ESP32-HUB75-MatrixPanel-DMA/ESP32-RGB64x32MatrixPanel-I2S-DMA.cpp
2020-08-02 22:13:04 +01:00

717 lines
No EOL
34 KiB
C++

#include "ESP32-RGB64x32MatrixPanel-I2S-DMA.h"
// Credits: Louis Beaudoin <https://github.com/pixelmatix/SmartMatrix/tree/teensylc>
// and Sprite_TM: https://www.esp32.com/viewtopic.php?f=17&t=3188 and https://www.esp32.com/viewtopic.php?f=13&t=3256
/*
This is example code to driver a p3(2121)64*32 -style RGB LED display. These types of displays do not have memory and need to be refreshed
continuously. The display has 2 RGB inputs, 4 inputs to select the active line, a pixel clock input, a latch enable input and an output-enable
input. The display can be seen as 2 64x16 displays consisting of the upper half and the lower half of the display. Each half has a separate
RGB pixel input, the rest of the inputs are shared.
Each display half can only show one line of RGB pixels at a time: to do this, the RGB data for the line is input by setting the RGB input pins
to the desired value for the first pixel, giving the display a clock pulse, setting the RGB input pins to the desired value for the second pixel,
giving a clock pulse, etc. Do this 64 times to clock in an entire row. The pixels will not be displayed yet: until the latch input is made high,
the display will still send out the previously clocked in line. Pulsing the latch input high will replace the displayed data with the data just
clocked in.
The 4 line select inputs select where the currently active line is displayed: when provided with a binary number (0-15), the latched pixel data
will immediately appear on this line. Note: While clocking in data for a line, the *previous* line is still displayed, and these lines should
be set to the value to reflect the position the *previous* line is supposed to be on.
Finally, the screen has an OE input, which is used to disable the LEDs when latching new data and changing the state of the line select inputs:
doing so hides any artefacts that appear at this time. The OE line is also used to dim the display by only turning it on for a limited time every
line.
All in all, an image can be displayed by 'scanning' the display, say, 100 times per second. The slowness of the human eye hides the fact that
only one line is showed at a time, and the display looks like every pixel is driven at the same time.
Now, the RGB inputs for these types of displays are digital, meaning each red, green and blue subpixel can only be on or off. This leads to a
color palette of 8 pixels, not enough to display nice pictures. To get around this, we use binary code modulation.
Binary code modulation is somewhat like PWM, but easier to implement in our case. First, we define the time we would refresh the display without
binary code modulation as the 'frame time'. For, say, a four-bit binary code modulation, the frame time is divided into 15 ticks of equal length.
We also define 4 subframes (0 to 3), defining which LEDs are on and which LEDs are off during that subframe. (Subframes are the same as a
normal frame in non-binary-coded-modulation mode, but are showed faster.) From our (non-monochrome) input image, we take the (8-bit: bit 7
to bit 0) RGB pixel values. If the pixel values have bit 7 set, we turn the corresponding LED on in subframe 3. If they have bit 6 set,
we turn on the corresponding LED in subframe 2, if bit 5 is set subframe 1, if bit 4 is set in subframe 0.
Now, in order to (on average within a frame) turn a LED on for the time specified in the pixel value in the input data, we need to weigh the
subframes. We have 15 pixels: if we show subframe 3 for 8 of them, subframe 2 for 4 of them, subframe 1 for 2 of them and subframe 1 for 1 of
them, this 'automatically' happens. (We also distribute the subframes evenly over the ticks, which reduces flicker.)
In this code, we use the I2S peripheral in parallel mode to achieve this. Essentially, first we allocate memory for all subframes. This memory
contains a sequence of all the signals (2xRGB, line select, latch enable, output enable) that need to be sent to the display for that subframe.
Then we ask the I2S-parallel driver to set up a DMA chain so the subframes are sent out in a sequence that satisfies the requirement that
subframe x has to be sent out for (2^x) ticks. Finally, we fill the subframes with image data.
We use a front buffer/back buffer technique here to make sure the display is refreshed in one go and drawing artifacts do not reach the display.
In practice, for small displays this is not really necessarily.
*/
bool RGB64x32MatrixPanel_I2S_DMA::allocateDMAmemory()
{
/***
* Step 1: Look at the overall DMA capable memory for the DMA FRAMEBUFFER data only (not the DMA linked list descriptors yet)
* and do some pre-checks.
