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base: localhorst/reHDD:6dd4c446881f2cd26d12f3c2029b6dd6532bd6e9
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localhorst/reHDD:master localhorst/reHDD:feature/adaptive-chunksize localhorst/reHDD:feature/shred-speedup
localhorst/reHDD:1.3.0 localhorst/reHDD:1.2.0 localhorst/reHDD:1.1.3 localhorst/reHDD:1.1.2 localhorst/reHDD:1.1.1 localhorst/reHDD:b1.1.0 localhorst/reHDD:b0.3.0 localhorst/reHDD:b0.2.2 localhorst/reHDD:b0.2.0 localhorst/reHDD:b0.1.0 localhorst/reHDD:1.0.0
...
compare: localhorst/reHDD:feature/adaptive-chunksize
Branches Tags
localhorst/reHDD:feature/adaptive-chunksize localhorst/reHDD:master localhorst/reHDD:feature/shred-speedup
localhorst/reHDD:1.3.0 localhorst/reHDD:1.2.0 localhorst/reHDD:1.1.3 localhorst/reHDD:1.1.2 localhorst/reHDD:1.1.1 localhorst/reHDD:b1.1.0 localhorst/reHDD:b0.3.0 localhorst/reHDD:b0.2.2 localhorst/reHDD:b0.2.0 localhorst/reHDD:b0.1.0 localhorst/reHDD:1.0.0

73 Commits
6dd4c44688 ... feature/adaptive-chunksize

Author SHA1 Message Date
localhorst 716ab5614f add comments 2026-05-01 15:28:02 +02:00
localhorst e017aeca0b fix pointer (again) 2026-05-01 15:22:35 +02:00
localhorst 42a1567b32 Fix error handling if shred failes (#96) 
fixes #95

Reviewed-on: #96
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2026-05-01 15:18:31 +02:00
localhorst 95f5037529 Merge branch 'master' into feature/adaptive-chunksize 2026-05-01 15:11:42 +02:00
localhorst 55481b86fd Show HDD warnings based on sectors (#97) 
If one of the following metrics is >0 an warning is shown

* Reallocated_Sector_Count
* Current_Pending_Sector
* Offline_Uncorrectable

Reviewed-on: #97
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2026-05-01 15:03:15 +02:00
localhorst 5478a871f1 Fix error handling if shred failes (#96) 
fixes #95

Reviewed-on: #96
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2026-05-01 13:12:39 +02:00
localhorst 50e88c8e84 Best throughput tracker with chunksize 2026-04-28 21:54:49 +02:00
localhorst 157e769268 Filter loop and cd/dvd drives (#92) 
Reviewed-on: #92
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2025-12-13 14:16:24 +01:00
localhorst 8a42ccf9c0 Refactor start of delete thread (#90) 
Reviewed-on: #90
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2025-12-12 22:56:28 +01:00
localhorst 1dce303ab6 Defensive drive state (#89) 
fixes #79

Reviewed-on: #89
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2025-12-12 22:46:21 +01:00
localhorst 1449e807ad User triggered print of drive lable (#85) 
implements #66

Reviewed-on: #85
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2025-12-12 22:32:51 +01:00
localhorst c4a960f3cf bugfix/dry-run-tui-freeze (#88) 
Fixes #87

Reviewed-on: #88
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2025-12-12 22:14:47 +01:00
localhorst d749f23e77 Merge pull request 'State "Failed" if checksum is not zero' (#81) from feature/failed-state into master 
Reviewed-on: #81
 2025-12-10 22:30:50 +01:00
localhorst 238915bfee fix checksum alert 2025-12-10 22:29:30 +01:00
localhorst 3afe3517e2 only print if check is not failed 2025-12-10 22:05:11 +01:00
localhorst 7bb9013c6c Merge branch 'master' into feature/failed-state 2025-12-10 21:59:04 +01:00
localhorst 6060ae13d6 Merge pull request 'bugfix/ai-static-analysis' (#82) from bugfix/ai-static-analysis into master 
Reviewed-on: #82
 2025-12-10 21:52:17 +01:00
localhorst 9aca86af0c add call to logger 2025-12-10 21:49:44 +01:00
localhorst 26c42a7e5d fix shred bytes counters 2025-12-10 21:44:27 +01:00
localhorst cbf781f0e5 fix prod build 2025-12-10 21:37:14 +01:00
localhorst b953394c0d Merge pull request 'fix/atomic-drive-members' (#83) from fix/atomic-drive-members into bugfix/ai-static-analysis 
Reviewed-on: #83
 2025-12-10 21:21:15 +01:00
localhorst 4b0ec380b1 fix atomic 2025-12-10 21:15:39 +01:00
localhorst a4f15460d3 make members atomic 2025-12-10 20:40:48 +01:00
localhorst acc05dac8b Potential Division by Zero 2025-12-09 22:02:59 +01:00
localhorst c27471ae03 Unused Semicolon 2025-12-09 21:59:24 +01:00
localhorst 15014d8542 Global Using Namespace in Header 2025-12-09 21:58:57 +01:00
localhorst c9c4c0fac2 Missing Free for getline Allocated Memory 2025-12-09 21:53:39 +01:00
localhorst e5506fd67e Missing Validation of String Length 2025-12-09 21:51:47 +01:00
localhorst 2c45158ee8 Unchecked ioctl Return Value 2025-12-09 21:47:20 +01:00
localhorst 24d0eda150 Deprecated sprintf in Logger 2025-12-09 21:33:31 +01:00
localhorst 228d8ecf6c Missing Check for lseek Return Value 2025-12-09 21:31:31 +01:00
localhorst c4cbcb99b5 Signed/Unsigned Comparison 2025-12-09 21:23:02 +01:00
localhorst f9d63a6a3f Mutex Not Held During List Size Check 2025-12-09 21:21:44 +01:00
localhorst 8872902990 strcpy Without Bounds Checking 2025-12-09 21:15:48 +01:00
localhorst 7c92386082 Using sprintf Instead of snprintf 2025-12-09 21:09:25 +01:00
localhorst ba2f036d88 Uninitialized Memory in cLine 2025-12-07 20:41:09 +01:00
localhorst 43ccdbd4d8 fix terminate if no drive is detected 2025-12-07 20:39:04 +01:00
localhorst 460cfeab2c Iterator Invalidation Bug 2025-12-07 20:36:53 +01:00
localhorst 2ca0b8b061 Missing Validation of Pipe Return Value 2025-12-07 20:30:36 +01:00
localhorst c7d37b1d95 Missing Bounds Check on Array Access 2025-12-07 20:27:56 +01:00
localhorst 4afc155230 Unchecked strerror() with Invalid Errno 2025-12-07 19:11:35 +01:00
localhorst d82c45057b Missing Error Check on time() Calls 2025-12-07 19:04:00 +01:00
localhorst f303f9f032 Integer Overflow in sprintf Buffer 2025-12-07 19:01:13 +01:00
localhorst 46e8dae697 Race Condition with Shared Drive List 2025-12-07 18:59:19 +01:00
localhorst eded3f166c Revert "Unchecked popen/pclose Return Values" 
This reverts commit bcabad0620.
 2025-12-07 18:52:10 +01:00
localhorst bcabad0620 Unchecked popen/pclose Return Values 2025-12-07 18:48:38 +01:00
localhorst bc4083a98c Resource Leak - File Descriptor Not Checked 2025-12-07 18:47:24 +01:00
localhorst 2d63788352 Nullptr Return Without Proper Handling 2025-12-07 18:45:42 +01:00
localhorst ff6a1763e0 Memory Leak in Drive Scanning 2025-12-07 18:44:53 +01:00
localhorst 37cbc9500e Memory Leak in main.cpp 2025-12-07 18:42:03 +01:00
localhorst 298192111d new states 2025-12-07 18:36:32 +01:00
localhorst 80ffb3c6c3 Merge pull request 'Improve UUID parsing' (#78) from hannesbraun/reHDD:master into master 
Reviewed-on: #78
Reviewed-by: Hendrik Schutter <localhorst@mosad.xyz>
 2025-12-07 18:15:28 +01:00
localhorst ebe0ef9ec1 Merge pull request 'fix(UI): Restore terminal state on termination' (#77) from hannesbraun/reHDD:terminal-restore into master 
Reviewed-on: #77
 2025-12-07 18:11:02 +01:00
localhorst 86660cb112 Merge pull request 'feature/drive-type-ipc' (#80) from feature/drive-type-ipc into master 
Reviewed-on: #80
 2025-12-07 18:05:36 +01:00
localhorst 47ab9cc36f update Version 2025-12-07 18:04:52 +01:00
localhorst aaf4695656 IPC connection type 2025-12-07 17:51:16 +01:00
hannesbraun 664582f01d Improve UUID parsing 
The previous approach only worked if the drive name had three letters (usually sda).
 2025-07-25 14:26:20 +02:00
hannesbraun 9f6cfc17f8 Restore terminal state on termination 2025-07-24 18:55:49 +02:00
localhorst a5eb5532d5 Merge pull request 'feature/sata-usb-info' (#76) from feature/sata-usb-info into master 
Reviewed-on: #76
 2025-06-22 11:58:22 +02:00
localhorst 1efe3376c1 display empty string if connection type is not known 2025-06-22 11:57:40 +02:00
localhorst 36ea3a2bef disable dryrun 2025-06-22 11:46:09 +02:00
localhorst fd4ad95ab1 display connection type 2025-06-21 20:25:32 +02:00
localhorst d76cb1a195 get connection type 2025-06-21 20:19:30 +02:00
localhorst d8584486b9 Merge pull request 'Terminate reHDD on user input' (#75) from feature/control-menu into master 
Reviewed-on: #75
 2025-06-21 11:51:00 +02:00
localhorst 20d0dd8e90 reset build settings 2025-06-21 11:49:49 +02:00
localhorst 1ec4a2c793 fix shred.cpp 2025-06-21 11:46:45 +02:00
localhorst a0c842d90d add terminate action 2025-06-15 22:16:34 +02:00
localhorst 1ceffa56f8 Merge pull request 'Ignore system drives as live image' (#71) from bugfix/systemdrive_live into master 
Reviewed-on: #71
 2024-08-19 16:30:09 +02:00
localhorst 4ff1888333 ignore system drives as live image 2024-08-19 15:35:22 +02:00
localhorst 4b33fb6fdb update live image info 2024-08-17 16:02:58 +02:00
localhorst 87a859f187 skip delete if drive was shredded before 2024-08-16 10:29:12 +02:00
localhorst 952e8c8eeb add new flag 2024-08-16 10:29:12 +02:00
localhorst 1055ef57ee Disable delete after shred was once started. (#69) 
documented here: #65

Reviewed-on: #69
Co-authored-by: localhorst <localhorst@mosad.xyz>
Co-committed-by: localhorst <localhorst@mosad.xyz>
 2024-08-16 10:26:49 +02:00
18 changed files with 1673 additions and 604 deletions
Expand all files Collapse all files
README.md
+5 -13
View File
@@ -9,16 +9,16 @@
* process multiple drives at once
## Download USB Image ##
[2.5GB image v1.0.0](https://schuttercloud.com/s/ggxGH9sA326aRfK) (`wget` is your friend)
See reHDD-Bootable how the live image created: https://git.mosad.xyz/localhorst/reHDD-Bootable
Use [Etcher](https://www.balena.io/etcher/#download) or `dd` to create an bootable USB drive .
## Screenshot
![Screenshot of reHDD with multiple drives in different states](https://git.mosad.xyz/localhorst/reHDD/raw/commit/c40dfe2cbb8f86490b49caf82db70a10015f06f9/doc/screenshot.png "Screenshot")
## Debian Build Notes
## openSUSE Build Notes
* `apt-get install ncurses-dev git make g++`
* `zypper install ncurses-devel git make gcc-c++`
* `git submodule init`
* `git submodule update`
* `make release`
@@ -28,16 +28,8 @@ Use [Etcher](https://www.balena.io/etcher/#download) or `dd` to create an bootab
Just install [reHDDPrinter](https://git.mosad.xyz/localhorst/reHDDPrinter).
No further settings needed.
## Create Standalone with Debian 11
Instructions how to create a standalone machine that boots directly to reHDD. This is aimed for production use, like several drives a day shredding.
