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Larger OLED Support (#1713)

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* Update header to declare full buffer size

* Strip refactoring

* Refactor the OLED scrolldown part 1

* High res capable scroll down

* Allow button press to skip scroll

* Bunch of Misc Fixups
This commit is contained in:
Ben V. Brown
2023-06-18 22:50:31 +10:00
committed by GitHub
parent d3d8e3d2d5
commit c6918093fb
8 changed files with 160 additions and 127 deletions
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12
source/Core/BSP/Miniware/BSP.cpp
View File

@@ -379,20 +379,32 @@ uint8_t preStartChecksDone() {
}
uint8_t getTipResistanceX10() {
#ifdef TIP_RESISTANCE_SENSE_Pin
// Return tip resistance in x10 ohms
// We can measure this using the op-amp
return lastTipResistance;
#else
return TIP_RESISTANCE;
#endif
}
uint8_t getTipThermalMass() {
#ifdef TIP_RESISTANCE_SENSE_Pin
if (lastTipResistance >= 80) {
return TIP_THERMAL_MASS;
}
return 45;
#else
return TIP_THERMAL_MASS;
#endif
}
uint8_t getTipInertia() {
#ifdef TIP_RESISTANCE_SENSE_Pin
if (lastTipResistance >= 80) {
return TIP_THERMAL_MASS;
}
return 10;
#else
return TIP_THERMAL_MASS;
#endif
}

4
source/Core/BSP/Miniware/Power.cpp
View File

@@ -5,7 +5,7 @@
#include "Settings.h"
#include "USBPD.h"
#include "configuration.h"
#include "stm32f1xx_hal.h"
void power_check() {
#ifdef POW_PD
// Cant start QC until either PD works or fails
@@ -27,7 +27,7 @@ bool getIsPoweredByDCIN() {
#endif
#ifdef MODEL_TS101
// TODO have to check what we are using
return false;
return HAL_GPIO_ReadPin(DC_SELECT_GPIO_Port, DC_SELECT_Pin) == GPIO_PIN_SET;
#endif
#ifdef MODEL_TS100
return true;

10
source/Core/BSP/Miniware/Setup.cpp
View File

@@ -113,7 +113,7 @@ uint16_t getADCVin(uint8_t sample) {
latestADC += hadc2.Instance->JDR2;
latestADC += hadc2.Instance->JDR3;
latestADC += hadc2.Instance->JDR4;
latestADC <<= 3;
latestADC <<= 1;
filter.update(latestADC);
}
return filter.average();
@@ -333,7 +333,7 @@ static void MX_TIP_CONTROL_TIMER_Init(void) {
#ifdef TIP_HAS_DIRECT_PWM
sConfigOC.Pulse = 0; // PWM is direct to tip
#else
sConfigOC.Pulse = 127; // 50% duty cycle, that is AC coupled through the cap to provide an on signal (This does not do tip at 50% duty cycle)
sConfigOC.Pulse = 127; // 50% duty cycle, that is AC coupled through the cap to provide an on signal (This does not do tip at 50% duty cycle)
#endif
sConfigOC.OCPolarity = TIM_OCPOLARITY_HIGH;
sConfigOC.OCFastMode = TIM_OCFAST_ENABLE;
@@ -352,7 +352,7 @@ static void MX_TIP_CONTROL_TIMER_Init(void) {
// Remap TIM3_CH1 to be on PB4
__HAL_AFIO_REMAP_TIM3_PARTIAL();
#else
// No re-map required
// No re-map required
#endif
HAL_TIM_PWM_Start(&htimTip, PWM_Out_CHANNEL);
}
@@ -496,8 +496,8 @@ static void MX_GPIO_Init(void) {
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
#endif
#else
/* TS80 */
/* Leave USB lines open circuit*/
/* TS80 */
/* Leave USB lines open circuit*/
#endif

