module/open-license-manager.git

			@@ -1,136 +1,243 @@
			#include <paths.h>
			#include <stdio.h>
			#include <stdlib.h>
			#include <cstring>
			#include <string>
			#include <system_error>
			#include <unistd.h>
			#include <sstream>
			#include <sys/ioctl.h>
			#include <sys/stat.h>
			#include "../os.hpp"
			#include "../../base/public-key.h"
			#include <openssl/evp.h>
			#include <openssl/bio.h>
			#include <openssl/pem.h>
			#include <stdio.h>
			#include "../os.h"
			#include "../../base/logger.h"

			namespace license {
			#include <mntent.h>
			#include <dirent.h>
			#include <sys/utsname.h>
			#ifdef _DEBUG
			#include <valgrind/memcheck.h>
			#endif

			using namespace std;
			#ifdef USE_DBUS
			#include <dbus-1.0/dbus/dbus.h>
			#endif

			vector<AdapterInfo> OsFunctions::getAdapterInfos() {
			return vector<AdapterInfo>();
			}
			vector<DiskInfo> OsFunctions::getDiskInfos() {
			struct stat filename_stat, mount_stat;
			static char discard[1024];
			char device[64], name[64], type[64];
			FILE *mounts = fopen(_PATH_MOUNTED, "r");
			/**
			*Usually uuid are hex number separated by "-". this method read up to 8 hex
			*numbers skipping - characters.
			*@param uuid uuid as read in /dev/disk/by-uuid
			*@param buffer_out: unsigned char buffer[8] output buffer for result
			*/
			static void parseUUID(const char uuid, unsigned char buffer_out, unsigned int out_size) {
			unsigned int i, j;
			char *hexuuid;
			unsigned char cur_character;
			// remove characters not in hex set
			size_t len = strlen(uuid);
			hexuuid = (char )malloc(sizeof(char) len);
			memset(buffer_out, 0, out_size);
			memset(hexuuid, 0, sizeof(char) * len);

			while (fscanf(mounts, "%64s %64s %64s %1024[^\n]", device, name, type,
			discard) != EOF) {
			if (stat(device, &mount_stat) != 0)
			for (i = 0, j = 0; i < len; i++) {
			if (isxdigit(uuid[i])) {
			hexuuid[j] = uuid[i];
			j++;
			} else {
			// skip
			continue;
			if (filename_stat.st_dev == mount_stat.st_rdev)
			fprintf(stderr, "device: %s; name: %s; type: %s\n", device, name,
			type);
			}
			}
			if (j % 2 == 1) {
			hexuuid[j++] = '0';
			}
			hexuuid[j] = '\0';
			for (i = 0; i < j / 2; i++) {
			sscanf(&hexuuid[i * 2], "%2hhx", &cur_character);
			buffer_out[i % out_size] = buffer_out[i % out_size] ^ cur_character;
			}

			return vector<DiskInfo>();
			free(hexuuid);
			}

			string OsFunctions::getModuleName() {
			char path[2048] = { 0 };
			string strPath;
			string result;
			pid_t pid = getpid();
			const string pidstr = to_string(((long) pid));
			strPath = string("/proc/") + pidstr + "/exe";
			const char * proc_path = strPath.c_str();
			int ch = readlink(proc_path, path, 2048);
			if (ch != -1) {
			path[ch] = '\0';
			result = string(path);
			#define MAX_UNITS 20
			FUNCTION_RETURN getDiskInfos(DiskInfo diskInfos, size_t disk_info_size) {
			struct stat mount_stat, sym_stat;
			/*static char discard[1024];
			char device[64], name[64], type[64];
			*/
			char cur_dir[MAX_PATH];
			struct mntent *ent;

			int maxDrives, currentDrive, i, drive_found;
			__ino64_t *statDrives = NULL;
			DiskInfo *tmpDrives = NULL;
			FILE *aFile = NULL;
			DIR disk_by_uuid_dir = NULL, disk_by_label = NULL;
			struct dirent *dir = NULL;
			FUNCTION_RETURN result;

			if (diskInfos != NULL) {
			maxDrives = *disk_info_size;
			tmpDrives = diskInfos;
			} else {
			throw runtime_error(
			string("Can't find: ") + strPath + " proc filesystem mounted?");
			maxDrives = MAX_UNITS;
			tmpDrives = (DiskInfo )malloc(sizeof(DiskInfo) maxDrives);
			}
			memset(tmpDrives, 0, sizeof(DiskInfo) * maxDrives);
			statDrives = (__ino64_t )malloc(maxDrives sizeof(__ino64_t));
			memset(statDrives, 0, sizeof(__ino64_t) * maxDrives);

