reactos/dll/win32/rpcrt4/rpc_transport.c

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/*
* RPC transport layer
*
* Copyright 2001 Ove Kåven, TransGaming Technologies
* Copyright 2003 Mike Hearn
* Copyright 2004 Filip Navara
* Copyright 2006 Mike McCormack
* Copyright 2006 Damjan Jovanovic
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*
*/
#include "ntstatus.h"
#define WIN32_NO_STATUS
#ifdef __REACTOS__
#define NONAMELESSUNION
#endif
#include "ws2tcpip.h"
#include <stdarg.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include "windef.h"
#include "winbase.h"
#include "winnls.h"
#include "winerror.h"
#include "wininet.h"
#include "wine/winternl.h"
#include "winioctl.h"
#include "rpc.h"
#include "rpcndr.h"
#include "wine/debug.h"
#include "rpc_binding.h"
#include "rpc_assoc.h"
#include "rpc_message.h"
#include "rpc_server.h"
#include "epm_towers.h"
#define DEFAULT_NCACN_HTTP_TIMEOUT (60 * 1000)
WINE_DEFAULT_DEBUG_CHANNEL(rpc);
#ifdef __REACTOS__ /* FIXME: Inspect */
BOOL WINAPI CancelIoEx(HANDLE handle, LPOVERLAPPED lpOverlapped)
{
IO_STATUS_BLOCK io_status;
NtCancelIoFile(handle, &io_status);
if (io_status.u.Status)
{
SetLastError( RtlNtStatusToDosError( io_status.u.Status ) );
return FALSE;
}
return TRUE;
}
#endif
static RpcConnection *rpcrt4_spawn_connection(RpcConnection *old_connection);
/**** ncacn_np support ****/
typedef struct _RpcConnection_np
{
RpcConnection common;
HANDLE pipe;
HANDLE listen_event;
char *listen_pipe;
IO_STATUS_BLOCK io_status;
HANDLE event_cache;
BOOL read_closed;
} RpcConnection_np;
static RpcConnection *rpcrt4_conn_np_alloc(void)
{
RpcConnection_np *npc = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(RpcConnection_np));
return &npc->common;
}
static HANDLE get_np_event(RpcConnection_np *connection)
{
HANDLE event = InterlockedExchangePointer(&connection->event_cache, NULL);
return event ? event : CreateEventW(NULL, TRUE, FALSE, NULL);
}
static void release_np_event(RpcConnection_np *connection, HANDLE event)
{
event = InterlockedExchangePointer(&connection->event_cache, event);
if (event)
CloseHandle(event);
}
#ifdef __REACTOS__
/**
* @brief
* Creates a security descriptor for RPC4 pipe
*
* @param[out] SecDesc
* A pointer to an allocated security descriptor.
*
* @return
* ERROR_SUCCESS is returned if the function has
* successfully created the security descriptor,
* otherwise a Win32 error code is returned.
*
* @remarks
* Everyone (aka World SID) and anonynous users
* are given a subset of rights to access the pipe,
* whereas admins are given full power.
*/
static DWORD rpcrt4_create_pipe_security(PSECURITY_DESCRIPTOR *SecDesc)
{
DWORD ErrCode;
PACL Dacl;
ULONG DaclSize, RelSDSize = 0;
PSID EveryoneSid = NULL, AnonymousSid = NULL, AdminsSid = NULL;
PSECURITY_DESCRIPTOR AbsSD = NULL, RelSD = NULL;
static SID_IDENTIFIER_AUTHORITY WorldAuthority = {SECURITY_WORLD_SID_AUTHORITY};
static SID_IDENTIFIER_AUTHORITY NtAuthority = {SECURITY_NT_AUTHORITY};
if (!AllocateAndInitializeSid(&WorldAuthority,
1,
SECURITY_WORLD_RID,
0, 0, 0, 0, 0, 0, 0,
&EveryoneSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate Everyone SID (error code %d)\n", GetLastError());
return GetLastError();
}
if (!AllocateAndInitializeSid(&NtAuthority,
1,
SECURITY_ANONYMOUS_LOGON_RID,
0, 0, 0, 0, 0, 0, 0,
&AnonymousSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate Anonymous SID (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!AllocateAndInitializeSid(&NtAuthority,
2,
SECURITY_BUILTIN_DOMAIN_RID,
DOMAIN_ALIAS_RID_ADMINS,
0, 0, 0, 0, 0, 0,
&AdminsSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate Admins SID (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
AbsSD = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(SECURITY_DESCRIPTOR));
if (AbsSD == NULL)
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate absolute SD!\n");
ErrCode = ERROR_OUTOFMEMORY;
goto Quit;
}
if (!InitializeSecurityDescriptor(AbsSD, SECURITY_DESCRIPTOR_REVISION))
{
ERR("rpcrt4_create_pipe_security(): Failed to create absolute SD (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
DaclSize = sizeof(ACL) +
sizeof(ACCESS_ALLOWED_ACE) + RtlLengthSid(EveryoneSid) +
sizeof(ACCESS_ALLOWED_ACE) + RtlLengthSid(AnonymousSid) +
sizeof(ACCESS_ALLOWED_ACE) + RtlLengthSid(AdminsSid);
Dacl = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, DaclSize);
if (Dacl == NULL)
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate DACL!\n");
ErrCode = ERROR_OUTOFMEMORY;
goto Quit;
}
if (!InitializeAcl(Dacl, DaclSize, ACL_REVISION))
{
ERR("rpcrt4_create_pipe_security(): Failed to create DACL (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!AddAccessAllowedAce(Dacl,
ACL_REVISION,
GENERIC_READ | GENERIC_WRITE | SYNCHRONIZE | READ_CONTROL,
EveryoneSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to set up ACE for Everyone SID (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!AddAccessAllowedAce(Dacl,
ACL_REVISION,
GENERIC_READ | GENERIC_WRITE | SYNCHRONIZE | READ_CONTROL,
AnonymousSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to set up ACE for Anonymous SID (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!AddAccessAllowedAce(Dacl,
ACL_REVISION,
GENERIC_ALL,
AdminsSid))
{
ERR("rpcrt4_create_pipe_security(): Failed to set up ACE for Admins SID (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!SetSecurityDescriptorDacl(AbsSD, TRUE, Dacl, FALSE))
{
ERR("rpcrt4_create_pipe_security(): Failed to set DACL to absolute SD (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!SetSecurityDescriptorOwner(AbsSD, AdminsSid, FALSE))
{
ERR("rpcrt4_create_pipe_security(): Failed to set SD owner (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!SetSecurityDescriptorGroup(AbsSD, AdminsSid, FALSE))
{
ERR("rpcrt4_create_pipe_security(): Failed to set SD group (error code %d)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
if (!MakeSelfRelativeSD(AbsSD, NULL, &RelSDSize) && GetLastError() != ERROR_INSUFFICIENT_BUFFER)
{
ERR("rpcrt4_create_pipe_security(): Unexpected error code (error code %d -- must be ERROR_INSUFFICIENT_BUFFER)\n", GetLastError());
ErrCode = GetLastError();
goto Quit;
}
RelSD = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, RelSDSize);
if (RelSD == NULL)
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate relative SD!\n");
ErrCode = ERROR_OUTOFMEMORY;
goto Quit;
}
if (!MakeSelfRelativeSD(AbsSD, RelSD, &RelSDSize) && GetLastError() == ERROR_INSUFFICIENT_BUFFER)
{
ERR("rpcrt4_create_pipe_security(): Failed to allocate relative SD, buffer too smal (expected size %lu)\n", RelSDSize);
ErrCode = ERROR_INSUFFICIENT_BUFFER;
goto Quit;
}
TRACE("rpcrt4_create_pipe_security(): Success!\n");
*SecDesc = RelSD;
ErrCode = ERROR_SUCCESS;
Quit:
if (ErrCode != ERROR_SUCCESS)
{
if (RelSD != NULL)
{
HeapFree(GetProcessHeap(), 0, RelSD);
}
}
if (EveryoneSid != NULL)
{
FreeSid(EveryoneSid);
}
if (AnonymousSid != NULL)
{
FreeSid(AnonymousSid);
}
if (AdminsSid != NULL)
{
FreeSid(AdminsSid);
}
if (Dacl != NULL)
{
HeapFree(GetProcessHeap(), 0, Dacl);
}
if (AbsSD != NULL)
{
HeapFree(GetProcessHeap(), 0, AbsSD);
}
return ErrCode;
}
#endif
static RPC_STATUS rpcrt4_conn_create_pipe(RpcConnection *conn)
{
RpcConnection_np *connection = (RpcConnection_np *) conn;
#ifdef __REACTOS__
DWORD ErrCode;
SECURITY_ATTRIBUTES SecurityAttributes;
PSECURITY_DESCRIPTOR PipeSecDesc;
#endif
TRACE("listening on %s\n", connection->listen_pipe);
#ifdef __REACTOS__
ErrCode = rpcrt4_create_pipe_security(&PipeSecDesc);
if (ErrCode != ERROR_SUCCESS)
{
ERR("rpcrt4_conn_create_pipe(): Pipe security descriptor creation failed!\n");
return RPC_S_CANT_CREATE_ENDPOINT;
}
SecurityAttributes.nLength = sizeof(SECURITY_ATTRIBUTES);
SecurityAttributes.lpSecurityDescriptor = PipeSecDesc;
SecurityAttributes.bInheritHandle = FALSE;
connection->pipe = CreateNamedPipeA(connection->listen_pipe, PIPE_ACCESS_DUPLEX | FILE_FLAG_OVERLAPPED,
PIPE_TYPE_MESSAGE | PIPE_READMODE_MESSAGE,
PIPE_UNLIMITED_INSTANCES,
RPC_MAX_PACKET_SIZE, RPC_MAX_PACKET_SIZE, 5000, &SecurityAttributes);
HeapFree(GetProcessHeap(), 0, PipeSecDesc);
#else
connection->pipe = CreateNamedPipeA(connection->listen_pipe, PIPE_ACCESS_DUPLEX | FILE_FLAG_OVERLAPPED,
PIPE_TYPE_MESSAGE | PIPE_READMODE_MESSAGE,
PIPE_UNLIMITED_INSTANCES,
RPC_MAX_PACKET_SIZE, RPC_MAX_PACKET_SIZE, 5000, NULL);
#endif
if (connection->pipe == INVALID_HANDLE_VALUE)
{
WARN("CreateNamedPipe failed with error %d\n", GetLastError());
if (GetLastError() == ERROR_FILE_EXISTS)
{
return RPC_S_DUPLICATE_ENDPOINT;
}
else
{
return RPC_S_CANT_CREATE_ENDPOINT;
}
}
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_conn_open_pipe(RpcConnection *Connection, LPCSTR pname, BOOL wait)
{
RpcConnection_np *npc = (RpcConnection_np *) Connection;
HANDLE pipe;
DWORD err, dwMode;
TRACE("connecting to %s\n", pname);
while (TRUE) {
DWORD dwFlags = 0;
if (Connection->QOS)
{
dwFlags = SECURITY_SQOS_PRESENT;
switch (Connection->QOS->qos->ImpersonationType)
{
case RPC_C_IMP_LEVEL_DEFAULT:
/* FIXME: what to do here? */
break;
case RPC_C_IMP_LEVEL_ANONYMOUS:
dwFlags |= SECURITY_ANONYMOUS;
break;
case RPC_C_IMP_LEVEL_IDENTIFY:
dwFlags |= SECURITY_IDENTIFICATION;
break;
case RPC_C_IMP_LEVEL_IMPERSONATE:
dwFlags |= SECURITY_IMPERSONATION;
break;
case RPC_C_IMP_LEVEL_DELEGATE:
dwFlags |= SECURITY_DELEGATION;
break;
}
if (Connection->QOS->qos->IdentityTracking == RPC_C_QOS_IDENTITY_DYNAMIC)
dwFlags |= SECURITY_CONTEXT_TRACKING;
}
pipe = CreateFileA(pname, GENERIC_READ|GENERIC_WRITE, 0, NULL,
OPEN_EXISTING, dwFlags | FILE_FLAG_OVERLAPPED, 0);
if (pipe != INVALID_HANDLE_VALUE) break;
err = GetLastError();
if (err == ERROR_PIPE_BUSY) {
if (WaitNamedPipeA(pname, NMPWAIT_USE_DEFAULT_WAIT)) {
TRACE("retrying busy server\n");
continue;
}
TRACE("connection failed, error=%x\n", err);
return RPC_S_SERVER_TOO_BUSY;
#ifdef __REACTOS__
} else if (err == ERROR_BAD_NETPATH) {
TRACE("connection failed, error=%x\n", err);
return RPC_S_SERVER_UNAVAILABLE;
#endif
}
if (!wait || !WaitNamedPipeA(pname, NMPWAIT_WAIT_FOREVER)) {
err = GetLastError();
WARN("connection failed, error=%x\n", err);
