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2cf799f45b
Xteink-X4-crosspoint-reader/lib/Epub/Epub.cpp
Jake Kenneally 2cf799f45b
feat: Add CSS parsing and CSS support in EPUBs (#411) 
## Summary

* **What is the goal of this PR?**

- Adds basic CSS parsing to EPUBs and determine the CSS rules when
rendering to the screen so that text is styled correctly. Currently
supports bold, underline, italics, margin, padding, and text alignment

## Additional Context

- My main reason for wanting this is that the book I'm currently
reading, Carl's Doomsday Scenario (2nd in the Dungeon Crawler Carl
series), relies _a lot_ on styled text for telling parts of the story.
When text is bolded, it's supposed to be a message that's rendered
"on-screen" in the story. When characters are "chatting" with each
other, the text is bolded and their names are underlined. Plus, normal
emphasis is provided with italicizing words here and there. So, this
greatly improves my experience reading this book on the Xteink, and I
figured it was useful enough for others too.
- For transparency: I'm a software engineer, but I'm mostly frontend and
TypeScript/JavaScript. It's been _years_ since I did any C/C++, so I
would not be surprised if I'm doing something dumb along the way in this
code. Please don't hesitate to ask for changes if something looks off. I
heavily relied on Claude Code for help, and I had a lot of inspiration
from how [microreader](https://github.com/CidVonHighwind/microreader)
achieves their CSS parsing and styling. I did give this as good of a
code review as I could and went through everything, and _it works on my
machine_ 😄

### Before

![IMG_6271](https://github.com/user-attachments/assets/dba7554d-efb6-4d13-88bc-8b83cd1fc615)

![IMG_6272](https://github.com/user-attachments/assets/61ba2de0-87c9-4f39-956f-013da4fe20a4)

### After

![IMG_6268](https://github.com/user-attachments/assets/ebe11796-cca9-4a46-b9c7-0709c7932818)

![IMG_6269](https://github.com/user-attachments/assets/e89c33dc-ff47-4bb7-855e-863fe44b3202)

---

### AI Usage

Did you use AI tools to help write this code? **YES**, Claude Code
2026-02-05 21:28:10 +11:00