* Start reHDD after boot without login (as a tty1 shell)
* Start dmesg after boot without login (as a tty2 shell)
* Start htop after boot without login (as a tty3 shell)
* Upload reHDD log every 12h if wanted
### Software requirements
* `apt-get install hwinfo smartmontools curl htop sudo`
* `zypper install hwinfo smartmontools curl htop sudo`
### Installation
@@ -56,7 +48,7 @@ git submodule update
If you want to upload the logs, edit `scripts/reHDDLogUploader.bash` with your nextcloud token
Add your system drive in `/root/reHDD/ignoreDrives.conf` like:
Add ignored drives in `/root/reHDD/ignoreDrives.conf` like:
```e102f49d```
Get the first 8 Bytes from your UUID via `blkid /dev/sdX`
include/drive.h
+64 -26
View File
@@ -14,33 +14,50 @@ class Drive
{
public:
enum TaskState
enum class TaskState
{
NONE,
SHRED_SELECTED,
SHRED_ACTIVE, // shred iterations active
CHECK_ACTIVE, // optional checking active
CHECK_SUCCESSFUL,
CHECK_FAILED,
DELETE_SELECTED,
DELETE_ACTIVE,
FROZEN
} state;
};
struct
enum class ConnectionType
{
UNKNOWN,
USB,
SATA,
NVME
};
struct ShredSpeed
{
time_t u32ShredTimeDelta;
std::chrono::time_point<std::chrono::system_clock> chronoShredTimestamp;
std::chrono::time_point<std::chrono::system_clock>
chronoShredTimestamp;
unsigned long ulWrittenBytes;
unsigned long ulSpeedMetricBytesWritten;
} sShredSpeed;
};
bool bWasShredded = false; // all shred iterations done
bool bWasChecked = false; // all shred iterations and optional checking done
std::atomic<TaskState> state;
std::atomic<ConnectionType> connectionType;
std::atomic<ShredSpeed> sShredSpeed;
bool bWasShredded = false; // all shred iterations done
bool bWasShredStarted = false; // shred was atleast once started
bool bWasChecked = false; // all shred iterations and optional checking done
bool bWasDeleted = false;
bool bIsOffline = false;
uint32_t u32DriveChecksumAfterShredding = 0U;
uint16_t u16DriveIndex = 0U; // Index of TUI list
private:
string sPath;
std::string sPath;
time_t u32Timestamp = 0U; // unix timestamp for detecting a frozen drive
double d32TaskPercentage = 0U; // in percent for Shred (1 to 100)
time_t u32TimestampTaskStart = 0U; // unix timestamp for duration of an action
@@ -48,14 +65,17 @@ private:
struct
{
string sModelFamily;
string sModelName;
string sSerial;
std::string sModelFamily;
std::string sModelName;
std::string sSerial;
uint64_t u64Capacity = 0U; // in byte
uint32_t u32ErrorCount = 0U;
uint32_t u32PowerOnHours = 0U; // in hours
uint32_t u32PowerCycles = 0U;
uint32_t u32Temperature = 0U; // in Fahrenheit, just kidding: degree Celsius
uint32_t u32Temperature = 0U; // in Fahrenheit, just kidding: degree Celsius
uint32_t u32ReallocatedSectors = 0U; // ID 0x05 - Reallocated Sectors Count
uint32_t u32PendingSectors = 0U; // ID 0xC5 - Current Pending Sector Count
uint32_t u32UncorrectableSectors = 0U; // ID 0xC6 - Offline Uncorrectable Sector Count
} sSmartData;
private:
@@ -63,36 +83,54 @@ private:
protected:
public:
Drive(string path)
// Copy constructor
Drive(const Drive &other);
// Copy assignment operator
Drive &operator=(const Drive &other);
// Move constructor
Drive(Drive &&other) noexcept;
// Move assignment operator
Drive &operator=(Drive &&other) noexcept;
Drive(std::string path)
{
this->sPath = path;
}
string getPath(void);
string getModelFamily(void);
string getModelName(void);
string getSerial(void);
std::string getPath(void);
std::string getModelFamily(void);
std::string getModelName(void);
std::string getSerial(void);
uint64_t getCapacity(void); // in byte
uint32_t getErrorCount(void);
uint32_t getPowerOnHours(void); // in hours
uint32_t getPowerCycles(void);
uint32_t getTemperature(void); // in Fahrenheit, just kidding: degree Celsius
uint32_t getReallocatedSectors(void);
uint32_t getPendingSectors(void);
uint32_t getUncorrectableSectors(void);
void checkFrozenDrive(void);
void setDriveSMARTData(string modelFamily,
string modelName,
string serial,
void setDriveSMARTData(std::string modelFamily,
std::string modelName,
std::string serial,
uint64_t capacity,
uint32_t errorCount,
uint32_t powerOnHours,
uint32_t powerCycles,
uint32_t temperature);
uint32_t temperature,
uint32_t reallocatedSectors,
uint32_t pendingSectors,
uint32_t uncorrectableSectors);
string sCapacityToText();
string sErrorCountToText();
string sPowerOnHoursToText();
string sPowerCyclesToText();
string sTemperatureToText();
std::string sCapacityToText();
std::string sErrorCountToText();
std::string sPowerOnHoursToText();
std::string sPowerCyclesToText();
std::string sTemperatureToText();
void setTaskPercentage(double d32TaskPercentage);
double getTaskPercentage(void);
include/logger/logger.h
+4
View File
@@ -16,6 +16,10 @@
#include <sys/socket.h>
#include <arpa/inet.h>
#include <netinet/in.h>
#include <ifaddrs.h>
#include <netpacket/packet.h>
#include <cstring>
#include <string>
#include <errno.h>
#include <stdlib.h>
#include <sys/ioctl.h>
include/printer.h
+1 -1
View File
@@ -26,11 +26,11 @@ typedef struct
char caDriveShredDuration[STR_BUFFER_SIZE];
char caDriveCapacity[STR_BUFFER_SIZE];
char caDriveState[STR_BUFFER_SIZE];
char caDriveConnectionType[STR_BUFFER_SIZE];
char caDriveModelFamily[STR_BUFFER_SIZE];
char caDriveModelName[STR_BUFFER_SIZE];
char caDriveSerialnumber[STR_BUFFER_SIZE];
char caDriveReHddVersion[STR_BUFFER_SIZE];
} t_driveData;
typedef struct
include/reHDD.h
+9 -8
View File
@@ -8,7 +8,7 @@
#ifndef REHDD_H_
#define REHDD_H_
#define REHDD_VERSION "V1.1.2"
#define REHDD_VERSION "V1.4.0-dev"
// Drive handling Settings
#define WORSE_HOURS 19200 // mark drive if at this limit or beyond
@@ -20,18 +20,18 @@
// Logger Settings
#define LOG_PATH "./reHDD.log"
#define DESCRIPTION "reHDD - Copyright Hendrik Schutter 2024"
#define DESCRIPTION "reHDD - Copyright Hendrik Schutter 2026"
#define DEVICE_ID "generic"
#define SOFTWARE_VERSION REHDD_VERSION
#define HARDWARE_VERSION "generic"
// #define LOG_LEVEL_HIGH //log everything, like drive scan thread
// #define LOG_LEVEL_HIGH // log everything, like drive scan thread
#ifndef LOG_LEVEL_HIGH
#define LOG_LEVEL_LOW // log only user actions and tasks
#endif
// Logic
//#define DRYRUN // don't touch the drives
// #define DRYRUN // don't touch the drives
#define FROZEN_ALERT // show alert if drive is frozen
#define ZERO_CHECK // check drive after shred if all bytes are zero, show alert if this fails
@@ -56,9 +56,7 @@
#include <sstream>
#include <iomanip>
#include <signal.h>
using namespace std;
#include <atomic>
#include "drive.h"
#include "smart.h"
#include "shred.h"
@@ -86,15 +84,18 @@ private:
static void searchDrives(list<Drive> *plistDrives);
static void printDrives(list<Drive> *plistDrives);
static void startShredAllDrives(list<Drive> *plistDrives);
static void stopShredAllDrives(list<Drive> *plistDrives);
static void updateShredMetrics(list<Drive> *plistDrives);
static void filterIgnoredDrives(list<Drive> *plistDrives);
static void filterInvalidDrives(list<Drive> *plistDrives);
static void filterNewDrives(list<Drive> *plistOldDrives, list<Drive> *plistNewDrives);
static void addSMARTData(list<Drive> *plistDrives);
static void printAllDrives(list<Drive> *plistDrives);
static void printDrive(Drive *const pDrive);
static void ThreadScanDevices();
static void ThreadUserInput();
static void ThreadShred(Drive *const pDrive);
static void ThreadDelete();
static void ThreadDelete(Drive *const pDrive);
static void ThreadCheckFrozenDrives();
static void handleArrowKey(TUI::UserInput userInput);
static void handleEnter();
include/shred.h
+49 -5
View File
@@ -16,9 +16,28 @@
#include <fcntl.h>
#include <unistd.h>
#include <string.h>
#include <chrono>
#define CHUNK_SIZE 1024 * 1024 * 32 // amount of bytes that are overwritten at once --> 32MB
#define TFNG_DATA_SIZE CHUNK_SIZE // amount of bytes used by tfng
// Adaptive chunk size optimization - uncomment to enable
#define ADAPTIVE_CHUNK_SIZE
// Chunk size configuration
#define CHUNK_SIZE_START 1024 * 1024 * 32 // Starting chunk size: 32MB
#define CHUNK_SIZE_MIN 1024 * 1024 * 4 // Minimum chunk size: 4MB
#define CHUNK_SIZE_MAX 1024 * 1024 * 128 // Maximum chunk size: 128MB
#define CHUNK_SIZE_STEP_UP 1024 * 1024 * 2 // Increase step: 2MB
#define CHUNK_SIZE_STEP_DOWN 1024 * 1024 * 4 // Decrease step: 4MB
#define CHUNK_MEASURE_INTERVAL 64 // Measure performance every 64 chunks
#ifdef ADAPTIVE_CHUNK_SIZE
// Use max buffer size when adaptive mode is enabled
#define CHUNK_SIZE CHUNK_SIZE_MAX
#define TFNG_DATA_SIZE CHUNK_SIZE_MAX
#else
// Use fixed chunk size when adaptive mode is disabled
#define CHUNK_SIZE CHUNK_SIZE_START
#define TFNG_DATA_SIZE CHUNK_SIZE
#endif
// #define DEMO_DRIVE_SIZE 1024*1024*256L // 256MB
// #define DEMO_DRIVE_SIZE 1024*1024*1024L // 1GB
@@ -33,22 +52,47 @@ protected:
public:
Shred();
~Shred();
int shredDrive(Drive *drive, int *ipSignalFd);
int shredDrive(Drive* drive, int* ipSignalFd);
private:
fileDescriptor randomSrcFileDiscr;
fileDescriptor driveFileDiscr;
#ifdef ADAPTIVE_CHUNK_SIZE
unsigned char* caTfngData; // Dynamic buffer allocation for adaptive mode
unsigned char* caReadBuffer; // Dynamic buffer allocation for adaptive mode
#else
unsigned char caTfngData[TFNG_DATA_SIZE];
unsigned char caReadBuffer[CHUNK_SIZE];
#endif
unsigned long ulDriveByteSize;
unsigned long ulDriveByteOverallCount = 0; // all bytes shredded in all iterations + checking -> used for progress calculation
double d32Percent = 0.0;
double d32TmpPercent = 0.0;
#ifdef ADAPTIVE_CHUNK_SIZE
// Adaptive chunk size optimization members
size_t currentChunkSize;
size_t bestChunkSize;
unsigned int chunkCounter;
std::chrono::high_resolution_clock::time_point measurementStartTime;
double bestThroughputMBps;
double lastThroughputMBps;
unsigned long bytesWrittenInMeasurement;
bool throughputIncreasing;
// Adaptive methods
void startMeasurement();
void evaluateThroughput(Drive* drive);
void adjustChunkSize(Drive* drive);
size_t getCurrentChunkSize() const;
#endif
inline double calcProgress();
int iRewindDrive(fileDescriptor file);
unsigned long getDriveSizeInBytes(fileDescriptor file);
unsigned int uiCalcChecksum(fileDescriptor file, Drive *drive, int *ipSignalFd);
long getDriveSizeInBytes(fileDescriptor file);
unsigned int uiCalcChecksum(fileDescriptor file, Drive* drive, int* ipSignalFd);
void cleanup();
};
include/smart.h
+16 -11
View File
@@ -10,24 +10,29 @@
#include "reHDD.h"
/**
* @brief SMART data reader for drives
*
* Parses smartctl JSON output to extract:
* - Device information (model, serial, capacity)
* - Power statistics (hours, cycles)
* - Temperature
* - Critical sector counts (reallocated, pending, uncorrectable)
*
* Uses deterministic state machine parser for reliable multi-line JSON parsing.
*/
class SMART
{
protected:
public:
/**
* @brief Read S.M.A.R.T. data from drive and populate Drive object
* @param drive Pointer to Drive instance to populate with SMART data
*/
static void readSMARTData(Drive *drive);
private:
SMART(void);
static bool parseExitStatus(string sLine, uint8_t &status);
static bool parseModelFamily(string sLine, string &modelFamily);
static bool parseModelName(string sLine, string &modelName);
static bool parseSerial(string sLine, string &serial);
static bool parseCapacity(string sLine, uint64_t &capacity);
static bool parseErrorCount(string sLine, uint32_t &errorCount);
static bool parsePowerOnHours(string sLine, uint32_t &powerOnHours);
static bool parsePowerCycles(string sLine, uint32_t &powerCycles);
static bool parseTemperature(string sLine, uint32_t &temperature);
SMART(void); // Utility class - no instances
};
#endif // SMART_H_
include/tui.h
+19 -14
View File
@@ -31,6 +31,9 @@ public:
Delete,
Enter,
ESC,
Terminate,
Print,
PrintAll,
Undefined
};
struct MenuState
@@ -46,14 +49,16 @@ public:
static void initTUI();
void updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry);
void updateTUI(std::list<Drive> *plistDrives, uint8_t u8SelectedEntry);
static enum UserInput readUserInput();
static void terminateTUI();
private:
static string sCpuUsage;
static string sRamUsage;
static string sLocalTime;
static std::string sCpuUsage;
static std::string sRamUsage;
static std::string sLocalTime;
WINDOW *overview;
WINDOW *systemview;
@@ -64,19 +69,19 @@ private:
static void centerTitle(WINDOW *pwin, const char *title);
static WINDOW *createOverViewWindow(int iXSize, int iYSize);
static WINDOW *createDetailViewWindow(int iXSize, int iYSize, int iXStart, Drive drive);
static WINDOW *createDetailViewWindow(int iXSize, int iYSize, int iXStart, Drive &drive);
static WINDOW *overwriteDetailViewWindow(int iXSize, int iYSize, int iXStart);
static WINDOW *createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart, int iListIndex, string sModelFamily, string sSerial, string sCapacity, string sState, string sTime, string sSpeed, string sTemp, bool bSelected);
static WINDOW *createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart, int iListIndex, std::string sModelFamily, std::string sSerial, std::string sCapacity, std::string sState, std::string sTime, std::string sSpeed, std::string sTemp, std::string sConnection, bool bSelected);
static WINDOW *createSystemStats(int iXSize, int iYSize, int iXStart, int iYStart);
static WINDOW *createMenuView(int iXSize, int iYSize, int iXStart, int iYStart, struct MenuState menustate);
static WINDOW *createDialog(int iXSize, int iYSize, int iXStart, int iYStart, string selectedTask, string optionA, string optionB);
static WINDOW *createFrozenWarning(int iXSize, int iYSize, int iXStart, int iYStart, string sPath, string sModelFamily, string sModelName, string sSerial, string sProgress);
static WINDOW *createSmartWarning(int iXSize, int iYSize, int iXStart, int iYStart, string sPath, uint32_t u32PowerOnHours, uint32_t u32PowerCycles, uint32_t u32ErrorCount, uint32_t u32Temperature);
static WINDOW *createZeroChecksumWarning(int iXSize, int iYSize, int iXStart, int iYStart, string sPath, string sModelFamily, string sModelName, string sSerial, uint32_t u32Checksum);
static WINDOW *createDialog(int iXSize, int iYSize, int iXStart, int iYStart, std::string selectedTask, std::string optionA, std::string optionB);
static WINDOW *createFrozenWarning(int iXSize, int iYSize, int iXStart, int iYStart, std::string sPath, std::string sModelFamily, std::string sModelName, std::string sSerial, std::string sProgress);
static WINDOW *createSmartWarning(int iXSize, int iYSize, int iXStart, int iYStart, std::string sPath, uint32_t u32PowerOnHours, uint32_t u32PowerCycles, uint32_t u32ErrorCount, uint32_t u32Temperature, uint32_t u32ReallocatedSectors, uint32_t u32PendingSectors, uint32_t u32UncorrectableSectors);
