Version v0.3.23 - Reorganized project structure - all sources in src/, builds in build/

Version v0.3.22 - Fix delete error
Version v0.3.21 - Fixing errors with adding entropy to file
2025-12-18 08:54:57 -04:00 · 2025-12-18 08:45:16 -04:00 · 2025-12-18 08:34:52 -04:00 · 2025-10-09 10:45:04 -04:00 · 2025-10-05 10:30:26 -04:00 · 2025-10-05 08:59:31 -04:00
23 changed files with 1883 additions and 6796 deletions
--- a/.gitignore
+++ b/.gitignore
@@ -1,10 +1,26 @@
-otp
+# Build artifacts
 build/
 *.o
 src/*.o
 # Runtime directories
 pads/
 files/
 # Personal files
 Gemini.md
 TropicOfCancer-HenryMiller.txt
 .gitea_token
 true_rng/
-swiftrng/
+Trash/
-# Auto-generated files (none currently)
+# Test binaries
 debug
 test_swiftrng
 test_swiftrng_debug
 test_swiftrng_detailed
 test_truerng
 # Temporary files
 *.pad
 *.state
--- a/HARDWARE_RNG_STATUS.md
+++ b/HARDWARE_RNG_STATUS.md
@@ -0,0 +1,46 @@
 # 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/15
+++ b/15
@@ -1,29 +1,32 @@
 CC = gcc
-CFLAGS = -Wall -Wextra -std=c99 -Iinclude
+CFLAGS = -Wall -Wextra -std=c99 -Isrc
 LIBS = -lm
 LIBS_STATIC = -static -lm
-TARGET = otp
+ARCH = $(shell uname -m)
-SOURCES = $(wildcard src/*.c) nostr_chacha20.c otp.c
+TARGET = build/otp-$(ARCH)
 SOURCES = $(wildcard src/*.c)
 OBJS = $(SOURCES:.c=.o)
 # Default build target
 $(TARGET): $(OBJS)
 	@mkdir -p build
 	$(CC) $(CFLAGS) -o $(TARGET) $(OBJS) $(LIBS)
 # Static linking target
 static: $(OBJS)
 	@mkdir -p build
 	$(CC) $(CFLAGS) -o $(TARGET) $(OBJS) $(LIBS_STATIC)
 %.o: %.c
 	$(CC) $(CFLAGS) -c $< -o $@
 clean:
-	rm -f $(TARGET) $(OBJS) *.pad *.state
+	rm -f $(OBJS) src/*.o build/otp-* *.pad *.state
 install:
-	sudo cp $(TARGET) /usr/local/bin/
+	sudo cp $(TARGET) /usr/local/bin/otp
 uninstall:
-	sudo rm -f /usr/local/bin/$(TARGET)
+	sudo rm -f /usr/local/bin/otp
 .PHONY: clean install uninstall static
--- a/README.md
+++ b/README.md
@@ -48,7 +48,9 @@ One-time pads can be trivially encrypted and decrypted using pencil and paper, m
 - **Perfect Security**: Implements true one-time pad encryption with information-theoretic security
 - **Text & File Encryption**: Supports both inline text and file encryption
 - **Multiple Output Formats**: Binary (.otp) and ASCII armored (.otp.asc) file formats
 - **Hardware RNG Support**: Direct entropy collection from TrueRNG USB devices with automatic detection
 - **Keyboard Entropy**: Optional keyboard entropy collection for enhanced randomness
 - **Modular Architecture**: Clean separation of concerns across multiple source modules
 - **Short Command Flags**: Convenient single-character flags for all operations
 - **Automatic Versioning**: Built-in semantic versioning with automatic patch increment
 - **Multiple Build Options**: Standard and static linking builds
@@ -169,14 +171,118 @@ These files are excluded from git (.gitignore) and regenerated on each build.
 ```
 otp/
 ├── build.sh          # Build script with automatic versioning
-├── Makefile         # Traditional make build system  
+├── Makefile         # Traditional make build system
-├── otp.c            # Main source code
+├── otp.c            # Legacy compatibility and global definitions
 ├── README.md        # This file
 ├── .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
 │   ├── ui.c         # Interactive user interface and menu system
 │   ├── state.c      # Global state management (pads directory, terminal dimensions)
 │   ├── crypto.c     # Core cryptographic operations (XOR, ChaCha20)
 │   ├── pads.c       # Pad management and file operations
 │   ├── entropy.c    # Entropy collection from various sources
 │   ├── trng.c       # Hardware RNG device detection and entropy collection
 │   └── util.c       # Utility functions and helpers
 ├── pads/            # OTP pad storage directory (created at runtime)
 └── VERSION          # Plain text version (generated)
 ```
 ## Architecture
 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)
 - **pads.c**: Pad file management, checksums, and state tracking
 - **entropy.c**: Entropy collection from keyboard, dice, and other sources
 - **trng.c**: Hardware RNG device detection and entropy collection from USB devices
 - **util.c**: Utility functions, file operations, and helper routines
 All modules share a common header (`include/otp.h`) that defines the public API and data structures.
 ## Hardware RNG Device Support
 The OTP cipher includes comprehensive support for hardware random number generators (RNGs) to enhance entropy quality for pad generation and entropy addition operations.
 ### Supported Devices
 The system automatically detects and supports the following hardware RNG devices:
 | Device | VID:PID | Status | Notes |
 |--------|---------|--------|-------|
 | **TrueRNG** | 04d8:f5fe | ✅ Working | Original TrueRNG device |
 | **TrueRNG (Alt)** | 1fc9:8111 | ✅ Working | Alternative VID/PID combination |
 | **TrueRNG Pro** | 04d8:f5fe | ✅ Working | Professional version |
 | **TrueRNG Pro V2** | 04d8:f5fe | ✅ Working | Latest professional version |
 ### Device Detection
 The system automatically scans `/dev/ttyACM*` ports and identifies hardware RNG devices by:
 1. **USB VID/PID Detection**: Reading vendor and product IDs from sysfs
 2. **Device Type Classification**: Identifying specific device variants
 3. **Port Configuration**: Applying device-specific serial port settings
 4. **Interactive Selection**: Presenting available devices for user selection
 ### Testing Hardware Devices
 A comprehensive test script is included to verify hardware RNG functionality:
 ```bash
 # Run hardware device tests
 ./test.sh
 ```
 The test script performs:
 - **Device Detection**: Scans for and identifies all connected hardware RNG devices
 - **Connectivity Testing**: Verifies each device can be opened and read from
 - **Configuration Testing**: Validates serial port configuration for each device type
 - **Entropy Quality Analysis**: Measures Shannon entropy of collected random data
 ### Current Test Results
 Based on testing with actual hardware devices:
 **✅ Working Devices:**
 - TrueRNG (Type 1): Full functionality confirmed
 - TrueRNG Pro V2 (Type 3): Full functionality confirmed
  - Device is detected and identified correctly
  - Serial port configuration may need adjustment for this device variant
 ### Usage in Entropy Collection
 When generating pads or adding entropy, the system will:
 1. **Auto-detect** all connected hardware RNG devices
 2. **Present a menu** of available devices if multiple are found
 3. **Test connectivity** before beginning entropy collection
 4. **Estimate completion time** based on device speed testing
 5. **Collect entropy** with progress indicators and quality metrics
 ### Device Configuration
 Each device type uses optimized serial port settings:
 - **TrueRNG devices**: 3Mbps baud rate, 8N1, no flow control
 - **Automatic timeout protection**: Prevents hanging on unresponsive devices
 - **Error recovery**: Graceful handling of device disconnection during operation
 ### Troubleshooting
 If hardware RNG devices are not detected:
 1. **Check USB connections**: Ensure devices are properly connected
 2. **Verify permissions**: User must have access to `/dev/ttyACM*` devices
 3. **Check device enumeration**: Use `lsusb` to verify USB device recognition
 4. **Review sysfs entries**: Ensure VID/PID information is available in `/sys/bus/usb/devices/`
 ## File Formats
 ### .otp File Format (Binary)
--- a/build.sh
+++ b/build.sh
@@ -16,18 +16,31 @@ print_error() { echo -e "${RED}[ERROR]${NC} $1"; }
 # Global variable for commit message
 COMMIT_MESSAGE=""
-# Parse command line arguments for -m flag
+# Parse command line arguments - check if first arg is a command, otherwise treat as commit message
-while [[ $# -gt 0 ]]; do
+COMMAND=""
-    case $1 in
+if [[ $# -gt 0 ]]; then
-        -m|--message)
+    case "$1" in
-            COMMIT_MESSAGE="$2"
+        build|clean|install|uninstall)
-            shift 2
+            COMMAND="$1"
            shift
            ;;
        *)
-            # Keep other arguments for main logic
+            # First argument is not a command, so default to build and treat all args as commit message
-            break
+            COMMAND="build"
            ;;
    esac
 else
    # No arguments, default to build
    COMMAND="build"
 fi
 # Any remaining arguments become the commit message
 for arg in "$@"; do
    if [[ -z "$COMMIT_MESSAGE" ]]; then
        COMMIT_MESSAGE="$arg"
    else
        COMMIT_MESSAGE="$COMMIT_MESSAGE $arg"
    fi
 done
 # Function to automatically increment version
@@ -135,18 +148,18 @@ update_source_version() {
    print_status "Updating version strings in source code..."
-    # Replace hardcoded version strings in otp.c with the current git tag
+    # Replace hardcoded version strings in src/otp.c with the current git tag
-    if [ -f "otp.c" ]; then
+    if [ -f "src/otp.c" ]; then
        # Update main menu version
-        sed -i "s/OTP v[0-9]\+\.[0-9]\+\.[0-9]\+/OTP $NEW_VERSION/g" otp.c
+        sed -i "s/OTP v[0-9]\+\.[0-9]\+\.[0-9]\+/OTP $NEW_VERSION/g" src/otp.c
        # Update ASCII output version
-        sed -i "s/Version: v[0-9]\+\.[0-9]\+\.[0-9]\+/Version: $NEW_VERSION/g" otp.c
+        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" otp.c
+        sed -i "s/Implementation v[0-9]\+\.[0-9]\+\.[0-9]\+/Implementation $NEW_VERSION/g" src/otp.c
-        print_success "Updated version strings in otp.c to $NEW_VERSION"
+        print_success "Updated version strings in src/otp.c to $NEW_VERSION"
    else
-        print_warning "otp.c not found - skipping version string updates"
+        print_warning "src/otp.c not found - skipping version string updates"
    fi
 }
@@ -222,16 +235,16 @@ create_gitea_release() {
    if echo "$response" | grep -q '"id"'; then
        print_success "Created release $version"
-        # Upload binaries with descriptive names
+        # Upload binaries with descriptive names from build directory
-        upload_release_asset "$api_url" "$token" "$version" "otp-x86_64" "otp-${version}-linux-x86_64"
+        upload_release_asset "$api_url" "$token" "$version" "build/otp-x86_64" "otp-${version}-linux-x86_64"
-        upload_release_asset "$api_url" "$token" "$version" "otp-arm64" "otp-${version}-linux-arm64"
+        upload_release_asset "$api_url" "$token" "$version" "build/otp-arm64" "otp-${version}-linux-arm64"
    else
        print_warning "Release may already exist or creation failed"
        print_status "Response: $response"
        # Try to upload to existing release anyway
-        upload_release_asset "$api_url" "$token" "$version" "otp-x86_64" "otp-${version}-linux-x86_64"
+        upload_release_asset "$api_url" "$token" "$version" "build/otp-x86_64" "otp-${version}-linux-x86_64"
-        upload_release_asset "$api_url" "$token" "$version" "otp-arm64" "otp-${version}-linux-arm64"
+        upload_release_asset "$api_url" "$token" "$version" "build/otp-arm64" "otp-${version}-linux-arm64"
    fi
 }
@@ -246,9 +259,8 @@ build_project() {
        # Build x86_64 only
        print_status "Building OTP project for x86_64..."
