Multi_WS2811_test - Test program for my Multi_WS2811 library that sta…

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Ned Konz / Mbed 2 deprecated Multi_WS2811_test

Test program for my Multi_WS2811 library that started out as a fork of heroic/WS2811. My library uses hardware DMA on the FRDM-KL25Z to drive up to 16 strings of WS2811 or WS2812 LEDs in parallel.

Dependencies: Multi_WS2811 mbed MMA8451Q

Fork of WS2811 by Heroic Robotics

NOTE: I have accidentally pushed changes for another fork of this program that I used in the recent Georgetown Carnival Power Tool Races. When I get some time, I will restore the test program to its original glory.

You can see my power tool racer (Nevermore's Revenge) here

/media/uploads/bikeNomad/img_0482.jpg

This tests my FRDM-KL25Z multi-string WS2811/WS2812 library. It uses the accelerometer to change the rainbow phase on two strings of LEDs as well as the touch sense to change brightness.

A video of this program in operation is here.

Here is the library that I developed to run the LEDs:

Import library Multi_WS2811

Library allowing up to 16 strings of 60 WS2811 or WS2812 LEDs to be driven from a single FRDM-KL25Z board. Uses hardware DMA to do a full 800 KHz rate without much CPU burden.

WS2801.cpp

Committer:: heroic
Date:: 2012-10-12
Revision:: 7:3025f0e0d70a
Parent:: 6:7aebe547f0f0

File content as of revision 7:3025f0e0d70a:

// Mbed library to control LPD8806-based RGB LED Strips
// (c) 2011 Jelmer Tiete
// This library is ported from the Arduino implementation of Adafruit Industries
// found at: http://github.com/adafruit/LPD8806
// and their strips: http://www.adafruit.com/products/306
// Released under the MIT License: http://mbed.org/license/mit
//
// Parameterized and modified to use soft SPI.
// Jas Strong <jasmine@electronpusher.org>
/*****************************************************************************/

#include "LedStrip.h"
#include "WS2801.h"

WS2801::WS2801(PinName dataPin, PinName clockPin, int n) :
    dat(dataPin),
    clk(clockPin) {
    // Allocate 3 bytes per pixel:
    numLEDs = n;
    if ((pixels = (uint8_t *)malloc(numLEDs * 3))) {
        memset(pixels, 0x00, numLEDs * 3); // Init to RGB 'off' state
    }
    guardtime.start();
}

/*
 *  Soft SPI clock-out implementation (CPOL = 0, CPHA = 0).
 *  Certainly not the fastest in the world but it'll do.
 *  Gets about 3.6 MHz;  could get several times as much
 *  using the bitbands directly  - jas.
 */
 
void WS2801::write(uint8_t byte) {
    for (int i=0; i<8; i++) {
        clk = 0;
        wait_us(WS2801_DELAY);
        dat = (byte & 0x80);
        clk = 1;
        wait_us(WS2801_DELAY);
        byte <<= 1;
    }
    clk = 0;
}

void WS2801::begin(void) {
    blank();
    show();
}

uint16_t WS2801::numPixels(void) {
    return numLEDs;
}

void WS2801::blank(void) {
    memset(pixels, 0x00, numLEDs * 3);
}

// This is how data is pushed to the strip.  Unfortunately, the company
// that makes the chip didnt release the  protocol document or you need
// to sign an NDA or something stupid like that, but we reverse engineered
// this from a strip controller and it seems to work very nicely!
void WS2801::show(void) {
    uint16_t i, nl3 = numLEDs * 3; // 3 bytes per LED
    while (guardtime.read_us() < 500)
        /* spin */;
    for (i=0; i<nl3; i++ ) {
        write(pixels[i]);
    }

    guardtime.reset();
}


uint32_t WS2801::total_luminance(void) {
    uint32_t running_total;
    running_total = 0;
    for (int i=0; i<numLEDs*3; i++)
        running_total += pixels[i];
    return running_total;
}

// Convert R,G,B to combined 32-bit color
uint32_t WS2801::Color(uint8_t r, uint8_t g, uint8_t b) {
    // Take the lowest 7 bits of each value and append them end to end
    // We have the top bit set high (its a 'parity-like' bit in the protocol
    // and must be set!)
    return ((uint32_t)g << 16) | ((uint32_t)r << 8) | (uint32_t)b;
}

// store the rgb component in our array
void WS2801::setPixelColor(uint16_t n, uint8_t r, uint8_t g, uint8_t b) {
    if (n >= numLEDs) return; // '>=' because arrays are 0-indexed

    pixels[n*3  ] = g;
    pixels[n*3+1] = r;
    pixels[n*3+2] = b;
}

void WS2801::setPixelR(uint16_t n, uint8_t r) {
    if (n >= numLEDs) return; // '>=' because arrays are 0-indexed

    pixels[n*3+1] = r;
}

void WS2801::setPixelG(uint16_t n, uint8_t g) {
    if (n >= numLEDs) return; // '>=' because arrays are 0-indexed

    pixels[n*3] = g;
}

void WS2801::setPixelB(uint16_t n, uint8_t b) {
    if (n >= numLEDs) return; // '>=' because arrays are 0-indexed

    pixels[n*3+2] = b;
}

void WS2801::setPixelColor(uint16_t n, uint32_t c) {
    if (n >= numLEDs) return; // '>=' because arrays are 0-indexed

    pixels[n*3  ] = (c >> 16);
    pixels[n*3+1] = (c >>  8);
    pixels[n*3+2] =  c;
}