return RPC_S_SERVER_UNAVAILABLE;
}
}
/* success */
/* pipe is connected; change to message-read mode. */
dwMode = PIPE_READMODE_MESSAGE;
SetNamedPipeHandleState(pipe, &dwMode, NULL, NULL);
npc->pipe = pipe;
return RPC_S_OK;
}
static char *ncalrpc_pipe_name(const char *endpoint)
{
static const char prefix[] = "\\\\.\\pipe\\lrpc\\";
char *pipe_name;
/* protseq=ncalrpc: supposed to use NT LPC ports,
* but we'll implement it with named pipes for now */
pipe_name = I_RpcAllocate(sizeof(prefix) + strlen(endpoint));
strcat(strcpy(pipe_name, prefix), endpoint);
return pipe_name;
}
static RPC_STATUS rpcrt4_ncalrpc_open(RpcConnection* Connection)
{
RpcConnection_np *npc = (RpcConnection_np *) Connection;
RPC_STATUS r;
LPSTR pname;
/* already connected? */
if (npc->pipe)
return RPC_S_OK;
pname = ncalrpc_pipe_name(Connection->Endpoint);
r = rpcrt4_conn_open_pipe(Connection, pname, TRUE);
I_RpcFree(pname);
return r;
}
static RPC_STATUS rpcrt4_protseq_ncalrpc_open_endpoint(RpcServerProtseq* protseq, const char *endpoint)
{
RPC_STATUS r;
RpcConnection *Connection;
char generated_endpoint[22];
if (!endpoint)
{
static LONG lrpc_nameless_id;
DWORD process_id = GetCurrentProcessId();
ULONG id = InterlockedIncrement(&lrpc_nameless_id);
snprintf(generated_endpoint, sizeof(generated_endpoint),
"LRPC%08x.%08x", process_id, id);
endpoint = generated_endpoint;
}
r = RPCRT4_CreateConnection(&Connection, TRUE, protseq->Protseq, NULL,
endpoint, NULL, NULL, NULL, NULL);
if (r != RPC_S_OK)
return r;
((RpcConnection_np*)Connection)->listen_pipe = ncalrpc_pipe_name(Connection->Endpoint);
r = rpcrt4_conn_create_pipe(Connection);
EnterCriticalSection(&protseq->cs);
list_add_head(&protseq->listeners, &Connection->protseq_entry);
Connection->protseq = protseq;
LeaveCriticalSection(&protseq->cs);
return r;
}
#ifdef __REACTOS__
static char *ncacn_pipe_name(const char *server, const char *endpoint)
#else
static char *ncacn_pipe_name(const char *endpoint)
#endif
{
#ifdef __REACTOS__
static const char prefix[] = "\\\\";
static const char local[] = ".";
char ComputerName[MAX_COMPUTERNAME_LENGTH + 1];
DWORD bufLen = ARRAY_SIZE(ComputerName);
#else
static const char prefix[] = "\\\\.";
#endif
char *pipe_name;
#ifdef __REACTOS__
if (server != NULL && *server != 0)
{
/* Trim any leading UNC server prefix. */
if (server[0] == '\\' && server[1] == '\\')
server += 2;
/* If the server represents the local computer, use instead
* the local prefix to avoid a round in UNC name resolution. */
if (GetComputerNameA(ComputerName, &bufLen) &&
(stricmp(ComputerName, server) == 0))
{
server = local;
}
}
else
{
server = local;
}
#endif
/* protseq=ncacn_np: named pipes */
#ifdef __REACTOS__
pipe_name = I_RpcAllocate(sizeof(prefix) + strlen(server) + strlen(endpoint));
strcpy(pipe_name, prefix);
strcat(pipe_name, server);
strcat(pipe_name, endpoint);
#else
pipe_name = I_RpcAllocate(sizeof(prefix) + strlen(endpoint));
strcat(strcpy(pipe_name, prefix), endpoint);
#endif
return pipe_name;
}
static RPC_STATUS rpcrt4_ncacn_np_open(RpcConnection* Connection)
{
RpcConnection_np *npc = (RpcConnection_np *) Connection;
RPC_STATUS r;
LPSTR pname;
/* already connected? */
if (npc->pipe)
return RPC_S_OK;
#ifdef __REACTOS__
pname = ncacn_pipe_name(Connection->NetworkAddr, Connection->Endpoint);
#else
pname = ncacn_pipe_name(Connection->Endpoint);
#endif
r = rpcrt4_conn_open_pipe(Connection, pname, FALSE);
I_RpcFree(pname);
return r;
}
static RPC_STATUS rpcrt4_protseq_ncacn_np_open_endpoint(RpcServerProtseq *protseq, const char *endpoint)
{
RPC_STATUS r;
RpcConnection *Connection;
char generated_endpoint[26];
if (!endpoint)
{
static LONG np_nameless_id;
DWORD process_id = GetCurrentProcessId();
ULONG id = InterlockedExchangeAdd(&np_nameless_id, 1 );
snprintf(generated_endpoint, sizeof(generated_endpoint),
"\\\\pipe\\\\%08x.%03x", process_id, id);
endpoint = generated_endpoint;
}
r = RPCRT4_CreateConnection(&Connection, TRUE, protseq->Protseq, NULL,
endpoint, NULL, NULL, NULL, NULL);
if (r != RPC_S_OK)
return r;
#ifdef __REACTOS__
((RpcConnection_np*)Connection)->listen_pipe = ncacn_pipe_name(NULL, Connection->Endpoint);
#else
((RpcConnection_np*)Connection)->listen_pipe = ncacn_pipe_name(Connection->Endpoint);
#endif
r = rpcrt4_conn_create_pipe(Connection);
EnterCriticalSection(&protseq->cs);
list_add_head(&protseq->listeners, &Connection->protseq_entry);
Connection->protseq = protseq;
LeaveCriticalSection(&protseq->cs);
return r;
}
static void rpcrt4_conn_np_handoff(RpcConnection_np *old_npc, RpcConnection_np *new_npc)
{
/* because of the way named pipes work, we'll transfer the connected pipe
* to the child, then reopen the server binding to continue listening */
new_npc->pipe = old_npc->pipe;
old_npc->pipe = 0;
assert(!old_npc->listen_event);
}
static RPC_STATUS rpcrt4_ncacn_np_handoff(RpcConnection *old_conn, RpcConnection *new_conn)
{
DWORD len = MAX_COMPUTERNAME_LENGTH + 1;
RPC_STATUS status;
rpcrt4_conn_np_handoff((RpcConnection_np *)old_conn, (RpcConnection_np *)new_conn);
status = rpcrt4_conn_create_pipe(old_conn);
/* Store the local computer name as the NetworkAddr for ncacn_np as long as
* we don't support named pipes over the network. */
new_conn->NetworkAddr = HeapAlloc(GetProcessHeap(), 0, len);
if (!GetComputerNameA(new_conn->NetworkAddr, &len))
{
ERR("Failed to retrieve the computer name, error %u\n", GetLastError());
return RPC_S_OUT_OF_RESOURCES;
}
return status;
}
static RPC_STATUS is_pipe_listening(const char *pipe_name)
{
return WaitNamedPipeA(pipe_name, 1) ? RPC_S_OK : RPC_S_NOT_LISTENING;
}
static RPC_STATUS rpcrt4_ncacn_np_is_server_listening(const char *endpoint)
{
char *pipe_name;
RPC_STATUS status;
#ifdef __REACTOS__
pipe_name = ncacn_pipe_name(NULL, endpoint);
#else
pipe_name = ncacn_pipe_name(endpoint);
#endif
status = is_pipe_listening(pipe_name);
I_RpcFree(pipe_name);
return status;
}
static RPC_STATUS rpcrt4_ncalrpc_np_is_server_listening(const char *endpoint)
{
char *pipe_name;
RPC_STATUS status;
pipe_name = ncalrpc_pipe_name(endpoint);
status = is_pipe_listening(pipe_name);
I_RpcFree(pipe_name);
return status;
}
static RPC_STATUS rpcrt4_ncalrpc_handoff(RpcConnection *old_conn, RpcConnection *new_conn)
{
DWORD len = MAX_COMPUTERNAME_LENGTH + 1;
RPC_STATUS status;
TRACE("%s\n", old_conn->Endpoint);
rpcrt4_conn_np_handoff((RpcConnection_np *)old_conn, (RpcConnection_np *)new_conn);
status = rpcrt4_conn_create_pipe(old_conn);
/* Store the local computer name as the NetworkAddr for ncalrpc. */
new_conn->NetworkAddr = HeapAlloc(GetProcessHeap(), 0, len);
if (!GetComputerNameA(new_conn->NetworkAddr, &len))
{
ERR("Failed to retrieve the computer name, error %u\n", GetLastError());
return RPC_S_OUT_OF_RESOURCES;
}
return status;
}
static int rpcrt4_conn_np_read(RpcConnection *conn, void *buffer, unsigned int count)
{
RpcConnection_np *connection = (RpcConnection_np *) conn;
HANDLE event;
NTSTATUS status;
event = get_np_event(connection);
if (!event)
return -1;
if (connection->read_closed)
status = STATUS_CANCELLED;
else
status = NtReadFile(connection->pipe, event, NULL, NULL, &connection->io_status, buffer, count, NULL, NULL);
if (status == STATUS_PENDING)
{
/* check read_closed again before waiting to avoid a race */
if (connection->read_closed)
{
IO_STATUS_BLOCK io_status;
#ifdef __REACTOS__ /* FIXME: We should also cancel I/O for other threads */
NtCancelIoFile(connection->pipe, &io_status);
#else
NtCancelIoFileEx(connection->pipe, &connection->io_status, &io_status);
#endif
}
WaitForSingleObject(event, INFINITE);
status = connection->io_status.u.Status;
}
release_np_event(connection, event);
return status && status != STATUS_BUFFER_OVERFLOW ? -1 : connection->io_status.Information;
}
static int rpcrt4_conn_np_write(RpcConnection *conn, const void *buffer, unsigned int count)
{
RpcConnection_np *connection = (RpcConnection_np *) conn;
IO_STATUS_BLOCK io_status;
HANDLE event;
NTSTATUS status;
event = get_np_event(connection);
if (!event)
return -1;
status = NtWriteFile(connection->pipe, event, NULL, NULL, &io_status, buffer, count, NULL, NULL);
if (status == STATUS_PENDING)
{
WaitForSingleObject(event, INFINITE);
status = io_status.u.Status;
}
release_np_event(connection, event);
if (status)
return -1;
assert(io_status.Information == count);
return count;
}
static int rpcrt4_conn_np_close(RpcConnection *conn)
{
RpcConnection_np *connection = (RpcConnection_np *) conn;
if (connection->pipe)
{
FlushFileBuffers(connection->pipe);
CloseHandle(connection->pipe);
connection->pipe = 0;
}
if (connection->listen_event)
{
CloseHandle(connection->listen_event);
connection->listen_event = 0;
}
if (connection->event_cache)
{
CloseHandle(connection->event_cache);
connection->event_cache = 0;
}
return 0;
}
static void rpcrt4_conn_np_close_read(RpcConnection *conn)
{
RpcConnection_np *connection = (RpcConnection_np*)conn;
IO_STATUS_BLOCK io_status;
connection->read_closed = TRUE;
#ifdef __REACTOS__ /* FIXME: We should also cancel I/O for other threads */
NtCancelIoFile(connection->pipe, &io_status);
#else
NtCancelIoFileEx(connection->pipe, &connection->io_status, &io_status);
#endif
}
static void rpcrt4_conn_np_cancel_call(RpcConnection *conn)
{
RpcConnection_np *connection = (RpcConnection_np *)conn;
CancelIoEx(connection->pipe, NULL);
}
static int rpcrt4_conn_np_wait_for_incoming_data(RpcConnection *conn)
{
return rpcrt4_conn_np_read(conn, NULL, 0);
}
static size_t rpcrt4_ncacn_np_get_top_of_tower(unsigned char *tower_data,
const char *networkaddr,
const char *endpoint)
{
twr_empty_floor_t *smb_floor;
twr_empty_floor_t *nb_floor;
size_t size;
size_t networkaddr_size;
size_t endpoint_size;
TRACE("(%p, %s, %s)\n", tower_data, networkaddr, endpoint);
networkaddr_size = networkaddr ? strlen(networkaddr) + 1 : 1;
endpoint_size = endpoint ? strlen(endpoint) + 1 : 1;
size = sizeof(*smb_floor) + endpoint_size + sizeof(*nb_floor) + networkaddr_size;
if (!tower_data)
return size;
smb_floor = (twr_empty_floor_t *)tower_data;
tower_data += sizeof(*smb_floor);
smb_floor->count_lhs = sizeof(smb_floor->protid);
