pixelflut-rgb-matrix-server/lib/framebuffer-internal.h

// -*- mode: c++; c-basic-offset: 2; indent-tabs-mode: nil; -*-
// Copyright (C) 2013 Henner Zeller <h.zeller@acm.org>
//
// 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 <http://gnu.org/licenses/gpl-2.0.txt>
#ifndef RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H
#define RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H

#include <stdint.h>
#include <stdlib.h>

#include "hardware-mapping.h"

namespace rgb_matrix {
class GPIO;
class PinPulser;
namespace internal {
class RowAddressSetter;

// An opaque type used within the framebuffer that can be used
// to copy between PixelMappers.
struct PixelDesignator {
  PixelDesignator() : gpio_word(-1), r_bit(0), g_bit(0), b_bit(0), mask(~0u){}
  long gpio_word;
  gpio_bits_t r_bit;
  gpio_bits_t g_bit;
  gpio_bits_t b_bit;
  gpio_bits_t mask;
};

class PixelDesignatorMap {
public:
  PixelDesignatorMap(int width, int height, const PixelDesignator &fill_bits);
  ~PixelDesignatorMap();

  // Get a writable version of the PixelDesignator. Outside Framebuffer used
  // by the RGBMatrix to re-assign mappings to new PixelDesignatorMappers.
  PixelDesignator *get(int x, int y);

  inline int width() const { return width_; }
  inline int height() const { return height_; }

  // All bits that set red/green/blue pixels; used for Fill().
  const PixelDesignator &GetFillColorBits() { return fill_bits_; }

private:
  const int width_;
  const int height_;
  const PixelDesignator fill_bits_;  // Precalculated for fill.
  PixelDesignator *const buffer_;
};

// Internal representation of the frame-buffer that as well can
// write itself to GPIO.
// Our internal memory layout mimicks as much as possible what needs to be
// written out.
class Framebuffer {
public:
  // Maximum usable bitplanes.
  //
  // 11 bits seems to be a sweet spot in which we still get somewhat useful
  // refresh rate and have good color richness. This is the default setting
  // However, in low-light situations, we want to be able to scale down
  // brightness more, having more bits at the bottom.
  // TODO(hzeller): make the default 15 bit or so, but slide the use of
  //  timing to lower bits if fewer bits requested to not affect the overall
  //  refresh in that case.
  //  This needs to be balanced to not create too agressive timing however.
  //  To be explored in a separete commit.
  //
  // For now, if someone needs very low level of light, change this to
  // say 13 and recompile. Run with --led-pwm-bits=13. Also, consider
  // --led-pwm-dither-bits=2 to have the refresh rate not suffer too much.
  static constexpr int kBitPlanes = 11;
  static constexpr int kDefaultBitPlanes = 11;

  Framebuffer(int rows, int columns, int parallel,
              int scan_mode,
              const char* led_sequence, bool inverse_color,
              PixelDesignatorMap **mapper);
  ~Framebuffer();

  // Initialize GPIO bits for output. Only call once.
  static void InitHardwareMapping(const char *named_hardware);
  static void InitGPIO(GPIO *io, int rows, int parallel,
                       bool allow_hardware_pulsing,
                       int pwm_lsb_nanoseconds,
                       int dither_bits,
                       int row_address_type);
  static void InitializePanels(GPIO *io, const char *panel_type, int columns);

  // Set PWM bits used for output. Default is 11, but if you only deal with
  // simple comic-colors, 1 might be sufficient. Lower require less CPU.
  // Returns boolean to signify if value was within range.
  bool SetPWMBits(uint8_t value);
  uint8_t pwmbits() { return pwm_bits_; }

  // Map brightness of output linearly to input with CIE1931 profile.
  void set_luminance_correct(bool on) { do_luminance_correct_ = on; }
  bool luminance_correct() const { return do_luminance_correct_; }

  // Set brightness in percent; range=1..100
  // This will only affect newly set pixels.
  void SetBrightness(uint8_t b) {
    brightness_ = (b <= 100 ? (b != 0 ? b : 1) : 100);
  }
  uint8_t brightness() { return brightness_; }

  void DumpToMatrix(GPIO *io, int pwm_bits_to_show);

  void Serialize(const char **data, size_t *len) const;
  bool Deserialize(const char *data, size_t len);
  void CopyFrom(const Framebuffer *other);

  // Canvas-inspired methods, but we're not implementing this interface to not
  // have an unnecessary vtable.
  int width() const;
  int height() const;
  void SetPixel(int x, int y, uint8_t red, uint8_t green, uint8_t blue);
  void Clear();
  void Fill(uint8_t red, uint8_t green, uint8_t blue);

private:
  static const struct HardwareMapping *hardware_mapping_;
  static RowAddressSetter *row_setter_;