728 lines
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#include "Epub.h"
#include <FsHelpers.h>
#include <HardwareSerial.h>
#include <JpegToBmpConverter.h>
#include <SDCardManager.h>
#include <ZipFile.h>
#include "Epub/parsers/ContainerParser.h"
#include "Epub/parsers/ContentOpfParser.h"
#include "Epub/parsers/TocNavParser.h"
#include "Epub/parsers/TocNcxParser.h"
bool Epub::findContentOpfFile(std::string* contentOpfFile) const {
const auto containerPath = "META-INF/container.xml";
size_t containerSize;
// Get file size without loading it all into heap
if (!getItemSize(containerPath, &containerSize)) {
Serial.printf("[%lu] [EBP] Could not find or size META-INF/container.xml\n", millis());
return false;
}
ContainerParser containerParser(containerSize);
if (!containerParser.setup()) {
return false;
}
// Stream read (reusing your existing stream logic)
if (!readItemContentsToStream(containerPath, containerParser, 512)) {
Serial.printf("[%lu] [EBP] Could not read META-INF/container.xml\n", millis());
return false;
}
// Extract the result
if (containerParser.fullPath.empty()) {
Serial.printf("[%lu] [EBP] Could not find valid rootfile in container.xml\n", millis());
return false;
}
*contentOpfFile = std::move(containerParser.fullPath);
return true;
}
bool Epub::parseContentOpf(BookMetadataCache::BookMetadata& bookMetadata) {
std::string contentOpfFilePath;
if (!findContentOpfFile(&contentOpfFilePath)) {
Serial.printf("[%lu] [EBP] Could not find content.opf in zip\n", millis());
return false;
}
contentBasePath = contentOpfFilePath.substr(0, contentOpfFilePath.find_last_of('/') + 1);
Serial.printf("[%lu] [EBP] Parsing content.opf: %s\n", millis(), contentOpfFilePath.c_str());
size_t contentOpfSize;
if (!getItemSize(contentOpfFilePath, &contentOpfSize)) {
Serial.printf("[%lu] [EBP] Could not get size of content.opf\n", millis());
return false;
}
ContentOpfParser opfParser(getCachePath(), getBasePath(), contentOpfSize, bookMetadataCache.get());
if (!opfParser.setup()) {
Serial.printf("[%lu] [EBP] Could not setup content.opf parser\n", millis());
return false;
}
if (!readItemContentsToStream(contentOpfFilePath, opfParser, 1024)) {
Serial.printf("[%lu] [EBP] Could not read content.opf\n", millis());
return false;
}
// Grab data from opfParser into epub
bookMetadata.title = opfParser.title;
bookMetadata.author = opfParser.author;
bookMetadata.language = opfParser.language;
bookMetadata.coverItemHref = opfParser.coverItemHref;
bookMetadata.textReferenceHref = opfParser.textReferenceHref;
if (!opfParser.tocNcxPath.empty()) {
tocNcxItem = opfParser.tocNcxPath;
}
if (!opfParser.tocNavPath.empty()) {
tocNavItem = opfParser.tocNavPath;
}
if (!opfParser.cssFiles.empty()) {
cssFiles = opfParser.cssFiles;
}
Serial.printf("[%lu] [EBP] Successfully parsed content.opf\n", millis());
return true;
}
bool Epub::parseTocNcxFile() const {
// the ncx file should have been specified in the content.opf file
if (tocNcxItem.empty()) {
Serial.printf("[%lu] [EBP] No ncx file specified\n", millis());
return false;
}
Serial.printf("[%lu] [EBP] Parsing toc ncx file: %s\n", millis(), tocNcxItem.c_str());
const auto tmpNcxPath = getCachePath() + "/toc.ncx";
FsFile tempNcxFile;
if (!SdMan.openFileForWrite("EBP", tmpNcxPath, tempNcxFile)) {
return false;
}
readItemContentsToStream(tocNcxItem, tempNcxFile, 1024);
tempNcxFile.close();
if (!SdMan.openFileForRead("EBP", tmpNcxPath, tempNcxFile)) {
return false;
}
const auto ncxSize = tempNcxFile.size();
TocNcxParser ncxParser(contentBasePath, ncxSize, bookMetadataCache.get());
if (!ncxParser.setup()) {
Serial.printf("[%lu] [EBP] Could not setup toc ncx parser\n", millis());
tempNcxFile.close();
return false;
}
const auto ncxBuffer = static_cast<uint8_t*>(malloc(1024));
if (!ncxBuffer) {