smb_floor->protid = EPM_PROTOCOL_SMB;
smb_floor->count_rhs = endpoint_size;
if (endpoint)
memcpy(tower_data, endpoint, endpoint_size);
else
tower_data[0] = 0;
tower_data += endpoint_size;
nb_floor = (twr_empty_floor_t *)tower_data;
tower_data += sizeof(*nb_floor);
nb_floor->count_lhs = sizeof(nb_floor->protid);
nb_floor->protid = EPM_PROTOCOL_NETBIOS;
nb_floor->count_rhs = networkaddr_size;
if (networkaddr)
memcpy(tower_data, networkaddr, networkaddr_size);
else
tower_data[0] = 0;
return size;
}
static RPC_STATUS rpcrt4_ncacn_np_parse_top_of_tower(const unsigned char *tower_data,
size_t tower_size,
char **networkaddr,
char **endpoint)
{
const twr_empty_floor_t *smb_floor = (const twr_empty_floor_t *)tower_data;
const twr_empty_floor_t *nb_floor;
TRACE("(%p, %d, %p, %p)\n", tower_data, (int)tower_size, networkaddr, endpoint);
if (tower_size < sizeof(*smb_floor))
return EPT_S_NOT_REGISTERED;
tower_data += sizeof(*smb_floor);
tower_size -= sizeof(*smb_floor);
if ((smb_floor->count_lhs != sizeof(smb_floor->protid)) ||
(smb_floor->protid != EPM_PROTOCOL_SMB) ||
(smb_floor->count_rhs > tower_size) ||
(tower_data[smb_floor->count_rhs - 1] != '\0'))
return EPT_S_NOT_REGISTERED;
if (endpoint)
{
*endpoint = I_RpcAllocate(smb_floor->count_rhs);
if (!*endpoint)
return RPC_S_OUT_OF_RESOURCES;
memcpy(*endpoint, tower_data, smb_floor->count_rhs);
}
tower_data += smb_floor->count_rhs;
tower_size -= smb_floor->count_rhs;
if (tower_size < sizeof(*nb_floor))
return EPT_S_NOT_REGISTERED;
nb_floor = (const twr_empty_floor_t *)tower_data;
tower_data += sizeof(*nb_floor);
tower_size -= sizeof(*nb_floor);
if ((nb_floor->count_lhs != sizeof(nb_floor->protid)) ||
(nb_floor->protid != EPM_PROTOCOL_NETBIOS) ||
(nb_floor->count_rhs > tower_size) ||
(tower_data[nb_floor->count_rhs - 1] != '\0'))
return EPT_S_NOT_REGISTERED;
if (networkaddr)
{
*networkaddr = I_RpcAllocate(nb_floor->count_rhs);
if (!*networkaddr)
{
if (endpoint)
{
I_RpcFree(*endpoint);
*endpoint = NULL;
}
return RPC_S_OUT_OF_RESOURCES;
}
memcpy(*networkaddr, tower_data, nb_floor->count_rhs);
}
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_conn_np_impersonate_client(RpcConnection *conn)
{
RpcConnection_np *npc = (RpcConnection_np *)conn;
BOOL ret;
TRACE("(%p)\n", conn);
if (conn->AuthInfo && SecIsValidHandle(&conn->ctx))
return RPCRT4_default_impersonate_client(conn);
ret = ImpersonateNamedPipeClient(npc->pipe);
if (!ret)
{
DWORD error = GetLastError();
WARN("ImpersonateNamedPipeClient failed with error %u\n", error);
switch (error)
{
case ERROR_CANNOT_IMPERSONATE:
return RPC_S_NO_CONTEXT_AVAILABLE;
}
}
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_conn_np_revert_to_self(RpcConnection *conn)
{
BOOL ret;
TRACE("(%p)\n", conn);
if (conn->AuthInfo && SecIsValidHandle(&conn->ctx))
return RPCRT4_default_revert_to_self(conn);
ret = RevertToSelf();
if (!ret)
{
WARN("RevertToSelf failed with error %u\n", GetLastError());
return RPC_S_NO_CONTEXT_AVAILABLE;
}
return RPC_S_OK;
}
typedef struct _RpcServerProtseq_np
{
RpcServerProtseq common;
HANDLE mgr_event;
} RpcServerProtseq_np;
static RpcServerProtseq *rpcrt4_protseq_np_alloc(void)
{
RpcServerProtseq_np *ps = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(*ps));
if (ps)
ps->mgr_event = CreateEventW(NULL, FALSE, FALSE, NULL);
return &ps->common;
}
static void rpcrt4_protseq_np_signal_state_changed(RpcServerProtseq *protseq)
{
RpcServerProtseq_np *npps = CONTAINING_RECORD(protseq, RpcServerProtseq_np, common);
SetEvent(npps->mgr_event);
}
static void *rpcrt4_protseq_np_get_wait_array(RpcServerProtseq *protseq, void *prev_array, unsigned int *count)
{
HANDLE *objs = prev_array;
RpcConnection_np *conn;
RpcServerProtseq_np *npps = CONTAINING_RECORD(protseq, RpcServerProtseq_np, common);
EnterCriticalSection(&protseq->cs);
/* open and count connections */
*count = 1;
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_np, common.protseq_entry)
{
if (!conn->pipe && rpcrt4_conn_create_pipe(&conn->common) != RPC_S_OK)
continue;
if (!conn->listen_event)
{
NTSTATUS status;
HANDLE event;
event = get_np_event(conn);
if (!event)
continue;
status = NtFsControlFile(conn->pipe, event, NULL, NULL, &conn->io_status, FSCTL_PIPE_LISTEN, NULL, 0, NULL, 0);
switch (status)
{
case STATUS_SUCCESS:
case STATUS_PIPE_CONNECTED:
conn->io_status.u.Status = status;
SetEvent(event);
break;
case STATUS_PENDING:
break;
default:
ERR("pipe listen error %x\n", status);
continue;
}
conn->listen_event = event;
}
(*count)++;
}
/* make array of connections */
if (objs)
objs = HeapReAlloc(GetProcessHeap(), 0, objs, *count*sizeof(HANDLE));
else
objs = HeapAlloc(GetProcessHeap(), 0, *count*sizeof(HANDLE));
if (!objs)
{
ERR("couldn't allocate objs\n");
LeaveCriticalSection(&protseq->cs);
return NULL;
}
objs[0] = npps->mgr_event;
*count = 1;
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_np, common.protseq_entry)
{
if (conn->listen_event)
objs[(*count)++] = conn->listen_event;
}
LeaveCriticalSection(&protseq->cs);
return objs;
}
static void rpcrt4_protseq_np_free_wait_array(RpcServerProtseq *protseq, void *array)
{
HeapFree(GetProcessHeap(), 0, array);
}
static int rpcrt4_protseq_np_wait_for_new_connection(RpcServerProtseq *protseq, unsigned int count, void *wait_array)
{
HANDLE b_handle;
HANDLE *objs = wait_array;
DWORD res;
RpcConnection *cconn = NULL;
RpcConnection_np *conn;
if (!objs)
return -1;
do
{
/* an alertable wait isn't strictly necessary, but due to our
* overlapped I/O implementation in Wine we need to free some memory
* by the file user APC being called, even if no completion routine was
* specified at the time of starting the async operation */
res = WaitForMultipleObjectsEx(count, objs, FALSE, INFINITE, TRUE);
} while (res == WAIT_IO_COMPLETION);
if (res == WAIT_OBJECT_0)
return 0;
else if (res == WAIT_FAILED)
{
ERR("wait failed with error %d\n", GetLastError());
return -1;
}
else
{
b_handle = objs[res - WAIT_OBJECT_0];
/* find which connection got a RPC */
EnterCriticalSection(&protseq->cs);
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_np, common.protseq_entry)
{
if (b_handle == conn->listen_event)
{
release_np_event(conn, conn->listen_event);
conn->listen_event = NULL;
if (conn->io_status.u.Status == STATUS_SUCCESS || conn->io_status.u.Status == STATUS_PIPE_CONNECTED)
cconn = rpcrt4_spawn_connection(&conn->common);
else
ERR("listen failed %x\n", conn->io_status.u.Status);
break;
}
}
LeaveCriticalSection(&protseq->cs);
if (!cconn)
{
ERR("failed to locate connection for handle %p\n", b_handle);
return -1;
}
RPCRT4_new_client(cconn);
return 1;
}
}
static size_t rpcrt4_ncalrpc_get_top_of_tower(unsigned char *tower_data,
const char *networkaddr,
const char *endpoint)
{
twr_empty_floor_t *pipe_floor;
size_t size;
size_t endpoint_size;
TRACE("(%p, %s, %s)\n", tower_data, networkaddr, endpoint);
endpoint_size = strlen(endpoint) + 1;
size = sizeof(*pipe_floor) + endpoint_size;
if (!tower_data)
return size;
pipe_floor = (twr_empty_floor_t *)tower_data;
tower_data += sizeof(*pipe_floor);
pipe_floor->count_lhs = sizeof(pipe_floor->protid);
pipe_floor->protid = EPM_PROTOCOL_PIPE;
pipe_floor->count_rhs = endpoint_size;
memcpy(tower_data, endpoint, endpoint_size);
return size;
}
static RPC_STATUS rpcrt4_ncalrpc_parse_top_of_tower(const unsigned char *tower_data,
size_t tower_size,
char **networkaddr,
char **endpoint)
{
const twr_empty_floor_t *pipe_floor = (const twr_empty_floor_t *)tower_data;
TRACE("(%p, %d, %p, %p)\n", tower_data, (int)tower_size, networkaddr, endpoint);
if (tower_size < sizeof(*pipe_floor))
return EPT_S_NOT_REGISTERED;
tower_data += sizeof(*pipe_floor);
tower_size -= sizeof(*pipe_floor);
if ((pipe_floor->count_lhs != sizeof(pipe_floor->protid)) ||
(pipe_floor->protid != EPM_PROTOCOL_PIPE) ||
(pipe_floor->count_rhs > tower_size) ||
(tower_data[pipe_floor->count_rhs - 1] != '\0'))
return EPT_S_NOT_REGISTERED;
if (networkaddr)
*networkaddr = NULL;
if (endpoint)
{
*endpoint = I_RpcAllocate(pipe_floor->count_rhs);
if (!*endpoint)
return RPC_S_OUT_OF_RESOURCES;
memcpy(*endpoint, tower_data, pipe_floor->count_rhs);
}
return RPC_S_OK;
}
static BOOL rpcrt4_ncalrpc_is_authorized(RpcConnection *conn)
{
return FALSE;
}
static RPC_STATUS rpcrt4_ncalrpc_authorize(RpcConnection *conn, BOOL first_time,
unsigned char *in_buffer,
unsigned int in_size,
unsigned char *out_buffer,
unsigned int *out_size)
{
/* since this protocol is local to the machine there is no need to
* authenticate the caller */
*out_size = 0;
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_ncalrpc_secure_packet(RpcConnection *conn,
enum secure_packet_direction dir,
RpcPktHdr *hdr, unsigned int hdr_size,
unsigned char *stub_data, unsigned int stub_data_size,
RpcAuthVerifier *auth_hdr,
unsigned char *auth_value, unsigned int auth_value_size)
{
/* since this protocol is local to the machine there is no need to secure
* the packet */
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_ncalrpc_inquire_auth_client(
RpcConnection *conn, RPC_AUTHZ_HANDLE *privs, RPC_WSTR *server_princ_name,
ULONG *authn_level, ULONG *authn_svc, ULONG *authz_svc, ULONG flags)
{
TRACE("(%p, %p, %p, %p, %p, %p, 0x%x)\n", conn, privs,
server_princ_name, authn_level, authn_svc, authz_svc, flags);
if (privs)
{
FIXME("privs not implemented\n");
*privs = NULL;
}
if (server_princ_name)
{
FIXME("server_princ_name not implemented\n");
*server_princ_name = NULL;
}
if (authn_level) *authn_level = RPC_C_AUTHN_LEVEL_PKT_PRIVACY;
if (authn_svc) *authn_svc = RPC_C_AUTHN_WINNT;
if (authz_svc)
{
FIXME("authorization service not implemented\n");
*authz_svc = RPC_C_AUTHZ_NONE;
}
if (flags)
FIXME("flags 0x%x not implemented\n", flags);
return RPC_S_OK;
}
/**** ncacn_ip_tcp support ****/
static size_t rpcrt4_ip_tcp_get_top_of_tower(unsigned char *tower_data,
const char *networkaddr,
unsigned char tcp_protid,
const char *endpoint)
{
twr_tcp_floor_t *tcp_floor;
twr_ipv4_floor_t *ipv4_floor;
struct addrinfo *ai;
struct addrinfo hints;
int ret;
size_t size = sizeof(*tcp_floor) + sizeof(*ipv4_floor);
TRACE("(%p, %s, %s)\n", tower_data, networkaddr, endpoint);
