CFG_RW *NewCfgRwEx2W(FOLDER **root, wchar_t *cfg_name, bool dont_backup, wchar_t *template_name)
{
CFG_RW *rw;
FOLDER *f;
bool loaded_from_template = false;
// Validate arguments
if (cfg_name == NULL || root == NULL)
{
return NULL;
}
f = CfgReadW(cfg_name);
if (f == NULL)
{
// Load from template
if (UniIsEmptyStr(template_name) == false)
{
f = CfgReadW(template_name);
if (f != NULL)
{
loaded_from_template = true;
goto LABEL_CONTIUNE;
}
}
rw = ZeroMalloc(sizeof(CFG_RW));
rw->lock = NewLock();
rw->FileNameW = CopyUniStr(cfg_name);
rw->FileName = CopyUniToStr(cfg_name);
rw->Io = FileCreateW(cfg_name);
*root = NULL;
rw->DontBackup = dont_backup;
return rw;
}
LABEL_CONTIUNE:
rw = ZeroMalloc(sizeof(CFG_RW));
rw->FileNameW = CopyUniStr(cfg_name);
rw->FileName = CopyUniToStr(cfg_name);
if (loaded_from_template == false)
{
rw->Io = FileOpenW(cfg_name, false);
}
else
{
rw->Io = FileCreateW(cfg_name);
}
rw->lock = NewLock();
*root = f;
rw->DontBackup = dont_backup;
return rw;
}
// Convert the token information to the SEC_INFO
SEC_INFO *TokenInfoToSecInfo(void *p_t)
{
SEC_INFO *s;
char buf[MAX_SIZE];
CK_TOKEN_INFO *t = (CK_TOKEN_INFO *)p_t;
// Validate arguments
if (t == NULL)
{
return NULL;
}
s = ZeroMalloc(sizeof(SEC_INFO));
// Label
Zero(buf, sizeof(buf));
Copy(buf, t->label, sizeof(t->label));
s->Label = ZeroMalloc(CalcUtf8ToUni(buf, 0));
Utf8ToUni(s->Label, 0, buf, 0);
// ManufacturerId
Zero(buf, sizeof(buf));
Copy(buf, t->manufacturerID, sizeof(t->manufacturerID));
s->ManufacturerId = ZeroMalloc(CalcUtf8ToUni(buf, 0));
Utf8ToUni(s->ManufacturerId, 0, buf, 0);
// Model
Zero(buf, sizeof(buf));
Copy(buf, t->model, sizeof(t->model));
s->Model = ZeroMalloc(CalcUtf8ToUni(buf, 0));
Utf8ToUni(s->Model, 0, buf, 0);
// SerialNumber
Zero(buf, sizeof(buf));
Copy(buf, t->serialNumber, sizeof(t->serialNumber));
s->SerialNumber = ZeroMalloc(CalcUtf8ToUni(buf, 0));
Utf8ToUni(s->SerialNumber, 0, buf, 0);
// Numeric value
s->MaxSession = t->ulMaxSessionCount;
s->MaxRWSession = t->ulMaxRwSessionCount;
s->MinPinLen = t->ulMinPinLen;
s->MaxPinLen = t->ulMaxPinLen;
s->TotalPublicMemory = t->ulTotalPublicMemory;
s->FreePublicMemory = t->ulFreePublicMemory;
s->TotalPrivateMemory = t->ulTotalPrivateMemory;
s->FreePrivateMemory = t->ulFreePrivateMemory;
// Hardware version
Format(buf, sizeof(buf), "%u.%02u", t->hardwareVersion.major, t->hardwareVersion.minor);
s->HardwareVersion = CopyStr(buf);
// Firmware version
Format(buf, sizeof(buf), "%u.%02u", t->firmwareVersion.major, t->firmwareVersion.minor);
s->FirmwareVersion = CopyStr(buf);
return s;
}
// Remove duplications from the token list
TOKEN_LIST *UniqueToken(TOKEN_LIST *t)
{
UINT i, num, j, n;
TOKEN_LIST *ret;
