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// -*- 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>
// The framebuffer is the workhorse: it represents the frame in some internal
// format that is friendly to be dumped to the matrix quickly. Provides methods
// to manipulate the content.
#include "framebuffer-internal.h"
#include <assert.h>
#include <ctype.h>
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <algorithm>
#include "gpio.h"
#include "../include/graphics.h"
namespace rgb_matrix {
namespace internal {
// We need one global instance of a timing correct pulser. There are different
// implementations depending on the context.
static PinPulser *sOutputEnablePulser = NULL;
#ifdef ONLY_SINGLE_SUB_PANEL
# define SUB_PANELS_ 1
#else
# define SUB_PANELS_ 2
#endif
PixelDesignator *PixelDesignatorMap::get(int x, int y) {
if (x < 0 || y < 0 || x >= width_ || y >= height_)
return NULL;
return buffer_ + (y*width_) + x;
}
PixelDesignatorMap::PixelDesignatorMap(int width, int height,
const PixelDesignator &fill_bits)
: width_(width), height_(height), fill_bits_(fill_bits),
buffer_(new PixelDesignator[width * height]) {
}
PixelDesignatorMap::~PixelDesignatorMap() {
delete [] buffer_;
}
// Different panel types use different techniques to set the row address.
// We abstract that away with different implementations of RowAddressSetter
class RowAddressSetter {
public:
virtual ~RowAddressSetter() {}
virtual gpio_bits_t need_bits() const = 0;
virtual void SetRowAddress(GPIO *io, int row) = 0;
};
namespace {
// The default DirectRowAddressSetter just sets the address in parallel
// output lines ABCDE with A the LSB and E the MSB.
class DirectRowAddressSetter : public RowAddressSetter {
public:
DirectRowAddressSetter(int double_rows, const HardwareMapping &h)
: row_mask_(0), last_row_(-1) {
assert(double_rows <= 32); // need to resize row_lookup_
if (double_rows > 16) row_mask_ |= h.e;
if (double_rows > 8) row_mask_ |= h.d;
if (double_rows > 4) row_mask_ |= h.c;
if (double_rows > 2) row_mask_ |= h.b;
row_mask_ |= h.a;
for (int i = 0; i < double_rows; ++i) {
// To avoid the bit-fiddle in the critical path, utilize
// a lookup-table for all possible rows.
gpio_bits_t row_address = (i & 0x01) ? h.a : 0;
row_address |= (i & 0x02) ? h.b : 0;
row_address |= (i & 0x04) ? h.c : 0;
row_address |= (i & 0x08) ? h.d : 0;
row_address |= (i & 0x10) ? h.e : 0;
row_lookup_[i] = row_address;
}
}
virtual gpio_bits_t need_bits() const { return row_mask_; }
virtual void SetRowAddress(GPIO *io, int row) {
if (row == last_row_) return;
io->WriteMaskedBits(row_lookup_[row], row_mask_);
last_row_ = row;
}
private:
gpio_bits_t row_mask_;
gpio_bits_t row_lookup_[32];
int last_row_;
};
// The SM5266RowAddressSetter (ABC Shifter + DE direct) sets bits ABC using
// a 8 bit shifter and DE directly. The panel this works with has 8 SM5266
// shifters (4 for the top 32 rows and 4 for the bottom 32 rows).
// DE is used to select the active shifter
// (rows 1-8/33-40, 9-16/41-48, 17-24/49-56, 25-32/57-64).
// Rows are enabled by shifting in 8 bits (high bit first) with a high bit
// enabling that row. This allows up to 8 rows per group to be active at the
// same time (if they have the same content), but that isn't implemented here.
// BK, DIN and DCK are the designations on the SM5266P datasheet.
// BK = Enable Input, DIN = Serial In, DCK = Clock
class SM5266RowAddressSetter : public RowAddressSetter {
public:
SM5266RowAddressSetter(int double_rows, const HardwareMapping &h)
: row_mask_(h.a | h.b | h.c),
last_row_(-1),
bk_(h.c),
din_(h.b),
dck_(h.a) {
assert(double_rows <= 32); // designed for up to 1/32 panel
if (double_rows > 8) row_mask_ |= h.d;
if (double_rows > 16) row_mask_ |= h.e;
for (int i = 0; i < double_rows; ++i) {
gpio_bits_t row_address = 0;
row_address |= (i & 0x08) ? h.d : 0;
row_address |= (i & 0x10) ? h.e : 0;
row_lookup_[i] = row_address;
}
}
virtual gpio_bits_t need_bits() const { return row_mask_; }
virtual void SetRowAddress(GPIO *io, int row) {
if (row == last_row_) return;
io->SetBits(bk_); // Enable serial input for the shifter
for (int r = 7; r >= 0; r--) {
if (row % 8 == r) {
io->SetBits(din_);
} else {
io->ClearBits(din_);
}
io->SetBits(dck_);
io->SetBits(dck_); // Longer clock time; tested with Pi3
io->ClearBits(dck_);
}
io->ClearBits(bk_); // Disable serial input to keep unwanted bits out of the shifters
last_row_ = row;
// Set bits D and E to enable the proper shifter to display the selected
// row.