-        make CC=gcc
+        make CC=gcc ARCH=x86_64
        if [ $? -eq 0 ]; then
            mv otp otp-x86_64
            print_success "x86_64 build completed successfully"
        else
            print_error "x86_64 build failed"
@@ -258,9 +270,8 @@ build_project() {
        # Build both architectures
        print_status "Building OTP project for x86_64..."
        make clean
-        make CC=gcc
+        make CC=gcc ARCH=x86_64
        if [ $? -eq 0 ]; then
            mv otp otp-x86_64
            print_success "x86_64 build completed successfully"
        else
            print_error "x86_64 build failed"
@@ -269,9 +280,8 @@ build_project() {
        print_status "Building OTP project for ARM64/AArch64..."
        make clean
-        make CC=aarch64-linux-gnu-gcc
+        make CC=aarch64-linux-gnu-gcc ARCH=arm64
        if [ $? -eq 0 ]; then
            mv otp otp-arm64
            print_success "ARM64/AArch64 build completed successfully"
        else
            print_error "ARM64/AArch64 build failed"
@@ -293,8 +303,8 @@ build_project() {
 clean_project() {
    print_status "Cleaning build artifacts..."
    make clean
-    # Remove cross-compiled binaries
+    # Remove build directory
-    rm -f otp-x86_64 otp-arm64
+    rm -rf build
    print_success "Clean completed"
 }
@@ -321,7 +331,7 @@ uninstall_project() {
 }
 # Main script logic
-case "${1:-build}" in
+case "$COMMAND" in
    build)
        build_project
        ;;
@@ -336,10 +346,11 @@ case "${1:-build}" in
        ;;
    *)
        echo "OTP Cipher Build Script"
-        echo "Usage: $0 [-m \"commit message\"] {build|clean|install|uninstall}"
+        echo "Usage: $0 [command] [commit message]"
        echo ""
-        echo "Options:"
+        echo "Arguments:"
-        echo "  -m, --message \"text\"  - Specify commit message (skips interactive prompt)"
+        echo "  command      - {build|clean|install|uninstall} (default: build)"
        echo "  commit message - Text to use as commit message (optional, skips interactive prompt)"
        echo ""
        echo "Commands:"
        echo "  build     - Cross-compile for x86_64 and ARM64/AArch64 with automatic version increment (default)"
@@ -348,8 +359,8 @@ case "${1:-build}" in
        echo "  uninstall - Remove from system"
        echo ""
        echo "Build Output:"
-        echo "  otp-x86_64  - Native x86_64 binary"
+        echo "  build/otp-x86_64  - Native x86_64 binary"
-        echo "  otp-arm64   - ARM64/AArch64 binary for Raspberry Pi (if cross-compiler available)"
+        echo "  build/otp-arm64   - ARM64/AArch64 binary for Raspberry Pi (if cross-compiler available)"
        echo ""
        echo "Gitea Integration:"
        echo "  - Automatically creates releases with binaries if ~/.gitea_token exists"
@@ -357,8 +368,9 @@ case "${1:-build}" in
        echo ""
        echo "Examples:"
        echo "  $0"
-        echo "  $0 -m \"Fixed checksum parsing bug\""
+        echo "  $0 \"Fixed checksum parsing bug\""
-        echo "  $0 --message \"Added new feature\" build"
+        echo "  $0 build \"Added new feature\""
        echo "  $0 clean"
        exit 1
        ;;
 esac
--- a/copy.c
+++ b/copy.c
--- a/otp.h
+++ b/otp.h
@@ -1,329 +0,0 @@
 #ifndef OTP_H
 #define OTP_H
 ////////////////////////////////////////////////////////////////////////////////
 //      OTP CIPHER - FUNCTION PROTOTYPES HEADER
 //      One Time Pad Implementation v0.2.109
 //      
 //      This header file contains all function prototypes extracted from otp.c
 //      Organized by functional categories for better maintainability
 ////////////////////////////////////////////////////////////////////////////////
 #include <stdio.h>
 #include <stdint.h>
 #include <stdlib.h>
 #include <termios.h>
 #include <sys/stat.h>
 #include <sys/ioctl.h>
 #include <time.h>
 #include <dirent.h>
 #include <fcntl.h>
 #include <unistd.h>
 #include <string.h>
 #include <ctype.h>
 // Constants
 #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"
 #define MAX_ENTROPY_BUFFER (4 * 1024 * 1024)  // 4MB entropy buffer for large operations
 ////////////////////////////////////////////////////////////////////////////////
 //      TYPE DEFINITIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Decrypt operation modes for universal decrypt function
 typedef enum {
    DECRYPT_MODE_INTERACTIVE,    // Interactive text decryption with prompts
    DECRYPT_MODE_SILENT,         // Silent text decryption (no prompts/labels)
    DECRYPT_MODE_FILE_TO_TEXT,   // File to text output with prompts
    DECRYPT_MODE_FILE_TO_FILE    // File to file output (binary)
 } decrypt_mode_t;
 // Pad filter types for selection functions
 typedef enum {
    PAD_FILTER_ALL,           // Show all pads
    PAD_FILTER_UNUSED_ONLY    // Show only unused pads (0% usage)
 } pad_filter_type_t;
 // Enhanced entropy system state structure
 typedef struct {
    size_t target_bytes;           // Target entropy to collect
    size_t collected_bytes;        // Bytes collected so far
    size_t unique_keys;           // Number of unique keys pressed
    double collection_start_time; // Start timestamp
    double last_keypress_time;    // Last keypress timestamp
    unsigned char quality_score;  // Entropy quality (0-100)
    int auto_complete_enabled;    // Allow auto-complete at minimum
    unsigned char key_histogram[256]; // Track key frequency
 } entropy_collection_state_t;
 ////////////////////////////////////////////////////////////////////////////////
 //      CORE APPLICATION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Main application entry points
 int main(int argc, char* argv[]);
 int interactive_mode(void);
 int command_line_mode(int argc, char* argv[]);
 int pipe_mode(int argc, char* argv[], const char* piped_text);
 ////////////////////////////////////////////////////////////////////////////////
 //      INPUT/OUTPUT DETECTION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Stdin detection functions
 int has_stdin_data(void);
 char* read_stdin_text(void);
 ////////////////////////////////////////////////////////////////////////////////
 //      PREFERENCES MANAGEMENT FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Configuration and preferences handling
 int load_preferences(void);
 int save_preferences(void);
 char* get_preference(const char* key);
 int set_preference(const char* key, const char* value);
 char* get_default_pad_path(void);
 int set_default_pad_path(const char* pad_path);
 ////////////////////////////////////////////////////////////////////////////////
 //      HARDWARE DETECTION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // OTP thumb drive detection function
 int detect_otp_thumb_drive(char* otp_drive_path, size_t path_size);
 ////////////////////////////////////////////////////////////////////////////////
 //      USB DRIVE MANAGEMENT FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 ////////////////////////////////////////////////////////////////////////////////
 //      EXTERNAL TOOL INTEGRATION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Editor and file manager functions
 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);
 ////////////////////////////////////////////////////////////////////////////////
 //      CORE CRYPTOGRAPHIC OPERATIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Primary encryption/decryption functions
 int generate_pad(uint64_t size_bytes, int show_progress);
 int encrypt_text(const char* pad_identifier, const char* input_text);
 int decrypt_text(const char* pad_identifier, const char* encrypted_message);
 int encrypt_file(const char* pad_identifier, const char* input_file, const char* output_file, int ascii_armor);
 int decrypt_file(const char* input_file, const char* output_file);
 int decrypt_binary_file(FILE* input_fp, const char* output_file);
 int decrypt_ascii_file(const char* input_file, const char* output_file);
 ////////////////////////////////////////////////////////////////////////////////
 //      ENHANCED ENTROPY SYSTEM FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Entropy source types
 typedef enum {
    ENTROPY_SOURCE_KEYBOARD = 1,
    ENTROPY_SOURCE_DICE = 2,
    ENTROPY_SOURCE_TRUERNG = 3,
    ENTROPY_SOURCE_FILE = 4
 } entropy_source_t;
 // Terminal control for entropy collection
 int setup_raw_terminal(struct termios* original_termios);
 void restore_terminal(struct termios* original_termios);
 // Entropy collection and feedback
 int collect_entropy_with_feedback(unsigned char* entropy_buffer, size_t target_bytes,
                                 size_t* collected_bytes, int allow_early_exit);
 void display_entropy_progress(const entropy_collection_state_t* state);
 void draw_progress_bar(double percentage, int width);
 void draw_quality_bar(double quality, int width, const char* label);
 // TrueRNG Device Constants (updated to match otp.c implementation)
 #define TRUERNG_VID "04D8"
 #define TRUERNG_PID "F5FE"
 #define TRUERNGPRO_VID "16D0"
 #define TRUERNGPRO_PID "0AA0"
 #define TRUERNGPROV2_VID "04D8"
 #define TRUERNGPROV2_PID "EBB5"
 // SwiftRNG Device Constants (same VID/PID as TrueRNG devices)
 #define SWIFT_RNG_VID "04D8"
 #define SWIFT_RNG_PID "F5FE"
 #define SWIFT_RNG_PRO_VID "16D0"
 #define SWIFT_RNG_PRO_PID "0AA0"
 #define SWIFT_RNG_PRO_V2_VID "04D8"
 #define SWIFT_RNG_PRO_V2_PID "EBB5"
 // TrueRNG/SwiftRNG Device Type enumeration
 typedef enum {
    TRUERNG_ORIGINAL = 1,
    TRUERNG_PRO = 2,
    TRUERNG_PRO_V2 = 3,
    SWIFT_RNG = 4,
    SWIFT_RNG_PRO = 5,
    SWIFT_RNG_PRO_V2 = 6
 } truerng_device_type_t;
 // Hardware RNG device information structure
 typedef struct {
    char port_path[256];              // Device port path (e.g., /dev/ttyUSB0)
    truerng_device_type_t device_type; // Device type identifier
    char friendly_name[64];           // Human-readable device name
    int is_working;                   // 1 if device passes basic test, 0 otherwise
 } hardware_rng_device_t;
 // Hardware RNG device detection and selection functions
 int detect_all_hardware_rng_devices(hardware_rng_device_t* devices, int max_devices, int* num_devices_found);
 int test_hardware_rng_device(const hardware_rng_device_t* device);
 int select_hardware_rng_device_interactive(hardware_rng_device_t* devices, int num_devices, hardware_rng_device_t* selected_device);
 int find_truerng_port(char* port_path, size_t port_path_size, truerng_device_type_t* device_type); // Legacy function for backward compatibility
 // TrueRNG entropy collection functions (updated to match implementation)
 int setup_truerng_serial_port(const char* port_path);
 int collect_truerng_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 int collect_truerng_entropy_from_device(const hardware_rng_device_t* device, unsigned char* entropy_buffer,
                                       size_t target_bytes, size_t* collected_bytes, int display_progress);
 int collect_truerng_entropy_streaming_from_device(const hardware_rng_device_t* device, const char* pad_chksum,
                                                 size_t total_bytes, int display_progress, int entropy_mode);
 const char* get_truerng_device_name(truerng_device_type_t device_type);
 int read_usb_device_info(const char* port_name, char* vid, char* pid);
 // Dice entropy collection functions (updated to match implementation)
 int collect_dice_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 // Unified entropy collection interface (updated to match implementation)
 int collect_entropy_by_source(entropy_source_t source, unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 // Entropy quality calculation
 double calculate_timing_quality(const entropy_collection_state_t* state);
 double calculate_variety_quality(const entropy_collection_state_t* state);
 unsigned char calculate_overall_quality(const entropy_collection_state_t* state);
 double get_precise_time(void);
 // Entropy processing and application
 int derive_chacha20_params(const unsigned char* entropy_data, size_t entropy_size,
                           unsigned char key[32], unsigned char nonce[12]);
 int add_entropy_to_pad(const char* pad_chksum, const unsigned char* entropy_data,
                       size_t entropy_size, int show_progress);
 int add_entropy_direct_xor(const char* pad_chksum, const unsigned char* entropy_data,
                          size_t entropy_size, uint64_t pad_size, int display_progress);
 int add_entropy_chacha20(const char* pad_chksum, const unsigned char* entropy_data,
                        size_t entropy_size, uint64_t pad_size, int display_progress);
 int handle_add_entropy_to_pad(const char* pad_chksum);
 // Enhanced entropy system helper functions
 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 MANAGEMENT FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Directory handling and path management
 int ensure_pads_directory(void);
 void get_pad_path(const char* chksum, char* pad_path, char* state_path);
 const char* get_files_directory(void);
 void get_default_file_path(const char* filename, char* result_path, size_t result_size);
 void get_directory_display(const char* file_path, char* result, size_t result_size);
 ////////////////////////////////////////////////////////////////////////////////
 //      UTILITY FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // General utility and helper functions
 uint64_t parse_size_string(const char* size_str);
 char* find_pad_by_prefix(const char* prefix);
 int show_pad_info(const char* chksum);
 void show_progress(uint64_t current, uint64_t total, time_t start_time);
 ////////////////////////////////////////////////////////////////////////////////
 //      FILE OPERATIONS
 ////////////////////////////////////////////////////////////////////////////////
 // File state and checksum operations
 int read_state_offset(const char* pad_chksum, uint64_t* offset);
 int write_state_offset(const char* pad_chksum, uint64_t offset);
 int calculate_checksum(const char* filename, char* checksum_hex);
 int calculate_checksum_with_progress(const char* filename, char* checksum_hex, int display_progress, uint64_t file_size);
 ////////////////////////////////////////////////////////////////////////////////
 //      UNIVERSAL CORE FUNCTIONS FOR CODE CONSOLIDATION
 ////////////////////////////////////////////////////////////////////////////////
 // Consolidated cryptographic operations
 int universal_xor_operation(const unsigned char* data, size_t data_len,
                           const unsigned char* pad_data, unsigned char* result);
 int parse_ascii_message(const char* message, char* chksum, uint64_t* offset, char* base64_data);
 int load_pad_data(const char* pad_chksum, uint64_t offset, size_t length, unsigned char** pad_data);
 int generate_ascii_armor(const char* chksum, uint64_t offset, const unsigned char* encrypted_data,
                        size_t data_length, char** ascii_output);
 int validate_pad_integrity(const char* pad_path, const char* expected_chksum);
 // Universal decrypt function - consolidates all decrypt operations
 int universal_decrypt(const char* input_data, const char* output_target, decrypt_mode_t mode);
 ////////////////////////////////////////////////////////////////////////////////
 //      BASE64 ENCODING FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Custom base64 implementation
 char* custom_base64_encode(const unsigned char* input, int length);
 unsigned char* custom_base64_decode(const char* input, int* output_length);
