cottongin/crosspoint-reader-mod
1
1
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
9e04eec072b1db251cca6dc570b619c3e39b5c36
crosspoint-reader-mod/src/activities/reader/XtcReaderActivity.cpp
GenesiaW c8683340ab feat: holding back button while booting, boots to home screen as a mean of escaping boot loop (#587) 
## Summary

* **What is the goal of this PR?** (e.g., Implements the new feature for
file uploading.)
- Allows back button to be held to escape boot loops when reader
activity crashes and device attempts to boot to previous state
- Reduces the need of removing SD card and access to another device to
delete the `/.crosspoint/state.bin`

* **What changes are included?**
  - Back button can be held while booting to boot to home screen
  - Update of User Guide section to include this feature 

## Additional Context

* Add any other information that might be helpful for the reviewer
(e.g., performance implications, potential risks,
  specific areas to focus on).

---

### AI Usage

While CrossPoint doesn't have restrictions on AI tools in contributing,
please be transparent about their usage as it
helps set the right context for reviewers.

Did you use AI tools to help write this code? _**NO**_

---------

Co-authored-by: Arthur Tazhitdinov <lisnake@gmail.com>
2026-02-05 22:45:09 +11:00

402 lines
13 KiB
C++
Raw Blame History

/**
* XtcReaderActivity.cpp
*
* XTC ebook reader activity implementation
* Displays pre-rendered XTC pages on e-ink display
*/
#include "XtcReaderActivity.h"
#include <FsHelpers.h>
#include <GfxRenderer.h>
#include <SDCardManager.h>
#include "CrossPointSettings.h"
#include "CrossPointState.h"
#include "MappedInputManager.h"
#include "RecentBooksStore.h"
#include "XtcReaderChapterSelectionActivity.h"
#include "components/UITheme.h"
#include "fontIds.h"
namespace {
constexpr unsigned long skipPageMs = 700;
constexpr unsigned long goHomeMs = 1000;
} // namespace
void XtcReaderActivity::taskTrampoline(void* param) {
auto* self = static_cast<XtcReaderActivity*>(param);
self->displayTaskLoop();
}
void XtcReaderActivity::onEnter() {
ActivityWithSubactivity::onEnter();
if (!xtc) {
return;
}
renderingMutex = xSemaphoreCreateMutex();
xtc->setupCacheDir();
// Load saved progress
loadProgress();
// Save current XTC as last opened book and add to recent books
APP_STATE.openEpubPath = xtc->getPath();
APP_STATE.saveToFile();
RECENT_BOOKS.addBook(xtc->getPath(), xtc->getTitle(), xtc->getAuthor(), xtc->getThumbBmpPath());
// Trigger first update
updateRequired = true;
xTaskCreate(&XtcReaderActivity::taskTrampoline, "XtcReaderActivityTask",
4096, // Stack size (smaller than EPUB since no parsing needed)
this, // Parameters
1, // Priority
&displayTaskHandle // Task handle
);
}
void XtcReaderActivity::onExit() {
ActivityWithSubactivity::onExit();
// Wait until not rendering to delete task
xSemaphoreTake(renderingMutex, portMAX_DELAY);
if (displayTaskHandle) {
vTaskDelete(displayTaskHandle);
displayTaskHandle = nullptr;
}
vSemaphoreDelete(renderingMutex);
renderingMutex = nullptr;
APP_STATE.readerActivityLoadCount = 0;
APP_STATE.saveToFile();
xtc.reset();
}
void XtcReaderActivity::loop() {
// Pass input responsibility to sub activity if exists
if (subActivity) {
subActivity->loop();
return;
}