*/
int _num_frame_buffers = (double_buffering_enabled) ? 2:1;
size_t _frame_buffer_memory_required = sizeof(frameStruct) * _num_frame_buffers;
size_t _dma_linked_list_memory_required = 0;
size_t _total_dma_capable_memory_reserved = 0;
// 1. Calculate and malloc the LARGEST available DMA memory block to matrix_framebuffer_malloc_1
#if SERIAL_DEBUG
Serial.printf("Panel Height: %d pixels.\r\n", MATRIX_HEIGHT);
Serial.printf("Panel Width: %d pixels.\r\n", MATRIX_WIDTH);
if (double_buffering_enabled) {
Serial.println("DOUBLE FRAME BUFFERS / DOUBLE BUFFERING IS ENABLED. DOUBLE THE RAM REQUIRED!");
}
Serial.println("DMA memory blocks available before any malloc's: ");
heap_caps_print_heap_info(MALLOC_CAP_DMA);
Serial.printf("We're going to need %d bytes of SRAM just for the frame buffer(s).\r\n", _frame_buffer_memory_required);
Serial.printf("Largest DMA capable SRAM memory block is %d bytes.\r\n", heap_caps_get_largest_free_block(MALLOC_CAP_DMA));
#endif
// Can we fit the framebuffer into the single DMA capable memory block available?
if ( heap_caps_get_largest_free_block(MALLOC_CAP_DMA) < _frame_buffer_memory_required ) {
#if SERIAL_DEBUG
Serial.printf("######### Insufficient memory for requested resolution. Reduce MATRIX_COLOR_DEPTH and try again.\r\n\tAdditional %d bytes of memory required.\r\n\r\n", (_frame_buffer_memory_required-heap_caps_get_largest_free_block(MALLOC_CAP_DMA)) );
#endif
return false;
}
// Allocate the framebuffer 1 memory, fail if we can even do this
matrix_framebuffer_malloc_1 = (frameStruct *)heap_caps_malloc(_frame_buffer_memory_required, MALLOC_CAP_DMA);
if ( matrix_framebuffer_malloc_1 == NULL ) {
Serial.println("ERROR: Couldn't malloc matrix_framebuffer_malloc_1! Critical fail.\r\n");
return false;
}
_total_dma_capable_memory_reserved += _frame_buffer_memory_required;
// SPLIT MEMORY MODE
#ifdef SPLIT_MEMORY_MODE
#if SERIAL_DEBUG
Serial.println("SPLIT MEMORY MODE ENABLED!");
Serial.print("Rows per frame (overall): "); Serial.println(ROWS_PER_FRAME, DEC);
Serial.print("Rows per split framebuffer malloc: "); Serial.println(SPLIT_MEMORY_ROWS_PER_FRAME, DEC);
#endif
// Can we fit the framebuffer into the single DMA capable memory block available?
// Can we fit the framebuffer into the single DMA capable memory block available?
if ( heap_caps_get_largest_free_block(MALLOC_CAP_DMA) < _frame_buffer_memory_required ) {
#if SERIAL_DEBUG
Serial.printf("######### Insufficient memory for second framebuffer for requested resolution. Reduce MATRIX_COLOR_DEPTH and try again.\r\n\tAdditional %d bytes of memory required.\r\n\r\n", (_frame_buffer_memory_required-heap_caps_get_largest_free_block(MALLOC_CAP_DMA)) );
#endif
return false;
}
// Allocate the framebuffer 2 memory, fail if we can even do this
matrix_framebuffer_malloc_2 = (frameStruct *)heap_caps_malloc(_frame_buffer_memory_required, MALLOC_CAP_DMA);
if ( matrix_framebuffer_malloc_2 == NULL ) {
Serial.println("ERROR: Couldn't malloc matrix_framebuffer_malloc_2! Critical fail.\r\n");
return false;
}
_total_dma_capable_memory_reserved += _frame_buffer_memory_required;
#endif
/***
* Step 2: Calculate the amount of memory required for the DMA engine's linked list descriptors.
* Credit to SmartMatrix for this stuff.
*/
// Calculate what color depth is actually possible based on memory avaialble vs. required dma linked-list descriptors.