10
source/Core/BSP/Miniware/configuration.h
View File

@@ -224,10 +224,10 @@
#ifdef MODEL_TS80
#define VOLTAGE_DIV 780 // Default divider from schematic
#define CALIBRATION_OFFSET 900 // the adc offset in uV
#define PID_POWER_LIMIT 24 // Sets the max pwm power limit
#define POWER_LIMIT 24 // 24 watts default power limit
#define PID_POWER_LIMIT 35 // Sets the max pwm power limit
#define POWER_LIMIT 32 // 24 watts default power limit
#define HARDWARE_MAX_WATTAGE_X10 180
#define HARDWARE_MAX_WATTAGE_X10 320
#define POW_QC
@@ -238,9 +238,9 @@
#define VOLTAGE_DIV 650 // Default for TS80P with slightly different resistors
#define CALIBRATION_OFFSET 1500 // the adc offset in uV
#define PID_POWER_LIMIT 35 // Sets the max pwm power limit
#define POWER_LIMIT 30 // 30 watts default power limit
#define POWER_LIMIT 32 // 30 watts default power limit
#define HARDWARE_MAX_WATTAGE_X10 300
#define HARDWARE_MAX_WATTAGE_X10 320
#define POW_PD 1
#define POW_QC 1

4
source/Core/BSP/Sequre_S60/configuration.h
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@@ -160,12 +160,12 @@
#define HAS_POWER_DEBUG_MENU
#define TEMP_NTC
#define I2C_SOFT_BUS_2 // For now we are doing software I2C to get around hardware chip issues
#define OLED_I2CBB
#define OLED_I2CBB2
#define MODEL_HAS_DCDC // We dont have DC/DC but have reallly fast PWM that gets us roughly the same place
#endif
#endif
#define FLASH_LOGOADDR (0x08000000 + (62 * 1024))
#define FLASH_LOGOADDR (0x08000000 + (62 * 1024))
#define SETTINGS_START_PAGE (0x08000000 + (63 * 1024))

