// -*- mode: c++; c-basic-offset: 2; indent-tabs-mode: nil; -*- // Copyright (C) 2013 Henner Zeller // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation version 2. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see #include "led-matrix.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "gpio.h" #include "thread.h" #include "framebuffer-internal.h" #include "multiplex-mappers-internal.h" // Leave this in here for a while. Setting things from old defines. #if defined(ADAFRUIT_RGBMATRIX_HAT) # error "ADAFRUIT_RGBMATRIX_HAT has long been deprecated. Please use the Options struct or --led-gpio-mapping=adafruit-hat commandline flag" #endif #if defined(ADAFRUIT_RGBMATRIX_HAT_PWM) # error "ADAFRUIT_RGBMATRIX_HAT_PWM has long been deprecated. Please use the Options struct or --led-gpio-mapping=adafruit-hat-pwm commandline flag" #endif namespace rgb_matrix { // Implementation details of RGBmatrix. class RGBMatrix::Impl { class UpdateThread; friend class UpdateThread; public: // Create an RGBMatrix. // // Needs an initialized GPIO object and configuration options from the // RGBMatrix::Options struct. // // If you pass an GPIO object (which has to be Init()ialized), it will start // the internal thread to start the screen immediately. // // If you need finer control over when the refresh thread starts (which you // might when you become a daemon), pass NULL here and see SetGPIO() method. // // The resulting canvas is (options.rows * options.parallel) high and // (32 * options.chain_length) wide. Impl(GPIO *io, const Options &options); ~Impl(); // Used to be there to help user delay initialization of thread starting, // these days only used internally. void SetGPIO(GPIO *io, bool start_thread = true); bool StartRefresh(); FrameCanvas *CreateFrameCanvas(); FrameCanvas *SwapOnVSync(FrameCanvas *other, unsigned framerate_fraction); bool ApplyPixelMapper(const PixelMapper *mapper); bool SetPWMBits(uint8_t value); uint8_t pwmbits(); // return the pwm-bits of the currently active buffer. void set_luminance_correct(bool on); bool luminance_correct() const; // Set brightness in percent for all created FrameCanvas. 1%..100%. // This will only affect newly set pixels. void SetBrightness(uint8_t brightness); uint8_t brightness(); uint64_t RequestInputs(uint64_t); uint64_t AwaitInputChange(int timeout_ms); uint64_t RequestOutputs(uint64_t output_bits); void OutputGPIO(uint64_t output_bits); void Clear(); private: friend class RGBMatrix; // Apply pixel mappers that have been passed down via a configuration // string. void ApplyNamedPixelMappers(const char *pixel_mapper_config, int chain, int parallel); Options params_; bool do_luminance_correct_; FrameCanvas *active_; GPIO *io_; Mutex active_frame_sync_; UpdateThread *updater_; std::vector created_frames_; internal::PixelDesignatorMap *shared_pixel_mapper_; uint64_t user_output_bits_; }; using namespace internal; // Pump pixels to screen. Needs to be high priority real-time because jitter class RGBMatrix::Impl::UpdateThread : public Thread { public: UpdateThread(GPIO *io, FrameCanvas *initial_frame, int pwm_dither_bits, bool show_refresh, int limit_refresh_hz, bool allow_busy_waiting) : io_(io), show_refresh_(show_refresh), target_frame_usec_(limit_refresh_hz < 1 ? 0 : 1e6/limit_refresh_hz), allow_busy_waiting_(allow_busy_waiting), running_(true), current_frame_(initial_frame), next_frame_(NULL), requested_frame_multiple_(1) { pthread_cond_init(&frame_done_, NULL); pthread_cond_init(&input_change_, NULL); switch (pwm_dither_bits) { case 0: start_bit_[0] = 0; start_bit_[1] = 0; start_bit_[2] = 0; start_bit_[3] = 0; break; case 1: start_bit_[0] = 0; start_bit_[1] = 1; start_bit_[2] = 0; start_bit_[3] = 1; break; case 2: start_bit_[0] = 0; start_bit_[1] = 1; start_bit_[2] = 2; start_bit_[3] = 2; break; } } void Stop() { MutexLock