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clang-format changes

This commit is contained in:
skullY 2019-08-30 11:19:03 -07:00 committed by skullydazed
parent 61af76a10d
commit b624f32f94
502 changed files with 32259 additions and 39062 deletions

View file

@ -1,240 +1,25 @@
#pragma once
#ifdef __AVR__
#include <avr/io.h>
#include <avr/pgmspace.h>
# include <avr/io.h>
# include <avr/pgmspace.h>
#elif defined(ESP8266)
#include <pgmspace.h>
# include <pgmspace.h>
#else
#define PROGMEM
# define PROGMEM
#endif
// Helidox 8x6 font with QMK Firmware Logo
// Online editor: http://teripom.x0.com/
static const unsigned char font[] PROGMEM = {
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0x1C, 0x3E, 0x7C, 0x3E, 0x1C, 0x00,
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0xFF, 0xE7, 0xC3, 0xE7, 0xFF, 0x00,
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0xFF, 0xE7, 0xDB, 0xE7, 0xFF, 0x00,
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};

View file

@ -23,64 +23,64 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#include <string.h>
#if defined(__AVR__)
#include <avr/io.h>
#include <avr/pgmspace.h>
# include <avr/io.h>
# include <avr/pgmspace.h>
#elif defined(ESP8266)
#include <pgmspace.h>
#else // defined(ESP8266)
#define PROGMEM
#define memcpy_P(des, src, len) memcpy(des, src, len)
#endif // defined(__AVR__)
# include <pgmspace.h>
#else // defined(ESP8266)
# define PROGMEM
# define memcpy_P(des, src, len) memcpy(des, src, len)
#endif // defined(__AVR__)
// Used commands from spec sheet: https://cdn-shop.adafruit.com/datasheets/SSD1306.pdf
// for SH1106: https://www.velleman.eu/downloads/29/infosheets/sh1106_datasheet.pdf
// Fundamental Commands
#define CONTRAST 0x81
#define DISPLAY_ALL_ON 0xA5
#define DISPLAY_ALL_ON_RESUME 0xA4
#define NORMAL_DISPLAY 0xA6
#define DISPLAY_ON 0xAF
#define DISPLAY_OFF 0xAE
#define NOP 0xE3
#define CONTRAST 0x81
#define DISPLAY_ALL_ON 0xA5
#define DISPLAY_ALL_ON_RESUME 0xA4
#define NORMAL_DISPLAY 0xA6
#define DISPLAY_ON 0xAF
#define DISPLAY_OFF 0xAE
#define NOP 0xE3
// Scrolling Commands
#define ACTIVATE_SCROLL 0x2F
#define DEACTIVATE_SCROLL 0x2E
#define SCROLL_RIGHT 0x26
#define SCROLL_LEFT 0x27
#define SCROLL_RIGHT_UP 0x29
#define SCROLL_LEFT_UP 0x2A
#define ACTIVATE_SCROLL 0x2F
#define DEACTIVATE_SCROLL 0x2E
#define SCROLL_RIGHT 0x26
#define SCROLL_LEFT 0x27
#define SCROLL_RIGHT_UP 0x29
#define SCROLL_LEFT_UP 0x2A
// Addressing Setting Commands
#define MEMORY_MODE 0x20
#define COLUMN_ADDR 0x21
#define PAGE_ADDR 0x22
#define PAM_SETCOLUMN_LSB 0x00
#define PAM_SETCOLUMN_MSB 0x10
#define PAM_PAGE_ADDR 0xB0 // 0xb0 -- 0xb7
#define MEMORY_MODE 0x20
#define COLUMN_ADDR 0x21
#define PAGE_ADDR 0x22
#define PAM_SETCOLUMN_LSB 0x00
#define PAM_SETCOLUMN_MSB 0x10
#define PAM_PAGE_ADDR 0xB0 // 0xb0 -- 0xb7
// Hardware Configuration Commands
#define DISPLAY_START_LINE 0x40
#define SEGMENT_REMAP 0xA0
#define SEGMENT_REMAP_INV 0xA1
#define MULTIPLEX_RATIO 0xA8
#define COM_SCAN_INC 0xC0
#define COM_SCAN_DEC 0xC8
#define DISPLAY_OFFSET 0xD3
#define COM_PINS 0xDA
#define COM_PINS_SEQ 0x02
#define COM_PINS_ALT 0x12
#define COM_PINS_SEQ_LR 0x22
#define COM_PINS_ALT_LR 0x32
#define DISPLAY_START_LINE 0x40
#define SEGMENT_REMAP 0xA0
#define SEGMENT_REMAP_INV 0xA1
#define MULTIPLEX_RATIO 0xA8
#define COM_SCAN_INC 0xC0
#define COM_SCAN_DEC 0xC8
#define DISPLAY_OFFSET 0xD3
#define COM_PINS 0xDA
#define COM_PINS_SEQ 0x02
#define COM_PINS_ALT 0x12
#define COM_PINS_SEQ_LR 0x22
#define COM_PINS_ALT_LR 0x32
// Timing & Driving Commands
#define DISPLAY_CLOCK 0xD5
#define PRE_CHARGE_PERIOD 0xD9
#define VCOM_DETECT 0xDB
#define DISPLAY_CLOCK 0xD5
#define PRE_CHARGE_PERIOD 0xD9
#define VCOM_DETECT 0xDB
// Charge Pump Commands
#define CHARGE_PUMP 0x8D
#define CHARGE_PUMP 0x8D
// Misc defines
#define OLED_TIMEOUT 60000
@ -91,12 +91,12 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#define I2C_CMD 0x00
#define I2C_DATA 0x40
#if defined(__AVR__)
// already defined on ARM
#define I2C_TIMEOUT 100
#define I2C_TRANSMIT_P(data) i2c_transmit_P((OLED_DISPLAY_ADDRESS << 1), &data[0], sizeof(data), I2C_TIMEOUT)
#else // defined(__AVR__)
#define I2C_TRANSMIT_P(data) i2c_transmit((OLED_DISPLAY_ADDRESS << 1), &data[0], sizeof(data), I2C_TIMEOUT)
#endif // defined(__AVR__)
// already defined on ARM
# define I2C_TIMEOUT 100
# define I2C_TRANSMIT_P(data) i2c_transmit_P((OLED_DISPLAY_ADDRESS << 1), &data[0], sizeof(data), I2C_TIMEOUT)
#else // defined(__AVR__)
# define I2C_TRANSMIT_P(data) i2c_transmit((OLED_DISPLAY_ADDRESS << 1), &data[0], sizeof(data), I2C_TIMEOUT)
#endif // defined(__AVR__)
#define I2C_TRANSMIT(data) i2c_transmit((OLED_DISPLAY_ADDRESS << 1), &data[0], sizeof(data), I2C_TIMEOUT)
#define I2C_WRITE_REG(mode, data, size) i2c_writeReg((OLED_DISPLAY_ADDRESS << 1), mode, data, size, I2C_TIMEOUT)
@ -106,19 +106,19 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