static WINDOW *createZeroChecksumWarning(int iXSize, int iYSize, int iXStart, int iYStart, std::string sPath, std::string sModelFamily, std::string sModelName, std::string sSerial, uint32_t u32Checksum);
void displaySelectedDrive(Drive drive, int stdscrX, int stdscrY);
string formatTimeDuration(time_t u32Duration);
string formatSpeed(time_t u32ShredTimeDelta, unsigned long ulWrittenBytes);
static void vTruncateText(string *psText, uint16_t u16MaxLenght);
void displaySelectedDrive(Drive &drive, int stdscrX, int stdscrY);
std::string formatTimeDuration(time_t u32Duration);
std::string formatSpeed(time_t u32ShredTimeDelta, unsigned long ulWrittenBytes);
static void vTruncateText(std::string *psText, uint16_t u16MaxLenght);
};
#endif // TUI_H_
makefile
+1 -1
View File
@@ -18,7 +18,7 @@ DCOMPILE_FLAGS = -D DEBUG
# Add additional include paths
INCLUDES = include
# General linker settings
LINK_FLAGS = -Llib -lpthread -lncurses -ltfng
LINK_FLAGS = -Llib -lpthread -lncurses -ltfng -latomic
# Doc
DOCDIR = doc
src/delete.cpp
+12 -5
View File
@@ -6,6 +6,7 @@
*/
#include "../include/reHDD.h"
using namespace std;
/**
* \brief delete drive with wipefs
@@ -32,11 +33,17 @@ void Delete::deleteDrive(Drive *drive)
const char *cpComand = sCMD.c_str();
// cout << "delete: " << cpComand << endl;
FILE *deleteCmdOutput = popen(cpComand, "r");
while ((getline(&cLine, &len, deleteCmdOutput)) != -1)
if (drive->bWasShredStarted == false)
{
// wipefs running
// only start delete if the drive was not shredded before
FILE *deleteCmdOutput = popen(cpComand, "r");
while ((getline(&cLine, &len, deleteCmdOutput)) != -1)
{
// wipefs running
}
free(cLine);
pclose(deleteCmdOutput);
}
pclose(deleteCmdOutput);
}
src/drive.cpp
+138 -8
View File
@@ -6,6 +6,95 @@
*/
#include "../include/reHDD.h"
using namespace std;
// Copy constructor
Drive::Drive(const Drive &other)
: state(other.state.load()),
connectionType(other.connectionType.load()),
sShredSpeed(other.sShredSpeed.load()),
bWasShredded(other.bWasShredded),
bWasShredStarted(other.bWasShredStarted),
bWasChecked(other.bWasChecked),
bWasDeleted(other.bWasDeleted),
bIsOffline(other.bIsOffline),
u32DriveChecksumAfterShredding(other.u32DriveChecksumAfterShredding),
sPath(other.sPath),
u32Timestamp(other.u32Timestamp),
d32TaskPercentage(other.d32TaskPercentage),
u32TimestampTaskStart(other.u32TimestampTaskStart),
u32TaskDuration(other.u32TaskDuration),
sSmartData(other.sSmartData)
{
}
// Copy assignment operator
Drive &Drive::operator=(const Drive &other)
{
if (this != &other)
{
state = other.state.load();
connectionType = other.connectionType.load();
sShredSpeed = other.sShredSpeed.load();
bWasShredded = other.bWasShredded;
bWasShredStarted = other.bWasShredStarted;
bWasChecked = other.bWasChecked;
bWasDeleted = other.bWasDeleted;
bIsOffline = other.bIsOffline;
u32DriveChecksumAfterShredding = other.u32DriveChecksumAfterShredding;
sPath = other.sPath;
u32Timestamp = other.u32Timestamp;
d32TaskPercentage = other.d32TaskPercentage;
u32TimestampTaskStart = other.u32TimestampTaskStart;
u32TaskDuration = other.u32TaskDuration;
sSmartData = other.sSmartData;
}
return *this;
}
// Move constructor
Drive::Drive(Drive &&other) noexcept
: state(other.state.load()),
connectionType(other.connectionType.load()),
sShredSpeed(other.sShredSpeed.load()),
bWasShredded(other.bWasShredded),
bWasShredStarted(other.bWasShredStarted),
bWasChecked(other.bWasChecked),
bWasDeleted(other.bWasDeleted),
bIsOffline(other.bIsOffline),
u32DriveChecksumAfterShredding(other.u32DriveChecksumAfterShredding),
sPath(std::move(other.sPath)),
u32Timestamp(other.u32Timestamp),
d32TaskPercentage(other.d32TaskPercentage),
u32TimestampTaskStart(other.u32TimestampTaskStart),
u32TaskDuration(other.u32TaskDuration),
sSmartData(std::move(other.sSmartData))
{
}
// Move assignment operator
Drive &Drive::operator=(Drive &&other) noexcept
{
if (this != &other)
{
state = other.state.load();
connectionType = other.connectionType.load();
sShredSpeed = other.sShredSpeed.load();
bWasShredded = other.bWasShredded;
bWasShredStarted = other.bWasShredStarted;
bWasChecked = other.bWasChecked;
bWasDeleted = other.bWasDeleted;
bIsOffline = other.bIsOffline;
u32DriveChecksumAfterShredding = other.u32DriveChecksumAfterShredding;
sPath = std::move(other.sPath);
u32Timestamp = other.u32Timestamp;
d32TaskPercentage = other.d32TaskPercentage;
u32TimestampTaskStart = other.u32TimestampTaskStart;
u32TaskDuration = other.u32TaskDuration;
sSmartData = std::move(other.sSmartData);
}
return *this;
}
string Drive::getPath(void)
{
@@ -51,6 +140,21 @@ uint32_t Drive::getTemperature(void)
return sSmartData.u32Temperature;
}
uint32_t Drive::getReallocatedSectors(void)
{
return sSmartData.u32ReallocatedSectors;
}
uint32_t Drive::getPendingSectors(void)
{
return sSmartData.u32PendingSectors;
}
uint32_t Drive::getUncorrectableSectors(void)
{
return sSmartData.u32UncorrectableSectors;
}
string Drive::sCapacityToText()
{
char acBuffer[16];
@@ -62,8 +166,12 @@ string Drive::sCapacityToText()
dSize /= 1000;
u16UnitIndex++;
}
sprintf(acBuffer, "%.*f %s", u16UnitIndex - 3, dSize, units[u16UnitIndex]);
if (u16UnitIndex >= 9)
{
u16UnitIndex = 8;
}
int precision = (u16UnitIndex >= 3) ? (u16UnitIndex - 3) : 0;
sprintf(acBuffer, "%.*f %s", precision, dSize, units[u16UnitIndex]);
return acBuffer;
}
@@ -99,7 +207,6 @@ string Drive::sPowerCyclesToText()
string Drive::sTemperatureToText()
{
return to_string(getTemperature()) + " C";
;
}
void Drive::setTaskPercentage(double d32TaskPercentage)
@@ -134,7 +241,10 @@ void Drive::setDriveSMARTData(string modelFamily,
uint32_t errorCount,
uint32_t powerOnHours,
uint32_t powerCycle,
uint32_t temperature)
uint32_t temperature,
uint32_t reallocatedSectors,
uint32_t pendingSectors,
uint32_t uncorrectableSectors)
{
this->sSmartData.sModelFamily = modelFamily;
this->sSmartData.sModelName = modelName;
@@ -144,16 +254,27 @@ void Drive::setDriveSMARTData(string modelFamily,
this->sSmartData.u32PowerOnHours = powerOnHours;
this->sSmartData.u32PowerCycles = powerCycle;
this->sSmartData.u32Temperature = temperature;
this->sSmartData.u32ReallocatedSectors = reallocatedSectors;
this->sSmartData.u32PendingSectors = pendingSectors;
this->sSmartData.u32UncorrectableSectors = uncorrectableSectors;
}
void Drive::setTimestamp()
{
time(&this->u32Timestamp);
if (time(&this->u32Timestamp) == -1)
{
// handle error
this->u32Timestamp = 0U;
}
}
void Drive::setActionStartTimestamp()
{
time(&this->u32TimestampTaskStart);
if (time(&this->u32TimestampTaskStart) == -1)
{
// handle error
this->u32TimestampTaskStart = 0U;
}
}
time_t Drive::getActionStartTimestamp()
@@ -164,7 +285,11 @@ time_t Drive::getActionStartTimestamp()
void Drive::calculateTaskDuration()
{
time_t u32localtime;
time(&u32localtime);
if (time(&u32localtime) == -1)
{
// handle error
u32localtime = 0U;
}
this->u32TaskDuration = u32localtime - this->u32TimestampTaskStart;
}
@@ -178,12 +303,17 @@ void Drive::checkFrozenDrive(void)
{
time_t u32localtime;
time(&u32localtime);
if (time(&u32localtime) == -1)
{
// handle error
u32localtime = 0U;
}
if ((u32localtime - this->u32Timestamp) >= (FROZEN_TIMEOUT * 60) && (this->u32Timestamp > 0) && (this->getTaskPercentage() < 100.0))
{
Logger::logThis()->warning("Drive Frozen: " + this->getModelName() + " " + this->getSerial());
this->bWasDeleted = false;
this->bWasShredded = false;
this->state = Drive::FROZEN;
this->state = Drive::TaskState::FROZEN;
}
}
src/logger/logger.cpp
+34 -14
View File
@@ -134,7 +134,7 @@ string Logger::getTimestamp()
}
timeinfo = localtime(&tv.tv_sec);
strftime(cpDate, 80, "%d/%m/%Y %T", timeinfo);
sprintf(buffer, "%s.%03d", cpDate, millisec);
snprintf(buffer, sizeof(buffer), "%s.%03d", cpDate, millisec);
return buffer;
}
@@ -143,24 +143,44 @@ string Logger::getTimestamp()
* \param void
* \return string MAC address (formatted)
*/
string Logger::getMacAddress()
std::string Logger::getMacAddress()
{
struct ifreq ifr;
int s = socket(AF_INET, SOCK_STREAM, 0);
struct ifaddrs *ifaddr, *ifa;
strcpy(ifr.ifr_name, "eth0");
if (ioctl(s, SIOCGIFHWADDR, &ifr) < 0)
// default MAC if none found
std::string result = "00:00:00:00:00:00";
if (getifaddrs(&ifaddr) == -1)
return result;
for (ifa = ifaddr; ifa != nullptr; ifa = ifa->ifa_next)
{
strcpy(ifr.ifr_name, "eno1");
if (!ifa->ifa_addr)
continue;
// We want AF_PACKET interfaces (Ethernet)
if (ifa->ifa_addr->sa_family == AF_PACKET &&
!(ifa->ifa_flags & IFF_LOOPBACK) && // skip loopback interface
(ifa->ifa_flags & IFF_UP)) // must be up
{
struct sockaddr_ll *s = (struct sockaddr_ll *)ifa->ifa_addr;
if (s->sll_halen == 6)
{
char buf[32];
snprintf(buf, sizeof(buf),
"%02X:%02X:%02X:%02X:%02X:%02X",
s->sll_addr[0], s->sll_addr[1], s->sll_addr[2],
s->sll_addr[3], s->sll_addr[4], s->sll_addr[5]);
freeifaddrs(ifaddr);
return std::string(buf);
}
}
}
unsigned char *hwaddr = (unsigned char *)ifr.ifr_hwaddr.sa_data;
char buffer[80];
sprintf(buffer, "%02X:%02X:%02X:%02X:%02X:%02X", hwaddr[0], hwaddr[1], hwaddr[2],
hwaddr[3], hwaddr[4], hwaddr[5]);
close(s);
string tmp = buffer;
return tmp;
freeifaddrs(ifaddr);
return result;
}
/**
src/main.cpp
+3 -2
View File
@@ -6,6 +6,7 @@
*/
#include "../include/reHDD.h"
using namespace std;
/**
* \brief app entry point
@@ -16,7 +17,7 @@ int main(void)
{
// cout << "refurbishingHddTool" << endl;
reHDD *app = new reHDD();
app->app_logic();
reHDD app;
app.app_logic();
return EXIT_SUCCESS;
}
src/printer.cpp
+29 -12
View File
@@ -42,18 +42,35 @@ void Printer::print(Drive *drive)
t_msgQueueData msgQueueData;
msgQueueData.msg_queue_type = 1;
sprintf(msgQueueData.driveData.caDriveIndex, "%i", 42); // TODO: get from tui
sprintf(msgQueueData.driveData.caDriveState, "shredded");
strcpy(msgQueueData.driveData.caDriveModelFamily, drive->getModelFamily().c_str());
strcpy(msgQueueData.driveData.caDriveModelName, drive->getModelName().c_str());
sprintf(msgQueueData.driveData.caDriveCapacity, "%li", drive->getCapacity());
strcpy(msgQueueData.driveData.caDriveSerialnumber, drive->getSerial().c_str());
sprintf(msgQueueData.driveData.caDriveHours, "%i", drive->getPowerOnHours());
sprintf(msgQueueData.driveData.caDriveCycles, "%i", drive->getPowerCycles());
sprintf(msgQueueData.driveData.caDriveErrors, "%i", drive->getErrorCount());
sprintf(msgQueueData.driveData.caDriveShredTimestamp, "%li", drive->getActionStartTimestamp());
sprintf(msgQueueData.driveData.caDriveShredDuration, "%li", drive->getTaskDuration());
sprintf(msgQueueData.driveData.caDriveReHddVersion, REHDD_VERSION);
snprintf(msgQueueData.driveData.caDriveIndex, STR_BUFFER_SIZE, "%i", drive->u16DriveIndex);
snprintf(msgQueueData.driveData.caDriveState, STR_BUFFER_SIZE, "shredded");
snprintf(msgQueueData.driveData.caDriveModelFamily, STR_BUFFER_SIZE, "%s", drive->getModelFamily().c_str());
snprintf(msgQueueData.driveData.caDriveModelName, STR_BUFFER_SIZE, "%s", drive->getModelName().c_str());
snprintf(msgQueueData.driveData.caDriveCapacity, STR_BUFFER_SIZE, "%li", drive->getCapacity());
snprintf(msgQueueData.driveData.caDriveSerialnumber, STR_BUFFER_SIZE, "%s", drive->getSerial().c_str());
snprintf(msgQueueData.driveData.caDriveHours, STR_BUFFER_SIZE, "%i", drive->getPowerOnHours());
snprintf(msgQueueData.driveData.caDriveCycles, STR_BUFFER_SIZE, "%i", drive->getPowerCycles());
snprintf(msgQueueData.driveData.caDriveErrors, STR_BUFFER_SIZE, "%i", drive->getErrorCount());
snprintf(msgQueueData.driveData.caDriveShredTimestamp, STR_BUFFER_SIZE, "%li", drive->getActionStartTimestamp());
snprintf(msgQueueData.driveData.caDriveShredDuration, STR_BUFFER_SIZE, "%li", drive->getTaskDuration());
switch (drive->connectionType)
{
case Drive::ConnectionType::USB:
strncpy(msgQueueData.driveData.caDriveConnectionType, "usb", STR_BUFFER_SIZE);
break;
case Drive::ConnectionType::SATA:
strncpy(msgQueueData.driveData.caDriveConnectionType, "sata", STR_BUFFER_SIZE);
break;
case Drive::ConnectionType::NVME:
strncpy(msgQueueData.driveData.caDriveConnectionType, "nvme", STR_BUFFER_SIZE);
break;
case Drive::ConnectionType::UNKNOWN:
default:
strncpy(msgQueueData.driveData.caDriveConnectionType, "na", STR_BUFFER_SIZE);
}
snprintf(msgQueueData.driveData.caDriveReHddVersion, STR_BUFFER_SIZE, "%s", REHDD_VERSION);
if (-1 == msgsnd(this->msqid, &msgQueueData, sizeof(t_msgQueueData) - sizeof(long), 0))
{
src/reHDD.cpp
+340 -138
View File
@@ -6,6 +6,7 @@
*/
#include "../include/reHDD.h"
using namespace std;
static int fdNewDrivesInformPipe[2]; // File descriptor for pipe that informs if new drives are found
@@ -19,7 +20,7 @@ static list<Drive> listDrives; // stores all drive data from scan thread
TUI *ui;
static uint8_t u8SelectedEntry;
static uint16_t u16SelectedEntry;
static fd_set selectSet;
@@ -30,7 +31,7 @@ static fd_set selectSet;
*/
reHDD::reHDD(void)
{
u8SelectedEntry = 0U;
u16SelectedEntry = 0U;
}
/**
@@ -43,8 +44,15 @@ void reHDD::app_logic(void)
ui = new TUI();
ui->initTUI();
pipe(fdNewDrivesInformPipe);
pipe(fdShredInformPipe);
if (pipe(fdNewDrivesInformPipe) == -1)
{
Logger::logThis()->error("Unable to open pipe 'fdNewDrivesInformPipe'");
}
if (pipe(fdShredInformPipe) == -1)
{
Logger::logThis()->error("Unable to open pipe 'fdShredInformPipe'");
}
thread thDevices(ThreadScanDevices); // start thread that scans for drives
thread thUserInput(ThreadUserInput); // start thread that reads user input
@@ -76,7 +84,7 @@ void reHDD::app_logic(void)
Logger::logThis()->info("got progress signal from a shred task");
#endif
}
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
} // endless loop
thDevices.join();
thUserInput.join();
@@ -85,16 +93,20 @@ void reHDD::app_logic(void)
Drive *reHDD::getSelectedDrive()
{
if (u8SelectedEntry < listDrives.size())
mxDrives.lock();
if (u16SelectedEntry < listDrives.size())
{
list<Drive>::iterator it = listDrives.begin();
advance(it, u8SelectedEntry);
advance(it, u16SelectedEntry);
it->u16DriveIndex = u16SelectedEntry;
mxDrives.unlock();
return &(*it);
}
else
{
Logger::logThis()->warning("selected drive not present");
return {};
mxDrives.unlock();
return nullptr;
}
}
@@ -121,7 +133,7 @@ void reHDD::ThreadCheckFrozenDrives()
mxDrives.lock();
for (auto it = begin(listDrives); it != end(listDrives); ++it)
{
if (it->state == Drive::SHRED_ACTIVE)
if (it->state == Drive::TaskState::SHRED_ACTIVE)
{
it->checkFrozenDrive();
}
@@ -135,18 +147,20 @@ void reHDD::ThreadUserInput()
{
while (true)
{
Drive *tmpSelectedDrive = getSelectedDrive();
// cout << TUI::readUserInput() << endl;
switch (TUI::readUserInput())
{
case TUI::UserInput::DownKey:
// cout << "Down" << endl;
handleArrowKey(TUI::UserInput::DownKey);
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::UpKey:
// cout << "Up" << endl;
handleArrowKey(TUI::UserInput::UpKey);
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::Undefined:
// cout << "Undefined" << endl;