Serial.printf("[%lu] [EBP] Could not allocate memory for toc ncx parser\n", millis());
tempNcxFile.close();
return false;
}
while (tempNcxFile.available()) {
const auto readSize = tempNcxFile.read(ncxBuffer, 1024);
if (readSize == 0) break;
const auto processedSize = ncxParser.write(ncxBuffer, readSize);
if (processedSize != readSize) {
Serial.printf("[%lu] [EBP] Could not process all toc ncx data\n", millis());
free(ncxBuffer);
tempNcxFile.close();
return false;
}
}
free(ncxBuffer);
tempNcxFile.close();
SdMan.remove(tmpNcxPath.c_str());
Serial.printf("[%lu] [EBP] Parsed TOC items\n", millis());
return true;
}
bool Epub::parseTocNavFile() const {
// the nav file should have been specified in the content.opf file (EPUB 3)
if (tocNavItem.empty()) {
Serial.printf("[%lu] [EBP] No nav file specified\n", millis());
return false;
}
Serial.printf("[%lu] [EBP] Parsing toc nav file: %s\n", millis(), tocNavItem.c_str());
const auto tmpNavPath = getCachePath() + "/toc.nav";
FsFile tempNavFile;
if (!SdMan.openFileForWrite("EBP", tmpNavPath, tempNavFile)) {
return false;
}
readItemContentsToStream(tocNavItem, tempNavFile, 1024);
tempNavFile.close();
if (!SdMan.openFileForRead("EBP", tmpNavPath, tempNavFile)) {
return false;
}
const auto navSize = tempNavFile.size();
// Note: We can't use `contentBasePath` here as the nav file may be in a different folder to the content.opf
// and the HTMLX nav file will have hrefs relative to itself
const std::string navContentBasePath = tocNavItem.substr(0, tocNavItem.find_last_of('/') + 1);
TocNavParser navParser(navContentBasePath, navSize, bookMetadataCache.get());
if (!navParser.setup()) {
Serial.printf("[%lu] [EBP] Could not setup toc nav parser\n", millis());
return false;
}
const auto navBuffer = static_cast<uint8_t*>(malloc(1024));
if (!navBuffer) {
Serial.printf("[%lu] [EBP] Could not allocate memory for toc nav parser\n", millis());
return false;
}
while (tempNavFile.available()) {
const auto readSize = tempNavFile.read(navBuffer, 1024);
const auto processedSize = navParser.write(navBuffer, readSize);
if (processedSize != readSize) {
Serial.printf("[%lu] [EBP] Could not process all toc nav data\n", millis());
free(navBuffer);
tempNavFile.close();
return false;
}
}
free(navBuffer);
tempNavFile.close();
SdMan.remove(tmpNavPath.c_str());
Serial.printf("[%lu] [EBP] Parsed TOC nav items\n", millis());
return true;
}
std::string Epub::getCssRulesCache() const { return cachePath + "/css_rules.cache"; }
bool Epub::loadCssRulesFromCache() const {
FsFile cssCacheFile;
if (SdMan.openFileForRead("EBP", getCssRulesCache(), cssCacheFile)) {
if (cssParser->loadFromCache(cssCacheFile)) {
cssCacheFile.close();
Serial.printf("[%lu] [EBP] Loaded CSS rules from cache\n", millis());
return true;
}
cssCacheFile.close();
Serial.printf("[%lu] [EBP] CSS cache invalid, reparsing\n", millis());
}
return false;
}
void Epub::parseCssFiles() const {
if (cssFiles.empty()) {
Serial.printf("[%lu] [EBP] No CSS files to parse, but CssParser created for inline styles\n", millis());
}
// Try to load from CSS cache first
if (!loadCssRulesFromCache()) {
// Cache miss - parse CSS files
for (const auto& cssPath : cssFiles) {
Serial.printf("[%lu] [EBP] Parsing CSS file: %s\n", millis(), cssPath.c_str());
// Extract CSS file to temp location
const auto tmpCssPath = getCachePath() + "/.tmp.css";
FsFile tempCssFile;
if (!SdMan.openFileForWrite("EBP", tmpCssPath, tempCssFile)) {
Serial.printf("[%lu] [EBP] Could not create temp CSS file\n", millis());
continue;
}
if (!readItemContentsToStream(cssPath, tempCssFile, 1024)) {
Serial.printf("[%lu] [EBP] Could not read CSS file: %s\n", millis(), cssPath.c_str());
tempCssFile.close();
SdMan.remove(tmpCssPath.c_str());
continue;
}
tempCssFile.close();
// Parse the CSS file
if (!SdMan.openFileForRead("EBP", tmpCssPath, tempCssFile)) {
