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hub75_BCM.c
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hub75_BCM.c
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/*****************************************************
*
* LED matrix driver for Raspberry RP2040
* (c) Peter Schulten, Mülheim, Germany
* peter_(at)_pitschu.de
*
* Unmodified reproduction and distribution of this entire
* source code in any form is permitted provided the above
* notice is preserved.
* I make this source code available free of charge and therefore
* offer neither support nor guarantee for its functionality.
* Furthermore, I assume no liability for the consequences of
* its use.
* The source code may only be used and modified for private,
* non-commercial purposes. Any further use requires my consent.
*
* History
* 25.01.2022 pitschu Start of work
*/
#include <stdio.h>
#include <string.h>
#include "stdint.h"
#include "stdlib.h"
#include "FreeRTOS.h"
#include "task.h"
#include "pico/stdlib.h"
#include "hardware/dma.h"
#include "hardware/irq.h"
#include "ps_debug.h"
#include "hub75.h"
uint32_t frameBuffer[DISPLAY_MAXPLANES * DISPLAY_WIDTH_SCAN * DISPLAY_SCAN]; // each entry contains RGB data for 2 or 4 consecutive pixels on one HUB75 channel
rgb_t* addrBuffer[(1<<DISPLAY_MAXPLANES)];
uint16_t bcmCounter = 1; // index in addrBuffer array
uint32_t ctrlBuffer[DISPLAY_MAXPLANES * DISPLAY_SCAN]; // N bit planes * # of scan lines
uint16_t masterBrightness = 0;
uint16_t bitPlanes = DISPLAY_MAXPLANES;
static PIO display_pio = pio0;
static uint display_sm_data;
static uint display_offset_data;
static uint display_sm_ctrl;
static uint display_offset_ctrl;
static int display_dma_chan;
static int ctrl_dma_chan;
static rgb_t overlayColors[16];
static uint8_t srgb_lut[256];
static void dma_hub75_handler()
{
// Clear the interrupt request.
if (dma_hw->ints0 & (1u << display_dma_chan))
{
dma_hw->ints0 = 1u << display_dma_chan;
// start next display cycle
dma_channel_set_read_addr(display_dma_chan, addrBuffer[bcmCounter], true);
if (++bcmCounter >= (1 << bitPlanes))
{
gpio_xor_mask(1<<15); // debug LED for frame time measurement
bcmCounter = 1;
}
}
if (dma_hw->ints0 & (1u << ctrl_dma_chan))
{
dma_hw->ints0 = 1u << ctrl_dma_chan;
// start next display cycle
dma_channel_set_read_addr(ctrl_dma_chan, &ctrlBuffer[0], true);
}
}
static void hub75_init()
{
// Initialize PIO
display_sm_data = pio_claim_unused_sm(display_pio, true);
display_sm_ctrl = pio_claim_unused_sm(display_pio, true);
for (int i=0; i<256; ++i) {
float k = (float)i * (1.0f / 255);
srgb_lut[i] = (uint8_t)lround(255 * k * k);
}
#ifdef PCB_LAYOUT_V1
display_offset_data = pio_add_program(display_pio, &ps_64_data_program);
ps_64_data_program_init(
display_pio,
display_sm_data,
display_offset_data,
PIO_DATA_OUT_BASE, PIO_DATA_OUT_CNT,