io->WriteMaskedBits(row_lookup_[row], row_mask_);
}
private:
gpio_bits_t row_mask_;
int last_row_;
const gpio_bits_t bk_;
const gpio_bits_t din_;
const gpio_bits_t dck_;
gpio_bits_t row_lookup_[32];
};
class ShiftRegisterRowAddressSetter : public RowAddressSetter {
public:
ShiftRegisterRowAddressSetter(int double_rows, const HardwareMapping &h)
: double_rows_(double_rows),
row_mask_(h.a | h.b), clock_(h.a), data_(h.b),
last_row_(-1) {
}
virtual gpio_bits_t need_bits() const { return row_mask_; }
virtual void SetRowAddress(GPIO *io, int row) {
if (row == last_row_) return;
for (int activate = 0; activate < double_rows_; ++activate) {
io->ClearBits(clock_);
if (activate == double_rows_ - 1 - row) {
io->ClearBits(data_);
} else {
io->SetBits(data_);
}
io->SetBits(clock_);
}
io->ClearBits(clock_);
io->SetBits(clock_);
last_row_ = row;
}
private:
const int double_rows_;
const gpio_bits_t row_mask_;
const gpio_bits_t clock_;
const gpio_bits_t data_;
int last_row_;
};
// Issue #823
// An shift register row address setter that does not use B but C for the
// data. Clock is inverted.
class ABCShiftRegisterRowAddressSetter : public RowAddressSetter {
public:
ABCShiftRegisterRowAddressSetter(int double_rows, const HardwareMapping &h)
: double_rows_(double_rows),
row_mask_(h.a | h.c),
clock_(h.a),
data_(h.c),
last_row_(-1) {
}
virtual gpio_bits_t need_bits() const { return row_mask_; }
virtual void SetRowAddress(GPIO *io, int row) {
for (int activate = 0; activate < double_rows_; ++activate) {
io->ClearBits(clock_);
if (activate == double_rows_ - 1 - row) {
io->SetBits(data_);
} else {
io->ClearBits(data_);
}
io->SetBits(clock_);
}
io->SetBits(clock_);
io->ClearBits(clock_);
last_row_ = row;
}
private:
const int double_rows_;
const gpio_bits_t row_mask_;
const gpio_bits_t clock_;
const gpio_bits_t data_;
int last_row_;
};
// The DirectABCDRowAddressSetter sets the address by one of
// row pin ABCD for 32х16 matrix 1:4 multiplexing. The matrix has
// 4 addressable rows. Row is selected by a low level on the
// corresponding row address pin. Other row address pins must be in high level.
//
// Row addr| 0 | 1 | 2 | 3
// --------+---+---+---+---
// Line A | 0 | 1 | 1 | 1
// Line B | 1 | 0 | 1 | 1
// Line C | 1 | 1 | 0 | 1
// Line D | 1 | 1 | 1 | 0
class DirectABCDLineRowAddressSetter : public RowAddressSetter {
public:
DirectABCDLineRowAddressSetter(int double_rows, const HardwareMapping &h)
: last_row_(-1) {
row_mask_ = h.a | h.b | h.c | h.d;
row_lines_[0] = /*h.a |*/ h.b | h.c | h.d;
row_lines_[1] = h.a /*| h.b*/ | h.c | h.d;
row_lines_[2] = h.a | h.b /*| h.c */| h.d;
row_lines_[3] = h.a | h.b | h.c /*| h.d*/;
}
virtual gpio_bits_t need_bits() const { return row_mask_; }
virtual void SetRowAddress(GPIO *io, int row) {
if (row == last_row_) return;
gpio_bits_t row_address = row_lines_[row % 4];
io->WriteMaskedBits(row_address, row_mask_);
last_row_ = row;
}
private:
gpio_bits_t row_lines_[4];
gpio_bits_t row_mask_;
int last_row_;
};
}
const struct HardwareMapping *Framebuffer::hardware_mapping_ = NULL;
RowAddressSetter *Framebuffer::row_setter_ = NULL;
Framebuffer::Framebuffer(int rows, int columns, int parallel,
int scan_mode,
const char *led_sequence, bool inverse_color,
PixelDesignatorMap **mapper)
: rows_(rows),
parallel_(parallel),
height_(rows * parallel),
columns_(columns),
scan_mode_(scan_mode),
inverse_color_(inverse_color),
pwm_bits_(kBitPlanes), do_luminance_correct_(true), brightness_(100),
double_rows_(rows / SUB_PANELS_),
buffer_size_(double_rows_ * columns_ * kBitPlanes * sizeof(gpio_bits_t)),
shared_mapper_(mapper) {
assert(hardware_mapping_ != NULL); // Called InitHardwareMapping() ?
