Version v0.3.43 - -m Remove unnecessary calculate_checksum() calls during encryption - use filename checksum directly

Version v0.3.42 - -m Suppress miniz warnings in archive.c header include
Version v0.3.41 - -m Suppress miniz library warnings, auto-select pad when only one available
2025-12-27 11:56:28 -05:00 · 2025-12-27 11:51:10 -05:00 · 2025-12-27 11:49:29 -05:00 · 2025-12-27 11:45:31 -05:00 · 2025-12-25 08:25:18 -05:00 · 2025-12-24 10:00:32 -05:00
25 changed files with 1494 additions and 321 deletions
--- a/.gitignore
+++ b/.gitignore
@@ -24,3 +24,10 @@ test_truerng
 # Temporary files
 *.pad
 *.state
 # Downloaded dependencies (source)
 miniz/
 microtar/
 # Test directories
 test_dir/
--- a/HARDWARE_RNG_STATUS.md
+++ b/HARDWARE_RNG_STATUS.md
@@ -1,46 +0,0 @@
 # Hardware RNG Implementation Status
 ## Overview
 The OTP cipher application now includes comprehensive hardware Random Number Generator (RNG) device support with automatic detection, device identification, and graceful handling of different device types.
 ## Supported Devices
 ### ✅ Fully Supported (TrueRNG Family)
 - **TrueRNG Original** (VID: 04d8, PID: f5fe)
 - **TrueRNG Pro** (VID: 04d8, PID: 0aa0)  
 - **TrueRNG Pro V2** (VID: 04d8, PID: ebb5)
 These devices work via serial port communication and are fully integrated into the entropy collection system.
 ### ⚠️ Detected but Not Supported (SwiftRNG Family)
 - **SwiftRNG** (VID: 1fc9, PID: 8111)
 SwiftRNG devices are detected and identified but cannot be used via serial port communication. They require the official SwiftRNG API with libusb-1.0 integration.
 ## Implementation Features
 ### Device Detection
 - **Automatic scanning** of `/dev/ttyUSB*` and `/dev/ttyACM*` devices
 - **VID/PID identification** via sysfs to distinguish device types
 - **Multi-device support** with interactive selection menus
 - **Real-time status indicators** showing device availability
 ### Device Communication
 - **Optimized serial port configuration** for each device type
 - **Timeout protection** to prevent hanging on unresponsive devices
 - **Error handling** with clear diagnostic messages
 - **Progress tracking** with speed estimation for large entropy collections
 ### Integration Points
 - **Pad enhancement** via entropy addition to existing pads
 - **Interactive menus** for device selection when multiple devices are present
 - **Command-line support** for automated workflows
 - **Graceful fallback** to other entropy sources when no hardware RNG is available
 ## Technical Implementation
 ### Core Functions
 - `detect_all_hardware_rng_devices()` - Scans and identifies all connected devices
 - `collect_truerng_entropy_from_device()` - Collects entropy from TrueRNG devices
--- a/29
+++ b/29
@@ -1,23 +1,40 @@
 CC = gcc
-CFLAGS = -Wall -Wextra -std=c99 -Isrc
+CFLAGS = -Wall -Wextra -std=c99 -Isrc -Isrc/miniz -Isrc/microtar
 CFLAGS_MINIZ = -Wall -Wextra -std=c99 -D_POSIX_C_SOURCE=200112L -Isrc -Isrc/miniz -Isrc/microtar -Wno-unused-function -Wno-implicit-function-declaration
 LIBS = -lm
 LIBS_STATIC = -static -lm
 ARCH = $(shell uname -m)
 TARGET = build/otp-$(ARCH)
 SOURCES = $(wildcard src/*.c)
 MINIZ_SOURCES = $(wildcard src/miniz/*.c)
 MICROTAR_SOURCES = $(wildcard src/microtar/*.c)
 OBJS = $(SOURCES:.c=.o)
 MINIZ_OBJS = $(MINIZ_SOURCES:.c=.o)
 MICROTAR_OBJS = $(MICROTAR_SOURCES:.c=.o)
 ALL_OBJS = $(OBJS) $(MINIZ_OBJS) $(MICROTAR_OBJS)
 # Default build target
-$(TARGET): $(OBJS)
+$(TARGET): $(ALL_OBJS)
 	@mkdir -p build
-	$(CC) $(CFLAGS) -o $(TARGET) $(OBJS) $(LIBS)
+	$(CC) $(CFLAGS) -o $(TARGET) $(ALL_OBJS) $(LIBS)
 	@rm -f $(ALL_OBJS)
 # Static linking target
-static: $(OBJS)
+static: $(ALL_OBJS)
 	@mkdir -p build
-	$(CC) $(CFLAGS) -o $(TARGET) $(OBJS) $(LIBS_STATIC)
+	$(CC) $(CFLAGS) -o $(TARGET) $(ALL_OBJS) $(LIBS_STATIC)
 	@rm -f $(ALL_OBJS)
-%.o: %.c
+# Compile main source files with full warnings
 src/%.o: src/%.c
 	$(CC) $(CFLAGS) -c $< -o $@
 # Compile miniz library files with reduced warnings
 src/miniz/%.o: src/miniz/%.c
 	$(CC) $(CFLAGS_MINIZ) -c $< -o $@
 # Compile microtar library files normally
 src/microtar/%.o: src/microtar/%.c
 	$(CC) $(CFLAGS) -c $< -o $@
 clean:
--- a/README.md
+++ b/README.md
@@ -1,9 +1,8 @@
 # OTP Cipher - One Time Pad Implementation
 ## Introduction
-A secure one-time pad (OTP) cipher implementation in C.
+A secure one-time pad (OTP) cipher implementation in C99.
 ## Why One-Time Pads
@@ -41,8 +40,6 @@ To address this problem, we can use Nostr to share among devices the place in th
 One-time pads can be trivially encrypted and decrypted using pencil and paper, making them accessible even without electronic devices.
 ## Features
 - **Perfect Security**: Implements true one-time pad encryption with information-theoretic security
@@ -57,106 +54,134 @@ One-time pads can be trivially encrypted and decrypted using pencil and paper, m
 - **Cross-Platform**: Works on Linux and other UNIX-like systems
-## Building
+## Quick Start
 ### Download Pre-Built Binaries
 **[Download Current Linux x86](https://git.laantungir.net/laantungir/otp/releases/download/v0.3.42/otp-v0.3.42-linux-x86_64)**
 **[Download Current Raspberry Pi 64](https://git.laantungir.net/laantungir/otp/releases/download/v0.3.42/otp-v0.3.42-linux-arm64)**
 After downloading:
 ```bash
 # Rename for convenience, then make executable
 mv otp-v0.3.42-linux-x86_64 otp
 chmod +x otp
 # Run it
 ./otp
 ```
 ### First Steps
 1. **Generate your first pad:**
   ```bash
   ./otp generate 1GB
   ```
 2. **Encrypt a message:**
   ```bash
   ./otp encrypt
   # Follow the interactive prompts
   ```
 3. **Decrypt a message:**
   ```bash
   ./otp decrypt
   # Paste the encrypted message
   ```
 ## Building from Source
 ### Prerequisites
 - GCC compiler
 - Git (for version tracking)
 - Make
 ### Build Commands
 Use the included build script for automatic versioning:
 ```bash
-# Standard build (default)
+make            # Build for current architecture
-./build.sh build
+make static     # Static linking (standalone binary)
-
+make clean      # Clean build artifacts
-# Static linking build
+make install    # Install to /usr/local/bin/otp
-./build.sh static
+make uninstall  # Remove from system
 # Clean build artifacts
 ./build.sh clean
 # Generate version files only
 ./build.sh version
 # Install to system
 ./build.sh install
 # Remove from system
 ./build.sh uninstall
 # Show usage
 ./build.sh help
 ```
-### Traditional Make
+Output: `build/otp-$(ARCH)` (e.g., `build/otp-x86_64`)
 You can also use make directly (without automatic versioning):
 After building, run with:
 ```bash
-make            # Standard build
+./build/otp-x86_64
 make static     # Static linking
 make clean      # Clean artifacts
 make install    # Install to /usr/local/bin/
 make uninstall  # Remove from system
 ```
 ## Usage
 The OTP Cipher operates in two modes:
 **Interactive Mode**: Run without arguments to access a menu-driven interface. Best for exploring features, managing pads, and performing operations step-by-step with prompts and guidance.
 **Command Line Mode**: Provide arguments to execute specific operations directly. Ideal for scripting, automation, and quick one-off tasks.
 ### Interactive Mode
 Launch the menu-driven interface:
 ```bash
 ./otp
 ```
 Navigate through menus to generate pads, encrypt/decrypt messages, manage pads, and configure settings.
 ### Command Line Mode
 Execute operations directly with arguments:
 ```bash
 # Generate a new pad
 ./otp generate 1GB
-# Encrypt text (interactive input)
+# Encrypt text (will prompt for input)
 ./otp encrypt <pad_hash_or_prefix>
-# Decrypt message (interactive input)  
+# Decrypt message (will prompt for input)
 ./otp decrypt <pad_hash_or_prefix>
 # List available pads
 ./otp list
 ```
-## Version System Details
+## Version System
 ### Centralized Version Management
 Version is defined in a single location: `src/main.h`
 ```c
 #define OTP_VERSION "v0.3.24"
 ```
 All code references this constant, ensuring consistency across:
 - Main menu display
 - ASCII armor output
 - Help/usage text
 ### Automatic Version Increment
-Every build automatically increments the patch version:
+The `build.sh` script automatically:
- v0.1.0 → v0.1.1 → v0.1.2, etc.
+1. Increments patch version (v0.3.24 → v0.3.25)
- Creates git tags for each version
+2. Updates `OTP_VERSION` in `src/main.h`
- Embeds detailed build information
+3. Creates git commit and tag
 4. Pushes to remote repository
 ### Manual Version Control
 For major/minor releases, create tags manually:
 ```bash
 # Feature release (minor bump)
-git tag v0.2.0    # Next build: v0.2.1
+git tag v0.4.0    # Next build: v0.4.1
-# Breaking change (major bump)  
+# Breaking change (major bump)
 git tag v1.0.0    # Next build: v1.0.1
 ```
 ### Version Information Available
 - Version number (major.minor.patch)
 - Git commit hash and branch
 - Build date and time
 - Full version display with metadata
 ### Generated Files
 The build system automatically manages Git versioning by incrementing tags.
 These files are excluded from git (.gitignore) and regenerated on each build.
 ## Security Features
 - Uses `/dev/urandom` for cryptographically secure random number generation
@@ -166,28 +191,32 @@ These files are excluded from git (.gitignore) and regenerated on each build.