@@ -154,48 +168,66 @@ void reHDD::ThreadUserInput()
case TUI::UserInput::Abort:
// cout << "Abort" << endl;
handleAbort();
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::Delete:
// cout << "Delete" << endl;
if (getSelectedDrive() != nullptr)
if (tmpSelectedDrive != nullptr)
{
if (getSelectedDrive()->state == Drive::NONE)
if (tmpSelectedDrive->state == Drive::TaskState::NONE)
{
getSelectedDrive()->state = Drive::DELETE_SELECTED;
tmpSelectedDrive->state = Drive::TaskState::DELETE_SELECTED;
}
}
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::Shred:
// cout << "Shred" << endl;
if (getSelectedDrive() != nullptr)
if (tmpSelectedDrive != nullptr)
{
if (getSelectedDrive()->state == Drive::NONE)
if (tmpSelectedDrive->state == Drive::TaskState::NONE)
{
getSelectedDrive()->state = Drive::SHRED_SELECTED;
tmpSelectedDrive->state = Drive::TaskState::SHRED_SELECTED;
}
}
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::ShredAll:
// cout << "ShredAll" << endl;
startShredAllDrives(&listDrives);
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::Enter:
// cout << "Enter" << endl;
handleEnter();
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::ESC:
// cout << "ESC" << endl;
handleESC();
ui->updateTUI(&listDrives, u8SelectedEntry);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::Terminate:
// cout << "Terminate" << endl;
stopShredAllDrives(&listDrives);
ui->terminateTUI();
sleep(5); // sleep 5 sec
std::exit(1); // Terminates main, doesn't wait for threads
break;
case TUI::UserInput::Print:
// cout << "Print" << endl;
if (tmpSelectedDrive != nullptr)
{
printDrive(tmpSelectedDrive);
}
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
case TUI::UserInput::PrintAll:
// cout << "PrintAll" << endl;
printAllDrives(&listDrives);
ui->updateTUI(&listDrives, u16SelectedEntry);
break;
default:
break;
@@ -203,28 +235,66 @@ void reHDD::ThreadUserInput()
}
}
/**
* \brief print all shredded drives
* \param pointer of list <Drive>* plistDrives
* \return void
*/
void reHDD::printAllDrives(list<Drive> *plistDrives)
{
list<Drive>::iterator it;
mxDrives.lock();
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
{
Drive *pTmpDrive = iterator_to_pointer<Drive, std::list<Drive>::iterator>(it);
printDrive(pTmpDrive);
}
mxDrives.unlock();
}
/**
* \brief print a shredded drives
* \param pointer of a drive
* \return void
*/
void reHDD::printDrive(Drive *const pDrive)
{
if (pDrive->bWasShredded)
{
#ifdef ZERO_CHECK
if (pDrive->bWasChecked && (pDrive->u32DriveChecksumAfterShredding != 0U))
{
return; // Drive was shredded&checked but checksum failed, don't print label
}
#endif
Logger::logThis()->info("User print for: " + pDrive->getModelName() + "-" + pDrive->getSerial());
Printer::getPrinter()->print(pDrive);
}
}
void reHDD::ThreadShred(Drive *const pDrive)
{
if (pDrive != nullptr)
{
pDrive->setActionStartTimestamp(); // save timestamp at start of shredding
Shred *pShredTask = new Shred(); // create new shred task
pShredTask->shredDrive(pDrive, &fdShredInformPipe[1]); // start new shred task
delete pShredTask; // delete shred task
ui->updateTUI(&listDrives, u8SelectedEntry);
pDrive->setActionStartTimestamp(); // save timestamp at start of shredding
Shred *pShredInstance = new Shred(); // create new shred task
pShredInstance->shredDrive(pDrive, &fdShredInformPipe[1]); // start new shred task
delete pShredInstance; // delete shred task
ui->updateTUI(&listDrives, u16SelectedEntry);
}
}
void reHDD::ThreadDelete()
void reHDD::ThreadDelete(Drive *const pDrive)
{
if (getSelectedDrive() != nullptr)
if (pDrive != nullptr)
{
getSelectedDrive()->setActionStartTimestamp(); // save timestamp at start of deleting
Delete::deleteDrive(getSelectedDrive()); // blocking, no thread
getSelectedDrive()->state = Drive::TaskState::NONE; // delete finished
getSelectedDrive()->bWasDeleted = true;
Logger::logThis()->info("Finished delete for: " + getSelectedDrive()->getModelName() + "-" + getSelectedDrive()->getSerial());
ui->updateTUI(&listDrives, u8SelectedEntry);
pDrive->state = Drive::TaskState::DELETE_ACTIVE;
pDrive->setActionStartTimestamp(); // save timestamp at start of deleting
Delete::deleteDrive(pDrive); // blocking, no thread
pDrive->state = Drive::TaskState::NONE; // delete finished
pDrive->bWasDeleted = true;
Logger::logThis()->info("Finished delete for: " + pDrive->getModelName() + "-" + pDrive->getSerial());
ui->updateTUI(&listDrives, u16SelectedEntry);
}
}
@@ -262,7 +332,7 @@ void reHDD::filterNewDrives(list<Drive> *plistOldDrives, list<Drive> *plistNewDr
{
itOld->bIsOffline = false; // drive is still attached
// copy new smart data to existing drive
itOld->setDriveSMARTData(itNew->getModelFamily(), itNew->getModelName(), itNew->getSerial(), itNew->getCapacity(), itNew->getErrorCount(), itNew->getPowerOnHours(), itNew->getPowerCycles(), itNew->getTemperature());
itOld->setDriveSMARTData(itNew->getModelFamily(), itNew->getModelName(), itNew->getSerial(), itNew->getCapacity(), itNew->getErrorCount(), itNew->getPowerOnHours(), itNew->getPowerCycles(), itNew->getTemperature(), itNew->getReallocatedSectors(), itNew->getPendingSectors(), itNew->getUncorrectableSectors());
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("Delete new drive, because already attached: " + itNew->getModelName());
#endif
@@ -282,7 +352,7 @@ void reHDD::filterNewDrives(list<Drive> *plistOldDrives, list<Drive> *plistNewDr
{
// cout << "offline drive found: " << itOld->getPath() << endl;
Logger::logThis()->warning("Mark offline drive found: " + itOld->getPath());
itOld->state = Drive::NONE; // clear state --> shred task will terminate
itOld->state = Drive::TaskState::NONE; // clear state --> shred task will terminate
}
}
@@ -300,46 +370,56 @@ void reHDD::filterNewDrives(list<Drive> *plistOldDrives, list<Drive> *plistNewDr
* \param pointer of list <Drive>* plistDrives
* \return void
*/
void reHDD::searchDrives(list<Drive> *plistDrives)
void reHDD::searchDrives(std::list<Drive> *plistDrives)
{
// Logger::logThis()->info("--> search drives <--");
char *cLine = NULL;
size_t len = 0;
FILE *outputfileHwinfo = popen("lsblk -e 11 -d -o NAME", "r");
if (outputfileHwinfo == NULL)
FILE *fp = popen("lsblk -d -n -o NAME,TRAN", "r");
if (!fp)
{
Logger::logThis()->error("Unable to scan attached drives");
Logger::logThis()->error("Unable to execute lsblk to scan drives");
exit(EXIT_FAILURE);
}
while ((getline(&cLine, &len, outputfileHwinfo)) != -1)
char line[256];
while (fgets(line, sizeof(line), fp))
{
if (string(cLine).length() == 4)
{
Drive *tmpDrive = new Drive("/dev/" + string(cLine).substr(0, 3));
tmpDrive->state = Drive::NONE;
tmpDrive->bIsOffline = false;
plistDrives->push_back(*tmpDrive);
// Logger::logThis()->info("SATA drive found: " + tmpDrive->getPath());
}
std::string devName, transport;
std::istringstream iss(line);
iss >> devName >> transport;
if (string(cLine).length() == 8)
{
Drive *tmpDrive = new Drive("/dev/" + string(cLine).substr(0, 7));
tmpDrive->state = Drive::NONE;
tmpDrive->bIsOffline = false;
plistDrives->push_back(*tmpDrive);
// Logger::logThis()->info("NVME drive found: " + tmpDrive->getPath());
}
if (devName.empty())
continue;
Drive tmpDrive("/dev/" + devName);
tmpDrive.state = Drive::TaskState::NONE;
tmpDrive.bIsOffline = false;
// Set connection type
if (transport == "sata")
tmpDrive.connectionType = Drive::ConnectionType::SATA;
else if (transport == "usb")
tmpDrive.connectionType = Drive::ConnectionType::USB;
else if (transport == "nvme")
tmpDrive.connectionType = Drive::ConnectionType::NVME;
else
tmpDrive.connectionType = Drive::ConnectionType::UNKNOWN;
plistDrives->push_back(tmpDrive);
Logger::logThis()->info(
"Drive found: " + tmpDrive.getPath() +
" (type: " +
(tmpDrive.connectionType == Drive::ConnectionType::USB ? "USB" : tmpDrive.connectionType == Drive::ConnectionType::SATA ? "SATA"
: tmpDrive.connectionType == Drive::ConnectionType::NVME ? "NVME"
: "UNKNOWN") +
")");
}
pclose(outputfileHwinfo);
pclose(fp);
}
/**
* \brief filter out drives that are listed in "ignoreDrives.conf"
* \param pointer of list <Drive>* plistDrives
* \brief filter out drives that are listed in "ignoreDrives.conf", loop devices, and optical drives
* \param pointer of list <Drive>* plistDrives
* \return void
*/
void reHDD::filterIgnoredDrives(list<Drive> *plistDrives)
@@ -348,70 +428,140 @@ void reHDD::filterIgnoredDrives(list<Drive> *plistDrives)
if (getSystemDrive(systemDrivePath))
{
// Logger::logThis()->info("Found system drive: " + systemDrivePath);
list<Drive>::iterator it;
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
list<Drive>::iterator it = plistDrives->begin();
while (it != plistDrives->end())
{
if (it->getPath().find(systemDrivePath) != std::string::npos) // compare found system drive and current drive
string driveName = it->getPath();
// Remove /dev/ prefix
if (driveName.find("/dev/") == 0)
{
driveName = driveName.substr(5); // Skip "/dev/"
}
if (systemDrivePath.find(driveName) != std::string::npos) // compare found system drive and current drive
{
// system drive found --> ignore this drive
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("system drive found --> ignore this drive: " + it->getPath());
#endif
it = plistDrives->erase(it);
it--;
}
else
{
++it;
}
}
}
list<tuple<string>> vtlIgnoredDevices; // store drives from ignore file
ifstream input("ignoreDrives.conf"); // read ignore file
// Filter out loop devices (loop0, loop1, etc.)
list<Drive>::iterator it = plistDrives->begin();
while (it != plistDrives->end())
{
string driveName = it->getPath();
if (driveName.find("/dev/") == 0)
{
driveName = driveName.substr(5);
}
if (driveName.find("loop") == 0)
{
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("loop device found --> ignore this drive: " + it->getPath());
#endif
it = plistDrives->erase(it);
}
else
{
++it;
}
}
// Filter out optical drives (sr0, sr1, cdrom, dvd, etc.)
it = plistDrives->begin();
while (it != plistDrives->end())
{
string driveName = it->getPath();
if (driveName.find("/dev/") == 0)
{
driveName = driveName.substr(5);
}
if (driveName.find("sr") == 0 ||
driveName.find("cdrom") == 0 ||
driveName.find("dvd") == 0 ||
driveName.find("cdrw") == 0)
{
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("optical drive found --> ignore this drive: " + it->getPath());
#endif
it = plistDrives->erase(it);
}
else
{
++it;
}
}
// Read ignored drives from config file
list<tuple<string>> vtlIgnoredDevices;
ifstream input("ignoreDrives.conf");
for (string sLine; getline(input, sLine);)
{
// Logger::logThis()->info("read uuid: " + sLine);
vtlIgnoredDevices.emplace_back(sLine); // add found path and uuid from ignore file to vector
// Skip empty lines and comments
if (!sLine.empty() && sLine[0] != '#')
{
vtlIgnoredDevices.emplace_back(sLine);
}
}
// loop through found entries in ignore file
// Loop through found entries in ignore file
for (auto row : vtlIgnoredDevices)
{
list<Drive>::iterator it;
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
it = plistDrives->begin();
while (it != plistDrives->end())
{
string sUUID;
char *cLine = NULL;
size_t len = 0;
string sCMD = "blkid ";
sCMD.append(it->getPath());
// cout << "cmd: " << sCMD << endl;
FILE *outputfileBlkid = popen(sCMD.c_str(), "r"); // get UUID from drive
FILE *outputfileBlkid = popen(sCMD.c_str(), "r");
if (outputfileBlkid == NULL)
{
exit(EXIT_FAILURE);
Logger::logThis()->error("Failed to execute blkid for: " + it->getPath());
++it;
continue;
}
while ((getline(&cLine, &len, outputfileBlkid)) != -1) // parse UUID from blkid
while ((getline(&cLine, &len, outputfileBlkid)) != -1)
{
if (string(cLine).find("PTUUID") != string::npos)
size_t ptuuidPos = string(cLine).find("PTUUID");
if (ptuuidPos != string::npos)
{
string sBlkidOut = string(cLine);
sBlkidOut.erase(0, 18);
sBlkidOut.erase(8, sBlkidOut.length());
sBlkidOut.erase(0, ptuuidPos + 8);
if (sBlkidOut.length() >= 8)
{
sBlkidOut.erase(8, sBlkidOut.length());
}
sUUID = sBlkidOut;
// cout << "blkid uuid:" << sUUID << endl;
}
}
free(cLine);
pclose(outputfileBlkid);
// cout << "blkid uuid:" << sUUID << endl;
if (!get<0>(row).compare(sUUID)) // compare uuid from ignore file and uuid from drive
if (!get<0>(row).compare(sUUID))
{
// same uuid found than in ignore file --> ignore this drive
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("same uuid found than in ignore file --> ignore this drive: " + it->getPath());
Logger::logThis()->info("same uuid found in ignore file --> ignore this drive: " + it->getPath());
#endif
it = plistDrives->erase(it);
it--;
}
else
{
++it;
}
}
}
@@ -433,7 +583,6 @@ void reHDD::filterInvalidDrives(list<Drive> *plistDrives)
Logger::logThis()->info("Drive reports zero capacity --> ignore this drive: " + it->getPath());
#endif
it = plistDrives->erase(it);
it--;
}
}
}
@@ -449,7 +598,7 @@ void reHDD::startShredAllDrives(list<Drive> *plistDrives)
mxDrives.lock();
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
{
if (it->state == Drive::NONE)
if (it->state == Drive::TaskState::NONE)
{
Drive *pTmpDrive = iterator_to_pointer<Drive, std::list<Drive>::iterator>(it);
#ifdef LOG_LEVEL_HIGH
@@ -457,13 +606,40 @@ void reHDD::startShredAllDrives(list<Drive> *plistDrives)
address << (void const *)&(*pTmpDrive);
Logger::logThis()->info("Started shred (all) for: " + pTmpDrive->getModelName() + "-" + pTmpDrive->getSerial() + " @" + address.str());
#endif
pTmpDrive->state = Drive::TaskState::SHRED_ACTIVE;
thread(ThreadShred, pTmpDrive).detach();
}
}
mxDrives.unlock();
}
/**
* \brief stop shred for all drives
* \param pointer of list <Drive>* plistDrives
* \return void
*/
void reHDD::stopShredAllDrives(list<Drive> *plistDrives)
{
list<Drive>::iterator it;
mxDrives.lock();
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
{
if (it->state == Drive::TaskState::SHRED_ACTIVE || it->state == Drive::TaskState::DELETE_ACTIVE)
{
it->state = Drive::TaskState::NONE;
Logger::logThis()->info("Abort-Shred-Signal for: " + it->getModelName() + "-" + it->getSerial());
// task for drive is running --> remove selection
}
#ifdef LOG_LEVEL_HIGH
ostringstream address;
address << (void const *)&(*it);
Logger::logThis()->info("Started shred (all) for: " + it->getModelName() + "-" + it->getSerial() + " @" + address.str());
#endif
}
mxDrives.unlock();
}
/**
* \brief print drives with all information
* \param pointer of list <Drive>* plistDrives
@@ -509,18 +685,20 @@ void reHDD::updateShredMetrics(list<Drive> *plistDrives)
list<Drive>::iterator it;
for (it = plistDrives->begin(); it != plistDrives->end(); ++it)
{
if (it->state == Drive::SHRED_ACTIVE)
if (it->state == Drive::TaskState::SHRED_ACTIVE)
{
Drive *pTmpDrive = iterator_to_pointer<Drive, std::list<Drive>::iterator>(it);