assert(shared_mapper_ != NULL); // Storage should be provided by RGBMatrix.
assert(rows_ >=4 && rows_ <= 64 && rows_ % 2 == 0);
if (parallel > hardware_mapping_->max_parallel_chains) {
fprintf(stderr, "The %s GPIO mapping only supports %d parallel chain%s, "
"but %d was requested.\n", hardware_mapping_->name,
hardware_mapping_->max_parallel_chains,
hardware_mapping_->max_parallel_chains > 1 ? "s" : "", parallel);
abort();
}
assert(parallel >= 1 && parallel <= 6);
bitplane_buffer_ = new gpio_bits_t[double_rows_ * columns_ * kBitPlanes];
// If we're the first Framebuffer created, the shared PixelMapper is
// still NULL, so create one.
// The first PixelMapper represents the physical layout of a standard matrix
// with the specific knowledge of the framebuffer, setting up PixelDesignators
// in a way that they are useful for this Framebuffer.
//
// Newly created PixelMappers then can just re-arrange PixelDesignators
// from the parent PixelMapper opaquely without having to know the details.
if (*shared_mapper_ == NULL) {
// Gather all the bits for given color for fast Fill()s and use the right
// bits according to the led sequence
const struct HardwareMapping &h = *hardware_mapping_;
gpio_bits_t r = h.p0_r1 | h.p0_r2 | h.p1_r1 | h.p1_r2 | h.p2_r1 | h.p2_r2 | h.p3_r1 | h.p3_r2 | h.p4_r1 | h.p4_r2 | h.p5_r1 | h.p5_r2;
gpio_bits_t g = h.p0_g1 | h.p0_g2 | h.p1_g1 | h.p1_g2 | h.p2_g1 | h.p2_g2 | h.p3_g1 | h.p3_g2 | h.p4_g1 | h.p4_g2 | h.p5_g1 | h.p5_g2;
gpio_bits_t b = h.p0_b1 | h.p0_b2 | h.p1_b1 | h.p1_b2 | h.p2_b1 | h.p2_b2 | h.p3_b1 | h.p3_b2 | h.p4_b1 | h.p4_b2 | h.p5_b1 | h.p5_b2;
PixelDesignator fill_bits;
fill_bits.r_bit = GetGpioFromLedSequence('R', led_sequence, r, g, b);
fill_bits.g_bit = GetGpioFromLedSequence('G', led_sequence, r, g, b);
fill_bits.b_bit = GetGpioFromLedSequence('B', led_sequence, r, g, b);
*shared_mapper_ = new PixelDesignatorMap(columns_, height_, fill_bits);
for (int y = 0; y < height_; ++y) {
for (int x = 0; x < columns_; ++x) {
InitDefaultDesignator(x, y, led_sequence, (*shared_mapper_)->get(x, y));
}
}
}
Clear();
}
Framebuffer::~Framebuffer() {
delete [] bitplane_buffer_;
}
// TODO: this should also be parsed from some special formatted string, e.g.