// Validate arguments
if (t == NULL)
{
return NULL;
}
num = 0;
for (i = 0;i < t->NumTokens;i++)
{
bool exists = false;
for (j = 0;j < i;j++)
{
if (StrCmpi(t->Token[j], t->Token[i]) == 0)
{
exists = true;
break;
}
}
if (exists == false)
{
num++;
}
}
ret = ZeroMalloc(sizeof(TOKEN_LIST));
ret->Token = ZeroMalloc(sizeof(char *) * num);
ret->NumTokens = num;
n = 0;
for (i = 0;i < t->NumTokens;i++)
{
bool exists = false;
for (j = 0;j < i;j++)
{
if (StrCmpi(t->Token[j], t->Token[i]) == 0)
{
exists = true;
break;
}
}
if (exists == false)
{
ret->Token[n++] = CopyStr(t->Token[i]);
}
}
return ret;
}
// Open a secure device
SECURE *OpenSec(UINT id)
{
SECURE_DEVICE *dev = GetSecureDevice(id);
SECURE *sec;
UINT err;
if (dev == NULL)
{
return NULL;
}
sec = ZeroMalloc(sizeof(SECURE));
sec->lock = NewLock();
sec->Error = SEC_ERROR_NOERROR;
sec->Dev = dev;
// Get whether it's a ePass or not
if (SearchStrEx(dev->DeviceName, "epass", 0, false) != INFINITE)
{
sec->IsEPass1000 = true;
}
// Load the module
if (LoadSecModule(sec) == false)
{
CloseSec(sec);
return NULL;
}
// Get the slot list
sec->NumSlot = 0;
if ((err = sec->Api->C_GetSlotList(true, NULL, &sec->NumSlot)) != CKR_OK || sec->NumSlot == 0)
{
// Failure
FreeSecModule(sec);
CloseSec(sec);
return NULL;
}
sec->SlotIdList = (UINT *)ZeroMalloc(sizeof(UINT *) * sec->NumSlot);
if (sec->Api->C_GetSlotList(TRUE, sec->SlotIdList, &sec->NumSlot) != CKR_OK)
{
// Failure
Free(sec->SlotIdList);
sec->SlotIdList = NULL;
FreeSecModule(sec);
CloseSec(sec);
return NULL;
}
return sec;
}
// Parse the token
TOKEN_LIST *ParseToken(char *src, char *separator)
{
TOKEN_LIST *ret;
char *tmp;
char *str1, *str2;
UINT len;
UINT num;
if (src == NULL)
{
ret = ZeroMalloc(sizeof(TOKEN_LIST));
ret->Token = ZeroMalloc(0);
return ret;
}
if (separator == NULL)
{
separator = " ,\t\r\n";
}
len = StrLen(src);
str1 = Malloc(len + 1);
str2 = Malloc(len + 1);
StrCpy(str1, 0, src);
StrCpy(str2, 0, src);
Lock(token_lock);
{
tmp = strtok(str1, separator);
num = 0;
while (tmp != NULL)
{
num++;
tmp = strtok(NULL, separator);
}
ret = Malloc(sizeof(TOKEN_LIST));
ret->NumTokens = num;
ret->Token = (char **)Malloc(sizeof(char *) * num);
num = 0;
tmp = strtok(str2, separator);
while (tmp != NULL)
{
ret->Token[num] = (char *)Malloc(StrLen(tmp) + 1);
StrCpy(ret->Token[num], 0, tmp);
num++;
tmp = strtok(NULL, separator);
}
}
Unlock(token_lock);
Free(str1);
Free(str2);
return ret;
}
// Initialize the packet adapter
bool NullPaInit(SESSION *s)
{
NULL_LAN *n;
static UINT id_seed = 0;
// Validate arguments
if (s == NULL)
{
return false;
}
id_seed++;
n = ZeroMalloc(sizeof(NULL_LAN));
n->Id = id_seed;
s->PacketAdapter->Param = (void *)n;
n->Cancel = NewCancel();