217
source/Core/Drivers/OLED.cpp
View File

@@ -14,17 +14,16 @@
#include <string.h>
// rendering to the buffer
uint8_t *OLED::firstStripPtr; // Pointers to the strips to allow for buffer
// having extra content
uint8_t *OLED::secondStripPtr; // Pointers to the strips
bool OLED::inLeftHandedMode; // Whether the screen is in left or not (used for
uint8_t *OLED::stripPointers[4]; // Pointers to the strips to allow for buffer having extra content
bool OLED::inLeftHandedMode; // Whether the screen is in left or not (used for
// offsets in GRAM)
OLED::DisplayState OLED::displayState;
int16_t OLED::cursor_x, OLED::cursor_y;
bool OLED::initDone = false;
uint8_t OLED::displayOffset;
uint8_t OLED::screenBuffer[16 + (OLED_WIDTH * (OLED_HEIGHT / 8)) + 10]; // The data buffer
uint8_t OLED::secondFrameBuffer[OLED_WIDTH * 2];
uint8_t OLED::secondFrameBuffer[16 + (OLED_WIDTH * (OLED_HEIGHT / 8)) + 10];
uint32_t OLED::displayChecksum;
/*Setup params for the OLED screen*/
/*http://www.displayfuture.com/Display/datasheet/controller/SSD1307.pdf*/
@@ -32,20 +31,20 @@ uint32_t OLED::displayChecksum;
/*Data packets are prefixed with 0x40*/
I2C_CLASS::I2C_REG OLED_Setup_Array[] = {
/**/
{0x80, 0xAE, 0}, /*Display off*/
{0x80, 0xD5, 0}, /*Set display clock divide ratio / osc freq*/
{0x80, 0x52, 0}, /*Divide ratios*/
{0x80, 0xA8, 0}, /*Set Multiplex Ratio*/
{0x80, OLED_HEIGHT - 1, 0}, /*Multiplex ratio adjusts how far down the matrix it scans*/
{0x80, 0xC0, 0}, /*Set COM Scan direction*/
{0x80, 0xD3, 0}, /*Set vertical Display offset*/
{0x80, 0x00, 0}, /*0 Offset*/
{0x80, 0x40, 0}, /*Set Display start line to 0*/
#ifdef OLED_SEGMENT_MAP_REVERSED
{0x80, 0xA1, 0}, /*Set Segment remap to normal*/
#else
{0x80, 0xA0, 0}, /*Set Segment remap to normal*/
#endif
{0x80, 0xAE, 0}, /*Display off*/
{0x80, 0xD3, 0}, /*Set display clock divide ratio / osc freq*/
{0x80, 0x52, 0}, /*Divide ratios*/
{0x80, 0xA8, 0}, /*Set Multiplex Ratio*/
{0x80, OLED_HEIGHT - 1, 0}, /*Multiplex ratio adjusts how far down the matrix it scans*/
{0x80, 0xC0, 0}, /*Set COM Scan direction*/
{0x80, 0xD3, 0}, /*Set vertical Display offset*/
{0x80, 0x00, 0}, /*0 Offset*/
{0x80, 0x40, 0}, /*Set Display start line to 0*/
#ifdef OLED_SEGMENT_MAP_REVERSED
{0x80, 0xA1, 0}, /*Set Segment remap to normal*/
#else
{0x80, 0xA0, 0}, /*Set Segment remap to normal*/
#endif
{0x80, 0x8D, 0}, /*Charge Pump*/
{0x80, 0x14, 0}, /*Charge Pump settings*/
{0x80, 0xDA, 0}, /*Set VCOM Pins hardware config*/
@@ -111,14 +110,22 @@ static uint8_t easeInOutTiming(uint8_t t) { return t * t * (300 - 2 * t) / 10000
* @param b The value associated with 100%
* @param t The percentage [0..<100]
*/
static uint8_t lerp(uint8_t a, uint8_t b, uint8_t t) { return a + t * (b - a) / 100; }
static uint16_t lerp(uint16_t a, uint16_t b, uint16_t t) { return a + t * (b - a) / 100; }
void OLED::initialize() {
cursor_x = cursor_y = 0;
inLeftHandedMode = false;
firstStripPtr = &screenBuffer[FRAMEBUFFER_START];
secondStripPtr = &screenBuffer[FRAMEBUFFER_START + OLED_WIDTH];
displayOffset = 0;
#ifdef OLED_128x32