// this is so we don't end up with rounding errors with
// parts of the display unusable or don't get cleared correctly
// and also allows for drawing & inverting
uint8_t oled_buffer[OLED_MATRIX_SIZE];
uint8_t* oled_cursor;
OLED_BLOCK_TYPE oled_dirty = 0;
bool oled_initialized = false;
bool oled_active = false;
bool oled_scrolling = false;
uint8_t oled_rotation = 0;
uint8_t oled_rotation_width = 0;
uint8_t oled_buffer[OLED_MATRIX_SIZE];
uint8_t * oled_cursor;
OLED_BLOCK_TYPE oled_dirty = 0;
bool oled_initialized = false;
bool oled_active = false;
bool oled_scrolling = false;
uint8_t oled_rotation = 0;
uint8_t oled_rotation_width = 0;
#if OLED_TIMEOUT > 0
uint32_t oled_timeout;
uint32_t oled_timeout;
#endif
#if OLED_SCROLL_TIMEOUT > 0
uint32_t oled_scroll_timeout;
uint32_t oled_scroll_timeout;
#endif
// Internal variables to reduce math instructions
@ -126,468 +126,445 @@ uint8_t oled_rotation_width = 0;
#if defined(__AVR__)
// identical to i2c_transmit, but for PROGMEM since all initialization is in PROGMEM arrays currently
// probably should move this into i2c_master...
static i2c_status_t i2c_transmit_P(uint8_t address, const uint8_t* data, uint16_t length, uint16_t timeout) {
i2c_status_t status = i2c_start(address | I2C_WRITE, timeout);
static i2c_status_t i2c_transmit_P(uint8_t address, const uint8_t *data, uint16_t length, uint16_t timeout) {
i2c_status_t status = i2c_start(address | I2C_WRITE, timeout);
for (uint16_t i = 0; i < length && status >= 0; i++) {
status = i2c_write(pgm_read_byte((const char*)data++), timeout);
if (status) break;
}
for (uint16_t i = 0; i < length && status >= 0; i++) {
status = i2c_write(pgm_read_byte((const char *)data++), timeout);
if (status) break;
}
i2c_stop();
i2c_stop();
return status;
return status;
}
#endif
// Flips the rendering bits for a character at the current cursor position
static void InvertCharacter(uint8_t *cursor)
{
const uint8_t *end = cursor + OLED_FONT_WIDTH;
while (cursor < end) {
*cursor = ~(*cursor);
cursor++;
}
static void InvertCharacter(uint8_t *cursor) {
const uint8_t *end = cursor + OLED_FONT_WIDTH;
while (cursor < end) {
*cursor = ~(*cursor);
cursor++;
}
}
bool oled_init(uint8_t rotation) {
oled_rotation = oled_init_user(rotation);
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
oled_rotation_width = OLED_DISPLAY_WIDTH;
} else {
oled_rotation_width = OLED_DISPLAY_HEIGHT;
}
i2c_init();
oled_rotation = oled_init_user(rotation);
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
oled_rotation_width = OLED_DISPLAY_WIDTH;
} else {
oled_rotation_width = OLED_DISPLAY_HEIGHT;
}
i2c_init();
static const uint8_t PROGMEM display_setup1[] = {
I2C_CMD,
DISPLAY_OFF,
DISPLAY_CLOCK, 0x80,
MULTIPLEX_RATIO, OLED_DISPLAY_HEIGHT - 1,
DISPLAY_OFFSET, 0x00,
DISPLAY_START_LINE | 0x00,
CHARGE_PUMP, 0x14,
static const uint8_t PROGMEM display_setup1[] = {
I2C_CMD,
DISPLAY_OFF,
DISPLAY_CLOCK,
0x80,
MULTIPLEX_RATIO,
OLED_DISPLAY_HEIGHT - 1,
DISPLAY_OFFSET,
0x00,
DISPLAY_START_LINE | 0x00,
CHARGE_PUMP,
0x14,
#if (OLED_IC != OLED_IC_SH1106)
// MEMORY_MODE is unsupported on SH1106 (Page Addressing only)
MEMORY_MODE, 0x00, // Horizontal addressing mode
// MEMORY_MODE is unsupported on SH1106 (Page Addressing only)
MEMORY_MODE,
0x00, // Horizontal addressing mode
#endif
};
if (I2C_TRANSMIT_P(display_setup1) != I2C_STATUS_SUCCESS) {
print("oled_init cmd set 1 failed\n");
return false;
}
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_180)) {
static const uint8_t PROGMEM display_normal[] = {
I2C_CMD,
SEGMENT_REMAP_INV,
COM_SCAN_DEC };
if (I2C_TRANSMIT_P(display_normal) != I2C_STATUS_SUCCESS) {
print("oled_init cmd normal rotation failed\n");
return false;
};
if (I2C_TRANSMIT_P(display_setup1) != I2C_STATUS_SUCCESS) {
print("oled_init cmd set 1 failed\n");
return false;
}
} else {
static const uint8_t PROGMEM display_flipped[] = {
I2C_CMD,
SEGMENT_REMAP,
COM_SCAN_INC };
if (I2C_TRANSMIT_P(display_flipped) != I2C_STATUS_SUCCESS) {
print("display_flipped failed\n");
return false;
}
}
static const uint8_t PROGMEM display_setup2[] = {
I2C_CMD,
COM_PINS, OLED_COM_PINS,
CONTRAST, 0x8F,
PRE_CHARGE_PERIOD, 0xF1,
VCOM_DETECT, 0x40,
DISPLAY_ALL_ON_RESUME,
NORMAL_DISPLAY,
DEACTIVATE_SCROLL,
DISPLAY_ON };
if (I2C_TRANSMIT_P(display_setup2) != I2C_STATUS_SUCCESS) {
print("display_setup2 failed\n");
return false;
}
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_180)) {
static const uint8_t PROGMEM display_normal[] = {I2C_CMD, SEGMENT_REMAP_INV, COM_SCAN_DEC};
if (I2C_TRANSMIT_P(display_normal) != I2C_STATUS_SUCCESS) {
print("oled_init cmd normal rotation failed\n");
return false;
}
} else {
static const uint8_t PROGMEM display_flipped[] = {I2C_CMD, SEGMENT_REMAP, COM_SCAN_INC};
if (I2C_TRANSMIT_P(display_flipped) != I2C_STATUS_SUCCESS) {
print("display_flipped failed\n");
return false;
}
}