// {addr={22,23,24,25,15},oe=18,clk=17,strobe=4, p0={11,27,7,8,9,10},...}
/* static */ void Framebuffer::InitHardwareMapping(const char *named_hardware) {
if (named_hardware == NULL || *named_hardware == '\0') {
named_hardware = "regular";
}
struct HardwareMapping *mapping = NULL;
for (HardwareMapping *it = matrix_hardware_mappings; it->name; ++it) {
if (strcasecmp(it->name, named_hardware) == 0) {
mapping = it;
break;
}
}
if (!mapping) {
fprintf(stderr, "There is no hardware mapping named '%s'.\nAvailable: ",
named_hardware);
for (HardwareMapping *it = matrix_hardware_mappings; it->name; ++it) {
if (it != matrix_hardware_mappings) fprintf(stderr, ", ");
fprintf(stderr, "'%s'", it->name);
}
fprintf(stderr, "\n");
abort();
}
if (mapping->max_parallel_chains == 0) {
// Auto determine.
struct HardwareMapping *h = mapping;
if ((h->p0_r1 | h->p0_g1 | h->p0_g1 | h->p0_r2 | h->p0_g2 | h->p0_g2) > 0)
++mapping->max_parallel_chains;
if ((h->p1_r1 | h->p1_g1 | h->p1_g1 | h->p1_r2 | h->p1_g2 | h->p1_g2) > 0)
++mapping->max_parallel_chains;
if ((h->p2_r1 | h->p2_g1 | h->p2_g1 | h->p2_r2 | h->p2_g2 | h->p2_g2) > 0)
++mapping->max_parallel_chains;
if ((h->p3_r1 | h->p3_g1 | h->p3_g1 | h->p3_r2 | h->p3_g2 | h->p3_g2) > 0)
++mapping->max_parallel_chains;
if ((h->p4_r1 | h->p4_g1 | h->p4_g1 | h->p4_r2 | h->p4_g2 | h->p4_g2) > 0)
++mapping->max_parallel_chains;
if ((h->p5_r1 | h->p5_g1 | h->p5_g1 | h->p5_r2 | h->p5_g2 | h->p5_g2) > 0)
++mapping->max_parallel_chains;
}
hardware_mapping_ = mapping;
}
/* static */ void Framebuffer::InitGPIO(GPIO *io, int rows, int parallel,
bool allow_hardware_pulsing,
int pwm_lsb_nanoseconds,
int dither_bits,
int row_address_type) {
if (sOutputEnablePulser != NULL)
return; // already initialized.
const struct HardwareMapping &h = *hardware_mapping_;
// Tell GPIO about all bits we intend to use.
gpio_bits_t all_used_bits = 0;
all_used_bits |= h.output_enable | h.clock | h.strobe;
all_used_bits |= h.p0_r1 | h.p0_g1 | h.p0_b1 | h.p0_r2 | h.p0_g2 | h.p0_b2;
if (parallel >= 2) {
all_used_bits |= h.p1_r1 | h.p1_g1 | h.p1_b1 | h.p1_r2 | h.p1_g2 | h.p1_b2;
}
if (parallel >= 3) {
all_used_bits |= h.p2_r1 | h.p2_g1 | h.p2_b1 | h.p2_r2 | h.p2_g2 | h.p2_b2;
}
if (parallel >= 4) {
all_used_bits |= h.p3_r1 | h.p3_g1 | h.p3_b1 | h.p3_r2 | h.p3_g2 | h.p3_b2;
}
if (parallel >= 5) {
all_used_bits |= h.p4_r1 | h.p4_g1 | h.p4_b1 | h.p4_r2 | h.p4_g2 | h.p4_b2;
}
if (parallel >= 6) {
all_used_bits |= h.p5_r1 | h.p5_g1 | h.p5_b1 | h.p5_r2 | h.p5_g2 | h.p5_b2;
}
const int double_rows = rows / SUB_PANELS_;
switch (row_address_type) {
case 0:
row_setter_ = new DirectRowAddressSetter(double_rows, h);
break;
case 1:
row_setter_ = new ShiftRegisterRowAddressSetter(double_rows, h);
break;
case 2:
row_setter_ = new DirectABCDLineRowAddressSetter(double_rows, h);
break;
case 3:
row_setter_ = new ABCShiftRegisterRowAddressSetter(double_rows, h);
break;
case 4:
row_setter_ = new SM5266RowAddressSetter(double_rows, h);
break;
default:
assert(0); // unexpected type.