l(&running_mutex_); running_ = false; } virtual void Run() { unsigned frame_count = 0; unsigned low_bit_sequence = 0; uint32_t largest_time = 0; gpio_bits_t last_gpio_bits = 0; // Let's start measure max time only after a we were running for a few // seconds to not pick up start-up glitches. static const int kHoldffTimeUs = 2000 * 1000; uint32_t initial_holdoff_start = GetMicrosecondCounter(); bool max_measure_enabled = false; while (running()) { const uint32_t start_time_us = GetMicrosecondCounter(); current_frame_->framebuffer() ->DumpToMatrix(io_, start_bit_[low_bit_sequence % 4]); // SwapOnVSync() exchange. { MutexLock l(&frame_sync_); // Do fast equality test first (likely due to frame_count reset). if (frame_count == requested_frame_multiple_ || frame_count % requested_frame_multiple_ == 0) { // We reset to avoid frame hick-up every couple of weeks // run-time iff requested_frame_multiple_ is not a factor of 2^32. frame_count = 0; if (next_frame_ != NULL) { current_frame_ = next_frame_; next_frame_ = NULL; } pthread_cond_signal(&frame_done_); } } // Read input bits. const gpio_bits_t inputs = io_->Read(); if (inputs != last_gpio_bits) { last_gpio_bits = inputs; MutexLock l(&input_sync_); gpio_inputs_ = inputs; pthread_cond_signal(&input_change_); } ++frame_count; ++low_bit_sequence; if (target_frame_usec_) { if (allow_busy_waiting_) { while ((GetMicrosecondCounter() - start_time_us) < target_frame_usec_) { // busy wait. We have our dedicated core, so ok to burn cycles. } } else { long spent_us = GetMicrosecondCounter() - start_time_us; SleepMicroseconds(target_frame_usec_ - spent_us); } } const uint32_t end_time_us = GetMicrosecondCounter(); if (show_refresh_) { uint32_t usec = end_time_us - start_time_us; printf("\b\b\b\b\b\b\b\b%6.1fHz", 1e6 / usec); if (usec > largest_time && max_measure_enabled) { largest_time = usec; const float lowest_hz = 1e6 / largest_time; printf(" (lowest: %.1fHz)" "\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b\b", lowest_hz); } else { // Don't measure at startup, as times will be janky. max_measure_enabled = (end_time_us - initial_holdoff_start) > kHoldffTimeUs; } } } } FrameCanvas *SwapOnVSync(FrameCanvas *other, unsigned frame_fraction) { MutexLock l(&frame_sync_); FrameCanvas *previous = current_frame_; next_frame_ = other; requested_frame_multiple_ = frame_fraction; frame_sync_.WaitOn(&frame_done_); return previous; } gpio_bits_t AwaitInputChange(int timeout_ms) { MutexLock l(&input_sync_); input_sync_.WaitOn(&input_change_, timeout_ms); return gpio_inputs_; } private: inline bool running() { MutexLock l(&running_mutex_); return running_; } GPIO *const io_; const bool show_refresh_; const uint32_t target_frame_usec_; const bool allow_busy_waiting_; uint32_t start_bit_[4]; Mutex running_mutex_; bool running_; Mutex input_sync_; pthread_cond_t input_change_; gpio_bits_t gpio_inputs_; Mutex frame_sync_; pthread_cond_t frame_done_; FrameCanvas *current_frame_; FrameCanvas *next_frame_; unsigned requested_frame_multiple_; }; // Some defaults. See options-initialize.cc for the command line parsing. RGBMatrix::Options::Options() : // Historically, we provided these options only as #defines. Make sure that // things still behave as before if someone has set these. // At some point: remove them from the Makefile. Later: remove them here. #ifdef DEFAULT_HARDWARE hardware_mapping(DEFAULT_HARDWARE), #else hardware_mapping("regular"), #endif rows(32), cols(32), chain_length(1), parallel(1), pwm_bits(internal::Framebuffer::kDefaultBitPlanes), #ifdef LSB_PWM_NANOSECONDS pwm_lsb_nanoseconds(LSB_PWM_NANOSECONDS), #else pwm_lsb_nanoseconds(130), #endif pwm_dither_bits(0), brightness(100), #ifdef RGB_SCAN_INTERLACED scan_mode(1), #else scan_mode(0), #endif row_address_type(0), multiplexing(0), #ifdef DISABLE_HARDWARE_PULSES disable_hardware_pulsing(true), #else