 - State tracking to prevent pad reuse
 - **Zero external crypto dependencies** - completely self-contained implementation
-## File Structure
+## Project Structure
 ```
 otp/
-├── build.sh          # Build script with automatic versioning
+├── build.sh              # Build script with automatic versioning
-├── Makefile         # Traditional make build system
+├── Makefile             # Traditional make build system
-├── otp.c            # Legacy compatibility and global definitions
+├── README.md            # This file
-├── README.md        # This file
+├── .gitignore           # Git ignore rules
 ├── .gitignore       # Git ignore rules
 ├── include/
 │   └── otp.h        # Public API header with all function prototypes
 ├── src/
-│   ├── main.c       # Main application entry point and command line handling
+│   ├── main.h           # Main header with all prototypes and OTP_VERSION
-│   ├── ui.c         # Interactive user interface and menu system
+│   ├── main.c           # Application entry point and command line handling
-│   ├── state.c      # Global state management (pads directory, terminal dimensions)
+│   ├── ui.c             # Interactive user interface and menu system
-│   ├── crypto.c     # Core cryptographic operations (XOR, ChaCha20)
+│   ├── state.c          # Global state management (pads directory, preferences)
-│   ├── pads.c       # Pad management and file operations
+│   ├── crypto.c         # Core cryptographic operations (XOR, base64)
-│   ├── entropy.c    # Entropy collection from various sources
+│   ├── pads.c           # Pad management and file operations
-│   ├── trng.c       # Hardware RNG device detection and entropy collection
+│   ├── entropy.c        # Entropy collection from various sources
-│   └── util.c       # Utility functions and helpers
+│   ├── trng.c           # Hardware RNG device detection and collection
-├── pads/            # OTP pad storage directory (created at runtime)
+│   ├── util.c           # Utility functions and helpers
-└── VERSION          # Plain text version (generated)
+│   ├── nostr_chacha20.c # ChaCha20 implementation for entropy expansion
 │   └── nostr_chacha20.h # ChaCha20 header
 ├── build/
 │   ├── otp-x86_64       # Native x86_64 binary (created by build)
 │   └── otp-arm64        # ARM64 binary (created by cross-compilation)
 ├── pads/                # OTP pad storage directory (created at runtime)
 ├── files/               # Encrypted file storage (created at runtime)
 └── tests/               # Test scripts and utilities
 ```
 ## Architecture
@@ -197,13 +226,14 @@ The OTP cipher uses a modular architecture with clean separation of concerns:
 - **main.c**: Application entry point, command line parsing, and mode selection
 - **ui.c**: Interactive user interface, menus, and terminal management
 - **state.c**: Global state management (pads directory, terminal dimensions, preferences)
- **crypto.c**: Core cryptographic operations (XOR encryption, ChaCha20 entropy mixing)
+- **crypto.c**: Core cryptographic operations (XOR encryption, base64 encoding)
 - **pads.c**: Pad file management, checksums, and state tracking
- **entropy.c**: Entropy collection from keyboard, dice, and other sources
+- **entropy.c**: Entropy collection from keyboard, dice, files, and hardware RNG
 - **trng.c**: Hardware RNG device detection and entropy collection from USB devices
 - **util.c**: Utility functions, file operations, and helper routines
 - **nostr_chacha20.c**: ChaCha20 stream cipher for entropy expansion
-All modules share a common header (`include/otp.h`) that defines the public API and data structures.
+All modules share a common header (`src/main.h`) that defines the public API, data structures, and version constant.
 ## Hardware RNG Device Support
@@ -401,13 +431,48 @@ No.  ChkSum (first 16 chars) Size         Used         % Used
 # Select "S" for show pad info, enter checksum or prefix
 ```
 ## Important Notes
 ### Size Units: Decimal (SI) vs Binary (IEC)
 **This program uses decimal (SI) units for all size specifications**, matching the behavior of most system tools like `ls -lh`, `df -h`, and file managers:
 - **1 KB** = 1,000 bytes (not 1,024)
 - **1 MB** = 1,000,000 bytes (not 1,048,576)
 - **1 GB** = 1,000,000,000 bytes (not 1,073,741,824)
 - **1 TB** = 1,000,000,000,000 bytes (not 1,099,511,627,776)
 **Why decimal units?**
 - Consistency with system tools (`ls`, `df`, file managers)
 - Matches storage device marketing (a "1TB" USB drive has ~1,000,000,000,000 bytes)
 - Avoids confusion when comparing sizes across different tools
 - Industry standard for storage devices and file systems
 **Example:** When you request a 100GB pad, the program creates exactly 100,000,000,000 bytes, which will display as "100GB" in `ls -lh` and your file manager.
 **Note:** Some technical tools may use binary units (GiB, MiB) where 1 GiB = 1,024³ bytes. This program intentionally uses decimal units for user-friendliness and consistency with common tools.
 ## License
 This project includes automatic versioning system based on the Generic Automatic Version Increment System.
 ## State Files
 Pad state files (`.state`) use a human-readable text format:
 ```
 offset=1234567890
 ```
 This tracks how many bytes of each pad have been used. The format is:
 - **Human-readable**: Can inspect with `cat checksum.state`
 - **Backward compatible**: Automatically reads old binary format
 - **Easy to debug**: Can manually edit if needed
 ## Contributing
 When contributing:
-1. The version will automatically increment on builds
+1. The version will automatically increment on builds via `build.sh`
-2. For major features, consider manually creating minor version tags
+2. Version is centralized in `src/main.h` as `OTP_VERSION`
-3. Generated version files (`src/version.*`, `VERSION`) should not be committed
+3. For major features, manually create minor/major version tags
 4. Build artifacts in `build/` and object files are auto-cleaned
--- a/TODO.md
+++ b/TODO.md
@@ -1,3 +0,0 @@
 # TODO
 ## The pad menu in interactive encrypt mode gives numbers instead of checksum selection
--- a/build.sh
+++ b/build.sh
@@ -146,20 +146,53 @@ increment_version() {
 update_source_version() {
    local NEW_VERSION="$1"
-    print_status "Updating version strings in source code..."
+    print_status "Updating version constant in source code..."
-    # Replace hardcoded version strings in src/otp.c with the current git tag
+    # Update OTP_VERSION constant in src/main.h
-    if [ -f "src/otp.c" ]; then
+    if [ -f "src/main.h" ]; then
-        # Update main menu version
+        sed -i "s/#define OTP_VERSION \"v[0-9]\+\.[0-9]\+\.[0-9]\+\"/#define OTP_VERSION \"$NEW_VERSION\"/g" src/main.h
-        sed -i "s/OTP v[0-9]\+\.[0-9]\+\.[0-9]\+/OTP $NEW_VERSION/g" src/otp.c
+        print_success "Updated OTP_VERSION in src/main.h to $NEW_VERSION"
        # Update ASCII output version
        sed -i "s/Version: v[0-9]\+\.[0-9]\+\.[0-9]\+/Version: $NEW_VERSION/g" src/otp.c
        # Update usage/help text version
        sed -i "s/Implementation v[0-9]\+\.[0-9]\+\.[0-9]\+/Implementation $NEW_VERSION/g" src/otp.c
        print_success "Updated version strings in src/otp.c to $NEW_VERSION"
    else
-        print_warning "src/otp.c not found - skipping version string updates"
+        print_warning "src/main.h not found - skipping version update"
    fi
    # Update README.md with direct download links
    if [ -f "README.md" ]; then
        print_status "Updating README.md with download links for $NEW_VERSION..."
        # Create the new download section with direct download links
        local NEW_DOWNLOAD_SECTION="### Download Pre-Built Binaries
 **[Download Current Linux x86](https://git.laantungir.net/laantungir/otp/releases/download/${NEW_VERSION}/otp-${NEW_VERSION}-linux-x86_64)**
 **[Download Current Raspberry Pi 64](https://git.laantungir.net/laantungir/otp/releases/download/${NEW_VERSION}/otp-${NEW_VERSION}-linux-arm64)**
 After downloading:
 \`\`\`bash
 # Rename for convenience, then make executable
 mv otp-${NEW_VERSION}-linux-x86_64 otp
 chmod +x otp
 # Run it
 ./otp
 \`\`\`"
        # Use awk to replace the section between "### Download Pre-Built Binaries" and "### First Steps"
        awk -v new_section="$NEW_DOWNLOAD_SECTION" '
            /^### Download Pre-Built Binaries/ {
                print new_section
                skip=1
                next
            }
            /^### First Steps/ {
                skip=0
            }
            !skip
        ' README.md > README.md.tmp && mv README.md.tmp README.md
        print_success "Updated README.md with download links for $NEW_VERSION"
    else
        print_warning "README.md not found - skipping README update"
    fi
 }
@@ -289,6 +322,10 @@ build_project() {
        fi
    fi
    # Clean up object files after successful build
    print_status "Cleaning up object files..."
    rm -f src/*.o
    # Create Gitea release with binaries
    if [ -f "$HOME/.gitea_token" ]; then
        create_gitea_release "$NEW_VERSION"
--- a/BIN
+++ b/BIN
--- a/debug.c
+++ b/debug.c
@@ -1 +0,0 @@
 int main() { printf("Testing direct filename: %d\n", strncmp("97d9d82b5414a9439102f3811fb90ab1d6368a00d33229a18b306476f9d04f82.pad", "97", 2)); return 0; }
--- a/manual_test.sh
+++ b/manual_test.sh
@@ -1,22 +0,0 @@
 #!/bin/bash
 echo "Manual OTP Test"
 echo "==============="
 # Generate a test pad
 echo "Generating test pad..."
 ./otp generate demo 1
 echo
 # Create a test message file for encryption
 echo "Creating test message..."
 echo "This is a secret message for testing OTP encryption!" > test_message.txt
 # Test encryption interactively
 echo "Testing encryption (will prompt for input):"
 echo "Please enter: This is a secret message for testing OTP encryption!"
 ./otp encrypt demo
 echo
 echo "Files created:"
 ls -la demo.*
--- a/1
+++ b/1
@@ -0,0 +1 @@
 ./build/otp-x86_64
--- a/src/archive.c
+++ b/src/archive.c
@@ -0,0 +1,493 @@
 #define _POSIX_C_SOURCE 200809L
 #define _DEFAULT_SOURCE
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <stdint.h>
 #include <unistd.h>
 #include <sys/stat.h>
 #include <dirent.h>
 #include <time.h>
 #include "main.h"
 #include "microtar/microtar.h"
 // Suppress warnings from miniz header
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wunused-function"
 #include "miniz/miniz.h"
 #pragma GCC diagnostic pop
 ////////////////////////////////////////////////////////////////////////////////
 //      DIRECTORY ARCHIVING FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Helper function to recursively add directory contents to TAR archive
 static int add_directory_to_tar(mtar_t* tar, const char* base_path, const char* relative_path) {
    DIR* dir = opendir(base_path);
    if (!dir) {
        printf("Error: Cannot open directory '%s'\n", base_path);
        return 1;
    }
    struct dirent* entry;
    while ((entry = readdir(dir)) != NULL) {
        // Skip . and ..