// Enter chapter selection activity
if (mappedInput.wasReleased(MappedInputManager::Button::Confirm)) {
if (xtc && xtc->hasChapters() && !xtc->getChapters().empty()) {
xSemaphoreTake(renderingMutex, portMAX_DELAY);
exitActivity();
enterNewActivity(new XtcReaderChapterSelectionActivity(
this->renderer, this->mappedInput, xtc, currentPage,
[this] {
exitActivity();
updateRequired = true;
},
[this](const uint32_t newPage) {
currentPage = newPage;
exitActivity();
updateRequired = true;
}));
xSemaphoreGive(renderingMutex);
}
}
// Long press BACK (1s+) goes directly to home
if (mappedInput.isPressed(MappedInputManager::Button::Back) && mappedInput.getHeldTime() >= goHomeMs) {
onGoHome();
return;
}
// Short press BACK goes to file selection
if (mappedInput.wasReleased(MappedInputManager::Button::Back) && mappedInput.getHeldTime() < goHomeMs) {
onGoBack();
return;
}
// When long-press chapter skip is disabled, turn pages on press instead of release.
const bool usePressForPageTurn = !SETTINGS.longPressChapterSkip;
const bool prevTriggered = usePressForPageTurn ? (mappedInput.wasPressed(MappedInputManager::Button::PageBack) ||
mappedInput.wasPressed(MappedInputManager::Button::Left))
: (mappedInput.wasReleased(MappedInputManager::Button::PageBack) ||
mappedInput.wasReleased(MappedInputManager::Button::Left));
const bool powerPageTurn = SETTINGS.shortPwrBtn == CrossPointSettings::SHORT_PWRBTN::PAGE_TURN &&
mappedInput.wasReleased(MappedInputManager::Button::Power);
const bool nextTriggered = usePressForPageTurn
? (mappedInput.wasPressed(MappedInputManager::Button::PageForward) || powerPageTurn ||
mappedInput.wasPressed(MappedInputManager::Button::Right))
: (mappedInput.wasReleased(MappedInputManager::Button::PageForward) || powerPageTurn ||
mappedInput.wasReleased(MappedInputManager::Button::Right));
if (!prevTriggered && !nextTriggered) {
return;
}
// Handle end of book
if (currentPage >= xtc->getPageCount()) {
currentPage = xtc->getPageCount() - 1;
updateRequired = true;
return;
}
const bool skipPages = SETTINGS.longPressChapterSkip && mappedInput.getHeldTime() > skipPageMs;
const int skipAmount = skipPages ? 10 : 1;
if (prevTriggered) {
if (currentPage >= static_cast<uint32_t>(skipAmount)) {
currentPage -= skipAmount;
} else {
currentPage = 0;
}
updateRequired = true;
} else if (nextTriggered) {
currentPage += skipAmount;
if (currentPage >= xtc->getPageCount()) {
currentPage = xtc->getPageCount(); // Allow showing "End of book"
}
updateRequired = true;
}
}
void XtcReaderActivity::displayTaskLoop() {
while (true) {
if (updateRequired) {
updateRequired = false;
xSemaphoreTake(renderingMutex, portMAX_DELAY);
renderScreen();
xSemaphoreGive(renderingMutex);
}
vTaskDelay(10 / portTICK_PERIOD_MS);
}
}
void XtcReaderActivity::renderScreen() {
if (!xtc) {
return;
}
// Bounds check
if (currentPage >= xtc->getPageCount()) {
// Show end of book screen
renderer.clearScreen();
renderer.drawCenteredText(UI_12_FONT_ID, 300, "End of book", true, EpdFontFamily::BOLD);
renderer.displayBuffer();
return;
}
renderPage();
saveProgress();
}
void XtcReaderActivity::renderPage() {
const uint16_t pageWidth = xtc->getPageWidth();
const uint16_t pageHeight = xtc->getPageHeight();
const uint8_t bitDepth = xtc->getBitDepth();
// Calculate buffer size for one page