if (!tower_data)
return size;
tcp_floor = (twr_tcp_floor_t *)tower_data;
tower_data += sizeof(*tcp_floor);
ipv4_floor = (twr_ipv4_floor_t *)tower_data;
tcp_floor->count_lhs = sizeof(tcp_floor->protid);
tcp_floor->protid = tcp_protid;
tcp_floor->count_rhs = sizeof(tcp_floor->port);
ipv4_floor->count_lhs = sizeof(ipv4_floor->protid);
ipv4_floor->protid = EPM_PROTOCOL_IP;
ipv4_floor->count_rhs = sizeof(ipv4_floor->ipv4addr);
hints.ai_flags = AI_NUMERICHOST;
/* FIXME: only support IPv4 at the moment. how is IPv6 represented by the EPM? */
hints.ai_family = PF_INET;
hints.ai_socktype = SOCK_STREAM;
hints.ai_protocol = IPPROTO_TCP;
hints.ai_addrlen = 0;
hints.ai_addr = NULL;
hints.ai_canonname = NULL;
hints.ai_next = NULL;
#ifdef __REACTOS__
static BOOL wsa_inited;
if (!wsa_inited)
{
WSADATA wsadata;
WSAStartup(MAKEWORD(2, 2), &wsadata);
/* Note: WSAStartup can be called more than once so we don't bother with
* making accesses to wsa_inited thread-safe */
wsa_inited = TRUE;
}
#endif
ret = getaddrinfo(networkaddr, endpoint, &hints, &ai);
if (ret)
{
ret = getaddrinfo("0.0.0.0", endpoint, &hints, &ai);
if (ret)
{
ERR("getaddrinfo failed: %s\n", gai_strerror(ret));
return 0;
}
}
if (ai->ai_family == PF_INET)
{
const struct sockaddr_in *sin = (const struct sockaddr_in *)ai->ai_addr;
tcp_floor->port = sin->sin_port;
ipv4_floor->ipv4addr = sin->sin_addr.s_addr;
}
else
{
ERR("unexpected protocol family %d\n", ai->ai_family);
freeaddrinfo(ai);
return 0;
}
freeaddrinfo(ai);
return size;
}
static RPC_STATUS rpcrt4_ip_tcp_parse_top_of_tower(const unsigned char *tower_data,
size_t tower_size,
char **networkaddr,
unsigned char tcp_protid,
char **endpoint)
{
const twr_tcp_floor_t *tcp_floor = (const twr_tcp_floor_t *)tower_data;
const twr_ipv4_floor_t *ipv4_floor;
struct in_addr in_addr;
TRACE("(%p, %d, %p, %p)\n", tower_data, (int)tower_size, networkaddr, endpoint);
if (tower_size < sizeof(*tcp_floor))
return EPT_S_NOT_REGISTERED;
tower_data += sizeof(*tcp_floor);
tower_size -= sizeof(*tcp_floor);
if (tower_size < sizeof(*ipv4_floor))
return EPT_S_NOT_REGISTERED;
ipv4_floor = (const twr_ipv4_floor_t *)tower_data;
if ((tcp_floor->count_lhs != sizeof(tcp_floor->protid)) ||
(tcp_floor->protid != tcp_protid) ||
(tcp_floor->count_rhs != sizeof(tcp_floor->port)) ||
(ipv4_floor->count_lhs != sizeof(ipv4_floor->protid)) ||
(ipv4_floor->protid != EPM_PROTOCOL_IP) ||
(ipv4_floor->count_rhs != sizeof(ipv4_floor->ipv4addr)))
return EPT_S_NOT_REGISTERED;
if (endpoint)
{
*endpoint = I_RpcAllocate(6 /* sizeof("65535") + 1 */);
if (!*endpoint)
return RPC_S_OUT_OF_RESOURCES;
sprintf(*endpoint, "%u", ntohs(tcp_floor->port));
}
if (networkaddr)
{
*networkaddr = I_RpcAllocate(INET_ADDRSTRLEN);
if (!*networkaddr)
{
if (endpoint)
{
I_RpcFree(*endpoint);
*endpoint = NULL;
}
return RPC_S_OUT_OF_RESOURCES;
}
in_addr.s_addr = ipv4_floor->ipv4addr;
if (!inet_ntop(AF_INET, &in_addr, *networkaddr, INET_ADDRSTRLEN))
{
ERR("inet_ntop: %u\n", WSAGetLastError());
I_RpcFree(*networkaddr);
*networkaddr = NULL;
if (endpoint)
{
I_RpcFree(*endpoint);
*endpoint = NULL;
}
return EPT_S_NOT_REGISTERED;
}
}
return RPC_S_OK;
}
typedef struct _RpcConnection_tcp
{
RpcConnection common;
int sock;
HANDLE sock_event;
HANDLE cancel_event;
} RpcConnection_tcp;
static BOOL rpcrt4_sock_wait_init(RpcConnection_tcp *tcpc)
{
static BOOL wsa_inited;
if (!wsa_inited)
{
WSADATA wsadata;
WSAStartup(MAKEWORD(2, 2), &wsadata);
/* Note: WSAStartup can be called more than once so we don't bother with
* making accesses to wsa_inited thread-safe */
wsa_inited = TRUE;
}
tcpc->sock_event = CreateEventW(NULL, FALSE, FALSE, NULL);
tcpc->cancel_event = CreateEventW(NULL, FALSE, FALSE, NULL);
if (!tcpc->sock_event || !tcpc->cancel_event)
{
ERR("event creation failed\n");
if (tcpc->sock_event) CloseHandle(tcpc->sock_event);
return FALSE;
}
return TRUE;
}
static BOOL rpcrt4_sock_wait_for_recv(RpcConnection_tcp *tcpc)
{
HANDLE wait_handles[2];
DWORD res;
if (WSAEventSelect(tcpc->sock, tcpc->sock_event, FD_READ | FD_CLOSE) == SOCKET_ERROR)
{
ERR("WSAEventSelect() failed with error %d\n", WSAGetLastError());
return FALSE;
}
wait_handles[0] = tcpc->sock_event;
wait_handles[1] = tcpc->cancel_event;
res = WaitForMultipleObjects(2, wait_handles, FALSE, INFINITE);
switch (res)
{
case WAIT_OBJECT_0:
return TRUE;
case WAIT_OBJECT_0 + 1:
return FALSE;
default:
ERR("WaitForMultipleObjects() failed with error %d\n", GetLastError());
return FALSE;
}
}
static BOOL rpcrt4_sock_wait_for_send(RpcConnection_tcp *tcpc)
{
DWORD res;
if (WSAEventSelect(tcpc->sock, tcpc->sock_event, FD_WRITE | FD_CLOSE) == SOCKET_ERROR)
{
ERR("WSAEventSelect() failed with error %d\n", WSAGetLastError());
return FALSE;
}
res = WaitForSingleObject(tcpc->sock_event, INFINITE);
switch (res)
{
case WAIT_OBJECT_0:
return TRUE;
default:
ERR("WaitForMultipleObjects() failed with error %d\n", GetLastError());
return FALSE;
}
}
static RpcConnection *rpcrt4_conn_tcp_alloc(void)
{
RpcConnection_tcp *tcpc;
tcpc = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(RpcConnection_tcp));
if (tcpc == NULL)
return NULL;
tcpc->sock = -1;
if (!rpcrt4_sock_wait_init(tcpc))
{
HeapFree(GetProcessHeap(), 0, tcpc);
return NULL;
}
return &tcpc->common;
}
static RPC_STATUS rpcrt4_ncacn_ip_tcp_open(RpcConnection* Connection)
{
RpcConnection_tcp *tcpc = (RpcConnection_tcp *) Connection;
int sock;
int ret;
struct addrinfo *ai;
struct addrinfo *ai_cur;
struct addrinfo hints;
TRACE("(%s, %s)\n", Connection->NetworkAddr, Connection->Endpoint);
if (tcpc->sock != -1)
return RPC_S_OK;
hints.ai_flags = 0;
hints.ai_family = PF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
hints.ai_protocol = IPPROTO_TCP;
hints.ai_addrlen = 0;
hints.ai_addr = NULL;
hints.ai_canonname = NULL;
hints.ai_next = NULL;
ret = getaddrinfo(Connection->NetworkAddr, Connection->Endpoint, &hints, &ai);
if (ret)
{
ERR("getaddrinfo for %s:%s failed: %s\n", Connection->NetworkAddr,
Connection->Endpoint, gai_strerror(ret));
return RPC_S_SERVER_UNAVAILABLE;
}
for (ai_cur = ai; ai_cur; ai_cur = ai_cur->ai_next)
{
int val;
u_long nonblocking;
if (ai_cur->ai_family != AF_INET && ai_cur->ai_family != AF_INET6)
{
TRACE("skipping non-IP/IPv6 address family\n");
continue;
}
if (TRACE_ON(rpc))
{
char host[256];
char service[256];
getnameinfo(ai_cur->ai_addr, ai_cur->ai_addrlen,
host, sizeof(host), service, sizeof(service),
NI_NUMERICHOST | NI_NUMERICSERV);
TRACE("trying %s:%s\n", host, service);
}
sock = socket(ai_cur->ai_family, ai_cur->ai_socktype, ai_cur->ai_protocol);
if (sock == -1)
{
WARN("socket() failed: %u\n", WSAGetLastError());
continue;
}
if (0>connect(sock, ai_cur->ai_addr, ai_cur->ai_addrlen))
{
WARN("connect() failed: %u\n", WSAGetLastError());
closesocket(sock);
continue;
}
/* RPC depends on having minimal latency so disable the Nagle algorithm */
val = 1;
setsockopt(sock, IPPROTO_TCP, TCP_NODELAY, (char *)&val, sizeof(val));
nonblocking = 1;
ioctlsocket(sock, FIONBIO, &nonblocking);
tcpc->sock = sock;
freeaddrinfo(ai);
TRACE("connected\n");
return RPC_S_OK;
}
freeaddrinfo(ai);
ERR("couldn't connect to %s:%s\n", Connection->NetworkAddr, Connection->Endpoint);
return RPC_S_SERVER_UNAVAILABLE;
}
static RPC_STATUS rpcrt4_protseq_ncacn_ip_tcp_open_endpoint(RpcServerProtseq *protseq, const char *endpoint)
{
RPC_STATUS status = RPC_S_CANT_CREATE_ENDPOINT;
int sock;
int ret;
struct addrinfo *ai;
struct addrinfo *ai_cur;
struct addrinfo hints;
TRACE("(%p, %s)\n", protseq, endpoint);
hints.ai_flags = AI_PASSIVE /* for non-localhost addresses */;
hints.ai_family = PF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
hints.ai_protocol = IPPROTO_TCP;
hints.ai_addrlen = 0;
hints.ai_addr = NULL;
hints.ai_canonname = NULL;
hints.ai_next = NULL;
ret = getaddrinfo(NULL, endpoint ? endpoint : "0", &hints, &ai);
if (ret)
{
ERR("getaddrinfo for port %s failed: %s\n", endpoint,
gai_strerror(ret));
if ((ret == EAI_SERVICE) || (ret == EAI_NONAME))
return RPC_S_INVALID_ENDPOINT_FORMAT;
return RPC_S_CANT_CREATE_ENDPOINT;
}
for (ai_cur = ai; ai_cur; ai_cur = ai_cur->ai_next)
{
RpcConnection_tcp *tcpc;
RPC_STATUS create_status;
struct sockaddr_storage sa;
socklen_t sa_len;
char service[NI_MAXSERV];
u_long nonblocking;
if (ai_cur->ai_family != AF_INET && ai_cur->ai_family != AF_INET6)
{
TRACE("skipping non-IP/IPv6 address family\n");
continue;
}
if (TRACE_ON(rpc))
{
char host[256];
getnameinfo(ai_cur->ai_addr, ai_cur->ai_addrlen,
host, sizeof(host), service, sizeof(service),
NI_NUMERICHOST | NI_NUMERICSERV);
TRACE("trying %s:%s\n", host, service);
}
sock = socket(ai_cur->ai_family, ai_cur->ai_socktype, ai_cur->ai_protocol);
if (sock == -1)
{
WARN("socket() failed: %u\n", WSAGetLastError());
status = RPC_S_CANT_CREATE_ENDPOINT;
continue;
}
ret = bind(sock, ai_cur->ai_addr, ai_cur->ai_addrlen);
if (ret < 0)
{
WARN("bind failed: %u\n", WSAGetLastError());
closesocket(sock);
if (WSAGetLastError() == WSAEADDRINUSE)
status = RPC_S_DUPLICATE_ENDPOINT;
else
status = RPC_S_CANT_CREATE_ENDPOINT;
continue;
}
sa_len = sizeof(sa);
if (getsockname(sock, (struct sockaddr *)&sa, &sa_len))
{
WARN("getsockname() failed: %u\n", WSAGetLastError());
closesocket(sock);
status = RPC_S_CANT_CREATE_ENDPOINT;
continue;
}
ret = getnameinfo((struct sockaddr *)&sa, sa_len,
NULL, 0, service, sizeof(service),
NI_NUMERICSERV);
if (ret)
{
WARN("getnameinfo failed: %s\n", gai_strerror(ret));
closesocket(sock);
status = RPC_S_CANT_CREATE_ENDPOINT;
continue;
}
create_status = RPCRT4_CreateConnection((RpcConnection **)&tcpc, TRUE,
protseq->Protseq, NULL,
service, NULL, NULL, NULL, NULL);
if (create_status != RPC_S_OK)
{
closesocket(sock);
status = create_status;
continue;
}
tcpc->sock = sock;
ret = listen(sock, protseq->MaxCalls);
if (ret < 0)
{
WARN("listen failed: %u\n", WSAGetLastError());
RPCRT4_ReleaseConnection(&tcpc->common);
status = RPC_S_OUT_OF_RESOURCES;
continue;
}
/* need a non-blocking socket, otherwise accept() has a potential
* race-condition (poll() says it is readable, connection drops,
* and accept() blocks until the next connection comes...)