static const uint8_t PROGMEM display_setup2[] = {I2C_CMD, COM_PINS, OLED_COM_PINS, CONTRAST, 0x8F, PRE_CHARGE_PERIOD, 0xF1, VCOM_DETECT, 0x40, DISPLAY_ALL_ON_RESUME, NORMAL_DISPLAY, DEACTIVATE_SCROLL, DISPLAY_ON};
if (I2C_TRANSMIT_P(display_setup2) != I2C_STATUS_SUCCESS) {
print("display_setup2 failed\n");
return false;
}
#if OLED_TIMEOUT > 0
oled_timeout = timer_read32() + OLED_TIMEOUT;
oled_timeout = timer_read32() + OLED_TIMEOUT;
#endif
#if OLED_SCROLL_TIMEOUT > 0
oled_scroll_timeout = timer_read32() + OLED_SCROLL_TIMEOUT;
oled_scroll_timeout = timer_read32() + OLED_SCROLL_TIMEOUT;
#endif
oled_clear();
oled_initialized = true;
oled_active = true;
oled_scrolling = false;
return true;
oled_clear();
oled_initialized = true;
oled_active = true;
oled_scrolling = false;
return true;
}
__attribute__((weak))
oled_rotation_t oled_init_user(oled_rotation_t rotation) {
return rotation;
}
__attribute__((weak)) oled_rotation_t oled_init_user(oled_rotation_t rotation) { return rotation; }
void oled_clear(void) {
memset(oled_buffer, 0, sizeof(oled_buffer));
oled_cursor = &oled_buffer[0];
oled_dirty = -1; // -1 will be max value as long as display_dirty is unsigned type
memset(oled_buffer, 0, sizeof(oled_buffer));
oled_cursor = &oled_buffer[0];
oled_dirty = -1; // -1 will be max value as long as display_dirty is unsigned type
}
static void calc_bounds(uint8_t update_start, uint8_t* cmd_array)
{
// Calculate commands to set memory addressing bounds.
uint8_t start_page = OLED_BLOCK_SIZE * update_start / OLED_DISPLAY_WIDTH;
uint8_t start_column = OLED_BLOCK_SIZE * update_start % OLED_DISPLAY_WIDTH;
static void calc_bounds(uint8_t update_start, uint8_t *cmd_array) {
// Calculate commands to set memory addressing bounds.
uint8_t start_page = OLED_BLOCK_SIZE * update_start / OLED_DISPLAY_WIDTH;
uint8_t start_column = OLED_BLOCK_SIZE * update_start % OLED_DISPLAY_WIDTH;
#if (OLED_IC == OLED_IC_SH1106)
// Commands for Page Addressing Mode. Sets starting page and column; has no end bound.
// Column value must be split into high and low nybble and sent as two commands.
cmd_array[0] = PAM_PAGE_ADDR | start_page;
cmd_array[1] = PAM_SETCOLUMN_LSB | ((OLED_COLUMN_OFFSET + start_column) & 0x0f);
cmd_array[2] = PAM_SETCOLUMN_MSB | ((OLED_COLUMN_OFFSET + start_column) >> 4 & 0x0f);
cmd_array[3] = NOP;
cmd_array[4] = NOP;
cmd_array[5] = NOP;
// Commands for Page Addressing Mode. Sets starting page and column; has no end bound.
// Column value must be split into high and low nybble and sent as two commands.
cmd_array[0] = PAM_PAGE_ADDR | start_page;
cmd_array[1] = PAM_SETCOLUMN_LSB | ((OLED_COLUMN_OFFSET + start_column) & 0x0f);
cmd_array[2] = PAM_SETCOLUMN_MSB | ((OLED_COLUMN_OFFSET + start_column) >> 4 & 0x0f);
cmd_array[3] = NOP;
cmd_array[4] = NOP;
cmd_array[5] = NOP;
#else
// Commands for use in Horizontal Addressing mode.
cmd_array[1] = start_column;
cmd_array[4] = start_page;
cmd_array[2] = (OLED_BLOCK_SIZE + OLED_DISPLAY_WIDTH - 1) % OLED_DISPLAY_WIDTH + cmd_array[1];
cmd_array[5] = (OLED_BLOCK_SIZE + OLED_DISPLAY_WIDTH - 1) / OLED_DISPLAY_WIDTH - 1;
// Commands for use in Horizontal Addressing mode.
cmd_array[1] = start_column;
cmd_array[4] = start_page;
cmd_array[2] = (OLED_BLOCK_SIZE + OLED_DISPLAY_WIDTH - 1) % OLED_DISPLAY_WIDTH + cmd_array[1];
cmd_array[5] = (OLED_BLOCK_SIZE + OLED_DISPLAY_WIDTH - 1) / OLED_DISPLAY_WIDTH - 1;
#endif
}
static void calc_bounds_90(uint8_t update_start, uint8_t* cmd_array)
{
cmd_array[1] = OLED_BLOCK_SIZE * update_start / OLED_DISPLAY_HEIGHT * 8;
cmd_array[4] = OLED_BLOCK_SIZE * update_start % OLED_DISPLAY_HEIGHT;
cmd_array[2] = (OLED_BLOCK_SIZE + OLED_DISPLAY_HEIGHT - 1) / OLED_DISPLAY_HEIGHT * 8 - 1 + cmd_array[1];;
cmd_array[5] = (OLED_BLOCK_SIZE + OLED_DISPLAY_HEIGHT - 1) % OLED_DISPLAY_HEIGHT / 8;
static void calc_bounds_90(uint8_t update_start, uint8_t *cmd_array) {
cmd_array[1] = OLED_BLOCK_SIZE * update_start / OLED_DISPLAY_HEIGHT * 8;
cmd_array[4] = OLED_BLOCK_SIZE * update_start % OLED_DISPLAY_HEIGHT;
cmd_array[2] = (OLED_BLOCK_SIZE + OLED_DISPLAY_HEIGHT - 1) / OLED_DISPLAY_HEIGHT * 8 - 1 + cmd_array[1];
;
cmd_array[5] = (OLED_BLOCK_SIZE + OLED_DISPLAY_HEIGHT - 1) % OLED_DISPLAY_HEIGHT / 8;
}
uint8_t crot(uint8_t a, int8_t n)
{
const uint8_t mask = 0x7;
n &= mask;
return a << n | a >> (-n & mask);
uint8_t crot(uint8_t a, int8_t n) {
const uint8_t mask = 0x7;
n &= mask;
return a << n | a >> (-n & mask);
}
static void rotate_90(const uint8_t* src, uint8_t* dest)
{
for (uint8_t i = 0, shift = 7; i < 8; ++i, --shift) {
uint8_t selector = (1 << i);
for (uint8_t j = 0; j < 8; ++j) {
dest[i] |= crot(src[j] & selector, shift - (int8_t)j);
static void rotate_90(const uint8_t *src, uint8_t *dest) {
for (uint8_t i = 0, shift = 7; i < 8; ++i, --shift) {
uint8_t selector = (1 << i);
for (uint8_t j = 0; j < 8; ++j) {
dest[i] |= crot(src[j] & selector, shift - (int8_t)j);
}
}
}
}
void oled_render(void) {
// Do we have work to do?
