GPS
937 [timGps] = &applyLedGpsLayer,
938 #endif
939 [timWarning] = &applyLedWarningLayer,
940 [timIndicator] = &applyLedIndicatorLayer,
941 #ifdef USE_LED_ANIMATION
942 [timAnimation] = &applyLedAnimationLayer,
943 #endif
944 [timRing] = &applyLedThrustRingLayer
947 void ledStripUpdate(timeUs_t currentTimeUs)
949 if (!(ledStripInitialised && isWS2811LedStripReady())) {
950 return;
953 if (IS_RC_MODE_ACTIVE(BOXLEDLOW)) {
954 if (ledStripEnabled) {
955 ledStripDisable();
956 ledStripEnabled = false;
958 return;
960 ledStripEnabled = true;
962 // test all led timers, setting corresponding bits
963 uint32_t timActive = 0;
964 for (timId_e timId = 0; timId < timTimerCount; timId++) {
965 // sanitize timer value, so that it can be safely incremented. Handles inital timerVal value.
966 // max delay is limited to 5s
967 timeDelta_t delta = cmpTimeUs(currentTimeUs, timerVal[timId]);
968 if (delta < 0 && delta > -LED_STRIP_MS(5000))
969 continue; // not ready yet
970 timActive |= 1 << timId;
971 if (delta >= LED_STRIP_MS(100) || delta < 0) {
972 timerVal[timId] = currentTimeUs;
976 if (!timActive)
977 return; // no change this update, keep old state
979 // apply all layers; triggered timed functions has to update timers
981 scaledThrottle = ARMING_FLAG(ARMED) ? scaleRange(rxGetChannelValue(THROTTLE), PWM_RANGE_MIN, PWM_RANGE_MAX, 10, 100) : 10;
983 applyLedFixedLayers();
985 for (timId_e timId = 0; timId < ARRAYLEN(layerTable); timId++) {
986 timeUs_t *timer = &timerVal[timId];
987 bool updateNow = timActive & (1 << timId);
988 (*layerTable[timId])(updateNow, timer);
990 ws2811UpdateStrip();
993 bool parseColor(int index, const char *colorConfig)
995 const char *remainingCharacters = colorConfig;
997 hsvColor_t *color = &ledStripConfigMutable()->colors[index];
999 bool result = true;
1000 static const uint16_t hsv_limit[HSV_COLOR_COMPONENT_COUNT] = {
1001 [HSV_HUE] = HSV_HUE_MAX,
1002 [HSV_SATURATION] = HSV_SATURATION_MAX,
1003 [HSV_VALUE] = HSV_VALUE_MAX,
1005 for (int componentIndex = 0; result && componentIndex < HSV_COLOR_COMPONENT_COUNT; componentIndex++) {
1006 int val = fastA2I(remainingCharacters);
1007 if (val > hsv_limit[componentIndex]) {
1008 result = false;
1009 break;
1011 switch (componentIndex) {
1012 case HSV_HUE:
1013 color->h = val;
1014 break;
1015 case HSV_SATURATION:
1016 color->s = val;
1017 break;
1018 case HSV_VALUE:
1019 color->v = val;
1020 break;
1022 remainingCharacters = strchr(remainingCharacters, ',');
1023 if (remainingCharacters) {
1024 remainingCharacters++; // skip separator
1025 } else {
1026 if (componentIndex < HSV_COLOR_COMPONENT_COUNT - 1) {
1027 result = false;
1032 if (!result) {
1033 memset(color, 0, sizeof(*color));
1036 return result;
1040 * Redefine a color in a mode.
1041 * */
1042 bool setModeColor(ledModeIndex_e modeIndex, int modeColorIndex, int colorIndex)
1044 // check color
1045 if (colorIndex < 0 || colorIndex >= LED_CONFIGURABLE_COLOR_COUNT)
1046 return false;
1047 if (modeIndex < LED_MODE_COUNT) { // modeIndex_e is unsigned, so one-sided test is enough
1048 if (modeColorIndex < 0 || modeColorIndex >= LED_DIRECTION_COUNT)
1049 return false;
1050 ledStripConfigMutable()->modeColors[modeIndex].color[modeColorIndex] = colorIndex;
1051 } else if (modeIndex == LED_SPECIAL) {
1052 if (modeColorIndex < 0 || modeColorIndex >= LED_SPECIAL_COLOR_COUNT)
1053 return false;
1054 ledStripConfigMutable()->specialColors.color[modeColorIndex] = colorIndex;
1055 } else {
1056 return false;
1058 return true;
1061 void ledStripInit(void)
1063 ledStripInitialised = false;
1066 void ledStripEnable(void)
1068 reevaluateLedConfig();
1069 ledStripInitialised = true;
1071 ws2811LedStripInit();
1074 static void ledStripDisable(void)
1076 setStripColor(&HSV(BLACK));
1078 ws2811UpdateStrip();
1080 #endif