e04c30c8ae
Signed-off-by: Emil Muratov <gpm@hotplug.ru>
1012 lines
No EOL
45 KiB
C++
1012 lines
No EOL
45 KiB
C++
#include <Arduino.h>
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#include "ESP32-HUB75-MatrixPanel-I2S-DMA.h"
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//#include "xtensa/core-macros.h"
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// Credits: Louis Beaudoin <https://github.com/pixelmatix/SmartMatrix/tree/teensylc>
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// and Sprite_TM: https://www.esp32.com/viewtopic.php?f=17&t=3188 and https://www.esp32.com/viewtopic.php?f=13&t=3256
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/*
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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
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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
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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
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RGB pixel input, the rest of the inputs are shared.
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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
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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,
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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,
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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
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clocked in.
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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
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will immediately appear on this line. Note: While clocking in data for a line, the *previous* line is still displayed, and these lines should
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be set to the value to reflect the position the *previous* line is supposed to be on.
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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:
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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
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line.
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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
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only one line is showed at a time, and the display looks like every pixel is driven at the same time.
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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
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color palette of 8 pixels, not enough to display nice pictures. To get around this, we use binary code modulation.
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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
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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.
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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
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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
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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,
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we turn on the corresponding LED in subframe 2, if bit 5 is set subframe 1, if bit 4 is set in subframe 0.
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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
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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
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them, this 'automatically' happens. (We also distribute the subframes evenly over the ticks, which reduces flicker.)
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In this code, we use the I2S peripheral in parallel mode to achieve this. Essentially, first we allocate memory for all subframes. This memory
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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.
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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
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subframe x has to be sent out for (2^x) ticks. Finally, we fill the subframes with image data.
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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.
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In practice, for small displays this is not really necessarily.
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*/
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// macro's to calculate sizes of a single buffer (double buffer takes twice as this)
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#define rowBitStructBuffSize sizeof(ESP32_I2S_DMA_STORAGE_TYPE) * (PIXELS_PER_ROW + CLKS_DURING_LATCH) * PIXEL_COLOR_DEPTH_BITS
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#define frameStructBuffSize ROWS_PER_FRAME * rowBitStructBuffSize
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/* this replicates same function in rowBitStruct, but due to induced inlining it might be MUCH faster when used in tight loops
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* while method from struct could be flushed out of instruction cache between loop cycles
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* do NOT forget about buff_id param if using this
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*/
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#define getRowDataPtr(row, _dpth, buff_id) &(dma_buff.rowBits[row]->data[_dpth * dma_buff.rowBits[row]->width + buff_id*(dma_buff.rowBits[row]->width * dma_buff.rowBits[row]->color_depth)])
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/* This library is designed to take an 8 bit / 1 byt value (0-255) for each R G B colour sub-pixel.
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* The PIXEL_COLOR_DEPTH_BITS should always be '8' as a result.
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* However, if the library is to be used with lower colour depth (i.e. 6 bit colour), then we need to ensure the 8-bit value passed to the colour masking
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* is adjusted accordingly to ensure the LSB's are shifted left to MSB, by the difference. Otherwise the colours will be all screwed up.
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*/
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#if PIXEL_COLOR_DEPTH_BITS < 8
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#define COLOR_DEPTH_LESS_THAN_8BIT_ADJUST +(8-PIXEL_COLOR_DEPTH_BITS)
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#else
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#define COLOR_DEPTH_LESS_THAN_8BIT_ADJUST // Nothing to adjust.
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#endif
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bool MatrixPanel_I2S_DMA::allocateDMAmemory()
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{
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/***
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* Step 1: Look at the overall DMA capable memory for the DMA FRAMEBUFFER data only (not the DMA linked list descriptors yet)
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* and do some pre-checks.
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*/
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int _num_frame_buffers = (m_cfg.double_buff) ? 2:1;
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size_t _frame_buffer_memory_required = frameStructBuffSize * _num_frame_buffers;
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size_t _dma_linked_list_memory_required = 0;
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size_t _total_dma_capable_memory_reserved = 0;
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// 1. Calculate the amount of DMA capable memory that's actually available
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Panel Width: %d pixels.\r\n"), PIXELS_PER_ROW);
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Serial.printf_P(PSTR("Panel Height: %d pixels.\r\n"), m_cfg.mx_height);
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if (m_cfg.double_buff) {
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Serial.println(F("DOUBLE FRAME BUFFERS / DOUBLE BUFFERING IS ENABLED. DOUBLE THE RAM REQUIRED!"));
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}
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Serial.println(F("DMA memory blocks available before any malloc's: "));
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heap_caps_print_heap_info(MALLOC_CAP_DMA);
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Serial.println(F("******************************************************************"));
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Serial.printf_P(PSTR("We're going to need %d bytes of SRAM just for the frame buffer(s).\r\n"), _frame_buffer_memory_required);
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Serial.printf_P(PSTR("The total amount of DMA capable SRAM memory is %d bytes.\r\n"), heap_caps_get_free_size(MALLOC_CAP_DMA));
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Serial.printf_P(PSTR("Largest DMA capable SRAM memory block is %d bytes.\r\n"), heap_caps_get_largest_free_block(MALLOC_CAP_DMA));
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Serial.println(F("******************************************************************"));
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#endif
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// Can we potentially fit the framebuffer into the DMA capable memory that's available?
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if ( heap_caps_get_free_size(MALLOC_CAP_DMA) < _frame_buffer_memory_required ) {
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("######### 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_free_size(MALLOC_CAP_DMA)) );
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#endif
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return false;
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}
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// Alright, theoretically we should be OK, so let us do this, so
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// lets allocate a chunk of memory for each row (a row could span multiple panels if chaining is in place)
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dma_buff.rowBits.reserve(ROWS_PER_FRAME);
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// iterate through number of rows
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for (int malloc_num =0; malloc_num < ROWS_PER_FRAME; ++malloc_num)
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{
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auto ptr = std::make_shared<rowBitStruct>(PIXELS_PER_ROW, PIXEL_COLOR_DEPTH_BITS, m_cfg.double_buff);
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if (ptr->data == nullptr){
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("ERROR: Couldn't malloc rowBitStruct %d! Critical fail.\r\n"), malloc_num);
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#endif
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return false;
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// TODO: should we release all previous rowBitStructs here???