if (!oled_dirty || oled_scrolling) {
return;
}
// Find first dirty block
uint8_t update_start = 0;
while (!(oled_dirty & (1 << update_start))) { ++update_start; }
// Set column & page position
static uint8_t display_start[] = {
I2C_CMD,
COLUMN_ADDR, 0, OLED_DISPLAY_WIDTH - 1,
PAGE_ADDR, 0, OLED_DISPLAY_HEIGHT / 8 - 1 };
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
calc_bounds(update_start, &display_start[1]); // Offset from I2C_CMD byte at the start
} else {
calc_bounds_90(update_start, &display_start[1]); // Offset from I2C_CMD byte at the start
}
// Send column & page position
if (I2C_TRANSMIT(display_start) != I2C_STATUS_SUCCESS) {
print("oled_render offset command failed\n");
return;
}
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
// Send render data chunk as is
if (I2C_WRITE_REG(I2C_DATA, &oled_buffer[OLED_BLOCK_SIZE * update_start], OLED_BLOCK_SIZE) != I2C_STATUS_SUCCESS) {
print("oled_render data failed\n");
return;
}
} else {
// Rotate the render chunks
const static uint8_t source_map[] = OLED_SOURCE_MAP;
const static uint8_t target_map[] = OLED_TARGET_MAP;
static uint8_t temp_buffer[OLED_BLOCK_SIZE];
memset(temp_buffer, 0, sizeof(temp_buffer));
for(uint8_t i = 0; i < sizeof(source_map); ++i) {
rotate_90(&oled_buffer[OLED_BLOCK_SIZE * update_start + source_map[i]], &temp_buffer[target_map[i]]);
// Do we have work to do?
if (!oled_dirty || oled_scrolling) {
return;
}
// Send render data chunk after rotating
if (I2C_WRITE_REG(I2C_DATA, &temp_buffer[0], OLED_BLOCK_SIZE) != I2C_STATUS_SUCCESS) {
print("oled_render90 data failed\n");
return;
// Find first dirty block
uint8_t update_start = 0;
while (!(oled_dirty & (1 << update_start))) {
++update_start;
}
}
// Turn on display if it is off
oled_on();
// Set column & page position
static uint8_t display_start[] = {I2C_CMD, COLUMN_ADDR, 0, OLED_DISPLAY_WIDTH - 1, PAGE_ADDR, 0, OLED_DISPLAY_HEIGHT / 8 - 1};
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
calc_bounds(update_start, &display_start[1]); // Offset from I2C_CMD byte at the start
} else {
calc_bounds_90(update_start, &display_start[1]); // Offset from I2C_CMD byte at the start
}
// Clear dirty flag
oled_dirty &= ~(1 << update_start);
// Send column & page position
if (I2C_TRANSMIT(display_start) != I2C_STATUS_SUCCESS) {
print("oled_render offset command failed\n");
return;
}
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
// Send render data chunk as is
if (I2C_WRITE_REG(I2C_DATA, &oled_buffer[OLED_BLOCK_SIZE * update_start], OLED_BLOCK_SIZE) != I2C_STATUS_SUCCESS) {
print("oled_render data failed\n");
return;
}
} else {
// Rotate the render chunks
const static uint8_t source_map[] = OLED_SOURCE_MAP;
const static uint8_t target_map[] = OLED_TARGET_MAP;
static uint8_t temp_buffer[OLED_BLOCK_SIZE];
memset(temp_buffer, 0, sizeof(temp_buffer));
for (uint8_t i = 0; i < sizeof(source_map); ++i) {
rotate_90(&oled_buffer[OLED_BLOCK_SIZE * update_start + source_map[i]], &temp_buffer[target_map[i]]);
}
// Send render data chunk after rotating
if (I2C_WRITE_REG(I2C_DATA, &temp_buffer[0], OLED_BLOCK_SIZE) != I2C_STATUS_SUCCESS) {
print("oled_render90 data failed\n");
return;
}
}
// Turn on display if it is off
oled_on();
// Clear dirty flag
oled_dirty &= ~(1 << update_start);
}
void oled_set_cursor(uint8_t col, uint8_t line) {
uint16_t index = line * oled_rotation_width + col * OLED_FONT_WIDTH;
uint16_t index = line * oled_rotation_width + col * OLED_FONT_WIDTH;
// Out of bounds?
if (index >= OLED_MATRIX_SIZE) {
index = 0;
}
// Out of bounds?
if (index >= OLED_MATRIX_SIZE) {
index = 0;
}
oled_cursor = &oled_buffer[index];
oled_cursor = &oled_buffer[index];
}
void oled_advance_page(bool clearPageRemainder) {
uint16_t index = oled_cursor - &oled_buffer[0];
uint8_t remaining = oled_rotation_width - (index % oled_rotation_width);
uint16_t index = oled_cursor - &oled_buffer[0];
uint8_t remaining = oled_rotation_width - (index % oled_rotation_width);
if (clearPageRemainder) {
// Remaining Char count
remaining = remaining / OLED_FONT_WIDTH;
if (clearPageRemainder) {
// Remaining Char count
remaining = remaining / OLED_FONT_WIDTH;
// Write empty character until next line
while (remaining--)
oled_write_char(' ', false);
} else {
// Next page index out of bounds?