n->PacketQueue = NewQueue();
n->Event = NewEvent();
NullGenerateMacAddress(n->MacAddr, n->Id, 0);
n->PacketGeneratorThread = NewThread(NullPacketGenerateThread, n);
return true;
}
// Register in the ARP table
void L3InsertArpTable(L3IF *f, UINT ip, UCHAR *mac)
{
L3ARPENTRY *a, t;
// Validate arguments
if (f == NULL || ip == 0 || ip == 0xffffffff || mac == NULL)
{
return;
}
Zero(&t, sizeof(t));
t.IpAddress = ip;
a = Search(f->ArpTable, &t);
if (a == NULL)
{
// Since this is not registered, register this
a = ZeroMalloc(sizeof(L3ARPENTRY));
a->IpAddress = ip;
Copy(a->MacAddress, mac, 6);
Insert(f->ArpTable, a);
}
// Extend the expiration date
a->Expire = Tick64() + ARP_ENTRY_EXPIRES;
// Send waiting IP packets
L3SendWaitingIp(f, mac, ip, a);
}
// IPv6 拡張オプションヘッダ (可変長) の追加
void BuildAndAddIPv6PacketOptionHeader(BUF *b, IPV6_OPTION_HEADER *opt, UCHAR next_header, UINT size)
{
IPV6_OPTION_HEADER *h;
UINT total_size;
// 引数チェック
if (b == NULL || opt == NULL)
{
return;
}
total_size = size;
if ((total_size % 8) != 0)
{
total_size = ((total_size / 8) + 1) * 8;
}
h = ZeroMalloc(total_size);
Copy(h, opt, size);
h->Size = (total_size / 8) - 1;
h->NextHeader = next_header;
WriteBuf(b, h, total_size);
Free(h);
}
// Extract the license agreement from the EXE file
wchar_t *ViExtractEula(char *exe)
{
BUF *b;
UINT tmp_size;
char *tmp;
wchar_t *ret;
// Validate arguments
if (exe == NULL)
{
return false;
}
b = ViExtractResource(exe, RT_RCDATA, "LICENSE");
if (b == NULL)
{
return NULL;
}
tmp_size = b->Size + 1;
tmp = ZeroMalloc(tmp_size);
Copy(tmp, b->Buf, b->Size);
FreeBuf(b);
ret = CopyStrToUni(tmp);
Free(tmp);
return ret;
}
// Convert the binary data to a hexadecimal string
void BinToStr(char *str, UINT str_size, void *data, UINT data_size)
{
char *tmp;
UCHAR *buf = (UCHAR *)data;
UINT size;
UINT i;
// Validate arguments
if (str == NULL || data == NULL)
{
if (str != NULL)
{
str[0] = 0;
}
return;
}
// Calculation of size
size = data_size * 2 + 1;
// Memory allocation
tmp = ZeroMalloc(size);
// Conversion
for (i = 0;i < data_size;i++)
{
sprintf(&tmp[i * 2], "%02X", buf[i]);
}
// Copy
StrCpy(str, str_size, tmp);
// Memory release
Free(tmp);
}
// Set the connection settings
UINT NtSetClientConfig(NAT *n, RPC_CREATE_LINK *t)
{
Lock(n->lock);
{
if (n->ClientOption != NULL || n->ClientAuth != NULL)
{
Free(n->ClientOption);
CiFreeClientAuth(n->ClientAuth);
}
n->ClientOption = ZeroMalloc(sizeof(CLIENT_OPTION));
Copy(n->ClientOption, t->ClientOption, sizeof(CLIENT_OPTION));
n->ClientAuth = CopyClientAuth(t->ClientAuth);
}
Unlock(n->lock);
NiWriteConfig(n);
if (n->Online)
{
NtOffline(n, NULL);
NtOnline(n, NULL);
}
return ERR_NO_ERROR;
}
// バイナリデータを 16 進文字列に変換する