stripPointers[0] = &screenBuffer[FRAMEBUFFER_START];
stripPointers[1] = &screenBuffer[FRAMEBUFFER_START + OLED_WIDTH];
stripPointers[2] = &screenBuffer[FRAMEBUFFER_START + 2 * OLED_WIDTH];
stripPointers[3] = &screenBuffer[FRAMEBUFFER_START + 3 * OLED_WIDTH];
#else
stripPointers[0] = &screenBuffer[FRAMEBUFFER_START];
stripPointers[1] = &screenBuffer[FRAMEBUFFER_START + OLED_WIDTH];
#endif
displayOffset = 0;
memcpy(&screenBuffer[0], &REFRESH_COMMANDS[0], sizeof(REFRESH_COMMANDS));
// Set the display to be ON once the settings block is sent and send the
@@ -133,14 +140,13 @@ void OLED::initialize() {
initDone = true;
}
void OLED::setFramebuffer(uint8_t *buffer) {
if (buffer == NULL) {
firstStripPtr = &screenBuffer[FRAMEBUFFER_START];
secondStripPtr = &screenBuffer[FRAMEBUFFER_START + OLED_WIDTH];
return;
}
stripPointers[0] = &buffer[FRAMEBUFFER_START];
stripPointers[1] = &buffer[FRAMEBUFFER_START + OLED_WIDTH];
firstStripPtr = &buffer[0];
secondStripPtr = &buffer[OLED_WIDTH];
#ifdef OLED_128x32
stripPointers[2] = &buffer[FRAMEBUFFER_START + (2 * OLED_WIDTH)];
stripPointers[3] = &buffer[FRAMEBUFFER_START + (3 * OLED_WIDTH)];
#endif
}
/*
@@ -233,7 +239,10 @@ void OLED::maskScrollIndicatorOnOLED() {
// Start of data
0x40,
#ifdef OLED_128x32
0x00,
0x00,
#endif
// Clears two 8px strips
0x00,
0x00,
@@ -249,8 +258,14 @@ void OLED::maskScrollIndicatorOnOLED() {
* Otherwise a rewinding navigation animation is shown to the second framebuffer contents.
*/
void OLED::transitionSecondaryFramebuffer(bool forwardNavigation) {
uint8_t *firstBackStripPtr = &secondFrameBuffer[0];
uint8_t *secondBackStripPtr = &secondFrameBuffer[OLED_WIDTH];
uint8_t *stripBackPointers[4];
stripBackPointers[0] = &secondFrameBuffer[0];
stripBackPointers[1] = &secondFrameBuffer[OLED_WIDTH];
#ifdef OLED_128x32
stripBackPointers[2] = &secondFrameBuffer[OLED_WIDTH * 2];
stripBackPointers[3] = &secondFrameBuffer[OLED_WIDTH * 3];
#endif
TickType_t totalDuration = TICKS_100MS * 5; // 500ms
TickType_t duration = 0;
@@ -262,6 +277,7 @@ void OLED::transitionSecondaryFramebuffer(bool forwardNavigation) {
uint8_t progress = ((duration * 100) / totalDuration); // Percentage of the period we are through for animation
progress = easeInOutTiming(progress);
progress = lerp(0, OLED_WIDTH, progress);
// Constrain
if (progress > OLED_WIDTH) {
progress = OLED_WIDTH;
}
@@ -278,11 +294,19 @@ void OLED::transitionSecondaryFramebuffer(bool forwardNavigation) {
offset = progress;
memmove(&firstStripPtr[oldStart], &firstStripPtr[oldPrevious], OLED_WIDTH - progress);
memmove(&secondStripPtr[oldStart], &secondStripPtr[oldPrevious], OLED_WIDTH - progress);
memmove(&stripPointers[0][oldStart], &stripPointers[0][oldPrevious], OLED_WIDTH - progress);
memmove(&stripPointers[1][oldStart], &stripPointers[1][oldPrevious], OLED_WIDTH - progress);
#ifdef OLED_128x32
memmove(&stripPointers[2][oldStart], &stripPointers[2][oldPrevious], OLED_WIDTH - progress);
memmove(&stripPointers[3][oldStart], &stripPointers[3][oldPrevious], OLED_WIDTH - progress);
#endif
memmove(&firstStripPtr[newStart], &firstBackStripPtr[newEnd], progress);