			aFile = setmntent("/proc/mounts", "r");
			if (aFile == NULL) {
			/proc not mounted/
			free(tmpDrives);
			free(statDrives);
			return FUNC_RET_ERROR;
			}

			currentDrive = 0;
			while (NULL != (ent = getmntent(aFile))) {
			if ((strncmp(ent->mnt_type, "ext", 3) == 0 \|\| strncmp(ent->mnt_type, "xfs", 3) == 0 \|\|
			strncmp(ent->mnt_type, "vfat", 4) == 0 \|\| strncmp(ent->mnt_type, "ntfs", 4) == 0) &&
			ent->mnt_fsname != NULL && strncmp(ent->mnt_fsname, "/dev/", 5) == 0) {
			if (stat(ent->mnt_fsname, &mount_stat) == 0) {
			drive_found = -1;
			for (i = 0; i < currentDrive; i++) {
			if (statDrives[i] == mount_stat.st_ino) {
			drive_found = i;
			}
			}
			if (drive_found == -1) {
			LOG_DEBUG("mntent: %s %s %d\n", ent->mnt_fsname, ent->mnt_dir,
			(unsigned long int)mount_stat.st_ino);
			strncpy(tmpDrives[currentDrive].device, ent->mnt_fsname, 255 - 1);
			statDrives[currentDrive] = mount_stat.st_ino;
			drive_found = currentDrive;
			currentDrive++;
			}
			if (strcmp(ent->mnt_dir, "/") == 0) {
			strcpy(tmpDrives[drive_found].label, "root");
			LOG_DEBUG("drive %s set to preferred\n", ent->mnt_fsname);
			tmpDrives[drive_found].preferred = 1;
			} else {
			tmpDrives[drive_found].preferred = 0;
			}
			}
			}
			}
			endmntent(aFile);

			if (diskInfos == NULL) {
			*disk_info_size = currentDrive;
			free(tmpDrives);
			result = (currentDrive > 0) ? FUNC_RET_OK : FUNC_RET_NOT_AVAIL;
			} else if (*disk_info_size >= currentDrive) {
			disk_by_uuid_dir = opendir("/dev/disk/by-uuid");
			if (disk_by_uuid_dir == NULL) {
			LOG_WARN("Open /dev/disk/by-uuid fail");
			free(statDrives);
			return FUNC_RET_ERROR;
			}
			result = FUNC_RET_OK;
			*disk_info_size = currentDrive;
			while ((dir = readdir(disk_by_uuid_dir)) != NULL) {
			strcpy(cur_dir, "/dev/disk/by-uuid/");
			strncat(cur_dir, dir->d_name, 200);
			if (stat(cur_dir, &sym_stat) == 0) {
			for (i = 0; i < currentDrive; i++) {
			if (sym_stat.st_ino == statDrives[i]) {
			parseUUID(dir->d_name, tmpDrives[i].disk_sn, sizeof(tmpDrives[i].disk_sn));
			#ifdef _DEBUG
			VALGRIND_CHECK_VALUE_IS_DEFINED(tmpDrives[i].device);

			LOG_DEBUG("uuid %d %s %02x%02x%02x%02x\n", i, tmpDrives[i].device, tmpDrives[i].disk_sn[0],
			tmpDrives[i].disk_sn[1], tmpDrives[i].disk_sn[2], tmpDrives[i].disk_sn[3]);
			#endif
			}
			}
			}
			}
			closedir(disk_by_uuid_dir);

			disk_by_label = opendir("/dev/disk/by-label");
			if (disk_by_label != NULL) {
			while ((dir = readdir(disk_by_label)) != NULL) {
			strcpy(cur_dir, "/dev/disk/by-label/");
			strcat(cur_dir, dir->d_name);
			if (stat(cur_dir, &sym_stat) == 0) {
			for (i = 0; i < currentDrive; i++) {
			if (sym_stat.st_ino == statDrives[i]) {
			strncpy(tmpDrives[i].label, dir->d_name, 255 - 1);
			printf("label %d %s %s\n", i, tmpDrives[i].label, tmpDrives[i].device);
			}
			}
			}
			}
			closedir(disk_by_label);
			}
			} else {
			result = FUNC_RET_BUFFER_TOO_SMALL;
			}
			free(statDrives);
			return result;
			}

			string OsFunctions::getUserHomePath() {
			return "";
			static void _getCpuid(unsigned int *p, unsigned int ax) {
			__asm __volatile(
			"movl %%ebx, %%esi\n\t"
			"cpuid\n\t"
			"xchgl %%ebx, %%esi"
			: "=a"(p[0]), "=S"(p[1]), "=c"(p[2]), "=d"(p[3])
			: "0"(ax));
			}

			bool OsFunctions::verifySignature(const char* stringToVerify,
			const char* signature) {
			EVP_MD_CTX *mdctx = NULL;

			char *pubKey = PUBLIC_KEY
			;

