Nordic Pucks
Library for interacting with seeedstudio epaper
Dependents: display-puck display-puck
EPD.cpp
- Committer:
- sigveseb
- Date:
- 2014-07-18
- Revision:
- 1:2f62e2b80305
- Parent:
- 0:6ac5ba1343bf
File content as of revision 1:2f62e2b80305:
// TODO: update copyright notice
// Copyright 2013 Pervasive Displays, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at:
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing,
// software distributed under the License is distributed on an
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
// express or implied. See the License for the specific language
// governing permissions and limitations under the License.
#include <limits.h>
#include <SPI.h>
#include "EPD.h"
#include <mbed.h>
// inline arrays
#define ARRAY(type, ...) ((type[]){__VA_ARGS__})
#define CU8(...) (ARRAY(const uint8_t, __VA_ARGS__))
Timer timer;
SPI spi(p20, p22, p25);
static void SPI_put(uint8_t c);
static void SPI_put_wait(uint8_t c, DigitalIn busy_pin);
static void SPI_send(DigitalOut cs_pin, const uint8_t *buffer, uint16_t length);
static void SPI_on();
EPD_Class::EPD_Class(PinName Pin_EPD_CS, PinName Pin_PANEL_ON, PinName Pin_BORDER, PinName Pin_DISCHARGE, PinName Pin_PWM, PinName Pin_RESET, PinName Pin_BUSY) :
EPD_Pin_EPD_CS(Pin_EPD_CS),
EPD_Pin_PANEL_ON(Pin_PANEL_ON),
EPD_Pin_BORDER(Pin_BORDER),
EPD_Pin_DISCHARGE(Pin_DISCHARGE),
EPD_Pin_PWM(Pin_PWM),
EPD_Pin_RESET(Pin_RESET),
EPD_Pin_BUSY(Pin_BUSY) {
}
void EPD_Class::begin(EPD_size sz)
{
this->size = sz;
this->stage_time = 480; // milliseconds
this->lines_per_display = 96;
this->dots_per_line = 128;
this->bytes_per_line = 128 / 8;
this->bytes_per_scan = 96 / 4;
this->filler = false;
timer.start();
this->EPD_Pin_PWM.period(1.0/300000.0);
// display size dependant items
{
static uint8_t cs[] = {0x72, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0f, 0xff, 0x00};
static uint8_t gs[] = {0x72, 0x03};
this->channel_select = cs;
this->channel_select_length = sizeof(cs);
this->gate_source = gs;
this->gate_source_length = sizeof(gs);
}
// set up size structure
switch (size) {
default:
case EPD_1_44: // default so no change
break;
case EPD_2_0: {
this->lines_per_display = 96;
this->dots_per_line = 200;
this->bytes_per_line = 200 / 8;
this->bytes_per_scan = 96 / 4;
this->filler = true;
static uint8_t cs[] = {0x72, 0x00, 0x00, 0x00, 0x00, 0x01, 0xff, 0xe0, 0x00};
static uint8_t gs[] = {0x72, 0x03};
this->channel_select = cs;
this->channel_select_length = sizeof(cs);
this->gate_source = gs;
this->gate_source_length = sizeof(gs);
break;
}
case EPD_2_7: {
this->stage_time = 630; // milliseconds
this->lines_per_display = 176;
this->dots_per_line = 264;
this->bytes_per_line = 264 / 8;
this->bytes_per_scan = 176 / 4;
this->filler = true;
static uint8_t cs[] = {0x72, 0x00, 0x00, 0x00, 0x7f, 0xff, 0xfe, 0x00, 0x00};
static uint8_t gs[] = {0x72, 0x00};
this->channel_select = cs;
this->channel_select_length = sizeof(cs);
this->gate_source = gs;
this->gate_source_length = sizeof(gs);
break;
}
}
this->factored_stage_time = this->stage_time;
}
void EPD_Class::start() {
this->EPD_Pin_PWM = 0.5;
this->EPD_Pin_RESET = 0;
this->EPD_Pin_PANEL_ON = 0;
this->EPD_Pin_DISCHARGE = 0;
this->EPD_Pin_BORDER = 0;
this->EPD_Pin_EPD_CS = 0;
spi.format(8,0);
spi.frequency(10000000);
SPI_on();
wait_ms(5);
this->EPD_Pin_PANEL_ON = 1;
wait_ms(10);
this->EPD_Pin_RESET = 1;
this->EPD_Pin_BORDER = 1;
this->EPD_Pin_EPD_CS = 1;
wait_ms(5);
this->EPD_Pin_RESET = 0;
wait_ms(5);
this->EPD_Pin_RESET = 1;
wait_ms(5);
// wait for COG to become ready
while (this->EPD_Pin_BUSY) {
}
// channel select
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x01), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, this->channel_select, this->channel_select_length);
// DC/DC frequency
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x06), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0xff), 2);