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}
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dma_buff.rowBits.emplace_back(ptr); // save new rowBitStruct into rows vector
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++dma_buff.rows;
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Malloc'ing %d bytes of memory @ address %ud for frame row %d.\r\n"), ptr->size()*_num_frame_buffers, (unsigned int)ptr->getDataPtr(), malloc_num);
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#endif
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}
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_total_dma_capable_memory_reserved += _frame_buffer_memory_required;
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/***
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* Step 2: Calculate the amount of memory required for the DMA engine's linked list descriptors.
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* Credit to SmartMatrix for this stuff.
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*/
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// Calculate what colour depth is actually possible based on memory available vs. required DMA linked-list descriptors.
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// aka. Calculate the lowest LSBMSB_TRANSITION_BIT value that will fit in memory
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int numDMAdescriptorsPerRow = 0;
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lsbMsbTransitionBit = 0;
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while(1) {
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numDMAdescriptorsPerRow = 1;
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for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++) {
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numDMAdescriptorsPerRow += (1<<(i - lsbMsbTransitionBit - 1));
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}
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size_t ramrequired = numDMAdescriptorsPerRow * ROWS_PER_FRAME * _num_frame_buffers * sizeof(lldesc_t);
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size_t largestblockfree = heap_caps_get_largest_free_block(MALLOC_CAP_DMA);
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("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);
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#endif
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if(ramrequired < largestblockfree)
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break;
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if(lsbMsbTransitionBit < PIXEL_COLOR_DEPTH_BITS - 1)
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lsbMsbTransitionBit++;
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else
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break;
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}
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Raised lsbMsbTransitionBit to %d/%d to fit in remaining RAM\r\n"), lsbMsbTransitionBit, PIXEL_COLOR_DEPTH_BITS - 1);
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#endif
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#ifndef IGNORE_REFRESH_RATE
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// calculate the lowest LSBMSB_TRANSITION_BIT value that will fit in memory that will meet or exceed the configured refresh rate
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while(1) {
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int psPerClock = 1000000000000UL/m_cfg.i2sspeed;
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int nsPerLatch = ((PIXELS_PER_ROW + CLKS_DURING_LATCH) * psPerClock) / 1000;
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// add time to shift out LSBs + LSB-MSB transition bit - this ignores fractions...
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int nsPerRow = PIXEL_COLOR_DEPTH_BITS * nsPerLatch;
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// add time to shift out MSBs
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for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++)
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nsPerRow += (1<<(i - lsbMsbTransitionBit - 1)) * (PIXEL_COLOR_DEPTH_BITS - i) * nsPerLatch;
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int nsPerFrame = nsPerRow * ROWS_PER_FRAME;
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int actualRefreshRate = 1000000000UL/(nsPerFrame);
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calculated_refresh_rate = actualRefreshRate;
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("lsbMsbTransitionBit of %d gives %d Hz refresh: \r\n"), lsbMsbTransitionBit, actualRefreshRate);
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#endif
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if (actualRefreshRate > min_refresh_rate) // HACK Hard Coded: 100
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break;
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if(lsbMsbTransitionBit < PIXEL_COLOR_DEPTH_BITS - 1)
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lsbMsbTransitionBit++;
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else
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break;
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}
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Raised lsbMsbTransitionBit to %d/%d to meet minimum refresh rate\r\n"), lsbMsbTransitionBit, PIXEL_COLOR_DEPTH_BITS - 1);
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#endif
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#endif
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/***
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* Step 2a: lsbMsbTransition bit is now finalised - recalculate the DMA descriptor count required, which is used for
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* memory allocation of the DMA linked list memory structure.
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*/
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numDMAdescriptorsPerRow = 1;
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for(int i=lsbMsbTransitionBit + 1; i<PIXEL_COLOR_DEPTH_BITS; i++) {
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numDMAdescriptorsPerRow += (1<<(i - lsbMsbTransitionBit - 1));
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}
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Recalculated number of DMA descriptors per row: %d\n"), numDMAdescriptorsPerRow);
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#endif
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// Refer to 'DMA_LL_PAYLOAD_SPLIT' code in configureDMA() below to understand why this exists.
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// numDMAdescriptorsPerRow is also used to calculate descount which is super important in i2s_parallel_config_t SoC DMA setup.
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if ( rowBitStructBuffSize > DMA_MAX ) {
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("rowColorDepthStruct struct is too large, split DMA payload required. Adding %d DMA descriptors\n"), PIXEL_COLOR_DEPTH_BITS-1);
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#endif
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numDMAdescriptorsPerRow += PIXEL_COLOR_DEPTH_BITS-1;
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// Note: If numDMAdescriptorsPerRow is even just one descriptor too large, DMA linked list will not correctly loop.
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}
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/***
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* Step 3: Allocate memory for DMA linked list, linking up each framebuffer row in sequence for GPIO output.
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*/
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_dma_linked_list_memory_required = numDMAdescriptorsPerRow * ROWS_PER_FRAME * _num_frame_buffers * sizeof(lldesc_t);
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("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);
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#endif
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_total_dma_capable_memory_reserved += _dma_linked_list_memory_required;
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// 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!