if (index + remaining >= OLED_MATRIX_SIZE) {
index = 0;
remaining = 0;
// Write empty character until next line
while (remaining--) oled_write_char(' ', false);
} else {
// Next page index out of bounds?
if (index + remaining >= OLED_MATRIX_SIZE) {
index = 0;
remaining = 0;
}
oled_cursor = &oled_buffer[index + remaining];
}
oled_cursor = &oled_buffer[index + remaining];
}
}
void oled_advance_char(void) {
uint16_t nextIndex = oled_cursor - &oled_buffer[0] + OLED_FONT_WIDTH;
uint8_t remainingSpace = oled_rotation_width - (nextIndex % oled_rotation_width);
uint16_t nextIndex = oled_cursor - &oled_buffer[0] + OLED_FONT_WIDTH;
uint8_t remainingSpace = oled_rotation_width - (nextIndex % oled_rotation_width);
// Do we have enough space on the current line for the next character
if (remainingSpace < OLED_FONT_WIDTH) {
nextIndex += remainingSpace;
}
// Do we have enough space on the current line for the next character
if (remainingSpace < OLED_FONT_WIDTH) {
nextIndex += remainingSpace;
}
// Did we go out of bounds
if (nextIndex >= OLED_MATRIX_SIZE) {
nextIndex = 0;
}
// Did we go out of bounds
if (nextIndex >= OLED_MATRIX_SIZE) {
nextIndex = 0;
}
// Update cursor position
oled_cursor = &oled_buffer[nextIndex];
// Update cursor position
oled_cursor = &oled_buffer[nextIndex];
}
// Main handler that writes character data to the display buffer
void oled_write_char(const char data, bool invert) {
// Advance to the next line if newline
if (data == '\n') {
// Old source wrote ' ' until end of line...
oled_advance_page(true);
return;
}
// Advance to the next line if newline
if (data == '\n') {
// Old source wrote ' ' until end of line...
oled_advance_page(true);
return;
}
if (data == '\r') {
oled_advance_page(false);
return;
}
if (data == '\r') {
oled_advance_page(false);
return;
}
// copy the current render buffer to check for dirty after
static uint8_t oled_temp_buffer[OLED_FONT_WIDTH];
memcpy(&oled_temp_buffer, oled_cursor, OLED_FONT_WIDTH);
// copy the current render buffer to check for dirty after
static uint8_t oled_temp_buffer[OLED_FONT_WIDTH];
memcpy(&oled_temp_buffer, oled_cursor, OLED_FONT_WIDTH);
// set the reder buffer data
uint8_t cast_data = (uint8_t)data; // font based on unsigned type for index
if (cast_data < OLED_FONT_START || cast_data > OLED_FONT_END) {
memset(oled_cursor, 0x00, OLED_FONT_WIDTH);
} else {
const uint8_t *glyph = &font[(cast_data - OLED_FONT_START) * OLED_FONT_WIDTH];
memcpy_P(oled_cursor, glyph, OLED_FONT_WIDTH);
}
// set the reder buffer data
uint8_t cast_data = (uint8_t)data; // font based on unsigned type for index
if (cast_data < OLED_FONT_START || cast_data > OLED_FONT_END) {
memset(oled_cursor, 0x00, OLED_FONT_WIDTH);
} else {
const uint8_t *glyph = &font[(cast_data - OLED_FONT_START) * OLED_FONT_WIDTH];
memcpy_P(oled_cursor, glyph, OLED_FONT_WIDTH);
}
// Invert if needed
if (invert) {
InvertCharacter(oled_cursor);
}
// Invert if needed
if (invert) {
InvertCharacter(oled_cursor);
}
// Dirty check
if (memcmp(&oled_temp_buffer, oled_cursor, OLED_FONT_WIDTH)) {
uint16_t index = oled_cursor - &oled_buffer[0];
oled_dirty |= (1 << (index / OLED_BLOCK_SIZE));
// Edgecase check if the written data spans the 2 chunks
oled_dirty |= (1 << ((index + OLED_FONT_WIDTH) / OLED_BLOCK_SIZE));
}
// Dirty check
if (memcmp(&oled_temp_buffer, oled_cursor, OLED_FONT_WIDTH)) {
uint16_t index = oled_cursor - &oled_buffer[0];
oled_dirty |= (1 << (index / OLED_BLOCK_SIZE));
// Edgecase check if the written data spans the 2 chunks
oled_dirty |= (1 << ((index + OLED_FONT_WIDTH) / OLED_BLOCK_SIZE));
}
// Finally move to the next char
oled_advance_char();
// Finally move to the next char
oled_advance_char();
}
void oled_write(const char *data, bool invert) {
const char *end = data + strlen(data);
while (data < end) {
oled_write_char(*data, invert);
data++;
}
const char *end = data + strlen(data);
while (data < end) {
oled_write_char(*data, invert);
data++;
}
}
void oled_write_ln(const char *data, bool invert) {
oled_write(data, invert);
oled_advance_page(true);
oled_write(data, invert);
oled_advance_page(true);
}
#if defined(__AVR__)
void oled_write_P(const char *data, bool invert) {
uint8_t c = pgm_read_byte(data);
while (c != 0) {
oled_write_char(c, invert);
c = pgm_read_byte(++data);
}
uint8_t c = pgm_read_byte(data);
while (c != 0) {
oled_write_char(c, invert);
c = pgm_read_byte(++data);
}
}
void oled_write_ln_P(const char *data, bool invert) {
oled_write_P(data, invert);
oled_advance_page(true);
oled_write_P(data, invert);
oled_advance_page(true);
}
#endif // defined(__AVR__)
#endif // defined(__AVR__)
bool oled_on(void) {
#if OLED_TIMEOUT > 0
oled_timeout = timer_read32() + OLED_TIMEOUT;
oled_timeout = timer_read32() + OLED_TIMEOUT;
#endif
static const uint8_t PROGMEM display_on[] = { I2C_CMD, DISPLAY_ON };
if (!oled_active) {
if (I2C_TRANSMIT_P(display_on) != I2C_STATUS_SUCCESS) {