        if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) {
            continue;
        }
        // Build full path
        char full_path[2048];
        snprintf(full_path, sizeof(full_path), "%s/%s", base_path, entry->d_name);
        // Build relative path for TAR
        char tar_path[2048];
        if (strlen(relative_path) > 0) {
            snprintf(tar_path, sizeof(tar_path), "%s/%s", relative_path, entry->d_name);
        } else {
            snprintf(tar_path, sizeof(tar_path), "%s", entry->d_name);
        }
        struct stat st;
        if (stat(full_path, &st) != 0) {
            printf("Warning: Cannot stat '%s', skipping\n", full_path);
            continue;
        }
        if (S_ISDIR(st.st_mode)) {
            // Recursively add subdirectory
            if (add_directory_to_tar(tar, full_path, tar_path) != 0) {
                closedir(dir);
                return 1;
            }
        } else if (S_ISREG(st.st_mode)) {
            // Add regular file
            FILE* fp = fopen(full_path, "rb");
            if (!fp) {
                printf("Warning: Cannot open '%s', skipping\n", full_path);
                continue;
            }
            // Get file size
            fseek(fp, 0, SEEK_END);
            size_t file_size = ftell(fp);
            fseek(fp, 0, SEEK_SET);
            // Read file data
            unsigned char* file_data = malloc(file_size);
            if (!file_data) {
                printf("Error: Memory allocation failed for '%s'\n", full_path);
                fclose(fp);
                closedir(dir);
                return 1;
            }
            size_t bytes_read = fread(file_data, 1, file_size, fp);
            fclose(fp);
            if (bytes_read != file_size) {
                printf("Warning: Could not read entire file '%s', skipping\n", full_path);
                free(file_data);
                continue;
            }
            // Write to TAR
            if (mtar_write_file_header(tar, tar_path, file_size) != MTAR_ESUCCESS) {
                printf("Error: Failed to write TAR header for '%s'\n", tar_path);
                free(file_data);
                closedir(dir);
                return 1;
            }
            if (mtar_write_data(tar, file_data, file_size) != MTAR_ESUCCESS) {
                printf("Error: Failed to write TAR data for '%s'\n", tar_path);
                free(file_data);
                closedir(dir);
                return 1;
            }
            free(file_data);
        }
    }
    closedir(dir);
    return 0;
 }
 // Create TAR archive from directory
 int create_tar_archive(const char* dir_path, const char* tar_output_path) {
    mtar_t tar;
    if (mtar_open(&tar, tar_output_path, "w") != MTAR_ESUCCESS) {
        printf("Error: Cannot create TAR file '%s'\n", tar_output_path);
        return 1;
    }
    // Get directory name for relative paths
    char dir_name[512];
    const char* last_slash = strrchr(dir_path, '/');
    if (last_slash) {
        strncpy(dir_name, last_slash + 1, sizeof(dir_name) - 1);
    } else {
        strncpy(dir_name, dir_path, sizeof(dir_name) - 1);
    }
    dir_name[sizeof(dir_name) - 1] = '\0';
    // Add directory contents to TAR
    int result = add_directory_to_tar(&tar, dir_path, dir_name);
    // Finalize and close TAR
    mtar_finalize(&tar);
    mtar_close(&tar);
    return result;
 }
 // Extract TAR archive to directory
 int extract_tar_archive(const char* tar_path, const char* output_dir) {
    mtar_t tar;
    mtar_header_t header;
    if (mtar_open(&tar, tar_path, "r") != MTAR_ESUCCESS) {
        printf("Error: Cannot open TAR file '%s'\n", tar_path);
        return 1;
    }
    // Create output directory if it doesn't exist
    mkdir(output_dir, 0755);
    // Extract each file
    while (mtar_read_header(&tar, &header) == MTAR_ESUCCESS) {
        char output_path[2048];
        snprintf(output_path, sizeof(output_path), "%s/%s", output_dir, header.name);
        // Create parent directories
        char* last_slash = strrchr(output_path, '/');
        if (last_slash) {
            char parent_dir[2048];
            strncpy(parent_dir, output_path, last_slash - output_path);
            parent_dir[last_slash - output_path] = '\0';
            // Create directories recursively
            char* p = parent_dir;
            while (*p) {
                if (*p == '/') {
                    *p = '\0';
                    mkdir(parent_dir, 0755);
                    *p = '/';
                }
                p++;
            }
            mkdir(parent_dir, 0755);
        }
        // Extract file data
        unsigned char* data = malloc(header.size);
        if (!data) {
            printf("Error: Memory allocation failed\n");
            mtar_close(&tar);
            return 1;
        }
        if (mtar_read_data(&tar, data, header.size) != MTAR_ESUCCESS) {
            printf("Error: Failed to read data for '%s'\n", header.name);
            free(data);
            mtar_close(&tar);
            return 1;
        }
        // Write to file
        FILE* fp = fopen(output_path, "wb");
        if (!fp) {
            printf("Error: Cannot create file '%s'\n", output_path);
            free(data);
            mtar_close(&tar);
            return 1;
        }
        fwrite(data, 1, header.size, fp);
        fclose(fp);
        free(data);
        mtar_next(&tar);
    }
    mtar_close(&tar);
    return 0;
 }
 ////////////////////////////////////////////////////////////////////////////////
 //      COMPRESSION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Compress file with gzip (miniz)
 int compress_file_gzip(const char* input_path, const char* output_path) {
    // Read input file
    FILE* in = fopen(input_path, "rb");
    if (!in) {
        printf("Error: Cannot open input file '%s'\n", input_path);
        return 1;
    }
    fseek(in, 0, SEEK_END);
    size_t input_size = ftell(in);
    fseek(in, 0, SEEK_SET);
    unsigned char* input_data = malloc(input_size);
    if (!input_data) {
        printf("Error: Memory allocation failed\n");
        fclose(in);
        return 1;
    }
    size_t bytes_read = fread(input_data, 1, input_size, in);
    fclose(in);
    if (bytes_read != input_size) {
        printf("Error: Failed to read input file\n");
        free(input_data);
        return 1;
    }
    // Compress with miniz
    mz_ulong compressed_size = compressBound(input_size);
    unsigned char* compressed_data = malloc(compressed_size);
    if (!compressed_data) {
        printf("Error: Memory allocation failed\n");
        free(input_data);
        return 1;
    }
    int result = compress2(compressed_data, &compressed_size,
                          input_data, input_size,
                          MZ_BEST_COMPRESSION);
    free(input_data);
    if (result != MZ_OK) {
        printf("Error: Compression failed (error code: %d)\n", result);
        free(compressed_data);
        return 1;
    }
    // Write compressed data
    FILE* out = fopen(output_path, "wb");
    if (!out) {
        printf("Error: Cannot create output file '%s'\n", output_path);
        free(compressed_data);
        return 1;
    }
    fwrite(compressed_data, 1, compressed_size, out);
    fclose(out);
    free(compressed_data);
    return 0;
 }
 // Decompress gzip file (miniz)
 int decompress_file_gzip(const char* input_path, const char* output_path) {
    // Read compressed file
    FILE* in = fopen(input_path, "rb");
    if (!in) {
        printf("Error: Cannot open compressed file '%s'\n", input_path);
        return 1;
    }
    fseek(in, 0, SEEK_END);
    size_t compressed_size = ftell(in);
    fseek(in, 0, SEEK_SET);
    unsigned char* compressed_data = malloc(compressed_size);
    if (!compressed_data) {
        printf("Error: Memory allocation failed\n");
        fclose(in);
        return 1;
    }
    size_t bytes_read = fread(compressed_data, 1, compressed_size, in);
    fclose(in);
    if (bytes_read != compressed_size) {
        printf("Error: Failed to read compressed file\n");
        free(compressed_data);
        return 1;
    }
    // Estimate decompressed size (try multiple times if needed)
    mz_ulong output_size = compressed_size * 10;
    unsigned char* output_data = NULL;
    int result;
    for (int attempt = 0; attempt < 3; attempt++) {
        output_data = realloc(output_data, output_size);
        if (!output_data) {
            printf("Error: Memory allocation failed\n");
            free(compressed_data);
            return 1;
        }
        mz_ulong temp_size = output_size;
        result = uncompress(output_data, &temp_size, compressed_data, compressed_size);
        if (result == MZ_OK) {
            output_size = temp_size;
            break;
        } else if (result == MZ_BUF_ERROR) {
            // Buffer too small, try larger
            output_size *= 2;
        } else {
            printf("Error: Decompression failed (error code: %d)\n", result);
            free(compressed_data);
            free(output_data);
            return 1;
        }
    }
    free(compressed_data);
    if (result != MZ_OK) {
        printf("Error: Decompression failed after multiple attempts\n");
        free(output_data);
        return 1;
    }
    // Write decompressed data
    FILE* out = fopen(output_path, "wb");
    if (!out) {
        printf("Error: Cannot create output file '%s'\n", output_path);
        free(output_data);
        return 1;
    }
    fwrite(output_data, 1, output_size, out);
    fclose(out);
    free(output_data);
    return 0;
 }
 ////////////////////////////////////////////////////////////////////////////////
 //      HIGH-LEVEL DIRECTORY ENCRYPTION/DECRYPTION
 ////////////////////////////////////////////////////////////////////////////////
 // Encrypt directory: TAR → GZIP → Encrypt
 int encrypt_directory(const char* dir_path, const char* pad_identifier, const char* output_file) {
    char temp_tar[512];
    char temp_gz[512];
    int result = 0;
    // Generate temporary file paths
    snprintf(temp_tar, sizeof(temp_tar), "/tmp/otp_tar_%d.tar", getpid());
    snprintf(temp_gz, sizeof(temp_gz), "/tmp/otp_gz_%d.tar.gz", getpid());
    printf("Creating TAR archive...\n");
    if (create_tar_archive(dir_path, temp_tar) != 0) {
        printf("Error: Failed to create TAR archive\n");
        return 1;
    }
    printf("Compressing archive...\n");
    if (compress_file_gzip(temp_tar, temp_gz) != 0) {
        printf("Error: Failed to compress archive\n");
        unlink(temp_tar);
        return 1;
    }
    printf("Encrypting compressed archive...\n");
    result = encrypt_file(pad_identifier, temp_gz, output_file, 0);
    // Cleanup temporary files
    unlink(temp_tar);
    unlink(temp_gz);
    if (result == 0) {
        printf("Directory encrypted successfully: %s\n", output_file);
    }
    return result;
 }
 // Detect if file is a compressed TAR archive
 int is_compressed_tar_archive(const char* file_path) {
    FILE* fp = fopen(file_path, "rb");
    if (!fp) {
        return 0;
    }
    unsigned char magic[512];
    size_t bytes_read = fread(magic, 1, sizeof(magic), fp);
    fclose(fp);
    if (bytes_read < 2) {
        return 0;
    }
    // Check for GZIP magic bytes (0x1f 0x8b)
    if (magic[0] == 0x1f && magic[1] == 0x8b) {
        return 1;
    }
    // Check for TAR magic ("ustar" at offset 257)
    if (bytes_read >= 262 && memcmp(magic + 257, "ustar", 5) == 0) {
        return 1;
    }
    return 0;
 }
 // Decrypt and extract directory: Decrypt → GUNZIP → Extract TAR
 int decrypt_and_extract_directory(const char* encrypted_file, const char* output_dir) {
    char temp_decrypted[512];
    char temp_tar[512];
    int result = 0;
    // Generate temporary file paths
    snprintf(temp_decrypted, sizeof(temp_decrypted), "/tmp/otp_decrypt_%d", getpid());
    snprintf(temp_tar, sizeof(temp_tar), "/tmp/otp_tar_%d.tar", getpid());
    printf("Decrypting file...\n");
    if (decrypt_file(encrypted_file, temp_decrypted) != 0) {
        printf("Error: Failed to decrypt file\n");
        return 1;
    }
    // Check if it's compressed
    FILE* fp = fopen(temp_decrypted, "rb");
    if (!fp) {
        printf("Error: Cannot open decrypted file\n");
        unlink(temp_decrypted);
        return 1;
    }
    unsigned char magic[2];
    fread(magic, 1, 2, fp);
    fclose(fp);
    if (magic[0] == 0x1f && magic[1] == 0x8b) {
        // GZIP compressed
        printf("Decompressing archive...\n");
        if (decompress_file_gzip(temp_decrypted, temp_tar) != 0) {
            printf("Error: Failed to decompress archive\n");
            unlink(temp_decrypted);
            return 1;
        }
        unlink(temp_decrypted);
    } else {
        // Not compressed, assume it's already TAR
        rename(temp_decrypted, temp_tar);
    }
    printf("Extracting archive...\n");
    result = extract_tar_archive(temp_tar, output_dir);
    // Cleanup
    unlink(temp_tar);
    if (result == 0) {
        printf("Directory extracted successfully to: %s\n", output_dir);
    }
    return result;
 }
--- a/src/crypto.c
+++ b/src/crypto.c
@@ -5,7 +5,7 @@
 #include <stdio.h>
 #include <time.h>
 #include <unistd.h>
-#include "otp.h"
+#include "main.h"
 #define PROGRESS_UPDATE_INTERVAL (64 * 1024 * 1024)  // 64MB intervals
@@ -198,7 +198,7 @@ int generate_ascii_armor(const char* chksum, uint64_t offset, const unsigned cha
    strcpy(*ascii_output, "-----BEGIN OTP MESSAGE-----\n");
    char temp_line[256];
-    snprintf(temp_line, sizeof(temp_line), "Version: v0.3.16\n");
+    snprintf(temp_line, sizeof(temp_line), "Version: %s\n", OTP_VERSION);
    strcat(*ascii_output, temp_line);
    snprintf(temp_line, sizeof(temp_line), "Pad-ChkSum: %s\n", chksum);