PIO_DATA_SET_BASE, PIO_DATA_SET_CNT,
PIO_DATA_SIDE_BASE, PIO_DATA_SIDE_CNT
);
display_offset_ctrl = pio_add_program(display_pio, &ps_64_ctrl_program);
ps_64_ctrl_program_init(
display_pio,
display_sm_ctrl,
display_offset_ctrl,
PIO_CTRL_OUT_BASE, PIO_CTRL_OUT_CNT,
PIO_CTRL_SET_BASE, PIO_CTRL_SET_CNT,
PIO_CTRL_SIDE_BASE, PIO_CTRL_SIDE_CNT
);
#endif
#ifdef PCB_LAYOUT_V2
#if HUB75_SIZE == 4040
display_offset_data = pio_add_program(display_pio, &ps_64_data2_program);
ps_64_data_program_init(
display_pio,
display_sm_data,
display_offset_data,
PIO_DATA_OUT_BASE, PIO_DATA_OUT_CNT,
PIO_DATA_SET_BASE, PIO_DATA_SET_CNT,
PIO_DATA_SIDE_BASE, PIO_DATA_SIDE_CNT
);
display_offset_ctrl = pio_add_program(display_pio, &ps_64_ctrl_program);
ps_64_ctrl_program_init(
display_pio,
display_sm_ctrl,
display_offset_ctrl,
PIO_CTRL_OUT_BASE, PIO_CTRL_OUT_CNT,
PIO_CTRL_SET_BASE, PIO_CTRL_SET_CNT,
PIO_CTRL_SIDE_BASE, PIO_CTRL_SIDE_CNT
);
#elif HUB75_SIZE == 8040
display_offset_data = pio_add_program(display_pio, &ps_128_data2_program);
ps_128_data2_program_init(
display_pio,
display_sm_data,
display_offset_data,
PIO_DATA_OUT_BASE, PIO_DATA_OUT_CNT,
PIO_DATA_SET_BASE, PIO_DATA_SET_CNT,
PIO_DATA_SIDE_BASE, PIO_DATA_SIDE_CNT
);
display_offset_ctrl = pio_add_program(display_pio, &ps_128_ctrl_program);
ps_128_ctrl_program_init(
display_pio,
display_sm_ctrl,
display_offset_ctrl,
PIO_CTRL_OUT_BASE, PIO_CTRL_OUT_CNT,
PIO_CTRL_SET_BASE, PIO_CTRL_SET_CNT,
PIO_CTRL_SIDE_BASE, PIO_CTRL_SIDE_CNT
);
#else
display_offset_data = pio_add_program(display_pio, &ps_128_data2_program);
ps_128_data2_program_init(
display_pio,
display_sm_data,
display_offset_data,
PIO_DATA_OUT_BASE, PIO_DATA_OUT_CNT,
PIO_DATA_SET_BASE, PIO_DATA_SET_CNT,
PIO_DATA_SIDE_BASE, PIO_DATA_SIDE_CNT
);
display_offset_ctrl = pio_add_program(display_pio, &ps_128_ctrl_program);
ps_128_ctrl_program_init(
display_pio,
display_sm_ctrl,
display_offset_ctrl,
PIO_CTRL_OUT_BASE, PIO_CTRL_OUT_CNT,
PIO_CTRL_SET_BASE, PIO_CTRL_SET_CNT,
PIO_CTRL_SIDE_BASE, PIO_CTRL_SIDE_CNT
);
#endif
#endif
// Initialize data port DMA
display_dma_chan = dma_claim_unused_channel(true);
dma_channel_config c = dma_channel_get_default_config(display_dma_chan);
channel_config_set_transfer_data_size(&c, DMA_SIZE_32);
channel_config_set_read_increment(&c, true);
channel_config_set_write_increment(&c, false);
channel_config_set_dreq(&c, DREQ_PIO0_TX0 + display_sm_data);
// channel_config_set_ring(&c, false, 15); // ring size is 8192
dma_channel_configure(
display_dma_chan,
&c,
&pio0_hw->txf[display_sm_data],
NULL, // Will be set later for each transfer
DISPLAY_SCAN * DISPLAY_WIDTH_SCAN, // complete frame buffer for 1 bit plane
false
);
dma_channel_set_irq0_enabled(display_dma_chan, true);
// Initialize control port DMA
ctrl_dma_chan = dma_claim_unused_channel(true);
c = dma_channel_get_default_config(ctrl_dma_chan);