*/
nonblocking = 1;
ret = ioctlsocket(sock, FIONBIO, &nonblocking);
if (ret < 0)
{
WARN("couldn't make socket non-blocking, error %d\n", ret);
RPCRT4_ReleaseConnection(&tcpc->common);
status = RPC_S_OUT_OF_RESOURCES;
continue;
}
EnterCriticalSection(&protseq->cs);
list_add_tail(&protseq->listeners, &tcpc->common.protseq_entry);
tcpc->common.protseq = protseq;
LeaveCriticalSection(&protseq->cs);
freeaddrinfo(ai);
/* since IPv4 and IPv6 share the same port space, we only need one
* successful bind to listen for both */
TRACE("listening on %s\n", endpoint);
return RPC_S_OK;
}
freeaddrinfo(ai);
ERR("couldn't listen on port %s\n", endpoint);
return status;
}
static RPC_STATUS rpcrt4_conn_tcp_handoff(RpcConnection *old_conn, RpcConnection *new_conn)
{
int ret;
struct sockaddr_in address;
socklen_t addrsize;
RpcConnection_tcp *server = (RpcConnection_tcp*) old_conn;
RpcConnection_tcp *client = (RpcConnection_tcp*) new_conn;
u_long nonblocking;
addrsize = sizeof(address);
ret = accept(server->sock, (struct sockaddr*) &address, &addrsize);
if (ret < 0)
{
ERR("Failed to accept a TCP connection: error %d\n", ret);
return RPC_S_OUT_OF_RESOURCES;
}
nonblocking = 1;
ioctlsocket(ret, FIONBIO, &nonblocking);
client->sock = ret;
client->common.NetworkAddr = HeapAlloc(GetProcessHeap(), 0, INET6_ADDRSTRLEN);
ret = getnameinfo((struct sockaddr*)&address, addrsize, client->common.NetworkAddr, INET6_ADDRSTRLEN, NULL, 0, NI_NUMERICHOST);
if (ret != 0)
{
ERR("Failed to retrieve the IP address, error %d\n", ret);
return RPC_S_OUT_OF_RESOURCES;
}
TRACE("Accepted a new TCP connection from %s\n", client->common.NetworkAddr);
return RPC_S_OK;
}
static int rpcrt4_conn_tcp_read(RpcConnection *Connection,
void *buffer, unsigned int count)
{
RpcConnection_tcp *tcpc = (RpcConnection_tcp *) Connection;
int bytes_read = 0;
while (bytes_read != count)
{
int r = recv(tcpc->sock, (char *)buffer + bytes_read, count - bytes_read, 0);
if (!r)
return -1;
else if (r > 0)
bytes_read += r;
else if (WSAGetLastError() == WSAEINTR)
continue;
else if (WSAGetLastError() != WSAEWOULDBLOCK)
{
WARN("recv() failed: %u\n", WSAGetLastError());
return -1;
}
else
{
if (!rpcrt4_sock_wait_for_recv(tcpc))
return -1;
}
}
TRACE("%d %p %u -> %d\n", tcpc->sock, buffer, count, bytes_read);
return bytes_read;
}
static int rpcrt4_conn_tcp_write(RpcConnection *Connection,
const void *buffer, unsigned int count)
{
RpcConnection_tcp *tcpc = (RpcConnection_tcp *) Connection;
int bytes_written = 0;
while (bytes_written != count)
{
int r = send(tcpc->sock, (const char *)buffer + bytes_written, count - bytes_written, 0);
if (r >= 0)
bytes_written += r;
else if (WSAGetLastError() == WSAEINTR)
continue;
else if (WSAGetLastError() != WSAEWOULDBLOCK)
return -1;
else
{
if (!rpcrt4_sock_wait_for_send(tcpc))
return -1;
}
}
TRACE("%d %p %u -> %d\n", tcpc->sock, buffer, count, bytes_written);
return bytes_written;
}
static int rpcrt4_conn_tcp_close(RpcConnection *conn)
{
RpcConnection_tcp *connection = (RpcConnection_tcp *) conn;
TRACE("%d\n", connection->sock);
if (connection->sock != -1)
closesocket(connection->sock);
connection->sock = -1;
CloseHandle(connection->sock_event);
CloseHandle(connection->cancel_event);
return 0;
}
static void rpcrt4_conn_tcp_close_read(RpcConnection *conn)
{
RpcConnection_tcp *connection = (RpcConnection_tcp *) conn;
shutdown(connection->sock, SD_RECEIVE);
}
static void rpcrt4_conn_tcp_cancel_call(RpcConnection *conn)
{
RpcConnection_tcp *connection = (RpcConnection_tcp *) conn;
TRACE("%p\n", connection);
SetEvent(connection->cancel_event);
}
static RPC_STATUS rpcrt4_conn_tcp_is_server_listening(const char *endpoint)
{
FIXME("\n");
return RPC_S_ACCESS_DENIED;
}
static int rpcrt4_conn_tcp_wait_for_incoming_data(RpcConnection *Connection)
{
RpcConnection_tcp *tcpc = (RpcConnection_tcp *) Connection;
TRACE("%p\n", Connection);
if (!rpcrt4_sock_wait_for_recv(tcpc))
return -1;
return 0;
}
static size_t rpcrt4_ncacn_ip_tcp_get_top_of_tower(unsigned char *tower_data,
const char *networkaddr,
const char *endpoint)
{
return rpcrt4_ip_tcp_get_top_of_tower(tower_data, networkaddr,
EPM_PROTOCOL_TCP, endpoint);
}
typedef struct _RpcServerProtseq_sock
{
RpcServerProtseq common;
HANDLE mgr_event;
} RpcServerProtseq_sock;
static RpcServerProtseq *rpcrt4_protseq_sock_alloc(void)
{
RpcServerProtseq_sock *ps = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(*ps));
if (ps)
{
static BOOL wsa_inited;
if (!wsa_inited)
{
WSADATA wsadata;
WSAStartup(MAKEWORD(2, 2), &wsadata);
/* Note: WSAStartup can be called more than once so we don't bother with
* making accesses to wsa_inited thread-safe */
wsa_inited = TRUE;
}
ps->mgr_event = CreateEventW(NULL, FALSE, FALSE, NULL);
}
return &ps->common;
}
static void rpcrt4_protseq_sock_signal_state_changed(RpcServerProtseq *protseq)
{
RpcServerProtseq_sock *sockps = CONTAINING_RECORD(protseq, RpcServerProtseq_sock, common);
SetEvent(sockps->mgr_event);
}
static void *rpcrt4_protseq_sock_get_wait_array(RpcServerProtseq *protseq, void *prev_array, unsigned int *count)
{
HANDLE *objs = prev_array;
RpcConnection_tcp *conn;
RpcServerProtseq_sock *sockps = CONTAINING_RECORD(protseq, RpcServerProtseq_sock, common);
EnterCriticalSection(&protseq->cs);
/* open and count connections */
*count = 1;
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_tcp, common.protseq_entry)
{
if (conn->sock != -1)
(*count)++;
}
/* make array of connections */
if (objs)
objs = HeapReAlloc(GetProcessHeap(), 0, objs, *count*sizeof(HANDLE));
else
objs = HeapAlloc(GetProcessHeap(), 0, *count*sizeof(HANDLE));
if (!objs)
{
ERR("couldn't allocate objs\n");
LeaveCriticalSection(&protseq->cs);
return NULL;
}
objs[0] = sockps->mgr_event;
*count = 1;
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_tcp, common.protseq_entry)
{
if (conn->sock != -1)
{
int res = WSAEventSelect(conn->sock, conn->sock_event, FD_ACCEPT);
if (res == SOCKET_ERROR)
ERR("WSAEventSelect() failed with error %d\n", WSAGetLastError());
else
{
objs[*count] = conn->sock_event;
(*count)++;
}
}
}
LeaveCriticalSection(&protseq->cs);
return objs;
}
static void rpcrt4_protseq_sock_free_wait_array(RpcServerProtseq *protseq, void *array)
{
HeapFree(GetProcessHeap(), 0, array);
}
static int rpcrt4_protseq_sock_wait_for_new_connection(RpcServerProtseq *protseq, unsigned int count, void *wait_array)
{
HANDLE b_handle;
HANDLE *objs = wait_array;
DWORD res;
RpcConnection *cconn = NULL;
RpcConnection_tcp *conn;
if (!objs)
return -1;
do
{
/* an alertable wait isn't strictly necessary, but due to our
* overlapped I/O implementation in Wine we need to free some memory
* by the file user APC being called, even if no completion routine was
* specified at the time of starting the async operation */
res = WaitForMultipleObjectsEx(count, objs, FALSE, INFINITE, TRUE);
} while (res == WAIT_IO_COMPLETION);
if (res == WAIT_OBJECT_0)
return 0;
if (res == WAIT_FAILED)
{
ERR("wait failed with error %d\n", GetLastError());
return -1;
}
b_handle = objs[res - WAIT_OBJECT_0];
/* find which connection got a RPC */
EnterCriticalSection(&protseq->cs);
LIST_FOR_EACH_ENTRY(conn, &protseq->listeners, RpcConnection_tcp, common.protseq_entry)
{
if (b_handle == conn->sock_event)
{
cconn = rpcrt4_spawn_connection(&conn->common);
break;
}
}
LeaveCriticalSection(&protseq->cs);
if (!cconn)
{
ERR("failed to locate connection for handle %p\n", b_handle);
return -1;
}
RPCRT4_new_client(cconn);
return 1;
}
static RPC_STATUS rpcrt4_ncacn_ip_tcp_parse_top_of_tower(const unsigned char *tower_data,
size_t tower_size,
char **networkaddr,
char **endpoint)
{
return rpcrt4_ip_tcp_parse_top_of_tower(tower_data, tower_size,
networkaddr, EPM_PROTOCOL_TCP,
endpoint);
}
/**** ncacn_http support ****/
/* 60 seconds is the period native uses */
#define HTTP_IDLE_TIME 60000
/* reference counted to avoid a race between a cancelled call's connection
* being destroyed and the asynchronous InternetReadFileEx call being
* completed */
typedef struct _RpcHttpAsyncData
{
LONG refs;
HANDLE completion_event;
WORD async_result;
INTERNET_BUFFERSW inet_buffers;
CRITICAL_SECTION cs;
} RpcHttpAsyncData;
static ULONG RpcHttpAsyncData_AddRef(RpcHttpAsyncData *data)
{
return InterlockedIncrement(&data->refs);
}
static ULONG RpcHttpAsyncData_Release(RpcHttpAsyncData *data)
{
ULONG refs = InterlockedDecrement(&data->refs);
if (!refs)
{
TRACE("destroying async data %p\n", data);
CloseHandle(data->completion_event);
HeapFree(GetProcessHeap(), 0, data->inet_buffers.lpvBuffer);
data->cs.DebugInfo->Spare[0] = 0;
DeleteCriticalSection(&data->cs);
HeapFree(GetProcessHeap(), 0, data);
}
return refs;
}
static void prepare_async_request(RpcHttpAsyncData *async_data)
{
ResetEvent(async_data->completion_event);