Serial.printf("[%lu] [EBP] Could not open temp CSS file for reading\n", millis());
SdMan.remove(tmpCssPath.c_str());
continue;
}
cssParser->loadFromStream(tempCssFile);
tempCssFile.close();
SdMan.remove(tmpCssPath.c_str());
}
// Save to cache for next time
FsFile cssCacheFile;
if (SdMan.openFileForWrite("EBP", getCssRulesCache(), cssCacheFile)) {
cssParser->saveToCache(cssCacheFile);
cssCacheFile.close();
}
Serial.printf("[%lu] [EBP] Loaded %zu CSS style rules from %zu files\n", millis(), cssParser->ruleCount(),
cssFiles.size());
}
}
// load in the meta data for the epub file
bool Epub::load(const bool buildIfMissing, const bool skipLoadingCss) {
Serial.printf("[%lu] [EBP] Loading ePub: %s\n", millis(), filepath.c_str());
// Initialize spine/TOC cache
bookMetadataCache.reset(new BookMetadataCache(cachePath));
// Always create CssParser - needed for inline style parsing even without CSS files
cssParser.reset(new CssParser());
// Try to load existing cache first
if (bookMetadataCache->load()) {
if (!skipLoadingCss && !loadCssRulesFromCache()) {
Serial.printf("[%lu] [EBP] Warning: CSS rules cache not found, attempting to parse CSS files\n", millis());
// to get CSS file list
if (!parseContentOpf(bookMetadataCache->coreMetadata)) {
Serial.printf("[%lu] [EBP] Could not parse content.opf from cached bookMetadata for CSS files\n", millis());
// continue anyway - book will work without CSS and we'll still load any inline style CSS
}
parseCssFiles();
}
Serial.printf("[%lu] [EBP] Loaded ePub: %s\n", millis(), filepath.c_str());
return true;
}
// If we didn't load from cache above and we aren't allowed to build, fail now
if (!buildIfMissing) {
return false;
}
// Cache doesn't exist or is invalid, build it
Serial.printf("[%lu] [EBP] Cache not found, building spine/TOC cache\n", millis());
setupCacheDir();
const uint32_t indexingStart = millis();
// Begin building cache - stream entries to disk immediately
if (!bookMetadataCache->beginWrite()) {
Serial.printf("[%lu] [EBP] Could not begin writing cache\n", millis());
return false;
}
// OPF Pass
const uint32_t opfStart = millis();
BookMetadataCache::BookMetadata bookMetadata;
if (!bookMetadataCache->beginContentOpfPass()) {
Serial.printf("[%lu] [EBP] Could not begin writing content.opf pass\n", millis());
return false;
}
if (!parseContentOpf(bookMetadata)) {
Serial.printf("[%lu] [EBP] Could not parse content.opf\n", millis());
return false;
}
if (!bookMetadataCache->endContentOpfPass()) {
Serial.printf("[%lu] [EBP] Could not end writing content.opf pass\n", millis());
return false;
}
Serial.printf("[%lu] [EBP] OPF pass completed in %lu ms\n", millis(), millis() - opfStart);
// TOC Pass - try EPUB 3 nav first, fall back to NCX
const uint32_t tocStart = millis();
if (!bookMetadataCache->beginTocPass()) {
Serial.printf("[%lu] [EBP] Could not begin writing toc pass\n", millis());
return false;
}
bool tocParsed = false;
// Try EPUB 3 nav document first (preferred)
if (!tocNavItem.empty()) {
Serial.printf("[%lu] [EBP] Attempting to parse EPUB 3 nav document\n", millis());
tocParsed = parseTocNavFile();
}
// Fall back to NCX if nav parsing failed or wasn't available
if (!tocParsed && !tocNcxItem.empty()) {
Serial.printf("[%lu] [EBP] Falling back to NCX TOC\n", millis());
tocParsed = parseTocNcxFile();
}
if (!tocParsed) {
Serial.printf("[%lu] [EBP] Warning: Could not parse any TOC format\n", millis());
// Continue anyway - book will work without TOC
}
if (!bookMetadataCache->endTocPass()) {
Serial.printf("[%lu] [EBP] Could not end writing toc pass\n", millis());
return false;
}
Serial.printf("[%lu] [EBP] TOC pass completed in %lu ms\n", millis(), millis() - tocStart);
// Close the cache files
if (!bookMetadataCache->endWrite()) {
Serial.printf("[%lu] [EBP] Could not end writing cache\n", millis());