void BinToStr(char *str, UINT str_size, void *data, UINT data_size)
{
char *tmp;
UCHAR *buf = (UCHAR *)data;
UINT size;
UINT i;
// 引数チェック
if (str == NULL || data == NULL)
{
if (str != NULL)
{
str[0] = 0;
}
return;
}
// サイズの計算
size = data_size * 2 + 1;
// メモリ確保
tmp = ZeroMalloc(size);
// 変換
for (i = 0;i < data_size;i++)
{
sprintf(&tmp[i * 2], "%02X", buf[i]);
}
// コピー
StrCpy(str, str_size, tmp);
// メモリ解放
Free(tmp);
}
// Create new VPN Azure client
AZURE_CLIENT *NewAzureClient(CEDAR *cedar, SERVER *server)
{
AZURE_CLIENT *ac;
// Validate arguments
if (cedar == NULL || server == NULL)
{
return NULL;
}
ac = ZeroMalloc(sizeof(AZURE_CLIENT));
ac->Cedar = cedar;
ac->Server = server;
ac->Lock = NewLock();
ac->IsEnabled = false;
ac->Event = NewEvent();
// Start main thread
ac->MainThread = NewThread(AcMainThread, ac);
return ac;
}
// バイナリデータを 16 進文字列に変換する (スペースも入れる)
void BinToStrEx(char *str, UINT str_size, void *data, UINT data_size)
{
char *tmp;
UCHAR *buf = (UCHAR *)data;
UINT size;
UINT i;
// 引数チェック
if (str == NULL || data == NULL)
{
return;
}
// サイズの計算
size = data_size * 3 + 1;
// メモリ確保
tmp = ZeroMalloc(size);
// 変換
for (i = 0;i < data_size;i++)
{
Format(&tmp[i * 3], 0, "%02X ", buf[i]);
}
Trim(tmp);
// コピー
StrCpy(str, str_size, tmp);
// メモリ解放
Free(tmp);
}
void BinToStrEx2(char *str, UINT str_size, void *data, UINT data_size, char padding_char)
{
char *tmp;
UCHAR *buf = (UCHAR *)data;
UINT size;
UINT i;
// 引数チェック
if (str == NULL || data == NULL)
{
return;
}
// サイズの計算
size = data_size * 3 + 1;
// メモリ確保
tmp = ZeroMalloc(size);
// 変換
for (i = 0;i < data_size;i++)
{
Format(&tmp[i * 3], 0, "%02X%c", buf[i], padding_char);
}
if (StrLen(tmp) >= 1)
{
if (tmp[StrLen(tmp) - 1] == padding_char)
{
tmp[StrLen(tmp) - 1] = 0;
}
}
// コピー
StrCpy(str, str_size, tmp);
// メモリ解放
Free(tmp);
}
// Create a SSTP server
SSTP_SERVER *NewSstpServer(CEDAR *cedar, IP *client_ip, UINT client_port, IP *server_ip,
UINT server_port, SOCK_EVENT *se,
char *client_host_name, char *crypt_name)
{
SSTP_SERVER *s = ZeroMalloc(sizeof(SSTP_SERVER));
s->LastRecvTick = Tick64();
StrCpy(s->ClientHostName, sizeof(s->ClientHostName), client_host_name);
StrCpy(s->ClientCipherName, sizeof(s->ClientCipherName), crypt_name);
s->Cedar = cedar;
AddRef(s->Cedar->ref);
NewTubePair(&s->TubeSend, &s->TubeRecv, 0);
SetTubeSockEvent(s->TubeSend, se);
s->Now = Tick64();
Copy(&s->ClientIp, client_ip, sizeof(IP));
s->ClientPort = client_port;
Copy(&s->ServerIp, server_ip, sizeof(IP));
s->ServerPort = server_port;
s->SockEvent = se;
AddRef(s->SockEvent->ref);
s->RecvQueue = NewQueueFast();
s->SendQueue = NewQueueFast();
s->Interrupt = NewInterruptManager();
return s;
}
// RPC_ENUM_NAT
void InRpcEnumNat(RPC_ENUM_NAT *t, PACK *p)
{
UINT i;