// high power mode osc
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x07), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x9d), 2);
// disable ADC
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x08), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x00), 2);
// Vcom level
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x09), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0xd0, 0x00), 3);
// gate and source voltage levels
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, this->gate_source, this->gate_source_length);
this->EPD_Pin_PWM = 0.5;
wait_ms(5); // pwm toggle >= 5ms
// driver latch on
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x03), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x01), 2);
// driver latch off
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x03), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x00), 2);
wait_ms(5);
// charge pump positive voltage on
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x01), 2);
// final delay before PWM off
wait_ms(30);
this->EPD_Pin_PWM = 0;
// charge pump negative voltage on
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x03), 2);
wait_ms(30);
// Vcom driver on
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x0f), 2);
wait_ms(30);
// output enable to disable
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x02), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x24), 2);
}
void EPD_Class::end()
{
// dummy frame
//this->frame_fixed(0x55, EPD_normal);
// dummy line and border
if (EPD_1_44 == this->size) {
// only for 1.44" EPD
this->line(0x7fffu, 0, 0xaa, false, EPD_normal);
wait_ms(250);
}
else {
// all other display sizes
this->line(0x7fffu, 0, 0x55, false, EPD_normal);
wait_ms(25);
this->EPD_Pin_BORDER = 0;
wait_ms(250);
this->EPD_Pin_BORDER = 1;
}
SPI_on();
// latch reset turn on
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x03), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x01), 2);
// output enable off
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x02), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x05), 2);
// Vcom power off
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x0e), 2);
// power off negative charge pump
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x02), 2);
// discharge
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x0c), 2);
wait_ms(120);
// all charge pumps off
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x05), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x00), 2);
// turn of osc
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x07), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x0d), 2);
// discharge internal - 1
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x50), 2);
wait_ms(40);
// discharge internal - 2
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0xA0), 2);
wait_ms(40);
// discharge internal - 3
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x00), 2);
// turn of power and all signals
//
wait_ms(10);
this->EPD_Pin_RESET = 0;
this->EPD_Pin_PANEL_ON = 0;
this->EPD_Pin_BORDER = 0;
// discharge pulse
this->EPD_Pin_DISCHARGE = 1;
wait_ms(250);
this->EPD_Pin_DISCHARGE = 0;
EPD_Pin_EPD_CS = 1;
}
// convert a temperature in Celcius to
// the scale factor for frame_*_repeat methods
int EPD_Class::temperature_to_factor_10x(int temperature)
{
if (temperature <= -10) {
return 170;
} else if (temperature <= -5) {
return 120;
} else if (temperature <= 5) {
return 80;
} else if (temperature <= 10) {
return 40;
} else if (temperature <= 15) {
return 30;
} else if (temperature <= 20) {
return 20;
} else if (temperature <= 40) {
return 10;
}
return 7;
}
// One frame of data is the number of lines * rows. For example:
// The 1.44” frame of data is 96 lines * 128 dots.
// The 2” frame of data is 96 lines * 200 dots.
// The 2.7” frame of data is 176 lines * 264 dots.