channel_config_set_transfer_data_size(&c, DMA_SIZE_32);
channel_config_set_read_increment(&c, true);
channel_config_set_write_increment(&c, false);
channel_config_set_dreq(&c, DREQ_PIO0_TX0 + display_sm_ctrl);
dma_channel_configure(
ctrl_dma_chan,
&c,
&pio0_hw->txf[display_sm_ctrl],
NULL, // Will be set later for each transfer
DISPLAY_SCAN, // complete frame buffer for 1 bit plane
false
);
dma_channel_set_irq0_enabled(ctrl_dma_chan, true);
irq_set_exclusive_handler(DMA_IRQ_0, dma_hub75_handler);
irq_set_priority(DMA_IRQ_0, 1);
irq_set_enabled(DMA_IRQ_0, true);
}
static void hub75_start()
{
dma_channel_set_read_addr(display_dma_chan, frameBuffer, true);
dma_channel_set_read_addr(ctrl_dma_chan, ctrlBuffer, true);
}
void hub75_config(int bpp)
{
if (bpp < 4) bpp = 4;
if (bpp > 8) bpp = 8;
bitPlanes = bpp;
irq_set_enabled(DMA_IRQ_0, false); // stop interrupts on DMA channels
gpio_init(DISPLAY_OENPIN); // switch display OFF
gpio_set_dir(DISPLAY_OENPIN, GPIO_OUT);
gpio_put(DISPLAY_OENPIN, 1);
if (pio_sm_is_claimed(display_pio, display_sm_ctrl))
{
pio_sm_set_enabled(display_pio, display_sm_ctrl, false);
pio_sm_init(display_pio, display_sm_ctrl, 0, NULL);
pio_sm_unclaim(display_pio, display_sm_ctrl);
}
if (pio_sm_is_claimed(display_pio, display_sm_data))
{
pio_sm_set_enabled(display_pio, display_sm_data, false);
pio_sm_init(display_pio, display_sm_data, 0, NULL);
pio_sm_unclaim(display_pio, display_sm_data);
}
pio_clear_instruction_memory(display_pio);
if (dma_channel_is_claimed(display_dma_chan))
{
dma_channel_abort(display_dma_chan);
dma_channel_config c = dma_channel_get_default_config(display_dma_chan);
channel_config_set_enable(&c, false);
dma_channel_set_config(display_dma_chan, &c, false);
dma_channel_unclaim(display_dma_chan);
}
if (dma_channel_is_claimed(ctrl_dma_chan))
{
dma_channel_abort(ctrl_dma_chan);
dma_channel_config c = dma_channel_get_default_config(ctrl_dma_chan);
channel_config_set_enable(&c, false);
dma_channel_set_config(ctrl_dma_chan, &c, false);
dma_channel_unclaim(ctrl_dma_chan);
}
irq_remove_handler(DMA_IRQ_0, dma_hub75_handler);
memset(frameBuffer, 0, bitPlanes * (DISPLAY_WIDTH_SCAN * DISPLAY_SCAN * sizeof(uint32_t)));
memset(ctrlBuffer, 0, bitPlanes * DISPLAY_SCAN * sizeof(uint32_t));
memset(addrBuffer, 0, (1<<bitPlanes) * sizeof(uint32_t*));
for (int bPos = 0; bPos < bitPlanes; bPos++)
{
for (int i = 1; i < (1<<bitPlanes); i++)
{
if (i & (1 << bPos) && (addrBuffer[i] == 0))
{
LOG_DEBUG("addrBuffer[%3d] = plane %d\n", i, (bitPlanes - bPos));
addrBuffer[i] = &frameBuffer[(bitPlanes - 1 - bPos) * (DISPLAY_WIDTH_SCAN * DISPLAY_SCAN)];
}
}
}
hub75_init();
hub75_start();
}
void hub75_set_masterbrightness(int brt)
{
brt += 4; // OE will be always HIGH during the last 4 pixels
if (brt < 4) brt = 4;
if (brt > (DISPLAY_WIDTH - 1)) brt = (DISPLAY_WIDTH - 1);
masterBrightness = brt;