memmove(&secondStripPtr[newStart], &secondBackStripPtr[newEnd], progress);
memmove(&stripPointers[0][newStart], &stripBackPointers[0][newEnd], progress);
memmove(&stripPointers[1][newStart], &stripBackPointers[1][newEnd], progress);
#ifdef OLED_128x32
memmove(&stripPointers[2][newStart], &stripBackPointers[2][newEnd], progress);
memmove(&stripPointers[3][newStart], &stripBackPointers[3][newEnd], progress);
#endif
refresh();
osDelay(TICKS_100MS / 7);
@@ -296,60 +320,62 @@ void OLED::useSecondaryFramebuffer(bool useSecondary) {
if (useSecondary) {
setFramebuffer(secondFrameBuffer);
} else {
setFramebuffer(NULL);
setFramebuffer(screenBuffer);
}
}
/**
* Plays a transition animation of scrolling downward. Note this does *not*
* use the secondary framebuffer.
*
* This transition relies on the previous screen data already in the OLED
* RAM. The caller shall not call `OLED::refresh()` before calling this
* method, as doing so will overwrite the previous screen data. The caller
* does not need to call `OLED::refresh()` after this function returns.
* This assumes that the current display output buffer has the current on screen contents
* Then the secondary buffer has the "new" contents to be slid up onto the screen
* Sadly we cant use the hardware scroll as some devices with the 128x32 screens dont have the GRAM for holding both screens at once
*
* **This function blocks until the transition has completed or user presses button**
*/
void OLED::transitionScrollDown() {
// We want to draw the updated framebuffer to the next page downward.
uint8_t const pageStart = screenBuffer[13];
uint8_t const nextPage = (pageStart + (OLED_HEIGHT / 8)) % 8;
// Change page start address:
screenBuffer[13] = nextPage;
// Change page end address:
screenBuffer[15] = (nextPage + 1) % 8;
refresh(); // Now refresh to write out the contents to the new page
osDelay(TICKS_100MS / 5);
for (uint8_t heightPos = 0; heightPos < OLED_HEIGHT; heightPos++) {
// For each line, we shuffle all bits up a row
for (uint8_t xPos = 0; xPos < OLED_WIDTH; xPos++) {
const uint16_t firstStripPos = FRAMEBUFFER_START + xPos;
const uint16_t secondStripPos = firstStripPos + OLED_WIDTH;
#ifdef OLED_128x32
// For 32 pixel high OLED's we have four strips to tailchain
const uint16_t thirdStripPos = secondStripPos + OLED_WIDTH;
const uint16_t fourthStripPos = thirdStripPos + OLED_WIDTH;
// Move the MSB off the first strip, and pop MSB from second strip onto the first strip
screenBuffer[firstStripPos] = (screenBuffer[firstStripPos] >> 1) | ((screenBuffer[secondStripPos] & 0x01) << 7);
// Now shuffle off the second strip
screenBuffer[secondStripPos] = (screenBuffer[secondStripPos] >> 1) | ((screenBuffer[thirdStripPos] & 0x01) << 7);
// Now shuffle off the third strip
screenBuffer[thirdStripPos] = (screenBuffer[thirdStripPos] >> 1) | ((screenBuffer[fourthStripPos] & 0x01) << 7);
// Now forth strip gets the start of the new buffer
screenBuffer[fourthStripPos] = (screenBuffer[fourthStripPos] >> 1) | ((secondFrameBuffer[firstStripPos] & 0x01) << 7);