return false;
}
// Build final book.bin
const uint32_t buildStart = millis();
if (!bookMetadataCache->buildBookBin(filepath, bookMetadata)) {
Serial.printf("[%lu] [EBP] Could not update mappings and sizes\n", millis());
return false;
}
Serial.printf("[%lu] [EBP] buildBookBin completed in %lu ms\n", millis(), millis() - buildStart);
Serial.printf("[%lu] [EBP] Total indexing completed in %lu ms\n", millis(), millis() - indexingStart);
if (!bookMetadataCache->cleanupTmpFiles()) {
Serial.printf("[%lu] [EBP] Could not cleanup tmp files - ignoring\n", millis());
}
// Reload the cache from disk so it's in the correct state
bookMetadataCache.reset(new BookMetadataCache(cachePath));
if (!bookMetadataCache->load()) {
Serial.printf("[%lu] [EBP] Failed to reload cache after writing\n", millis());
return false;
}
if (!skipLoadingCss) {
// Parse CSS files after cache reload
parseCssFiles();
}
Serial.printf("[%lu] [EBP] Loaded ePub: %s\n", millis(), filepath.c_str());
return true;
}
bool Epub::clearCache() const {
if (!SdMan.exists(cachePath.c_str())) {
Serial.printf("[%lu] [EPB] Cache does not exist, no action needed\n", millis());
return true;
}
if (!SdMan.removeDir(cachePath.c_str())) {
Serial.printf("[%lu] [EPB] Failed to clear cache\n", millis());
return false;
}
Serial.printf("[%lu] [EPB] Cache cleared successfully\n", millis());
return true;
}
void Epub::setupCacheDir() const {
if (SdMan.exists(cachePath.c_str())) {
return;
}
SdMan.mkdir(cachePath.c_str());
}
const std::string& Epub::getCachePath() const { return cachePath; }
const std::string& Epub::getPath() const { return filepath; }
const std::string& Epub::getTitle() const {
static std::string blank;
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
return blank;
}
return bookMetadataCache->coreMetadata.title;
}
const std::string& Epub::getAuthor() const {
static std::string blank;
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
return blank;
}
return bookMetadataCache->coreMetadata.author;
}
const std::string& Epub::getLanguage() const {
static std::string blank;
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
return blank;
}
return bookMetadataCache->coreMetadata.language;
}
std::string Epub::getCoverBmpPath(bool cropped) const {
const auto coverFileName = std::string("cover") + (cropped ? "_crop" : "");
return cachePath + "/" + coverFileName + ".bmp";
}
bool Epub::generateCoverBmp(bool cropped) const {
// Already generated, return true
if (SdMan.exists(getCoverBmpPath(cropped).c_str())) {
return true;
}
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] Cannot generate cover BMP, cache not loaded\n", millis());
return false;
}
const auto coverImageHref = bookMetadataCache->coreMetadata.coverItemHref;
if (coverImageHref.empty()) {
Serial.printf("[%lu] [EBP] No known cover image\n", millis());
return false;
}
if (coverImageHref.substr(coverImageHref.length() - 4) == ".jpg" ||
coverImageHref.substr(coverImageHref.length() - 5) == ".jpeg") {
Serial.printf("[%lu] [EBP] Generating BMP from JPG cover image (%s mode)\n", millis(), cropped ? "cropped" : "fit");
const auto coverJpgTempPath = getCachePath() + "/.cover.jpg";
FsFile coverJpg;
if (!SdMan.openFileForWrite("EBP", coverJpgTempPath, coverJpg)) {
return false;
}
readItemContentsToStream(coverImageHref, coverJpg, 1024);
coverJpg.close();
if (!SdMan.openFileForRead("EBP", coverJpgTempPath, coverJpg)) {
return false;
}
FsFile coverBmp;
if (!SdMan.openFileForWrite("EBP", getCoverBmpPath(cropped), coverBmp)) {
coverJpg.close();
return false;
}
const bool success = JpegToBmpConverter::jpegFileToBmpStream(coverJpg, coverBmp, cropped);
coverJpg.close();
coverBmp.close();
SdMan.remove(coverJpgTempPath.c_str());
if (!success) {
Serial.printf("[%lu] [EBP] Failed to generate BMP from JPG cover image\n", millis());