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if(_dma_linked_list_memory_required > heap_caps_get_largest_free_block(MALLOC_CAP_DMA)) {
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Serial.println(F("ERROR: Not enough SRAM left over for DMA linked-list descriptor memory reservation! Oh so close!\r\n"));
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return false;
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} // linked list descriptors memory check
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// malloc the DMA linked list descriptors that i2s_parallel will need
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desccount = numDMAdescriptorsPerRow * ROWS_PER_FRAME;
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//lldesc_t * dmadesc_a = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
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dmadesc_a = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
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assert("Can't allocate descriptor framebuffer a");
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if(!dmadesc_a) {
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Serial.println(F("ERROR: Could not malloc descriptor framebuffer a."));
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return false;
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}
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if (m_cfg.double_buff) // reserve space for second framebuffer linked list
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{
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//lldesc_t * dmadesc_b = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
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dmadesc_b = (lldesc_t *)heap_caps_malloc(desccount * sizeof(lldesc_t), MALLOC_CAP_DMA);
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assert("Could not malloc descriptor framebuffer b.");
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if(!dmadesc_b) {
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Serial.println(F("ERROR: Could not malloc descriptor framebuffer b."));
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return false;
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}
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}
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Serial.println(F("*** ESP32-HUB75-MatrixPanel-I2S-DMA: Memory Allocations Complete ***"));
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Serial.printf_P(PSTR("Total memory that was reserved: %d kB.\r\n"), _total_dma_capable_memory_reserved/1024);
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Serial.printf_P(PSTR("... of which was used for the DMA Linked List(s): %d kB.\r\n"), _dma_linked_list_memory_required/1024);
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Serial.printf_P(PSTR("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));
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Serial.printf_P(PSTR("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));
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// Just os we know
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initialized = true;
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return true;
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} // end allocateDMAmemory()
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void MatrixPanel_I2S_DMA::configureDMA(const HUB75_I2S_CFG& _cfg)
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{
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#if SERIAL_DEBUG
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Serial.println(F("configureDMA(): Starting configuration of DMA engine.\r\n"));
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#endif
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lldesc_t *previous_dmadesc_a = 0;
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lldesc_t *previous_dmadesc_b = 0;
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int current_dmadescriptor_offset = 0;
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// 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.
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int num_dma_payload_color_depths = PIXEL_COLOR_DEPTH_BITS;
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if ( rowBitStructBuffSize > DMA_MAX ) {
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num_dma_payload_color_depths = 1;
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}
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// 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.
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for(int row = 0; row < ROWS_PER_FRAME; row++) {
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR( "Row %d DMA payload of %d bytes. DMA_MAX is %d.\n"), row, dma_buff.rowBits[row]->size(), DMA_MAX);
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#endif
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// 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
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// 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
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link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, dma_buff.rowBits[row]->getDataPtr(), dma_buff.rowBits[row]->size(num_dma_payload_color_depths));
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previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
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if (m_cfg.double_buff) {
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link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, dma_buff.rowBits[row]->getDataPtr(0, 1), dma_buff.rowBits[row]->size(num_dma_payload_color_depths));
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previous_dmadesc_b = &dmadesc_b[current_dmadescriptor_offset]; }
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current_dmadescriptor_offset++;
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// If the number of pixels per row is too great for the size of a DMA payload, so we need to split what we were going to send above.
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if ( rowBitStructBuffSize > DMA_MAX )
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{
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#if SERIAL_DEBUG
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Serial.printf_P(PSTR("Spliting DMA payload for %d color depths into %d byte payloads.\r\n"), PIXEL_COLOR_DEPTH_BITS-1, rowBitStructBuffSize/PIXEL_COLOR_DEPTH_BITS );
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#endif
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for (int cd = 1; cd < PIXEL_COLOR_DEPTH_BITS; cd++)
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{
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// 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
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// 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
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link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, dma_buff.rowBits[row]->getDataPtr(cd, 0), dma_buff.rowBits[row]->size(num_dma_payload_color_depths) );
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previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
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if (m_cfg.double_buff) {
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link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, dma_buff.rowBits[row]->getDataPtr(cd, 1), dma_buff.rowBits[row]->size(num_dma_payload_color_depths));
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previous_dmadesc_b = &dmadesc_b[current_dmadescriptor_offset]; }
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current_dmadescriptor_offset++;
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|
|
|
} // 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
|
|
|
|
#if SERIAL_DEBUG
|
|
Serial.printf_P(PSTR("configureDMA(): DMA Loops for PIXEL_COLOR_DEPTH_BITS %d is: %d.\r\n"), i, (1<<(i - lsbMsbTransitionBit - 1)));
|
|
#endif
|
|
|
|
for(int k=0; k < (1<<(i - lsbMsbTransitionBit - 1)); k++)
|
|
{
|
|
link_dma_desc(&dmadesc_a[current_dmadescriptor_offset], previous_dmadesc_a, dma_buff.rowBits[row]->getDataPtr(i, 0), dma_buff.rowBits[row]->size(PIXEL_COLOR_DEPTH_BITS - i) );
|
|
previous_dmadesc_a = &dmadesc_a[current_dmadescriptor_offset];
|
|
|
|
if (m_cfg.double_buff) {
|
|
link_dma_desc(&dmadesc_b[current_dmadescriptor_offset], previous_dmadesc_b, dma_buff.rowBits[row]->getDataPtr(i, 1), dma_buff.rowBits[row]->size(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_P(PSTR("configureDMA(): Configured LL structure. %d DMA Linked List descriptors populated.\r\n"), current_dmadescriptor_offset);
|
|
|
|
if ( desccount != current_dmadescriptor_offset)
|
|
{
|
|
Serial.printf_P(PSTR("configureDMA(): ERROR! Expected descriptor count of %d != actual DMA descriptors of %d!\r\n"), desccount, current_dmadescriptor_offset);
|
|
}
|
|
#endif
|
|
|
|
//End markers for DMA LL
|
|
dmadesc_a[desccount-1].eof = 1;
|
|
dmadesc_a[desccount-1].qe.stqe_next=(lldesc_t*)&dmadesc_a[0];
|
|
|
|
if (m_cfg.double_buff) {
|
|
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
|
|
}
|
|
|
|
#if SERIAL_DEBUG
|
|
Serial.println(F("Performing I2S setup:"));
|
|
#endif
|
|
|
|
i2s_parallel_config_t cfg = {
|
|
.gpio_bus={_cfg.gpio.r1, _cfg.gpio.g1, _cfg.gpio.b1, _cfg.gpio.r2, _cfg.gpio.g2, _cfg.gpio.b2, _cfg.gpio.lat, _cfg.gpio.oe, _cfg.gpio.a, _cfg.gpio.b, _cfg.gpio.c, _cfg.gpio.d, _cfg.gpio.e, -1, -1, -1},
|
|
.gpio_clk=_cfg.gpio.clk,
|
|
.sample_rate=_cfg.i2sspeed,
|
|
.sample_width=ESP32_I2S_DMA_MODE,
|
|
.desccount_a=desccount,
|
|
.lldesc_a=dmadesc_a,
|
|
.desccount_b=desccount,
|
|
.lldesc_b=dmadesc_b
|
|
};
|
|
|
|
// Setup I2S
|
|
i2s_parallel_driver_install(I2S_NUM_1, &cfg);
|
|
//i2s_parallel_setup_without_malloc(&I2S1, &cfg);
|
|
|
|
// Start DMA Output
|
|
i2s_parallel_send_dma(I2S_NUM_1, &dmadesc_a[0]);
|
|
|
|
#if SERIAL_DEBUG
|
|
Serial.println(F("configureDMA(): DMA configuration completed on I2S1."));
|
|
Serial.println(F("DMA Memory Map after DMA LL allocations:"));
|
|
heap_caps_print_heap_info(MALLOC_CAP_DMA);
|
|
#endif
|
|
|
|
} // end initMatrixDMABuff
|
|
|
|
|
|
/* There are 'bits' set in the frameStruct that we simply don't need to set every single time we change a pixel / DMA buffer co-ordinate.