print("oled_on cmd failed\n");
return oled_active;
static const uint8_t PROGMEM display_on[] = {I2C_CMD, DISPLAY_ON};
if (!oled_active) {
if (I2C_TRANSMIT_P(display_on) != I2C_STATUS_SUCCESS) {
print("oled_on cmd failed\n");
return oled_active;
}
oled_active = true;
}
oled_active = true;
}
return oled_active;
return oled_active;
}
bool oled_off(void) {
static const uint8_t PROGMEM display_off[] = { I2C_CMD, DISPLAY_OFF };
if (oled_active) {
if (I2C_TRANSMIT_P(display_off) != I2C_STATUS_SUCCESS) {
print("oled_off cmd failed\n");
return oled_active;
static const uint8_t PROGMEM display_off[] = {I2C_CMD, DISPLAY_OFF};
if (oled_active) {
if (I2C_TRANSMIT_P(display_off) != I2C_STATUS_SUCCESS) {
print("oled_off cmd failed\n");
return oled_active;
}
oled_active = false;
}
oled_active = false;
}
return !oled_active;
return !oled_active;
}
bool oled_scroll_right(void) {
// Dont enable scrolling if we need to update the display
// This prevents scrolling of bad data from starting the scroll too early after init
if (!oled_dirty && !oled_scrolling) {
static const uint8_t PROGMEM display_scroll_right[] = {
I2C_CMD, SCROLL_RIGHT, 0x00, 0x00, 0x00, 0x0F, 0x00, 0xFF, ACTIVATE_SCROLL };
if (I2C_TRANSMIT_P(display_scroll_right) != I2C_STATUS_SUCCESS) {
print("oled_scroll_right cmd failed\n");
return oled_scrolling;
// Dont enable scrolling if we need to update the display
// This prevents scrolling of bad data from starting the scroll too early after init
if (!oled_dirty && !oled_scrolling) {
static const uint8_t PROGMEM display_scroll_right[] = {I2C_CMD, SCROLL_RIGHT, 0x00, 0x00, 0x00, 0x0F, 0x00, 0xFF, ACTIVATE_SCROLL};
if (I2C_TRANSMIT_P(display_scroll_right) != I2C_STATUS_SUCCESS) {
print("oled_scroll_right cmd failed\n");
return oled_scrolling;
}
oled_scrolling = true;
}
oled_scrolling = true;
}
return oled_scrolling;
return oled_scrolling;
}
bool oled_scroll_left(void) {
// Dont enable scrolling if we need to update the display
// This prevents scrolling of bad data from starting the scroll too early after init
if (!oled_dirty && !oled_scrolling) {
static const uint8_t PROGMEM display_scroll_left[] = {
I2C_CMD, SCROLL_LEFT, 0x00, 0x00, 0x00, 0x0F, 0x00, 0xFF, ACTIVATE_SCROLL };
if (I2C_TRANSMIT_P(display_scroll_left) != I2C_STATUS_SUCCESS) {
print("oled_scroll_left cmd failed\n");
return oled_scrolling;
// Dont enable scrolling if we need to update the display
// This prevents scrolling of bad data from starting the scroll too early after init
if (!oled_dirty && !oled_scrolling) {
static const uint8_t PROGMEM display_scroll_left[] = {I2C_CMD, SCROLL_LEFT, 0x00, 0x00, 0x00, 0x0F, 0x00, 0xFF, ACTIVATE_SCROLL};
if (I2C_TRANSMIT_P(display_scroll_left) != I2C_STATUS_SUCCESS) {
print("oled_scroll_left cmd failed\n");
return oled_scrolling;
}
oled_scrolling = true;
}
oled_scrolling = true;
}
return oled_scrolling;
return oled_scrolling;
}
bool oled_scroll_off(void) {
if (oled_scrolling) {
static const uint8_t PROGMEM display_scroll_off[] = { I2C_CMD, DEACTIVATE_SCROLL };
if (I2C_TRANSMIT_P(display_scroll_off) != I2C_STATUS_SUCCESS) {
print("oled_scroll_off cmd failed\n");
return oled_scrolling;
if (oled_scrolling) {
static const uint8_t PROGMEM display_scroll_off[] = {I2C_CMD, DEACTIVATE_SCROLL};
if (I2C_TRANSMIT_P(display_scroll_off) != I2C_STATUS_SUCCESS) {
print("oled_scroll_off cmd failed\n");
return oled_scrolling;
}
oled_scrolling = false;
oled_dirty = -1;
}
oled_scrolling = false;
oled_dirty = -1;
}
return !oled_scrolling;
return !oled_scrolling;
}
uint8_t oled_max_chars(void) {
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
return OLED_DISPLAY_WIDTH / OLED_FONT_WIDTH;
}
return OLED_DISPLAY_HEIGHT / OLED_FONT_WIDTH;
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
return OLED_DISPLAY_WIDTH / OLED_FONT_WIDTH;
}
return OLED_DISPLAY_HEIGHT / OLED_FONT_WIDTH;
}
uint8_t oled_max_lines(void) {
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
return OLED_DISPLAY_HEIGHT / OLED_FONT_HEIGHT;
}
return OLED_DISPLAY_WIDTH / OLED_FONT_HEIGHT;
if (!HAS_FLAGS(oled_rotation, OLED_ROTATION_90)) {
return OLED_DISPLAY_HEIGHT / OLED_FONT_HEIGHT;
}
return OLED_DISPLAY_WIDTH / OLED_FONT_HEIGHT;
}
void oled_task(void) {
if (!oled_initialized) {
return;
}
if (!oled_initialized) {
return;
}
oled_set_cursor(0, 0);
oled_set_cursor(0, 0);
oled_task_user();
oled_task_user();
#if OLED_SCROLL_TIMEOUT > 0
if (oled_dirty && oled_scrolling) {
oled_scroll_timeout = timer_read32() + OLED_SCROLL_TIMEOUT;
oled_scroll_off();
}
if (oled_dirty && oled_scrolling) {
oled_scroll_timeout = timer_read32() + OLED_SCROLL_TIMEOUT;
oled_scroll_off();
}
#endif
// Smart render system, no need to check for dirty
oled_render();
// Smart render system, no need to check for dirty
oled_render();
// Display timeout check
// Display timeout check
#if OLED_TIMEOUT > 0
if (oled_active && timer_expired32(timer_read32(), oled_timeout)) {