disable_hardware_pulsing(false), #endif #ifdef SHOW_REFRESH_RATE show_refresh_rate(true), #else show_refresh_rate(false), #endif #ifdef INVERSE_RGB_DISPLAY_COLORS inverse_colors(true), #else inverse_colors(false), #endif led_rgb_sequence("RGB"), pixel_mapper_config(NULL), panel_type(NULL), #ifdef FIXED_FRAME_MICROSECONDS limit_refresh_rate_hz(1e6 / FIXED_FRAME_MICROSECONDS), #else limit_refresh_rate_hz(0), #endif #ifdef DISABLE_BUSY_WAITING disable_busy_waiting(true) #else disable_busy_waiting(false) #endif { // Nothing to see here. } #define DEBUG_MATRIX_OPTIONS 0 #if DEBUG_MATRIX_OPTIONS static void PrintOptions(const RGBMatrix::Options &o) { #define P_INT(val) fprintf(stderr, "%s : %d\n", #val, o.val) #define P_STR(val) fprintf(stderr, "%s : %s\n", #val, o.val) #define P_BOOL(val) fprintf(stderr, "%s : %s\n", #val, o.val ? "true":"false") P_STR(hardware_mapping); P_INT(rows); P_INT(cols); P_INT(chain_length); P_INT(parallel); P_INT(pwm_bits); P_INT(pwm_lsb_nanoseconds); P_INT(pwm_dither_bits); P_INT(brightness); P_INT(scan_mode); P_INT(row_address_type); P_INT(multiplexing); P_BOOL(disable_hardware_pulsing); P_BOOL(show_refresh_rate); P_BOOL(inverse_colors); P_STR(led_rgb_sequence); P_STR(pixel_mapper_config); P_STR(panel_type); P_INT(limit_refresh_rate_hz); P_BOOL(disable_busy_waiting); #undef P_INT #undef P_STR #undef P_BOOL } #endif // DEBUG_MATRIX_OPTIONS RGBMatrix::Impl::Impl(GPIO *io, const Options &options) : params_(options), io_(NULL), updater_(NULL), shared_pixel_mapper_(NULL), user_output_bits_(0) { assert(params_.Validate(NULL)); #if DEBUG_MATRIX_OPTIONS PrintOptions(params_); #endif const MultiplexMapper *multiplex_mapper = NULL; if (params_.multiplexing > 0) { const MuxMapperList &multiplexers = GetRegisteredMultiplexMappers(); if (params_.multiplexing <= (int) multiplexers.size()) { // TODO: we could also do a find-by-name here, but not sure if worthwhile multiplex_mapper = multiplexers[params_.multiplexing - 1]; } } if (multiplex_mapper) { // The multiplexers might choose to have a different physical layout. // We need to configure that first before setting up the hardware. multiplex_mapper->EditColsRows(¶ms_.cols, ¶ms_.rows); } Framebuffer::InitHardwareMapping(params_.hardware_mapping); active_ = CreateFrameCanvas(); active_->Clear(); SetGPIO(io, true); // We need to apply the mapping for the panels first. ApplyPixelMapper(multiplex_mapper); // .. followed by higher level mappers that might arrange panels. ApplyNamedPixelMappers(options.pixel_mapper_config, params_.chain_length, params_.parallel); } RGBMatrix::Impl::~Impl() { if (updater_) { updater_->Stop(); updater_->WaitStopped(); } delete updater_; // Make sure LEDs are off. active_->Clear(); if (io_) active_->framebuffer()->DumpToMatrix(io_, 0); for (size_t i = 0; i < created_frames_.size(); ++i) { delete created_frames_[i]; } delete shared_pixel_mapper_; } RGBMatrix::~RGBMatrix() { delete impl_; } uint64_t RGBMatrix::Impl::RequestInputs(uint64_t bits) { return io_->RequestInputs(static_cast(bits)); } uint64_t RGBMatrix::Impl::RequestOutputs(uint64_t output_bits) { uint64_t success_bits = io_->InitOutputs(static_cast(output_bits)); user_output_bits_ |= success_bits; return success_bits; } void RGBMatrix::Impl::OutputGPIO(uint64_t output_bits) { io_->WriteMaskedBits(static_cast(output_bits), static_cast(user_output_bits_)); } void RGBMatrix::Impl::ApplyNamedPixelMappers(const char *pixel_mapper_config, int chain, int parallel) { if (pixel_mapper_config == NULL || strlen(pixel_mapper_config) == 0) return; char *const writeable_copy = strdup(pixel_mapper_config); const char *const end = writeable_copy + strlen(writeable_copy); char *s = writeable_copy; while (s < end) { char *const semicolon = strchrnul(s, ';'); *semicolon = '\0'; char *optional_param_start = strchr(s, ':'); if (optional_param_start) { *optional_param_start++ = '\0'; } if (*s == '\0' && optional_param_start && *optional_param_start != '\0') { fprintf(stderr, "Stray parameter ':%s' without mapper name ?