// aka. Calculate the lowest LSBMSB_TRANSITION_BIT value that will fit in memory
int numDMAdescriptorsPerRow = 0;
lsbMsbTransitionBit = 0;
while(1) {
numDMAdescriptorsPerRow = 1;
for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++) {
numDMAdescriptorsPerRow += 1<<(i - lsbMsbTransitionBit - 1);
}
int ramrequired = numDMAdescriptorsPerRow * ROWS_PER_FRAME * _num_frame_buffers * sizeof(lldesc_t);
int largestblockfree = heap_caps_get_largest_free_block(MALLOC_CAP_DMA);
#if SERIAL_DEBUG
Serial.printf("lsbMsbTransitionBit of %d with %d DMA descriptors per frame row, requires %d bytes RAM, %d available, leaving %d free: \r\n", lsbMsbTransitionBit, numDMAdescriptorsPerRow, ramrequired, largestblockfree, largestblockfree - ramrequired);
#endif
if(ramrequired < largestblockfree)
break;
if(lsbMsbTransitionBit < PIXEL_COLOR_DEPTH_BITS - 1)
lsbMsbTransitionBit++;
else
break;
}
Serial.printf("Raised lsbMsbTransitionBit to %d/%d to fit in remaining RAM\r\n", lsbMsbTransitionBit, PIXEL_COLOR_DEPTH_BITS - 1);
// calculate the lowest LSBMSB_TRANSITION_BIT value that will fit in memory that will meet or exceed the configured refresh rate
while(1) {
int psPerClock = 1000000000000UL/ESP32_I2S_CLOCK_SPEED;
int nsPerLatch = ((PIXELS_PER_ROW + CLKS_DURING_LATCH) * psPerClock) / 1000;
// add time to shift out LSBs + LSB-MSB transition bit - this ignores fractions...
int nsPerRow = PIXEL_COLOR_DEPTH_BITS * nsPerLatch;
// add time to shift out MSBs
for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++)
nsPerRow += (1<<(i - lsbMsbTransitionBit - 1)) * (PIXEL_COLOR_DEPTH_BITS - i) * nsPerLatch;
int nsPerFrame = nsPerRow * ROWS_PER_FRAME;
int actualRefreshRate = 1000000000UL/(nsPerFrame);
calculated_refresh_rate = actualRefreshRate;
#if SERIAL_DEBUG
Serial.printf("lsbMsbTransitionBit of %d gives %d Hz refresh: \r\n", lsbMsbTransitionBit, actualRefreshRate);
#endif
if (actualRefreshRate > min_refresh_rate) // HACK Hard Coded: 100
break;
if(lsbMsbTransitionBit < PIXEL_COLOR_DEPTH_BITS - 1)
lsbMsbTransitionBit++;
else
break;
}
Serial.printf("Raised lsbMsbTransitionBit to %d/%d to meet minimum refresh rate\r\n", lsbMsbTransitionBit, PIXEL_COLOR_DEPTH_BITS - 1);
/***
* Step 2a: lsbMsbTransition bit is now finalised - recalculate the DMA descriptor count required, which is used for
* memory allocation of the DMA linked list memory structure.
*/
numDMAdescriptorsPerRow = 1;
for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++) {
numDMAdescriptorsPerRow += 1<<(i - lsbMsbTransitionBit - 1);
}
// Refer to 'DMA_LL_PAYLOAD_SPLIT' code in configureDMA() below to understand why this exists.
// numDMAdescriptorsPerRow is also used to calcaulte descount which is super important in i2s_parallel_config_t SoC DMA setup.
if ( sizeof(rowColorDepthStruct) > DMA_MAX ) {
#if SERIAL_DEBUG
Serial.println("Split DMA payload required.");
#endif
numDMAdescriptorsPerRow += PIXEL_COLOR_DEPTH_BITS-1;
// Not if numDMAdescriptorsPerRow is even just one descriptor too large, DMA linked list will not correctly loop.
}
/***
* Step 3: Allocate memory for DMA linked list, linking up each framebuffer row in sequence for GPIO output.
*/
_dma_linked_list_memory_required = numDMAdescriptorsPerRow * ROWS_PER_FRAME * _num_frame_buffers * sizeof(lldesc_t);
#if SERIAL_DEBUG
Serial.printf("Descriptors for lsbMsbTransitionBit of %d/%d with %d frame rows require %d bytes of DMA RAM with %d numDMAdescriptorsPerRow.\r\n", lsbMsbTransitionBit, PIXEL_COLOR_DEPTH_BITS - 1, ROWS_PER_FRAME, _dma_linked_list_memory_required, numDMAdescriptorsPerRow);
#endif
_total_dma_capable_memory_reserved += _dma_linked_list_memory_required;
// Do a final check to see if we have enough space for the additional DMA linked list descriptors that will be required to link it all up!