|
|
* For example, the bits that determine the address lines, we don't need to set these every time. Once they're in place, and assuming we
|
|
* don't accidently clear them, then we don't need to set them again.
|
|
* So to save processing, we strip this logic out to the absolute bare minimum, which is toggling only the R,G,B pixels (bits) per co-ord.
|
|
*
|
|
* Critical dependency: That 'updateMatrixDMABuffer(uint8_t red, uint8_t green, uint8_t blue)' has been run at least once over the
|
|
* entire frameBuffer to ensure all the non R,G,B bitmasks are in place (i.e. like OE, Address Lines etc.)
|
|
*
|
|
* Note: If you change the brightness with setBrightness() you MUST then clearScreen() and repaint / flush the entire framebuffer.
|
|
*/
|
|
|
|
/** @brief - Update pixel at specific co-ordinate in the DMA buffer
|
|
* this is the main method used to update DMA buffer on pixel-by-pixel level so it must be fast, real fast!
|
|
* Let's put it into IRAM to avoid situations when it could be flushed out of instruction cache
|
|
* and had to be read from spi-flash over and over again.
|
|
* Yes, it is always a tradeoff between memory/speed/size, but compared to DMA-buffer size is not a big deal
|
|
*/
|
|
void IRAM_ATTR MatrixPanel_I2S_DMA::updateMatrixDMABuffer(int16_t x_coord, int16_t y_coord, uint8_t red, uint8_t green, uint8_t blue)
|
|
{
|
|
if ( !initialized ) {
|
|
#if SERIAL_DEBUG
|
|
Serial.println(F("Cannot updateMatrixDMABuffer as setup failed!"));
|
|
#endif
|
|
return;
|
|
}
|
|
|
|
/* 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 >= PIXELS_PER_ROW || y_coord >= m_cfg.mx_height) {
|
|
return;
|
|
}
|
|
|
|
/* LED Brightness Compensation. Because if we do a basic "red & mask" for example,
|
|
* we'll NEVER send the dimmest possible colour, due to binary skew.
|
|
* i.e. It's almost impossible for color_depth_idx of 0 to be sent out to the MATRIX unless the 'value' of a color is exactly '1'
|
|
* https://ledshield.wordpress.com/2012/11/13/led-brightness-to-your-eye-gamma-correction-no/
|
|
*/
|
|
#ifndef NO_CIE1931
|
|
red = lumConvTab[red];
|
|
green = lumConvTab[green];
|
|
blue = lumConvTab[blue];
|
|
#endif
|
|
|
|
/* When using the drawPixel, we are obviously only changing the value of one x,y position,
|
|
* however, the two-scan panels paint 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.
|
|
*/
|
|
|
|
// We need to update the correct uint16_t in the rowBitStruct array, that gets sent out in parallel
|
|
// 16 bit parallel mode - Save the calculated value to the bitplane memory in reverse order to account for I2S Tx FIFO mode1 ordering
|
|
x_coord & 1U ? --x_coord : ++x_coord;
|
|
|
|
uint16_t _colorbitclear = BITMASK_RGB1_CLEAR, _colorbitoffset = 0;
|
|
|
|
if (y_coord >= ROWS_PER_FRAME){ // if we are drawing to the bottom part of the panel
|
|
_colorbitoffset = BITS_RGB2_OFFSET;
|
|
_colorbitclear = BITMASK_RGB2_CLEAR;
|
|
y_coord -= ROWS_PER_FRAME;
|
|
}
|
|
|
|
// Iterating through colour depth bits, which we assume are 8 bits per RGB subpixel (24bpp)
|
|
uint8_t color_depth_idx = PIXEL_COLOR_DEPTH_BITS;
|
|
do {
|
|
--color_depth_idx;
|
|
uint8_t mask = (1 << (color_depth_idx COLOR_DEPTH_LESS_THAN_8BIT_ADJUST)); // expect 24 bit color (8 bits per RGB subpixel)
|
|
uint16_t RGB_output_bits = 0;
|
|
|
|
/* Per the .h file, the order of the output RGB bits is:
|
|
* BIT_B2, BIT_G2, BIT_R2, BIT_B1, BIT_G1, BIT_R1 */
|
|
RGB_output_bits |= (bool)(blue & mask); // --B
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(green & mask); // -BG
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(red & mask); // BGR
|
|
RGB_output_bits <<= _colorbitoffset; // shift color bits to the required position
|
|
|
|
|
|
// Get the contents at this address,
|
|
// it would represent a vector pointing to the full row of pixels for the specified color depth bit at Y coordinate
|
|
ESP32_I2S_DMA_STORAGE_TYPE *p = getRowDataPtr(y_coord, color_depth_idx, back_buffer_id);
|
|
|
|
|
|
// We need to update the correct uint16_t word in the rowBitStruct array poiting to a specific pixel at X - coordinate
|
|
p[x_coord] &= _colorbitclear; // reset RGB bits
|
|
p[x_coord] |= RGB_output_bits; // set new RGB bits
|
|
|
|
} while(color_depth_idx); // end of color depth loop (8)
|
|
} // updateMatrixDMABuffer (specific co-ords change)
|
|
|
|
|
|
/* Update the entire buffer with a single specific colour - quicker */
|
|
void MatrixPanel_I2S_DMA::updateMatrixDMABuffer(uint8_t red, uint8_t green, uint8_t blue)
|
|
{
|
|
if ( !initialized ) return;
|
|
|
|
/* https://ledshield.wordpress.com/2012/11/13/led-brightness-to-your-eye-gamma-correction-no/ */
|
|
#ifndef NO_CIE1931
|
|
red = lumConvTab[red];
|
|
green = lumConvTab[green];
|
|
blue = lumConvTab[blue];
|
|
#endif
|
|
|
|