SdMan.remove(getCoverBmpPath(cropped).c_str());
}
Serial.printf("[%lu] [EBP] Generated BMP from JPG cover image, success: %s\n", millis(), success ? "yes" : "no");
return success;
} else {
Serial.printf("[%lu] [EBP] Cover image is not a JPG, skipping\n", millis());
}
return false;
}
std::string Epub::getThumbBmpPath() const { return cachePath + "/thumb.bmp"; }
bool Epub::generateThumbBmp() const {
// Already generated, return true
if (SdMan.exists(getThumbBmpPath().c_str())) {
return true;
}
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] Cannot generate thumb BMP, cache not loaded\n", millis());
return false;
}
const auto coverImageHref = bookMetadataCache->coreMetadata.coverItemHref;
if (coverImageHref.empty()) {
Serial.printf("[%lu] [EBP] No known cover image for thumbnail\n", millis());
return false;
}
if (coverImageHref.substr(coverImageHref.length() - 4) == ".jpg" ||
coverImageHref.substr(coverImageHref.length() - 5) == ".jpeg") {
Serial.printf("[%lu] [EBP] Generating thumb BMP from JPG cover image\n", millis());
const auto coverJpgTempPath = getCachePath() + "/.cover.jpg";
FsFile coverJpg;
if (!SdMan.openFileForWrite("EBP", coverJpgTempPath, coverJpg)) {
return false;
}
readItemContentsToStream(coverImageHref, coverJpg, 1024);
coverJpg.close();
if (!SdMan.openFileForRead("EBP", coverJpgTempPath, coverJpg)) {
return false;
}
FsFile thumbBmp;
if (!SdMan.openFileForWrite("EBP", getThumbBmpPath(), thumbBmp)) {
coverJpg.close();
return false;
}
// Use smaller target size for Continue Reading card (half of screen: 240x400)
// Generate 1-bit BMP for fast home screen rendering (no gray passes needed)
constexpr int THUMB_TARGET_WIDTH = 240;
constexpr int THUMB_TARGET_HEIGHT = 400;
const bool success = JpegToBmpConverter::jpegFileTo1BitBmpStreamWithSize(coverJpg, thumbBmp, THUMB_TARGET_WIDTH,
THUMB_TARGET_HEIGHT);
coverJpg.close();
thumbBmp.close();
SdMan.remove(coverJpgTempPath.c_str());
if (!success) {
Serial.printf("[%lu] [EBP] Failed to generate thumb BMP from JPG cover image\n", millis());
SdMan.remove(getThumbBmpPath().c_str());
}
Serial.printf("[%lu] [EBP] Generated thumb BMP from JPG cover image, success: %s\n", millis(),
success ? "yes" : "no");
return success;
} else {
Serial.printf("[%lu] [EBP] Cover image is not a JPG, skipping thumbnail\n", millis());
}
return false;
}
uint8_t* Epub::readItemContentsToBytes(const std::string& itemHref, size_t* size, const bool trailingNullByte) const {
if (itemHref.empty()) {
Serial.printf("[%lu] [EBP] Failed to read item, empty href\n", millis());
return nullptr;
}
const std::string path = FsHelpers::normalisePath(itemHref);
const auto content = ZipFile(filepath).readFileToMemory(path.c_str(), size, trailingNullByte);
if (!content) {
Serial.printf("[%lu] [EBP] Failed to read item %s\n", millis(), path.c_str());
return nullptr;
}
return content;
}
bool Epub::readItemContentsToStream(const std::string& itemHref, Print& out, const size_t chunkSize) const {
if (itemHref.empty()) {
Serial.printf("[%lu] [EBP] Failed to read item, empty href\n", millis());
return false;
}
const std::string path = FsHelpers::normalisePath(itemHref);
return ZipFile(filepath).readFileToStream(path.c_str(), out, chunkSize);
}
bool Epub::getItemSize(const std::string& itemHref, size_t* size) const {
const std::string path = FsHelpers::normalisePath(itemHref);
return ZipFile(filepath).getInflatedFileSize(path.c_str(), size);
}
int Epub::getSpineItemsCount() const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
return 0;
}
return bookMetadataCache->getSpineCount();
}
size_t Epub::getCumulativeSpineItemSize(const int spineIndex) const { return getSpineItem(spineIndex).cumulativeSize; }
BookMetadataCache::SpineEntry Epub::getSpineItem(const int spineIndex) const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] getSpineItem called but cache not loaded\n", millis());