if(_dma_linked_list_memory_required > heap_caps_get_largest_free_block(MALLOC_CAP_DMA)) {
Serial.printf("ERROR: Not enough SRAM left over for DMA linked-list descriptor memory reservation! Oh so close!\r\n");
return false;
} // linked list descriptors memory check
// malloc the DMA linked list descriptors that i2s_parallel will need
desccount = numDMAdescriptorsPerRow * ROWS_PER_FRAME;
//lldesc_t * dmadesc_a = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
dmadesc_a = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
assert("Can't allocate descriptor framebuffer a");
if(!dmadesc_a) {
Serial.printf("ERROR: Could not malloc descriptor framebuffer a.");
return false;
}
if (double_buffering_enabled) // reserve space for second framebuffer linked list
{
//lldesc_t * dmadesc_b = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
dmadesc_b = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
assert("Could not malloc descriptor framebuffer b.");
if(!dmadesc_b) {
Serial.printf("ERROR: Could not malloc descriptor framebuffer b.");
return false;
}
}
Serial.printf("*** ESP32-RGB64x32MatrixPanel-I2S-DMA: Memory Allocations Complete *** \r\n");
Serial.printf("Total memory that was reserved: %d kB.\r\n", _total_dma_capable_memory_reserved/1024);
Serial.printf("Heap Memory Available: %d bytes total. Largest free block: %d bytes.\r\n", heap_caps_get_free_size(0), heap_caps_get_largest_free_block(0));
Serial.printf("General RAM Available: %d bytes total. Largest free block: %d bytes.\r\n", heap_caps_get_free_size(MALLOC_CAP_DEFAULT), heap_caps_get_largest_free_block(MALLOC_CAP_DEFAULT));
#if SERIAL_DEBUG
Serial.println("DMA memory blocks available after malloc's: ");
heap_caps_print_heap_info(MALLOC_CAP_DMA);
delay(1000);
#endif
// Just os we know
everything_OK = true;
return true;
} // end initMatrixDMABuffer()
void RGB64x32MatrixPanel_I2S_DMA::configureDMA(int r1_pin, int g1_pin, int b1_pin, int r2_pin, int g2_pin, int b2_pin, int a_pin, int b_pin, int c_pin, int d_pin, int e_pin, int lat_pin, int oe_pin, int clk_pin)
{
#if SERIAL_DEBUG
Serial.println("configureDMA(): Starting configuration of DMA engine.\r\n");
#endif
lldesc_t *previous_dmadesc_a = 0;
lldesc_t *previous_dmadesc_b = 0;
int current_dmadescriptor_offset = 0;
// HACK: If we need to split the payload in 1/2 so that it doesn't breach DMA_MAX, lets do it by the color_depth.
int num_dma_payload_color_depths = PIXEL_COLOR_DEPTH_BITS;
if ( sizeof(rowColorDepthStruct) > DMA_MAX ) {
num_dma_payload_color_depths = 1;
}
// Fill DMA linked lists for both frames (as in, halves of the HUB75 panel) and if double buffering is enabled, link it up for both buffers.
for(int j = 0; j < ROWS_PER_FRAME; j++) {
// Split framebuffer malloc hack 'improvement'
frameStruct *fb_malloc_ptr = matrix_framebuffer_malloc_1;
int fb_malloc_j = j;
#ifdef SPLIT_MEMORY_MODE
if ( j >= SPLIT_MEMORY_ROWS_PER_FRAME ) {
fb_malloc_ptr = matrix_framebuffer_malloc_2;
fb_malloc_j -= SPLIT_MEMORY_ROWS_PER_FRAME; // IMPORTANT
#if SERIAL_DEBUG
Serial.printf("Split memory mode. Panel row: %d, mapped to framebuffer malloc 2 offset: %d.\r\n", j, fb_malloc_j);
#endif
}
#endif
#if SERIAL_DEBUG
Serial.printf("DMA payload of %d bytes. DMA_MAX is %d.\r\n", sizeof(rowBitStruct) * PIXEL_COLOR_DEPTH_BITS, DMA_MAX);
#endif
// first set of data is LSB through MSB, single pass (IF TOTAL SIZE < DMA_MAX) - all color bits are displayed once, which takes care of everything below and inlcluding LSBMSB_TRANSITION_BIT
// NOTE: size must be less than DMA_MAX - worst case for library: 16-bpp with 256 pixels per row would exceed this, need to break into two
link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, &(fb_malloc_ptr[0].rowdata[fb_malloc_j].rowbits[0].data), sizeof(rowBitStruct) * num_dma_payload_color_depths);
previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
if (double_buffering_enabled) {
link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, &(fb_malloc_ptr[1].rowdata[fb_malloc_j].rowbits[0].data), sizeof(rowBitStruct) * num_dma_payload_color_depths);
previous_dmadesc_b = &dmadesc_b[current_dmadescriptor_offset]; }
current_dmadescriptor_offset++;
// If the number of pixels per row is to great for the size of a DMA payload, so we need to split what we were going to send above.