@@ -297,7 +297,6 @@ int encrypt_text(const char* pad_identifier, const char* input_text) {
    }
    char text_buffer[MAX_INPUT_SIZE];
    char chksum_hex[MAX_HASH_LENGTH];
    uint64_t current_offset;
    char pad_path[MAX_HASH_LENGTH + 20];
@@ -327,12 +326,8 @@ int encrypt_text(const char* pad_identifier, const char* input_text) {
        }
    }
-    // Calculate XOR checksum of pad file
+    // Use pad_chksum directly - it's already the checksum from the filename
-    if (calculate_checksum(pad_path, chksum_hex) != 0) {
+    // No need to recalculate by reading the entire pad file
        printf("Error: Cannot calculate pad checksum\n");
        free(pad_chksum);
        return 1;
    }
    // Get input text - either from parameter or user input
    if (input_text != NULL) {
@@ -464,7 +459,7 @@ int encrypt_text(const char* pad_identifier, const char* input_text) {
    // Use universal ASCII armor generator
    char* ascii_output;
-    if (generate_ascii_armor(chksum_hex, current_offset, ciphertext, input_len, &ascii_output) != 0) {
+    if (generate_ascii_armor(pad_chksum, current_offset, ciphertext, input_len, &ascii_output) != 0) {
        printf("Error: Failed to generate ASCII armor\n");
        free(pad_data);
        free(ciphertext);
@@ -746,7 +741,6 @@ int encrypt_file(const char* pad_identifier, const char* input_file, const char*
        return 1;
    }
    char chksum_hex[MAX_HASH_LENGTH];
    uint64_t current_offset;
    char pad_path[MAX_HASH_LENGTH + 20];
@@ -791,12 +785,8 @@ int encrypt_file(const char* pad_identifier, const char* input_file, const char*
        }
    }
-    // Calculate XOR checksum of pad file
+    // Use pad_chksum directly - it's already the checksum from the filename
-    if (calculate_checksum(pad_path, chksum_hex) != 0) {
+    // No need to recalculate by reading the entire pad file
        printf("Error: Cannot calculate pad checksum\n");
        free(pad_chksum);
        return 1;
    }
    // Check if we have enough pad space
    struct stat pad_stat;
@@ -927,7 +917,7 @@ int encrypt_file(const char* pad_identifier, const char* input_file, const char*
        // Use universal ASCII armor generator
        char* ascii_output;
-        if (generate_ascii_armor(chksum_hex, current_offset, encrypted_data, file_size, &ascii_output) != 0) {
+        if (generate_ascii_armor(pad_chksum, current_offset, encrypted_data, file_size, &ascii_output) != 0) {
            printf("Error: Failed to generate ASCII armor\n");
            fclose(output_fp);
            free(encrypted_data);
@@ -961,7 +951,7 @@ int encrypt_file(const char* pad_identifier, const char* input_file, const char*
        // Pad checksum: 32 bytes (binary)
        unsigned char pad_chksum_bin[32];
        for (int i = 0; i < 32; i++) {
-            sscanf(chksum_hex + i*2, "%2hhx", &pad_chksum_bin[i]);
+            sscanf(pad_chksum + i*2, "%2hhx", &pad_chksum_bin[i]);
        }
        fwrite(pad_chksum_bin, 1, 32, output_fp);
--- a/src/entropy.c
+++ b/src/entropy.c
@@ -16,7 +16,7 @@
 #include <fcntl.h>
 #include <math.h>
 #include "nostr_chacha20.h"
-#include "otp.h"
+#include "main.h"
 // In-place pad entropy addition using Chacha20 or direct XOR
@@ -82,7 +82,7 @@ int add_entropy_direct_xor(const char* pad_chksum, const unsigned char* entropy_
    if (display_progress) {
        printf("Adding entropy to pad using direct XOR...\n");
-        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1024.0*1024.0*1024.0), pad_size);
+        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1000.0*1000.0*1000.0), pad_size);
        printf("Entropy size: %zu bytes\n", entropy_size);
    }
@@ -212,15 +212,29 @@ int add_entropy_chacha20(const char* pad_chksum, const unsigned char* entropy_da
    if (display_progress) {
        printf("Adding entropy to pad using Chacha20...\n");
-        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1024.0*1024.0*1024.0), pad_size);
+        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1000.0*1000.0*1000.0), pad_size);
    }
    // Process pad in chunks
    unsigned char buffer[64 * 1024]; // 64KB chunks
    unsigned char keystream[64 * 1024];
    uint64_t offset = 0;
-    uint32_t counter = 0;
+    uint32_t counter_low = 0;
    uint32_t counter_high = 0;
    time_t start_time = time(NULL);
    // Use extended counter for pads larger than 256GB
    // 256GB = 2^32 blocks * 64 bytes = 274,877,906,944 bytes
    int use_extended = (pad_size > 274877906944ULL);
    // For extended mode, use reduced 8-byte nonce
    unsigned char nonce_reduced[8];
    if (use_extended) {
        memcpy(nonce_reduced, nonce + 4, 8);
        if (display_progress) {
            printf("Using extended counter mode for large pad (>256GB)\n");
        }
    }
    while (offset < pad_size) {
        size_t chunk_size = sizeof(buffer);
@@ -237,7 +251,15 @@ int add_entropy_chacha20(const char* pad_chksum, const unsigned char* entropy_da
        }
        // Generate keystream for this chunk
-        if (chacha20_encrypt(key, counter, nonce, buffer, keystream, chunk_size) != 0) {
+        int chacha_result;
        if (use_extended) {
            chacha_result = chacha20_encrypt_extended(key, counter_low, counter_high,
                                                      nonce_reduced, buffer, keystream, chunk_size);
        } else {
            chacha_result = chacha20_encrypt(key, counter_low, nonce, buffer, keystream, chunk_size);
        }
        if (chacha_result != 0) {
            printf("Error: Chacha20 keystream generation failed\n");
            fclose(pad_file);
            chmod(pad_path, S_IRUSR);
@@ -265,7 +287,16 @@ int add_entropy_chacha20(const char* pad_chksum, const unsigned char* entropy_da
        }
        offset += chunk_size;
-        counter += (chunk_size + 63) / 64; // Round up for block count
+        
        // Update counters
        uint32_t blocks = (chunk_size + 63) / 64; // Round up for block count
        uint32_t old_counter_low = counter_low;
        counter_low += blocks;
        // Check for overflow and increment high counter
        if (counter_low < old_counter_low) {
            counter_high++;
        }
        // Show progress for large pads
        if (display_progress && offset % (64 * 1024 * 1024) == 0) { // Every 64MB
@@ -282,7 +313,8 @@ int add_entropy_chacha20(const char* pad_chksum, const unsigned char* entropy_da
    if (display_progress) {
        show_progress(pad_size, pad_size, start_time);
-        printf("\n✓ Entropy successfully added to pad using Chacha20\n");
+        printf("\n✓ Entropy successfully added to pad using Chacha20%s\n",
               use_extended ? " (extended counter)" : "");
        printf("✓ Pad integrity maintained\n");
        printf("✓ %zu bytes of entropy distributed across entire pad\n", entropy_size);
        printf("✓ Pad restored to read-only mode\n");
@@ -593,8 +625,8 @@ int add_file_entropy_streaming(const char* pad_chksum, const char* file_path, si
    if (display_progress) {
        printf("Adding entropy to pad using streaming direct XOR...\n");
-        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1024.0*1024.0*1024.0), pad_size);
+        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1000.0*1000.0*1000.0), pad_size);
-        printf("Entropy file: %.2f GB (%zu bytes)\n", (double)file_size / (1024.0*1024.0*1024.0), file_size);
+        printf("Entropy file: %.2f GB (%zu bytes)\n", (double)file_size / (1000.0*1000.0*1000.0), file_size);
    }
    // Process in chunks
--- a/src/main.c
+++ b/src/main.c
@@ -15,7 +15,7 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "otp.h"
+#include "main.h"
 int main(int argc, char* argv[]) {
    // Initialize terminal dimensions first
@@ -241,7 +241,7 @@ int command_line_mode(int argc, char* argv[]) {
 }
 void print_usage(const char* program_name) {
-    printf("OTP Cipher - One Time Pad Implementation v0.3.16\n");
+    printf("OTP Cipher - One Time Pad Implementation %s\n", OTP_VERSION);
    printf("Built for testing entropy system\n");
    printf("Usage:\n");
    printf("  %s                                         - Interactive mode\n", program_name);
--- a/src/main.h
+++ b/src/main.h
@@ -1,12 +1,12 @@
-#ifndef OTP_H
+#ifndef MAIN_H
-#define OTP_H
+#define MAIN_H
 ////////////////////////////////////////////////////////////////////////////////
-//      OTP CIPHER - FUNCTION PROTOTYPES HEADER
+//      OTP CIPHER - MAIN HEADER FILE
-//      One Time Pad Implementation v0.2.109
+//      One Time Pad Implementation
-//      
+//
-//      This header file contains all function prototypes extracted from otp.c
+//      This header file contains all function prototypes and type definitions
-//      Organized by functional categories for better maintainability
+//      for the OTP Cipher project
 ////////////////////////////////////////////////////////////////////////////////
 #include <stdio.h>
@@ -22,6 +22,9 @@
 #include <string.h>
 #include <ctype.h>
 // Version - Updated automatically by build.sh
 #define OTP_VERSION "v0.3.42"
 // Constants
 #define MAX_INPUT_SIZE 4096
 #define MAX_LINE_LENGTH 1024
@@ -127,6 +130,7 @@ char* get_preferred_editor(void);
 char* get_preferred_file_manager(void);
 int launch_text_editor(const char* initial_content, char* result_buffer, size_t buffer_size);
 int launch_file_manager(const char* start_directory, char* selected_file, size_t buffer_size);
 int launch_directory_manager(const char* start_directory, char* selected_dir, size_t buffer_size);
 ////////////////////////////////////////////////////////////////////////////////
 //      CORE CRYPTOGRAPHIC OPERATIONS
@@ -235,6 +239,23 @@ int update_pad_checksum_after_entropy(const char* old_chksum, char* new_chksum);
 int rename_pad_files_safely(const char* old_chksum, const char* new_chksum);
 int is_pad_unused(const char* pad_chksum);
 ////////////////////////////////////////////////////////////////////////////////
 //      DIRECTORY ARCHIVING AND COMPRESSION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Directory encryption/decryption (TAR + GZIP + OTP)
 int encrypt_directory(const char* dir_path, const char* pad_identifier, const char* output_file);
 int decrypt_and_extract_directory(const char* encrypted_file, const char* output_dir);
 int is_compressed_tar_archive(const char* file_path);
 // TAR archive operations
 int create_tar_archive(const char* dir_path, const char* tar_output_path);
 int extract_tar_archive(const char* tar_path, const char* output_dir);
 // Compression operations
 int compress_file_gzip(const char* input_path, const char* output_path);
 int decompress_file_gzip(const char* input_path, const char* output_path);
 ////////////////////////////////////////////////////////////////////////////////
 //      DIRECTORY MANAGEMENT FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
@@ -311,6 +332,7 @@ int handle_decrypt_menu(void);
 int handle_pads_menu(void);
 int handle_text_encrypt(void);
 int handle_file_encrypt(void);
 int handle_directory_encrypt(void);
 int handle_verify_pad(const char* pad_chksum);
 int handle_delete_pad(const char* pad_chksum);
@@ -335,4 +357,4 @@ char* select_pad_interactive(const char* title, const char* prompt, pad_filter_t
 // Help and usage display
 void print_usage(const char* program_name);
-#endif // OTP_H
+#endif // MAIN_H
--- a/src/nostr_chacha20.c
+++ b/src/nostr_chacha20.c
@@ -129,8 +129,8 @@ int chacha20_block(const uint8_t key[32], uint32_t counter,
    return 0;
 }
-int chacha20_encrypt(const uint8_t key[32], uint32_t counter, 
+int chacha20_encrypt(const uint8_t key[32], uint32_t counter,
-                     const uint8_t nonce[12], const uint8_t* input, 
+                     const uint8_t nonce[12], const uint8_t* input,
                     uint8_t* output, size_t length) {
    uint8_t keystream[CHACHA20_BLOCK_SIZE];
    size_t offset = 0;
@@ -161,3 +161,45 @@ int chacha20_encrypt(const uint8_t key[32], uint32_t counter,
    return 0;
 }
 int chacha20_encrypt_extended(const uint8_t key[32], uint32_t counter_low,
                               uint32_t counter_high, const uint8_t nonce[8],
                               const uint8_t* input, uint8_t* output, size_t length) {
    uint8_t keystream[CHACHA20_BLOCK_SIZE];
    uint8_t extended_nonce[12];
    size_t offset = 0;
    while (length > 0) {
        /* Build extended 12-byte nonce: [counter_high (4 bytes)][nonce (8 bytes)] */
        u32_to_bytes_le(counter_high, extended_nonce);
        memcpy(extended_nonce + 4, nonce, 8);
        /* Generate keystream block using extended nonce */
        int ret = chacha20_block(key, counter_low, extended_nonce, keystream);
        if (ret != 0) {
            return ret;
        }
        /* XOR with input to produce output */
        size_t block_len = (length < CHACHA20_BLOCK_SIZE) ? length : CHACHA20_BLOCK_SIZE;
        for (size_t i = 0; i < block_len; i++) {
            output[offset + i] = input[offset + i] ^ keystream[i];
        }
        /* Move to next block */
        offset += block_len;
        length -= block_len;
        counter_low++;
        /* Check for counter_low overflow and increment counter_high */
        if (counter_low == 0) {
            counter_high++;
            /* Check for counter_high overflow (extremely unlikely - > 1 exabyte) */
            if (counter_high == 0) {
                return -1; /* Extended counter wrapped around */
            }
        }
    }
    return 0;
 }
--- a/src/nostr_chacha20.h
+++ b/src/nostr_chacha20.h
@@ -63,10 +63,10 @@ int chacha20_block(const uint8_t key[32], uint32_t counter,
 /**
 * ChaCha20 encryption/decryption
- * 
+ *
 * Encrypts or decrypts data using ChaCha20 stream cipher.