}
all_used_bits |= row_setter_->need_bits();
// Adafruit HAT identified by the same prefix.
const bool is_some_adafruit_hat = (0 == strncmp(h.name, "adafruit-hat",
strlen("adafruit-hat")));
// Initialize outputs, make sure that all of these are supported bits.
const gpio_bits_t result = io->InitOutputs(all_used_bits,
is_some_adafruit_hat);
assert(result == all_used_bits); // Impl: all bits declared in gpio.cc ?
std::vector<int> bitplane_timings;
uint32_t timing_ns = pwm_lsb_nanoseconds;
for (int b = 0; b < kBitPlanes; ++b) {
bitplane_timings.push_back(timing_ns);
if (b >= dither_bits) timing_ns *= 2;
}
sOutputEnablePulser = PinPulser::Create(io, h.output_enable,
allow_hardware_pulsing,
bitplane_timings);
}
// NOTE: first version for panel initialization sequence, need to refine
// until it is more clear how different panel types are initialized to be
// able to abstract this more.
static void InitFM6126(GPIO *io, const struct HardwareMapping &h, int columns) {
const gpio_bits_t bits_on
= h.p0_r1 | h.p0_g1 | h.p0_b1 | h.p0_r2 | h.p0_g2 | h.p0_b2
| h.p1_r1 | h.p1_g1 | h.p1_b1 | h.p1_r2 | h.p1_g2 | h.p1_b2
| h.p2_r1 | h.p2_g1 | h.p2_b1 | h.p2_r2 | h.p2_g2 | h.p2_b2
| h.p3_r1 | h.p3_g1 | h.p3_b1 | h.p3_r2 | h.p3_g2 | h.p3_b2
| h.p4_r1 | h.p4_g1 | h.p4_b1 | h.p4_r2 | h.p4_g2 | h.p4_b2
| h.p5_r1 | h.p5_g1 | h.p5_b1 | h.p5_r2 | h.p5_g2 | h.p5_b2
| h.a; // Address bit 'A' is always on.
const gpio_bits_t bits_off = h.a;
const gpio_bits_t mask = bits_on | h.strobe;
// Init bits. TODO: customize, as we can do things such as brightness here,
// which would allow more higher quality output.
static const char* init_b12 = "0111111111111111"; // full bright
static const char* init_b13 = "0000000001000000"; // panel on.
io->ClearBits(h.clock | h.strobe);
for (int i = 0; i < columns; ++i) {
gpio_bits_t value = init_b12[i % 16] == '0' ? bits_off : bits_on;
if (i > columns - 12) value |= h.strobe;
io->WriteMaskedBits(value, mask);
io->SetBits(h.clock);
io->ClearBits(h.clock);
}
io->ClearBits(h.strobe);
for (int i = 0; i < columns; ++i) {
gpio_bits_t value = init_b13[i % 16] == '0' ? bits_off : bits_on;
if (i > columns - 13) value |= h.strobe;
io->WriteMaskedBits(value, mask);
io->SetBits(h.clock);
io->ClearBits(h.clock);
}
io->ClearBits(h.strobe);
}
// The FM6217 is very similar to the FM6216.
// FM6217 adds Register 3 to allow for automatic bad pixel supression.
static void InitFM6127(GPIO *io, const struct HardwareMapping &h, int columns) {
const gpio_bits_t bits_r_on= h.p0_r1 | h.p0_r2;
const gpio_bits_t bits_g_on= h.p0_g1 | h.p0_g2;
const gpio_bits_t bits_b_on= h.p0_b1 | h.p0_b2;
const gpio_bits_t bits_on= bits_r_on | bits_g_on | bits_b_on;
const gpio_bits_t bits_off = 0;
const gpio_bits_t mask = bits_on | h.strobe;
static const char* init_b12 = "1111111111001110"; // register 1
static const char* init_b13 = "1110000001100010"; // register 2.
static const char* init_b11 = "0101111100000000"; // register 3.