			BIO* bio = BIO_new_mem_buf((void*) (pubKey), strlen(pubKey));
			RSA *rsa = PEM_read_bio_RSAPublicKey(bio, NULL,NULL,NULL);
			BIO_free(bio);
			if (rsa == NULL) {
			throw new logic_error("Error reading public key");
			FUNCTION_RETURN getCpuId(unsigned char identifier[6]) {
			unsigned int i;
			unsigned int cpuinfo[4] = {0, 0, 0, 0};
			_getCpuid(cpuinfo, 0);
			for (i = 0; i < 3; i++) {
			identifier[i * 2] = cpuinfo[i] & 0xFF;
			identifier[i * 2 + 1] = (cpuinfo[i] & 0xFF00) >> 8;
			}
			EVP_PKEY *pkey = EVP_PKEY_new();
			return FUNC_RET_OK;
			}

			EVP_PKEY_assign_RSA(pkey, rsa);

			/BIO bo = BIO_new(BIO_s_mem());
			BIO_write(bo, pubKey, strlen(pubKey));
			RSA *key = 0;
			PEM_read_bio_RSAPublicKey(bo, &key, 0, 0);
			BIO_free(bo);*/

			//RSA* rsa = EVP_PKEY_get1_RSA( key );
			//RSA * pubKey = d2i_RSA_PUBKEY(NULL, <der encoded byte stream pointer>, <num bytes>);
			/* Create the Message Digest Context */
			if (!(mdctx = EVP_MD_CTX_create())) {
			throw new logic_error("Error creating context");
			FUNCTION_RETURN getMachineName(unsigned char identifier[6]) {
			static struct utsname u;

			if (uname(&u) < 0) {
			return FUNC_RET_ERROR;
			}
			if (1 != EVP_DigestVerifyInit(mdctx, NULL, EVP_sha256(), NULL, pkey)) {
			throw new logic_error("Error initializing digest");
			}
			memcpy(identifier, u.nodename, 6);
			return FUNC_RET_OK;
			}

			if (1
			!= EVP_DigestVerifyUpdate(mdctx, stringToVerify,
			strlen(stringToVerify))) {
			throw new logic_error("Error initializing digest");
			FUNCTION_RETURN getOsSpecificIdentifier(unsigned char identifier[6]) {
			#if USE_DBUS
			char *dbus_id = dbus_get_local_machine_id();
			if (dbus_id == NULL) {
			return FUNC_RET_ERROR;
			}
			if (1
			== EVP_DigestVerifyFinal(mdctx, (unsigned char *) signature,
			(unsigned long int) strlen(signature))) {
			return true;
			memcpy(identifier, dbus_id, 6);
			dbus_free(dbus_id);
			return FUNC_RET_OK;
			#else
			return FUNC_RET_NOT_AVAIL;
			#endif
			}

			FUNCTION_RETURN getModuleName(char buffer[MAX_PATH]) {
			FUNCTION_RETURN result;
			char path[MAX_PATH] = {0};
			char proc_path[MAX_PATH], pidStr[64];
			pid_t pid = getpid();
			sprintf(pidStr, "%d", pid);
			strcpy(proc_path, "/proc/");
			strcat(proc_path, pidStr);
			strcat(proc_path, "/exe");

			int ch = readlink(proc_path, path, MAX_PATH - 1);
			if (ch != -1) {
			path[ch] = '\0';
			strncpy(buffer, path, ch);
			result = FUNC_RET_OK;
			} else {

			return false;
			result = FUNC_RET_ERROR;
			}
			}

			VIRTUALIZATION OsFunctions::getVirtualization() {
			//http://www.ibiblio.org/gferg/ldp/GCC-Inline-Assembly-HOWTO.html
			//
			bool rc = true;
			/*__asm__ (
			"push %edx\n"
			"push %ecx\n"
			"push %ebx\n"
			"mov %eax, 'VMXh'\n"
			"mov %ebx, 0\n" // any value but not the MAGIC VALUE
			"mov %ecx, 10\n"// get VMWare version
			"mov %edx, 'VX'\n"// port number
			"in %eax, dx\n"// read port on return EAX returns the VERSION
			"cmp %ebx, 'VMXh'\n"// is it a reply from VMWare?
			"setz [rc] \n"// set return value
			"pop %ebx \n"
			"pop %ecx \n"
			"pop %edx \n"
			);*/

			return NONE;
			}

			return result;
			}