// Now cycle all the secondary buffers
uint8_t startLine = (pageStart * 8) + 1;
uint8_t scrollTo = (pageStart + (OLED_HEIGHT / 8)) * 8;
// Scroll the screen by changing display start line.
// This effectively scrolls off the bottom of the current page and into the next one
for (uint8_t current = startLine; current <= scrollTo; current++) {
if (getButtonState() != BUTTON_NONE) {
current = scrollTo;
secondFrameBuffer[firstStripPos] = (secondFrameBuffer[firstStripPos] >> 1) | ((secondFrameBuffer[secondStripPos] & 0x01) << 7);
secondFrameBuffer[secondStripPos] = (secondFrameBuffer[secondStripPos] >> 1) | ((secondFrameBuffer[thirdStripPos] & 0x01) << 7);
secondFrameBuffer[thirdStripPos] = (secondFrameBuffer[thirdStripPos] >> 1) | ((secondFrameBuffer[fourthStripPos] & 0x01) << 7);
// Finally on the bottom row; we shuffle it up ready
secondFrameBuffer[fourthStripPos] >>= 1;
#else
// Move the MSB off the first strip, and pop MSB from second strip onto the first strip
screenBuffer[firstStripPos] = (screenBuffer[firstStripPos] >> 1) | ((screenBuffer[secondStripPos] & 0x01) << 7);
// Now shuffle off the second strip MSB, and replace it with the MSB of the secondary buffer
screenBuffer[secondStripPos] = (screenBuffer[secondStripPos] >> 1) | ((secondFrameBuffer[firstStripPos] & 0x01) << 7);
// Finally, do the shuffle on the second frame buffer
secondFrameBuffer[firstStripPos] = (secondFrameBuffer[firstStripPos] >> 1) | ((secondFrameBuffer[secondStripPos] & 0x01) << 7);
// Finally on the bottom row; we shuffle it up ready
secondFrameBuffer[secondStripPos] >>= 1;
#endif
}
// Set display start line (0x40~0x7F):
// X[5:0] - display start line value
uint8_t scrollCommandByte = 0b01000000 | (current & 0b00111111);
// Also update setup command for "set display start line":
OLED_Setup_Array[8].val = scrollCommandByte;
I2C_CLASS::I2C_RegisterWrite(DEVICEADDR_OLED, 0x80, scrollCommandByte);
if (getButtonState() != BUTTON_NONE) {
// Exit early, but have to transition whole buffer
memcpy(screenBuffer + FRAMEBUFFER_START, secondFrameBuffer + FRAMEBUFFER_START, sizeof(screenBuffer) - FRAMEBUFFER_START);
refresh(); // Now refresh to write out the contents to the new page
return;
}
refresh(); // Now refresh to write out the contents to the new page
osDelay(TICKS_100MS / 7);
}
// Now that scroll is done, revert to default page to avoid wrap issues
screenBuffer[13] = pageStart;
screenBuffer[15] = (pageStart + 1) % 8;
uint8_t scrollCommandByte = 0b01000000;
OLED_Setup_Array[8].val = scrollCommandByte;
refresh();
I2C_CLASS::I2C_RegisterWrite(DEVICEADDR_OLED, 0x80, scrollCommandByte);
}
void OLED::setRotation(bool leftHanded) {
@@ -387,7 +413,7 @@ void OLED::setRotation(bool leftHanded) {
screenBuffer[7] = inLeftHandedMode ? OLED_GRAM_END_FLIP : OLED_GRAM_END; // End address of the ram segment we are writing to (96 wide)
screenBuffer[9] = inLeftHandedMode ? 0xC8 : 0xC0;
// Force a screen refresh
const int len = FRAMEBUFFER_START + (OLED_WIDTH * 2);
const int len = FRAMEBUFFER_START + (OLED_WIDTH * (OLED_HEIGHT / 8));
I2C_CLASS::Transmit(DEVICEADDR_OLED, screenBuffer, len);