 ////////////////////////////////////////////////////////////////////////////////
 //      TERMINAL UI FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Terminal dimension and UI functions
 void init_terminal_dimensions(void);
 void print_centered_header(const char* text, int pause_before_clear);
 ////////////////////////////////////////////////////////////////////////////////
 //      MENU SYSTEM FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Interactive menu interface functions
 void show_main_menu(void);
 int handle_generate_menu(void);
 int handle_encrypt_menu(void);
 int handle_decrypt_menu(void);
 int handle_pads_menu(void);
 int handle_text_encrypt(void);
 int handle_file_encrypt(void);
 int handle_verify_pad(const char* pad_chksum);
 int handle_delete_pad(const char* pad_chksum);
 ////////////////////////////////////////////////////////////////////////////////
 //      ENHANCED INPUT FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Advanced input handling
 int get_filename_with_default(const char* prompt, const char* default_path, char* result, size_t result_size);
 ////////////////////////////////////////////////////////////////////////////////
 //      PAD SELECTION FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Unified pad selection interface
 char* select_pad_interactive(const char* title, const char* prompt, pad_filter_type_t filter_type, int allow_cancel);
 ////////////////////////////////////////////////////////////////////////////////
 //      USAGE AND HELP FUNCTIONS
 ////////////////////////////////////////////////////////////////////////////////
 // Help and usage display
 void print_usage(const char* program_name);
 #endif // OTP_H
--- a/src/crypto.c
+++ b/src/crypto.c
@@ -5,7 +5,7 @@
 #include <stdio.h>
 #include <time.h>
 #include <unistd.h>
-#include "../include/otp.h"
+#include "otp.h"
 #define PROGRESS_UPDATE_INTERVAL (64 * 1024 * 1024)  // 64MB intervals
--- a/src/entropy.c
+++ b/src/entropy.c
@@ -15,8 +15,8 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../nostr_chacha20.h"
+#include "nostr_chacha20.h"
-#include "../include/otp.h"
+#include "otp.h"
 // In-place pad entropy addition using Chacha20 or direct XOR
@@ -457,20 +457,17 @@ int derive_chacha20_params(const unsigned char* entropy_data, size_t entropy_siz
    return 0; // Success
 }
-// Collect entropy from binary file
+// Get file path and size information for entropy collection
-int collect_file_entropy(unsigned char* entropy_buffer, size_t target_bytes,
+int get_file_entropy_info(char* file_path, size_t max_path_len, size_t* file_size, int display_progress) {
                        size_t* collected_bytes, int display_progress) {
    if (display_progress) {
        print_centered_header("File Entropy Collection", 0);
        printf("Load entropy from binary file (.bin format)\n");
        printf("Target: %zu bytes\n", target_bytes);
    }
    printf("Enter path to binary entropy file: ");
    fflush(stdout);
-    char file_path[512];
+    if (!fgets(file_path, max_path_len, stdin)) {
    if (!fgets(file_path, sizeof(file_path), stdin)) {
        printf("Error: Failed to read input\n");
        return 1;
    }
@@ -490,12 +487,31 @@ int collect_file_entropy(unsigned char* entropy_buffer, size_t target_bytes,
        return 1;
    }
-    size_t file_size = file_stat.st_size;
+    *file_size = file_stat.st_size;
-    if (file_size == 0) {
+    if (*file_size == 0) {
        printf("Error: File is empty\n");
        return 1;
    }
    if (display_progress) {
        printf("✓ File found: %s\n", file_path);
        printf("  Size: %zu bytes\n", *file_size);
    }
    return 0; // Success
 }
 // Collect entropy from binary file (legacy function for backward compatibility)
 int collect_file_entropy(unsigned char* entropy_buffer, size_t target_bytes,
                        size_t* collected_bytes, int display_progress) {
    char file_path[512];
    size_t file_size;
    // Get file path and size first
    if (get_file_entropy_info(file_path, sizeof(file_path), &file_size, display_progress) != 0) {
        return 1;
    }
    if (file_size < target_bytes) {
        printf("Warning: File size (%zu bytes) is smaller than target (%zu bytes)\n",
               file_size, target_bytes);
@@ -544,6 +560,131 @@ int collect_file_entropy(unsigned char* entropy_buffer, size_t target_bytes,
    return 0; // Success
 }
 // Add file entropy directly to pad using streaming (for large files)
 int add_file_entropy_streaming(const char* pad_chksum, const char* file_path, size_t file_size, int display_progress) {
    // Get pad file path
    char pad_path[1024];
    char state_path[1024];
    get_pad_path(pad_chksum, pad_path, state_path);
    // Check if pad exists and get size
    struct stat pad_stat;
    if (stat(pad_path, &pad_stat) != 0) {
        printf("Error: Pad file not found: %s\n", pad_path);
        return 1;
    }
    uint64_t pad_size = pad_stat.st_size;
    // Open entropy file for reading
    FILE* entropy_file = fopen(file_path, "rb");
    if (!entropy_file) {
        printf("Error: Cannot open entropy file '%s' for reading\n", file_path);
        return 1;
    }
    // Open pad file for read/write
    FILE* pad_file = fopen(pad_path, "r+b");
    if (!pad_file) {
        printf("Error: Cannot open pad file for modification: %s\n", pad_path);
        fclose(entropy_file);
        return 1;
    }
    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("Entropy file: %.2f GB (%zu bytes)\n", (double)file_size / (1024.0*1024.0*1024.0), file_size);
    }
    // Process in chunks
    unsigned char pad_buffer[64 * 1024];
    unsigned char entropy_buffer[64 * 1024];
    uint64_t offset = 0;
    size_t entropy_offset = 0;
    time_t start_time = time(NULL);
    while (offset < pad_size) {
        size_t chunk_size = sizeof(pad_buffer);
        if (pad_size - offset < chunk_size) {
            chunk_size = pad_size - offset;
        }
        // Read current pad data
        if (fread(pad_buffer, 1, chunk_size, pad_file) != chunk_size) {
            printf("Error: Cannot read pad data at offset %lu\n", offset);
            fclose(entropy_file);
            fclose(pad_file);
            return 1;
        }
        // Read entropy data (wrap around if file smaller than pad)
        size_t entropy_read = 0;
        while (entropy_read < chunk_size) {
            size_t to_read = chunk_size - entropy_read;
            if (to_read > sizeof(entropy_buffer)) {
                to_read = sizeof(entropy_buffer);
            }
            size_t read_bytes = fread(entropy_buffer, 1, to_read, entropy_file);
            if (read_bytes == 0) {
                // Reached end of entropy file, wrap around
                fseek(entropy_file, 0, SEEK_SET);
                entropy_offset = 0;
                read_bytes = fread(entropy_buffer, 1, to_read, entropy_file);
                if (read_bytes == 0) {
                    printf("Error: Cannot read from entropy file\n");
                    fclose(entropy_file);
                    fclose(pad_file);
                    return 1;
                }
            }
            // XOR this chunk
            for (size_t i = 0; i < read_bytes; i++) {
                pad_buffer[entropy_read + i] ^= entropy_buffer[i];
            }
            entropy_read += read_bytes;
            entropy_offset += read_bytes;
        }
        // Seek back and write modified data
        if (fseek(pad_file, offset, SEEK_SET) != 0) {
            printf("Error: Cannot seek to offset %lu\n", offset);
            fclose(entropy_file);
            fclose(pad_file);
            return 1;
        }
        if (fwrite(pad_buffer, 1, chunk_size, pad_file) != chunk_size) {
            printf("Error: Cannot write modified pad data\n");
            fclose(entropy_file);
            fclose(pad_file);
            return 1;
        }
        offset += chunk_size;
        // Show progress for large pads
        if (display_progress && offset % (64 * 1024 * 1024) == 0) {
            show_progress(offset, pad_size, start_time);
        }
    }
    fclose(entropy_file);
    fclose(pad_file);
    if (display_progress) {
        show_progress(pad_size, pad_size, start_time);
        printf("\n✓ Entropy successfully added to pad using streaming direct XOR\n");
        printf("✓ Pad integrity maintained\n");
        printf("✓ %zu bytes of entropy distributed across entire pad\n", file_size);
    }
    return 0;
 }
 // Collect entropy by source type with unified interface
 int collect_entropy_by_source(entropy_source_t source, unsigned char* entropy_buffer,
                              size_t target_bytes, size_t* collected_bytes, int display_progress) {
--- a/src/main.c
+++ b/src/main.c
@@ -15,7 +15,7 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../include/otp.h"
+#include "otp.h"
 int main(int argc, char* argv[]) {
    // Initialize terminal dimensions first
@@ -24,8 +24,9 @@ int main(int argc, char* argv[]) {
    // Load preferences
    load_preferences();
-    // Detect interactive mode: only true when running with no arguments
+    // Detect interactive mode: true when running with no arguments AND no piped input
-    set_interactive_mode((argc == 1));
+    int is_interactive = (argc == 1 && !has_stdin_data());
    set_interactive_mode(is_interactive);
    // Check for OTP thumb drive on startup
    char otp_drive_path[512];
@@ -46,15 +47,25 @@ int main(int argc, char* argv[]) {
 }
 int command_line_mode(int argc, char* argv[]) {
-    // Check for help flags first
+    // Check for help flags first (only if we have arguments)
-    if (strcmp(argv[1], "-h") == 0 || strcmp(argv[1], "--h") == 0 ||
+    if (argc > 1 && (strcmp(argv[1], "-h") == 0 || strcmp(argv[1], "--h") == 0 ||
        strcmp(argv[1], "-help") == 0 || strcmp(argv[1], "--help") == 0 ||
-        strcmp(argv[1], "help") == 0) {
+        strcmp(argv[1], "help") == 0)) {
        print_usage(argv[0]);
        return 0;
    }
-    if (strcmp(argv[1], "generate") == 0 || strcmp(argv[1], "-g") == 0) {
+    // If no arguments but piped input, default to encrypt mode
    if (argc == 1 && has_stdin_data()) {
        char* piped_text = read_stdin_text();
        if (piped_text) {
            int result = pipe_mode(argc, argv, piped_text);
            free(piped_text);
            return result;
        }
    }
    if (argc > 1 && (strcmp(argv[1], "generate") == 0 || strcmp(argv[1], "-g") == 0)) {
        if (argc != 3) {
            printf("Usage: %s generate|-g <size>\n", argv[0]);
            printf("Size examples: 1024, 1GB, 5TB, 512MB\n");
--- a/src/nostr_chacha20.c
+++ b/src/nostr_chacha20.c
--- a/src/nostr_chacha20.h
+++ b/src/nostr_chacha20.h
--- a/src/otp.c
+++ b/src/otp.c
--- a/include/otp.h
+++ b/include/otp.h
@@ -164,36 +164,23 @@ void display_entropy_progress(const entropy_collection_state_t* state);
 void draw_progress_bar(double percentage, int width);
 void draw_quality_bar(double quality, int width, const char* label);
-// TrueRNG Device Constants (updated to match otp.c implementation)
+// Hardware RNG Device Constants (lowercase to match sysfs output)
-#define TRUERNG_VID "04D8"
+#define TRUERNG_VID "04d8"
-#define TRUERNG_PID "F5FE"
+#define TRUERNG_ORIGINAL_PID "f5fe"
-#define TRUERNGPRO_VID "16D0"
+#define TRUERNG_PRO_PID "0aa0"
-#define TRUERNGPRO_PID "0AA0"
+#define TRUERNG_PRO_V2_PID "ebb5"
 #define TRUERNGPROV2_VID "04D8"
 #define TRUERNGPROV2_PID "EBB5"
-// SwiftRNG Device Constants (same VID/PID as TrueRNG devices)
+// Hardware RNG Device Type enumeration
 #define SWIFT_RNG_VID "04D8"
 #define SWIFT_RNG_PID "F5FE"
 #define SWIFT_RNG_PRO_VID "16D0"
 #define SWIFT_RNG_PRO_PID "0AA0"
 #define SWIFT_RNG_PRO_V2_VID "04D8"
 #define SWIFT_RNG_PRO_V2_PID "EBB5"
 // TrueRNG/SwiftRNG Device Type enumeration
 typedef enum {
    TRUERNG_ORIGINAL = 1,
    TRUERNG_PRO = 2,
-    TRUERNG_PRO_V2 = 3,
+    TRUERNG_PRO_V2 = 3
-    SWIFT_RNG = 4,
+} hardware_rng_device_type_t;
    SWIFT_RNG_PRO = 5,
    SWIFT_RNG_PRO_V2 = 6
 } truerng_device_type_t;
 // Hardware RNG device information structure
 typedef struct {
    char port_path[256];              // Device port path (e.g., /dev/ttyUSB0)
-    truerng_device_type_t device_type; // Device type identifier
+    hardware_rng_device_type_t device_type; // Device type identifier
    char friendly_name[64];           // Human-readable device name
    int is_working;                   // 1 if device passes basic test, 0 otherwise
 } hardware_rng_device_t;
@@ -202,21 +189,27 @@ typedef struct {
 int detect_all_hardware_rng_devices(hardware_rng_device_t* devices, int max_devices, int* num_devices_found);
 int test_hardware_rng_device(const hardware_rng_device_t* device);
 int select_hardware_rng_device_interactive(hardware_rng_device_t* devices, int num_devices, hardware_rng_device_t* selected_device);
-int find_truerng_port(char* port_path, size_t port_path_size, truerng_device_type_t* device_type); // Legacy function for backward compatibility
+int find_truerng_port(char* port_path, size_t port_path_size, hardware_rng_device_type_t* device_type); // Legacy function for backward compatibility
 // TrueRNG entropy collection functions (updated to match implementation)
 int configure_rng_serial_port(int fd, hardware_rng_device_type_t device_type);
 int setup_truerng_serial_port(const char* port_path);
 int collect_truerng_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 int collect_truerng_entropy_from_device(const hardware_rng_device_t* device, unsigned char* entropy_buffer,
                                       size_t target_bytes, size_t* collected_bytes, int display_progress);
 int collect_truerng_entropy_streaming_from_device(const hardware_rng_device_t* device, const char* pad_chksum,
                                                 size_t total_bytes, int display_progress, int entropy_mode);
-const char* get_truerng_device_name(truerng_device_type_t device_type);
+const char* get_truerng_device_name(hardware_rng_device_type_t device_type);
 int read_usb_device_info(const char* port_name, char* vid, char* pid);
 // Dice entropy collection functions (updated to match implementation)
 int collect_dice_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 // File entropy collection functions
 int get_file_entropy_info(char* file_path, size_t max_path_len, size_t* file_size, int display_progress);
 int collect_file_entropy(unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
 int add_file_entropy_streaming(const char* pad_chksum, const char* file_path, size_t file_size, int display_progress);
 // Unified entropy collection interface (updated to match implementation)
 int collect_entropy_by_source(entropy_source_t source, unsigned char* entropy_buffer, size_t target_bytes, size_t* collected_bytes, int display_progress);
--- a/src/pads.c
+++ b/src/pads.c
@@ -15,17 +15,20 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../include/otp.h"
+#include <errno.h>
 #include "otp.h"
 // Extracted pad management functions from otp.c
 int show_pad_info(const char* chksum) {
-    char pad_filename[MAX_HASH_LENGTH + 10];
+    char pad_filename[1024];
-    char state_filename[MAX_HASH_LENGTH + 10];
+    char state_filename[1024];
-    snprintf(pad_filename, sizeof(pad_filename), "%s.pad", chksum);
+    // Use full paths with pads directory
-    snprintf(state_filename, sizeof(state_filename), "%s.state", chksum);
+    const char* pads_dir = get_current_pads_dir();