for(uint8_t color_depth_idx=0; color_depth_idx<PIXEL_COLOR_DEPTH_BITS; color_depth_idx++) // color depth - 8 iterations
|
|
{
|
|
// let's precalculate RGB1 and RGB2 bits than flood it over the entire DMA buffer
|
|
uint16_t RGB_output_bits = 0;
|
|
uint8_t mask = (1 << color_depth_idx COLOR_DEPTH_LESS_THAN_8BIT_ADJUST); // 24 bit color
|
|
|
|
/* Per the .h file, the order of the output RGB bits is:
|
|
* BIT_B2, BIT_G2, BIT_R2, BIT_B1, BIT_G1, BIT_R1 */
|
|
RGB_output_bits |= (bool)(blue & mask); // --B
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(green & mask); // -BG
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(red & mask); // BGR
|
|
|
|
// Duplicate and shift across so we have have 6 populated bits of RGB1 and RGB2 pin values suitable for DMA buffer
|
|
RGB_output_bits |= RGB_output_bits << BITS_RGB2_OFFSET; //BGRBGR
|
|
|
|
//Serial.printf("Fill with: 0x%#06x\n", RGB_output_bits);
|
|
|
|
// iterate rows
|
|
int matrix_frame_parallel_row = dma_buff.rowBits.size();
|
|
do {
|
|
--matrix_frame_parallel_row;
|
|
|
|
// The destination for the pixel row bitstream
|
|
ESP32_I2S_DMA_STORAGE_TYPE *p = getRowDataPtr(matrix_frame_parallel_row, color_depth_idx, back_buffer_id);
|
|
|
|
// iterate pixels in a row
|
|
int x_coord=dma_buff.rowBits[matrix_frame_parallel_row]->width;
|
|
do {
|
|
--x_coord;
|
|
p[x_coord] &= BITMASK_RGB12_CLEAR; // reset color bits
|
|
p[x_coord] |= RGB_output_bits; // set new color bits
|
|
} while(x_coord);
|
|
|
|
} while(matrix_frame_parallel_row); // end row iteration
|
|
} // colour depth loop (8)
|
|
} // updateMatrixDMABuffer (full frame paint)
|
|
|
|
|
|
#define CLK_PULSE digitalWrite(_cfg.gpio.clk, HIGH); digitalWrite(_cfg.gpio.clk, LOW);
|
|
|
|
/**
|
|
* pre-init procedures for specific drivers
|
|
*
|
|
*/
|
|
void MatrixPanel_I2S_DMA::shiftDriver(const HUB75_I2S_CFG& _cfg){
|
|
switch (_cfg.driver){
|
|
case HUB75_I2S_CFG::ICN2038S:
|
|
case HUB75_I2S_CFG::FM6124:
|
|
case HUB75_I2S_CFG::FM6126A:
|
|
{
|
|
#if SERIAL_DEBUG
|
|
Serial.println( F("MatrixPanel_I2S_DMA - initializing FM6124 driver..."));
|
|
#endif
|
|
bool REG1[16] = {0,0,0,0,0, 1,1,1,1,1,1, 0,0,0,0,0}; // this sets global matrix brightness power
|
|
bool REG2[16] = {0,0,0,0,0, 0,0,0,0,1,0, 0,0,0,0,0}; // a single bit enables the matrix output
|
|
|
|
for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2, _cfg.gpio.clk, _cfg.gpio.lat, _cfg.gpio.oe}){
|
|
pinMode(_pin, OUTPUT);
|
|
digitalWrite(_pin, LOW);
|
|
}
|
|
|
|
digitalWrite(_cfg.gpio.oe, HIGH); // Disable Display
|
|
|
|
// Send Data to control register REG1
|
|
// this sets the matrix brightness actually
|
|
for (int l = 0; l < PIXELS_PER_ROW; l++){
|
|
for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2})
|
|
digitalWrite(_pin, REG1[l%16]); // we have 16 bits shifters and write the same value all over the matrix array
|
|
|
|
if (l > PIXELS_PER_ROW - 12){ // pull the latch 11 clocks before the end of matrix so that REG1 starts counting to save the value
|
|
digitalWrite(_cfg.gpio.lat, HIGH);
|
|
}
|
|
CLK_PULSE
|
|
}
|
|
|
|
// drop the latch and save data to the REG1 all over the FM6124 chips
|
|
digitalWrite(_cfg.gpio.lat, LOW);
|
|
|
|
// Send Data to control register REG2 (enable LED output)
|
|
for (int l = 0; l < PIXELS_PER_ROW; l++){
|
|
for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2})
|
|
digitalWrite(_pin, REG2[l%16]); // we have 16 bits shifters and we write the same value all over the matrix array
|
|
|
|
if (l > PIXELS_PER_ROW - 13){ // pull the latch 12 clocks before the end of matrix so that reg2 stars counting to save the value
|
|
digitalWrite(_cfg.gpio.lat, HIGH);
|
|
}
|
|
CLK_PULSE
|
|
}
|
|
|
|
// drop the latch and save data to the REG1 all over the FM6126 chips
|
|
digitalWrite(_cfg.gpio.lat, LOW);
|
|
|
|
// blank data regs to keep matrix clear after manipulations
|
|
for (uint8_t _pin:{_cfg.gpio.r1, _cfg.gpio.r2, _cfg.gpio.g1, _cfg.gpio.g2, _cfg.gpio.b1, _cfg.gpio.b2})
|
|
digitalWrite(_pin, LOW);
|
|
|
|
for (int l = 0; l < PIXELS_PER_ROW; ++l){
|
|
CLK_PULSE
|
|
}
|
|
|
|
digitalWrite(_cfg.gpio.lat, HIGH);
|
|
CLK_PULSE
|
|
digitalWrite(_cfg.gpio.lat, LOW);
|
|
digitalWrite(_cfg.gpio.oe, LOW); // Enable Display
|
|
CLK_PULSE
|
|
}
|
|
break;
|
|
case HUB75_I2S_CFG::SHIFT:
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
|
|
/**
|
|
* clear screen to black and reset all service bits
|
|
*/
|
|
void MatrixPanel_I2S_DMA::clearScreen(){
|
|
clearFrameBuffer();
|
|
brtCtrlOE(brightness);
|
|
if (m_cfg.double_buff){
|
|
clearFrameBuffer(1);
|
|
brtCtrlOE(brightness, 1);
|
|
}
|
|
}
|
|
|
|
/**
|
|
* @brief - clears and reinitializes color/control data in DMA buffs
|
|
* When allocated, DMA buffs might be dirtry, so we need to blank it and initialize ABCDE,LAT,OE control bits.