osDelay(TICKS_10MS);
checkDisplayBufferChecksum();
@@ -540,15 +566,16 @@ void OLED::drawArea(int16_t x, int8_t y, uint8_t wide, uint8_t height, const uin
if (y == 0) {
// Splat first line of data
for (uint8_t xx = visibleStart; xx < visibleEnd; xx++) {
firstStripPtr[xx + x] = ptr[xx];
stripPointers[0][xx + x] = ptr[xx];
}
}
if (y == 8 || height == 16) {
if (y == 8 || height >= 16) {
// Splat the second line
for (uint8_t xx = visibleStart; xx < visibleEnd; xx++) {
secondStripPtr[x + xx] = ptr[xx + (height == 16 ? wide : 0)];
stripPointers[1][x + xx] = ptr[xx + (height == 16 ? wide : 0)];
}
}
// TODO NEEDS HEIGHT HANDLERS for 24/32
}
// Draw an area, but y must be aligned on 0/8 offset
@@ -574,15 +601,15 @@ void OLED::drawAreaSwapped(int16_t x, int8_t y, uint8_t wide, uint8_t height, co
if (y == 0) {
// Splat first line of data
for (uint8_t xx = visibleStart; xx < visibleEnd; xx += 2) {
firstStripPtr[xx + x] = ptr[xx + 1];
firstStripPtr[xx + x + 1] = ptr[xx];
stripPointers[0][xx + x] = ptr[xx + 1];
stripPointers[0][xx + x + 1] = ptr[xx];
}
}
if (y == 8 || height == 16) {
// Splat the second line
for (uint8_t xx = visibleStart; xx < visibleEnd; xx += 2) {
secondStripPtr[x + xx] = ptr[xx + 1 + (height == 16 ? wide : 0)];
secondStripPtr[x + xx + 1] = ptr[xx + (height == 16 ? wide : 0)];
stripPointers[1][x + xx] = ptr[xx + 1 + (height == 16 ? wide : 0)];
stripPointers[1][x + xx + 1] = ptr[xx + (height == 16 ? wide : 0)];
}
}
}
@@ -608,13 +635,13 @@ void OLED::fillArea(int16_t x, int8_t y, uint8_t wide, uint8_t height, const uin
if (y == 0) {
// Splat first line of data
for (uint8_t xx = visibleStart; xx < visibleEnd; xx++) {
firstStripPtr[xx + x] = value;
stripPointers[0][xx + x] = value;
}
}
if (y == 8 || height == 16) {
// Splat the second line
for (uint8_t xx = visibleStart; xx < visibleEnd; xx++) {
secondStripPtr[x + xx] = value;
stripPointers[1][x + xx] = value;
}
}
}
@@ -630,9 +657,9 @@ void OLED::drawFilledRect(uint8_t x0, uint8_t y0, uint8_t x1, uint8_t y1, bool c
mask = mask << (y0 % 8);
for (uint8_t col = x0; col < x1; col++)
if (clear)
firstStripPtr[(y0 / 8) * 96 + col] &= ~mask;
stripPointers[0][(y0 / 8) * 96 + col] &= ~mask;
else
firstStripPtr[(y0 / 8) * 96 + col] |= mask;
stripPointers[0][(y0 / 8) * 96 + col] |= mask;
}
// Next loop down the line the total number of solids
if (y0 / 8 != y1 / 8)
@@ -640,18 +667,18 @@ void OLED::drawFilledRect(uint8_t x0, uint8_t y0, uint8_t x1, uint8_t y1, bool c
for (uint8_t r = (y0 / 8); r < (y1 / 8); r++) {
// This gives us the row index r
if (clear)
firstStripPtr[(r * 96) + col] = 0;
stripPointers[0][(r * 96) + col] = 0;
else
firstStripPtr[(r * 96) + col] = 0xFF;
stripPointers[0][(r * 96) + col] = 0xFF;
}
// Finally draw the tail
mask = ~(mask << (y1 % 8));
for (uint8_t col = x0; col < x1; col++)
if (clear)
firstStripPtr[(y1 / 8) * 96 + col] &= ~mask;
stripPointers[0][(y1 / 8) * 96 + col] &= ~mask;
else
firstStripPtr[(y1 / 8) * 96 + col] |= mask;
stripPointers[0][(y1 / 8) * 96 + col] |= mask;
}
void OLED::drawHeatSymbol(uint8_t state) {