return {};
}
if (spineIndex < 0 || spineIndex >= bookMetadataCache->getSpineCount()) {
Serial.printf("[%lu] [EBP] getSpineItem index:%d is out of range\n", millis(), spineIndex);
return bookMetadataCache->getSpineEntry(0);
}
return bookMetadataCache->getSpineEntry(spineIndex);
}
BookMetadataCache::TocEntry Epub::getTocItem(const int tocIndex) const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] getTocItem called but cache not loaded\n", millis());
return {};
}
if (tocIndex < 0 || tocIndex >= bookMetadataCache->getTocCount()) {
Serial.printf("[%lu] [EBP] getTocItem index:%d is out of range\n", millis(), tocIndex);
return {};
}
return bookMetadataCache->getTocEntry(tocIndex);
}
int Epub::getTocItemsCount() const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
return 0;
}
return bookMetadataCache->getTocCount();
}
// work out the section index for a toc index
int Epub::getSpineIndexForTocIndex(const int tocIndex) const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] getSpineIndexForTocIndex called but cache not loaded\n", millis());
return 0;
}
if (tocIndex < 0 || tocIndex >= bookMetadataCache->getTocCount()) {
Serial.printf("[%lu] [EBP] getSpineIndexForTocIndex: tocIndex %d out of range\n", millis(), tocIndex);
return 0;
}
const int spineIndex = bookMetadataCache->getTocEntry(tocIndex).spineIndex;
if (spineIndex < 0) {
Serial.printf("[%lu] [EBP] Section not found for TOC index %d\n", millis(), tocIndex);
return 0;
}
return spineIndex;
}
int Epub::getTocIndexForSpineIndex(const int spineIndex) const { return getSpineItem(spineIndex).tocIndex; }
size_t Epub::getBookSize() const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded() || bookMetadataCache->getSpineCount() == 0) {
return 0;
}
return getCumulativeSpineItemSize(getSpineItemsCount() - 1);
}
int Epub::getSpineIndexForTextReference() const {
if (!bookMetadataCache || !bookMetadataCache->isLoaded()) {
Serial.printf("[%lu] [EBP] getSpineIndexForTextReference called but cache not loaded\n", millis());
return 0;
}
Serial.printf("[%lu] [ERS] Core Metadata: cover(%d)=%s, textReference(%d)=%s\n", millis(),
bookMetadataCache->coreMetadata.coverItemHref.size(),
bookMetadataCache->coreMetadata.coverItemHref.c_str(),
bookMetadataCache->coreMetadata.textReferenceHref.size(),
bookMetadataCache->coreMetadata.textReferenceHref.c_str());
if (bookMetadataCache->coreMetadata.textReferenceHref.empty()) {
// there was no textReference in epub, so we return 0 (the first chapter)
return 0;
}
// loop through spine items to get the correct index matching the text href
for (size_t i = 0; i < getSpineItemsCount(); i++) {
if (getSpineItem(i).href == bookMetadataCache->coreMetadata.textReferenceHref) {
Serial.printf("[%lu] [ERS] Text reference %s found at index %d\n", millis(),
bookMetadataCache->coreMetadata.textReferenceHref.c_str(), i);
return i;
}
}
// This should not happen, as we checked for empty textReferenceHref earlier
Serial.printf("[%lu] [EBP] Section not found for text reference\n", millis());
return 0;
}
// Calculate progress in book (returns 0.0-1.0)
float Epub::calculateProgress(const int currentSpineIndex, const float currentSpineRead) const {
const size_t bookSize = getBookSize();
if (bookSize == 0) {
return 0.0f;
}
const size_t prevChapterSize = (currentSpineIndex >= 1) ? getCumulativeSpineItemSize(currentSpineIndex - 1) : 0;
const size_t curChapterSize = getCumulativeSpineItemSize(currentSpineIndex) - prevChapterSize;
const float sectionProgSize = currentSpineRead * static_cast<float>(curChapterSize);
const float totalProgress = static_cast<float>(prevChapterSize) + sectionProgSize;
return totalProgress / static_cast<float>(bookSize);
}
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