  // This returns the gpio-bit for given color (one of 'R', 'G', 'B'). This is
  // returning the right value in case "led_sequence" is _not_ "RGB"
  static gpio_bits_t GetGpioFromLedSequence(char col, const char *led_sequence,
                                            gpio_bits_t default_r,
                                            gpio_bits_t default_g,
                                            gpio_bits_t default_b);

  void InitDefaultDesignator(int x, int y, const char *led_sequence,
                             PixelDesignator *designator);
  inline void  MapColors(uint8_t r, uint8_t g, uint8_t b,
                         uint16_t *red, uint16_t *green, uint16_t *blue);
  const int rows_;     // Number of rows. 16 or 32.
  const int parallel_; // Parallel rows of chains. 1 or 2.
  const int height_;   // rows * parallel
  const int columns_;  // Number of columns. Number of chained boards * 32.

  const int scan_mode_;
  const bool inverse_color_;

  uint8_t pwm_bits_;   // PWM bits to display.
  bool do_luminance_correct_;
  uint8_t brightness_;

  const int double_rows_;
  const size_t buffer_size_;

  // The frame-buffer is organized in bitplanes.
  // Highest level (slowest to cycle through) are double rows.
  // For each double-row, we store pwm-bits columns of a bitplane.
  // Each bitplane-column is pre-filled IoBits, of which the colors are set.
  // Of course, that means that we store unrelated bits in the frame-buffer,
  // but it allows easy access in the critical section.
  gpio_bits_t *bitplane_buffer_;
  inline gpio_bits_t *ValueAt(int double_row, int column, int bit);

  PixelDesignatorMap **shared_mapper_;  // Storage in RGBMatrix.
};
}  // namespace internal
}  // namespace rgb_matrix
#endif // RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H
Initial commit 2020-12-26 12:23:47 +00:00			`// -- mode: c++; c-basic-offset: 2; indent-tabs-mode: nil; --`
			`// Copyright (C) 2013 Henner Zeller <h.zeller@acm.org>`
			`//`
			`// 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 <http://gnu.org/licenses/gpl-2.0.txt>`
			`#ifndef RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H`
			`#define RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H`

			`#include <stdint.h>`
			`#include <stdlib.h>`

			`#include "hardware-mapping.h"`

			`namespace rgb_matrix {`
			`class GPIO;`
			`class PinPulser;`
			`namespace internal {`
			`class RowAddressSetter;`

			`// An opaque type used within the framebuffer that can be used`
			`// to copy between PixelMappers.`
			`struct PixelDesignator {`
			`PixelDesignator() : gpio_word(-1), r_bit(0), g_bit(0), b_bit(0), mask(~0u){}`
			`long gpio_word;`
			`gpio_bits_t r_bit;`
			`gpio_bits_t g_bit;`
			`gpio_bits_t b_bit;`
			`gpio_bits_t mask;`
			`};`

			`class PixelDesignatorMap {`
			`public:`
			`PixelDesignatorMap(int width, int height, const PixelDesignator &fill_bits);`
			`~PixelDesignatorMap();`

			`// Get a writable version of the PixelDesignator. Outside Framebuffer used`
			`// by the RGBMatrix to re-assign mappings to new PixelDesignatorMappers.`
			`PixelDesignator *get(int x, int y);`

			`inline int width() const { return width_; }`
			`inline int height() const { return height_; }`

			`// All bits that set red/green/blue pixels; used for Fill().`
			`const PixelDesignator &GetFillColorBits() { return fill_bits_; }`

			`private:`
			`const int width_;`
			`const int height_;`
			`const PixelDesignator fill_bits_; // Precalculated for fill.`
			`PixelDesignator *const buffer_;`
			`};`

			`// Internal representation of the frame-buffer that as well can`
			`// write itself to GPIO.`
			`// Our internal memory layout mimicks as much as possible what needs to be`
			`// written out.`
			`class Framebuffer {`
			`public:`
			`// Maximum usable bitplanes.`
			`//`
			`// 11 bits seems to be a sweet spot in which we still get somewhat useful`
			`// refresh rate and have good color richness. This is the default setting`
			`// However, in low-light situations, we want to be able to scale down`
			`// brightness more, having more bits at the bottom.`
			`// TODO(hzeller): make the default 15 bit or so, but slide the use of`
			`// timing to lower bits if fewer bits requested to not affect the overall`
			`// refresh in that case.`
			`// This needs to be balanced to not create too agressive timing however.`
			`// To be explored in a separete commit.`
			`//`
			`// For now, if someone needs very low level of light, change this to`
			`// say 13 and recompile. Run with --led-pwm-bits=13. Also, consider`
			`// --led-pwm-dither-bits=2 to have the refresh rate not suffer too much.`
			`static constexpr int kBitPlanes = 11;`
			`static constexpr int kDefaultBitPlanes = 11;`