|
|
* Those control bits are constants during the entire DMA sweep and never changed when updating just pixel color data
|
|
* so we could set it once on DMA buffs initialization and forget.
|
|
* This effectively clears buffers to blank BLACK and makes it ready to display output.
|
|
* (Brightness control via OE bit manipulation is another case)
|
|
*/
|
|
void MatrixPanel_I2S_DMA::clearFrameBuffer(bool _buff_id){
|
|
if (!initialized)
|
|
return;
|
|
|
|
// we start with iterating all rows in dma_buff structure
|
|
int row_idx = dma_buff.rowBits.size();
|
|
do {
|
|
--row_idx;
|
|
|
|
ESP32_I2S_DMA_STORAGE_TYPE* row = dma_buff.rowBits[row_idx]->getDataPtr(0, _buff_id); // set pointer to the HEAD of a buffer holding data for the entire matrix row
|
|
|
|
ESP32_I2S_DMA_STORAGE_TYPE abcde = (ESP32_I2S_DMA_STORAGE_TYPE)row_idx;
|
|
abcde <<= BITS_ADDR_OFFSET; // shift row y-coord to match ABCDE bits in vector from 8 to 12
|
|
|
|
// get last pixel index in a row of all colordepths
|
|
int x_pixel = dma_buff.rowBits[row_idx]->width * dma_buff.rowBits[row_idx]->color_depth;
|
|
//Serial.printf(" from pixel %d, ", x_pixel);
|
|
|
|
// fill all x_pixels except color_index[0] (LSB) ones, this also clears all color data to 0's black
|
|
do {
|
|
--x_pixel;
|
|
row[x_pixel] = abcde;
|
|
} while(x_pixel!=dma_buff.rowBits[row_idx]->width);
|
|
|
|
// color_index[0] (LSB) x_pixels must be "marked" with a previous's row address, 'cause it is used to display
|
|
// previous row while we pump in LSB's for a new row
|
|
abcde = ((ESP32_I2S_DMA_STORAGE_TYPE)row_idx-1) << BITS_ADDR_OFFSET;
|
|
do {
|
|
--x_pixel;
|
|
row[x_pixel] = abcde;
|
|
} while(x_pixel);
|
|
|
|
// let's set LAT/OE control bits for specific pixels in each color_index subrows
|
|
uint8_t coloridx = dma_buff.rowBits[row_idx]->color_depth;
|
|
do {
|
|
--coloridx;
|
|
|
|
// switch pointer to a row for a specific color index
|
|
row = dma_buff.rowBits[row_idx]->getDataPtr(coloridx, _buff_id);
|
|
|
|
// drive latch while shifting out last bit of RGB data
|
|
row[dma_buff.rowBits[row_idx]->width - 2] |= BIT_LAT; // -1 pixel to compensate array index starting at 0
|
|
|
|
// need to disable OE before/after latch to hide row transition
|
|
// Should be one clock or more before latch, otherwise can get ghosting
|
|
uint8_t _blank = m_cfg.latch_blanking;
|
|
do {
|
|
--_blank;
|
|
row[0 + _blank] |= BIT_OE;
|
|
row[dma_buff.rowBits[row_idx]->width - _blank - 3 ] |= BIT_OE; // (LAT pulse is (width-2) -1 pixel to compensate array index starting at 0
|
|
} while (_blank);
|
|
|
|
} while(coloridx);
|
|
|
|
} while(row_idx);
|
|
}
|
|
|
|
/**
|
|
* @brief - reset OE bits in DMA buffer in a way to control brightness
|
|
* @param brt - brightness level from 0 to row_width
|
|
* @param _buff_id - buffer id to control
|
|
*/
|
|
void MatrixPanel_I2S_DMA::brtCtrlOE(int brt, const bool _buff_id){
|
|
if (!initialized)
|
|
return;
|
|
|
|
if (brt > PIXELS_PER_ROW - m_cfg.latch_blanking) // can't control values larger than (row_width - latch_blanking) to avoid ongoing issues being raised about brightness and ghosting.