 * Since ChaCha20 is a stream cipher, encryption and decryption are the same operation.
- * 
+ *
 * @param key[in]           32-byte key
 * @param counter[in]       Initial 32-bit counter value
 * @param nonce[in]         12-byte nonce
@@ -75,10 +75,29 @@ int chacha20_block(const uint8_t key[32], uint32_t counter,
 * @param length[in]        Length of input data in bytes
 * @return                  0 on success, negative on error
 */
-int chacha20_encrypt(const uint8_t key[32], uint32_t counter, 
+int chacha20_encrypt(const uint8_t key[32], uint32_t counter,
-                     const uint8_t nonce[12], const uint8_t* input, 
+                     const uint8_t nonce[12], const uint8_t* input,
                     uint8_t* output, size_t length);
 /**
 * ChaCha20 encryption/decryption with extended counter (64-bit)
 *
 * Extended version that supports files larger than 256GB by using
 * part of the nonce as a high-order counter extension.
 *
 * @param key[in]           32-byte key
 * @param counter_low[in]   Initial 32-bit counter value (low bits)
 * @param counter_high[in]  Initial 32-bit counter value (high bits)
 * @param nonce[in]         8-byte reduced nonce (instead of 12)
 * @param input[in]         Input data to encrypt/decrypt
 * @param output[out]       Output buffer (can be same as input)
 * @param length[in]        Length of input data in bytes
 * @return                  0 on success, negative on error
 */
 int chacha20_encrypt_extended(const uint8_t key[32], uint32_t counter_low,
                               uint32_t counter_high, const uint8_t nonce[8],
                               const uint8_t* input, uint8_t* output, size_t length);
 /*
 * ============================================================================
 * UTILITY FUNCTIONS
--- a/src/otp.c
+++ b/src/otp.c
@@ -1,35 +0,0 @@
 #define _POSIX_C_SOURCE 200809L
 #define _DEFAULT_SOURCE
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <stdint.h>
 #include <unistd.h>
 #include <sys/stat.h>
 #include <sys/statvfs.h>
 #include <sys/ioctl.h>
 #include <dirent.h>
 #include <time.h>
 #include <ctype.h>
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
 #include "nostr_chacha20.h"
 #include "otp.h"
 #define MAX_INPUT_SIZE 4096
 #define MAX_LINE_LENGTH 1024
 #define MAX_HASH_LENGTH 65
 #define PROGRESS_UPDATE_INTERVAL (64 * 1024 * 1024)  // 64MB intervals
 #define DEFAULT_PADS_DIR "pads"
 #define FILES_DIR "files"
 ////////////////////////////////////////////////////////////////////////////////
 ////////////////////////////////////////////////////////////////////////////////
 //      GLOBAL VARIABLES
 ///////////////////////////////////////////////////////////////////////////////
 ////////////////////////////////////////////////////////////////////////////////
 char current_pads_dir[512] = DEFAULT_PADS_DIR;
--- a/src/pads.c
+++ b/src/pads.c
@@ -16,7 +16,7 @@
 #include <fcntl.h>
 #include <math.h>
 #include <errno.h>
-#include "otp.h"
+#include "main.h"
 // Extracted pad management functions from otp.c
@@ -43,9 +43,9 @@ int show_pad_info(const char* chksum) {
    printf("ChkSum: %s\n", chksum);
    printf("File: %s\n", pad_filename);
-    double size_gb = (double)st.st_size / (1024.0 * 1024.0 * 1024.0);
+    double size_gb = (double)st.st_size / (1000.0 * 1000.0 * 1000.0);
-    double used_gb = (double)used_bytes / (1024.0 * 1024.0 * 1024.0);
+    double used_gb = (double)used_bytes / (1000.0 * 1000.0 * 1000.0);
-    double remaining_gb = (double)(st.st_size - used_bytes) / (1024.0 * 1024.0 * 1024.0);
+    double remaining_gb = (double)(st.st_size - used_bytes) / (1000.0 * 1000.0 * 1000.0);
    printf("Total size: %.2f GB (%lu bytes)\n", size_gb, st.st_size);
    printf("Used: %.2f GB (%lu bytes)\n", used_gb, used_bytes);
@@ -89,15 +89,18 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
    const char* pads_dir = get_current_pads_dir();
    struct statvfs stat;
    if (statvfs(pads_dir, &stat) == 0) {
        // Use f_bavail (available to non-root users) for accurate space reporting
        // This accounts for filesystem reserved space (e.g., 5% on ext4)
        uint64_t available_bytes = stat.f_bavail * stat.f_frsize;
-        double available_gb = (double)available_bytes / (1024.0 * 1024.0 * 1024.0);
+        double available_gb = (double)available_bytes / (1000.0 * 1000.0 * 1000.0);
-        double required_gb = (double)size_bytes / (1024.0 * 1024.0 * 1024.0);
+        double required_gb = (double)size_bytes / (1000.0 * 1000.0 * 1000.0);
        if (available_bytes < size_bytes) {
            printf("\n⚠ WARNING: Insufficient disk space!\n");
-            printf("  Required: %.2f GB\n", required_gb);
+            printf("  Required: %.2f GB (%lu bytes)\n", required_gb, size_bytes);
-            printf("  Available: %.2f GB\n", available_gb);
+            printf("  Available: %.2f GB (%lu bytes)\n", available_gb, available_bytes);
            printf("  Shortfall: %.2f GB\n", required_gb - available_gb);
            printf("  Location: %s\n", pads_dir);
            printf("\nContinue anyway? (y/N): ");
            char response[10];
@@ -126,11 +129,54 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
    FILE* pad_file = fopen(temp_filename, "wb");
    if (!pad_file) {
-        printf("Error: Cannot create temporary pad file %s\n", temp_filename);
+        printf("Error: Cannot create temporary pad file '%s': %s (errno %d)\n",
               temp_filename, strerror(errno), errno);
        fclose(urandom);
        return 1;
    }
    // Preallocate full file size using posix_fallocate for guaranteed space reservation
    // This actually allocates disk blocks (unlike ftruncate which creates sparse files)
    int fd = fileno(pad_file);
    double size_gb = (double)size_bytes / (1000.0 * 1000.0 * 1000.0);
    if (display_progress) {
        printf("Allocating %.2f GB on disk...\n", size_gb);
    }
    int alloc_result = posix_fallocate(fd, 0, (off_t)size_bytes);
    if (alloc_result != 0) {
        printf("Error: Failed to allocate %.2f GB temp file: %s (errno %d)\n",
               size_gb, strerror(alloc_result), alloc_result);
        printf("  Temp file: %s\n", temp_filename);
        printf("  Location: %s\n", pads_dir);
        if (alloc_result == ENOSPC) {
            printf("  Cause: No space left on device\n");
            printf("  This means the actual available space is less than reported\n");
        } else if (alloc_result == EOPNOTSUPP) {
            printf("  Cause: Filesystem doesn't support posix_fallocate\n");
            printf("  Falling back to ftruncate (sparse file)...\n");
            if (ftruncate(fd, (off_t)size_bytes) != 0) {
                printf("  Fallback failed: %s\n", strerror(errno));
                fclose(pad_file);
                fclose(urandom);
                unlink(temp_filename);
                return 1;
            }
        } else {
            printf("  Possible causes: quota limits, filesystem restrictions\n");
            fclose(pad_file);
            fclose(urandom);
            unlink(temp_filename);
            return 1;
        }
    }
    if (display_progress && alloc_result == 0) {
        printf("✓ Allocated %.2f GB on disk (guaranteed space)\n", size_gb);
    }
    unsigned char buffer[64 * 1024]; // 64KB buffer
    uint64_t bytes_written = 0;
    time_t start_time = time(NULL);
@@ -146,7 +192,8 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
        }
        if (fread(buffer, 1, (size_t)chunk_size, urandom) != (size_t)chunk_size) {
-            printf("Error: Failed to read from /dev/urandom\n");
+            printf("Error: Failed to read %lu bytes from /dev/urandom at position %lu: %s (errno %d)\n",
                   chunk_size, bytes_written, strerror(errno), errno);
            fclose(urandom);
            fclose(pad_file);
            unlink(temp_filename);
@@ -154,7 +201,11 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
        }
        if (fwrite(buffer, 1, (size_t)chunk_size, pad_file) != (size_t)chunk_size) {
-            printf("Error: Failed to write to pad file\n");
+            printf("Error: fwrite failed for %lu bytes at position %lu/%lu (%.1f%%): %s (errno %d)\n",
                   chunk_size, bytes_written, size_bytes,
                   (double)bytes_written / size_bytes * 100.0, strerror(errno), errno);
            printf("  Temp file: %s\n", temp_filename);
            printf("  Disk space was checked - possible causes: fragmentation, I/O timeout, quota\n");
            fclose(urandom);
            fclose(pad_file);
            unlink(temp_filename);
@@ -202,10 +253,10 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
    }
    // Initialize state file with offset 32 (first 32 bytes reserved for checksum encryption)
-    FILE* state_file = fopen(state_path, "wb");
+    FILE* state_file = fopen(state_path, "w");
    if (state_file) {
        uint64_t reserved_bytes = 32;
-        fwrite(&reserved_bytes, sizeof(uint64_t), 1, state_file);
+        fprintf(state_file, "offset=%lu\n", reserved_bytes);
        fclose(state_file);
    } else {
        printf("Error: Failed to create state file\n");
@@ -213,8 +264,10 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
        return 1;
    }
-    double size_gb = (double)size_bytes / (1024.0 * 1024.0 * 1024.0);
+    if (display_progress) {
-    printf("Generated pad: %s (%.2f GB)\n", pad_path, size_gb);
+        double final_size_gb = (double)size_bytes / (1000.0 * 1000.0 * 1000.0);
        printf("Generated pad: %s (%.2f GB)\n", pad_path, final_size_gb);
    }
    printf("Pad checksum: %s\n", chksum_hex);
    printf("State file: %s\n", state_path);
    printf("Pad file set to read-only\n");
@@ -233,19 +286,33 @@ int read_state_offset(const char* pad_chksum, uint64_t* offset) {
    const char* pads_dir = get_current_pads_dir();
    snprintf(state_filename, sizeof(state_filename), "%s/%s.state", pads_dir, pad_chksum);
-    FILE* state_file = fopen(state_filename, "rb");
+    FILE* state_file = fopen(state_filename, "r");
    if (!state_file) {
        *offset = 0;
        return 0;
    }
-    if (fread(offset, sizeof(uint64_t), 1, state_file) != 1) {
+    // Read text format only (required format: "offset=<number>")
    char line[128];
    if (fgets(line, sizeof(line), state_file)) {
        // Check if it's text format (starts with "offset=")
        if (strncmp(line, "offset=", 7) == 0) {
            *offset = strtoull(line + 7, NULL, 10);
            fclose(state_file);
            return 0;
        }
        // Not in proper text format - error
        fclose(state_file);
        fprintf(stderr, "Error: State file '%s' is not in proper text format\n", state_filename);
        fprintf(stderr, "Expected format: offset=<number>\n");
        fprintf(stderr, "Please convert old binary state files to text format\n");
        *offset = 0;
-        return 0;
+        return 1;
    }
    fclose(state_file);
    *offset = 0;
    return 0;
 }
@@ -254,12 +321,13 @@ int write_state_offset(const char* pad_chksum, uint64_t offset) {
    const char* pads_dir = get_current_pads_dir();
    snprintf(state_filename, sizeof(state_filename), "%s/%s.state", pads_dir, pad_chksum);
-    FILE* state_file = fopen(state_filename, "wb");
+    FILE* state_file = fopen(state_filename, "w");
    if (!state_file) {
        return 1;
    }
-    if (fwrite(&offset, sizeof(uint64_t), 1, state_file) != 1) {
+    // Write in text format for human readability