\n", optional_param_start); } if (*s) { ApplyPixelMapper(FindPixelMapper(s, chain, parallel, optional_param_start)); } s = semicolon + 1; } free(writeable_copy); } void RGBMatrix::Impl::SetGPIO(GPIO *io, bool start_thread) { if (io != NULL && io_ == NULL) { io_ = io; Framebuffer::InitGPIO(io_, params_.rows, params_.parallel, !params_.disable_hardware_pulsing, params_.pwm_lsb_nanoseconds, params_.pwm_dither_bits, params_.row_address_type); Framebuffer::InitializePanels(io_, params_.panel_type, params_.cols * params_.chain_length); } if (start_thread) { StartRefresh(); } } bool RGBMatrix::Impl::StartRefresh() { if (updater_ == NULL && io_ != NULL) { updater_ = new UpdateThread(io_, active_, params_.pwm_dither_bits, params_.show_refresh_rate, params_.limit_refresh_rate_hz, !params_.disable_busy_waiting); // If we have multiple processors, the kernel // jumps around between these, creating some global flicker. // So let's tie it to the last CPU available. // The Raspberry Pi2 has 4 cores, our attempt to bind it to // core #3 will succeed. // The Raspberry Pi1 only has one core, so this affinity // call will simply fail and we keep using the only core. updater_->Start(99, (1<<3)); // Prio: high. Also: put on last CPU. } return updater_ != NULL; } FrameCanvas *RGBMatrix::Impl::CreateFrameCanvas() { FrameCanvas *result = new FrameCanvas(new Framebuffer(params_.rows, params_.cols * params_.chain_length, params_.parallel, params_.scan_mode, params_.led_rgb_sequence, params_.inverse_colors, &shared_pixel_mapper_)); if (created_frames_.empty()) { // First time. Get defaults from initial Framebuffer. do_luminance_correct_ = result->framebuffer()->luminance_correct(); } result->framebuffer()->SetPWMBits(params_.pwm_bits); result->framebuffer()->set_luminance_correct(do_luminance_correct_); result->framebuffer()->SetBrightness(params_.brightness); created_frames_.push_back(result); if (created_frames_.size() % 500 == 0) { if (created_frames_.size() == 500) { fprintf(stderr, "CreateFrameCanvas() called %d times; Usually you only want to call it once (or at most a few times) for double-buffering. These frames will not be freed until the end of the program.\n" "Typical reasons: \n" " * Accidentally called CreateFrameCanvas() inside your inner loop (move outside the loop. Create offscreen-canvas once, then re-use. See SwapOnVSync() examples).\n" " * Used to pre-compute many frames (use led_matrix::StreamWriter instead for such use-case. See e.g. led-image-viewer)\n", (int)created_frames_.size()); } else { fprintf(stderr, "FYI: CreateFrameCanvas() now called %d times.\n", (int)created_frames_.size()); } } return result; } FrameCanvas *RGBMatrix::Impl::SwapOnVSync(FrameCanvas *other, unsigned frame_fraction) { if (frame_fraction == 0) frame_fraction = 1; // correct user error. if (!updater_) return NULL; FrameCanvas *const previous = updater_->SwapOnVSync(other, frame_fraction); if (other) active_ = other; return previous; } uint64_t RGBMatrix::Impl::AwaitInputChange(int timeout_ms) { if (!updater_) return 0; return updater_->AwaitInputChange(timeout_ms); } bool RGBMatrix::Impl::SetPWMBits(uint8_t value) { const bool success = active_->framebuffer()->SetPWMBits(value); if (success) { params_.pwm_bits = value; } return success; } uint8_t RGBMatrix::Impl::pwmbits() { return params_.pwm_bits; } // Map brightness of output linearly to input with CIE1931 profile. void RGBMatrix::Impl::set_luminance_correct(bool on) { active_->framebuffer()->set_luminance_correct(on); do_luminance_correct_ = on; } bool RGBMatrix::Impl::luminance_correct() const { return do_luminance_correct_; } void RGBMatrix::Impl::SetBrightness(uint8_t brightness) { for (size_t i = 0; i < created_frames_.size(); ++i) { created_frames_[i]->framebuffer()->SetBrightness(brightness); } params_.brightness = brightness; } uint8_t RGBMatrix::Impl::brightness() { return params_.brightness; } bool RGBMatrix::Impl::ApplyPixelMapper(const PixelMapper *mapper) { if (mapper == NULL) return true; using internal::PixelDesignatorMap; const int old_width = shared_pixel_mapper_->width(); const int old_height = shared_pixel_mapper_->height(); int new_width, new_height; if (!mapper->GetSizeMapping(old_width, old_height, &new_width, &new_height)) { return false; } PixelDesignatorMap *new_mapper = new PixelDesignatorMap( new_width, new_height, shared_pixel_mapper_->GetFillColorBits()); for (int y = 0; y < new_height; ++y) { for (int x = 0; x < new_width; ++x) { int orig_x = -1, orig_y = -1; mapper->MapVisibleToMatrix(old_width, old_height, x, y, &orig_x, &orig_y); if (orig_x < 0 || orig_y < 0 || orig_x >= old_width || orig_y >= old_height) { fprintf(stderr, "Error in PixelMapper: (%d, %d) -> (%d, %d) [range: " "%dx%d]\n", x, y, orig_x, orig_y, old_width, old_height); continue; } const internal::PixelDesignator *orig_designator; orig_designator = shared_pixel_mapper_->get(orig_x, orig_y); *new_mapper->get(x, y) = *orig_designator; } } delete shared_pixel_mapper_; shared_pixel_mapper_ = new_mapper; return true; } // -- Public interface of RGBMatrix. Delegate everything to impl_ static bool drop_privs(const char *priv_user, const char *priv_group) { uid_t ruid, euid, suid; if (getresuid(&ruid, &euid, &suid) >= 0) { if (euid != 0) // not root anyway. No priv dropping. return true; } if (priv_user == nullptr || priv_user[0] == 0) priv_user = "daemon"; if (priv_group == nullptr || priv_group[0] == 0) priv_group = "daemon"; gid_t gid = atoi(priv_group); // Attempt to parse as GID first if (gid == 0) { struct group *g = getgrnam(priv_group); if (g == NULL) { perror("group lookup."); return false; } gid = g->gr_gid; } if (setresgid(gid, gid, gid) != 0) { perror("setresgid()"); return false; } uid_t uid = atoi(priv_user); // Attempt to parse as UID first. if (uid == 0) { struct passwd *p = getpwnam(priv_user); if (p == NULL) { perror("user lookup."); return false; } uid = p->pw_uid; } if (setresuid(uid, uid, uid) != 0) { perror("setresuid()"); return false; } return true; } RGBMatrix *RGBMatrix::CreateFromOptions(const RGBMatrix::Options &options, const RuntimeOptions &runtime_options) { std::string error; if (!options.Validate(&error)) { fprintf(stderr, "%s\n", error.c_str()); return NULL; } // For the Pi4, we might need 2, maybe up to 4. Let's open up to 5. // on supproted architectures, -1 will emit memory barier (DSB ST) after GPIO write if (runtime_options.gpio_slowdown < (LED_MATRIX_ALLOW_BARRIER_DELAY ? -1 : 0) || runtime_options.gpio_slowdown > 5) { fprintf(stderr, "--led-slowdown-gpio=%d is outside usable range\n", runtime_options.gpio_slowdown); return NULL; } static GPIO io; // This static var is a little bit icky. if (runtime_options.do_gpio_init && !io.Init(runtime_options.gpio_slowdown)) { fprintf(stderr, "Must run as root to be able to access /dev/mem\n" "Prepend 'sudo' to the command\n"); return NULL; } if (runtime_options.daemon > 0 && daemon(1, 0) != 0) { perror("Failed to become daemon"); } RGBMatrix::Impl *result = new RGBMatrix::Impl(NULL, options); // Allowing daemon also means we are allowed to start the thread now. const bool allow_daemon = !