// Validate arguments
if (t == NULL || p == NULL)
{
return;
}
Zero(t, sizeof(RPC_ENUM_NAT));
t->NumItem = PackGetInt(p, "NumItem");
PackGetStr(p, "HubName", t->HubName, sizeof(t->HubName));
t->Items = ZeroMalloc(sizeof(RPC_ENUM_NAT_ITEM) * t->NumItem);
for (i = 0;i < t->NumItem;i++)
{
RPC_ENUM_NAT_ITEM *e = &t->Items[i];
e->Id = PackGetIntEx(p, "Id", i);
e->Protocol = PackGetIntEx(p, "Protocol", i);
e->SrcIp = PackGetIntEx(p, "SrcIp", i);
PackGetStrEx(p, "SrcHost", e->SrcHost, sizeof(e->SrcHost), i);
e->SrcPort = PackGetIntEx(p, "SrcPort", i);
e->DestIp = PackGetIntEx(p, "DestIp", i);
PackGetStrEx(p, "DestHost", e->DestHost, sizeof(e->DestHost), i);
e->DestPort = PackGetIntEx(p, "DestPort", i);
e->CreatedTime = PackGetInt64Ex(p, "CreatedTime", i);
e->LastCommTime = PackGetInt64Ex(p, "LastCommTime", i);
e->SendSize = PackGetInt64Ex(p, "SendSize", i);
e->RecvSize = PackGetInt64Ex(p, "RecvSize", i);
e->TcpStatus = PackGetIntEx(p, "TcpStatus", i);
}
}
// RPC_ENUM_DHCP
void InRpcEnumDhcp(RPC_ENUM_DHCP *t, PACK *p)
{
UINT i;
// Validate arguments
if (t == NULL || p == NULL)
{
return;
}
Zero(t, sizeof(RPC_ENUM_DHCP));
t->NumItem = PackGetInt(p, "NumItem");
t->Items = ZeroMalloc(sizeof(RPC_ENUM_DHCP_ITEM) * t->NumItem);
PackGetStr(p, "HubName", t->HubName, sizeof(t->HubName));
for (i = 0;i < t->NumItem;i++)
{
RPC_ENUM_DHCP_ITEM *e = &t->Items[i];
e->Id = PackGetIntEx(p, "Id", i);
e->LeasedTime = PackGetInt64Ex(p, "LeasedTime", i);
e->ExpireTime = PackGetInt64Ex(p, "ExpireTime", i);
PackGetDataEx2(p, "MacAddress", e->MacAddress, 6, i);
e->IpAddress = PackGetIp32Ex(p, "IpAddress", i);
e->Mask = PackGetIntEx(p, "Mask", i);
PackGetStrEx(p, "Hostname", e->Hostname, sizeof(e->Hostname), i);
}
}
// Issue an ARP query
void L3SendArp(L3IF *f, UINT ip)
{
L3ARPWAIT t, *w;
// Validate arguments
if (f == NULL || ip == 0 || ip == 0xffffffff)
{
return;
}
// Examine whether it has not already registered
Zero(&t, sizeof(t));
t.IpAddress = ip;
w = Search(f->ArpWaitTable, &t);
if (w != NULL)
{
// Do not do anything because it is already registered in the waiting list
return;
}
else
{
// Register in the waiting list newly
w = ZeroMalloc(sizeof(L3ARPWAIT));
w->Expire = Tick64() + ARP_REQUEST_GIVEUP;
w->IpAddress = ip;
Insert(f->ArpWaitTable, w);
}
}
// 64bit 整数のためのフォーマット文字列を置換する
char *ReplaceFormatStringFor64(char *fmt)
{
char *tmp;
char *ret;
UINT tmp_size;
// 引数チェック
if (fmt == NULL)
{
return NULL;
}
tmp_size = StrSize(fmt) * 2;
tmp = ZeroMalloc(tmp_size);
#ifdef OS_WIN32
ReplaceStrEx(tmp, tmp_size, fmt, "%ll", "%I64", false);
#else // OS_WIN32
ReplaceStrEx(tmp, tmp_size, fmt, "%I64", "%ll", false);
#endif // OS_WIN32
ret = CopyStr(tmp);
Free(tmp);
return ret;
}