			`Framebuffer(int rows, int columns, int parallel,`
			`int scan_mode,`
			`const char* led_sequence, bool inverse_color,`
			`PixelDesignatorMap **mapper);`
			`~Framebuffer();`

			`// Initialize GPIO bits for output. Only call once.`
			`static void InitHardwareMapping(const char *named_hardware);`
			`static void InitGPIO(GPIO *io, int rows, int parallel,`
			`bool allow_hardware_pulsing,`
			`int pwm_lsb_nanoseconds,`
			`int dither_bits,`
			`int row_address_type);`
			`static void InitializePanels(GPIO io, const char panel_type, int columns);`

			`// Set PWM bits used for output. Default is 11, but if you only deal with`
			`// simple comic-colors, 1 might be sufficient. Lower require less CPU.`
			`// Returns boolean to signify if value was within range.`
			`bool SetPWMBits(uint8_t value);`
			`uint8_t pwmbits() { return pwm_bits_; }`

			`// Map brightness of output linearly to input with CIE1931 profile.`
			`void set_luminance_correct(bool on) { do_luminance_correct_ = on; }`
			`bool luminance_correct() const { return do_luminance_correct_; }`

			`// Set brightness in percent; range=1..100`
			`// This will only affect newly set pixels.`
			`void SetBrightness(uint8_t b) {`
			`brightness_ = (b <= 100 ? (b != 0 ? b : 1) : 100);`
			`}`
			`uint8_t brightness() { return brightness_; }`

			`void DumpToMatrix(GPIO *io, int pwm_bits_to_show);`

			`void Serialize(const char *data, size_t len) const;`
			`bool Deserialize(const char *data, size_t len);`
			`void CopyFrom(const Framebuffer *other);`

			`// Canvas-inspired methods, but we're not implementing this interface to not`
			`// have an unnecessary vtable.`
			`int width() const;`
			`int height() const;`
			`void SetPixel(int x, int y, uint8_t red, uint8_t green, uint8_t blue);`
			`void Clear();`
			`void Fill(uint8_t red, uint8_t green, uint8_t blue);`

			`private:`
			`static const struct HardwareMapping *hardware_mapping_;`
			`static RowAddressSetter *row_setter_;`

			`// This returns the gpio-bit for given color (one of 'R', 'G', 'B'). This is`
			`// returning the right value in case "led_sequence" is _not_ "RGB"`
			`static gpio_bits_t GetGpioFromLedSequence(char col, const char *led_sequence,`
			`gpio_bits_t default_r,`
			`gpio_bits_t default_g,`
			`gpio_bits_t default_b);`

			`void InitDefaultDesignator(int x, int y, const char *led_sequence,`
			`PixelDesignator *designator);`
			`inline void MapColors(uint8_t r, uint8_t g, uint8_t b,`
			`uint16_t red, uint16_t green, uint16_t *blue);`
			`const int rows_; // Number of rows. 16 or 32.`
			`const int parallel_; // Parallel rows of chains. 1 or 2.`
			`const int height_; // rows * parallel`
			`const int columns_; // Number of columns. Number of chained boards * 32.`

			`const int scan_mode_;`
			`const bool inverse_color_;`

			`uint8_t pwm_bits_; // PWM bits to display.`
			`bool do_luminance_correct_;`
			`uint8_t brightness_;`

			`const int double_rows_;`
			`const size_t buffer_size_;`

			`// The frame-buffer is organized in bitplanes.`
			`// Highest level (slowest to cycle through) are double rows.`
			`// For each double-row, we store pwm-bits columns of a bitplane.`
			`// Each bitplane-column is pre-filled IoBits, of which the colors are set.`
			`// Of course, that means that we store unrelated bits in the frame-buffer,`
			`// but it allows easy access in the critical section.`
			`gpio_bits_t *bitplane_buffer_;`
			`inline gpio_bits_t *ValueAt(int double_row, int column, int bit);`

			`PixelDesignatorMap **shared_mapper_; // Storage in RGBMatrix.`
			`};`
			`} // namespace internal`
			`} // namespace rgb_matrix`
			`#endif // RPI_RGBMATRIX_FRAMEBUFFER_INTERNAL_H`