RpcHttpAsyncData_AddRef(async_data);
}
static RPC_STATUS wait_async_request(RpcHttpAsyncData *async_data, BOOL call_ret, HANDLE cancel_event)
{
HANDLE handles[2] = { async_data->completion_event, cancel_event };
DWORD res;
if(call_ret) {
RpcHttpAsyncData_Release(async_data);
return RPC_S_OK;
}
if(GetLastError() != ERROR_IO_PENDING) {
RpcHttpAsyncData_Release(async_data);
ERR("Request failed with error %d\n", GetLastError());
return RPC_S_SERVER_UNAVAILABLE;
}
res = WaitForMultipleObjects(2, handles, FALSE, DEFAULT_NCACN_HTTP_TIMEOUT);
if(res != WAIT_OBJECT_0) {
TRACE("Cancelled\n");
return RPC_S_CALL_CANCELLED;
}
if(async_data->async_result) {
ERR("Async request failed with error %d\n", async_data->async_result);
return RPC_S_SERVER_UNAVAILABLE;
}
return RPC_S_OK;
}
struct authinfo
{
DWORD scheme;
CredHandle cred;
CtxtHandle ctx;
TimeStamp exp;
ULONG attr;
ULONG max_token;
char *data;
unsigned int data_len;
BOOL finished; /* finished authenticating */
};
typedef struct _RpcConnection_http
{
RpcConnection common;
HINTERNET app_info;
HINTERNET session;
HINTERNET in_request;
HINTERNET out_request;
WCHAR *servername;
HANDLE timer_cancelled;
HANDLE cancel_event;
DWORD last_sent_time;
ULONG bytes_received;
ULONG flow_control_mark; /* send a control packet to the server when this many bytes received */
ULONG flow_control_increment; /* number of bytes to increment flow_control_mark by */
UUID connection_uuid;
UUID in_pipe_uuid;
UUID out_pipe_uuid;
RpcHttpAsyncData *async_data;
} RpcConnection_http;
static RpcConnection *rpcrt4_ncacn_http_alloc(void)
{
RpcConnection_http *httpc;
httpc = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(*httpc));
if (!httpc) return NULL;
httpc->async_data = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(RpcHttpAsyncData));
if (!httpc->async_data)
{
HeapFree(GetProcessHeap(), 0, httpc);
return NULL;
}
TRACE("async data = %p\n", httpc->async_data);
httpc->cancel_event = CreateEventW(NULL, FALSE, FALSE, NULL);
httpc->async_data->refs = 1;
httpc->async_data->inet_buffers.dwStructSize = sizeof(INTERNET_BUFFERSW);
InitializeCriticalSection(&httpc->async_data->cs);
httpc->async_data->cs.DebugInfo->Spare[0] = (DWORD_PTR)(__FILE__ ": RpcHttpAsyncData.cs");
return &httpc->common;
}
typedef struct _HttpTimerThreadData
{
PVOID timer_param;
DWORD *last_sent_time;
HANDLE timer_cancelled;
} HttpTimerThreadData;
static VOID rpcrt4_http_keep_connection_active_timer_proc(PVOID param, BOOLEAN dummy)
{
HINTERNET in_request = param;
RpcPktHdr *idle_pkt;
idle_pkt = RPCRT4_BuildHttpHeader(NDR_LOCAL_DATA_REPRESENTATION, 0x0001,
0, 0);
if (idle_pkt)
{
DWORD bytes_written;
InternetWriteFile(in_request, idle_pkt, idle_pkt->common.frag_len, &bytes_written);
RPCRT4_FreeHeader(idle_pkt);
}
}
static inline DWORD rpcrt4_http_timer_calc_timeout(DWORD *last_sent_time)
{
DWORD cur_time = GetTickCount();
DWORD cached_last_sent_time = *last_sent_time;
return HTTP_IDLE_TIME - (cur_time - cached_last_sent_time > HTTP_IDLE_TIME ? 0 : cur_time - cached_last_sent_time);
}
static DWORD CALLBACK rpcrt4_http_timer_thread(PVOID param)
{
HttpTimerThreadData *data_in = param;
HttpTimerThreadData data;
DWORD timeout;
data = *data_in;
HeapFree(GetProcessHeap(), 0, data_in);
for (timeout = HTTP_IDLE_TIME;
WaitForSingleObject(data.timer_cancelled, timeout) == WAIT_TIMEOUT;
timeout = rpcrt4_http_timer_calc_timeout(data.last_sent_time))
{
/* are we too soon after last send? */
if (GetTickCount() - *data.last_sent_time < HTTP_IDLE_TIME)
continue;
rpcrt4_http_keep_connection_active_timer_proc(data.timer_param, TRUE);
}
CloseHandle(data.timer_cancelled);
return 0;
}
static VOID WINAPI rpcrt4_http_internet_callback(
HINTERNET hInternet,
DWORD_PTR dwContext,
DWORD dwInternetStatus,
LPVOID lpvStatusInformation,
DWORD dwStatusInformationLength)
{
RpcHttpAsyncData *async_data = (RpcHttpAsyncData *)dwContext;
switch (dwInternetStatus)
{
case INTERNET_STATUS_REQUEST_COMPLETE:
TRACE("INTERNET_STATUS_REQUEST_COMPLETED\n");
if (async_data)
{
INTERNET_ASYNC_RESULT *async_result = lpvStatusInformation;
async_data->async_result = async_result->dwResult ? ERROR_SUCCESS : async_result->dwError;
SetEvent(async_data->completion_event);
RpcHttpAsyncData_Release(async_data);
}
break;
}
}
static RPC_STATUS rpcrt4_http_check_response(HINTERNET hor)
{
BOOL ret;
DWORD status_code;
DWORD size;
DWORD index;
WCHAR buf[32];
WCHAR *status_text = buf;
TRACE("\n");
index = 0;
size = sizeof(status_code);
ret = HttpQueryInfoW(hor, HTTP_QUERY_STATUS_CODE|HTTP_QUERY_FLAG_NUMBER, &status_code, &size, &index);
if (!ret)
return GetLastError();
if (status_code == HTTP_STATUS_OK)
return RPC_S_OK;
index = 0;
size = sizeof(buf);
ret = HttpQueryInfoW(hor, HTTP_QUERY_STATUS_TEXT, status_text, &size, &index);
if (!ret && GetLastError() == ERROR_INSUFFICIENT_BUFFER)
{
status_text = HeapAlloc(GetProcessHeap(), 0, size);
ret = HttpQueryInfoW(hor, HTTP_QUERY_STATUS_TEXT, status_text, &size, &index);
}
ERR("server returned: %d %s\n", status_code, ret ? debugstr_w(status_text) : "<status text unavailable>");
if(status_text != buf) HeapFree(GetProcessHeap(), 0, status_text);
if (status_code == HTTP_STATUS_DENIED)
return ERROR_ACCESS_DENIED;
return RPC_S_SERVER_UNAVAILABLE;
}
static RPC_STATUS rpcrt4_http_internet_connect(RpcConnection_http *httpc)
{
static const WCHAR wszUserAgent[] = {'M','S','R','P','C',0};
LPWSTR proxy = NULL;
LPWSTR user = NULL;
LPWSTR password = NULL;
LPWSTR servername = NULL;
const WCHAR *option;
INTERNET_PORT port;
if (httpc->common.QOS &&
(httpc->common.QOS->qos->AdditionalSecurityInfoType == RPC_C_AUTHN_INFO_TYPE_HTTP))
{
const RPC_HTTP_TRANSPORT_CREDENTIALS_W *http_cred = httpc->common.QOS->qos->u.HttpCredentials;
if (http_cred->TransportCredentials)
{
WCHAR *p;
const SEC_WINNT_AUTH_IDENTITY_W *cred = http_cred->TransportCredentials;
ULONG len = cred->DomainLength + 1 + cred->UserLength;
user = HeapAlloc(GetProcessHeap(), 0, (len + 1) * sizeof(WCHAR));
if (!user)
return RPC_S_OUT_OF_RESOURCES;
p = user;
if (cred->DomainLength)
{
memcpy(p, cred->Domain, cred->DomainLength * sizeof(WCHAR));
p += cred->DomainLength;
*p = '\\';
p++;
}
memcpy(p, cred->User, cred->UserLength * sizeof(WCHAR));
p[cred->UserLength] = 0;
password = RPCRT4_strndupW(cred->Password, cred->PasswordLength);
}
}
for (option = httpc->common.NetworkOptions; option;
option = (wcschr(option, ',') ? wcschr(option, ',')+1 : NULL))
{
static const WCHAR wszRpcProxy[] = {'R','p','c','P','r','o','x','y','=',0};
static const WCHAR wszHttpProxy[] = {'H','t','t','p','P','r','o','x','y','=',0};
if (!_wcsnicmp(option, wszRpcProxy, ARRAY_SIZE(wszRpcProxy)-1))
{
const WCHAR *value_start = option + ARRAY_SIZE(wszRpcProxy)-1;
const WCHAR *value_end;
const WCHAR *p;
value_end = wcschr(option, ',');
if (!value_end)
value_end = value_start + lstrlenW(value_start);
for (p = value_start; p < value_end; p++)
if (*p == ':')
{
port = wcstol(p+1, NULL, 10);
value_end = p;
break;
}
TRACE("RpcProxy value is %s\n", debugstr_wn(value_start, value_end-value_start));
servername = RPCRT4_strndupW(value_start, value_end-value_start);
}
else if (!_wcsnicmp(option, wszHttpProxy, ARRAY_SIZE(wszHttpProxy)-1))
{
const WCHAR *value_start = option + ARRAY_SIZE(wszHttpProxy)-1;
const WCHAR *value_end;
value_end = wcschr(option, ',');
if (!value_end)
value_end = value_start + lstrlenW(value_start);
TRACE("HttpProxy value is %s\n", debugstr_wn(value_start, value_end-value_start));
proxy = RPCRT4_strndupW(value_start, value_end-value_start);
}
else
FIXME("unhandled option %s\n", debugstr_w(option));
}
httpc->app_info = InternetOpenW(wszUserAgent, proxy ? INTERNET_OPEN_TYPE_PROXY : INTERNET_OPEN_TYPE_PRECONFIG,
NULL, NULL, INTERNET_FLAG_ASYNC);
if (!httpc->app_info)
{
HeapFree(GetProcessHeap(), 0, password);
HeapFree(GetProcessHeap(), 0, user);
HeapFree(GetProcessHeap(), 0, proxy);
HeapFree(GetProcessHeap(), 0, servername);
ERR("InternetOpenW failed with error %d\n", GetLastError());
return RPC_S_SERVER_UNAVAILABLE;
}
InternetSetStatusCallbackW(httpc->app_info, rpcrt4_http_internet_callback);
/* if no RpcProxy option specified, set the HTTP server address to the
* RPC server address */
if (!servername)
{
servername = HeapAlloc(GetProcessHeap(), 0, (strlen(httpc->common.NetworkAddr) + 1)*sizeof(WCHAR));
if (!servername)
{
HeapFree(GetProcessHeap(), 0, password);
HeapFree(GetProcessHeap(), 0, user);
HeapFree(GetProcessHeap(), 0, proxy);
return RPC_S_OUT_OF_RESOURCES;
}
MultiByteToWideChar(CP_ACP, 0, httpc->common.NetworkAddr, -1, servername, strlen(httpc->common.NetworkAddr) + 1);
}
port = (httpc->common.QOS &&
(httpc->common.QOS->qos->AdditionalSecurityInfoType == RPC_C_AUTHN_INFO_TYPE_HTTP) &&
(httpc->common.QOS->qos->u.HttpCredentials->Flags & RPC_C_HTTP_FLAG_USE_SSL)) ?