if ( sizeof(rowColorDepthStruct) > DMA_MAX )
{
#if SERIAL_DEBUG
Serial.printf("Spliting DMA payload for %d color depths into %d byte payloads.\r\n", PIXEL_COLOR_DEPTH_BITS-1, sizeof(rowBitStruct) );
#endif
for (int cd = 1; cd < PIXEL_COLOR_DEPTH_BITS; cd++)
{
// first set of data is LSB through MSB, single pass - all color bits are displayed once, which takes care of everything below and inlcluding LSBMSB_TRANSITION_BIT
// TODO: size must be less than DMA_MAX - worst case for library: 16-bpp with 256 pixels per row would exceed this, need to break into two
link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, &(fb_malloc_ptr[0].rowdata[fb_malloc_j].rowbits[cd].data), sizeof(rowBitStruct) );
previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
if (double_buffering_enabled) {
link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, &(fb_malloc_ptr[1].rowdata[fb_malloc_j].rowbits[cd].data), sizeof(rowBitStruct) );
previous_dmadesc_b = &dmadesc_b[current_dmadescriptor_offset]; }
current_dmadescriptor_offset++;
} // additional linked list items
} // row depth struct
for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++)
{
// binary time division setup: we need 2 of bit (LSBMSB_TRANSITION_BIT + 1) four of (LSBMSB_TRANSITION_BIT + 2), etc
// because we sweep through to MSB each time, it divides the number of times we have to sweep in half (saving linked list RAM)
// we need 2^(i - LSBMSB_TRANSITION_BIT - 1) == 1 << (i - LSBMSB_TRANSITION_BIT - 1) passes from i to MSB
//Serial.printf("buffer %d: repeat %d times, size: %d, from %d - %d\r\n", current_dmadescriptor_offset, 1<<(i - lsbMsbTransitionBit - 1), (PIXEL_COLOR_DEPTH_BITS - i), i, PIXEL_COLOR_DEPTH_BITS-1);
for(int k=0; k < 1<<(i - lsbMsbTransitionBit - 1); k++)
{
link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, &(fb_malloc_ptr[0].rowdata[fb_malloc_j].rowbits[i].data), sizeof(rowBitStruct) * (PIXEL_COLOR_DEPTH_BITS - i));
previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
if (double_buffering_enabled) {
link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, &(fb_malloc_ptr[1].rowdata[fb_malloc_j].rowbits[i].data), sizeof(rowBitStruct) * (PIXEL_COLOR_DEPTH_BITS - i));
previous_dmadesc_b = &dmadesc_b[current_dmadescriptor_offset]; }
current_dmadescriptor_offset++;
} // end color depth ^ 2 linked list
} // end color depth loop
} // end frame rows
#if SERIAL_DEBUG
Serial.printf("configureDMA(): Configured LL structure. %d DMA Linked List descriptors populated.\r\n", current_dmadescriptor_offset);
#endif
dmadesc_a[desccount-1].eof = 1;
dmadesc_a[desccount-1].qe.stqe_next=(lldesc_t*)&dmadesc_a[0];
//End markers for DMA LL
if (double_buffering_enabled) {
dmadesc_b[desccount-1].eof = 1;
dmadesc_b[desccount-1].qe.stqe_next=(lldesc_t*)&dmadesc_b[0];
} else {
dmadesc_b = dmadesc_a; // link to same 'a' buffer
}
/*
//End markers
dmadesc_a[desccount-1].eof = 1;
dmadesc_b[desccount-1].eof = 1;
dmadesc_a[desccount-1].qe.stqe_next=(lldesc_t*)&dmadesc_a[0];
dmadesc_b[desccount-1].qe.stqe_next=(lldesc_t*)&dmadesc_b[0];
*/
//Serial.printf("Performing I2S setup.\n");
i2s_parallel_config_t cfg={
.gpio_bus={r1_pin, g1_pin, b1_pin, r2_pin, g2_pin, b2_pin, lat_pin, oe_pin, a_pin, b_pin, c_pin, d_pin, e_pin, -1, -1, -1},
.gpio_clk=clk_pin,
.clkspeed_hz=ESP32_I2S_CLOCK_SPEED, //ESP32_I2S_CLOCK_SPEED, // formula used is 80000000L/(cfg->clkspeed_hz + 1), must result in >=2. Acceptable values 26.67MHz, 20MHz, 16MHz, 13.34MHz...