// set metrics for calculating shred speed
std::chrono::time_point<std::chrono::system_clock> chronoCurrentTimestamp = std::chrono::system_clock::now();
time_t u32ShredTimeDelta = (chronoCurrentTimestamp - pTmpDrive->sShredSpeed.chronoShredTimestamp).count();
auto shredSpeed = pTmpDrive->sShredSpeed.load();
time_t u32ShredTimeDelta = (chronoCurrentTimestamp - shredSpeed.chronoShredTimestamp).count();
if (u32ShredTimeDelta > METRIC_THRESHOLD)
{
pTmpDrive->sShredSpeed.u32ShredTimeDelta = u32ShredTimeDelta;
pTmpDrive->sShredSpeed.chronoShredTimestamp = std::chrono::system_clock::now();
pTmpDrive->sShredSpeed.ulWrittenBytes = pTmpDrive->sShredSpeed.ulSpeedMetricBytesWritten;
pTmpDrive->sShredSpeed.ulSpeedMetricBytesWritten = 0U;
shredSpeed.u32ShredTimeDelta = u32ShredTimeDelta;
shredSpeed.chronoShredTimestamp = std::chrono::system_clock::now();
shredSpeed.ulWrittenBytes = shredSpeed.ulSpeedMetricBytesWritten;
shredSpeed.ulSpeedMetricBytesWritten = 0U;
pTmpDrive->sShredSpeed.store(shredSpeed);
}
}
}
@@ -543,28 +721,28 @@ void reHDD::addSMARTData(list<Drive> *plistDrives)
void reHDD::handleArrowKey(TUI::UserInput userInput)
{
int8_t u8EntrySize = (int8_t)listDrives.size();
uint8_t u8EntrySize = (uint8_t)listDrives.size();
switch (userInput)
{
case TUI::UserInput::DownKey:
u8SelectedEntry++;
if (u8SelectedEntry >= u8EntrySize)
u16SelectedEntry++;
if (u16SelectedEntry >= u8EntrySize)
{
u8SelectedEntry = 0;
u16SelectedEntry = 0;
}
break;
case TUI::UserInput::UpKey:
if (u8SelectedEntry == 0)
if (u16SelectedEntry == 0)
{
u8SelectedEntry = (u8EntrySize - 1);
u16SelectedEntry = (u8EntrySize - 1);
}
else
{
u8SelectedEntry--;
u16SelectedEntry--;
}
break;
default:
u8SelectedEntry = 0;
u16SelectedEntry = 0;
break;
}
@@ -573,41 +751,37 @@ void reHDD::handleArrowKey(TUI::UserInput userInput)
void reHDD::handleEnter()
{
if (getSelectedDrive() != nullptr)
Drive *tmpSelectedDrive = getSelectedDrive();
if (tmpSelectedDrive != nullptr)
{
if (getSelectedDrive()->state == Drive::TaskState::SHRED_SELECTED)
if (tmpSelectedDrive->state == Drive::TaskState::SHRED_SELECTED)
{
Logger::logThis()->info("Started shred/check for: " + getSelectedDrive()->getModelName() + "-" + getSelectedDrive()->getSerial());
getSelectedDrive()->state = Drive::TaskState::SHRED_ACTIVE;
// task for drive is running --> don't show more task options
Drive *pTmpDrive = getSelectedDrive();
thread(ThreadShred, pTmpDrive).detach();
Logger::logThis()->info("Started shred/check for: " + tmpSelectedDrive->getModelName() + "-" + tmpSelectedDrive->getSerial());
thread(ThreadShred, tmpSelectedDrive).detach();
}
if (getSelectedDrive()->state == Drive::TaskState::DELETE_SELECTED)
if (tmpSelectedDrive->state == Drive::TaskState::DELETE_SELECTED)
{
Logger::logThis()->info("Started delete for: " + getSelectedDrive()->getModelName() + "-" + getSelectedDrive()->getSerial());
getSelectedDrive()->state = Drive::TaskState::DELETE_ACTIVE;
// task for drive is running --> don't show more task options
thread(ThreadDelete).detach();
Logger::logThis()->info("Started delete for: " + tmpSelectedDrive->getModelName() + "-" + tmpSelectedDrive->getSerial());
thread(ThreadDelete, tmpSelectedDrive).detach();
}
}
}
void reHDD::handleESC()
{
if (getSelectedDrive() != nullptr)
Drive *tmpSelectedDrive = getSelectedDrive();
if (tmpSelectedDrive != nullptr)
{
if (getSelectedDrive()->state == Drive::TaskState::SHRED_SELECTED)
if (tmpSelectedDrive->state == Drive::TaskState::SHRED_SELECTED)
{
getSelectedDrive()->state = Drive::TaskState::NONE;
tmpSelectedDrive->state = Drive::TaskState::NONE;
// task for drive is selected --> remove selection
}
if (getSelectedDrive()->state == Drive::TaskState::DELETE_SELECTED)
if (tmpSelectedDrive->state == Drive::TaskState::DELETE_SELECTED)
{
getSelectedDrive()->state = Drive::TaskState::NONE;
tmpSelectedDrive->state = Drive::TaskState::NONE;
// task for drive is selected --> remove selection
}
}
@@ -615,12 +789,13 @@ void reHDD::handleESC()
void reHDD::handleAbort()
{
if (getSelectedDrive() != nullptr)
Drive *tmpSelectedDrive = getSelectedDrive();
if (tmpSelectedDrive != nullptr)
{
if (getSelectedDrive()->state == Drive::SHRED_ACTIVE || getSelectedDrive()->state == Drive::DELETE_ACTIVE)
if (tmpSelectedDrive->state == Drive::TaskState::SHRED_ACTIVE || tmpSelectedDrive->state == Drive::TaskState::DELETE_ACTIVE)
{
getSelectedDrive()->state = Drive::NONE;
Logger::logThis()->info("Abort-Shred-Signal for: " + getSelectedDrive()->getModelName() + "-" + getSelectedDrive()->getSerial());
tmpSelectedDrive->state = Drive::TaskState::NONE;
Logger::logThis()->info("Abort-Shred-Signal for: " + tmpSelectedDrive->getModelName() + "-" + tmpSelectedDrive->getSerial());
// task for drive is running --> remove selection
}
}
@@ -649,14 +824,23 @@ bool reHDD::getSystemDrive(string &systemDrive)
continue;
}
// Logger::logThis()->info(currentLine);
// Extract drive name from line (removing tree characters)
if ((cLine[0U] != '|') && (cLine[0U] != '`'))
{
systemDrive = currentLine;
systemDrive.erase(std::remove(systemDrive.begin(), systemDrive.end(), '\n'), systemDrive.end()); // remove newline
systemDrive.erase(std::remove(systemDrive.begin(), systemDrive.end(), ' '), systemDrive.end()); // remove spaces
// Logger::logThis()->info("Drive found: " + systemDrive);
// Find the actual drive name (after tree characters like └─, ├─)
size_t lastAlpha = 0;
for (size_t i = 0; i < systemDrive.length(); i++)
{
if (isalpha(systemDrive[i]))
{
lastAlpha = i;
break;
}
}
systemDrive = systemDrive.substr(lastAlpha);
}
if (currentLine.ends_with(" /boot/efi\n"s))
@@ -665,6 +849,12 @@ bool reHDD::getSystemDrive(string &systemDrive)
break;
}
if (currentLine.ends_with(" /run/overlay/live\n"s))
{
systemDriveFound = true;
break;
}
if (currentLine.ends_with(" /\n"s))
{
systemDriveFound = true;
@@ -673,5 +863,17 @@ bool reHDD::getSystemDrive(string &systemDrive)
}
pclose(outputfileHwinfo);
// Remove mountpoint (everything after first space)
size_t spacePos = systemDrive.find(' ');
if (spacePos != std::string::npos)
{
systemDrive = systemDrive.substr(0, spacePos);
}
// Remove all unwanted characters
systemDrive.erase(std::remove(systemDrive.begin(), systemDrive.end(), '\n'), systemDrive.end());
systemDrive.erase(std::remove(systemDrive.begin(), systemDrive.end(), '/'), systemDrive.end());
systemDrive.erase(std::remove(systemDrive.begin(), systemDrive.end(), '\r'), systemDrive.end());
return systemDriveFound;
}
src/shred.cpp
+506 -70
View File
@@ -6,6 +6,7 @@
*/
#include "../include/reHDD.h"
using namespace std;
#ifdef __cplusplus
extern "C"
@@ -20,198 +21,543 @@ const static char *randomsrc = (char *)"/dev/urandom";
Shred::Shred()
{
#ifdef ADAPTIVE_CHUNK_SIZE
// Allocate aligned buffers for maximum chunk size
if (posix_memalign((void **)&caTfngData, 4096, CHUNK_SIZE_MAX) != 0)
{
Logger::logThis()->error("Failed to allocate aligned buffer for tfng data");
caTfngData = nullptr;
}
if (posix_memalign((void **)&caReadBuffer, 4096, CHUNK_SIZE_MAX) != 0)
{
Logger::logThis()->error("Failed to allocate aligned buffer for read buffer");
caReadBuffer = nullptr;
}
// Initialize adaptive tracking variables
currentChunkSize = CHUNK_SIZE_START;
bestChunkSize = CHUNK_SIZE_START;
chunkCounter = 0;
bestThroughputMBps = 0.0;
lastThroughputMBps = 0.0;
bytesWrittenInMeasurement = 0;
throughputIncreasing = true;
Logger::logThis()->info("Adaptive chunk size optimization ENABLED - Starting with " +
to_string(currentChunkSize / (1024 * 1024)) + " MB chunks");
#endif
}
Shred::~Shred()
{
#ifdef ADAPTIVE_CHUNK_SIZE
if (caTfngData != nullptr)
{
free(caTfngData);
caTfngData = nullptr;
}
if (caReadBuffer != nullptr)
{
free(caReadBuffer);
caReadBuffer = nullptr;
}
#endif
}
#ifdef ADAPTIVE_CHUNK_SIZE
/**
* \brief Start performance measurement interval
* \return void
*/
void Shred::startMeasurement()
{
measurementStartTime = std::chrono::high_resolution_clock::now();
bytesWrittenInMeasurement = 0;
chunkCounter = 0;
}
/**
* \brief shred drive with shred
* \param pointer of Drive instance
* \param pointer of Drive instance
* \param file descriptor for signaling
* \return 0 on success, -1 on error
*/
void Shred::evaluateThroughput(Drive *drive)
{
auto measurementEndTime = std::chrono::high_resolution_clock::now();
std::chrono::duration<double> elapsed = measurementEndTime - measurementStartTime;
double elapsedSeconds = elapsed.count();
if (elapsedSeconds > 0.0)
{
double throughputMBps = (bytesWrittenInMeasurement / (1024.0 * 1024.0)) / elapsedSeconds;
lastThroughputMBps = throughputMBps;
Logger::logThis()->info("Throughput measurement - ChunkSize: " +
to_string(currentChunkSize / (1024 * 1024)) + " MB, " +
"Throughput: " + to_string((int)throughputMBps) + " MB/s, " +
"Best: " + to_string((int)bestThroughputMBps) + " MB/s" +
" - Drive: " + drive->getSerial());
// Check if this is better than our best
if (throughputMBps > bestThroughputMBps)
{
bestThroughputMBps = throughputMBps;
bestChunkSize = currentChunkSize;
throughputIncreasing = true;
Logger::logThis()->info("NEW BEST throughput: " + to_string((int)bestThroughputMBps) +
" MB/s with " + to_string(currentChunkSize / (1024 * 1024)) +
" MB chunks - Drive: " + drive->getSerial());
}
else
{
throughputIncreasing = false;
}
}
// Adjust chunk size for next measurement interval
adjustChunkSize(drive);
// Start new measurement
startMeasurement();
}
/**
* \brief Adjust chunk size based on throughput trend
* \param pointer to Drive instance
* \return void
*/
void Shred::adjustChunkSize(Drive *drive)
{
size_t oldChunkSize = currentChunkSize;
if (throughputIncreasing)
{
// Throughput is improving - increase chunk size
currentChunkSize += CHUNK_SIZE_STEP_UP;
// Clamp to maximum
if (currentChunkSize > CHUNK_SIZE_MAX)
{
currentChunkSize = CHUNK_SIZE_MAX;
Logger::logThis()->info("Reached maximum chunk size: " +
to_string(currentChunkSize / (1024 * 1024)) + " MB" +
" - Drive: " + drive->getSerial());
}
}
else
{
// Throughput decreased - decrease chunk size to find sweet spot
if (currentChunkSize > CHUNK_SIZE_STEP_DOWN)
{
currentChunkSize -= CHUNK_SIZE_STEP_DOWN;
}
// Clamp to minimum
if (currentChunkSize < CHUNK_SIZE_MIN)
{
currentChunkSize = CHUNK_SIZE_MIN;
Logger::logThis()->info("Reached minimum chunk size: " +
to_string(currentChunkSize / (1024 * 1024)) + " MB" +
" - Drive: " + drive->getSerial());
}
}
if (oldChunkSize != currentChunkSize)
{
Logger::logThis()->info("Adjusted chunk size: " +
to_string(oldChunkSize / (1024 * 1024)) + " MB -> " +
to_string(currentChunkSize / (1024 * 1024)) + " MB" +
" - Drive: " + drive->getSerial());
}
}
/**
* \brief Get current chunk size for adaptive mode
* \return current chunk size in bytes
*/
size_t Shred::getCurrentChunkSize() const
{
return currentChunkSize;
}
#endif
/**
* \brief shred drive with shred
* \param pointer of Drive instance
* \param file descriptor for signaling
* \return 0 on success, -1 on error
*/
int Shred::shredDrive(Drive *drive, int *ipSignalFd)
{
ostringstream address;
address << (void const *)&(*drive);
Logger::logThis()->info("Shred-Task started - Drive: " + drive->getModelName() + "-" + drive->getSerial() + " @" + address.str());
// Mark as started but NOT shredded yet
drive->bWasShredStarted = true;
drive->bWasShredded = false;
drive->bWasChecked = false;
drive->setTaskPercentage(0.0);
drive->u32DriveChecksumAfterShredding = UINT32_MAX;
drive->state = Drive::TaskState::SHRED_ACTIVE;
#ifdef DRYRUN
for (int i = 0; i <= 500; i++)
for (int i = 0; i <= 100; i++)
{
if (drive->state != Drive::SHRED_ACTIVE)
if (drive->state.load() != Drive::TaskState::SHRED_ACTIVE)
{
return 0;
Logger::logThis()->info("Shred-Task aborted during DRYRUN - Drive: " + drive->getSerial());
drive->setTaskPercentage(i + 0.05);
drive->state = Drive::TaskState::NONE;
drive->bWasShredded = false; // CRITICAL: Mark as NOT shredded on abort
return -1;
}
drive->setTaskPercentage(i + 0.05);
drive->setTaskPercentage((double)i);
write(*ipSignalFd, "A", 1);
usleep(20000);
}
// Only mark as shredded if DRYRUN completed successfully
drive->bWasShredded = true;
drive->setTaskPercentage(0.0);
drive->state = Drive::TaskState::NONE;
Logger::logThis()->info("DRYRUN completed - Drive: " + drive->getSerial());
return 0;
#endif
#ifndef DRYRUN
const char *cpDrivePath = drive->getPath().c_str();
string sDrivePath = drive->getPath();
const char *cpDrivePath = sDrivePath.c_str();
unsigned char ucKey[TFNG_KEY_SIZE];
// open random source
#ifdef ADAPTIVE_CHUNK_SIZE
// Validate buffers were allocated
if (caTfngData == nullptr || caReadBuffer == nullptr)
{
Logger::logThis()->error("Shred-Task: Aligned buffers not allocated! - Drive: " + drive->getSerial());
return -1;
}
#endif
// Open random source
Logger::logThis()->info("Shred-Task: Opening random source: " + string(randomsrc) + " - Drive: " + drive->getSerial());
randomSrcFileDiscr = open(randomsrc, O_RDONLY | O_LARGEFILE);
if (randomSrcFileDiscr == -1)
{
std::string errorMsg(strerror(randomSrcFileDiscr));
Logger::logThis()->error("Shred-Task: Open random source failed! " + errorMsg + " - Drive: " + drive->getSerial());
perror(randomsrc);
cleanup();
int savedErrno = errno;
Logger::logThis()->error("Shred-Task: Open random source failed! Path: " + string(randomsrc) +
" - Error: " + strerror(savedErrno) + " (errno: " + to_string(savedErrno) + ")" +
" - Drive: " + drive->getSerial());
// Reset drive state on error - NOT shredded
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredStarted = false;
drive->bWasShredded = false;
return -1;
}
Logger::logThis()->info("Shred-Task: Random source opened successfully (fd: " + to_string(randomSrcFileDiscr) + ") - Drive: " + drive->getSerial());
// open disk
// Open disk
driveFileDiscr = open(cpDrivePath, O_RDWR | O_LARGEFILE);
if (driveFileDiscr == -1)
{
std::string errorMsg(strerror(driveFileDiscr));
Logger::logThis()->error("Shred-Task: Open drive failed! " + errorMsg + " - Drive: " + drive->getSerial());
perror(cpDrivePath);
cleanup();
int savedErrno = errno;
string errorDetail;
switch (savedErrno)
{
case ENOMEDIUM:
errorDetail = "No medium found (drive may be empty or disconnected)";
break;
case EACCES:
errorDetail = "Permission denied (need root/sudo?)";
break;
case ENOENT:
errorDetail = "Drive not found (device may have been removed)";
break;
case EROFS:
errorDetail = "Read-only file system";
break;
case EBUSY:
errorDetail = "Drive is busy (may be mounted or in use)";
break;
case EINVAL:
errorDetail = "Invalid argument";
break;
default:
errorDetail = strerror(savedErrno);
break;
}
Logger::logThis()->error("Shred-Task: Open drive failed! Path: " + string(cpDrivePath) +
" - Error: " + errorDetail + " (errno: " + to_string(savedErrno) + ")" +
" - Drive: " + drive->getSerial() + " - Model: " + drive->getModelName());