    if (fprintf(state_file, "offset=%lu\n", offset) < 0) {
        fclose(state_file);
        return 1;
    }
@@ -358,25 +426,25 @@ char* select_pad_interactive(const char* title, const char* prompt, pad_filter_t
                }
                // Format total size
-                if (st.st_size < 1024) {
+                if (st.st_size < 1000) {
                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%luB", st.st_size);
-                } else if (st.st_size < 1024 * 1024) {
+                } else if (st.st_size < 1000 * 1000) {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fKB", (double)st.st_size / 1024.0);
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fKB", (double)st.st_size / 1000.0);
-                } else if (st.st_size < 1024 * 1024 * 1024) {
+                } else if (st.st_size < 1000 * 1000 * 1000) {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fMB", (double)st.st_size / (1024.0 * 1024.0));
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fMB", (double)st.st_size / (1000.0 * 1000.0));
                } else {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.2fGB", (double)st.st_size / (1024.0 * 1024.0 * 1024.0));
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.2fGB", (double)st.st_size / (1000.0 * 1000.0 * 1000.0));
                }
                // Format used size
-                if (used_bytes < 1024) {
+                if (used_bytes < 1000) {
                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%luB", used_bytes);
-                } else if (used_bytes < 1024 * 1024) {
+                } else if (used_bytes < 1000 * 1000) {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fKB", (double)used_bytes / 1024.0);
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fKB", (double)used_bytes / 1000.0);
-                } else if (used_bytes < 1024 * 1024 * 1024) {
+                } else if (used_bytes < 1000 * 1000 * 1000) {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fMB", (double)used_bytes / (1024.0 * 1024.0));
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fMB", (double)used_bytes / (1000.0 * 1000.0));
                } else {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.2fGB", (double)used_bytes / (1024.0 * 1024.0 * 1024.0));
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.2fGB", (double)used_bytes / (1000.0 * 1000.0 * 1000.0));
                }
                // Calculate percentage
@@ -402,6 +470,13 @@ char* select_pad_interactive(const char* title, const char* prompt, pad_filter_t
        return NULL;
    }
    // If only one pad available, auto-select it
    if (pad_count == 1) {
        printf("\n%s\n", title);
        printf("Only one pad available - auto-selecting: %.16s...\n\n", pads[0].chksum);
        return strdup(pads[0].chksum);
    }
    // Calculate minimal unique prefixes for each pad
    char prefixes[100][65];
    int prefix_lengths[100];
@@ -558,6 +633,27 @@ int handle_pads_menu(void) {
    // Get list of pads from current directory
    const char* pads_dir = get_current_pads_dir();
    // Display directory and space information
    printf("Pads Directory: %s\n", pads_dir);
    // Get filesystem space information
    struct statvfs vfs_stat;
    if (statvfs(pads_dir, &vfs_stat) == 0) {
        uint64_t total_bytes = vfs_stat.f_blocks * vfs_stat.f_frsize;
        uint64_t available_bytes = vfs_stat.f_bavail * vfs_stat.f_frsize;
        uint64_t used_bytes = total_bytes - (vfs_stat.f_bfree * vfs_stat.f_frsize);
        double total_gb = (double)total_bytes / (1000.0 * 1000.0 * 1000.0);
        double available_gb = (double)available_bytes / (1000.0 * 1000.0 * 1000.0);
        double used_gb = (double)used_bytes / (1000.0 * 1000.0 * 1000.0);
        double used_percent = (double)used_bytes / total_bytes * 100.0;
        printf("Drive Space: %.2f GB total, %.2f GB used (%.1f%%), %.2f GB available\n",
               total_gb, used_gb, used_percent, available_gb);
    }
    printf("\n");
    DIR* dir = opendir(pads_dir);
    if (!dir) {
        printf("Error: Cannot open pads directory %s\n", pads_dir);
@@ -593,25 +689,25 @@ int handle_pads_menu(void) {
                read_state_offset(pads[pad_count].chksum, &used_bytes);
                // Format total size
-                if (st.st_size < 1024) {
+                if (st.st_size < 1000) {
                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%luB", st.st_size);
-                } else if (st.st_size < 1024 * 1024) {
+                } else if (st.st_size < 1000 * 1000) {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fKB", (double)st.st_size / 1024.0);
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fKB", (double)st.st_size / 1000.0);
-                } else if (st.st_size < 1024 * 1024 * 1024) {
+                } else if (st.st_size < 1000 * 1000 * 1000) {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fMB", (double)st.st_size / (1024.0 * 1024.0));
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.1fMB", (double)st.st_size / (1000.0 * 1000.0));
                } else {
-                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.2fGB", (double)st.st_size / (1024.0 * 1024.0 * 1024.0));
+                    snprintf(pads[pad_count].size_str, sizeof(pads[pad_count].size_str), "%.2fGB", (double)st.st_size / (1000.0 * 1000.0 * 1000.0));
                }
                // Format used size
-                if (used_bytes < 1024) {
+                if (used_bytes < 1000) {
                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%luB", used_bytes);
-                } else if (used_bytes < 1024 * 1024) {
+                } else if (used_bytes < 1000 * 1000) {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fKB", (double)used_bytes / 1024.0);
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fKB", (double)used_bytes / 1000.0);
-                } else if (used_bytes < 1024 * 1024 * 1024) {
+                } else if (used_bytes < 1000 * 1000 * 1000) {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fMB", (double)used_bytes / (1024.0 * 1024.0));
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.1fMB", (double)used_bytes / (1000.0 * 1000.0));
                } else {
-                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.2fGB", (double)used_bytes / (1024.0 * 1024.0 * 1024.0));
+                    snprintf(pads[pad_count].used_str, sizeof(pads[pad_count].used_str), "%.2fGB", (double)used_bytes / (1000.0 * 1000.0 * 1000.0));
                }
                // Calculate percentage
@@ -923,9 +1019,9 @@ int handle_verify_pad(const char* chksum) {
    printf("ChkSum: %s\n", chksum);
    printf("File: %s\n", pad_filename);
-    double size_gb = (double)st.st_size / (1024.0 * 1024.0 * 1024.0);
+    double size_gb = (double)st.st_size / (1000.0 * 1000.0 * 1000.0);
-    double used_gb = (double)used_bytes / (1024.0 * 1024.0 * 1024.0);
+    double used_gb = (double)used_bytes / (1000.0 * 1000.0 * 1000.0);
-    double remaining_gb = (double)(st.st_size - used_bytes) / (1024.0 * 1024.0 * 1024.0);
+    double remaining_gb = (double)(st.st_size - used_bytes) / (1000.0 * 1000.0 * 1000.0);
    printf("Total size: %.2f GB (%lu bytes)\n", size_gb, st.st_size);
    printf("Used: %.2f GB (%lu bytes)\n", used_gb, used_bytes);
@@ -991,7 +1087,7 @@ int handle_delete_pad(const char* chksum) {
        uint64_t used_bytes;
        read_state_offset(chksum, &used_bytes);
-        double size_gb = (double)st.st_size / (1024.0 * 1024.0 * 1024.0);
+        double size_gb = (double)st.st_size / (1000.0 * 1000.0 * 1000.0);
        printf("\nPad to delete:\n");
        printf("Checksum: %s\n", chksum);
        printf("Size: %.2f GB\n", size_gb);
@@ -1179,7 +1275,7 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
        target_bytes = (size_t)pad_stat.st_size;
        printf("\nHardware RNG selected - will enhance entire pad with hardware entropy\n");
        printf("Pad size: %.2f GB (%zu bytes)\n",
-                (double)target_bytes / (1024.0 * 1024.0 * 1024.0), target_bytes);
+                (double)target_bytes / (1000.0 * 1000.0 * 1000.0), target_bytes);
    } else if (entropy_source == ENTROPY_SOURCE_FILE) {
        // Special handling for file entropy - ask for file path first
        char file_path[512];
@@ -1201,7 +1297,7 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
        printf("\nFile vs Pad Size Analysis:\n");
        printf("  Entropy file: %zu bytes\n", file_size);
        printf("  Target pad: %.2f GB (%lu bytes)\n",
-               (double)pad_size / (1024.0 * 1024.0 * 1024.0), pad_size);
+               (double)pad_size / (1000.0 * 1000.0 * 1000.0), pad_size);
        // Smart method selection based on file size vs pad size
        if (file_size >= pad_size) {
@@ -1385,10 +1481,10 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
        printf("✓ Device test successful!\n");
        printf("  Test collected: %zu bytes in %.1f seconds\n", test_collected, test_time);
-        printf("  Speed: %.1f KB/s (%.1f MB/s)\n", bytes_per_second / 1024.0, bytes_per_second / (1024.0 * 1024.0));
+        printf("  Speed: %.1f KB/s (%.1f MB/s)\n", bytes_per_second / 1000.0, bytes_per_second / (1000.0 * 1000.0));
        printf("\nPad enhancement estimate:\n");
-        printf("  Pad size: %.2f GB (%zu bytes)\n", (double)target_bytes / (1024.0 * 1024.0 * 1024.0), target_bytes);
+        printf("  Pad size: %.2f GB (%zu bytes)\n", (double)target_bytes / (1000.0 * 1000.0 * 1000.0), target_bytes);
        if (estimated_hours >= 1.0) {
            printf("  Estimated time: %.1f hours\n", estimated_hours);
--- a/src/state.c
+++ b/src/state.c
@@ -1,6 +1,6 @@
 #include <string.h>
 #include <stdlib.h>
-#include "otp.h"
+#include "main.h"
 // Global state variables
 static char current_pads_dir[512] = DEFAULT_PADS_DIR;
--- a/src/trng.c
+++ b/src/trng.c
@@ -17,7 +17,7 @@
 #include <math.h>
 #include <errno.h>
 #include "nostr_chacha20.h"
-#include "otp.h"
+#include "main.h"
 // Basic TrueRNG entropy collection function
 int collect_truerng_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress) {
@@ -153,7 +153,7 @@ int collect_truerng_entropy_streaming_from_device(const hardware_rng_device_t* d
    if (display_progress) {
        printf("Streaming entropy from %s to pad...\n", device->friendly_name);
-        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1024.0*1024.0*1024.0), pad_size);
+        printf("Pad size: %.2f GB (%lu bytes)\n", (double)pad_size / (1000.0*1000.0*1000.0), pad_size);
        printf("Enhancing entire pad with hardware entropy\n");
    }
--- a/src/ui.c
+++ b/src/ui.c
@@ -15,7 +15,7 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "otp.h"
+#include "main.h"
 // Initialize terminal dimensions
 void init_terminal_dimensions(void) {
@@ -99,6 +99,9 @@ int interactive_mode(void) {
            case 'F':
                handle_file_encrypt();
                break;
            case 'R':
                handle_directory_encrypt();
                break;
            case 'D':
                handle_decrypt_menu();
                break;
@@ -120,14 +123,17 @@ int interactive_mode(void) {
 void show_main_menu(void) {
    printf("\n");
-    print_centered_header("Main Menu - OTP v0.3.16", 0);
+    char header[64];
    snprintf(header, sizeof(header), "Main Menu - OTP %s", OTP_VERSION);
    print_centered_header(header, 0);
    printf("\n");
-    printf(" \033[4mT\033[0mext encrypt\n");    //TEXT ENCRYPT