.bits=ESP32_I2S_DMA_MODE, //ESP32_I2S_DMA_MODE,
.bufa=0,
.bufb=0,
desccount,
desccount,
dmadesc_a,
dmadesc_b
};
//Setup I2S
i2s_parallel_setup_without_malloc(&I2S1, &cfg);
#if SERIAL_DEBUG
Serial.println("configureDMA(): DMA configuration completed on I2S1.\r\n");
#endif
#if SERIAL_DEBUG
Serial.println("DMA Memory Map after DMA LL allocations: ");
heap_caps_print_heap_info(MALLOC_CAP_DMA);
delay(1000);
#endif
} // end initMatrixDMABuff
/* Update a specific co-ordinate in the DMA buffer */
void RGB64x32MatrixPanel_I2S_DMA::updateMatrixDMABuffer(int16_t x_coord, int16_t y_coord, uint8_t red, uint8_t green, uint8_t blue)
{
if ( !everything_OK ) {
#if SERIAL_DEBUG
Serial.println("Cannot updateMatrixDMABuffer as setup failed!");
#endif
return;
}
#ifdef SPLIT_MEMORY_MODE
#ifdef SERIAL_DEBUG
int tmp_y_coord = y_coord;
#endif
#endif
/* 1) Check that the co-ordinates are within range, or it'll break everything big time.
* Valid co-ordinates are from 0 to (MATRIX_XXXX-1)
*/
if ( x_coord < 0 || y_coord < 0 || x_coord >= MATRIX_WIDTH || y_coord >= MATRIX_HEIGHT) {
return;
}
/* 2) Convert the vertical axis / y-axis pixel co-ordinate to a matrix panel parallel co-ordinate..
* eg. If the y co-ordinate is 23, that's actually in the second half of the panel, row 7.
* 23 (y coord) - 16 (for 32px high panel) = 7
*/
bool paint_top_half = true;
if ( y_coord >= ROWS_PER_FRAME) // co-ords start at zero, y_coord = 15 = 16 (rows per frame)
{
y_coord -= ROWS_PER_FRAME; // Subtract the ROWS_PER_FRAME from the pixel co-ord to get the panel co-ord.
paint_top_half = false;
}
for(int color_depth_idx=0; color_depth_idx<PIXEL_COLOR_DEPTH_BITS; color_depth_idx++) // color depth - 8 iterations
{
uint16_t mask = (1 << color_depth_idx); // 24 bit color
// The destination for the pixel bitstream
//rowBitStruct *p = &matrix_framebuffer_malloc_1[back_buffer_id].rowdata[y_coord].rowbits[color_depth_idx]; //matrixUpdateFrames location to write to uint16_t's
rowBitStruct *p = &matrix_framebuffer_malloc_1[back_buffer_id].rowdata[y_coord].rowbits[color_depth_idx];
#ifdef SPLIT_MEMORY_MODE
if (y_coord >= SPLIT_MEMORY_ROWS_PER_FRAME ) {
p = &matrix_framebuffer_malloc_2[back_buffer_id].rowdata[(y_coord-SPLIT_MEMORY_ROWS_PER_FRAME)].rowbits[color_depth_idx]; //matrixUpdateFrames location to write to uint16_t's
#ifdef SERIAL_DEBUG
// Serial.printf("fb_malloc_2. y-coord: %d, calc. offset: %d \r\n", tmp_y_coord, (y_coord-SPLIT_MEMORY_ROWS_PER_FRAME) );
#endif
}
#endif
int v=0; // the output bitstream
// if there is no latch to hold address, output ADDX lines directly to GPIO and latch data at end of cycle
int gpioRowAddress = y_coord;
// normally output current rows ADDX, special case for LSB, output previous row's ADDX (as previous row is being displayed for one latch cycle)
if(color_depth_idx == 0)
gpioRowAddress = y_coord-1;
if (gpioRowAddress & 0x01) v|=BIT_A; // 1
if (gpioRowAddress & 0x02) v|=BIT_B; // 2
if (gpioRowAddress & 0x04) v|=BIT_C; // 4
if (gpioRowAddress & 0x08) v|=BIT_D; // 8
if (gpioRowAddress & 0x10) v|=BIT_E; // 16
/* ORIG
// need to disable OE after latch to hide row transition
if((x_coord) == 0) v|=BIT_OE;
// drive latch while shifting out last bit of RGB data
if((x_coord) == PIXELS_PER_LATCH-1) v|=BIT_LAT;
// need to turn off OE one clock before latch, otherwise can get ghosting
if((x_coord)==PIXELS_PER_LATCH-1) v|=BIT_OE;
*/