// the image is arranged by line which matches the display size
// so smallest would have 96 * 32 bytes
void EPD_Class::frame_fixed(uint8_t fixed_value, EPD_stage stage, int from_line, int to_line)
{
for (uint8_t line = from_line; line < to_line; line++)
{
this->line(line, 0, fixed_value, false, stage);
}
}
void EPD_Class::frame_data(const uint8_t *image, EPD_stage stage, int from_line, int to_line)
{
for (uint8_t line = from_line; line < to_line; line++)
{
this->line(line, &image[(line - from_line) * this->bytes_per_line], 0, true, stage);
}
}
void EPD_Class::frame_fixed_repeat(uint8_t fixed_value, EPD_stage stage, int from_line, int to_line)
{
long stage_time = this->factored_stage_time;
do {
unsigned long t_start = timer.read_ms();
this->frame_fixed(fixed_value, stage, from_line, to_line);
unsigned long t_end = timer.read_ms();
if (t_end > t_start) {
stage_time -= t_end - t_start;
} else {
stage_time -= t_start - t_end + 1 + ULONG_MAX;
}
} while (stage_time > 0);
}
void EPD_Class::frame_data_repeat(const uint8_t *image, EPD_stage stage, int from_line, int to_line)
{
long stage_time = this->factored_stage_time;
do {
unsigned long t_start = timer.read_ms();
this->frame_data(image, stage, from_line, to_line);
unsigned long t_end = timer.read_ms();
if (t_end > t_start) {
stage_time -= t_end - t_start;
} else {
stage_time -= t_start - t_end + 1 + ULONG_MAX;
}
} while (stage_time > 0);
}
void EPD_Class::line(uint16_t line, const uint8_t *data, uint8_t fixed_value, bool read_progmem, EPD_stage stage)
{
// charge pump voltage levels
SPI_on();
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x04), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, this->gate_source, this->gate_source_length);
// send data
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x0a), 2);
wait_us(10);
// CS low
this->EPD_Pin_EPD_CS = 0;
SPI_put_wait(0x72, this->EPD_Pin_BUSY);
// even pixels
for (uint16_t b = this->bytes_per_line; b > 0; --b)
{
if (0 != data)
{
uint8_t pixels = data[b - 1] & 0xaa;
switch(stage)
{
case EPD_compensate: // B -> W, W -> B (Current Image)
pixels = 0xaa | ((pixels ^ 0xaa) >> 1);
break;
case EPD_white: // B -> N, W -> W (Current Image)
pixels = 0x55 + ((pixels ^ 0xaa) >> 1);
break;
case EPD_inverse: // B -> N, W -> B (New Image)
pixels = 0x55 | (pixels ^ 0xaa);
break;
case EPD_normal: // B -> B, W -> W (New Image)
pixels = 0xaa | (pixels >> 1);
break;
}
SPI_put_wait(pixels, this->EPD_Pin_BUSY);
}
else
{
SPI_put_wait(fixed_value, this->EPD_Pin_BUSY);
}
}
// scan line
for (uint16_t b = 0; b < this->bytes_per_scan; ++b)
{
if (line / 4 == b)
{
SPI_put_wait(0xc0 >> (2 * (line & 0x03)), this->EPD_Pin_BUSY);
}
else
{
SPI_put_wait(0x00, this->EPD_Pin_BUSY);
}
}
// odd pixels
for (uint16_t b = 0; b < this->bytes_per_line; ++b)
{
if (0 != data)
{
uint8_t pixels = data[b] & 0x55;
switch(stage)
{
case EPD_compensate: // B -> W, W -> B (Current Image)
pixels = 0xaa | (pixels ^ 0x55);
break;
case EPD_white: // B -> N, W -> W (Current Image)
pixels = 0x55 + (pixels ^ 0x55);
break;
case EPD_inverse: // B -> N, W -> B (New Image)
pixels = 0x55 | ((pixels ^ 0x55) << 1);
break;
case EPD_normal: // B -> B, W -> W (New Image)
pixels = 0xaa | pixels;
break;
}
uint8_t p1 = (pixels >> 6) & 0x03;
uint8_t p2 = (pixels >> 4) & 0x03;
uint8_t p3 = (pixels >> 2) & 0x03;
uint8_t p4 = (pixels >> 0) & 0x03;
pixels = (p1 << 0) | (p2 << 2) | (p3 << 4) | (p4 << 6);
SPI_put_wait(pixels, this->EPD_Pin_BUSY);
}
else
{
SPI_put_wait(fixed_value, this->EPD_Pin_BUSY);
}
}
if (this->filler)
{
SPI_put_wait(0x00, this->EPD_Pin_BUSY);
}
// CS high
this->EPD_Pin_EPD_CS = 1;
// output data to panel
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x70, 0x02), 2);
wait_us(10);
SPI_send(this->EPD_Pin_EPD_CS, CU8(0x72, 0x2f), 2);
}
static void SPI_on() {
wait_us(10);
}
static void SPI_put(uint8_t c) {
spi.write(c);
}
static void SPI_put_wait(uint8_t c, DigitalIn busy_pin) {
SPI_put(c);
// wait for COG ready
while (1 == busy_pin) {
}
}
static void SPI_send(DigitalOut cs_pin, const uint8_t *buffer, uint16_t length) {
// CS low
cs_pin = 0;
// send all data
for (uint16_t i = 0; i < length; ++i) {
SPI_put(*buffer++);
}
// CS high
cs_pin = 1;
}