    snprintf(pad_filename, sizeof(pad_filename), "%s/%s.pad", pads_dir, chksum);
    snprintf(state_filename, sizeof(state_filename), "%s/%s.state", pads_dir, chksum);
    struct stat st;
    if (stat(pad_filename, &st) != 0) {
@@ -82,13 +85,37 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
        return 1;
    }
    // Check available disk space before starting
    const char* pads_dir = get_current_pads_dir();
    struct statvfs stat;
    if (statvfs(pads_dir, &stat) == 0) {
        uint64_t available_bytes = stat.f_bavail * stat.f_frsize;
        double available_gb = (double)available_bytes / (1024.0 * 1024.0 * 1024.0);
        double required_gb = (double)size_bytes / (1024.0 * 1024.0 * 1024.0);
        if (available_bytes < size_bytes) {
            printf("\n⚠ WARNING: Insufficient disk space!\n");
            printf("  Required: %.2f GB\n", required_gb);
            printf("  Available: %.2f GB\n", available_gb);
            printf("  Shortfall: %.2f GB\n", required_gb - available_gb);
            printf("\nContinue anyway? (y/N): ");
            char response[10];
            if (!fgets(response, sizeof(response), stdin) ||
                (toupper(response[0]) != 'Y')) {
                printf("Pad generation cancelled.\n");
                return 1;
            }
            printf("\n");
        }
    }
    char temp_filename[1024];
    char pad_path[MAX_HASH_LENGTH + 20];
    char state_path[MAX_HASH_LENGTH + 20];
    char chksum_hex[MAX_HASH_LENGTH];
    // Create temporary filename in the pads directory to avoid cross-filesystem issues
    const char* pads_dir = get_current_pads_dir();
    snprintf(temp_filename, sizeof(temp_filename), "%s/temp_%ld.pad", pads_dir, time(NULL));
    FILE* urandom = fopen("/dev/urandom", "rb");
@@ -193,8 +220,10 @@ int generate_pad(uint64_t size_bytes, int display_progress) {
    printf("Pad file set to read-only\n");
    printf("Use 'Add entropy' in Pads menu to enhance randomness.\n");
-    // Pause before returning to menu to let user see the success message
+    // Pause before returning to menu to let user see the success message (only in interactive mode)
-    print_centered_header("Pad Generation Complete", 1);
+    if (get_interactive_mode()) {
        print_centered_header("Pad Generation Complete", 1);
    }
    return 0;
 }
@@ -872,12 +901,14 @@ int update_pad_checksum_after_entropy(const char* old_chksum, char* new_chksum)
 // Verify pad integrity by checking its checksum
 int handle_verify_pad(const char* chksum) {
-    char pad_filename[MAX_HASH_LENGTH + 10];
+    char pad_filename[1024];
-    char state_filename[MAX_HASH_LENGTH + 10];
+    char state_filename[1024];
    char calculated_chksum[MAX_HASH_LENGTH];
-    snprintf(pad_filename, sizeof(pad_filename), "%s.pad", chksum);
+    // Use full paths with pads directory
-    snprintf(state_filename, sizeof(state_filename), "%s.state", chksum);
+    const char* pads_dir = get_current_pads_dir();
    snprintf(pad_filename, sizeof(pad_filename), "%s/%s.pad", pads_dir, chksum);
    snprintf(state_filename, sizeof(state_filename), "%s/%s.state", pads_dir, chksum);
    struct stat st;
    if (stat(pad_filename, &st) != 0) {
@@ -925,11 +956,13 @@ int handle_verify_pad(const char* chksum) {
 // Delete a pad and its associated state file
 int handle_delete_pad(const char* chksum) {
-    char pad_filename[MAX_HASH_LENGTH + 10];
+    char pad_filename[1024];
-    char state_filename[MAX_HASH_LENGTH + 10];
+    char state_filename[1024];
-    snprintf(pad_filename, sizeof(pad_filename), "%s.pad", chksum);
+    // Use full paths with pads directory
-    snprintf(state_filename, sizeof(state_filename), "%s.state", chksum);
+    const char* pads_dir = get_current_pads_dir();
    snprintf(pad_filename, sizeof(pad_filename), "%s/%s.pad", pads_dir, chksum);
    snprintf(state_filename, sizeof(state_filename), "%s/%s.state", pads_dir, chksum);
    // Check if pad exists
    if (access(pad_filename, F_OK) != 0) {
@@ -1019,6 +1052,61 @@ int handle_delete_pad(const char* chksum) {
    return 0;
 }
 // Helper function to temporarily make pad writable and store original permissions
 static int make_pad_temporarily_writable(const char* pad_path, mode_t* original_mode) {
    struct stat st;
    // Get current permissions
    if (stat(pad_path, &st) != 0) {
        printf("Error: Cannot get pad file permissions: %s\n", strerror(errno));
        return 1;
    }
    // Store original permissions
    *original_mode = st.st_mode;
    // Check if already writable
    if (st.st_mode & S_IWUSR) {
        return 0; // Already writable, no change needed
    }
    // Make writable by adding write permission for owner
    mode_t new_mode = st.st_mode | S_IWUSR;
    if (chmod(pad_path, new_mode) != 0) {
        printf("Error: Cannot make pad file writable: %s\n", strerror(errno));
        return 1;
    }
    printf("✓ Temporarily made pad writable for entropy addition\n");
    return 0;
 }
 // Helper function to restore original pad permissions
 static int restore_pad_permissions(const char* pad_path, mode_t original_mode) {
    struct stat st;
    // Get current permissions to check if they changed
    if (stat(pad_path, &st) != 0) {
        printf("Warning: Cannot check current pad permissions: %s\n", strerror(errno));
        return 1;
    }
    // Only restore if permissions are different from original
    if (st.st_mode != original_mode) {
        if (chmod(pad_path, original_mode) != 0) {
            printf("Warning: Cannot restore original pad permissions: %s\n", strerror(errno));
            return 1;
        }
        // Check if we restored to read-only
        if (!(original_mode & S_IWUSR)) {
            printf("✓ Restored pad to read-only protection\n");
        }
    }
    return 0;
 }
 int handle_add_entropy_to_pad(const char* pad_chksum) {
    char header_text[128];
    snprintf(header_text, sizeof(header_text), "Add Entropy to Pad: %.16s...", pad_chksum);
@@ -1073,11 +1161,13 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
    size_t target_bytes;
    // Declare variables that may be used later
    char pad_path[1024] = "";
    char state_path[1024] = "";
    // For TrueRNG, automatically use the full pad size
    if (entropy_source == ENTROPY_SOURCE_TRUERNG) {
        // Get the pad file size
        char pad_path[1024];
        char state_path[1024];
        get_pad_path(pad_chksum, pad_path, state_path);
        struct stat pad_stat;
@@ -1087,17 +1177,98 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
        }
        target_bytes = (size_t)pad_stat.st_size;
-        printf("\nTrueRNG selected - will enhance entire pad with hardware entropy\n");
+        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 / (1024.0 * 1024.0 * 1024.0), target_bytes);
    } else if (entropy_source == ENTROPY_SOURCE_FILE) {
        // Special handling for file entropy - ask for file path first
        char file_path[512];
        size_t file_size;
        if (get_file_entropy_info(file_path, sizeof(file_path), &file_size, 1) != 0) {
            return 1;
        }
        // Get pad size for comparison
        get_pad_path(pad_chksum, pad_path, state_path);
        struct stat pad_stat;
        if (stat(pad_path, &pad_stat) != 0) {
            printf("Error: Cannot get pad file size\n");
            return 1;
        }
        uint64_t pad_size = pad_stat.st_size;
        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);
        // Smart method selection based on file size vs pad size
        if (file_size >= pad_size) {
            printf("✓ Using Streaming Direct XOR method (file ≥ pad size)\n");
            printf("  Method: Streaming XOR - entropy file will be distributed across entire pad\n");
            printf("  Processing: File will be streamed in chunks (no memory limit)\n");
            // Store original permissions and make pad temporarily writable
            mode_t original_mode;
            if (make_pad_temporarily_writable(pad_path, &original_mode) != 0) {
                printf("Error: Cannot make pad file writable for entropy addition\n");
                return 1;
            }
            // Use streaming method for large files
            int result = add_file_entropy_streaming(pad_chksum, file_path, file_size, 1);
            if (result != 0) {
                printf("Error: Failed to add file entropy to pad\n");
                restore_pad_permissions(pad_path, original_mode);
                return 1;
            }
            // Update checksum after entropy addition
            printf("\n🔄 Updating pad checksum...\n");
            char new_chksum[65];
            int checksum_result = update_pad_checksum_after_entropy(pad_chksum, new_chksum);
            if (checksum_result == 0) {
                printf("✓ Pad checksum updated successfully\n");
                printf("  Old checksum: %.16s...\n", pad_chksum);
                printf("  New checksum: %.16s...\n", new_chksum);
                printf("✓ Pad files renamed to new checksum\n");
                // Restore permissions on the new pad file
                char new_pad_path[1024];
                const char* pads_dir = get_current_pads_dir();
                snprintf(new_pad_path, sizeof(new_pad_path), "%s/%s.pad", pads_dir, new_chksum);
                restore_pad_permissions(new_pad_path, original_mode);
            } else if (checksum_result == 2) {
                printf("ℹ Checksum unchanged (unusual but not an error)\n");
                restore_pad_permissions(pad_path, original_mode);
            } else {
                printf("⚠ Warning: Checksum update failed (entropy was added successfully)\n");
                printf("  You may need to manually handle the checksum update\n");
                restore_pad_permissions(pad_path, original_mode);
                return 1;
            }
            printf("\n🎉 SUCCESS! Your pad now has enhanced randomness from the entropy file!\n");
            print_centered_header("Entropy Enhancement Complete", 1);
            return 0; // Success - exit early, don't continue to buffer-based method
        } else {
            printf("✓ Using ChaCha20 method (file < pad size)\n");
            printf("  Method: ChaCha20 - entropy will be expanded to fill entire pad\n");
            target_bytes = file_size; // Use entire file, ChaCha20 will expand it
        }
        printf("  Target entropy: %zu bytes\n", target_bytes);
    } else {
        // For other entropy sources, show the selection menu
        printf("\nEntropy collection options:\n");
        printf(" 1. Recommended (2048 bytes) - Optimal security\n");
        printf(" 2. Minimum (1024 bytes) - Good security\n");
-        printf(" 3. Maximum (4096 bytes) - Maximum security\n");
+        printf(" 3. Custom amount\n");
-        printf(" 4. Custom amount\n");
+        printf("Enter choice (1-3): ");
        printf("Enter choice (1-4): ");
        char amount_input[10];
        if (!fgets(amount_input, sizeof(amount_input), stdin)) {
@@ -1116,10 +1287,7 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
                target_bytes = 1024;
                break;
            case 3:
-                target_bytes = 4096;
+                printf("Enter custom amount (512+ bytes): ");
                break;
            case 4:
                printf("Enter custom amount (512-8192 bytes): ");
                char custom_input[32];
                if (!fgets(custom_input, sizeof(custom_input), stdin)) {
                    printf("Error: Failed to read input\n");
@@ -1127,8 +1295,8 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
                }
                size_t custom_amount = (size_t)atoi(custom_input);
-                if (custom_amount < 512 || custom_amount > 8192) {
+                if (custom_amount < 512) {
-                    printf("Error: Invalid amount. Must be between 512 and 8192 bytes.\n");
+                    printf("Error: Invalid amount. Must be at least 512 bytes.\n");
                    return 1;
                }
                target_bytes = custom_amount;
@@ -1141,11 +1309,146 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
    // For TrueRNG, detect all devices and present selection menu
    if (entropy_source == ENTROPY_SOURCE_TRUERNG) {
        // Detect available hardware RNG devices
        hardware_rng_device_t devices[10];
        int num_devices_found = 0;
        if (detect_all_hardware_rng_devices(devices, 10, &num_devices_found) != 0) {
            printf("Error: Failed to detect hardware RNG devices\n");
            return 1;
        }
        if (num_devices_found == 0) {
            printf("No hardware RNG devices found.\n");
            printf("\nSupported devices:\n");
            printf("  - TrueRNG Original (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_ORIGINAL_PID);
            printf("  - TrueRNG Pro (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_PRO_PID);
            printf("  - TrueRNG Pro V2 (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_PRO_V2_PID);
            printf("\nPlease connect a TrueRNG or SwiftRNG device and try again.\n");
            return 1;
        }
        // Select device interactively
        hardware_rng_device_t selected_device;
        if (select_hardware_rng_device_interactive(devices, num_devices_found, &selected_device) != 0) {
            printf("Device selection cancelled.\n");
            return 1;
        }
        // Test device speed and estimate completion time
        printf("\nTesting %s connection and speed...\n", selected_device.friendly_name);
        printf("Device: %s (Type: %d)\n", selected_device.port_path, selected_device.device_type);
        // Test with smaller amount (10KB) to avoid hanging on slow/unresponsive devices
        const size_t test_bytes = 10 * 1024; // 10KB test (reduced from 100KB)
        unsigned char* test_buffer = malloc(test_bytes);
        if (!test_buffer) {
            printf("Error: Cannot allocate test buffer\n");
            return 1;
        }
        size_t test_collected = 0;
        time_t test_start = time(NULL);
        // Use non-blocking test to avoid hanging
        int test_result = collect_truerng_entropy_from_device(&selected_device, test_buffer, test_bytes, &test_collected, 0);
        time_t test_end = time(NULL);
        double test_time = difftime(test_end, test_start);
        free(test_buffer);
        if (test_result != 0) {
            printf("Error: Device test failed - cannot establish connection\n");
            printf("This may be due to:\n");
            printf("  - Device not properly connected\n");
            printf("  - Incorrect device type identification\n");
            printf("  - Serial port configuration issues\n");
            printf("  - Device requires different baud rate or settings\n");
            return 1;
        }
        if (test_collected == 0) {
            printf("Error: Device returned no data - check device connection and type\n");
            return 1;
        }
        if (test_time < 1.0) {
            test_time = 1.0; // Minimum 1 second to avoid division by zero
        }
        // Calculate speed and estimate completion time
        double bytes_per_second = test_collected / test_time;
        double estimated_seconds = target_bytes / bytes_per_second;
        double estimated_minutes = estimated_seconds / 60.0;
        double estimated_hours = estimated_minutes / 60.0;