INTERNET_DEFAULT_HTTPS_PORT : INTERNET_DEFAULT_HTTP_PORT;
httpc->session = InternetConnectW(httpc->app_info, servername, port, user, password,
INTERNET_SERVICE_HTTP, 0, 0);
HeapFree(GetProcessHeap(), 0, password);
HeapFree(GetProcessHeap(), 0, user);
HeapFree(GetProcessHeap(), 0, proxy);
if (!httpc->session)
{
ERR("InternetConnectW failed with error %d\n", GetLastError());
HeapFree(GetProcessHeap(), 0, servername);
return RPC_S_SERVER_UNAVAILABLE;
}
httpc->servername = servername;
return RPC_S_OK;
}
static int rpcrt4_http_async_read(HINTERNET req, RpcHttpAsyncData *async_data, HANDLE cancel_event,
void *buffer, unsigned int count)
{
char *buf = buffer;
BOOL ret;
unsigned int bytes_left = count;
RPC_STATUS status = RPC_S_OK;
async_data->inet_buffers.lpvBuffer = HeapAlloc(GetProcessHeap(), 0, count);
while (bytes_left)
{
async_data->inet_buffers.dwBufferLength = bytes_left;
prepare_async_request(async_data);
ret = InternetReadFileExW(req, &async_data->inet_buffers, IRF_ASYNC, 0);
status = wait_async_request(async_data, ret, cancel_event);
if (status != RPC_S_OK)
{
if (status == RPC_S_CALL_CANCELLED)
TRACE("call cancelled\n");
break;
}
if (!async_data->inet_buffers.dwBufferLength)
break;
memcpy(buf, async_data->inet_buffers.lpvBuffer,
async_data->inet_buffers.dwBufferLength);
bytes_left -= async_data->inet_buffers.dwBufferLength;
buf += async_data->inet_buffers.dwBufferLength;
}
HeapFree(GetProcessHeap(), 0, async_data->inet_buffers.lpvBuffer);
async_data->inet_buffers.lpvBuffer = NULL;
TRACE("%p %p %u -> %u\n", req, buffer, count, status);
return status == RPC_S_OK ? count : -1;
}
static RPC_STATUS send_echo_request(HINTERNET req, RpcHttpAsyncData *async_data, HANDLE cancel_event)
{
BYTE buf[20];
BOOL ret;
RPC_STATUS status;
TRACE("sending echo request to server\n");
prepare_async_request(async_data);
ret = HttpSendRequestW(req, NULL, 0, NULL, 0);
status = wait_async_request(async_data, ret, cancel_event);
if (status != RPC_S_OK) return status;
status = rpcrt4_http_check_response(req);
if (status != RPC_S_OK) return status;
rpcrt4_http_async_read(req, async_data, cancel_event, buf, sizeof(buf));
/* FIXME: do something with retrieved data */
return RPC_S_OK;
}
static RPC_STATUS insert_content_length_header(HINTERNET request, DWORD len)
{
static const WCHAR fmtW[] =
{'C','o','n','t','e','n','t','-','L','e','n','g','t','h',':',' ','%','u','\r','\n',0};
WCHAR header[ARRAY_SIZE(fmtW) + 10];
swprintf(header, fmtW, len);
if ((HttpAddRequestHeadersW(request, header, -1, HTTP_ADDREQ_FLAG_REPLACE | HTTP_ADDREQ_FLAG_ADD))) return RPC_S_OK;
return RPC_S_SERVER_UNAVAILABLE;
}
/* prepare the in pipe for use by RPC packets */
static RPC_STATUS rpcrt4_http_prepare_in_pipe(HINTERNET in_request, RpcHttpAsyncData *async_data, HANDLE cancel_event,
const UUID *connection_uuid, const UUID *in_pipe_uuid,
const UUID *association_uuid, BOOL authorized)
{
BOOL ret;
RPC_STATUS status;
RpcPktHdr *hdr;
INTERNET_BUFFERSW buffers_in;
DWORD bytes_written;
if (!authorized)
{
/* ask wininet to authorize, if necessary */
status = send_echo_request(in_request, async_data, cancel_event);
if (status != RPC_S_OK) return status;
}
memset(&buffers_in, 0, sizeof(buffers_in));
buffers_in.dwStructSize = sizeof(buffers_in);
/* FIXME: get this from the registry */
buffers_in.dwBufferTotal = 1024 * 1024 * 1024; /* 1Gb */
status = insert_content_length_header(in_request, buffers_in.dwBufferTotal);
if (status != RPC_S_OK) return status;
prepare_async_request(async_data);
ret = HttpSendRequestExW(in_request, &buffers_in, NULL, 0, 0);
status = wait_async_request(async_data, ret, cancel_event);
if (status != RPC_S_OK) return status;
TRACE("sending HTTP connect header to server\n");
hdr = RPCRT4_BuildHttpConnectHeader(FALSE, connection_uuid, in_pipe_uuid, association_uuid);
if (!hdr) return RPC_S_OUT_OF_RESOURCES;
ret = InternetWriteFile(in_request, hdr, hdr->common.frag_len, &bytes_written);
RPCRT4_FreeHeader(hdr);
if (!ret)
{
ERR("InternetWriteFile failed with error %d\n", GetLastError());
return RPC_S_SERVER_UNAVAILABLE;
}
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_http_read_http_packet(HINTERNET request, RpcHttpAsyncData *async_data,
HANDLE cancel_event, RpcPktHdr *hdr, BYTE **data)
{
unsigned short data_len;
unsigned int size;
if (rpcrt4_http_async_read(request, async_data, cancel_event, hdr, sizeof(hdr->common)) < 0)
return RPC_S_SERVER_UNAVAILABLE;
if (hdr->common.ptype != PKT_HTTP || hdr->common.frag_len < sizeof(hdr->http))
{
ERR("wrong packet type received %d or wrong frag_len %d\n",
hdr->common.ptype, hdr->common.frag_len);
return RPC_S_PROTOCOL_ERROR;
}
size = sizeof(hdr->http) - sizeof(hdr->common);
if (rpcrt4_http_async_read(request, async_data, cancel_event, &hdr->common + 1, size) < 0)
return RPC_S_SERVER_UNAVAILABLE;
data_len = hdr->common.frag_len - sizeof(hdr->http);
if (data_len)
{
*data = HeapAlloc(GetProcessHeap(), 0, data_len);
if (!*data)
return RPC_S_OUT_OF_RESOURCES;
if (rpcrt4_http_async_read(request, async_data, cancel_event, *data, data_len) < 0)
{
HeapFree(GetProcessHeap(), 0, *data);
return RPC_S_SERVER_UNAVAILABLE;
}
}
else
*data = NULL;
if (!RPCRT4_IsValidHttpPacket(hdr, *data, data_len))
{
ERR("invalid http packet\n");
HeapFree(GetProcessHeap(), 0, *data);
return RPC_S_PROTOCOL_ERROR;
}
return RPC_S_OK;
}
/* prepare the out pipe for use by RPC packets */
static RPC_STATUS rpcrt4_http_prepare_out_pipe(HINTERNET out_request, RpcHttpAsyncData *async_data,
HANDLE cancel_event, const UUID *connection_uuid,
const UUID *out_pipe_uuid, ULONG *flow_control_increment,
BOOL authorized)
{
BOOL ret;
RPC_STATUS status;
RpcPktHdr *hdr;
BYTE *data_from_server;
RpcPktHdr pkt_from_server;
ULONG field1, field3;
BYTE buf[20];
if (!authorized)
{
/* ask wininet to authorize, if necessary */
status = send_echo_request(out_request, async_data, cancel_event);
if (status != RPC_S_OK) return status;
}
else
rpcrt4_http_async_read(out_request, async_data, cancel_event, buf, sizeof(buf));
hdr = RPCRT4_BuildHttpConnectHeader(TRUE, connection_uuid, out_pipe_uuid, NULL);
if (!hdr) return RPC_S_OUT_OF_RESOURCES;
status = insert_content_length_header(out_request, hdr->common.frag_len);
if (status != RPC_S_OK)
{
RPCRT4_FreeHeader(hdr);
return status;
}
TRACE("sending HTTP connect header to server\n");
prepare_async_request(async_data);
ret = HttpSendRequestW(out_request, NULL, 0, hdr, hdr->common.frag_len);
status = wait_async_request(async_data, ret, cancel_event);
RPCRT4_FreeHeader(hdr);
if (status != RPC_S_OK) return status;
status = rpcrt4_http_check_response(out_request);
if (status != RPC_S_OK) return status;
status = rpcrt4_http_read_http_packet(out_request, async_data, cancel_event,
&pkt_from_server, &data_from_server);
if (status != RPC_S_OK) return status;
status = RPCRT4_ParseHttpPrepareHeader1(&pkt_from_server, data_from_server,
&field1);
HeapFree(GetProcessHeap(), 0, data_from_server);
if (status != RPC_S_OK) return status;
TRACE("received (%d) from first prepare header\n", field1);
for (;;)
{
status = rpcrt4_http_read_http_packet(out_request, async_data, cancel_event,
&pkt_from_server, &data_from_server);
if (status != RPC_S_OK) return status;
if (pkt_from_server.http.flags != 0x0001) break;
TRACE("http idle packet, waiting for real packet\n");
HeapFree(GetProcessHeap(), 0, data_from_server);
if (pkt_from_server.http.num_data_items != 0)
{
ERR("HTTP idle packet should have no data items instead of %d\n",
pkt_from_server.http.num_data_items);
return RPC_S_PROTOCOL_ERROR;
}
}
status = RPCRT4_ParseHttpPrepareHeader2(&pkt_from_server, data_from_server,
&field1, flow_control_increment,
&field3);
HeapFree(GetProcessHeap(), 0, data_from_server);
if (status != RPC_S_OK) return status;
TRACE("received (0x%08x 0x%08x %d) from second prepare header\n", field1, *flow_control_increment, field3);
return RPC_S_OK;
}
static UINT encode_base64(const char *bin, unsigned int len, WCHAR *base64)
{
static const char enc[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
UINT i = 0, x;
while (len > 0)
{
/* first 6 bits, all from bin[0] */
base64[i++] = enc[(bin[0] & 0xfc) >> 2];
x = (bin[0] & 3) << 4;
/* next 6 bits, 2 from bin[0] and 4 from bin[1] */
if (len == 1)
{
base64[i++] = enc[x];
base64[i++] = '=';
base64[i++] = '=';
break;
}
base64[i++] = enc[x | ((bin[1] & 0xf0) >> 4)];
x = (bin[1] & 0x0f) << 2;
/* next 6 bits 4 from bin[1] and 2 from bin[2] */
if (len == 2)
{
base64[i++] = enc[x];
base64[i++] = '=';
break;
}
base64[i++] = enc[x | ((bin[2] & 0xc0) >> 6)];
/* last 6 bits, all from bin [2] */
base64[i++] = enc[bin[2] & 0x3f];
bin += 3;
len -= 3;
}
base64[i] = 0;
return i;
}
static inline char decode_char( WCHAR c )
{
if (c >= 'A' && c <= 'Z') return c - 'A';
if (c >= 'a' && c <= 'z') return c - 'a' + 26;
if (c >= '0' && c <= '9') return c - '0' + 52;
if (c == '+') return 62;
if (c == '/') return 63;
return 64;
}
static unsigned int decode_base64( const WCHAR *base64, unsigned int len, char *buf )
{
unsigned int i = 0;
char c0, c1, c2, c3;
const WCHAR *p = base64;
while (len > 4)
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
if ((c3 = decode_char( p[3] )) > 63) return 0;
if (buf)
{
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
buf[i + 2] = (c2 << 6) | c3;
}
len -= 4;
i += 3;
p += 4;
}
if (p[2] == '=')
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if (buf) buf[i] = (c0 << 2) | (c1 >> 4);
i++;
}
else if (p[3] == '=')
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
if (buf)
{
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
}
i += 2;
}
else
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
if ((c3 = decode_char( p[3] )) > 63) return 0;
if (buf)
{
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
buf[i + 2] = (c2 << 6) | c3;
}
i += 3;
}
return i;
}
static struct authinfo *alloc_authinfo(void)
{
struct authinfo *ret;
if (!(ret = HeapAlloc(GetProcessHeap(), 0, sizeof(*ret) ))) return NULL;
SecInvalidateHandle(&ret->cred);
SecInvalidateHandle(&ret->ctx);
memset(&ret->exp, 0, sizeof(ret->exp));
ret->scheme = 0;
ret->attr = 0;
ret->max_token = 0;
ret->data = NULL;
ret->data_len = 0;
ret->finished = FALSE;
return ret;
}
static void destroy_authinfo(struct authinfo *info)
{
if (!info) return;
if (SecIsValidHandle(&info->ctx))
DeleteSecurityContext(&info->ctx);
if (SecIsValidHandle(&info->cred))
FreeCredentialsHandle(&info->cred);
HeapFree(GetProcessHeap(), 0, info->data);
HeapFree(GetProcessHeap(), 0, info);
}
static const WCHAR basicW[] = {'B','a','s','i','c',0};
static const WCHAR ntlmW[] = {'N','T','L','M',0};