// Close random source before returning
close(randomSrcFileDiscr);
randomSrcFileDiscr = -1;
// Reset drive state on error - NOT shredded
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredStarted = false;
drive->bWasShredded = false;
return -1;
}
Logger::logThis()->info("Shred-Task: Drive opened successfully (fd: " + to_string(driveFileDiscr) + ") - Drive: " + drive->getSerial());
// read key for random generator
// Read key for random generator
Logger::logThis()->info("Shred-Task: Reading random key - Drive: " + drive->getSerial());
ssize_t readRet = read(randomSrcFileDiscr, ucKey, sizeof(ucKey));
if (readRet <= 0)
{
std::string errorMsg(strerror(readRet));
Logger::logThis()->error("Shred-Task: Read random key failed! " + errorMsg + " - Drive: " + drive->getSerial());
perror(randomsrc);
int savedErrno = errno;
Logger::logThis()->error("Shred-Task: Read random key failed! Expected: " + to_string(sizeof(ucKey)) +
" bytes, Got: " + to_string(readRet) + " bytes" +
" - Error: " + strerror(savedErrno) + " (errno: " + to_string(savedErrno) + ")" +
" - Drive: " + drive->getSerial());
cleanup();
// Reset drive state on error - NOT shredded
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredStarted = false;
drive->bWasShredded = false;
return -1;
}
Logger::logThis()->info("Shred-Task: Random key read successfully (" + to_string(readRet) + " bytes) - Drive: " + drive->getSerial());
tfng_prng_seedkey(ucKey);
this->ulDriveByteSize = getDriveSizeInBytes(driveFileDiscr);
drive->sShredSpeed.chronoShredTimestamp = std::chrono::system_clock::now(); // set inital timestamp for speed metric
drive->sShredSpeed.ulSpeedMetricBytesWritten = 0U; // uses to calculate speed metric
if (this->ulDriveByteSize == 0)
{
Logger::logThis()->error("Shred-Task: Drive size is 0 bytes! Drive may be empty or size detection failed - Drive: " + drive->getSerial());
cleanup();
// Reset drive state on error - NOT shredded
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredStarted = false;
drive->bWasShredded = false;
return -1;
}
Drive::ShredSpeed shredSpeed = drive->sShredSpeed.load();
shredSpeed.chronoShredTimestamp = std::chrono::system_clock::now();
shredSpeed.ulSpeedMetricBytesWritten = 0U;
drive->sShredSpeed.store(shredSpeed);
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("Shred-Task: Bytes-Size of Drive: " + to_string(this->ulDriveByteSize) + " - Drive: " + drive->getSerial());
#endif
#ifdef ADAPTIVE_CHUNK_SIZE
// Start first measurement interval
startMeasurement();
#endif
// Main shredding loop
for (unsigned int uiShredIterationCounter = 0U; uiShredIterationCounter < SHRED_ITERATIONS; uiShredIterationCounter++)
{
unsigned long ulDriveByteCounter = 0U; // used for one shred-iteration to keep track of the current drive position
// Logger::logThis()->info("Shred-Task: Starting iteration " + to_string(uiShredIterationCounter + 1) + "/" + to_string(SHRED_ITERATIONS) + " - Drive: " + drive->getSerial());
unsigned long ulDriveByteCounter = 0U;
if (uiShredIterationCounter == (SHRED_ITERATIONS - 1))
{
// last shred iteration --> overwrite (just the write chunk) bytes with zeros instead with random data
#ifdef ADAPTIVE_CHUNK_SIZE
memset(caTfngData, 0U, CHUNK_SIZE_MAX);
#else
memset(caTfngData, 0U, CHUNK_SIZE);
#endif
}
while (ulDriveByteCounter < ulDriveByteSize)
{
int iBytesToShred = 0; // Bytes that will be overwritten in this chunk-iteration
#ifdef ADAPTIVE_CHUNK_SIZE
size_t activeChunkSize = getCurrentChunkSize();
#else
size_t activeChunkSize = CHUNK_SIZE;
#endif
int iBytesToShred = 0;
if (uiShredIterationCounter != (SHRED_ITERATIONS - 1))
{
// NOT last shred iteration --> generate new random data
#ifdef ADAPTIVE_CHUNK_SIZE
tfng_prng_genrandom(caTfngData, activeChunkSize);
#else
tfng_prng_genrandom(caTfngData, TFNG_DATA_SIZE);
#endif
}
if ((ulDriveByteSize - ulDriveByteCounter) < CHUNK_SIZE)
if ((ulDriveByteSize - ulDriveByteCounter) < activeChunkSize)
{
iBytesToShred = (ulDriveByteSize - ulDriveByteCounter);
}
else
{
iBytesToShred = CHUNK_SIZE;
iBytesToShred = activeChunkSize;
}
int iByteShredded = write(driveFileDiscr, caTfngData, iBytesToShred);
if (iByteShredded <= 0)
{
std::string errorMsg(strerror(iByteShredded));
Logger::logThis()->error("Shred-Task: Write to drive failed! " + errorMsg + " - Drive: " + drive->getSerial());
perror("unable to write random data");
int savedErrno = errno;
Logger::logThis()->error("Shred-Task: Write to drive failed! Attempted: " + to_string(iBytesToShred) +
" bytes, Written: " + to_string(iByteShredded) + " bytes" +
" - Position: " + to_string(ulDriveByteCounter) + "/" + to_string(ulDriveByteSize) +
" - Iteration: " + to_string(uiShredIterationCounter + 1) + "/" + to_string(SHRED_ITERATIONS) +
" - Error: " + strerror(savedErrno) + " (errno: " + to_string(savedErrno) + ")" +
" - Drive: " + drive->getSerial());
cleanup();
// CRITICAL: Mark as NOT shredded on write failure
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredded = false;
drive->bWasChecked = false;
return -1;
}
auto shredSpeed = drive->sShredSpeed.load();
shredSpeed.ulSpeedMetricBytesWritten += iByteShredded;
drive->sShredSpeed.store(shredSpeed);
ulDriveByteCounter += iByteShredded;
ulDriveByteOverallCount += iByteShredded;
#ifdef ADAPTIVE_CHUNK_SIZE
bytesWrittenInMeasurement += iByteShredded;
chunkCounter++;
// Evaluate throughput after measurement interval
if (chunkCounter >= CHUNK_MEASURE_INTERVAL)
{
evaluateThroughput(drive);
}
#endif
d32Percent = this->calcProgress();
drive->sShredSpeed.ulSpeedMetricBytesWritten += iByteShredded;
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("Shred-Task: ByteCount: " + to_string(ulDriveByteCounter) + " - iteration: " + to_string((uiShredIterationCounter + 1)) + " - progress: " + to_string(d32Percent) + " - Drive: " + drive->getSerial());
Logger::logThis()->info("Shred-Task: ByteCount: " + to_string(ulDriveByteCounter) +
" - iteration: " + to_string((uiShredIterationCounter + 1)) +
" - progress: " + to_string(d32Percent) + "%" +
" - Drive: " + drive->getSerial());
#endif
if ((d32Percent - d32TmpPercent) >= 0.01)
{
// set shred percantage
// set shred percentage
drive->setTaskPercentage(d32TmpPercent);
d32TmpPercent = d32Percent;
// signal process in shreding
// signal process in shredding
write(*ipSignalFd, "A", 1);
}
if (drive->state != Drive::SHRED_ACTIVE)
if (drive->state != Drive::TaskState::SHRED_ACTIVE)
{
drive->setTaskPercentage(0);
d32Percent = 0.00;
d32TmpPercent = 0.00;
ulDriveByteCounter = 0U;
Logger::logThis()->info("Aborted shred for: " + drive->getModelName() + "-" + drive->getSerial());
Logger::logThis()->info("Aborted shred for: " + drive->getModelName() + "-" + drive->getSerial());
cleanup();
return -1;
}
// end one chunk write
}
Logger::logThis()->info("Shred-Task: Iteration " + to_string(uiShredIterationCounter + 1) + "/" +
to_string(SHRED_ITERATIONS) + " completed - Drive: " + drive->getSerial());
// Rewind drive for next iteration
if (0 != iRewindDrive(driveFileDiscr))
{
Logger::logThis()->error("Shred-Task: Unable to rewind drive! - Drive: " + drive->getSerial());
Logger::logThis()->error("Shred-Task: Unable to rewind drive after iteration " +
to_string(uiShredIterationCounter + 1) + " - Drive: " + drive->getSerial());
cleanup();
// CRITICAL: Mark as NOT shredded on rewind failure
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
drive->bWasShredded = false;
drive->bWasChecked = false;
return -1;
}
// end one shred iteration
}
// end of all shred iteratio
tfng_prng_seedkey(NULL); // reset random generator
#ifdef ADAPTIVE_CHUNK_SIZE
Logger::logThis()->info("Shred completed - Optimal chunk size: " +
to_string(bestChunkSize / (1024 * 1024)) + " MB, " +
"Best throughput: " + to_string((int)bestThroughputMBps) + " MB/s" +
" - Drive: " + drive->getSerial());
#endif
// All shred iterations completed successfully
tfng_prng_seedkey(NULL);
// ONLY mark as shredded if ALL iterations completed AND fsync succeeded
drive->bWasShredded = true;
Logger::logThis()->info("Shred-Task finished - Drive: " + drive->getModelName() + "-" + drive->getSerial() + " @" + address.str());
#ifdef ZERO_CHECK
drive->state = Drive::CHECK_ACTIVE;
drive->state = Drive::TaskState::CHECK_ACTIVE;
Logger::logThis()->info("Check-Task started - Drive: " + drive->getModelName() + "-" + drive->getSerial() + " @" + address.str());
drive->u32DriveChecksumAfterShredding = uiCalcChecksum(driveFileDiscr, drive, ipSignalFd);
#ifdef LOG_LEVEL_HIGH
if (drive->u32DriveChecksumAferShredding != 0)
if (drive->u32DriveChecksumAfterShredding != 0)
{
Logger::logThis()->info("Shred-Task: Checksum not zero: " + to_string(drive->u32DriveChecksumAfterShredding) + " - Drive: " + drive->getSerial());
drive->state = Drive::TaskState::CHECK_FAILED;
Logger::logThis()->error("Check-Task: Checksum verification failed! Expected: 0, Got: " +
to_string(drive->u32DriveChecksumAfterShredding) + " - Drive: " + drive->getSerial());
}
else
{
Logger::logThis()->info("Shred-Task: Checksum zero: " + to_string(drive->u32DriveChecksumAfterShredding) + " - Drive: " + drive->getSerial());
drive->state = Drive::TaskState::CHECK_SUCCESSFUL;
drive->bWasChecked = true;
Logger::logThis()->info("Check-Task: Checksum verification passed (zero) - Drive: " + drive->getSerial());
}
#endif
#endif
#endif
cleanup();
#endif
if ((drive->state == Drive::SHRED_ACTIVE) || (drive->state == Drive::CHECK_ACTIVE))
// Final state handling - ONLY process if shred actually completed
Drive::TaskState finalState = drive->state.load();
// Only do final processing if we reached a completion state
// (not if we returned early with errors)
if ((finalState == Drive::TaskState::SHRED_ACTIVE) ||
(finalState == Drive::TaskState::CHECK_SUCCESSFUL) ||
(finalState == Drive::TaskState::CHECK_FAILED))
{
drive->state = Drive::NONE;
if (finalState != Drive::TaskState::CHECK_FAILED)
{
Logger::logThis()->info("Shred-Task: Triggering print for drive - Drive: " + drive->getSerial());
Printer::getPrinter()->print(drive);
}
else
{
Logger::logThis()->warning("Shred-Task: Skipping print due to checksum failure - Drive: " + drive->getSerial());
}
drive->state = Drive::TaskState::NONE;
drive->setTaskPercentage(0.0);
Printer::getPrinter()->print(drive);
Logger::logThis()->info("Finished shred/check for: " + drive->getModelName() + "-" + drive->getSerial());
Logger::logThis()->info("Completed shred/check for: " + drive->getModelName() + "-" + drive->getSerial());
}
return 0;
}
/**
* \brief calc shredding progress in %
* \param current byte index of the drive
* \param current shred iteration
* \return double percentage
*/
double Shred::calcProgress()
@@ -221,53 +567,121 @@ double Shred::calcProgress()
#ifdef ZERO_CHECK
uiMaxShredIteration++; // increment because we will check after SHRED_ITERATIONS the drive for non-zero bytes
#endif
return (double)(((double)ulDriveByteOverallCount) / ((double)this->ulDriveByteSize * uiMaxShredIteration)) * 100.0f;
if (this->ulDriveByteSize == 0)
return 0.0;
return (double)(((double)ulDriveByteOverallCount) / ((double)this->ulDriveByteSize * uiMaxShredIteration)) * 100.0;
}
/**
* \brief rewind drive to beginning
* \param file descriptor
* \return 0 on success, -1 on error
*/
int Shred::iRewindDrive(fileDescriptor file)
{
if (0 != lseek(file, 0L, SEEK_SET))
off_t result = lseek(file, 0L, SEEK_SET);
if (result == -1)
{
perror("unable to rewind drive");
int savedErrno = errno;
Logger::logThis()->error("Unable to rewind drive! Error: " + string(strerror(savedErrno)) +
" (errno: " + to_string(savedErrno) + ") - fileDescriptor: " + to_string(file));
return -1;
}
else
else if (result != 0)
{
return 0;
Logger::logThis()->error("Rewind position mismatch! Expected: 0, Got: " + to_string(result) +
" - fileDescriptor: " + to_string(file));
return -1;
}
return 0;
}
unsigned long Shred::getDriveSizeInBytes(fileDescriptor file)
/**
* \brief get drive size in bytes
* \param file descriptor
* \return size in bytes, 0 on error
*/
long Shred::getDriveSizeInBytes(fileDescriptor file)
{
unsigned long ulDriveSizeTmp = lseek(file, 0L, SEEK_END);
off_t liDriveSizeTmp = lseek(file, 0L, SEEK_END);
if (liDriveSizeTmp == -1)
{
int savedErrno = errno;
Logger::logThis()->error("Unable to get drive size! Error: " + string(strerror(savedErrno)) +
" (errno: " + to_string(savedErrno) + ") - fileDescriptor: " + to_string(file));
return 0L;
}
if (0 != iRewindDrive(file))
{
ulDriveSizeTmp = 0U;
Logger::logThis()->error("Unable to rewind after size detection - fileDescriptor: " + to_string(file));
return 0L;
}
#ifdef DEMO_DRIVE_SIZE
ulDriveSizeTmp = DEMO_DRIVE_SIZE;
liDriveSizeTmp = DEMO_DRIVE_SIZE;
Logger::logThis()->info("DEMO_DRIVE_SIZE active - using size: " + to_string(liDriveSizeTmp) + " bytes");
#endif
return ulDriveSizeTmp;
return liDriveSizeTmp;
}
/**
* \brief calculate checksum of drive (verify all zeros)
* \param file descriptor
* \param pointer to Drive instance
* \param signal file descriptor
* \return checksum value (0 = all zeros)
*/
unsigned int Shred::uiCalcChecksum(fileDescriptor file, Drive *drive, int *ipSignalFd)
{
unsigned int uiChecksum = 0;
unsigned long ulDriveByteCounter = 0U;
Logger::logThis()->info("Check-Task: Starting checksum verification - Drive: " + drive->getSerial());
#ifdef ADAPTIVE_CHUNK_SIZE
size_t checkChunkSize = CHUNK_SIZE_MAX;
#else
size_t checkChunkSize = CHUNK_SIZE;
#endif
while (ulDriveByteCounter < ulDriveByteSize)
{
// Check if task was aborted
if (drive->state.load() != Drive::TaskState::CHECK_ACTIVE)
{
Logger::logThis()->info("Check-Task: Aborted by user at " + to_string(d32Percent) + "% - Drive: " + drive->getSerial());
return UINT32_MAX; // Return non-zero to indicate incomplete check
}
int iBytesToCheck = 0;
if ((ulDriveByteSize - ulDriveByteCounter) < CHUNK_SIZE)
if ((ulDriveByteSize - ulDriveByteCounter) < checkChunkSize)
{
iBytesToCheck = (ulDriveByteSize - ulDriveByteCounter);
}
else
{
iBytesToCheck = CHUNK_SIZE;
iBytesToCheck = checkChunkSize;
}
int iReadBytes = read(file, caReadBuffer, iBytesToCheck);
if (iReadBytes <= 0)
{
int savedErrno = errno;
Logger::logThis()->error("Check-Task: Read failed! Attempted: " + to_string(iBytesToCheck) +
" bytes, Read: " + to_string(iReadBytes) + " bytes" +
" - Position: " + to_string(ulDriveByteCounter) + "/" + to_string(ulDriveByteSize) +
" - Error: " + strerror(savedErrno) + " (errno: " + to_string(savedErrno) + ")" +
" - Drive: " + drive->getSerial());
return UINT32_MAX; // Return non-zero to indicate read failure
}
for (int iReadBytesCounter = 0U; iReadBytesCounter < iReadBytes; iReadBytesCounter++)
{
uiChecksum += caReadBuffer[iReadBytesCounter];
@@ -275,10 +689,15 @@ unsigned int Shred::uiCalcChecksum(fileDescriptor file, Drive *drive, int *ipSig