+    printf(" \033[4mT\033[0mext encrypt\n");       //TEXT ENCRYPT
-    printf(" \033[4mF\033[0mile encrypt\n");    //FILE ENCRYPT
+    printf(" \033[4mF\033[0mile encrypt\n");       //FILE ENCRYPT
-    printf(" \033[4mD\033[0mecrypt\n");         //DECRYPT
+    printf(" Di\033[4mr\033[0mectory encrypt\n");  //DIRECTORY ENCRYPT
-    printf(" \033[4mP\033[0mads\n");            //PADS
+    printf(" \033[4mD\033[0mecrypt\n");            //DECRYPT
-    printf(" E\033[4mx\033[0mit\n");            //EXIT
+    printf(" \033[4mP\033[0mads\n");               //PADS
    printf(" E\033[4mx\033[0mit\n");               //EXIT
    printf("\nSelect option: ");
 }
@@ -150,7 +156,7 @@ int handle_generate_menu(void) {
        return 1;
    }
-    double size_gb = (double)size / (1024.0 * 1024.0 * 1024.0);
+    double size_gb = (double)size / (1000.0 * 1000.0 * 1000.0);
    printf("Generating %.2f GB pad...\n", size_gb);
    printf("Note: Use 'Add entropy' in Pads menu to enhance randomness after creation.\n");
@@ -350,7 +356,23 @@ int handle_decrypt_menu(void) {
            return 1;
        }
-        return decrypt_file(selected_file, output_file);
+        // Check if it's a directory archive
        if (strstr(selected_file, ".tar.gz.otp") || strstr(selected_file, ".tar.otp")) {
            // It's a directory archive - extract to directory
            char extract_dir[512];
            strncpy(extract_dir, output_file, sizeof(extract_dir) - 1);
            extract_dir[sizeof(extract_dir) - 1] = '\0';
            // Remove .tar.gz.otp or .tar.otp extension to get directory name
            char* ext = strstr(extract_dir, ".tar.gz.otp");
            if (!ext) ext = strstr(extract_dir, ".tar.otp");
            if (ext) *ext = '\0';
            printf("Extracting directory archive to: %s/\n", extract_dir);
            return decrypt_and_extract_directory(selected_file, extract_dir);
        } else {
            return decrypt_file(selected_file, output_file);
        }
    }
    else if (strncmp(input_line, "-----BEGIN OTP MESSAGE-----", 27) == 0) {
        // Looks like ASCII armor - collect the full message
@@ -402,7 +424,23 @@ int handle_decrypt_menu(void) {
                return 1;
            }
-            return decrypt_file(input_line, output_file);
+            // Check if it's a directory archive
            if (strstr(input_line, ".tar.gz.otp") || strstr(input_line, ".tar.otp")) {
                // It's a directory archive - extract to directory
                char extract_dir[512];
                strncpy(extract_dir, output_file, sizeof(extract_dir) - 1);
                extract_dir[sizeof(extract_dir) - 1] = '\0';
                // Remove .tar.gz.otp or .tar.otp extension to get directory name
                char* ext = strstr(extract_dir, ".tar.gz.otp");
                if (!ext) ext = strstr(extract_dir, ".tar.otp");
                if (ext) *ext = '\0';
                printf("Extracting directory archive to: %s/\n", extract_dir);
                return decrypt_and_extract_directory(input_line, extract_dir);
            } else {
                return decrypt_file(input_line, output_file);
            }
        } else {
            printf("Input not recognized as ASCII armor or valid file path.\n");
            return 1;
@@ -499,5 +537,86 @@ int handle_file_encrypt(void) {
    int result = encrypt_file(selected_pad, input_file, output_filename, ascii_armor);
    free(selected_pad);
    return result;
 }
 int handle_directory_encrypt(void) {
    printf("\n");
    print_centered_header("Directory Encrypt", 0);
    // Directory selection options
    printf("\nDirectory selection options:\n");
    printf(" 1. Type directory path directly\n");
    printf(" 2. Use file manager (navigate to directory)\n");
    printf("Enter choice (1-2): ");
    char choice_input[10];
    char dir_path[512];
    if (!fgets(choice_input, sizeof(choice_input), stdin)) {
        printf("Error: Failed to read input\n");
        return 1;
    }
    if (atoi(choice_input) == 2) {
        // Use directory manager
        if (launch_directory_manager(".", dir_path, sizeof(dir_path)) != 0) {
            printf("Falling back to manual directory path entry.\n");
            printf("Enter directory path to encrypt: ");
            if (!fgets(dir_path, sizeof(dir_path), stdin)) {
                printf("Error: Failed to read input\n");
                return 1;
            }
            dir_path[strcspn(dir_path, "\n")] = 0;
        }
    } else {
        // Direct directory path input
        printf("Enter directory path to encrypt: ");
        if (!fgets(dir_path, sizeof(dir_path), stdin)) {
            printf("Error: Failed to read input\n");
            return 1;
        }
        dir_path[strcspn(dir_path, "\n")] = 0;
    }
    // Check if directory exists
    struct stat st;
    if (stat(dir_path, &st) != 0 || !S_ISDIR(st.st_mode)) {
        printf("Error: '%s' is not a valid directory\n", dir_path);
        return 1;
    }
    // Select pad
    char* selected_pad = select_pad_interactive("Select Pad for Directory Encryption",
                                              "Select pad (by prefix)",
                                              PAD_FILTER_ALL, 1);
    if (!selected_pad) {
        printf("Directory encryption cancelled.\n");
        return 1;
    }
    // Generate default output filename
    char default_output[1024];
    const char* dir_name = strrchr(dir_path, '/');
    if (dir_name) {
        dir_name++; // Skip the '/'
    } else {
        dir_name = dir_path;
    }
    snprintf(default_output, sizeof(default_output), "%s.tar.gz.otp", dir_name);
    // Get output filename
    char output_file[512];
    if (get_filename_with_default("Output filename:", default_output, output_file, sizeof(output_file)) != 0) {
        printf("Error: Failed to read input\n");
        free(selected_pad);
        return 1;
    }
    // Encrypt directory
    int result = encrypt_directory(dir_path, selected_pad, output_file);
    free(selected_pad);
    return result;
 }
--- a/src/util.c
+++ b/src/util.c
@@ -15,7 +15,7 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "otp.h"
+#include "main.h"
 // Global variables for preferences
 static char default_pad_path[1024] = "";
@@ -240,6 +240,83 @@ int launch_file_manager(const char* start_directory, char* selected_file, size_t
    return 1; // Fall back to manual entry
 }
 int launch_directory_manager(const char* start_directory, char* selected_dir, size_t buffer_size) {
    char* fm = get_preferred_file_manager();
    if (!fm) {
        printf("No file manager found. Please install ranger, fzf, nnn, or lf.\n");
        printf("Falling back to manual directory path entry.\n");
        return 1; // Fall back to manual entry
    }
    char temp_filename[64];
    snprintf(temp_filename, sizeof(temp_filename), "/tmp/otp_dir_%ld.tmp", time(NULL));
    char command[512];
    int result = 1;
    printf("Opening %s for directory selection...\n", fm);
    printf("Navigate INTO the directory you want to encrypt, then press 'q' to quit and select it.\n");
    if (strcmp(fm, "ranger") == 0) {
        snprintf(command, sizeof(command), "cd '%s' && ranger --choosedir=%s",
                start_directory ? start_directory : ".", temp_filename);
    } else if (strcmp(fm, "fzf") == 0) {
        // fzf doesn't have directory-only mode easily, use find
        snprintf(command, sizeof(command), "cd '%s' && find . -type d | fzf > %s",
                start_directory ? start_directory : ".", temp_filename);
    } else if (strcmp(fm, "nnn") == 0) {
        snprintf(command, sizeof(command), "cd '%s' && nnn -p %s",
                start_directory ? start_directory : ".", temp_filename);
    } else if (strcmp(fm, "lf") == 0) {
        snprintf(command, sizeof(command), "cd '%s' && lf -selection-path=%s",
                start_directory ? start_directory : ".", temp_filename);
    }
    result = system(command);
    if (result == 0 || result == 256) { // Some file managers return 256 on success
        // Read selected directory from temp file
        FILE* temp_file = fopen(temp_filename, "r");
        if (temp_file) {
            if (fgets(selected_dir, buffer_size, temp_file)) {
                // Remove trailing newline
                selected_dir[strcspn(selected_dir, "\n\r")] = 0;
                // For relative paths, make absolute if needed
                if (selected_dir[0] == '.' && selected_dir[1] == '/') {
                    char current_dir[512];
                    if (getcwd(current_dir, sizeof(current_dir))) {
                        char abs_path[1024];
                        snprintf(abs_path, sizeof(abs_path), "%s/%s", current_dir, selected_dir + 2);
                        strncpy(selected_dir, abs_path, buffer_size - 1);
                        selected_dir[buffer_size - 1] = '\0';
                    }
                } else if (selected_dir[0] != '/') {
                    // Relative path without ./
                    char current_dir[512];
                    if (getcwd(current_dir, sizeof(current_dir))) {
                        char abs_path[1024];
                        snprintf(abs_path, sizeof(abs_path), "%s/%s", current_dir, selected_dir);
                        strncpy(selected_dir, abs_path, buffer_size - 1);
                        selected_dir[buffer_size - 1] = '\0';
                    }
                }
                fclose(temp_file);
                unlink(temp_filename);
                free(fm);
                return 0; // Success
            }
            fclose(temp_file);
        }
    }
    // Clean up and indicate failure
    unlink(temp_filename);
    free(fm);
    return 1; // Fall back to manual entry
 }
 // Stdin detection functions implementation
 int has_stdin_data(void) {
    // Check if stdin is a pipe/redirect (not a terminal)
@@ -519,13 +596,13 @@ uint64_t parse_size_string(const char* size_str) {
        }
        if (strcmp(unit, "K") == 0 || strcmp(unit, "KB") == 0) {
-            multiplier = 1024ULL;
+            multiplier = 1000ULL;
        } else if (strcmp(unit, "M") == 0 || strcmp(unit, "MB") == 0) {
-            multiplier = 1024ULL * 1024ULL;
+            multiplier = 1000ULL * 1000ULL;
        } else if (strcmp(unit, "G") == 0 || strcmp(unit, "GB") == 0) {
-            multiplier = 1024ULL * 1024ULL * 1024ULL;
+            multiplier = 1000ULL * 1000ULL * 1000ULL;
        } else if (strcmp(unit, "T") == 0 || strcmp(unit, "TB") == 0) {
-            multiplier = 1024ULL * 1024ULL * 1024ULL * 1024ULL;
+            multiplier = 1000ULL * 1000ULL * 1000ULL * 1000ULL;
        } else {
            return 0; // Invalid unit
        }
--- a/tests/test_chacha20_extended
+++ b/tests/test_chacha20_extended
--- a/tests/test_chacha20_extended.c
+++ b/tests/test_chacha20_extended.c
@@ -0,0 +1,263 @@
 /*
 * test_chacha20_extended.c - Test ChaCha20 extended counter implementation
 * 
 * This test verifies that the extended counter properly handles:
 * 1. Counter overflow at 2^32 blocks (256GB boundary)
 * 2. Correct keystream generation across the overflow boundary
 * 3. No duplicate keystream blocks
 */
 #include <stdio.h>
 #include <stdint.h>
 #include <string.h>
 #include <stdlib.h>
 #include "../src/nostr_chacha20.h"
 #define TEST_BLOCK_SIZE 64
 #define BLOCKS_NEAR_OVERFLOW 10  // Test blocks around overflow point
 // Test helper: Compare two blocks for equality