io->ClearBits(h.clock | h.strobe);
for (int i = 0; i < columns; ++i) {
gpio_bits_t value = init_b12[i % 16] == '0' ? bits_off : bits_on;
if (i > columns - 12) value |= h.strobe;
io->WriteMaskedBits(value, mask);
io->SetBits(h.clock);
io->ClearBits(h.clock);
}
io->ClearBits(h.strobe);
for (int i = 0; i < columns; ++i) {
gpio_bits_t value = init_b13[i % 16] == '0' ? bits_off : bits_on;
if (i > columns - 13) value |= h.strobe;
io->WriteMaskedBits(value, mask);
io->SetBits(h.clock);
io->ClearBits(h.clock);
}
io->ClearBits(h.strobe);
for (int i = 0; i < columns; ++i) {
gpio_bits_t value = init_b11[i % 16] == '0' ? bits_off : bits_on;
if (i > columns - 11) value |= h.strobe;
io->WriteMaskedBits(value, mask);
io->SetBits(h.clock);
io->ClearBits(h.clock);
}
io->ClearBits(h.strobe);
}
/*static*/ void Framebuffer::InitializePanels(GPIO *io,
const char *panel_type,
int columns) {
if (!panel_type || panel_type[0] == '\0') return;
if (strncasecmp(panel_type, "fm6126", 6) == 0) {
InitFM6126(io, *hardware_mapping_, columns);
}
else if (strncasecmp(panel_type, "fm6127", 6) == 0) {
InitFM6127(io, *hardware_mapping_, columns);
}
// else if (strncasecmp(...)) // more init types
else {
fprintf(stderr, "Unknown panel type '%s'; typo ?\n", panel_type);
}
}
bool Framebuffer::SetPWMBits(uint8_t value) {
if (value < 1 || value > kBitPlanes)
return false;
pwm_bits_ = value;
return true;
}
inline gpio_bits_t *Framebuffer::ValueAt(int double_row, int column, int bit) {
return &bitplane_buffer_[ double_row * (columns_ * kBitPlanes)
+ bit * columns_
+ column ];
}
void Framebuffer::Clear() {
if (inverse_color_) {
Fill(0, 0, 0);
} else {
// Cheaper.
memset(bitplane_buffer_, 0,
sizeof(*bitplane_buffer_) * double_rows_ * columns_ * kBitPlanes);
}
}
// Do CIE1931 luminance correction and scale to output bitplanes
static uint16_t luminance_cie1931(uint8_t c, uint8_t brightness) {
float out_factor = ((1 << internal::Framebuffer::kBitPlanes) - 1);
float v = (float) c * brightness / 255.0;
return roundf(out_factor * ((v <= 8) ? v / 902.3 : pow((v + 16) / 116.0, 3)));
}
struct ColorLookup {
uint16_t color[256];
};
static ColorLookup *CreateLuminanceCIE1931LookupTable() {
ColorLookup *for_brightness = new ColorLookup[100];
for (int c = 0; c < 256; ++c)
for (int b = 0; b < 100; ++b)
for_brightness[b].color[c] = luminance_cie1931(c, b + 1);
return for_brightness;
}
static inline uint16_t CIEMapColor(uint8_t brightness, uint8_t c) {
static ColorLookup *luminance_lookup = CreateLuminanceCIE1931LookupTable();
return luminance_lookup[brightness - 1].color[c];
}
// Non luminance correction. TODO: consider getting rid of this.
static inline uint16_t DirectMapColor(uint8_t brightness, uint8_t c) {
// simple scale down the color value
c = c * brightness / 100;
// shift to be left aligned with top-most bits.
constexpr int shift = internal::Framebuffer::kBitPlanes - 8;
return (shift > 0) ? (c << shift) : (c >> -shift);
}
inline void Framebuffer::MapColors(
uint8_t r, uint8_t g, uint8_t b,
uint16_t *red, uint16_t *green, uint16_t *blue) {
if (do_luminance_correct_) {
*red = CIEMapColor(brightness_, r);
*green = CIEMapColor(brightness_, g);
*blue = CIEMapColor(brightness_, b);
} else {
*red = DirectMapColor(brightness_, r);
*green = DirectMapColor(brightness_, g);
*blue = DirectMapColor(brightness_, b);
}
if (inverse_color_) {
*red = ~(*red);
*green = ~(*green);
*blue = ~(*blue);
}
}
void Framebuffer::Fill(uint8_t r, uint8_t g, uint8_t b) {
uint16_t red, green, blue;
MapColors(r, g, b, &red, &green, &blue);
const PixelDesignator &fill = (*shared_mapper_)->GetFillColorBits();
for (int b = kBitPlanes - pwm_bits_; b < kBitPlanes; ++b) {
uint16_t mask = 1 << b;
gpio_bits_t plane_bits = 0;
plane_bits |= ((red & mask) == mask) ? fill.r_bit : 0;
plane_bits |= ((green & mask) == mask) ? fill.g_bit : 0;
plane_bits |= ((blue & mask) == mask) ? fill.b_bit : 0;
for (int row = 0; row < double_rows_; ++row) {
gpio_bits_t *row_data = ValueAt(row, 0, b);
for (int col = 0; col < columns_; ++col) {
*row_data++ = plane_bits;
}
}
}
}
int Framebuffer::width() const { return (*shared_mapper_)->width(); }
int Framebuffer::height() const { return (*shared_mapper_)->height(); }
void Framebuffer::SetPixel(int x, int y, uint8_t r, uint8_t g, uint8_t b) {
const PixelDesignator *designator = (*shared_mapper_)->get(x, y);
if (designator == NULL) return;
const long pos = designator->gpio_word;
if (pos < 0) return; // non-used pixel marker.