// XTG (1-bit): Row-major, ((width+7)/8) * height bytes
// XTH (2-bit): Two bit planes, column-major, ((width * height + 7) / 8) * 2 bytes
size_t pageBufferSize;
if (bitDepth == 2) {
pageBufferSize = ((static_cast<size_t>(pageWidth) * pageHeight + 7) / 8) * 2;
} else {
pageBufferSize = ((pageWidth + 7) / 8) * pageHeight;
}
// Allocate page buffer
uint8_t* pageBuffer = static_cast<uint8_t*>(malloc(pageBufferSize));
if (!pageBuffer) {
Serial.printf("[%lu] [XTR] Failed to allocate page buffer (%lu bytes)\n", millis(), pageBufferSize);
renderer.clearScreen();
renderer.drawCenteredText(UI_12_FONT_ID, 300, "Memory error", true, EpdFontFamily::BOLD);
renderer.displayBuffer();
return;
}
// Load page data
size_t bytesRead = xtc->loadPage(currentPage, pageBuffer, pageBufferSize);
if (bytesRead == 0) {
Serial.printf("[%lu] [XTR] Failed to load page %lu\n", millis(), currentPage);
free(pageBuffer);
renderer.clearScreen();
renderer.drawCenteredText(UI_12_FONT_ID, 300, "Page load error", true, EpdFontFamily::BOLD);
renderer.displayBuffer();
return;
}
// Clear screen first
renderer.clearScreen();
// Copy page bitmap using GfxRenderer's drawPixel
// XTC/XTCH pages are pre-rendered with status bar included, so render full page
const uint16_t maxSrcY = pageHeight;
if (bitDepth == 2) {
// XTH 2-bit mode: Two bit planes, column-major order
// - Columns scanned right to left (x = width-1 down to 0)
// - 8 vertical pixels per byte (MSB = topmost pixel in group)
// - First plane: Bit1, Second plane: Bit2
// - Pixel value = (bit1 << 1) | bit2
// - Grayscale: 0=White, 1=Dark Grey, 2=Light Grey, 3=Black
const size_t planeSize = (static_cast<size_t>(pageWidth) * pageHeight + 7) / 8;
const uint8_t* plane1 = pageBuffer; // Bit1 plane
const uint8_t* plane2 = pageBuffer + planeSize; // Bit2 plane
const size_t colBytes = (pageHeight + 7) / 8; // Bytes per column (100 for 800 height)
// Lambda to get pixel value at (x, y)
auto getPixelValue = [&](uint16_t x, uint16_t y) -> uint8_t {
const size_t colIndex = pageWidth - 1 - x;
const size_t byteInCol = y / 8;
const size_t bitInByte = 7 - (y % 8);
const size_t byteOffset = colIndex * colBytes + byteInCol;
const uint8_t bit1 = (plane1[byteOffset] >> bitInByte) & 1;
const uint8_t bit2 = (plane2[byteOffset] >> bitInByte) & 1;
return (bit1 << 1) | bit2;
};
// Optimized grayscale rendering without storeBwBuffer (saves 48KB peak memory)
// Flow: BW display → LSB/MSB passes → grayscale display → re-render BW for next frame
// Count pixel distribution for debugging
uint32_t pixelCounts[4] = {0, 0, 0, 0};
for (uint16_t y = 0; y < pageHeight; y++) {
for (uint16_t x = 0; x < pageWidth; x++) {
pixelCounts[getPixelValue(x, y)]++;
}
}
Serial.printf("[%lu] [XTR] Pixel distribution: White=%lu, DarkGrey=%lu, LightGrey=%lu, Black=%lu\n", millis(),
pixelCounts[0], pixelCounts[1], pixelCounts[2], pixelCounts[3]);
// Pass 1: BW buffer - draw all non-white pixels as black
for (uint16_t y = 0; y < pageHeight; y++) {
for (uint16_t x = 0; x < pageWidth; x++) {
if (getPixelValue(x, y) >= 1) {
renderer.drawPixel(x, y, true);
}
}
}
// Display BW with conditional refresh based on pagesUntilFullRefresh
if (pagesUntilFullRefresh <= 1) {
renderer.displayBuffer(HalDisplay::HALF_REFRESH);
pagesUntilFullRefresh = SETTINGS.getRefreshFrequency();
} else {