        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("\nPad enhancement estimate:\n");
        printf("  Pad size: %.2f GB (%zu bytes)\n", (double)target_bytes / (1024.0 * 1024.0 * 1024.0), target_bytes);
        if (estimated_hours >= 1.0) {
            printf("  Estimated time: %.1f hours\n", estimated_hours);
        } else if (estimated_minutes >= 1.0) {
            printf("  Estimated time: %.1f minutes\n", estimated_minutes);
        } else {
            printf("  Estimated time: %.1f seconds\n", estimated_seconds);
        }
        // Store original permissions and make pad temporarily writable
        mode_t original_mode;
        if (make_pad_temporarily_writable(pad_path, &original_mode) != 0) {
            // If we can't make it writable, check if it's a filesystem issue
            if (access(pad_path, F_OK) == 0 && access(pad_path, W_OK) != 0) {
                printf("\nError: Cannot make pad file writable: %s\n", pad_path);
                printf("Reason: %s\n", strerror(errno));
                if (errno == EROFS) {
                    printf("The filesystem appears to be read-only.\n");
                    printf("This commonly occurs with:\n");
                    printf("  - USB drives mounted read-only\n");
                    printf("  - CD-ROM/DVD drives\n");
                    printf("  - Network filesystems with read-only access\n");
                } else if (errno == EACCES) {
                    printf("Permission denied. Check file permissions.\n");
                }
                printf("\nTo fix this issue:\n");
                printf("1. Remount the drive read-write: sudo mount -o remount,rw %s\n", pad_path);
                printf("2. Copy the pad to local storage, enhance it, then copy back\n");
                printf("3. Check file permissions: ls -la '%s'\n", pad_path);
            }
            return 1;
        }
        // Ask user for confirmation
        printf("\n⚠ This will modify the entire pad file and update its checksum.\n");
        printf("The process cannot be interrupted once started.\n");
        printf("\nDo you want to continue with hardware entropy enhancement? (y/N): ");
        char confirm_input[10];
        if (!fgets(confirm_input, sizeof(confirm_input), stdin)) {
            printf("Error: Failed to read input\n");
            return 1;
        }
        if (toupper(confirm_input[0]) != 'Y') {
            printf("Hardware entropy enhancement cancelled.\n");
            return 0;
        }
        printf("\nStarting hardware entropy enhancement...\n");
        // Use streaming collection with selected device
-        int result = collect_truerng_entropy_streaming_from_device(NULL, pad_chksum, target_bytes, 1, 1);
+        int result = collect_truerng_entropy_streaming_from_device(&selected_device, pad_chksum, target_bytes, 1, 1);
        if (result != 0) {
            printf("Error: TrueRNG streaming entropy collection failed\n");
            // Restore original permissions before returning
            restore_pad_permissions(pad_path, original_mode);
            return 1;
        }
@@ -1159,11 +1462,21 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
            printf("  Old checksum: %.16s...\n", pad_chksum);
            printf("  New checksum: %.16s...\n", new_chksum);
            printf("✓ Pad files renamed to new checksum\n");
            // Restore permissions on the new pad file
            char new_pad_path[1024];
            const char* pads_dir = get_current_pads_dir();
            snprintf(new_pad_path, sizeof(new_pad_path), "%s/%s.pad", pads_dir, new_chksum);
            restore_pad_permissions(new_pad_path, original_mode);
        } else if (checksum_result == 2) {
            printf("ℹ Checksum unchanged (unusual but not an error)\n");
            // Restore original permissions
            restore_pad_permissions(pad_path, original_mode);
        } else {
            printf("⚠ Warning: Checksum update failed (entropy was added successfully)\n");
            printf("  You may need to manually handle the checksum update\n");
            // Restore original permissions before returning
            restore_pad_permissions(pad_path, original_mode);
            return 1;
        }
@@ -1203,6 +1516,21 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
    printf("\nProcessing entropy and modifying pad...\n");
    // Get pad path and manage permissions for traditional entropy addition
    if (strlen(pad_path) == 0) {
        get_pad_path(pad_chksum, pad_path, state_path);
    }
    // Store original permissions and make pad temporarily writable
    mode_t original_mode;
    if (make_pad_temporarily_writable(pad_path, &original_mode) != 0) {
        printf("Error: Cannot make pad file writable for entropy addition\n");
        // Clear entropy buffer for security
        memset(entropy_buffer, 0, MAX_ENTROPY_BUFFER);
        free(entropy_buffer);
        return 1;
    }
    // Add entropy to pad
    result = add_entropy_to_pad(pad_chksum, entropy_buffer, collected_bytes, 1);
@@ -1212,6 +1540,36 @@ int handle_add_entropy_to_pad(const char* pad_chksum) {
    if (result != 0) {
        printf("Error: Failed to add entropy to pad\n");
        // Restore original permissions before returning
        restore_pad_permissions(pad_path, original_mode);
        return 1;
    }
    // Update checksum after entropy addition for traditional methods
    printf("\n🔄 Updating pad checksum...\n");
    char new_chksum[65];
    int checksum_result = update_pad_checksum_after_entropy(pad_chksum, new_chksum);
    if (checksum_result == 0) {
        printf("✓ Pad checksum updated successfully\n");
        printf("  Old checksum: %.16s...\n", pad_chksum);
        printf("  New checksum: %.16s...\n", new_chksum);
        printf("✓ Pad files renamed to new checksum\n");
        // Restore permissions on the new pad file
        char new_pad_path[1024];
        const char* pads_dir = get_current_pads_dir();
        snprintf(new_pad_path, sizeof(new_pad_path), "%s/%s.pad", pads_dir, new_chksum);
        restore_pad_permissions(new_pad_path, original_mode);
    } else if (checksum_result == 2) {
        printf("ℹ Checksum unchanged (unusual but not an error)\n");
        // Restore original permissions
        restore_pad_permissions(pad_path, original_mode);
    } else {
        printf("⚠ Warning: Checksum update failed (entropy was added successfully)\n");
        printf("  You may need to manually handle the checksum update\n");
        // Restore original permissions before returning
        restore_pad_permissions(pad_path, original_mode);
        return 1;
    }
--- a/src/state.c
+++ b/src/state.c
@@ -1,6 +1,6 @@
 #include <string.h>
 #include <stdlib.h>
-#include "../include/otp.h"
+#include "otp.h"
 // Global state variables
 static char current_pads_dir[512] = DEFAULT_PADS_DIR;
--- a/src/trng.c
+++ b/src/trng.c
@@ -15,8 +15,9 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../nostr_chacha20.h"
+#include <errno.h>
-#include "../include/otp.h"
+#include "nostr_chacha20.h"
 #include "otp.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) {
@@ -35,10 +36,10 @@ int collect_truerng_entropy(unsigned char* entropy_buffer, size_t target_bytes,
        if (display_progress) {
            printf("No hardware RNG devices found.\n");
            printf("\nSupported devices:\n");
-            printf("  - TrueRNG/SwiftRNG (PID: %s, VID: %s)\n", TRUERNG_VID, TRUERNG_PID);
+            printf("  - TrueRNG Original (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_ORIGINAL_PID);
-            printf("  - TrueRNGpro/SwiftRNGpro (PID: %s, VID: %s)\n", TRUERNGPRO_VID, TRUERNGPRO_PID);
+            printf("  - TrueRNG Pro (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_PRO_PID);
-            printf("  - TrueRNGproV2/SwiftRNGproV2 (PID: %s, VID: %s)\n", TRUERNGPROV2_VID, TRUERNGPROV2_PID);
+            printf("  - TrueRNG Pro V2 (VID: %s, PID: %s)\n", TRUERNG_VID, TRUERNG_PRO_V2_PID);
-            printf("\nPlease connect a TrueRNG or SwiftRNG device and try again.\n");
+            printf("\nPlease connect a TrueRNG device and try again.\n");
        }
        return 1;
    }
@@ -68,47 +69,504 @@ int collect_truerng_entropy(unsigned char* entropy_buffer, size_t target_bytes,
    return 0;
 }
-// Wrapper function to match the header declaration
+// Streaming entropy collection directly to pad file
 // Note: Full implementation moved to otp.c during modularization
 // This is a placeholder that should be implemented when the full streaming
 // functionality is moved to the trng module
 int collect_truerng_entropy_streaming_from_device(const hardware_rng_device_t* device, const char* pad_chksum,
                                                  size_t total_bytes, int display_progress, int entropy_mode) {
-    // For now, return an error - full implementation needs to be moved from otp.c
+    (void)entropy_mode; // Suppress unused parameter warning
-    (void)device; // Suppress unused parameter warning
+    if (!device || !pad_chksum || total_bytes == 0) {
-    (void)pad_chksum;
+        return 1; // Invalid parameters
-    (void)total_bytes;
+    }
    (void)display_progress;
    (void)entropy_mode;
-    fprintf(stderr, "Error: collect_truerng_entropy_streaming_from_device not yet implemented in modular version\n");
+
-    return 1; // Error
+    // Get pad file path
    char pad_path[1024];
    char state_path[1024];
    get_pad_path(pad_chksum, pad_path, state_path);
    // Check if pad exists and get size
    struct stat pad_stat;
    if (stat(pad_path, &pad_stat) != 0) {
        if (display_progress) {
            printf("Error: Pad file not found: %s\n", pad_path);
        }
        return 1;
    }
    uint64_t pad_size = pad_stat.st_size;
    if (total_bytes > pad_size) {
        if (display_progress) {
            printf("Error: Requested entropy (%zu bytes) exceeds pad size (%lu bytes)\n", total_bytes, pad_size);
        }
        return 1;
    }
    // Open the RNG device
    int device_fd = open(device->port_path, O_RDONLY | O_NOCTTY);
    if (device_fd < 0) {
        if (display_progress) {
            printf("Error: Cannot open RNG device %s: %s\n", device->port_path, strerror(errno));
        }
        return 1;
    }
    // Configure serial port for this device type
    if (configure_rng_serial_port(device_fd, device->device_type) != 0) {
        if (display_progress) {
            printf("Error: Failed to configure serial port for %s\n", device->friendly_name);
        }
        close(device_fd);
        return 1;
    }
    // Standard delay for TrueRNG devices
    usleep(100000); // 100ms
    // Open pad file for read/write
    FILE* pad_file = fopen(pad_path, "r+b");
    if (!pad_file) {
        if (display_progress) {
            printf("Error: Cannot open pad file for modification: %s\n", pad_path);
            printf("Reason: %s\n", strerror(errno));
            // Provide additional diagnostics
            if (errno == EROFS) {
                printf("The filesystem appears to be read-only. Check if the drive is mounted read-only.\n");
            } else if (errno == EACCES) {
                printf("Permission denied. Check file permissions and mount options.\n");
            } else if (errno == ENOENT) {
                printf("File not found. The pad file may have been moved or deleted.\n");
            } else if (errno == EISDIR) {
                printf("Path is a directory, not a file.\n");
            } else {
                printf("This may be due to filesystem limitations or mount options.\n");
            }
            printf("\nTroubleshooting suggestions:\n");
            printf("1. Ensure the external drive is mounted read-write: mount -o remount,rw /media/teknari/OTP_01\n");
            printf("2. Check file permissions: ls -la '%s'\n", pad_path);
            printf("3. Verify the drive supports the required operations\n");
            printf("4. Try copying the pad to local storage, enhancing it, then copying back\n");
        }
        close(device_fd);
        return 1;
    }
    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("Enhancing entire pad with hardware entropy\n");
    }
    // Process pad in chunks
    unsigned char buffer[64 * 1024]; // 64KB chunks
    size_t bytes_processed = 0;
    time_t start_time = time(NULL);
    int error_occurred = 0;
    while (bytes_processed < total_bytes && !error_occurred) {
        size_t chunk_size = sizeof(buffer);
        if (total_bytes - bytes_processed < chunk_size) {
            chunk_size = total_bytes - bytes_processed;
        }
        // Read entropy from device
        ssize_t entropy_read = read(device_fd, buffer, chunk_size);
        if (entropy_read < 0) {
            if (errno == EINTR) {
                continue; // Interrupted, try again
            }
            if (display_progress) {
                printf("Error: Failed to read from TrueRNG device: %s\n", strerror(errno));
                printf("Device may have been disconnected during operation.\n");
            }
            error_occurred = 1;
            break;
        }
        if (entropy_read == 0) {
            if (display_progress) {
                printf("Error: TrueRNG device returned no data (device disconnected?)\n");
            }
            error_occurred = 1;
            break;
        }
        // Read current pad data at this position
        if (fseek(pad_file, bytes_processed, SEEK_SET) != 0) {
            if (display_progress) {
                printf("Error: Cannot seek to position %zu in pad file\n", bytes_processed);
            }
            error_occurred = 1;
            break;
        }
        unsigned char pad_data[64 * 1024];
        size_t pad_read = fread(pad_data, 1, entropy_read, pad_file);
        if (pad_read != (size_t)entropy_read) {
            if (display_progress) {
                printf("Error: Cannot read pad data at position %zu\n", bytes_processed);
            }
            error_occurred = 1;
            break;
        }
        // XOR entropy with existing pad data
        for (size_t i = 0; i < (size_t)entropy_read; i++) {
            pad_data[i] ^= buffer[i];
        }
        // Seek back and write modified data
        if (fseek(pad_file, bytes_processed, SEEK_SET) != 0) {
            if (display_progress) {
                printf("Error: Cannot seek back to position %zu in pad file\n", bytes_processed);
            }
            error_occurred = 1;
            break;
        }
        if (fwrite(pad_data, 1, entropy_read, pad_file) != (size_t)entropy_read) {
            if (display_progress) {
                printf("Error: Cannot write modified pad data\n");
            }
            error_occurred = 1;
            break;
        }
        bytes_processed += entropy_read;
        // Show progress for large pads
        if (display_progress && bytes_processed % (64 * 1024 * 1024) == 0) { // Every 64MB
            show_progress(bytes_processed, total_bytes, start_time);
        }
    }
    close(device_fd);
    fclose(pad_file);
    if (error_occurred) {
        return 1;
    }
    if (display_progress) {
        show_progress(total_bytes, total_bytes, start_time);
        printf("\n✓ Successfully streamed %zu bytes of hardware entropy to pad\n", bytes_processed);
    }
    return 0;
 }
 // Detect all available hardware RNG devices
 int detect_all_hardware_rng_devices(hardware_rng_device_t* devices, int max_devices, int* num_devices_found) {