uint16_t red, green, blue;
MapColors(r, g, b, &red, &green, &blue);
gpio_bits_t *bits = bitplane_buffer_ + pos;
const int min_bit_plane = kBitPlanes - pwm_bits_;
bits += (columns_ * min_bit_plane);
const gpio_bits_t r_bits = designator->r_bit;
const gpio_bits_t g_bits = designator->g_bit;
const gpio_bits_t b_bits = designator->b_bit;
const gpio_bits_t designator_mask = designator->mask;
for (uint16_t mask = 1<<min_bit_plane; mask != 1<<kBitPlanes; mask <<=1 ) {
gpio_bits_t color_bits = 0;
if (red & mask) color_bits |= r_bits;
if (green & mask) color_bits |= g_bits;
if (blue & mask) color_bits |= b_bits;
*bits = (*bits & designator_mask) | color_bits;
bits += columns_;
}
}
void Framebuffer::SetPixels(int x, int y, int width, int height, Color *colors) {
for (int iy = 0; iy < height; ++iy) {
for (int ix = 0; ix < width; ++ix) {
SetPixel(x + ix, y + iy, colors->r, colors->g, colors->b);
++colors;
}
}
}
// Strange LED-mappings such as RBG or so are handled here.
gpio_bits_t Framebuffer::GetGpioFromLedSequence(char col,
const char *led_sequence,
gpio_bits_t default_r,
gpio_bits_t default_g,
gpio_bits_t default_b) {
const char *pos = strchr(led_sequence, col);
if (pos == NULL) pos = strchr(led_sequence, tolower(col));
if (pos == NULL) {
fprintf(stderr, "LED sequence '%s' does not contain any '%c'.\n",
led_sequence, col);
abort();
}
switch (pos - led_sequence) {
case 0: return default_r;
case 1: return default_g;
case 2: return default_b;
}
return default_r; // String too long, should've been caught earlier.
}
void Framebuffer::InitDefaultDesignator(int x, int y, const char *seq,
PixelDesignator *d) {
const struct HardwareMapping &h = *hardware_mapping_;
gpio_bits_t *bits = ValueAt(y % double_rows_, x, 0);
d->gpio_word = bits - bitplane_buffer_;
d->r_bit = d->g_bit = d->b_bit = 0;
if (y < rows_) {
if (y < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p0_r1, h.p0_g1, h.p0_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p0_r1, h.p0_g1, h.p0_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p0_r1, h.p0_g1, h.p0_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p0_r2, h.p0_g2, h.p0_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p0_r2, h.p0_g2, h.p0_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p0_r2, h.p0_g2, h.p0_b2);
}
}
else if (y >= rows_ && y < 2 * rows_) {
if (y - rows_ < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p1_r1, h.p1_g1, h.p1_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p1_r1, h.p1_g1, h.p1_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p1_r1, h.p1_g1, h.p1_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p1_r2, h.p1_g2, h.p1_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p1_r2, h.p1_g2, h.p1_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p1_r2, h.p1_g2, h.p1_b2);
}
}
else if (y >= 2*rows_ && y < 3 * rows_) {
if (y - 2*rows_ < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p2_r1, h.p2_g1, h.p2_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p2_r1, h.p2_g1, h.p2_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p2_r1, h.p2_g1, h.p2_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p2_r2, h.p2_g2, h.p2_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p2_r2, h.p2_g2, h.p2_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p2_r2, h.p2_g2, h.p2_b2);
}
}
else if (y >= 3*rows_ && y < 4 * rows_) {
if (y - 3*rows_ < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p3_r1, h.p3_g1, h.p3_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p3_r1, h.p3_g1, h.p3_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p3_r1, h.p3_g1, h.p3_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p3_r2, h.p3_g2, h.p3_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p3_r2, h.p3_g2, h.p3_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p3_r2, h.p3_g2, h.p3_b2);