renderer.displayBuffer();
pagesUntilFullRefresh--;
}
// Pass 2: LSB buffer - mark DARK gray only (XTH value 1)
// In LUT: 0 bit = apply gray effect, 1 bit = untouched
renderer.clearScreen(0x00);
for (uint16_t y = 0; y < pageHeight; y++) {
for (uint16_t x = 0; x < pageWidth; x++) {
if (getPixelValue(x, y) == 1) { // Dark grey only
renderer.drawPixel(x, y, false);
}
}
}
renderer.copyGrayscaleLsbBuffers();
// Pass 3: MSB buffer - mark LIGHT AND DARK gray (XTH value 1 or 2)
// In LUT: 0 bit = apply gray effect, 1 bit = untouched
renderer.clearScreen(0x00);
for (uint16_t y = 0; y < pageHeight; y++) {
for (uint16_t x = 0; x < pageWidth; x++) {
const uint8_t pv = getPixelValue(x, y);
if (pv == 1 || pv == 2) { // Dark grey or Light grey
renderer.drawPixel(x, y, false);
}
}
}
renderer.copyGrayscaleMsbBuffers();
// Display grayscale overlay
renderer.displayGrayBuffer();
// Pass 4: Re-render BW to framebuffer (restore for next frame, instead of restoreBwBuffer)
renderer.clearScreen();
for (uint16_t y = 0; y < pageHeight; y++) {
for (uint16_t x = 0; x < pageWidth; x++) {
if (getPixelValue(x, y) >= 1) {
renderer.drawPixel(x, y, true);
}
}
}
// Cleanup grayscale buffers with current frame buffer
renderer.cleanupGrayscaleWithFrameBuffer();
free(pageBuffer);
Serial.printf("[%lu] [XTR] Rendered page %lu/%lu (2-bit grayscale)\n", millis(), currentPage + 1,
xtc->getPageCount());
return;
} else {
// 1-bit mode: 8 pixels per byte, MSB first
const size_t srcRowBytes = (pageWidth + 7) / 8; // 60 bytes for 480 width
for (uint16_t srcY = 0; srcY < maxSrcY; srcY++) {
const size_t srcRowStart = srcY * srcRowBytes;
for (uint16_t srcX = 0; srcX < pageWidth; srcX++) {
// Read source pixel (MSB first, bit 7 = leftmost pixel)
const size_t srcByte = srcRowStart + srcX / 8;
const size_t srcBit = 7 - (srcX % 8);
const bool isBlack = !((pageBuffer[srcByte] >> srcBit) & 1); // XTC: 0 = black, 1 = white
if (isBlack) {
renderer.drawPixel(srcX, srcY, true);
}
}
}
}
// White pixels are already cleared by clearScreen()
free(pageBuffer);
// XTC pages already have status bar pre-rendered, no need to add our own
// Display with appropriate refresh
if (pagesUntilFullRefresh <= 1) {
renderer.displayBuffer(HalDisplay::HALF_REFRESH);
pagesUntilFullRefresh = SETTINGS.getRefreshFrequency();
} else {
renderer.displayBuffer();
pagesUntilFullRefresh--;
}
Serial.printf("[%lu] [XTR] Rendered page %lu/%lu (%u-bit)\n", millis(), currentPage + 1, xtc->getPageCount(),
bitDepth);
}
void XtcReaderActivity::saveProgress() const {
FsFile f;
if (SdMan.openFileForWrite("XTR", xtc->getCachePath() + "/progress.bin", f)) {
uint8_t data[4];
data[0] = currentPage & 0xFF;
data[1] = (currentPage >> 8) & 0xFF;
data[2] = (currentPage >> 16) & 0xFF;
data[3] = (currentPage >> 24) & 0xFF;
f.write(data, 4);
f.close();
}
}
void XtcReaderActivity::loadProgress() {
FsFile f;
if (SdMan.openFileForRead("XTR", xtc->getCachePath() + "/progress.bin", f)) {
uint8_t data[4];
if (f.read(data, 4) == 4) {
currentPage = data[0] | (data[1] << 8) | (data[2] << 16) | (data[3] << 24);
Serial.printf("[%lu] [XTR] Loaded progress: page %lu\n", millis(), currentPage);
// Validate page number
if (currentPage >= xtc->getPageCount()) {
currentPage = 0;
}
}
f.close();
}
}
Reference in New Issue View Git Blame Copy Permalink