    *num_devices_found = 0;
-    // For now, return empty list - full implementation would scan /dev for TrueRNG devices
+    // Scan /dev directory for serial devices (ttyUSB*, ttyACM*)
-    // This is a placeholder that should be implemented when the full TRNG functionality
+    DIR* dev_dir = opendir("/dev");
-    // is moved to the trng module
+    if (!dev_dir) {
        return 1; // Error opening /dev
    }
-    (void)devices; // Suppress unused parameter warning
+    struct dirent* entry;
-    (void)max_devices;
+    while ((entry = readdir(dev_dir)) != NULL && *num_devices_found < max_devices) {
        // Check for serial device patterns
        if (strncmp(entry->d_name, "ttyUSB", 6) == 0 || strncmp(entry->d_name, "ttyACM", 6) == 0) {
            char device_path[512]; // Increased buffer size to prevent truncation
            int ret = snprintf(device_path, sizeof(device_path), "/dev/%s", entry->d_name);
            if (ret >= (int)sizeof(device_path)) {
                continue; // Skip if path would be truncated
            }
-    return 0; // Success but no devices found
+            // Check if this is a TrueRNG/SwiftRNG device by reading VID/PID
            char vid[5], pid[5];
            if (read_usb_device_info(device_path, vid, pid) == 0) {
                hardware_rng_device_type_t device_type = 0;
                // Check against known TrueRNG VID/PID combinations
                if (strcmp(vid, TRUERNG_VID) == 0 && strcmp(pid, TRUERNG_ORIGINAL_PID) == 0) {
                    device_type = TRUERNG_ORIGINAL;
                } else if (strcmp(vid, TRUERNG_VID) == 0 && strcmp(pid, TRUERNG_PRO_PID) == 0) {
                    device_type = TRUERNG_PRO;
                } else if (strcmp(vid, TRUERNG_VID) == 0 && strcmp(pid, TRUERNG_PRO_V2_PID) == 0) {
                    device_type = TRUERNG_PRO_V2;
                }
                if (device_type != 0) {
                    // Found a TrueRNG/SwiftRNG device
                    hardware_rng_device_t* device = &devices[*num_devices_found];
                    strncpy(device->port_path, device_path, sizeof(device->port_path) - 1);
                    device->device_type = device_type;
                    strncpy(device->friendly_name, get_truerng_device_name(device_type), sizeof(device->friendly_name) - 1);
                    // Assume device is working if VID/PID matches (no test needed)
                    device->is_working = 1;
                    (*num_devices_found)++;
                }
            }
        }
    }
    closedir(dev_dir);
    return 0; // Success
 }
 // Configure serial port for different RNG device types
 int configure_rng_serial_port(int fd, hardware_rng_device_type_t device_type) {
    (void)device_type; // Suppress unused parameter warning - all TrueRNG devices use same config
    struct termios tty;
    if (tcgetattr(fd, &tty) != 0) {
        return 1; // Error getting terminal attributes
    }
    // TrueRNG configuration - traditional serial settings
    // TrueRNG devices: 115200 baud, 8N1, no flow control
    cfsetospeed(&tty, B115200);
    cfsetispeed(&tty, B115200);
    tty.c_cflag = (tty.c_cflag & ~CSIZE) | CS8;     // 8-bit chars
    tty.c_cflag |= CLOCAL | CREAD;                   // ignore modem controls, enable reading
    tty.c_cflag &= ~(PARENB | PARODD);              // no parity
    tty.c_cflag &= ~CSTOPB;                          // 1 stop bit
    tty.c_cflag &= ~CRTSCTS;                         // no hardware flow control
    tty.c_iflag &= ~(IXON | IXOFF | IXANY);          // no software flow control
    tty.c_iflag &= ~(ICANON | ECHO | ECHOE | ISIG);  // raw mode
    tty.c_oflag &= ~OPOST;                           // raw output
    // Set timeouts for TrueRNG
    tty.c_cc[VMIN] = 1;   // read at least 1 character
    tty.c_cc[VTIME] = 10; // 1 second timeout
    if (tcsetattr(fd, TCSANOW, &tty) != 0) {
        return 1; // Error setting terminal attributes
    }
    // Flush any existing data
    tcflush(fd, TCIOFLUSH);
    return 0; // Success
 }
 // Collect entropy from a specific TrueRNG device
 int collect_truerng_entropy_from_device(const hardware_rng_device_t* device, unsigned char* entropy_buffer,
                                       size_t target_bytes, size_t* collected_bytes, int display_progress) {
-    // For now, return an error - full implementation needs to be moved from otp.c
+    if (!device || !entropy_buffer || !collected_bytes || target_bytes == 0) {
-    (void)device; // Suppress unused parameter warning
+        return 1; // Invalid parameters
-    (void)entropy_buffer;
+    }
    (void)target_bytes;
    (void)collected_bytes;
    (void)display_progress;
-    fprintf(stderr, "Error: collect_truerng_entropy_from_device not yet implemented in modular version\n");
+
-    return 1; // Error
+    // Open the TrueRNG device
-}
+    int device_fd = open(device->port_path, O_RDONLY | O_NOCTTY);
    if (device_fd < 0) {
        if (display_progress) {
            printf("Error: Cannot open RNG device %s: %s\n", device->port_path, strerror(errno));
        }
        return 1;
    }
    // Configure serial port for this device type
    if (configure_rng_serial_port(device_fd, device->device_type) != 0) {
        if (display_progress) {
            printf("Error: Failed to configure serial port for %s\n", device->friendly_name);
        }
        close(device_fd);
        return 1;
    }
    // Standard delay for TrueRNG devices
    usleep(100000); // 100ms
    if (display_progress) {
        printf("Collecting %zu bytes from %s...\n", target_bytes, device->friendly_name);
    }
    // Read entropy data with timeout protection
    size_t total_read = 0;
    time_t start_time = time(NULL);
    time_t last_progress_time = start_time;
    while (total_read < target_bytes) {
        // Check for overall timeout (5 minutes max for large collections)
        time_t current_time = time(NULL);
        if (difftime(current_time, start_time) > 300) { // 5 minutes timeout
            if (display_progress) {
                printf("Error: Collection timeout - device may be unresponsive\n");
            }
            close(device_fd);
            return 1;
        }
        size_t remaining = target_bytes - total_read;
        size_t chunk_size = (remaining > 4096) ? 4096 : remaining; // Read in 4KB chunks
        ssize_t bytes_read = read(device_fd, entropy_buffer + total_read, chunk_size);
        if (bytes_read < 0) {
            if (errno == EINTR) {
                continue; // Interrupted, try again
            }
            if (errno == EAGAIN || errno == EWOULDBLOCK) {
                // Timeout occurred, check if we have enough data for a test
                if (total_read > 0 && target_bytes > 1024) {
                    // For testing purposes, we have enough data
                    break;
                }
                // For small collections, this is an error
                if (display_progress) {
                    printf("Error: Device read timeout - no data received\n");
                }
                close(device_fd);
                return 1;
            }
            if (display_progress) {
                printf("Error: Failed to read from TrueRNG device: %s\n", strerror(errno));
                printf("Device may have been disconnected.\n");
            }
            close(device_fd);
            return 1;
        }
        if (bytes_read == 0) {
            // End of data - this shouldn't happen for RNG devices
            if (total_read == 0) {
                if (display_progress) {
                    printf("Error: TrueRNG device returned no data (device disconnected or misconfigured?)\n");
                }
                close(device_fd);
                return 1;
            } else {
                // We have some data, might be enough for testing
                break;
            }
        }
        total_read += bytes_read;
        // Show progress
        if (display_progress && (total_read % 1024 == 0 || difftime(current_time, last_progress_time) >= 1)) {
            show_progress(total_read, target_bytes, start_time);
            last_progress_time = current_time;
        }
    }
    close(device_fd);
    if (display_progress) {
        show_progress(target_bytes, target_bytes, start_time);
        printf("\n✓ Successfully collected %zu bytes from TrueRNG device\n", total_read);
    }
    *collected_bytes = total_read;
    return 0;
 }
 // Read USB device VID/PID information from sysfs
 int read_usb_device_info(const char* device_path, char* vid, char* pid) {
    // Extract device name from path (e.g., /dev/ttyUSB0 -> ttyUSB0)
    const char* device_name = strrchr(device_path, '/');
    if (!device_name) device_name = device_path;
    else device_name++; // Skip the '/'
    // Construct sysfs path for USB device info
    char sysfs_path[256];
    snprintf(sysfs_path, sizeof(sysfs_path), "/sys/class/tty/%s/device/../idVendor", device_name);
    FILE* vid_file = fopen(sysfs_path, "r");
    if (!vid_file) {
        return 1; // Cannot read VID
    }
    if (fscanf(vid_file, "%4s", vid) != 1) {
        fclose(vid_file);
        return 1; // Cannot parse VID
    }
    fclose(vid_file);
    // Read PID
    snprintf(sysfs_path, sizeof(sysfs_path), "/sys/class/tty/%s/device/../idProduct", device_name);
    FILE* pid_file = fopen(sysfs_path, "r");
    if (!pid_file) {
        return 1; // Cannot read PID
    }
    if (fscanf(pid_file, "%4s", pid) != 1) {
        fclose(pid_file);
        return 1; // Cannot parse PID
    }
    fclose(pid_file);
    return 0; // Success
 }
 // Get friendly name for hardware RNG device type
 const char* get_truerng_device_name(hardware_rng_device_type_t device_type) {
    switch (device_type) {
        case TRUERNG_ORIGINAL:
            return "TrueRNG";
        case TRUERNG_PRO:
            return "TrueRNG Pro";
        case TRUERNG_PRO_V2:
            return "TrueRNG Pro V2";
        default:
            return "Unknown Hardware RNG Device";
    }
 }
 // Test if a hardware RNG device is working by attempting to read from it
 int test_hardware_rng_device(const hardware_rng_device_t* device) {
    int fd = open(device->port_path, O_RDONLY | O_NONBLOCK);
    if (fd < 0) {
        return 1; // Cannot open device
    }
    // Try to read a small amount of data
    unsigned char test_buffer[16];
    ssize_t bytes_read = read(fd, test_buffer, sizeof(test_buffer));
    close(fd);
    if (bytes_read <= 0) {
        return 1; // Cannot read from device
    }
    return 0; // Device appears to be working
 }
 // Interactive device selection for hardware RNG
 int select_hardware_rng_device_interactive(hardware_rng_device_t* devices, int num_devices, hardware_rng_device_t* selected_device) {
    if (num_devices == 0) {
        printf("No hardware RNG devices found.\n");
        return 1; // No devices available
    }
    if (num_devices == 1) {
        // Only one device, use it automatically
        *selected_device = devices[0];
        printf("Using %s (%s)\n\n", devices[0].friendly_name, devices[0].port_path);
        return 0;
    }
    // Multiple devices - let user choose
    printf("\nAvailable Hardware RNG Devices:\n");
    for (int i = 0; i < num_devices; i++) {
        printf("%d. %s (%s)\n",
               i + 1,
               devices[i].friendly_name,
               devices[i].port_path);
    }
    printf("\nSelect device (1-%d): ", num_devices);
    char input[10];
    if (fgets(input, sizeof(input), stdin) == NULL) {
        return 1; // Input error
    }
    int choice = atoi(input);
    if (choice < 1 || choice > num_devices) {
        printf("Invalid selection.\n");
        return 1;
    }
    *selected_device = devices[choice - 1];
    printf("Selected: %s (%s)\n", selected_device->friendly_name, selected_device->port_path);
    return 0;
 }
--- a/src/ui.c
+++ b/src/ui.c
@@ -15,7 +15,7 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../include/otp.h"
+#include "otp.h"
 // Initialize terminal dimensions
 void init_terminal_dimensions(void) {
--- a/src/util.c
+++ b/src/util.c
@@ -15,10 +15,9 @@
 #include <termios.h>
 #include <fcntl.h>
 #include <math.h>
-#include "../include/otp.h"
+#include "otp.h"
 // Global variables for preferences
 extern char current_pads_dir[512];
 static char default_pad_path[1024] = "";
 void show_progress(uint64_t current, uint64_t total, time_t start_time) {
@@ -355,7 +354,7 @@ int load_preferences(void) {
        }
        // Find the first available pad to set as default
-        DIR* dir = opendir(current_pads_dir);
+        DIR* dir = opendir(get_current_pads_dir());
        if (dir) {
            struct dirent* entry;
            char first_pad_path[1024];
@@ -364,9 +363,10 @@ int load_preferences(void) {
            while ((entry = readdir(dir)) != NULL && !found_pad) {
                if (strstr(entry->d_name, ".pad") && strlen(entry->d_name) == 68) {
                    // Found a pad file - construct full absolute path
-                    if (current_pads_dir[0] == '/') {
+                    const char* pads_dir = get_current_pads_dir();
                    if (pads_dir[0] == '/') {
                        // Already absolute path
-                        int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s", current_pads_dir, entry->d_name);
+                        int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s", pads_dir, entry->d_name);
                        if (ret >= (int)sizeof(first_pad_path)) {
                            // Path was truncated, skip this entry
                            continue;
@@ -375,14 +375,14 @@ int load_preferences(void) {
                        // Relative path - make it absolute
                        char current_dir[512];
                        if (getcwd(current_dir, sizeof(current_dir))) {
-                            int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s/%s", current_dir, current_pads_dir, entry->d_name);
+                            int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s/%s", current_dir, pads_dir, entry->d_name);
                            if (ret >= (int)sizeof(first_pad_path)) {
                                // Path was truncated, skip this entry
                                continue;
                            }
                        } else {
                            // Fallback to relative path
-                            int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s", current_pads_dir, entry->d_name);
+                            int ret = snprintf(first_pad_path, sizeof(first_pad_path), "%s/%s", pads_dir, entry->d_name);
                            if (ret >= (int)sizeof(first_pad_path)) {
                                // Path was truncated, skip this entry
                                continue;
@@ -641,7 +641,7 @@ void get_directory_display(const char* file_path, char* result, size_t result_si
    }
    // Current working directory
-    if (strcmp(dir_path, ".") == 0 || strcmp(dir_path, current_pads_dir) == 0) {
+    if (strcmp(dir_path, ".") == 0 || strcmp(dir_path, get_current_pads_dir()) == 0) {
        strncpy(result, "pads", result_size - 1);
        result[result_size - 1] = '\0';
        return;
--- a/test.sh
+++ b/test.sh
@@ -1,27 +0,0 @@
 #!/bin/bash
 echo "Testing OTP Cipher Implementation"
 echo "================================="
 # Test 1: Generate a pad
 echo "Test 1: Generating pad..."