oled_off();
}
if (oled_active && timer_expired32(timer_read32(), oled_timeout)) {
oled_off();
}
#endif
#if OLED_SCROLL_TIMEOUT > 0
if (!oled_scrolling && timer_expired32(timer_read32(), oled_scroll_timeout)) {
#ifdef OLED_SCROLL_TIMEOUT_RIGHT
oled_scroll_right();
#else
oled_scroll_left();
#endif
}
if (!oled_scrolling && timer_expired32(timer_read32(), oled_scroll_timeout)) {
# ifdef OLED_SCROLL_TIMEOUT_RIGHT
oled_scroll_right();
# else
oled_scroll_left();
# endif
}
#endif
}
__attribute__((weak))
void oled_task_user(void) {
}
__attribute__((weak)) void oled_task_user(void) {}

View file

@ -21,129 +21,133 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
// an enumeration of the chips this driver supports
#define OLED_IC_SSD1306 0
#define OLED_IC_SH1106 1
#define OLED_IC_SH1106 1
#if defined(OLED_DISPLAY_CUSTOM)
// Expected user to implement the necessary defines
// Expected user to implement the necessary defines
#elif defined(OLED_DISPLAY_128X64)
// Double height 128x64
#ifndef OLED_DISPLAY_WIDTH
#define OLED_DISPLAY_WIDTH 128
#endif
#ifndef OLED_DISPLAY_HEIGHT
#define OLED_DISPLAY_HEIGHT 64
#endif
#ifndef OLED_MATRIX_SIZE
#define OLED_MATRIX_SIZE (OLED_DISPLAY_HEIGHT / 8 * OLED_DISPLAY_WIDTH) // 1024 (compile time mathed)
#endif
#ifndef OLED_BLOCK_TYPE
#define OLED_BLOCK_TYPE uint16_t
#endif
#ifndef OLED_BLOCK_COUNT
#define OLED_BLOCK_COUNT (sizeof(OLED_BLOCK_TYPE) * 8) // 32 (compile time mathed)
#endif
#ifndef OLED_BLOCK_SIZE
#define OLED_BLOCK_SIZE (OLED_MATRIX_SIZE / OLED_BLOCK_COUNT) // 32 (compile time mathed)
#endif
#ifndef OLED_COM_PINS
#define OLED_COM_PINS COM_PINS_ALT
#endif
// Double height 128x64
# ifndef OLED_DISPLAY_WIDTH
# define OLED_DISPLAY_WIDTH 128
# endif
# ifndef OLED_DISPLAY_HEIGHT
# define OLED_DISPLAY_HEIGHT 64
# endif
# ifndef OLED_MATRIX_SIZE
# define OLED_MATRIX_SIZE (OLED_DISPLAY_HEIGHT / 8 * OLED_DISPLAY_WIDTH) // 1024 (compile time mathed)
# endif
# ifndef OLED_BLOCK_TYPE
# define OLED_BLOCK_TYPE uint16_t
# endif
# ifndef OLED_BLOCK_COUNT
# define OLED_BLOCK_COUNT (sizeof(OLED_BLOCK_TYPE) * 8) // 32 (compile time mathed)
# endif
# ifndef OLED_BLOCK_SIZE
# define OLED_BLOCK_SIZE (OLED_MATRIX_SIZE / OLED_BLOCK_COUNT) // 32 (compile time mathed)
# endif
# ifndef OLED_COM_PINS
# define OLED_COM_PINS COM_PINS_ALT
# endif
// For 90 degree rotation, we map our internal matrix to oled matrix using fixed arrays
// The OLED writes to it's memory horizontally, starting top left, but our memory starts bottom left in this mode
#ifndef OLED_SOURCE_MAP
#define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56 }
#endif
#ifndef OLED_TARGET_MAP
#define OLED_TARGET_MAP { 56, 48, 40, 32, 24, 16, 8, 0 }
#endif
// If OLED_BLOCK_TYPE is uint32_t, these tables would look like:
// #define OLED_SOURCE_MAP { 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 24, 16, 8, 0 }
// If OLED_BLOCK_TYPE is uint16_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 56, 48, 40, 32, 24, 16, 8, 0 }
// If OLED_BLOCK_TYPE is uint8_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56, 64, 72, 80, 88, 96, 104, 112, 120 }
// #define OLED_TARGET_MAP { 56, 120, 48, 112, 40, 104, 32, 96, 24, 88, 16, 80, 8, 72, 0, 64 }
#else // defined(OLED_DISPLAY_128X64)
// Default 128x32
#ifndef OLED_DISPLAY_WIDTH
#define OLED_DISPLAY_WIDTH 128
#endif
#ifndef OLED_DISPLAY_HEIGHT
#define OLED_DISPLAY_HEIGHT 32
#endif
#ifndef OLED_MATRIX_SIZE
#define OLED_MATRIX_SIZE (OLED_DISPLAY_HEIGHT / 8 * OLED_DISPLAY_WIDTH) // 512 (compile time mathed)
#endif
#ifndef OLED_BLOCK_TYPE
#define OLED_BLOCK_TYPE uint16_t // Type to use for segmenting the oled display for smart rendering, use unsigned types only
#endif
#ifndef OLED_BLOCK_COUNT
#define OLED_BLOCK_COUNT (sizeof(OLED_BLOCK_TYPE) * 8) // 16 (compile time mathed)
#endif
#ifndef OLED_BLOCK_SIZE
#define OLED_BLOCK_SIZE (OLED_MATRIX_SIZE / OLED_BLOCK_COUNT) // 32 (compile time mathed)
#endif
#ifndef OLED_COM_PINS
#define OLED_COM_PINS COM_PINS_SEQ
#endif
// For 90 degree rotation, we map our internal matrix to oled matrix using fixed arrays
// The OLED writes to it's memory horizontally, starting top left, but our memory starts bottom left in this mode
# ifndef OLED_SOURCE_MAP
# define OLED_SOURCE_MAP \
{ 0, 8, 16, 24, 32, 40, 48, 56 }
# endif
# ifndef OLED_TARGET_MAP
# define OLED_TARGET_MAP \
{ 56, 48, 40, 32, 24, 16, 8, 0 }
# endif
// If OLED_BLOCK_TYPE is uint32_t, these tables would look like:
// #define OLED_SOURCE_MAP { 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 24, 16, 8, 0 }
// If OLED_BLOCK_TYPE is uint16_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 56, 48, 40, 32, 24, 16, 8, 0 }
// If OLED_BLOCK_TYPE is uint8_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56, 64, 72, 80, 88, 96, 104, 112, 120 }
// #define OLED_TARGET_MAP { 56, 120, 48, 112, 40, 104, 32, 96, 24, 88, 16, 80, 8, 72, 0, 64 }