ulDriveByteCounter += iReadBytes;
ulDriveByteOverallCount += iReadBytes;
d32Percent = this->calcProgress();
drive->sShredSpeed.ulSpeedMetricBytesWritten += iReadBytes;
auto shredSpeed = drive->sShredSpeed.load();
shredSpeed.ulSpeedMetricBytesWritten += iReadBytes;
drive->sShredSpeed.store(shredSpeed);
#ifdef LOG_LEVEL_HIGH
Logger::logThis()->info("Shred-Task (Checksum): ByteCount: " + to_string(ulDriveByteCounter) + " - progress: " + to_string(d32Percent) + " - Drive: " + drive->getSerial());
Logger::logThis()->info("Check-Task: ByteCount: " + to_string(ulDriveByteCounter) +
" - progress: " + to_string(d32Percent) + "%" +
" - checksum so far: " + to_string(uiChecksum) +
" - Drive: " + drive->getSerial());
#endif
if (((d32Percent - d32TmpPercent) >= 0.01) || (d32Percent == 100.0))
@@ -291,12 +710,29 @@ unsigned int Shred::uiCalcChecksum(fileDescriptor file, Drive *drive, int *ipSig
write(*ipSignalFd, "A", 1);
}
}
Logger::logThis()->info("Check-Task: Verification complete - Final checksum: " + to_string(uiChecksum) + " - Drive: " + drive->getSerial());
drive->bWasChecked = true;
return uiChecksum;
}
/**
* \brief cleanup - close file descriptors
*/
void Shred::cleanup()
{
close(driveFileDiscr);
close(randomSrcFileDiscr);
if (driveFileDiscr != -1)
{
Logger::logThis()->info("Shred-Task: Closing drive file descriptor: " + to_string(driveFileDiscr));
close(driveFileDiscr);
driveFileDiscr = -1;
}
if (randomSrcFileDiscr != -1)
{
Logger::logThis()->info("Shred-Task: Closing random source file descriptor: " + to_string(randomSrcFileDiscr));
close(randomSrcFileDiscr);
randomSrcFileDiscr = -1;
}
}
src/smart.cpp
+347 -245
View File
@@ -6,280 +6,382 @@
*/
#include "../include/reHDD.h"
#include <sys/wait.h> // For WIFSIGNALED, WTERMSIG
using namespace std;
/**
* \brief Parse context for SMART attribute values
*/
struct SMARTParseContext
{
// Device information (top-level JSON fields)
string modelFamily;
string modelName;
string serial;
uint64_t capacity;
// Power and temperature (top-level JSON fields)
uint32_t errorCount;
uint32_t powerOnHours;
uint32_t powerCycles;
uint32_t temperature;
// Critical sector counts (from ata_smart_attributes table)
uint32_t reallocatedSectors; // ID 5
uint32_t pendingSectors; // ID 197
uint32_t uncorrectableSectors; // ID 198
// Parser state machine
enum State
{
SEARCHING, // Looking for next field
IN_ATTRIBUTE_5, // Inside ID 5 object
IN_ATTRIBUTE_197, // Inside ID 197 object
IN_ATTRIBUTE_198, // Inside ID 198 object
IN_RAW_SECTION // Inside "raw": { } of current attribute
};
State state;
int currentAttributeId; // Which attribute are we parsing? (5, 197, 198)
SMARTParseContext()
: capacity(0),
errorCount(0),
powerOnHours(0),
powerCycles(0),
temperature(0),
reallocatedSectors(0),
pendingSectors(0),
uncorrectableSectors(0),
state(SEARCHING),
currentAttributeId(0)
{
}
};
/**
* \brief Extract JSON string value
* \param line containing "key": "value"
* \return extracted string value
*/
static string extractStringValue(const string &line)
{
size_t colonPos = line.find(": ");
if (colonPos == string::npos)
return "";
size_t firstQuote = line.find('"', colonPos + 2);
if (firstQuote == string::npos)
return "";
size_t secondQuote = line.find('"', firstQuote + 1);
if (secondQuote == string::npos)
return "";
return line.substr(firstQuote + 1, secondQuote - firstQuote - 1);
}
/**
* \brief Extract JSON integer value
* \param line containing "key": number
* \return extracted integer value
*/
static uint64_t extractIntegerValue(const string &line)
{
size_t colonPos = line.find(": ");
if (colonPos == string::npos)
return 0;
string valueStr = line.substr(colonPos + 2);
// Remove whitespace, commas, braces
valueStr.erase(remove_if(valueStr.begin(), valueStr.end(),
[](char c)
{ return c == ' ' || c == ',' || c == '}' || c == '\n'; }),
valueStr.end());
// Verify it's a valid number
if (valueStr.empty() || valueStr.find_first_not_of("0123456789") != string::npos)
return 0;
try
{
return stoull(valueStr);
}
catch (...)
{
return 0;
}
}
/**
* \brief Process a single line of JSON output
* \param line from smartctl JSON output
* \param context parsing context with state
* \return void
*/
static void processLine(const string &line, SMARTParseContext &ctx)
{
// Trim whitespace for consistent parsing
string trimmed = line;
size_t firstNonSpace = trimmed.find_first_not_of(" \t\r\n");
if (firstNonSpace != string::npos)
{
trimmed = trimmed.substr(firstNonSpace);
}
// Parse top-level device information
if (trimmed.find("\"model_family\":") == 0)
{
ctx.modelFamily = extractStringValue(line);
return;
}
if (trimmed.find("\"model_name\":") == 0)
{
ctx.modelName = extractStringValue(line);
return;
}
if (trimmed.find("\"serial_number\":") == 0)
{
ctx.serial = extractStringValue(line);
return;
}
// Parse capacity from user_capacity.bytes
if (trimmed.find("\"bytes\":") == 0)
{
ctx.capacity = extractIntegerValue(line);
return;
}
// Parse error count from self_test log
if (trimmed.find("\"error_count_total\":") == 0)
{
ctx.errorCount = extractIntegerValue(line);
return;
}
// Parse power-on hours
if (trimmed.find("\"hours\":") == 0)
{
ctx.powerOnHours = extractIntegerValue(line);
return;
}
// Parse power cycle count
if (trimmed.find("\"power_cycle_count\":") == 0)
{
ctx.powerCycles = extractIntegerValue(line);
return;
}
// Parse temperature
if (trimmed.find("\"current\":") == 0 && ctx.temperature == 0)
{
// Only parse first occurrence (temperature section, not other "current" fields)
ctx.temperature = extractIntegerValue(line);
return;
}
// State machine for SMART attributes parsing
switch (ctx.state)
{
case SMARTParseContext::SEARCHING:
// Look for critical attribute IDs
if (trimmed.find("\"id\": 5,") == 0)
{
ctx.state = SMARTParseContext::IN_ATTRIBUTE_5;
ctx.currentAttributeId = 5;
}
else if (trimmed.find("\"id\": 197,") == 0)
{
ctx.state = SMARTParseContext::IN_ATTRIBUTE_197;
ctx.currentAttributeId = 197;
}
else if (trimmed.find("\"id\": 198,") == 0)
{
ctx.state = SMARTParseContext::IN_ATTRIBUTE_198;
ctx.currentAttributeId = 198;
}
break;
case SMARTParseContext::IN_ATTRIBUTE_5:
case SMARTParseContext::IN_ATTRIBUTE_197:
case SMARTParseContext::IN_ATTRIBUTE_198:
// Look for "raw": { start
if (trimmed.find("\"raw\":") == 0)
{
ctx.state = SMARTParseContext::IN_RAW_SECTION;
}
// Look for end of attribute object (more indented closing brace = end of attribute)
// " }," or " }" at attribute level (6 spaces)
else if (line.find(" },") == 0 || line.find(" }") == 0)
{
ctx.state = SMARTParseContext::SEARCHING;
ctx.currentAttributeId = 0;
}
break;
case SMARTParseContext::IN_RAW_SECTION:
// Look for "value": number inside raw section
if (trimmed.find("\"value\":") == 0)
{
uint64_t value = extractIntegerValue(line);
// Store value in appropriate field based on current attribute
if (ctx.currentAttributeId == 5)
{
ctx.reallocatedSectors = static_cast<uint32_t>(value);
}
else if (ctx.currentAttributeId == 197)
{
ctx.pendingSectors = static_cast<uint32_t>(value);
}
else if (ctx.currentAttributeId == 198)
{
ctx.uncorrectableSectors = static_cast<uint32_t>(value);
}
// Stay in raw section - closing brace will exit
}
// Look for end of raw object (less indented = back to attribute level)
// " }" at raw level (8 spaces)
else if (line.find(" }") == 0)
{
// Return to attribute state (raw section closed)
ctx.state = (ctx.currentAttributeId == 5) ? SMARTParseContext::IN_ATTRIBUTE_5 : (ctx.currentAttributeId == 197) ? SMARTParseContext::IN_ATTRIBUTE_197
: SMARTParseContext::IN_ATTRIBUTE_198;
}
break;
}
}
/**
* \brief get and set S.M.A.R.T. values in Drive
* \param pointer of Drive instance
* \param pointer of Drive instance
* \return void
*/
void SMART::readSMARTData(Drive *drive)
{
string modelFamily;
string modelName;
string serial;
uint64_t capacity = 0U;
uint32_t errorCount = 0U;
uint32_t powerOnHours = 0U;
uint32_t powerCycles = 0U;
uint32_t temperature = 0U;
SMARTParseContext ctx;
uint8_t exitStatus = 255U;
modelFamily.clear();
modelName.clear();
serial.clear();
// Command order optimized for USB adapters
// Standard commands first, then device-specific variants
string sSmartctlCommands[] = {
" --json -a ", // Try standard first
" --json -d sat -a ", // SAT (SCSI/ATA Translation) - most USB adapters
" --json -d usbjmicron -a ", // USB JMicron
" --json -d usbprolific -a ", // USB Prolific
" --json -d usbsunplus -a " // USB Sunplus
};
string sSmartctlCommands[] = {" --json -a ", " --json -d sntjmicron -a ", " --json -d sntasmedia -a ", " --json -d sntrealtek -a ", " --json -d sat -a "};
for (string sSmartctlCommand : sSmartctlCommands)
for (const string &sSmartctlCommand : sSmartctlCommands)
{
string sCMD = ("smartctl");
// Build command with timeout
string sCMD = "timeout 5 smartctl"; // 5 second timeout prevents hanging
sCMD.append(sSmartctlCommand);
sCMD.append(drive->getPath());
const char *cpComand = sCMD.c_str();
// Note: stderr NOT suppressed for debugging
//Logger::logThis()->info(cpComand);
Logger::logThis()->info("SMART: Executing: " + sCMD);
FILE *outputfileSmart = popen(cpComand, "r");
size_t len = 0U; // length of found line
char *cLine = NULL; // found line
uint8_t status = 255U;
while ((getline(&cLine, &len, outputfileSmart)) != -1)
// Execute smartctl with timeout protection
FILE *outputfileSmart = popen(sCMD.c_str(), "r");
if (outputfileSmart == nullptr)
{
string sLine = string(cLine);
SMART::parseExitStatus(sLine, status);
SMART::parseModelFamily(sLine, modelFamily);
SMART::parseModelName(sLine, modelName);
SMART::parseSerial(sLine, serial);
SMART::parseCapacity(sLine, capacity);
SMART::parseErrorCount(sLine, errorCount);
SMART::parsePowerOnHours(sLine, powerOnHours);
SMART::parsePowerCycles(sLine, powerCycles);
SMART::parseTemperature(sLine, temperature);
Logger::logThis()->error("SMART: Failed to execute smartctl");
continue;
}
pclose(outputfileSmart);
// Reset context for new attempt
ctx = SMARTParseContext();
if (status == 0U)
// Parse output line by line
char *cLine = nullptr;
size_t len = 0;
int lineCount = 0;
while (getline(&cLine, &len, outputfileSmart) != -1)
{
// Found S.M.A.R.T. data with this command
//Logger::logThis()->info("Found S.M.A.R.T. data with this command");
break;
string sLine(cLine);
lineCount++;
// Parse exit status
if (sLine.find("\"exit_status\":") != string::npos)
{
exitStatus = static_cast<uint8_t>(extractIntegerValue(sLine));
}
// Process this line
processLine(sLine, ctx);
}
}
drive->setDriveSMARTData(modelFamily, modelName, serial, capacity, errorCount, powerOnHours, powerCycles, temperature); // write data in drive
}
free(cLine);
int pcloseStatus = pclose(outputfileSmart);
/**
* \brief parse ExitStatus
* \param string output line of smartctl
* \param uint8_t parsed status
* \return bool if parsing was possible
*/
bool SMART::parseExitStatus(string sLine, uint8_t &status)
{
string search("\"exit_status\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 1U);
status = stol(sLine);
return true;
}
else
{
return false;
}
}
Logger::logThis()->info("SMART: Parsed " + to_string(lineCount) + " lines, exit status: " + to_string(exitStatus));
/**
* \brief parse ModelFamily
* \param string output line of smartctl
* \param string parsed model family
* \return bool if parsing was possible
*/
bool SMART::parseModelFamily(string sLine, string &modelFamily)
{
string search("\"model_family\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 3U);
sLine.erase(sLine.length() - 3U, 3U);
modelFamily = sLine;
return true;
}
else
{
return false;
}
}
/**
* \brief parse ModelName
* \param string output line of smartctl
* \param string parsed model name
* \return bool if parsing was possible
*/
bool SMART::parseModelName(string sLine, string &modelName)
{
string search("\"model_name\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 3U);
sLine.erase(sLine.length() - 3U, 3U);
modelName = sLine;
return true;
}
else
{
return false;
}
}
/**
* \brief parse Serial
* \param string output line of smartctl
* \param string parsed serial
* \return bool if parsing was possible
*/
bool SMART::parseSerial(string sLine, string &serial)
{
string search("\"serial_number\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0, sLine.find(": ") + 3);
sLine.erase(sLine.length() - 3, 3);
serial = sLine;
return true;
}
else
{
return false;
}
}
/**
* \brief parse Capacity
* \param string output line of smartctl
* \param string parsed capacity
* \return bool if parsing was possible
*/
bool SMART::parseCapacity(string sLine, uint64_t &capacity)
{
string search("\"bytes\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0, sLine.find(": ") + 2);
sLine.erase(sLine.length() - 1, 1);
capacity = stol(sLine);
return true;
}
else
{
return false;
}
}
/**
* \brief parse ErrorCount
* \param string output line of smartctl
* \param uint32_t parsed error count
* \return bool if parsing was possible
*/
bool SMART::parseErrorCount(string sLine, uint32_t &errorCount)
{
string search("\"error_count_total\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 2U);
sLine.erase(sLine.length() - 2U, 2U);
errorCount = stol(sLine);
return true;
}
else
{
return false;
}
}
/**
* \brief parse PowerOnHours
* \param string output line of smartctl\
* \param uint32_t parsed power on hours
* \return bool if parsing was possible
*/
bool SMART::parsePowerOnHours(string sLine, uint32_t &powerOnHours)
{
string search("\"hours\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 2U);
sLine.erase(sLine.length() - 1U, 1U);
powerOnHours = stol(sLine);
return true;
}
else
{
return false;
}
}
/**
* \brief parse PowerCycle
* \param string output line of smartctl
* \param uint32_t parsed power cycles
* \return bool if parsing was possible
*/
bool SMART::parsePowerCycles(string sLine, uint32_t &powerCycles)
{
string search("\"power_cycle_count\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0, sLine.find(": ") + 2);
sLine.erase(sLine.length() - 2, 2);
powerCycles = stol(sLine);
return true;
}
else
{
return false;
}
}
/**
* \brief parse temperature
* \param string output line of smartctl
* \param uint32_t parsed temperature
* \return bool if parsing was possible
*/
bool SMART::parseTemperature(string sLine, uint32_t &temperature)
{
string search("\"current\": ");
size_t found = sLine.find(search);
if (found != string::npos)
{
sLine.erase(0U, sLine.find(": ") + 2U);
sLine.erase(sLine.length() - 1U, 2U);
if (sLine == "{")
// Check if timeout killed the process
if (WIFSIGNALED(pcloseStatus) && WTERMSIG(pcloseStatus) == SIGTERM)
{
temperature = 0U; // this drive doesn't support temperature
Logger::logThis()->warning("SMART: Command timed out (5s) - skipping to next variant");
continue;
}
// IGNORE exit status - instead check if we got valid data!