 ./otp generate test 2
 echo
 # Test 2: Check if files were created
 echo "Test 2: Checking generated files..."
 ls -la test.pad test.state
 echo
 # Test 3: Test encryption
 echo "Test 3: Testing encryption..."
 echo "Secret Message" | ./otp encrypt test > encrypted_output.txt
 cat encrypted_output.txt
 echo
 # Test 4: Test decryption
 echo "Test 4: Testing decryption..."
 cat encrypted_output.txt | ./otp decrypt test
 echo
 echo "Tests completed!"
--- a/tests/temp_device_test.c
+++ b/tests/temp_device_test.c
@@ -0,0 +1,23 @@
 #include <stdio.h>
 #include <stdlib.h>
 #include "include/otp.h"
 int main(int argc, char* argv[]) {
    (void)argc; (void)argv;
    hardware_rng_device_t devices[10];
    int num_devices_found = 0;
    if (detect_all_hardware_rng_devices(devices, 10, &num_devices_found) != 0) {
        printf("ERROR: Device detection failed\n");
        return 1;
    }
    printf("DEVICES_FOUND:%d\n", num_devices_found);
    for (int i = 0; i < num_devices_found; i++) {
        printf("DEVICE:%d:%s:%d:%s\n", i, devices[i].port_path, devices[i].device_type, devices[i].friendly_name);
    }
    return 0;
 }
--- a/tests/test.sh
+++ b/tests/test.sh
@@ -0,0 +1,499 @@
 #!/bin/bash
 # Hardware RNG Device Testing Script
 # Tests all three detected hardware RNG devices for functionality
 # Author: OTP Cipher Implementation
 # Version: 1.0
 set -e  # Exit on any error
 echo "========================================================================"
 echo "Hardware RNG Device Testing Script - OTP Cipher v0.3.16"
 echo "========================================================================"
 echo
 # Colors for output
 RED='\033[0;31m'
 GREEN='\033[0;32m'
 YELLOW='\033[1;33m'
 BLUE='\033[0;34m'
 NC='\033[0m' # No Color
 # Test counters
 TOTAL_TESTS=0
 PASSED_TESTS=0
 FAILED_TESTS=0
 # Function to print test results
 print_result() {
    local test_name="$1"
    local result="$2"
    local details="$3"
    TOTAL_TESTS=$((TOTAL_TESTS + 1))
    if [ "$result" = "PASS" ]; then
        echo -e "${GREEN}✓ PASS${NC}: $test_name"
        PASSED_TESTS=$((PASSED_TESTS + 1))
    elif [ "$result" = "FAIL" ]; then
        echo -e "${RED}✗ FAIL${NC}: $test_name"
        FAILED_TESTS=$((FAILED_TESTS + 1))
        if [ -n "$details" ]; then
            echo -e "  ${RED}Error:${NC} $details"
        fi
    elif [ "$result" = "SKIP" ]; then
        echo -e "${YELLOW}⚠ SKIP${NC}: $test_name"
        if [ -n "$details" ]; then
            echo -e "  ${YELLOW}Reason:${NC} $details"
        fi
    fi
 }
 # Function to test device detection
 test_device_detection() {
    echo -e "${BLUE}=== Device Detection Tests ===${NC}"
    echo
    # Test 1: Check if devices are detected
    echo "Scanning for hardware RNG devices..."
    # Create a temporary test program to check device detection
    cat > temp_device_test.c << 'EOF'
 #include <stdio.h>
 #include <stdlib.h>
 #include "include/otp.h"
 int main(int argc, char* argv[]) {
    (void)argc; (void)argv; // Suppress unused parameter warnings
    hardware_rng_device_t devices[10];
    int num_devices_found = 0;
    if (detect_all_hardware_rng_devices(devices, 10, &num_devices_found) != 0) {
        printf("ERROR: Device detection failed\n");
        return 1;
    }
    printf("DEVICES_FOUND:%d\n", num_devices_found);
    for (int i = 0; i < num_devices_found; i++) {
        printf("DEVICE:%d:%s:%d:%s\n", i, devices[i].port_path, devices[i].device_type, devices[i].friendly_name);
    }
    return 0;
 }
 EOF
    # Compile the test program
    if gcc -Wall -Wextra -std=c99 -Iinclude -o temp_device_test temp_device_test.c src/trng.o src/util.o src/state.o src/pads.o src/crypto.o src/entropy.o src/ui.o nostr_chacha20.o -lm 2>/dev/null; then
        # Run device detection
        DEVICE_OUTPUT=$(./temp_device_test 2>/dev/null)
        DEVICE_COUNT=$(echo "$DEVICE_OUTPUT" | grep "DEVICES_FOUND:" | cut -d: -f2)
        if [ "$DEVICE_COUNT" -gt 0 ]; then
            print_result "Hardware RNG device detection" "PASS" "Found $DEVICE_COUNT devices"
            # Parse device information
            echo "$DEVICE_OUTPUT" | grep "DEVICE:" | while IFS=: read -r prefix index port_path device_type friendly_name; do
                echo "  Device $index: $friendly_name at $port_path (Type: $device_type)"
            done
            echo
            # Store device info for later tests
            echo "$DEVICE_OUTPUT" > temp_devices.txt
        else
            print_result "Hardware RNG device detection" "FAIL" "No devices found"
            echo "  Expected devices: TrueRNG, SwiftRNG variants"
            echo "  Check USB connections and device permissions"
            echo
        fi
        # Clean up
        rm -f temp_device_test temp_device_test.c
    else
        print_result "Device detection compilation" "FAIL" "Could not compile test program"
    fi
 }
 # Function to test individual device connectivity
 test_device_connectivity() {
    echo -e "${BLUE}=== Device Connectivity Tests ===${NC}"
    echo
    if [ ! -f temp_devices.txt ]; then
        print_result "Device connectivity tests" "SKIP" "No devices detected in previous test"
        return
    fi
    DEVICE_COUNT=$(grep "DEVICES_FOUND:" temp_devices.txt | cut -d: -f2)
    if [ "$DEVICE_COUNT" -eq 0 ]; then
        print_result "Device connectivity tests" "SKIP" "No devices available for testing"
        return
    fi
    # Test each detected device
    grep "DEVICE:" temp_devices.txt | while IFS=: read -r prefix index port_path device_type friendly_name; do
        echo "Testing device: $friendly_name at $port_path"
        # Create device-specific test
        cat > temp_connectivity_test.c << 'EOF'
 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>
 #include <time.h>
 #include "include/otp.h"
 int main(int argc, char* argv[]) {
    if (argc != 4) {
        printf("Usage: %s <port_path> <device_type> <friendly_name>\n", argv[0]);
        return 1;
    }
    hardware_rng_device_t device;
    snprintf(device.port_path, sizeof(device.port_path), "%s", argv[1]);
    device.device_type = atoi(argv[2]);
    snprintf(device.friendly_name, sizeof(device.friendly_name), "%s", argv[3]);
    device.is_working = 0;
    // Test with small buffer (1KB) and short timeout
    const size_t test_bytes = 1024;
    unsigned char* test_buffer = malloc(test_bytes);
    if (!test_buffer) {
        printf("ERROR: Cannot allocate test buffer\n");
        return 1;
    }
    size_t collected = 0;
    time_t start_time = time(NULL);
    printf("TESTING:%s\n", device.friendly_name);
    // Test device connectivity with timeout
    int result = collect_truerng_entropy_from_device(&device, test_buffer, test_bytes, &collected, 0);
    time_t end_time = time(NULL);
    double test_duration = difftime(end_time, start_time);
    if (result == 0 && collected > 0) {
        double speed_kbps = (collected / 1024.0) / (test_duration > 0 ? test_duration : 1.0);
        printf("SUCCESS:%zu:%0.2f:%0.2f\n", collected, test_duration, speed_kbps);
    } else {
        printf("FAILED:%d:%zu:%0.2f\n", result, collected, test_duration);
    }
    free(test_buffer);
    return 0;
 }
 EOF
        # Compile and run connectivity test
        if gcc -Wall -Wextra -std=c99 -Iinclude -o temp_connectivity_test temp_connectivity_test.c src/trng.o src/util.o src/state.o src/pads.o src/crypto.o src/entropy.o src/ui.o nostr_chacha20.o -lm 2>/dev/null; then
            # Run test with timeout to prevent hanging
            CONNECTIVITY_OUTPUT=$(timeout 30s ./temp_connectivity_test "$port_path" "$device_type" "$friendly_name" 2>/dev/null || echo "TIMEOUT")
            if echo "$CONNECTIVITY_OUTPUT" | grep -q "SUCCESS:"; then
                # Parse success output
                SUCCESS_LINE=$(echo "$CONNECTIVITY_OUTPUT" | grep "SUCCESS:")
                COLLECTED=$(echo "$SUCCESS_LINE" | cut -d: -f2)
                DURATION=$(echo "$SUCCESS_LINE" | cut -d: -f3)
                SPEED=$(echo "$SUCCESS_LINE" | cut -d: -f4)
                print_result "Device connectivity: $friendly_name" "PASS" "Collected ${COLLECTED} bytes in ${DURATION}s (${SPEED} KB/s)"
            elif echo "$CONNECTIVITY_OUTPUT" | grep -q "FAILED:"; then
                # Parse failure output
                FAILED_LINE=$(echo "$CONNECTIVITY_OUTPUT" | grep "FAILED:")
                ERROR_CODE=$(echo "$FAILED_LINE" | cut -d: -f2)
                COLLECTED=$(echo "$FAILED_LINE" | cut -d: -f3)
                print_result "Device connectivity: $friendly_name" "FAIL" "Error code $ERROR_CODE, collected $COLLECTED bytes"
            elif echo "$CONNECTIVITY_OUTPUT" | grep -q "TIMEOUT"; then
                print_result "Device connectivity: $friendly_name" "FAIL" "Test timed out after 30 seconds"
            else
                print_result "Device connectivity: $friendly_name" "FAIL" "Unexpected test output"
            fi
        else
            print_result "Device connectivity test compilation: $friendly_name" "FAIL" "Could not compile test program"
        fi
        echo
    done
    # Clean up
    rm -f temp_connectivity_test temp_connectivity_test.c
 }
 # Function to test device configuration
 test_device_configuration() {
    echo -e "${BLUE}=== Device Configuration Tests ===${NC}"
    echo
    if [ ! -f temp_devices.txt ]; then
        print_result "Device configuration tests" "SKIP" "No devices detected"
        return
    fi
    # Test serial port configuration for each device type
    grep "DEVICE:" temp_devices.txt | while IFS=: read -r prefix index port_path device_type friendly_name; do
        echo "Testing serial configuration for: $friendly_name"
        # Create configuration test
        cat > temp_config_test.c << 'EOF'
 #include <stdio.h>
 #include <stdlib.h>
 #include <fcntl.h>
 #include <unistd.h>
 #include <termios.h>
 #include "include/otp.h"
 int main(int argc, char* argv[]) {
    if (argc != 3) {
        printf("Usage: %s <port_path> <device_type>\n", argv[0]);
        return 1;
    }
    const char* port_path = argv[1];
    hardware_rng_device_type_t device_type = atoi(argv[2]);
    printf("TESTING_CONFIG:%s:%d\n", port_path, device_type);
    // Test opening the device
    int fd = open(port_path, O_RDONLY | O_NOCTTY | O_NONBLOCK);
    if (fd < 0) {
        printf("FAILED:Cannot open device\n");
        return 1;
    }
    // Test configuring the serial port
    int config_result = configure_rng_serial_port(fd, device_type);
    if (config_result == 0) {
        printf("SUCCESS:Serial port configured successfully\n");
    } else {
        printf("FAILED:Serial port configuration failed\n");
    }
    close(fd);
    return 0;
 }
 EOF
        # Compile and run configuration test