// Send an L2 packet immediately
void L3SendL2Now(L3IF *f, UCHAR *dest_mac, UCHAR *src_mac, USHORT protocol, void *data, UINT size)
{
UCHAR *buf;
MAC_HEADER *mac_header;
PKT *p;
// Validate arguments
if (f == NULL || dest_mac == NULL || src_mac == NULL || data == NULL)
{
return;
}
// Buffer creation
buf = Malloc(MAC_HEADER_SIZE + size);
// MAC header
mac_header = (MAC_HEADER *)&buf[0];
Copy(mac_header->DestAddress, dest_mac, 6);
Copy(mac_header->SrcAddress, src_mac, 6);
mac_header->Protocol = Endian16(protocol);
// Copy data
Copy(&buf[sizeof(MAC_HEADER)], data, size);
// Size
size += sizeof(MAC_HEADER);
// Packet generation
p = ZeroMalloc(sizeof(PKT));
p->PacketData = buf;
p->PacketSize = size;
// Add to the queue
InsertQueue(f->SendQueue, p);
}
// チェックサム計算
USHORT CalcChecksumForIPv6(IPV6_ADDR *src_ip, IPV6_ADDR *dest_ip, UCHAR protocol, void *data, UINT size)
{
UCHAR *tmp;
UINT tmp_size;
IPV6_PSEUDO_HEADER *ph;
USHORT ret;
// 引数チェック
if (data == NULL && size != 0)
{
return 0;
}
tmp_size = size + sizeof(IPV6_PSEUDO_HEADER);
tmp = ZeroMalloc(tmp_size);
ph = (IPV6_PSEUDO_HEADER *)tmp;
Copy(&ph->SrcAddress, src_ip, sizeof(IPV6_ADDR));
Copy(&ph->DestAddress, dest_ip, sizeof(IPV6_ADDR));
ph->UpperLayerPacketSize = Endian32(size);
ph->NextHeader = protocol;
Copy(((UCHAR *)tmp) + sizeof(IPV6_PSEUDO_HEADER), data, size);
ret = IpChecksum(tmp, tmp_size);
Free(tmp);
return ret;
}
void BinToStrEx2(char *str, UINT str_size, void *data, UINT data_size, char padding_char)
{
char *tmp;
UCHAR *buf = (UCHAR *)data;
UINT size;
UINT i;
// Validate arguments
if (str == NULL || data == NULL)
{
return;
}
// Calculation of size
size = data_size * 3 + 1;
// Memory allocation
tmp = ZeroMalloc(size);
// Conversion
for (i = 0;i < data_size;i++)
{
Format(&tmp[i * 3], 0, "%02X%c", buf[i], padding_char);
}
if (StrLen(tmp) >= 1)
{
if (tmp[StrLen(tmp) - 1] == padding_char)
{
tmp[StrLen(tmp) - 1] = 0;
}
}
// Copy
StrCpy(str, str_size, tmp);
// Memory release
Free(tmp);
}
// Enumerate all devices
UINT EtEnumAllDevice(EL *e, RPC_ENUM_DEVICE *t)
{
TOKEN_LIST *eth;
UINT i;
if (IsEthSupported() == false)
{
return ERR_NOT_SUPPORTED;
}
FreeRpcEnumDevice(t);
Zero(t, sizeof(RPC_ENUM_DEVICE));
eth = GetEthList();
t->NumItem = eth->NumTokens;
t->Items = ZeroMalloc(sizeof(RPC_ENUM_DEVICE_ITEM) * t->NumItem);
for (i = 0;i < eth->NumTokens;i++)
{
char *name = eth->Token[i];
RPC_ENUM_DEVICE_ITEM *item = &t->Items[i];
StrCpy(item->DeviceName, sizeof(item->DeviceName), name);
}
FreeToken(eth);
return ERR_NO_ERROR;
}
// Create new traffic size object
TRAFFIC *NewTraffic()
{
TRAFFIC *t;
t = ZeroMalloc(sizeof(TRAFFIC));
return t;
}
// Create a new SecureNAT
SNAT *SnNewSecureNAT(HUB *h, VH_OPTION *o)
{