|
|
brt = PIXELS_PER_ROW - m_cfg.latch_blanking;
|
|
|
|
if (brt < 0)
|
|
brt = 0;
|
|
|
|
// start with iterating all rows in dma_buff structure
|
|
int row_idx = dma_buff.rowBits.size();
|
|
do {
|
|
--row_idx;
|
|
|
|
// let's set OE control bits for specific pixels in each color_index subrows
|
|
uint8_t coloridx = dma_buff.rowBits[row_idx]->color_depth;
|
|
do {
|
|
--coloridx;
|
|
|
|
// switch pointer to a row for a specific color index
|
|
ESP32_I2S_DMA_STORAGE_TYPE* row = dma_buff.rowBits[row_idx]->getDataPtr(coloridx, _buff_id);
|
|
|
|
int x_coord = dma_buff.rowBits[row_idx]->width;
|
|
do {
|
|
--x_coord;
|
|
|
|
// Brightness control via OE toggle - disable matrix output at specified x_coord
|
|
if((coloridx > lsbMsbTransitionBit || !coloridx) && ((x_coord) >= brt)){
|
|
row[x_coord] |= BIT_OE; continue; // For Brightness control
|
|
}
|
|
// 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(coloridx && coloridx <= lsbMsbTransitionBit) {
|
|
// divide brightness in half for each bit below lsbMsbTransitionBit
|
|
int lsbBrightness = brt >> (lsbMsbTransitionBit - coloridx + 1);
|
|
if((x_coord) >= lsbBrightness)
|
|
row[x_coord] |= BIT_OE; // For Brightness
|
|
|
|
continue;
|
|
}
|
|
|
|
// clear OE bit for all other pixels
|
|
row[x_coord] &= BITMASK_OE_CLEAR;
|
|
} while(x_coord);
|
|
|
|
// need to disable OE before/after latch to hide row transition
|
|
// Should be one clock or more before latch, otherwise can get ghosting
|
|
uint8_t _blank = m_cfg.latch_blanking;
|
|
do {
|
|
--_blank;
|
|
row[0 + _blank] |= BIT_OE;
|
|
// no need, has been done already
|
|
//row[dma_buff.rowBits[row_idx]->width - _blank - 3 ] |= BIT_OE; // (LAT pulse is (width-2) -1 pixel to compensate array index starting at 0
|
|
} while (_blank);
|
|
|
|
} while(coloridx);
|
|
} while(row_idx);
|
|
}
|
|
|
|
|
|
/*
|
|
* overload for compatibility
|
|
*/
|
|
bool MatrixPanel_I2S_DMA::begin(int r1, int g1, int b1, int r2, int g2, int b2, int a, int b, int c, int d, int e, int lat, int oe, int clk){
|
|
|
|
// RGB
|
|
m_cfg.gpio.r1 = r1; m_cfg.gpio.g1 = g1; m_cfg.gpio.b1 = b1;
|
|
m_cfg.gpio.r2 = r2; m_cfg.gpio.g2 = g2; m_cfg.gpio.b2 = b2;
|
|
|
|
// Line Select
|
|
m_cfg.gpio.a = a; m_cfg.gpio.b = b; m_cfg.gpio.c = c;
|
|
m_cfg.gpio.d = d; m_cfg.gpio.e = e;
|
|
|
|
// Clock & Control
|
|
m_cfg.gpio.lat = lat; m_cfg.gpio.oe = oe; m_cfg.gpio.clk = clk;
|
|
|
|
return begin();
|
|
}
|
|
|
|
/**
|
|
* @brief - Sets how many clock cycles to blank OE before/after LAT signal change
|
|
* @param uint8_t pulses - clocks before/after OE
|
|
* default is DEFAULT_LAT_BLANKING
|
|
* Max is MAX_LAT_BLANKING
|
|
* @returns - new value for m_cfg.latch_blanking
|
|
*/
|
|
uint8_t MatrixPanel_I2S_DMA::setLatBlanking(uint8_t pulses){
|
|
if (pulses > MAX_LAT_BLANKING)
|
|
pulses = MAX_LAT_BLANKING;
|
|
|
|
if (!pulses)
|
|
pulses = DEFAULT_LAT_BLANKING;
|
|
|
|
m_cfg.latch_blanking = pulses;
|
|
setPanelBrightness(brightness); // set brighness to reset OE bits to the values matching new LAT blanking setting
|
|
return m_cfg.latch_blanking;
|
|
}
|
|
|
|
|
|
#ifndef NO_FAST_FUNCTIONS
|
|
/**
|
|
* @brief - update DMA buff drawing horizontal line at specified coordinates
|
|
* @param x_ccord - line start coordinate x
|
|
* @param y_ccord - line start coordinate y
|
|
* @param l - line length
|
|
* @param r,g,b, - RGB888 color
|
|
*/
|
|
void MatrixPanel_I2S_DMA::hlineDMA(int16_t x_coord, int16_t y_coord, int16_t l, uint8_t red, uint8_t green, uint8_t blue){
|
|
if ( !initialized )
|
|
return;
|
|
|
|
if ( x_coord < 0 || y_coord < 0 || l < 1 || x_coord >= PIXELS_PER_ROW || y_coord >= m_cfg.mx_height)
|
|
return;
|
|
|
|
if (x_coord+l > PIXELS_PER_ROW)
|
|
l = PIXELS_PER_ROW - x_coord + 1; // reset width to end of row
|
|
|
|
/* LED Brightness Compensation */
|
|
#ifndef NO_CIE1931
|
|
red = lumConvTab[red];
|
|
green = lumConvTab[green];
|
|
blue = lumConvTab[blue];
|
|
#endif
|
|
|
|
uint16_t _colorbitclear = BITMASK_RGB1_CLEAR, _colorbitoffset = 0;
|
|
|
|
if (y_coord >= ROWS_PER_FRAME){ // if we are drawing to the bottom part of the panel
|
|
_colorbitoffset = BITS_RGB2_OFFSET;
|
|
_colorbitclear = BITMASK_RGB2_CLEAR;
|
|
y_coord -= ROWS_PER_FRAME;
|
|
}
|
|
|
|
// Iterating through color depth bits (8 iterations)
|
|
uint8_t color_depth_idx = PIXEL_COLOR_DEPTH_BITS;
|
|
do {
|
|
--color_depth_idx;
|
|
|
|
// let's precalculate RGB1 and RGB2 bits than flood it over the entire DMA buffer
|
|
uint16_t RGB_output_bits = 0;
|
|
uint8_t mask = (1 << color_depth_idx COLOR_DEPTH_LESS_THAN_8BIT_ADJUST);
|
|
|
|
/* Per the .h file, the order of the output RGB bits is:
|
|