}
}
else if (y >= 4*rows_ && y < 5 * rows_){
if (y - 4*rows_ < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p4_r1, h.p4_g1, h.p4_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p4_r1, h.p4_g1, h.p4_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p4_r1, h.p4_g1, h.p4_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p4_r2, h.p4_g2, h.p4_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p4_r2, h.p4_g2, h.p4_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p4_r2, h.p4_g2, h.p4_b2);
}
}
else {
if (y - 5*rows_ < double_rows_) {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p5_r1, h.p5_g1, h.p5_b1);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p5_r1, h.p5_g1, h.p5_b1);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p5_r1, h.p5_g1, h.p5_b1);
} else {
d->r_bit = GetGpioFromLedSequence('R', seq, h.p5_r2, h.p5_g2, h.p5_b2);
d->g_bit = GetGpioFromLedSequence('G', seq, h.p5_r2, h.p5_g2, h.p5_b2);
d->b_bit = GetGpioFromLedSequence('B', seq, h.p5_r2, h.p5_g2, h.p5_b2);
}
}
d->mask = ~(d->r_bit | d->g_bit | d->b_bit);
}
void Framebuffer::Serialize(const char **data, size_t *len) const {
*data = reinterpret_cast<const char*>(bitplane_buffer_);
*len = buffer_size_;
}
bool Framebuffer::Deserialize(const char *data, size_t len) {
if (len != buffer_size_) return false;
memcpy(bitplane_buffer_, data, len);
return true;
}
void Framebuffer::CopyFrom(const Framebuffer *other) {
if (other == this) return;
memcpy(bitplane_buffer_, other->bitplane_buffer_, buffer_size_);
}
void Framebuffer::DumpToMatrix(GPIO *io, int pwm_low_bit) {
const struct HardwareMapping &h = *hardware_mapping_;
gpio_bits_t color_clk_mask = 0; // Mask of bits while clocking in.
color_clk_mask |= h.p0_r1 | h.p0_g1 | h.p0_b1 | h.p0_r2 | h.p0_g2 | h.p0_b2;
if (parallel_ >= 2) {
color_clk_mask |= h.p1_r1 | h.p1_g1 | h.p1_b1 | h.p1_r2 | h.p1_g2 | h.p1_b2;
}
if (parallel_ >= 3) {
color_clk_mask |= h.p2_r1 | h.p2_g1 | h.p2_b1 | h.p2_r2 | h.p2_g2 | h.p2_b2;
}
if (parallel_ >= 4) {
color_clk_mask |= h.p3_r1 | h.p3_g1 | h.p3_b1 | h.p3_r2 | h.p3_g2 | h.p3_b2;
}
if (parallel_ >= 5) {
color_clk_mask |= h.p4_r1 | h.p4_g1 | h.p4_b1 | h.p4_r2 | h.p4_g2 | h.p4_b2;
}
if (parallel_ >= 6) {
color_clk_mask |= h.p5_r1 | h.p5_g1 | h.p5_b1 | h.p5_r2 | h.p5_g2 | h.p5_b2;
}
color_clk_mask |= h.clock;
// Depending if we do dithering, we might not always show the lowest bits.
const int start_bit = std::max(pwm_low_bit, kBitPlanes - pwm_bits_);
const uint8_t half_double = double_rows_/2;
for (uint8_t row_loop = 0; row_loop < double_rows_; ++row_loop) {
uint8_t d_row;
switch (scan_mode_) {
case 0: // progressive
default:
d_row = row_loop;
break;
case 1: // interlaced
d_row = ((row_loop < half_double)
? (row_loop << 1)
: ((row_loop - half_double) << 1) + 1);
}
// Rows can't be switched very quickly without ghosting, so we do the
// full PWM of one row before switching rows.
for (int b = start_bit; b < kBitPlanes; ++b) {
gpio_bits_t *row_data = ValueAt(d_row, 0, b);
// While the output enable is still on, we can already clock in the next
// data.
for (int col = 0; col < columns_; ++col) {
const gpio_bits_t &out = *row_data++;
io->WriteMaskedBits(out, color_clk_mask); // col + reset clock
io->SetBits(h.clock); // Rising edge: clock color in.
}
io->ClearBits(color_clk_mask); // clock back to normal.
// OE of the previous row-data must be finished before strobe.
sOutputEnablePulser->WaitPulseFinished();
// Setting address and strobing needs to happen in dark time.
row_setter_->SetRowAddress(io, d_row);
io->SetBits(h.strobe); // Strobe in the previously clocked in row.
io->ClearBits(h.strobe);
// Now switch on for the sleep time necessary for that bit-plane.
sOutputEnablePulser->SendPulse(b);
}
}
}
} // namespace internal
} // namespace rgb_matrix