// need to disable OE after latch to hide row transition
if((x_coord) == 0 ) v|=BIT_OE;
// drive latch while shifting out last bit of RGB data
if((x_coord) == PIXELS_PER_ROW-1) v|=BIT_LAT;
// need to turn off OE one clock before latch, otherwise can get ghosting
if((x_coord)==PIXELS_PER_ROW-2) v|=BIT_OE;
// turn off OE after brightness value is reached when displaying MSBs
// MSBs always output normal brightness
// LSB (!color_depth_idx) outputs normal brightness as MSB from previous row is being displayed
if((color_depth_idx > lsbMsbTransitionBit || !color_depth_idx) && ((x_coord) >= brightness)) v|=BIT_OE; // For Brightness
// special case for the bits *after* LSB through (lsbMsbTransitionBit) - OE is output after data is shifted, so need to set OE to fractional brightness
if(color_depth_idx && color_depth_idx <= lsbMsbTransitionBit) {
// divide brightness in half for each bit below lsbMsbTransitionBit
int lsbBrightness = brightness >> (lsbMsbTransitionBit - color_depth_idx + 1);
if((x_coord) >= lsbBrightness) v|=BIT_OE; // For Brightness
}
/* When using the drawPixel, we are obviously only changing the value of one x,y position,
* however, the HUB75 is wired up such that it is always painting TWO lines at the same time
* and this reflects the parallel in-DMA-memory data structure of uint16_t's that are getting
* pumped out at high speed.
*
* So we need to ensure we persist the bits (8 of them) of the uint16_t for the row we aren't changing.
*
* The DMA buffer order has also been reversed (refer to the last code in this function)
* so we have to check for this and check the correct position of the MATRIX_DATA_STORAGE_TYPE
* data.
*/
int tmp_x_coord = x_coord;
if(x_coord%2)
{
tmp_x_coord -= 1;
} else {
tmp_x_coord += 1;
} // end reordering
if (paint_top_half)
{ // Need to copy what the RGB status is for the bottom pixels
// Set the color of the pixel of interest
if (green & mask) { v|=BIT_G1; }
if (blue & mask) { v|=BIT_B1; }
if (red & mask) { v|=BIT_R1; }
// Persist what was painted to the other half of the frame equiv. pixel
if (p->data[tmp_x_coord] & BIT_R2)
v|=BIT_R2;
if (p->data[tmp_x_coord] & BIT_G2)
v|=BIT_G2;
if (p->data[tmp_x_coord] & BIT_B2)
v|=BIT_B2;
}
else
{ // Do it the other way around
// Color to set
if (red & mask) { v|=BIT_R2; }
if (green & mask) { v|=BIT_G2; }
if (blue & mask) { v|=BIT_B2; }
// Copy
if (p->data[tmp_x_coord] & BIT_R1)
v|=BIT_R1;
if (p->data[tmp_x_coord] & BIT_G1)
v|=BIT_G1;
if (p->data[tmp_x_coord] & BIT_B1)
v|=BIT_B1;
} // paint
// 16 bit parallel mode
//Save the calculated value to the bitplane memory in reverse order to account for I2S Tx FIFO mode1 ordering
if(x_coord%2){
p->data[(x_coord)-1] = v;
} else {
p->data[(x_coord)+1] = v;
} // end reordering
} // color depth loop (8)
} // updateMatrixDMABuffer (specific co-ords change)
/* Update the entire buffer with a single specific colour - quicker */
void RGB64x32MatrixPanel_I2S_DMA::updateMatrixDMABuffer(uint8_t red, uint8_t green, uint8_t blue)
{
if ( !everything_OK ) return;
for (unsigned int matrix_frame_parallel_row = 0; matrix_frame_parallel_row < ROWS_PER_FRAME; matrix_frame_parallel_row++) // half height - 16 iterations
{
for(int color_depth_idx=0; color_depth_idx<PIXEL_COLOR_DEPTH_BITS; color_depth_idx++) // color depth - 8 iterations
{
uint16_t mask = (1 << color_depth_idx); // 24 bit color
// The destination for the pixel bitstream