* BIT_B2, BIT_G2, BIT_R2, BIT_B1, BIT_G1, BIT_R1 */
|
|
RGB_output_bits |= (bool)(blue & mask); // --B
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(green & mask); // -BG
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(red & mask); // BGR
|
|
RGB_output_bits <<= _colorbitoffset; // shift color bits to the required position
|
|
|
|
// Get the contents at this address,
|
|
// it would represent a vector pointing to the full row of pixels for the specified color depth bit at Y coordinate
|
|
ESP32_I2S_DMA_STORAGE_TYPE *p = dma_buff.rowBits[y_coord]->getDataPtr(color_depth_idx, back_buffer_id);
|
|
// inlined version works slower here, dunno why :(
|
|
// ESP32_I2S_DMA_STORAGE_TYPE *p = getRowDataPtr(y_coord, color_depth_idx, back_buffer_id);
|
|
|
|
int16_t _l = l;
|
|
do { // iterate pixels in a row
|
|
int16_t _x = x_coord + --_l;
|
|
// Save the calculated value to the bitplane memory in reverse order to account for I2S Tx FIFO mode1 ordering
|
|
uint16_t &v = p[_x & 1U ? --_x : ++_x];
|
|
|
|
v &= _colorbitclear; // reset color bits
|
|
v |= RGB_output_bits; // set new color bits
|
|
} while(_l); // iterate pixels in a row
|
|
} while(color_depth_idx); // end of color depth loop (8)
|
|
} // hlineDMA()
|
|
|
|
|
|
/**
|
|
* @brief - update DMA buff drawing vertical line at specified coordinates
|
|
* @param x_ccord - line start coordinate x
|
|
* @param y_ccord - line start coordinate y
|
|
* @param l - line length
|
|
* @param r,g,b, - RGB888 color
|
|
*/
|
|
void MatrixPanel_I2S_DMA::vlineDMA(int16_t x_coord, int16_t y_coord, int16_t l, uint8_t red, uint8_t green, uint8_t blue){
|
|
if ( !initialized )
|
|
return;
|
|
|
|
if ( x_coord < 0 || y_coord < 0 || l < 1 || x_coord >= PIXELS_PER_ROW || y_coord >= m_cfg.mx_height)
|
|
return;
|
|
|
|
if (y_coord + l > m_cfg.mx_height)
|
|
l = m_cfg.mx_height - y_coord + 1; // reset width to end of col
|
|
|
|
/* LED Brightness Compensation */
|
|
#ifndef NO_CIE1931
|
|
red = lumConvTab[red];
|
|
green = lumConvTab[green];
|
|
blue = lumConvTab[blue];
|
|
#endif
|
|
|
|
// Save the calculated value to the bitplane memory in reverse order to account for I2S Tx FIFO mode1 ordering
|
|
x_coord & 1U ? --x_coord : ++x_coord;
|
|
|
|
uint8_t color_depth_idx = PIXEL_COLOR_DEPTH_BITS;
|
|
do { // Iterating through color depth bits (8 iterations)
|
|
--color_depth_idx;
|
|
|
|
// let's precalculate RGB1 and RGB2 bits than flood it over the entire DMA buffer
|
|
uint8_t mask = (1 << color_depth_idx COLOR_DEPTH_LESS_THAN_8BIT_ADJUST);
|
|
uint16_t RGB_output_bits = 0;
|
|
|
|
/* Per the .h file, the order of the output RGB bits is:
|
|
* BIT_B2, BIT_G2, BIT_R2, BIT_B1, BIT_G1, BIT_R1 */
|
|
RGB_output_bits |= (bool)(blue & mask); // --B
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(green & mask); // -BG
|
|
RGB_output_bits <<= 1;
|
|
RGB_output_bits |= (bool)(red & mask); // BGR
|
|
|
|
int16_t _l = 0, _y = y_coord;
|
|
uint16_t _colorbitclear = BITMASK_RGB1_CLEAR;
|
|
do { // iterate pixels in a column
|
|
|
|
if (_y >= ROWS_PER_FRAME){ // if y-coord overlaped bottom-half panel
|
|
_y -= ROWS_PER_FRAME;
|
|
_colorbitclear = BITMASK_RGB2_CLEAR;
|
|
RGB_output_bits <<= BITS_RGB2_OFFSET;
|
|
}
|
|
|
|
// Get the contents at this address,
|
|
// it would represent a vector pointing to the full row of pixels for the specified color depth bit at Y coordinate
|
|
ESP32_I2S_DMA_STORAGE_TYPE *p = getRowDataPtr(_y, color_depth_idx, back_buffer_id);
|
|
|
|
p[x_coord] &= _colorbitclear; // reset RGB bits
|
|
p[x_coord] |= RGB_output_bits; // set new RGB bits
|
|
++_y;
|
|
} while(++_l!=l); // iterate pixels in a col
|
|
} while(color_depth_idx); // end of color depth loop (8)
|
|
} // vlineDMA()
|
|
|
|
|
|
/**
|
|
* @brief - update DMA buff drawing a rectangular at specified coordinates
|
|
* this works much faster than mulltiple consecutive per-pixel calls to updateMatrixDMABuffer()
|
|
* @param int16_t x, int16_t y - coordinates of a top-left corner
|
|
* @param int16_t w, int16_t h - width and height of a rectangular, min is 1 px
|
|
* @param uint8_t r - RGB888 color
|
|
* @param uint8_t g - RGB888 color
|
|
* @param uint8_t b - RGB888 color
|
|
*/
|
|
void MatrixPanel_I2S_DMA::fillRectDMA(int16_t x, int16_t y, int16_t w, int16_t h, uint8_t r, uint8_t g, uint8_t b){
|
|
|
|
// h-lines are >2 times faster than v-lines
|
|
// so will use it only for tall rects with h >2w
|
|
if (h>2*w){
|
|
// draw using v-lines
|
|
do {
|
|
--w;
|
|
vlineDMA(x+w, y, h, r,g,b);
|
|
} while(w);
|
|
} else {
|
|
// draw using h-lines
|
|
do {
|
|
--h;
|
|
hlineDMA(x, y+h, w, r,g,b);
|
|
} while(h);
|
|
}
|
|
}
|
|
|
|
#endif // NO_FAST_FUNCTIONS
|