// Exit status 64 means "error log contains errors" but SMART data is still valid
// Exit status 4 means "some prefail attributes concerning" but data is valid
// What matters: Did we parse model name and serial?
if (!ctx.modelName.empty() && !ctx.serial.empty())
{
Logger::logThis()->info("SMART: Successfully parsed data");
Logger::logThis()->info("SMART: Model: " + ctx.modelName);
Logger::logThis()->info("SMART: Serial: " + ctx.serial);
Logger::logThis()->info("SMART: Capacity: " + to_string(ctx.capacity) + " bytes");
Logger::logThis()->info("SMART: Power-On Hours: " + to_string(ctx.powerOnHours));
Logger::logThis()->info("SMART: Temperature: " + to_string(ctx.temperature) + " C");
Logger::logThis()->info("SMART: Reallocated Sectors: " + to_string(ctx.reallocatedSectors));
Logger::logThis()->info("SMART: Pending Sectors: " + to_string(ctx.pendingSectors));
Logger::logThis()->info("SMART: Uncorrectable Sectors: " + to_string(ctx.uncorrectableSectors));
if (exitStatus != 0)
{
Logger::logThis()->info("SMART: Note - exit status " + to_string(exitStatus) + " indicates warnings/errors in SMART log");
}
break; // Success - we got data!
}
else
{
temperature = stol(sLine);
Logger::logThis()->warning("SMART: No valid data parsed (exit status: " + to_string(exitStatus) + ")");
}
return true;
}
else
// Check if we got ANY data
if (ctx.modelName.empty() && ctx.serial.empty())
{
return false;
Logger::logThis()->warning("SMART: No SMART data available for this drive - may not support SMART or need root privileges");
// Try basic device info without SMART (use hdparm or similar as fallback)
// For now, just log that SMART is not available
ctx.modelName = "SMART not available";
ctx.serial = "N/A";
}
// Write parsed data to drive
drive->setDriveSMARTData(
ctx.modelFamily,
ctx.modelName,
ctx.serial,
ctx.capacity,
ctx.errorCount,
ctx.powerOnHours,
ctx.powerCycles,
ctx.temperature,
ctx.reallocatedSectors,
ctx.pendingSectors,
ctx.uncorrectableSectors);
}
src/tui.cpp
+92 -27
View File
@@ -6,6 +6,7 @@
*/
#include "../include/reHDD.h"
using namespace std;
static std::mutex mxUIrefresh;
@@ -63,6 +64,11 @@ void TUI::initTUI()
void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
{
if (isendwin())
{
return;
}
mxUIrefresh.lock();
uint16_t u16StdscrX, u16StdscrY;
getmaxyx(stdscr, u16StdscrY, u16StdscrX);
@@ -93,6 +99,9 @@ void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
string sSpeed = " ";
string sTime = " ";
string sTemp = it->sTemperatureToText();
string sConnection = (it->connectionType == Drive::ConnectionType::USB ? "USB" : it->connectionType == Drive::ConnectionType::SATA ? "SATA"
: it->connectionType == Drive::ConnectionType::NVME ? "NVME"
: "");
bool bSelectedEntry = false;
@@ -101,10 +110,10 @@ void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
bSelectedEntry = true; // mark this drive in entries list
displaySelectedDrive(*it, u16StdscrX, u16StdscrY);
if ((it->getPowerOnHours() >= WORSE_HOURS) || (it->getPowerCycles() >= WORSE_POWERUP) || (it->getErrorCount() > 0) || (it->getTemperature() >= WORSE_TEMPERATURE))
if ((it->getPowerOnHours() >= WORSE_HOURS) || (it->getPowerCycles() >= WORSE_POWERUP) || (it->getErrorCount() > 0) || (it->getTemperature() >= WORSE_TEMPERATURE) || (it->getReallocatedSectors() > 0) || (it->getPendingSectors() > 0) || (it->getUncorrectableSectors() > 0))
{
// smart values are bad --> show warning
smartWarning = createSmartWarning(50, 10, ((u16StdscrX) - (int)(u16StdscrX / 2) + 35), (int)(u16StdscrY / 2) - 5, it->getPath(), it->getPowerOnHours(), it->getPowerCycles(), it->getErrorCount(), it->getTemperature());
smartWarning = createSmartWarning(50, 14, ((u16StdscrX) - (int)(u16StdscrX / 2) + 35), (int)(u16StdscrY / 2) - 7, it->getPath(), it->getPowerOnHours(), it->getPowerCycles(), it->getErrorCount(), it->getTemperature(), it->getReallocatedSectors(), it->getPendingSectors(), it->getUncorrectableSectors());
wrefresh(smartWarning);
}
}
@@ -113,30 +122,40 @@ void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
switch (it->state)
{
case Drive::SHRED_ACTIVE:
case Drive::TaskState::SHRED_ACTIVE:
{
stream << fixed << setprecision(3) << (it->getTaskPercentage());
sState = "Shredding: " + stream.str() + "%";
it->calculateTaskDuration();
sTime = this->formatTimeDuration(it->getTaskDuration());
sSpeed = this->formatSpeed(it->sShredSpeed.u32ShredTimeDelta, it->sShredSpeed.ulWrittenBytes);
auto shredSpeed = it->sShredSpeed.load();
sSpeed = this->formatSpeed(shredSpeed.u32ShredTimeDelta, shredSpeed.ulWrittenBytes);
break;
case Drive::CHECK_ACTIVE:
}
case Drive::TaskState::CHECK_ACTIVE:
{
stream << fixed << setprecision(3) << (it->getTaskPercentage());
sState = "Checking: " + stream.str() + "%";
it->calculateTaskDuration();
sTime = this->formatTimeDuration(it->getTaskDuration());
sSpeed = this->formatSpeed(it->sShredSpeed.u32ShredTimeDelta, it->sShredSpeed.ulWrittenBytes);
auto shredSpeed = it->sShredSpeed.load();
sSpeed = this->formatSpeed(shredSpeed.u32ShredTimeDelta, shredSpeed.ulWrittenBytes);
break;
case Drive::DELETE_ACTIVE:
}
case Drive::TaskState::DELETE_ACTIVE:
{
sState = "Deleting ...";
it->calculateTaskDuration();
sTime = this->formatTimeDuration(it->getTaskDuration());
break;
case Drive::NONE:
case Drive::SHRED_SELECTED:
case Drive::DELETE_SELECTED:
}
case Drive::TaskState::NONE:
case Drive::TaskState::SHRED_SELECTED:
case Drive::TaskState::DELETE_SELECTED:
case Drive::TaskState::CHECK_SUCCESSFUL:
{
if (it->bWasDeleted)
{
sState = "DELETED"; // mark drive as deleted previously
@@ -163,9 +182,9 @@ void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
wrefresh(dialog);
}
#endif
break;
case Drive::FROZEN:
}
case Drive::TaskState::FROZEN:
stream << fixed << setprecision(3) << (it->getTaskPercentage());
#ifdef FROZEN_ALERT
if (bSelectedEntry)
@@ -182,7 +201,7 @@ void TUI::updateTUI(list<Drive> *plistDrives, uint8_t u8SelectedEntry)
uint16_t u16StartOffsetY = (2 * (u8Index));
WINDOW *tmp = createEntryWindow((int)(u16StdscrX * (float)(3.0 / 7.0) - 2), 2, 3, u16StartOffsetY + 2, (distance(plistDrives->begin(), it) + 1), sModelFamily, sSerial, sCapacity, sState, sTime, sSpeed, sTemp, bSelectedEntry);
WINDOW *tmp = createEntryWindow((int)(u16StdscrX * (float)(3.0 / 7.0) - 2), 2, 3, u16StartOffsetY + 2, (distance(plistDrives->begin(), it) + 1), sModelFamily, sSerial, sCapacity, sState, sTime, sSpeed, sTemp, sConnection, bSelectedEntry);
wrefresh(tmp);
u8Index++;
} // end loop though drives
@@ -237,6 +256,15 @@ enum TUI::UserInput TUI::readUserInput()
case 'S':
return TUI::UserInput::ShredAll;
break;
case 'T':
return TUI::UserInput::Terminate;
break;
case 'p':
return TUI::UserInput::Print;
break;
case 'P':
return TUI::UserInput::PrintAll;
break;
default:
return TUI::UserInput::Undefined;
break;
@@ -244,6 +272,11 @@ enum TUI::UserInput TUI::readUserInput()
return TUI::UserInput::Undefined;
}
void TUI::terminateTUI()
{
endwin();
}
void TUI::centerTitle(WINDOW *pwin, const char *title)
{
int x, maxX, stringSize;
@@ -273,7 +306,7 @@ WINDOW *TUI::createOverViewWindow(int iXSize, int iYSize)
return newWindow;
}
WINDOW *TUI::createDetailViewWindow(int iXSize, int iYSize, int iXStart, Drive drive)
WINDOW *TUI::createDetailViewWindow(int iXSize, int iYSize, int iXStart, Drive &drive)
{
WINDOW *newWindow;
newWindow = newwin(iYSize, iXSize, 1, iXStart);
@@ -321,7 +354,7 @@ WINDOW *TUI::overwriteDetailViewWindow(int iXSize, int iYSize, int iXStart)
string sLine01 = "reHDD - hard drive refurbishing tool";
string sLine02 = "Version: " + string(REHDD_VERSION);
string sLine03 = "Available under GPL 3.0";
string sLine03 = "Free software under the GNU GPL 3.0";
string sLine04 = "https://git.mosad.xyz/localhorst/reHDD";
string sLine05 = "Delete: Wipe format table - this is NOT secure";
string sLine06 = "Shred: Overwrite drive " + to_string(SHRED_ITERATIONS) + " iterations - this is secure";
@@ -342,7 +375,7 @@ WINDOW *TUI::overwriteDetailViewWindow(int iXSize, int iYSize, int iXStart)
return newWindow;
}
WINDOW *TUI::createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart, int iListIndex, string sModelFamily, string sSerial, string sCapacity, string sState, string sTime, string sSpeed, string sTemp, bool bSelected)
WINDOW *TUI::createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart, int iListIndex, string sModelFamily, string sSerial, string sCapacity, string sState, string sTime, string sSpeed, string sTemp, string sConnection, bool bSelected)
{
WINDOW *newWindow;
newWindow = newwin(iYSize, iXSize, iYStart, iXStart);
@@ -387,6 +420,7 @@ WINDOW *TUI::createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart,
37-43: Capacity
44: space
47-49: Temp
57-60: Connection Type
line:02
0-2: space
@@ -403,6 +437,7 @@ WINDOW *TUI::createEntryWindow(int iXSize, int iYSize, int iXStart, int iYStart,
mvwaddstr(newWindow, 0, 3, sModelFamily.c_str());
mvwaddstr(newWindow, 0, 37, sCapacity.c_str());
mvwaddstr(newWindow, 0, 47, sTemp.c_str());
mvwaddstr(newWindow, 0, 57, sConnection.c_str());
vTruncateText(&sSerial, 28);
mvwaddstr(newWindow, 1, 3, sSerial.c_str());
@@ -437,7 +472,7 @@ WINDOW *TUI::createSystemStats(int iXSize, int iYSize, int iXStart, int iYStart)
sLine03.append(__DATE__);
sLine03.append(" ");
sLine03.append(__TIME__);
string sLine04 = "Available under GPL 3.0";
string sLine04 = "Free software under the GNU GPL 3.0";
string sLine05 = "https://git.mosad.xyz/localhorst/reHDD";
uint16_t u16Line = 2;
@@ -464,7 +499,7 @@ WINDOW *TUI::createMenuView(int iXSize, int iYSize, int iXStart, int iYStart, st
centerTitle(newWindow, "Controls");
uint16_t u16Line = 4;
uint16_t u16Line = 2;
if (menustate.bAbort)
{
@@ -482,8 +517,16 @@ WINDOW *TUI::createMenuView(int iXSize, int iYSize, int iXStart, int iYStart, st
{
string sLineTmp = "Press d for Delete";
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLineTmp.size() / 2), sLineTmp.c_str());
u16Line++;
}
string sLineTmp = "Press p for Print (P for all drives)";
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLineTmp.size() / 2), sLineTmp.c_str());
u16Line++;
sLineTmp = "Press T for terminating reHDD";
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLineTmp.size() / 2), sLineTmp.c_str());
return newWindow;
}
@@ -610,7 +653,7 @@ void TUI::vTruncateText(string *psText, uint16_t u16MaxLenght)
}
}
void TUI::displaySelectedDrive(Drive drive, int stdscrX, int stdscrY)
void TUI::displaySelectedDrive(Drive &drive, int stdscrX, int stdscrY)
{
struct MenuState menustate;
static bool dialogIsActive;
@@ -623,27 +666,27 @@ void TUI::displaySelectedDrive(Drive drive, int stdscrX, int stdscrY)
// set menustate based on drive state
switch (drive.state)
{
case Drive::NONE: // no task running or selected for this drive
case Drive::TaskState::NONE: // no task running or selected for this drive
menustate.bShred = true;
menustate.bDelete = true;
break;
case Drive::DELETE_ACTIVE: // delete task running for this drive
case Drive::TaskState::DELETE_ACTIVE: // delete task running for this drive
menustate.bAbort = true;
break;
case Drive::SHRED_ACTIVE: // shred task running for this drive
case Drive::TaskState::SHRED_ACTIVE: // shred task running for this drive
menustate.bAbort = true;
break;
case Drive::CHECK_ACTIVE: // check task running for this drive
case Drive::TaskState::CHECK_ACTIVE: // check task running for this drive
menustate.bAbort = true;
break;
case Drive::DELETE_SELECTED: // delete task selected for this drive
case Drive::TaskState::DELETE_SELECTED: // delete task selected for this drive
menustate.bConfirmDelete = true;
break;
case Drive::SHRED_SELECTED: // shred task selected for this drive
case Drive::TaskState::SHRED_SELECTED: // shred task selected for this drive
menustate.bConfirmShred = true;
break;
default:
@@ -678,7 +721,7 @@ void TUI::displaySelectedDrive(Drive drive, int stdscrX, int stdscrY)
}
}
WINDOW *TUI::createSmartWarning(int iXSize, int iYSize, int iXStart, int iYStart, string sPath, uint32_t u32PowerOnHours, uint32_t u32PowerCycles, uint32_t u32ErrorCount, uint32_t u32Temperature)
WINDOW *TUI::createSmartWarning(int iXSize, int iYSize, int iXStart, int iYStart, string sPath, uint32_t u32PowerOnHours, uint32_t u32PowerCycles, uint32_t u32ErrorCount, uint32_t u32Temperature, uint32_t u32ReallocatedSectors, uint32_t u32PendingSectors, uint32_t u32UncorrectableSectors)
{
WINDOW *newWindow;
newWindow = newwin(iYSize, iXSize, iYStart, iXStart);
@@ -720,6 +763,28 @@ WINDOW *TUI::createSmartWarning(int iXSize, int iYSize, int iXStart, int iYStart
{
string sLineTmp = "Drive too hot: " + to_string(u32Temperature) + " C";
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLine01.size() / 2), sLineTmp.c_str());
u16Line++;
}
if (u32ReallocatedSectors > 0)
{
string sLineTmp = "CRITICAL: Reallocated sectors detected: " + to_string(u32ReallocatedSectors);
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLine01.size() / 2), sLineTmp.c_str());
u16Line++;
}
if (u32PendingSectors > 0)
{
string sLineTmp = "CRITICAL: Pending sectors detected: " + to_string(u32PendingSectors);
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLine01.size() / 2), sLineTmp.c_str());
u16Line++;
}
if (u32UncorrectableSectors > 0)
{
string sLineTmp = "CRITICAL: Uncorrectable sectors: " + to_string(u32UncorrectableSectors);
mvwaddstr(newWindow, u16Line++, (iXSize / 2) - (sLine01.size() / 2), sLineTmp.c_str());
}
return newWindow;
}