186 lines
7.0 KiB
Plaintext
186 lines
7.0 KiB
Plaintext
// Arduino "bridge" code between host computer and WS2801-based digital
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// RGB LED pixels (e.g. Adafruit product ID #322). Intended for use
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// with USB-native boards such as Teensy or Adafruit 32u4 Breakout;
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// works on normal serial Arduinos, but throughput is severely limited.
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// LED data is streamed, not buffered, making this suitable for larger
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// installations (e.g. video wall, etc.) than could otherwise be held
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// in the Arduino's limited RAM.
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// Some effort is put into avoiding buffer underruns (where the output
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// side becomes starved of data). The WS2801 latch protocol, being
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// delay-based, could be inadvertently triggered if the USB bus or CPU
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// is swamped with other tasks. This code buffers incoming serial data
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// and introduces intentional pauses if there's a threat of the buffer
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// draining prematurely. The cost of this complexity is somewhat
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// reduced throughput, the gain is that most visual glitches are
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// avoided (though ultimately a function of the load on the USB bus and
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// host CPU, and out of our control).
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// LED data and clock lines are connected to the Arduino's SPI output.
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// On traditional Arduino boards, SPI data out is digital pin 11 and
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// clock is digital pin 13. On both Teensy and the 32u4 Breakout,
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// data out is pin B2, clock is B1. LEDs should be externally
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// powered -- trying to run any more than just a few off the Arduino's
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// 5V line is generally a Bad Idea. LED ground should also be
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// connected to Arduino ground.
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#include <SPI.h>
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// LED pin for Adafruit 32u4 Breakout Board:
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//#define LED_DDR DDRE
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//#define LED_PORT PORTE
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//#define LED_PIN _BV(PORTE6)
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// LED pin for Teensy:
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//#define LED_DDR DDRD
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//#define LED_PORT PORTD
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//#define LED_PIN _BV(PORTD6)
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// LED pin for Arduino:
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#define LED_DDR DDRB
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#define LED_PORT PORTB
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#define LED_PIN _BV(PORTB5)
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// A 'magic word' (along with LED count & checksum) precedes each block
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// of LED data; this assists the microcontroller in syncing up with the
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// host-side software and properly issuing the latch (host I/O is
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// likely buffered, making usleep() unreliable for latch). You may see
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// an initial glitchy frame or two until the two come into alignment.
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// The magic word can be whatever sequence you like, but each character
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// should be unique, and frequent pixel values like 0 and 255 are
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// avoided -- fewer false positives. The host software will need to
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// generate a compatible header: immediately following the magic word
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// are three bytes: a 16-bit count of the number of LEDs (high byte
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// first) followed by a simple checksum value (high byte XOR low byte
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// XOR 0x55). LED data follows, 3 bytes per LED, in order R, G, B,
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// where 0 = off and 255 = max brightness.
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static const uint8_t magic[] = {'A','d','a'};
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#define MAGICSIZE sizeof(magic)
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#define HEADERSIZE (MAGICSIZE + 3)
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#define MODE_HEADER 0
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#define MODE_HOLD 1
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#define MODE_DATA 2
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void setup()
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{
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// Dirty trick: the circular buffer for serial data is 256 bytes,
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// and the "in" and "out" indices are unsigned 8-bit types -- this
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// much simplifies the cases where in/out need to "wrap around" the
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// beginning/end of the buffer. Otherwise there'd be a ton of bit-
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// masking and/or conditional code every time one of these indices
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// needs to change, slowing things down tremendously.
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uint8_t
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buffer[256],
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indexIn = 0,
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indexOut = 0,
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mode = MODE_HEADER,
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hi, lo, chk, i, spiFlag;
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int16_t
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bytesBuffered = 0,
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c;
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int32_t
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bytesRemaining;
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unsigned long
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t = 0;
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LED_DDR |= LED_PIN; // Enable output for LED
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LED_PORT &= ~LED_PIN; // LED off
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Serial.begin(115200); // Teensy/32u4 disregards baud rate; is OK!
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SPI.begin();
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SPI.setBitOrder(MSBFIRST);
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SPI.setDataMode(SPI_MODE0);
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SPI.setClockDivider(SPI_CLOCK_DIV8); // 2 MHz
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// WS2801 datasheet recommends max SPI clock of 2 MHz, and 50 Ohm
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// resistors on SPI lines for impedance matching. In practice and
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// at short distances, 2 MHz seemed to work reliably enough without
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// resistors, and 4 MHz was possible with a 220 Ohm resistor on the
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// SPI clock line only. Your mileage may vary. Experiment!
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// SPI.setClockDivider(SPI_CLOCK_DIV4); // 4 MHz
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// loop() is avoided as even that small bit of function overhead
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// has a measurable impact on this code's overall throughput.
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for(;;) {
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// Implementation is a simple finite-state machine.
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// Regardless of mode, check for serial input each time:
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if((bytesBuffered < 256) && ((c = Serial.read()) >= 0)) {
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buffer[indexIn++] = c;
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bytesBuffered++;
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}
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switch(mode) {
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case MODE_HEADER:
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// In header-seeking mode. Is there enough data to check?
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if(bytesBuffered >= HEADERSIZE) {
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// Indeed. Check for a 'magic word' match.
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for(i=0; (i<MAGICSIZE) && (buffer[indexOut++] == magic[i++]););
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if(i == MAGICSIZE) {
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// Magic word matches. Now how about the checksum?
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hi = buffer[indexOut++];
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lo = buffer[indexOut++];
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chk = buffer[indexOut++];
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if(chk == (hi ^ lo ^ 0x55)) {
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// Checksum looks valid. Get 16-bit LED count, add 1
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// (# LEDs is always > 0) and multiply by 3 for R,G,B.
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bytesRemaining = 3L * (256L * (long)hi + (long)lo + 1L);
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bytesBuffered -= 3;
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mode = MODE_HOLD; // Proceed to latch wait mode
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spiFlag = 0; // No data out yet
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} else {
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// Checksum didn't match; search resumes after magic word.
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indexOut -= 3; // Rewind
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}
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} // else no header match. Resume at first mismatched byte.
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bytesBuffered -= i;
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}
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break;
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case MODE_HOLD:
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// Ostensibly "waiting for the latch from the prior frame
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// to complete" mode, but may also revert to this mode when
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// underrun prevention necessitates a delay.
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if(micros() < t) break; // Still holding; continue buffering.
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// Latch/delay complete. Advance to data-issuing mode...
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LED_PORT &= ~LED_PIN; // LED off
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mode = MODE_DATA; // ...and fall through (no break):
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case MODE_DATA:
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while(spiFlag && !(SPSR & _BV(SPIF))); // Wait for prior byte
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if(bytesRemaining > 0) {
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if(bytesBuffered > 0) {
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SPDR = buffer[indexOut++]; // Issue next byte
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bytesBuffered--;
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bytesRemaining--;
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spiFlag = 1;
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}
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// If serial buffer is threatening to underrun, start
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// introducing progressively longer pauses to allow more
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// data to arrive (up to a point).
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if((bytesBuffered < 32) && (bytesRemaining > bytesBuffered)) {
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mode = MODE_HOLD;
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t = micros() + 60 + (32 - bytesBuffered) * 20;
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}
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} else {
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// End of data -- issue latch:
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t = micros() + 1000; // Latch duration = 1000 uS
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LED_PORT |= LED_PIN; // LED on
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mode = MODE_HEADER; // Begin next header search
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}
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} // end switch
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} // end for(;;)
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}
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void loop()
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{
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// Not used. See note in setup() function.
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}
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