#else // defined(OLED_DISPLAY_128X64)
// Default 128x32
# ifndef OLED_DISPLAY_WIDTH
# define OLED_DISPLAY_WIDTH 128
# endif
# ifndef OLED_DISPLAY_HEIGHT
# define OLED_DISPLAY_HEIGHT 32
# endif
# ifndef OLED_MATRIX_SIZE
# define OLED_MATRIX_SIZE (OLED_DISPLAY_HEIGHT / 8 * OLED_DISPLAY_WIDTH) // 512 (compile time mathed)
# endif
# ifndef OLED_BLOCK_TYPE
# define OLED_BLOCK_TYPE uint16_t // Type to use for segmenting the oled display for smart rendering, use unsigned types only
# endif
# ifndef OLED_BLOCK_COUNT
# define OLED_BLOCK_COUNT (sizeof(OLED_BLOCK_TYPE) * 8) // 16 (compile time mathed)
# endif
# ifndef OLED_BLOCK_SIZE
# define OLED_BLOCK_SIZE (OLED_MATRIX_SIZE / OLED_BLOCK_COUNT) // 32 (compile time mathed)
# endif
# ifndef OLED_COM_PINS
# define OLED_COM_PINS COM_PINS_SEQ
# endif
// For 90 degree rotation, we map our internal matrix to oled matrix using fixed arrays
// The OLED writes to it's memory horizontally, starting top left, but our memory starts bottom left in this mode
#ifndef OLED_SOURCE_MAP
#define OLED_SOURCE_MAP { 0, 8, 16, 24 }
#endif
#ifndef OLED_TARGET_MAP
#define OLED_TARGET_MAP { 24, 16, 8, 0 }
#endif
// If OLED_BLOCK_TYPE is uint8_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 48, 32, 16, 0, 56, 40, 24, 8 }
#endif // defined(OLED_DISPLAY_CUSTOM)
// For 90 degree rotation, we map our internal matrix to oled matrix using fixed arrays
// The OLED writes to it's memory horizontally, starting top left, but our memory starts bottom left in this mode
# ifndef OLED_SOURCE_MAP
# define OLED_SOURCE_MAP \
{ 0, 8, 16, 24 }
# endif
# ifndef OLED_TARGET_MAP
# define OLED_TARGET_MAP \
{ 24, 16, 8, 0 }
# endif
// If OLED_BLOCK_TYPE is uint8_t, these tables would look like:
// #define OLED_SOURCE_MAP { 0, 8, 16, 24, 32, 40, 48, 56 }
// #define OLED_TARGET_MAP { 48, 32, 16, 0, 56, 40, 24, 8 }
#endif // defined(OLED_DISPLAY_CUSTOM)
#if !defined(OLED_IC)
#define OLED_IC OLED_IC_SSD1306
# define OLED_IC OLED_IC_SSD1306
#endif
// the column address corresponding to the first column in the display hardware
#if !defined(OLED_COLUMN_OFFSET)
#define OLED_COLUMN_OFFSET 0
# define OLED_COLUMN_OFFSET 0
#endif
// Address to use for the i2c oled communication
#if !defined(OLED_DISPLAY_ADDRESS)
#define OLED_DISPLAY_ADDRESS 0x3C
# define OLED_DISPLAY_ADDRESS 0x3C
#endif
// Custom font file to use
#if !defined(OLED_FONT_H)
#define OLED_FONT_H "glcdfont.c"
# define OLED_FONT_H "glcdfont.c"
#endif
// unsigned char value of the first character in the font file
#if !defined(OLED_FONT_START)
#define OLED_FONT_START 0
# define OLED_FONT_START 0
#endif
// unsigned char value of the last character in the font file
#if !defined(OLED_FONT_END)
#define OLED_FONT_END 224
# define OLED_FONT_END 224
#endif
// Font render width
#if !defined(OLED_FONT_WIDTH)
#define OLED_FONT_WIDTH 6
# define OLED_FONT_WIDTH 6
#endif
// Font render height
#if !defined(OLED_FONT_HEIGHT)
#define OLED_FONT_HEIGHT 8
# define OLED_FONT_HEIGHT 8
#endif
#if !defined(OLED_TIMEOUT)
#if defined(OLED_DISABLE_TIMEOUT)
#define OLED_TIMEOUT 0
#else
#define OLED_TIMEOUT 60000
#endif
# if defined(OLED_DISABLE_TIMEOUT)
# define OLED_TIMEOUT 0
# else
# define OLED_TIMEOUT 60000
# endif
#endif
// OLED Rotation enum values are flags
@ -151,7 +155,7 @@ typedef enum {
OLED_ROTATION_0 = 0,
OLED_ROTATION_90 = 1,
OLED_ROTATION_180 = 2,
OLED_ROTATION_270 = 3, // OLED_ROTATION_90 | OLED_ROTATION_180
OLED_ROTATION_270 = 3, // OLED_ROTATION_90 | OLED_ROTATION_180
} oled_rotation_t;
// Initialize the oled display, rotating the rendered output based on the define passed in.
@ -208,15 +212,15 @@ void oled_write_P(const char *data, bool invert);
// Remapped to call 'void oled_write_ln(const char *data, bool invert);' on ARM
void oled_write_ln_P(const char *data, bool invert);
#else
// Writes a string to the buffer at current cursor position
// Advances the cursor while writing, inverts the pixels if true
#define oled_write_P(data, invert) oled_write(data, invert)
// Writes a string to the buffer at current cursor position
// Advances the cursor while writing, inverts the pixels if true
# define oled_write_P(data, invert) oled_write(data, invert)
// Writes a string to the buffer at current cursor position
// Advances the cursor while writing, inverts the pixels if true
// Advances the cursor to the next page, wiring ' ' to the remainder of the current page
#define oled_write_ln_P(data, invert) oled_write(data, invert)
#endif // defined(__AVR__)
// Writes a string to the buffer at current cursor position
// Advances the cursor while writing, inverts the pixels if true
// Advances the cursor to the next page, wiring ' ' to the remainder of the current page
# define oled_write_ln_P(data, invert) oled_write(data, invert)
#endif // defined(__AVR__)
// Can be used to manually turn on the screen if it is off
// Returns true if the screen was on or turns on