        if gcc -Wall -Wextra -std=c99 -Iinclude -o temp_config_test temp_config_test.c src/trng.o src/util.o src/state.o src/ui.o -lm 2>/dev/null; then
            CONFIG_OUTPUT=$(./temp_config_test "$port_path" "$device_type" 2>/dev/null || echo "ERROR")
            if echo "$CONFIG_OUTPUT" | grep -q "SUCCESS:"; then
                print_result "Serial configuration: $friendly_name" "PASS" "Port configured successfully"
            elif echo "$CONFIG_OUTPUT" | grep -q "FAILED:"; then
                REASON=$(echo "$CONFIG_OUTPUT" | grep "FAILED:" | cut -d: -f2)
                print_result "Serial configuration: $friendly_name" "FAIL" "$REASON"
            else
                print_result "Serial configuration: $friendly_name" "FAIL" "Unexpected configuration result"
            fi
        else
            print_result "Configuration test compilation: $friendly_name" "FAIL" "Could not compile test program"
        fi
    done
    echo
    # Clean up
    rm -f temp_config_test temp_config_test.c
 }
 # Function to test entropy quality
 test_entropy_quality() {
    echo -e "${BLUE}=== Entropy Quality Tests ===${NC}"
    echo
    if [ ! -f temp_devices.txt ]; then
        print_result "Entropy quality tests" "SKIP" "No devices detected"
        return
    fi
    # Test entropy quality for working devices
    grep "DEVICE:" temp_devices.txt | while IFS=: read -r prefix index port_path device_type friendly_name; do
        echo "Testing entropy quality for: $friendly_name"
        # Create entropy quality test
        cat > temp_quality_test.c << 'EOF'
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <time.h>
 #include "include/otp.h"
 // Simple entropy quality check
 double calculate_byte_entropy(unsigned char* data, size_t length) {
    int counts[256] = {0};
    double entropy = 0.0;
    // Count byte frequencies
    for (size_t i = 0; i < length; i++) {
        counts[data[i]]++;
    }
    // Calculate Shannon entropy
    for (int i = 0; i < 256; i++) {
        if (counts[i] > 0) {
            double p = (double)counts[i] / length;
            entropy -= p * log2(p);
        }
    }
    return entropy;
 }
 int main(int argc, char* argv[]) {
    if (argc != 4) {
        printf("Usage: %s <port_path> <device_type> <friendly_name>\n", argv[0]);
        return 1;
    }
    hardware_rng_device_t device;
    snprintf(device.port_path, sizeof(device.port_path), "%s", argv[1]);
    device.device_type = atoi(argv[2]);
    snprintf(device.friendly_name, sizeof(device.friendly_name), "%s", argv[3]);
    // Test with 4KB sample
    const size_t test_bytes = 4096;
    unsigned char* test_buffer = malloc(test_bytes);
    if (!test_buffer) {
        printf("ERROR: Cannot allocate test buffer\n");
        return 1;
    }
    size_t collected = 0;
    printf("TESTING_QUALITY:%s\n", device.friendly_name);
    // Collect entropy sample
    int result = collect_truerng_entropy_from_device(&device, test_buffer, test_bytes, &collected, 0);
    if (result == 0 && collected >= 1024) {  // Need at least 1KB for meaningful analysis
        double entropy = calculate_byte_entropy(test_buffer, collected);
        double entropy_percentage = (entropy / 8.0) * 100.0;  // Max entropy is 8 bits per byte
        if (entropy_percentage >= 95.0) {
            printf("EXCELLENT:%0.2f:%zu\n", entropy_percentage, collected);
        } else if (entropy_percentage >= 85.0) {
            printf("GOOD:%0.2f:%zu\n", entropy_percentage, collected);
        } else if (entropy_percentage >= 70.0) {
            printf("FAIR:%0.2f:%zu\n", entropy_percentage, collected);
        } else {
            printf("POOR:%0.2f:%zu\n", entropy_percentage, collected);
        }
    } else {
        printf("FAILED:%d:%zu\n", result, collected);
    }
    free(test_buffer);
    return 0;
 }
 EOF
        # Compile and run quality test
        if gcc -Wall -Wextra -std=c99 -Iinclude -o temp_quality_test temp_quality_test.c src/trng.o src/util.o src/state.o src/ui.o -lm 2>/dev/null; then
            QUALITY_OUTPUT=$(timeout 30s ./temp_quality_test "$port_path" "$device_type" "$friendly_name" 2>/dev/null || echo "TIMEOUT")
            if echo "$QUALITY_OUTPUT" | grep -q "EXCELLENT:"; then
                QUALITY_LINE=$(echo "$QUALITY_OUTPUT" | grep "EXCELLENT:")
                PERCENTAGE=$(echo "$QUALITY_LINE" | cut -d: -f2)
                BYTES=$(echo "$QUALITY_LINE" | cut -d: -f3)
                print_result "Entropy quality: $friendly_name" "PASS" "Excellent quality (${PERCENTAGE}% entropy, ${BYTES} bytes)"
            elif echo "$QUALITY_OUTPUT" | grep -q "GOOD:"; then
                QUALITY_LINE=$(echo "$QUALITY_OUTPUT" | grep "GOOD:")
                PERCENTAGE=$(echo "$QUALITY_LINE" | cut -d: -f2)
                BYTES=$(echo "$QUALITY_LINE" | cut -d: -f3)
                print_result "Entropy quality: $friendly_name" "PASS" "Good quality (${PERCENTAGE}% entropy, ${BYTES} bytes)"
            elif echo "$QUALITY_OUTPUT" | grep -q "FAIR:"; then
                QUALITY_LINE=$(echo "$QUALITY_OUTPUT" | grep "FAIR:")
                PERCENTAGE=$(echo "$QUALITY_LINE" | cut -d: -f2)
                BYTES=$(echo "$QUALITY_LINE" | cut -d: -f3)
                print_result "Entropy quality: $friendly_name" "PASS" "Fair quality (${PERCENTAGE}% entropy, ${BYTES} bytes)"
            elif echo "$QUALITY_OUTPUT" | grep -q "POOR:"; then
                QUALITY_LINE=$(echo "$QUALITY_OUTPUT" | grep "POOR:")
                PERCENTAGE=$(echo "$QUALITY_LINE" | cut -d: -f2)
                BYTES=$(echo "$QUALITY_LINE" | cut -d: -f3)
                print_result "Entropy quality: $friendly_name" "FAIL" "Poor quality (${PERCENTAGE}% entropy, ${BYTES} bytes)"
            elif echo "$QUALITY_OUTPUT" | grep -q "FAILED:"; then
                print_result "Entropy quality: $friendly_name" "FAIL" "Could not collect sufficient entropy for analysis"
            elif echo "$QUALITY_OUTPUT" | grep -q "TIMEOUT"; then
                print_result "Entropy quality: $friendly_name" "FAIL" "Quality test timed out"
            else
                print_result "Entropy quality: $friendly_name" "FAIL" "Unexpected quality test output"
            fi
        else
            print_result "Quality test compilation: $friendly_name" "FAIL" "Could not compile test program"
        fi
    done
    echo
    # Clean up
    rm -f temp_quality_test temp_quality_test.c
 }
 # Function to print final summary
 print_summary() {
    echo
    echo "========================================================================"
    echo -e "${BLUE}Test Summary${NC}"
    echo "========================================================================"
    echo "Total tests run: $TOTAL_TESTS"
    echo -e "Passed: ${GREEN}$PASSED_TESTS${NC}"
    echo -e "Failed: ${RED}$FAILED_TESTS${NC}"
    echo -e "Success rate: $(( (PASSED_TESTS * 100) / (TOTAL_TESTS > 0 ? TOTAL_TESTS : 1) ))%"
    echo
    if [ $FAILED_TESTS -eq 0 ]; then
        echo -e "${GREEN}🎉 All tests passed! Hardware RNG devices are working correctly.${NC}"
    elif [ $PASSED_TESTS -gt $FAILED_TESTS ]; then
        echo -e "${YELLOW}⚠ Some tests failed, but most devices are working.${NC}"
        echo "Check the failed tests above for specific device issues."
    else
        echo -e "${RED}❌ Multiple test failures detected.${NC}"
        echo "Hardware RNG devices may have connectivity or configuration issues."
    fi
    echo
 }
 # Main test execution
 main() {
    echo "Starting comprehensive hardware RNG device testing..."
    echo "This will test device detection, connectivity, configuration, and entropy quality."
    echo
    # Ensure the OTP binary exists
    if [ ! -f "./otp" ]; then
        echo -e "${RED}Error: OTP binary not found. Please run 'make' first.${NC}"
        exit 1
    fi
    # Run all test suites
    test_device_detection
    test_device_connectivity
    test_device_configuration
    test_entropy_quality
    # Clean up temporary files
    rm -f temp_devices.txt
    # Print final summary
    print_summary
 }
 # Run main function
 main "$@"
--- a/tests/test_truerng.c
+++ b/tests/test_truerng.c
@@ -0,0 +1,55 @@
 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>
 #include <time.h>
 #include "include/otp.h"
 int main(int argc, char* argv[]) {
    (void)argc; (void)argv; // Suppress unused parameter warnings
    hardware_rng_device_t device;
    snprintf(device.port_path, sizeof(device.port_path), "/dev/ttyUSB0");
    device.device_type = TRUERNG_ORIGINAL;
    snprintf(device.friendly_name, sizeof(device.friendly_name), "TrueRNG");
    device.is_working = 1;
    printf("Debug: Device type set to: %d (TRUERNG_ORIGINAL should be %d)\n", device.device_type, TRUERNG_ORIGINAL);
    printf("Debug: Comparison result: device.device_type == SWIFTRNG is %s\n", 
           (device.device_type == SWIFTRNG) ? "TRUE" : "FALSE");
    // Test with small buffer (1KB) and short timeout
    const size_t test_bytes = 1024;
    unsigned char* test_buffer = malloc(test_bytes);
    if (!test_buffer) {
        printf("ERROR: Cannot allocate test buffer\n");
        return 1;
    }
    size_t collected = 0;
    time_t start_time = time(NULL);
    printf("Testing TrueRNG device at %s...\n", device.port_path);
    // Test device connectivity with timeout
    int result = collect_truerng_entropy_from_device(&device, test_buffer, test_bytes, &collected, 1);
    time_t end_time = time(NULL);
    double test_duration = difftime(end_time, start_time);
    if (result == 0 && collected > 0) {
        double speed_kbps = (collected / 1024.0) / (test_duration > 0 ? test_duration : 1.0);
        printf("SUCCESS: Collected %zu bytes in %.2f seconds (%.2f KB/s)\n", collected, test_duration, speed_kbps);
        // Show first few bytes as hex
        printf("First 16 bytes: ");
        for (int i = 0; i < 16 && i < (int)collected; i++) {
            printf("%02x ", test_buffer[i]);
        }
        printf("\n");
    } else {
        printf("FAILED: Error code %d, collected %zu bytes in %.2f seconds\n", result, collected, test_duration);
    }
    free(test_buffer);
    return result;
 }
Author	SHA1	Message	Date
Laan Tungir	a5a1bd92c4	Version v0.3.23 - Reorganized project structure - all sources in src/, builds in build/	2025-12-18 08:54:57 -04:00
Laan Tungir	3ff91e7681	Version v0.3.22 - Fix delete error	2025-12-18 08:45:16 -04:00
Laan Tungir	05f5d6ca4f	Version v0.3.21 - Fixing errors with adding entropy to file	2025-12-18 08:34:52 -04:00
Laan Tungir	33b34bf5a5	Reupload	2025-10-09 10:45:04 -04:00
Laan Tungir	9d91ec912a	Version v0.3.20 - .	2025-10-05 10:30:26 -04:00
Laan Tungir	7e431d98e9	Version v0.3.19 - Completed modularization project	2025-10-05 08:59:31 -04:00
Laan Tungir	90ffb25a2b	Version v0.3.18 - Refactoring complete	2025-10-05 08:51:24 -04:00