}
void hub75_set_overlaycolor(int index, rgb_t color)
{
if (index < 1 || index > 15) // index 0 is used internally for 'no overlay'
return;
overlayColors[index] = color;
}
rgb_t srgb_remap(rgb_t color) {
rgbV_t r;
r.value = color;
r.c.R = srgb_lut[r.c.R];
r.c.G = srgb_lut[r.c.G];
r.c.B = srgb_lut[r.c.B];
return r.value;
}
#if HUB75_SIZE == 4040 || HUB75_SIZE == 8040
int hub75_update(rgb_t *image, uint8_t *overlay)
{
int x, y, b, plane;
rgb_t* ip;
rgb_t* fp, * cp;
uint8_t flag = 0;
uint8_t brtCnt = 0;
for (b = (8 - bitPlanes); b < 8; b++) // only MSB bits of RGB color
{
ip = image;
fp = &frameBuffer[(b - (8 - bitPlanes)) * (DISPLAY_SCAN * DISPLAY_WIDTH_SCAN)];
cp = &ctrlBuffer[(b - (8 - bitPlanes)) * DISPLAY_SCAN];
for (y = 0; y < DISPLAY_SCAN; y++)
{
rgb_t* ip_uu = image + (y * DISPLAY_WIDTH);
rgb_t* ip_lu = image + ((y + DISPLAY_SCAN) * DISPLAY_WIDTH);
uint8_t* op_uu = overlay + (y * DISPLAY_WIDTH);
uint8_t* op_lu = overlay + ((y + DISPLAY_SCAN) * DISPLAY_WIDTH);
brtCnt = 0;
for (x = 0; x < DISPLAY_WIDTH_SCAN; x++) // 4 pixels per framebuffer word
{
rgb_t ipu, ipl;
ipu = *ip_uu++;
ipl = *ip_lu++;
if (*op_uu != 0)
ipu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0)
ipl = overlayColors[*op_lu];
op_lu++;
rgb_t img = (((ipu & (1 << b)) >> b) << 2 |
(((ipu >> 8) & (1 << b)) >> b) << 1 |
((ipu >> 16) & (1 << b)) >> b) |
((((ipl & (1 << b)) >> b) << 2 |
(((ipl >> 8) & (1 << b)) >> b) << 1 |
(((ipl >> 16) & (1 << b))) >> b) << 3);
if (++brtCnt > masterBrightness)
img |= (1 << 7);
ipu = *ip_uu++;
ipl = *ip_lu++;
if (*op_uu != 0)
ipu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0)
ipl = overlayColors[*op_lu];
op_lu++;
img |= ((((ipu & (1 << b)) >> b) << 2 |
(((ipu >> 8) & (1 << b)) >> b) << 1 |
((ipu >> 16) & (1 << b)) >> b) |
((((ipl & (1 << b)) >> b) << 2 |
(((ipl >> 8) & (1 << b)) >> b) << 1 |
(((ipl >> 16) & (1 << b))) >> b) << 3)) << 8;
if (++brtCnt > masterBrightness)
img |= (1 << 15);
ipu = *ip_uu++;
ipl = *ip_lu++;
if (*op_uu != 0)
ipu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0)
ipl = overlayColors[*op_lu];
op_lu++;
img |= ((((ipu & (1 << b)) >> b) << 2 |
(((ipu >> 8) & (1 << b)) >> b) << 1 |
((ipu >> 16) & (1 << b)) >> b) |
((((ipl & (1 << b)) >> b) << 2 |
(((ipl >> 8) & (1 << b)) >> b) << 1 |
(((ipl >> 16) & (1 << b))) >> b) << 3)) << 16;
if (++brtCnt > masterBrightness)
img |= (1 << 23);
ipu = *ip_uu++;
ipl = *ip_lu++;
if (*op_uu != 0)
ipu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0)
ipl = overlayColors[*op_lu];
op_lu++;
img |= ((((ipu & (1 << b)) >> b) << 2 |
(((ipu >> 8) & (1 << b)) >> b) << 1 |
((ipu >> 16) & (1 << b)) >> b) |
((((ipl & (1 << b)) >> b) << 2 |
(((ipl >> 8) & (1 << b)) >> b) << 1 |
(((ipl >> 16) & (1 << b))) >> b) << 3)) << 24;
if (++brtCnt > masterBrightness)
img |= (1 << 31);
*fp++ = img;
}
uint32_t ctrl = ((y) & 0x1F); // ADDR lines: bits 0..4
