Files

mod: Phase 1 - bring forward mod-exclusive files with ActivityManager migration

Brings ~55 mod-exclusive files to the upstream-based mod/master-resync branch:

Activities (migrated to new ActivityManager pattern):
- Clock/Time: SetTimeActivity, SetTimezoneOffsetActivity, NtpSyncActivity
- Dictionary: DictionaryDefinitionActivity, DictionarySuggestionsActivity,
  DictionaryWordSelectActivity, LookedUpWordsActivity
- Bookmark: EpubReaderBookmarkSelectionActivity
- Book management: BookManageMenuActivity, EndOfBookMenuActivity
- OPDS: OpdsServerListActivity, OpdsSettingsActivity
- Utility: DirectoryPickerActivity, NumericStepperActivity

Utilities (unchanged):
- BookManager, BookSettings, BookmarkStore, BootNtpSync
- Dictionary, LookupHistory, TimeSync, OpdsServerStore

Libraries: PlaceholderCover, TableData, ChapterXPathIndexer
Scripts: inject_mod_version, generate_book_icon, preview_placeholder_cover
Docs: KOReader sync XPath mapping

Migration changes:
- ActivityWithSubactivity -> Activity base class
- Callback constructors -> finish()/setResult() pattern
- enterNewActivity() -> startActivityForResult()
- Activity::RenderLock&& -> RenderLock&&

These files won't compile yet - they reference mod settings and I18n
strings that will be added in subsequent phases.

Made-with: Cursor

2026-03-07 15:10:00 -05:00

10 KiB

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TTF Font Investigation

Investigate replacing compile-time bitmap fonts with runtime TTF rendering using stb_truetype (the core of lvgl-ttf-esp32), integrated into the existing custom GfxRenderer pipeline for the ESP32-C3 e-ink reader.

id	content	status
poc-stb	Phase 1: Add stb_truetype.h and build a minimal proof-of-concept that loads a TTF from SD, rasterizes glyphs, and draws them via GfxRenderer	pending

id	content	status
measure-ram	Phase 1: Measure actual RAM consumption and render performance of stb_truetype on ESP32-C3	pending

id	content	status
spiffs-mmap	Phase 3: Test SPIFFS memory-mapping of TTF files using esp_partition_mmap() to avoid loading into RAM	pending

id	content	status
font-provider	Phase 2: Create FontProvider abstraction layer and TtfFontProvider with glyph caching	pending

id	content	status
renderer-refactor	Phase 2: Refactor GfxRenderer to use FontProvider interface instead of direct EpdFontFamily	pending

id	content	status
settings-integration	Phase 4: Update settings to support arbitrary font sizes and custom font selection	pending

id	content	status
remove-bitmap-fonts	Phase 5: Remove compiled bitmap reader fonts, keep only small UI bitmap fonts	pending

false

TTF Font Rendering Investigation

Current State

The project uses no LVGL -- it has a custom GfxRenderer that draws directly into an e-ink framebuffer. Fonts are pre-rasterized offline (TTF -> Python FreeType script -> C header bitmaps) and embedded at compile time.

Cost of current approach:

~2.7 MB flash (mod build, Bookerly + NotoSans + Ubuntu) up to ~7 MB (full build with OpenDyslexic)
Only 4 discrete sizes per family (12/14/16/18 pt) -- no runtime scaling
Each size x style (regular/bold/italic/bold-italic) is a separate ~80-200 KB bitmap blob
App partition is only 6.25 MB -- fonts consume 43-100%+ of available space

Why lvgl-ttf-esp32 Is Relevant (and What Isn't)

The lvgl-ttf-esp32 repo wraps stb_truetype (a single-header C library) with an LVGL font driver. Since this project does not use LVGL, the wrapper is irrelevant, but the stb_truetype library itself is exactly what's needed -- a lightweight, zero-dependency TTF rasterizer that runs on ESP32.

Proposed Architecture

flowchart TD
    subgraph current [Current Pipeline]
        TTF_Offline["TTF files (offline)"] --> fontconvert["fontconvert.py (FreeType)"]
        fontconvert --> headers["56 .h files (~2.7-7 MB flash)"]
        headers --> EpdFont["EpdFont / EpdFontFamily"]
        EpdFont --> GfxRenderer["GfxRenderer::renderChar()"]
    end

    subgraph proposed [Proposed Pipeline]
        TTF_SD["TTF files on SD card (~100-500 KB each)"] --> stb["stb_truetype.h (runtime)"]
        stb --> cache["Glyph cache (RAM + SD)"]
        cache --> TtfFont["TtfFont (new class)"]
        TtfFont --> FontProvider["FontProvider interface"]
        FontProvider --> GfxRenderer2["GfxRenderer::renderChar()"]
    end

Core Idea

stb_truetype.h -- add as a single header file in lib/. It rasterizes individual glyphs from TTF data on demand.
TTF files on SD card -- load at runtime from .crosspoint/fonts/. A typical TTF family (4 styles) is ~400-800 KB total vs 2.7 MB+ as bitmaps.
Glyph cache -- since e-ink pages are static, cache rasterized glyphs in RAM (LRU, ~20-50 KB) and optionally persist to SD card to avoid re-rasterizing across page turns.
**FontProvider abstraction** -- interface over both EpdFont (bitmap, for UI fonts) and new TtfFont (runtime, for reader fonts), so both can coexist.