SNAT *s;
THREAD *t;
// Validate arguments
if (h == NULL || o == NULL)
{
return NULL;
}
s = ZeroMalloc(sizeof(SNAT));
s->Cedar = h->Cedar;
s->Hub = h;
s->lock = NewLock();
// Create a NAT
s->Nat = NiNewNatEx(s, o);
// Initialize the virtual machine
VirtualInit(s->Nat->Virtual);
// Create a thread
t = NewThread(SnSecureNATThread, s);
WaitThreadInit(t);
ReleaseThread(t);
return s;
}
// Create the EL
EL *NewEl()
{
EL *e;
#ifdef OS_WIN32
RegistWindowsFirewallAll();
#endif
e = ZeroMalloc(sizeof(EL));
e->lock = NewLock();
e->ref = NewRef();
e->Cedar = NewCedar(NULL, NULL);
// Ethernet initialization
InitEth();
// Setting initialization
ElInitConfig(e);
// Listener start
ElStartListener(e);
// Initialize the license status
ElParseCurrentLicenseStatus(e->LicenseSystem, e->LicenseStatus);
// Eraser start
e->Eraser = NewEraser(NULL, e->AutoDeleteCheckDiskFreeSpaceMin);
return e;
}
// Read the string table
void ViLoadStringTables()
{
UINT i, n;
HINSTANCE hInst = GetModuleHandle(NULL);
string_table = NewList(ViCompareString);
n = 0;
for (i = 1;;i++)
{
wchar_t *str = ViLoadString(hInst, i);
if (str != NULL)
{
VI_STRING *s;
n = 0;
s = ZeroMalloc(sizeof(VI_STRING));
s->Id = i;
s->String = str;
s->StringA = CopyUniToStr(str);
Insert(string_table, s);
}
else
{
n++;
if (n >= 1500)
{
break;
}
}
}
}
// Device enumeration
UINT EtEnumDevice(EL *e, RPC_ENUM_DEVICE *t)
{
bool is_beta_expired = ElIsBetaExpired();
if (is_beta_expired)
{
// The beta version has expired
return ERR_BETA_EXPIRES;
}
FreeRpcEnumDevice(t);
Zero(t, sizeof(RPC_ENUM_DEVICE));
LockList(e->DeviceList);
{
UINT i;
t->NumItem = LIST_NUM(e->DeviceList);
t->Items = ZeroMalloc(sizeof(RPC_ENUM_DEVICE_ITEM) * t->NumItem);
for (i = 0;i < t->NumItem;i++)
{
RPC_ENUM_DEVICE_ITEM *d = &t->Items[i];
EL_DEVICE *eld = LIST_DATA(e->DeviceList, i);
StrCpy(d->DeviceName, sizeof(d->DeviceName), eld->DeviceName);
d->Active = eld->Active && ((ELOG_IS_BETA || e->LicenseStatus->Valid) ? true : false);
}
}
UnlockList(e->DeviceList);
return ERR_NO_ERROR;
}
// ICMPv6 パケットの送信
BUF *BuildICMPv6(IPV6_ADDR *src_ip, IPV6_ADDR *dest_ip, UCHAR hop_limit, UCHAR type, UCHAR code, void *data, UINT size, UINT id)
{
ICMP_HEADER *icmp;
void *data_buf;
BUF *ret;
// 引数チェック
if (src_ip == NULL || dest_ip == NULL || data == NULL)
{
return NULL;
}
// ヘッダの組み立て
icmp = ZeroMalloc(sizeof(ICMP_HEADER) + size);
data_buf = ((UCHAR *)icmp) + sizeof(ICMP_HEADER);
Copy(data_buf, data, size);
icmp->Type = type;
icmp->Code = code;
icmp->Checksum = CalcChecksumForIPv6(src_ip, dest_ip, IP_PROTO_ICMPV6, icmp,
sizeof(ICMP_HEADER) + size);
ret = BuildIPv6(dest_ip, src_ip, id, IP_PROTO_ICMPV6, hop_limit, icmp,
sizeof(ICMP_HEADER) + size);
Free(icmp);
return ret;
}