rowBitStruct *p = &matrix_framebuffer_malloc_1[back_buffer_id].rowdata[matrix_frame_parallel_row].rowbits[color_depth_idx]; //matrixUpdateFrames location to write to uint16_t's
#ifdef SPLIT_MEMORY_MODE
if (matrix_frame_parallel_row >= SPLIT_MEMORY_ROWS_PER_FRAME ) {
p = &matrix_framebuffer_malloc_2[back_buffer_id].rowdata[(matrix_frame_parallel_row-SPLIT_MEMORY_ROWS_PER_FRAME)].rowbits[color_depth_idx]; //matrixUpdateFrames location to write to uint16_t's
#ifdef SERIAL_DEBUG
//Serial.printf("Using framebuffer_malloc_2. Row %d = Offset %d\r\n", matrix_frame_parallel_row, (matrix_frame_parallel_row-SPLIT_MEMORY_ROWS_PER_FRAME) );
#endif
}
else
{
#ifdef SERIAL_DEBUG
// Serial.printf("Using framebuffer_malloc_1. Row %d\r\n", matrix_frame_parallel_row );
#endif
}
#endif
for(int x_coord=0; x_coord < MATRIX_WIDTH; x_coord++) // row pixel width 64 iterations
{
int v=0; // the output bitstream
// if there is no latch to hold address, output ADDX lines directly to GPIO and latch data at end of cycle
int gpioRowAddress = matrix_frame_parallel_row;
// normally output current rows ADDX, special case for LSB, output previous row's ADDX (as previous row is being displayed for one latch cycle)
if(color_depth_idx == 0)
gpioRowAddress = matrix_frame_parallel_row-1;
if (gpioRowAddress & 0x01) v|=BIT_A; // 1
if (gpioRowAddress & 0x02) v|=BIT_B; // 2
if (gpioRowAddress & 0x04) v|=BIT_C; // 4
if (gpioRowAddress & 0x08) v|=BIT_D; // 8
if (gpioRowAddress & 0x10) v|=BIT_E; // 16
/* ORIG
// need to disable OE after latch to hide row transition
if((x_coord) == 0) v|=BIT_OE;
// drive latch while shifting out last bit of RGB data
if((x_coord) == PIXELS_PER_LATCH-1) v|=BIT_LAT;
// need to turn off OE one clock before latch, otherwise can get ghosting
if((x_coord)==PIXELS_PER_LATCH-1) v|=BIT_OE;
*/
// need to disable OE after latch to hide row transition
if((x_coord) == 0 ) v|=BIT_OE;
// drive latch while shifting out last bit of RGB data
if((x_coord) == PIXELS_PER_ROW-1) v|=BIT_LAT;
// need to turn off OE one clock before latch, otherwise can get ghosting
if((x_coord)==PIXELS_PER_ROW-2) v|=BIT_OE;
// turn off OE after brightness value is reached when displaying MSBs
// MSBs always output normal brightness
// LSB (!color_depth_idx) outputs normal brightness as MSB from previous row is being displayed
if((color_depth_idx > lsbMsbTransitionBit || !color_depth_idx) && ((x_coord) >= brightness)) v|=BIT_OE; // For Brightness
// special case for the bits *after* LSB through (lsbMsbTransitionBit) - OE is output after data is shifted, so need to set OE to fractional brightness
if(color_depth_idx && color_depth_idx <= lsbMsbTransitionBit) {
// divide brightness in half for each bit below lsbMsbTransitionBit
int lsbBrightness = brightness >> (lsbMsbTransitionBit - color_depth_idx + 1);
if((x_coord) >= lsbBrightness) v|=BIT_OE; // For Brightness
}
// Top and bottom matrix MATRIX_ROWS_IN_PARALLEL half colours
if (green & mask) { v|=BIT_G1; v|=BIT_R2; }
if (blue & mask) { v|=BIT_B1; v|=BIT_G2; }
if (red & mask) { v|=BIT_R1; v|=BIT_B2; }
// 16 bit parallel mode
//Save the calculated value to the bitplane memory in reverse order to account for I2S Tx FIFO mode1 ordering
if(x_coord%2) {
p->data[(x_coord)-1] = v;
} else {
p->data[(x_coord)+1] = v;
} // end reordering
} // end x_coord iteration
} // colour depth loop (8)
} // end row iteration
} // updateMatrixDMABuffer (full frame paint)