*cp++ = ctrl;
}
}
return 0;
}
#elif HUB75_SIZE == 8080
int hub75_update(rgb_t* image, uint8_t* overlay)
{
int x, y, b, plane;
rgb_t* ip;
uint32_t* fp, * cp;
uint8_t flag = 0;
uint8_t brtCnt = 0;
for (b = (8 - bitPlanes); b < 8; b++) // only MSB bits of RGB color
{
ip = image;
fp = &frameBuffer[(b - (8 - bitPlanes)) * DISPLAY_SCAN * (DISPLAY_WIDTH / 2)];
cp = &ctrlBuffer[(b - (8 - bitPlanes)) * DISPLAY_SCAN];
for (y = 0; y < DISPLAY_SCAN; y++)
{
rgb_t* ip_uu = image + (y * DISPLAY_WIDTH);
rgb_t* ip_lu = image + ((y + DISPLAY_SCAN) * DISPLAY_WIDTH);
rgb_t* ip_ul = image + ((y + DISPLAY_HEIGHT/2) * DISPLAY_WIDTH);
rgb_t* ip_ll = image + (((y + DISPLAY_HEIGHT / 2) + DISPLAY_SCAN) * DISPLAY_WIDTH);
uint8_t* op_uu = overlay + (y * DISPLAY_WIDTH);
uint8_t* op_lu = overlay + ((y + DISPLAY_SCAN) * DISPLAY_WIDTH);
uint8_t* op_ul = overlay + ((y + DISPLAY_HEIGHT / 2) * DISPLAY_WIDTH);
uint8_t* op_ll = overlay + (((y + DISPLAY_HEIGHT / 2) + DISPLAY_SCAN) * DISPLAY_WIDTH);
brtCnt = 0;
for (x = 0; x < DISPLAY_WIDTH / 2; x++) // 4 pixels per framebuffer word
{
rgb_t ipuu = *ip_uu++;
rgb_t iplu = *ip_lu++;
rgb_t ipul = *ip_ul++;
rgb_t ipll = *ip_ll++;
if (*op_uu != 0) ipuu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0) iplu = overlayColors[*op_lu];
op_lu++;
if (*op_ul != 0) ipul = overlayColors[*op_ul];
op_ul++;
if (*op_ll != 0) ipll = overlayColors[*op_ll];
op_ll++;
rgb_t img = (((ipuu & (1 << b)) >> b) << 2 |
(((ipuu >> 8) & (1 << b)) >> b) << 1 |
((ipuu >> 16) & (1 << b)) >> b) |
((((iplu & (1 << b)) >> b) << 2 |
(((iplu >> 8) & (1 << b)) >> b) << 1 |
(((iplu >> 16) & (1 << b))) >> b) << 3) |
((((ipul & (1 << b)) >> b) << 2 |
(((ipul >> 8) & (1 << b)) >> b) << 1 |
(((ipul >> 16) & (1 << b))) >> b) << 6) |
((((ipll & (1 << b)) >> b) << 2 |
(((ipll >> 8) & (1 << b)) >> b) << 1 |
(((ipll >> 16) & (1 << b))) >> b) << 9);
if (++brtCnt > masterBrightness) img |= (1 << 12);
ipuu = *ip_uu++;
iplu = *ip_lu++;
ipul = *ip_ul++;
ipll = *ip_ll++;
if (*op_uu != 0) ipuu = overlayColors[*op_uu];
op_uu++;
if (*op_lu != 0) iplu = overlayColors[*op_lu];
op_lu++;
if (*op_ul != 0) ipul = overlayColors[*op_ul];
op_ul++;
if (*op_ll != 0) ipll = overlayColors[*op_ll];
op_ll++;
img |= ((((ipuu & (1 << b)) >> b) << 2 |
(((ipuu >> 8) & (1 << b)) >> b) << 1 |
((ipuu >> 16) & (1 << b)) >> b) |
((((iplu & (1 << b)) >> b) << 2 |
(((iplu >> 8) & (1 << b)) >> b) << 1 |
(((iplu >> 16) & (1 << b))) >> b) << 3) |
((((ipul & (1 << b)) >> b) << 2 |
(((ipul >> 8) & (1 << b)) >> b) << 1 |
(((ipul >> 16) & (1 << b))) >> b) << 6) |
((((ipll & (1 << b)) >> b) << 2 |
(((ipll >> 8) & (1 << b)) >> b) << 1 |
(((ipll >> 16) & (1 << b))) >> b) << 9)) << 16;
if (++brtCnt > masterBrightness) img |= (1 << (16+12));
*fp++ = img;
}
uint32_t ctrl = ((y) & 0x1F); // ADDR lines: bits 0..4
*cp++ = ctrl;
}
}
return 0;
}
#endif