 int blocks_equal(const uint8_t* block1, const uint8_t* block2, size_t len) {
    return memcmp(block1, block2, len) == 0;
 }
 // Test 1: Verify extended counter handles overflow correctly
 int test_counter_overflow() {
    printf("Test 1: Counter overflow handling\n");
    printf("  Testing counter transition from 0xFFFFFFFF to 0x00000000...\n");
    uint8_t key[32];
    uint8_t nonce[8];
    uint8_t input[TEST_BLOCK_SIZE];
    uint8_t output1[TEST_BLOCK_SIZE];
    uint8_t output2[TEST_BLOCK_SIZE];
    uint8_t output3[TEST_BLOCK_SIZE];
    // Initialize test data
    memset(key, 0xAA, 32);
    memset(nonce, 0xBB, 8);
    memset(input, 0, TEST_BLOCK_SIZE);
    // Test at counter_low = 0xFFFFFFFE, counter_high = 0
    uint32_t counter_low = 0xFFFFFFFE;
    uint32_t counter_high = 0;
    printf("  Block at counter_low=0xFFFFFFFE, counter_high=0...\n");
    if (chacha20_encrypt_extended(key, counter_low, counter_high, nonce, 
                                   input, output1, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Error at counter_low=0xFFFFFFFE\n");
        return 1;
    }
    // Test at counter_low = 0xFFFFFFFF, counter_high = 0
    counter_low = 0xFFFFFFFF;
    printf("  Block at counter_low=0xFFFFFFFF, counter_high=0...\n");
    if (chacha20_encrypt_extended(key, counter_low, counter_high, nonce, 
                                   input, output2, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Error at counter_low=0xFFFFFFFF\n");
        return 1;
    }
    // Test at counter_low = 0x00000000, counter_high = 1 (after overflow)
    counter_low = 0x00000000;
    counter_high = 1;
    printf("  Block at counter_low=0x00000000, counter_high=1...\n");
    if (chacha20_encrypt_extended(key, counter_low, counter_high, nonce, 
                                   input, output3, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Error at counter_low=0x00000000, counter_high=1\n");
        return 1;
    }
    // Verify all three blocks are different (no keystream reuse)
    if (blocks_equal(output1, output2, TEST_BLOCK_SIZE)) {
        printf("  ❌ FAILED: Blocks at 0xFFFFFFFE and 0xFFFFFFFF are identical!\n");
        return 1;
    }
    if (blocks_equal(output2, output3, TEST_BLOCK_SIZE)) {
        printf("  ❌ FAILED: Blocks at 0xFFFFFFFF,0 and 0x00000000,1 are identical!\n");
        return 1;
    }
    if (blocks_equal(output1, output3, TEST_BLOCK_SIZE)) {
        printf("  ❌ FAILED: Blocks at 0xFFFFFFFE,0 and 0x00000000,1 are identical!\n");
        return 1;
    }
    printf("  ✓ All blocks are unique across overflow boundary\n");
    printf("  ✓ PASSED\n\n");
    return 0;
 }
 // Test 2: Simulate processing data that crosses 256GB boundary
 int test_large_file_simulation() {
    printf("Test 2: Large file simulation (256GB+ boundary)\n");
    printf("  Simulating processing across 256GB boundary...\n");
    uint8_t key[32];
    uint8_t nonce[8];
    uint8_t input[1024];
    uint8_t output[1024];
    // Initialize test data
    memset(key, 0x55, 32);
    memset(nonce, 0x77, 8);
    for (int i = 0; i < 1024; i++) {
        input[i] = i & 0xFF;
    }
    // Simulate being at 256GB - 512 bytes (just before overflow)
    // 256GB = 2^32 blocks * 64 bytes = 274,877,906,944 bytes
    // Block number at 256GB - 512 bytes = 2^32 - 8 blocks
    uint32_t counter_low = 0xFFFFFFF8;  // 2^32 - 8
    uint32_t counter_high = 0;
    printf("  Processing 1KB starting at block 0xFFFFFFF8 (256GB - 512 bytes)...\n");
    // This should cross the overflow boundary
    int result = chacha20_encrypt_extended(key, counter_low, counter_high, nonce, 
                                           input, output, 1024);
    if (result != 0) {
        printf("  ❌ FAILED: Error processing data across 256GB boundary\n");
        return 1;
    }
    printf("  ✓ Successfully processed data across 256GB boundary\n");
    printf("  ✓ PASSED\n\n");
    return 0;
 }
 // Test 3: Verify extended vs standard ChaCha20 compatibility
 int test_compatibility() {
    printf("Test 3: Compatibility with standard ChaCha20\n");
    printf("  Verifying extended mode matches standard mode when counter_high=0...\n");
    uint8_t key[32];
    uint8_t nonce_standard[12];
    uint8_t nonce_reduced[8];
    uint8_t input[TEST_BLOCK_SIZE];
    uint8_t output_standard[TEST_BLOCK_SIZE];
    uint8_t output_extended[TEST_BLOCK_SIZE];
    // Initialize test data
    memset(key, 0x33, 32);
    memset(nonce_standard, 0x44, 12);
    memcpy(nonce_reduced, nonce_standard + 4, 8);  // Extract last 8 bytes
    memset(input, 0, TEST_BLOCK_SIZE);
    uint32_t counter = 42;
    // Standard ChaCha20
    if (chacha20_encrypt(key, counter, nonce_standard, input, 
                        output_standard, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Standard ChaCha20 error\n");
        return 1;
    }
    // Extended ChaCha20 with counter_high=0 and matching nonce
    // The extended version builds nonce as [counter_high][nonce_reduced]
    // So we need to ensure the first 4 bytes of nonce_standard are 0
    uint8_t nonce_standard_zero[12] = {0};
    memcpy(nonce_standard_zero + 4, nonce_reduced, 8);
    if (chacha20_encrypt(key, counter, nonce_standard_zero, input, 
                        output_standard, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Standard ChaCha20 error\n");
        return 1;
    }
    if (chacha20_encrypt_extended(key, counter, 0, nonce_reduced, input, 
                                  output_extended, TEST_BLOCK_SIZE) != 0) {
        printf("  ❌ FAILED: Extended ChaCha20 error\n");
        return 1;
    }
    // Compare outputs
    if (!blocks_equal(output_standard, output_extended, TEST_BLOCK_SIZE)) {
        printf("  ❌ FAILED: Extended mode output differs from standard mode\n");
        printf("  First 16 bytes of standard: ");
        for (int i = 0; i < 16; i++) printf("%02x ", output_standard[i]);
        printf("\n  First 16 bytes of extended: ");
        for (int i = 0; i < 16; i++) printf("%02x ", output_extended[i]);
        printf("\n");
        return 1;
    }
    printf("  ✓ Extended mode matches standard mode when counter_high=0\n");
    printf("  ✓ PASSED\n\n");
    return 0;
 }
 // Test 4: Stress test - verify no errors at extreme counter values
 int test_extreme_values() {
    printf("Test 4: Extreme counter values\n");
    printf("  Testing at various extreme counter positions...\n");
    uint8_t key[32];
    uint8_t nonce[8];
    uint8_t input[TEST_BLOCK_SIZE];
    uint8_t output[TEST_BLOCK_SIZE];
    memset(key, 0x99, 32);
    memset(nonce, 0x66, 8);
    memset(input, 0, TEST_BLOCK_SIZE);
    // Test various extreme positions
    struct {
        uint32_t counter_low;
        uint32_t counter_high;
        const char* description;
    } test_cases[] = {
        {0x00000000, 0, "Start of first 256GB segment"},
        {0xFFFFFFFF, 0, "End of first 256GB segment"},
        {0x00000000, 1, "Start of second 256GB segment"},
        {0xFFFFFFFF, 1, "End of second 256GB segment"},
        {0x00000000, 0xFFFF, "Start of segment 65535"},
        {0xFFFFFFFF, 0xFFFF, "End of segment 65535"},
    };
    for (size_t i = 0; i < sizeof(test_cases) / sizeof(test_cases[0]); i++) {
        printf("  Testing: %s (0x%08X, 0x%08X)...\n", 
               test_cases[i].description,
               test_cases[i].counter_low,
               test_cases[i].counter_high);
        if (chacha20_encrypt_extended(key, test_cases[i].counter_low, 
                                      test_cases[i].counter_high, nonce,
                                      input, output, TEST_BLOCK_SIZE) != 0) {
            printf("  ❌ FAILED at %s\n", test_cases[i].description);
            return 1;
        }
    }
    printf("  ✓ All extreme values handled correctly\n");
    printf("  ✓ PASSED\n\n");
    return 0;
 }
 int main() {
    printf("=================================================================\n");
    printf("ChaCha20 Extended Counter Test Suite\n");
    printf("=================================================================\n\n");
    int failures = 0;
    failures += test_counter_overflow();
    failures += test_large_file_simulation();
    failures += test_compatibility();
    failures += test_extreme_values();
    printf("=================================================================\n");
    if (failures == 0) {
        printf("✓ ALL TESTS PASSED\n");
        printf("=================================================================\n");
        printf("\nThe extended counter implementation is working correctly.\n");
        printf("It can now handle pads larger than 256GB without overflow errors.\n");
        return 0;
    } else {
        printf("❌ %d TEST(S) FAILED\n", failures);
        printf("=================================================================\n");
        return 1;
    }
 }
Author	SHA1	Message	Date
Laan Tungir	3bef639cc3	Version v0.3.43 - -m Remove unnecessary calculate_checksum() calls during encryption - use filename checksum directly	2025-12-27 11:56:28 -05:00
Laan Tungir	81eded2995	Version v0.3.42 - -m Suppress miniz warnings in archive.c header include	2025-12-27 11:51:10 -05:00
Laan Tungir	e126e30889	Version v0.3.41 - -m Suppress miniz library warnings, auto-select pad when only one available	2025-12-27 11:49:29 -05:00
Laan Tungir	6fe12e0c1c	Version v0.3.40 - -m Add directory encryption (TAR+GZIP+OTP), integrate ranger for directory selection, add microtar/miniz libraries, remove binary state file backward compatibility - enforce text format only	2025-12-27 11:45:31 -05:00
Laan Tungir	89aa3baff6	Version v0.3.39 - .	2025-12-25 08:25:18 -05:00
Laan Tungir	39e818dd51	Version v0.3.38 - Implement ChaCha20 nonce extension to support pads larger than 256GB	2025-12-24 10:00:32 -05:00
Laan Tungir	977da58a3b	Version v0.3.37 - Implement ChaCha20 nonce extension to support pads larger than 256GB	2025-12-24 10:00:27 -05:00
Laan Tungir	2c311a9a61	Version v0.3.36 - "."	2025-12-21 09:18:39 -04:00
Laan Tungir	b969590625	Version v0.3.35 - Convert to decimal units (1000-based) to match system tools, add posix_fallocate for guaranteed space allocation, use f_bavail for accurate space reporting, add drive info to Pad Management header	2025-12-20 10:02:15 -04:00
Laan Tungir	cf52274c2c	Version v0.3.34 - Fixed usb space reporting	2025-12-20 09:25:38 -04:00
Laan Tungir	f3599fef37	Version v0.3.33 - Update readme.md some more	2025-12-18 10:20:36 -04:00
Laan Tungir	c229aec88e	Version v0.3.32 - Update readme.md some more	2025-12-18 10:12:41 -04:00
Laan Tungir	862465c5c2	Version v0.3.31 - Update readme.md	2025-12-18 09:53:22 -04:00
Laan Tungir	799e34e045	Version v0.3.30 - Update readme.md	2025-12-18 09:46:32 -04:00
Laan Tungir	1d6f4a225d	Version v0.3.29 - Update versioning system	2025-12-18 09:33:18 -04:00
Laan Tungir	4bd0c5aa42	Version v0.3.28 - Cleaned up file structure, removing otp.c and otp.h files	2025-12-18 09:28:38 -04:00
Laan Tungir	dffae799aa	Version v0.3.27 - Clean up .o files	2025-12-18 09:21:12 -04:00
Laan Tungir	ed9fb759db	Version v0.3.26 - Change .state file to plain text instead of binary	2025-12-18 09:18:32 -04:00
Laan Tungir	2c7f16ce51	Version v0.3.25 - Clean up directory structure	2025-12-18 08:59:18 -04:00
		`@@ -1,3 +0,0 @@`
			`# TODO`

			`## The pad menu in interactive encrypt mode gives numbers instead of checksum selection`
		`@@ -1 +0,0 @@`
			`int main() { printf("Testing direct filename: %d\n", strncmp("97d9d82b5414a9439102f3811fb90ab1d6368a00d33229a18b306476f9d04f82.pad", "97", 2)); return 0; }`