Integration Points

These are the key files/interfaces that would need changes:

Component	File	Change
Font abstraction	New `lib/FontProvider/`	`FontProvider` interface with `getGlyph()`, `getMetrics()`
TTF renderer	New `lib/TtfFont/`	Wraps stb_truetype, manages TTF loading + glyph cache
GfxRenderer	lib/GfxRenderer/GfxRenderer.h	Change `fontMap` from `EpdFontFamily` to `FontProvider*`; update `renderChar`, `getTextWidth`, `getSpaceWidth`
Font registration	src/main.cpp	Register TTF fonts from SD instead of (or alongside) bitmap fonts
Settings	src/CrossPointSettings.cpp	`getReaderFontId()` supports arbitrary sizes, not just 4 discrete ones
PlaceholderCover	lib/PlaceholderCover/PlaceholderCoverGenerator.cpp	Uses own `renderGlyph()` -- needs similar adaptation
Text layout	lib/Epub/Epub/ParsedText.cpp	Uses `getTextWidth()` / `getSpaceWidth()` for line breaking -- works unchanged if FontProvider is transparent

Feasibility Analysis

Memory (ESP32-C3, ~380 KB RAM)

stb_truetype itself: ~15-20 KB code in flash, minimal RAM overhead
TTF file in memory: requires the full TTF loaded into RAM for glyph access. Options:
- Memory-mapped from flash (SPIFFS): store TTF in SPIFFS (3.4 MB available, currently unused), memory-map via mmap() on ESP-IDF -- zero RAM cost
- Partial loading from SD: read only needed tables on demand (stb_truetype supports custom stbtt_read() but the default API expects full file in memory)
- Load into PSRAM: ESP32-C3 has no PSRAM, so this is not an option
Glyph cache: ~50 bytes metadata + bitmap per glyph. At 18pt, a glyph bitmap is ~20x25 pixels = ~63 bytes (1-bit). Caching 256 glyphs = ~30 KB RAM.
Rasterization temp buffer: stb_truetype allocates ~10-20 KB temporarily per glyph render (uses malloc)

Verdict: The biggest constraint is holding the TTF file in RAM. A typical Bookerly-Regular.ttf is ~150 KB. With 4 styles loaded, that's ~600 KB -- too much for 380 KB RAM. The viable path is using SPIFFS to store TTFs and memory-map them, or implementing a chunked reader that loads TTF table data on demand from SD.

Flash Savings

Remove: 2.7-7 MB of bitmap font headers from firmware
Add: ~40 KB for stb_truetype + TtfFont code
Net savings: 2.6-6.9 MB flash freed
TTF files move to SD card or SPIFFS (not in firmware)

Performance

stb_truetype rasterizes a glyph in ~0.5-2 ms on ESP32 (160 MHz)
A typical page has ~~200-300 glyphs, but with caching, only unique glyphs need rasterizing (~~60-80 per page)
First page render: ~60-160 ms extra for cache warmup
Subsequent pages: mostly cache hits, negligible overhead
E-ink refresh takes ~300-1000 ms anyway, so TTF rasterization cost is acceptable

Anti-aliasing for E-ink

stb_truetype produces 8-bit alpha bitmaps (256 levels). The current system uses 1-bit or 2-bit glyphs. The adapter would:

1-bit mode: threshold the alpha (e.g., alpha > 128 = black)
2-bit mode: quantize to 4 levels (0, 85, 170, 255) for e-ink grayscale

This should actually produce better quality than the offline FreeType conversion since stb_truetype does sub-pixel hinting.

Recommended Implementation Phases

Phase 1: Proof of Concept (stb_truetype standalone)

Add stb_truetype.h to the project
Write a minimal test that loads a TTF from SD, rasterizes a few glyphs, and draws them via GfxRenderer::drawPixel()
Measure RAM usage and render time
Validate glyph quality on e-ink

Phase 2: FontProvider Abstraction

Create FontProvider interface matching EpdFontFamily's public API
Wrap existing EpdFontFamily in a BitmapFontProvider
Create TtfFontProvider backed by stb_truetype + glyph cache
Refactor GfxRenderer::fontMap to use FontProvider*

Phase 3: TTF Storage Strategy

Evaluate SPIFFS memory mapping vs. SD-card chunked loading
Implement the chosen strategy
Handle font discovery (scan SD card for .ttf files)

Phase 4: Settings and UI Integration

Replace discrete font-size enum with a continuous size setting (or finer granularity)
Add "Custom Font" option in settings
Update section cache invalidation when font/size changes

Phase 5: Remove Bitmap Reader Fonts

Keep bitmap fonts only for UI (Ubuntu 10/12, NotoSans 8) which are small (~62 KB)
Remove Bookerly, NotoSans, OpenDyslexic bitmap headers
Ship TTF files on SD card (or downloadable)

Key Risk: TTF-in-RAM on ESP32-C3

The critical question is whether TTF file data can be accessed without loading the full file into RAM. Three mitigation strategies:

SPIFFS + mmap: Store TTFs in the 3.4 MB SPIFFS partition and use ESP-IDF's esp_partition_mmap() to map them into the address space. Zero RAM cost, but SPIFFS is read-only after flashing (unless written at runtime).
SD card + custom I/O: Implement stbtt_GetFontOffsetForIndex and glyph extraction using buffered SD reads. stb_truetype's API assumes a contiguous byte array, so this would require a patched or wrapper approach.
Load one style at a time: Only keep the active style's TTF in RAM (~150 KB). Switch styles by unloading/reloading. Feasible but adds latency on style changes (bold/italic).

Strategy 1 (SPIFFS mmap) is the most promising since the SPIFFS partition is already allocated but unused.

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