26
source/Core/Drivers/OLED.hpp
View File

@@ -37,18 +37,15 @@ extern "C" {
#define DEVICEADDR_OLED (0x3c << 1)
#ifdef OLED_128x32
// TODO; for now just cropping in on the screen from 128x32 to 96x16
#define OLED_WIDTH 96
#define OLED_HEIGHT 16
#define OLED_GRAM_START 0x10 // Should be 0x00 when we have full width
#define OLED_GRAM_END 0x6F // Should be 0x7F when we have full width
#define OLED_WIDTH 128
#define OLED_HEIGHT 32
#define OLED_GRAM_START 0x00 // Should be 0x00 when we have full width
#define OLED_GRAM_END 0x7F // Should be 0x7F when we have full width
#define OLED_GRAM_START_FLIP 0
#define OLED_GRAM_END_FLIP 95
#define OLED_GRAM_END_FLIP 0x7F
#define OLED_VCOM_LAYOUT 0x12
#define OLED_SEGMENT_MAP_REVERSED
#warning "128x32 OLED's Not fully supported"
#else
#define OLED_WIDTH 96
#define OLED_HEIGHT 16
@@ -80,7 +77,7 @@ public:
static void refresh() {
if (checkDisplayBufferChecksum()) {
const int len = FRAMEBUFFER_START + (OLED_WIDTH * 2);
const int len = FRAMEBUFFER_START + (OLED_WIDTH * (OLED_HEIGHT / 8));
I2C_CLASS::Transmit(DEVICEADDR_OLED, screenBuffer, len);
// DMA tx time is ~ 20mS Ensure after calling this you delay for at least 25ms
// or we need to goto double buffering
@@ -121,7 +118,7 @@ public:
// Draws a number at the current cursor location
static void printNumber(uint16_t number, uint8_t places, FontStyle fontStyle, bool noLeaderZeros = true);
// Clears the buffer
static void clearScreen() { memset(firstStripPtr, 0, OLED_WIDTH * 2); }
static void clearScreen() { memset(stripPointers[0], 0, OLED_WIDTH * (OLED_HEIGHT / 8)); }
// Draws the battery level symbol
static void drawBattery(uint8_t state) { drawSymbol(3 + (state > 10 ? 10 : state)); }
// Draws a checkbox
@@ -143,7 +140,7 @@ public:
private:
static bool checkDisplayBufferChecksum() {
uint32_t hash = 0;
const int len = FRAMEBUFFER_START + (OLED_WIDTH * 2);
const int len = sizeof(screenBuffer);
for (int i = 0; i < len; i++) {
hash += (i * screenBuffer[i]);
}
@@ -154,16 +151,15 @@ private:
}
static void drawChar(uint16_t charCode, FontStyle fontStyle); // Draw a character to the current cursor location
static void setFramebuffer(uint8_t *buffer);
static uint8_t *firstStripPtr; // Pointers to the strips to allow for buffer having extra content
static uint8_t *secondStripPtr; // Pointers to the strips
static uint8_t *stripPointers[4]; // Pointers to the strips to allow for buffer having extra content
static bool inLeftHandedMode; // Whether the screen is in left or not (used for offsets in GRAM)
static bool initDone;
static DisplayState displayState;
static int16_t cursor_x, cursor_y;
static uint8_t displayOffset;
static uint32_t displayChecksum;
static uint8_t screenBuffer[16 + (OLED_WIDTH * 2) + 10]; // The data buffer
static uint8_t secondFrameBuffer[OLED_WIDTH * 2];
static uint8_t screenBuffer[16 + (OLED_WIDTH * (OLED_HEIGHT / 8)) + 10]; // The data buffer
static uint8_t secondFrameBuffer[16 + OLED_WIDTH * (OLED_HEIGHT / 8) + 10];
};
#endif /* OLED_HPP_ */

4
source/Core/Src/settingsGUI.cpp
View File

@@ -1006,9 +1006,6 @@ void gui_Menu(const menuitem *menu) {
animOpenState = true;
// The menu entering/exiting transition uses the secondary framebuffer,
// but the scroll down transition does not.
if (navState == NavState::ScrollingDown) {
OLED::useSecondaryFramebuffer(false);
}
OLED::setCursor(0, 0);
OLED::clearScreen();
if (menu[currentScreen].shortDescriptionSize > 0) {
@@ -1019,6 +1016,7 @@ void gui_Menu(const menuitem *menu) {
// Play the scroll down animation.
OLED::maskScrollIndicatorOnOLED();
OLED::transitionScrollDown();
OLED::useSecondaryFramebuffer(false);
} else {
// The menu was drawn in a secondary framebuffer.
// Now we play a transition from the pre-drawn primary