(runtime_options.daemon < 0); if (runtime_options.do_gpio_init) result->SetGPIO(&io, allow_daemon); // TODO(hzeller): if we disallow daemon, then we might also disallow // drop privileges: we can't drop privileges until we have created the // realtime thread that usually requires root to be established. // Double check and document. if (runtime_options.drop_privileges > 0) { drop_privs(runtime_options.drop_priv_user, runtime_options.drop_priv_group); } return new RGBMatrix(result); } // Public interface. RGBMatrix *RGBMatrix::CreateFromFlags(int *argc, char ***argv, RGBMatrix::Options *m_opt_in, RuntimeOptions *rt_opt_in, bool remove_consumed_options) { RGBMatrix::Options scratch_matrix; RGBMatrix::Options *mopt = (m_opt_in != NULL) ? m_opt_in : &scratch_matrix; RuntimeOptions scratch_rt; RuntimeOptions *ropt = (rt_opt_in != NULL) ? rt_opt_in : &scratch_rt; if (!ParseOptionsFromFlags(argc, argv, mopt, ropt, remove_consumed_options)) return NULL; return CreateFromOptions(*mopt, *ropt); } FrameCanvas *RGBMatrix::CreateFrameCanvas() { return impl_->CreateFrameCanvas(); } FrameCanvas *RGBMatrix::SwapOnVSync(FrameCanvas *other, unsigned framerate_fraction) { return impl_->SwapOnVSync(other, framerate_fraction); } bool RGBMatrix::ApplyPixelMapper(const PixelMapper *mapper) { return impl_->ApplyPixelMapper(mapper); } bool RGBMatrix::SetPWMBits(uint8_t value) { return impl_->SetPWMBits(value); } uint8_t RGBMatrix::pwmbits() { return impl_->pwmbits(); } void RGBMatrix::set_luminance_correct(bool on) { return impl_->set_luminance_correct(on); } bool RGBMatrix::luminance_correct() const { return impl_->luminance_correct(); } void RGBMatrix::SetBrightness(uint8_t brightness) { impl_->SetBrightness(brightness); } uint8_t RGBMatrix::brightness() { return impl_->brightness(); } uint64_t RGBMatrix::RequestInputs(uint64_t all_interested_bits) { return impl_->RequestInputs(all_interested_bits); } uint64_t RGBMatrix::AwaitInputChange(int timeout_ms) { return impl_->AwaitInputChange(timeout_ms); } uint64_t RGBMatrix::RequestOutputs(uint64_t all_interested_bits) { return impl_->RequestOutputs(all_interested_bits); } void RGBMatrix::OutputGPIO(uint64_t output_bits) { impl_->OutputGPIO(output_bits); } bool RGBMatrix::StartRefresh() { return impl_->StartRefresh(); } // -- Implementation of RGBMatrix Canvas: delegation to ContentBuffer int RGBMatrix::width() const { return impl_->active_->width(); } int RGBMatrix::height() const { return impl_->active_->height(); } void RGBMatrix::SetPixel(int x, int y, uint8_t red, uint8_t green, uint8_t blue) { impl_->active_->SetPixel(x, y, red, green, blue); } void RGBMatrix::Clear() { impl_->active_->Clear(); } void RGBMatrix::Fill(uint8_t red, uint8_t green, uint8_t blue) { impl_->active_->Fill(red, green, blue); } // FrameCanvas implementation of Canvas FrameCanvas::~FrameCanvas() { delete frame_; } int FrameCanvas::width() const { return frame_->width(); } int FrameCanvas::height() const { return frame_->height(); } void FrameCanvas::SetPixel(int x, int y, uint8_t red, uint8_t green, uint8_t blue) { frame_->SetPixel(x, y, red, green, blue); } void FrameCanvas::SetPixels(int x, int y, int width, int height, Color *colors) { frame_->SetPixels(x, y, width, height, colors); } void FrameCanvas::Clear() { return frame_->Clear(); } void FrameCanvas::Fill(uint8_t red, uint8_t green, uint8_t blue) { frame_->Fill(red, green, blue); } bool FrameCanvas::SetPWMBits(uint8_t value) { return frame_->SetPWMBits(value); } uint8_t FrameCanvas::pwmbits() { return frame_->pwmbits(); } // Map brightness of output linearly to input with CIE1931 profile. void FrameCanvas::set_luminance_correct(bool on) { frame_->set_luminance_correct(on); } bool FrameCanvas::luminance_correct() const { return frame_->luminance_correct(); } void FrameCanvas::SetBrightness(uint8_t brightness) { frame_->SetBrightness(brightness); } uint8_t FrameCanvas::brightness() { return frame_->brightness(); } void FrameCanvas::Serialize(const char **data, size_t *len) const { frame_->Serialize(data, len); } bool FrameCanvas::Deserialize(const char *data, size_t len) { return frame_->Deserialize(data, len); } void FrameCanvas::CopyFrom(const FrameCanvas &other) { frame_->CopyFrom(other.frame_); } } // end namespace rgb_matrix