static const WCHAR passportW[] = {'P','a','s','s','p','o','r','t',0};
static const WCHAR digestW[] = {'D','i','g','e','s','t',0};
static const WCHAR negotiateW[] = {'N','e','g','o','t','i','a','t','e',0};
static const struct
{
const WCHAR *str;
unsigned int len;
DWORD scheme;
}
auth_schemes[] =
{
{ basicW, ARRAY_SIZE(basicW) - 1, RPC_C_HTTP_AUTHN_SCHEME_BASIC },
{ ntlmW, ARRAY_SIZE(ntlmW) - 1, RPC_C_HTTP_AUTHN_SCHEME_NTLM },
{ passportW, ARRAY_SIZE(passportW) - 1, RPC_C_HTTP_AUTHN_SCHEME_PASSPORT },
{ digestW, ARRAY_SIZE(digestW) - 1, RPC_C_HTTP_AUTHN_SCHEME_DIGEST },
{ negotiateW, ARRAY_SIZE(negotiateW) - 1, RPC_C_HTTP_AUTHN_SCHEME_NEGOTIATE }
};
static DWORD auth_scheme_from_header( const WCHAR *header )
{
unsigned int i;
for (i = 0; i < ARRAY_SIZE(auth_schemes); i++)
{
if (!_wcsnicmp( header, auth_schemes[i].str, auth_schemes[i].len ) &&
(header[auth_schemes[i].len] == ' ' || !header[auth_schemes[i].len])) return auth_schemes[i].scheme;
}
return 0;
}
static BOOL get_authvalue(HINTERNET request, DWORD scheme, WCHAR *buffer, DWORD buflen)
{
DWORD len, index = 0;
for (;;)
{
len = buflen;
if (!HttpQueryInfoW(request, HTTP_QUERY_WWW_AUTHENTICATE, buffer, &len, &index)) return FALSE;
if (auth_scheme_from_header(buffer) == scheme) break;
}
return TRUE;
}
static RPC_STATUS do_authorization(HINTERNET request, SEC_WCHAR *servername,
const RPC_HTTP_TRANSPORT_CREDENTIALS_W *creds, struct authinfo **auth_ptr)
{
struct authinfo *info = *auth_ptr;
SEC_WINNT_AUTH_IDENTITY_W *id = creds->TransportCredentials;
RPC_STATUS status = RPC_S_SERVER_UNAVAILABLE;
if ((!info && !(info = alloc_authinfo()))) return RPC_S_SERVER_UNAVAILABLE;
switch (creds->AuthnSchemes[0])
{
case RPC_C_HTTP_AUTHN_SCHEME_BASIC:
{
int userlen = WideCharToMultiByte(CP_UTF8, 0, id->User, id->UserLength, NULL, 0, NULL, NULL);
int passlen = WideCharToMultiByte(CP_UTF8, 0, id->Password, id->PasswordLength, NULL, 0, NULL, NULL);
info->data_len = userlen + passlen + 1;
if (!(info->data = HeapAlloc(GetProcessHeap(), 0, info->data_len)))
{
status = RPC_S_OUT_OF_MEMORY;
break;
}
WideCharToMultiByte(CP_UTF8, 0, id->User, id->UserLength, info->data, userlen, NULL, NULL);
info->data[userlen] = ':';
WideCharToMultiByte(CP_UTF8, 0, id->Password, id->PasswordLength, info->data + userlen + 1, passlen, NULL, NULL);
info->scheme = RPC_C_HTTP_AUTHN_SCHEME_BASIC;
info->finished = TRUE;
status = RPC_S_OK;
break;
}
case RPC_C_HTTP_AUTHN_SCHEME_NTLM:
case RPC_C_HTTP_AUTHN_SCHEME_NEGOTIATE:
{
static SEC_WCHAR ntlmW[] = {'N','T','L','M',0}, negotiateW[] = {'N','e','g','o','t','i','a','t','e',0};
SECURITY_STATUS ret;
SecBufferDesc out_desc, in_desc;
SecBuffer out, in;
ULONG flags = ISC_REQ_CONNECTION|ISC_REQ_USE_DCE_STYLE|ISC_REQ_MUTUAL_AUTH|ISC_REQ_DELEGATE;
SEC_WCHAR *scheme;
int scheme_len;
const WCHAR *p;
WCHAR auth_value[2048];
DWORD size = sizeof(auth_value);
BOOL first = FALSE;
if (creds->AuthnSchemes[0] == RPC_C_HTTP_AUTHN_SCHEME_NTLM) scheme = ntlmW;
else scheme = negotiateW;
scheme_len = lstrlenW( scheme );
if (!*auth_ptr)
{
TimeStamp exp;
SecPkgInfoW *pkg_info;
ret = AcquireCredentialsHandleW(NULL, scheme, SECPKG_CRED_OUTBOUND, NULL, id, NULL, NULL, &info->cred, &exp);
if (ret != SEC_E_OK) break;
ret = QuerySecurityPackageInfoW(scheme, &pkg_info);
if (ret != SEC_E_OK) break;
info->max_token = pkg_info->cbMaxToken;
FreeContextBuffer(pkg_info);
first = TRUE;
}
else
{
if (info->finished || !get_authvalue(request, creds->AuthnSchemes[0], auth_value, size)) break;
if (auth_scheme_from_header(auth_value) != info->scheme)
{
ERR("authentication scheme changed\n");
break;
}
}
in.BufferType = SECBUFFER_TOKEN;
in.cbBuffer = 0;
in.pvBuffer = NULL;
in_desc.ulVersion = 0;
in_desc.cBuffers = 1;
in_desc.pBuffers = &in;
p = auth_value + scheme_len;
if (!first && *p == ' ')
{
int len = lstrlenW(++p);
in.cbBuffer = decode_base64(p, len, NULL);
if (!(in.pvBuffer = HeapAlloc(GetProcessHeap(), 0, in.cbBuffer))) break;
decode_base64(p, len, in.pvBuffer);
}
out.BufferType = SECBUFFER_TOKEN;
out.cbBuffer = info->max_token;
if (!(out.pvBuffer = HeapAlloc(GetProcessHeap(), 0, out.cbBuffer)))
{
HeapFree(GetProcessHeap(), 0, in.pvBuffer);
break;
}
out_desc.ulVersion = 0;
out_desc.cBuffers = 1;
out_desc.pBuffers = &out;
ret = InitializeSecurityContextW(first ? &info->cred : NULL, first ? NULL : &info->ctx,
first ? servername : NULL, flags, 0, SECURITY_NETWORK_DREP,
in.pvBuffer ? &in_desc : NULL, 0, &info->ctx, &out_desc,
&info->attr, &info->exp);
HeapFree(GetProcessHeap(), 0, in.pvBuffer);
if (ret == SEC_E_OK)
{
HeapFree(GetProcessHeap(), 0, info->data);
info->data = out.pvBuffer;
info->data_len = out.cbBuffer;
info->finished = TRUE;
TRACE("sending last auth packet\n");
status = RPC_S_OK;
}
else if (ret == SEC_I_CONTINUE_NEEDED)
{
HeapFree(GetProcessHeap(), 0, info->data);
info->data = out.pvBuffer;
info->data_len = out.cbBuffer;
TRACE("sending next auth packet\n");
status = RPC_S_OK;
}
else
{
ERR("InitializeSecurityContextW failed with error 0x%08x\n", ret);
HeapFree(GetProcessHeap(), 0, out.pvBuffer);
break;
}
info->scheme = creds->AuthnSchemes[0];
break;
}
default:
FIXME("scheme %u not supported\n", creds->AuthnSchemes[0]);
break;
}
if (status != RPC_S_OK)
{
destroy_authinfo(info);
*auth_ptr = NULL;
return status;
}
*auth_ptr = info;
return RPC_S_OK;
}
static RPC_STATUS insert_authorization_header(HINTERNET request, ULONG scheme, char *data, int data_len)
{
static const WCHAR authW[] = {'A','u','t','h','o','r','i','z','a','t','i','o','n',':',' '};
static const WCHAR basicW[] = {'B','a','s','i','c',' '};
static const WCHAR negotiateW[] = {'N','e','g','o','t','i','a','t','e',' '};
static const WCHAR ntlmW[] = {'N','T','L','M',' '};
int scheme_len, auth_len = ARRAY_SIZE(authW), len = ((data_len + 2) * 4) / 3;
const WCHAR *scheme_str;
WCHAR *header, *ptr;
RPC_STATUS status = RPC_S_SERVER_UNAVAILABLE;
switch (scheme)
{
case RPC_C_HTTP_AUTHN_SCHEME_BASIC:
scheme_str = basicW;
scheme_len = ARRAY_SIZE(basicW);
break;
case RPC_C_HTTP_AUTHN_SCHEME_NEGOTIATE:
scheme_str = negotiateW;
scheme_len = ARRAY_SIZE(negotiateW);
break;
case RPC_C_HTTP_AUTHN_SCHEME_NTLM:
scheme_str = ntlmW;
scheme_len = ARRAY_SIZE(ntlmW);
break;
default:
ERR("unknown scheme %u\n", scheme);
return RPC_S_SERVER_UNAVAILABLE;
}
if ((header = HeapAlloc(GetProcessHeap(), 0, (auth_len + scheme_len + len + 2) * sizeof(WCHAR))))
{
memcpy(header, authW, auth_len * sizeof(WCHAR));
ptr = header + auth_len;
memcpy(ptr, scheme_str, scheme_len * sizeof(WCHAR));
ptr += scheme_len;
len = encode_base64(data, data_len, ptr);
ptr[len++] = '\r';
ptr[len++] = '\n';
ptr[len] = 0;
if (HttpAddRequestHeadersW(request, header, -1, HTTP_ADDREQ_FLAG_ADD|HTTP_ADDREQ_FLAG_REPLACE))
status = RPC_S_OK;
HeapFree(GetProcessHeap(), 0, header);
}
return status;
}
static void drain_content(HINTERNET request, RpcHttpAsyncData *async_data, HANDLE cancel_event)
{
DWORD count, len = 0, size = sizeof(len);
char buf[2048];
HttpQueryInfoW(request, HTTP_QUERY_FLAG_NUMBER|HTTP_QUERY_CONTENT_LENGTH, &len, &size, NULL);
if (!len) return;
for (;;)
{
count = min(sizeof(buf), len);
if (rpcrt4_http_async_read(request, async_data, cancel_event, buf, count) <= 0) return;
len -= count;
}
}
static RPC_STATUS authorize_request(RpcConnection_http *httpc, HINTERNET request)
{
static const WCHAR authW[] = {'A','u','t','h','o','r','i','z','a','t','i','o','n',':','\r','\n',0};
struct authinfo *info = NULL;
RPC_STATUS status;
BOOL ret;
for (;;)
{
status = do_authorization(request, httpc->servername, httpc->common.QOS->qos->u.HttpCredentials, &info);
if (status != RPC_S_OK) break;
status = insert_authorization_header(request, info->scheme, info->data, info->data_len);
if (status != RPC_S_OK) break;
prepare_async_request(httpc->async_data);
ret = HttpSendRequestW(request, NULL, 0, NULL, 0);
status = wait_async_request(httpc->async_data, ret, httpc->cancel_event);
if (status != RPC_S_OK || info->finished) break;
status = rpcrt4_http_check_response(request);
if (status != RPC_S_OK && status != ERROR_ACCESS_DENIED) break;
drain_content(request, httpc->async_data, httpc->cancel_event);
}
if (info->scheme != RPC_C_HTTP_AUTHN_SCHEME_BASIC)
HttpAddRequestHeadersW(request, authW, -1, HTTP_ADDREQ_FLAG_REPLACE | HTTP_ADDREQ_FLAG_ADD);
destroy_authinfo(info);
return status;
}
static BOOL has_credentials(RpcConnection_http *httpc)
{
RPC_HTTP_TRANSPORT_CREDENTIALS_W *creds;
SEC_WINNT_AUTH_IDENTITY_W *id;
if (!httpc->common.QOS || httpc->common.QOS->qos->AdditionalSecurityInfoType != RPC_C_AUTHN_INFO_TYPE_HTTP)
return FALSE;
creds = httpc->common.QOS->qos->u.HttpCredentials;
if (creds->AuthenticationTarget != RPC_C_HTTP_AUTHN_TARGET_SERVER || !creds->NumberOfAuthnSchemes)
return FALSE;
id = creds->TransportCredentials;
if (!id || !id->User || !id->Password) return FALSE;
return TRUE;
}
static BOOL is_secure(RpcConnection_http *httpc)
{
return httpc->common.QOS &&
(httpc->common.QOS->qos->AdditionalSecurityInfoType == RPC_C_AUTHN_INFO_TYPE_HTTP) &&
(httpc->common.QOS->qos->u.HttpCredentials->Flags & RPC_C_HTTP_FLAG_USE_SSL);
}
static RPC_STATUS set_auth_cookie(RpcConnection_http *httpc, const WCHAR *value)
{
static WCHAR httpW[] = {'h','t','t','p',0};
static WCHAR httpsW[] = {'h','t','t','p','s',0};
URL_COMPONENTSW uc;
DWORD len;
WCHAR *url;
BOOL ret;
if (!value) return RPC_S_OK;
uc.dwStructSize = sizeof(uc);
uc.lpszScheme = is_secure(httpc) ? httpsW : httpW;
uc.dwSchemeLength = 0;
uc.lpszHostName = httpc->servername;
uc.dwHostNameLength = 0;
uc.nPort = 0;
uc.lpszUserName = NULL;
uc.dwUserNameLength = 0;
uc.lpszPassword = NULL;
uc.dwPasswordLength = 0;
uc.lpszUrlPath = NULL;
uc.dwUrlPathLength = 0;
uc.lpszExtraInfo = NULL;
uc.dwExtraInfoLength = 0;
if (!InternetCreateUrlW(&uc, 0, NULL, &len) && (GetLastError() != ERROR_INSUFFICIENT_BUFFER))
return RPC_S_SERVER_UNAVAILABLE;
if (!(url = HeapAlloc(GetProcessHeap(), 0, len))) return RPC_S_OUT_OF_MEMORY;
len = len / sizeof(WCHAR) - 1;
if (!InternetCreateUrlW(&uc, 0, url, &len))
{
HeapFree(GetProcessHeap(), 0, url);
return RPC_S_SERVER_UNAVAILABLE;
}
ret = InternetSetCookieW(url, NULL, value);
HeapFree(GetProcessHeap(), 0, url);
if (!ret) return RPC_S_SERVER_UNAVAILABLE;
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_ncacn_http_open(RpcConnection* Connection)
{
RpcConnection_http *httpc = (RpcConnection_http *)Connection;
static const WCHAR wszVerbIn[] = {'R','P','C','_','I','N','_','D','A','T','A',0};
static const WCHAR wszVerbOut[] = {'R','P','C','_','O','U','T','_','D','A','T','A',0};
static const WCHAR wszRpcProxyPrefix[] = {'/','r','p','c','/','r','p','c','p','r','o','x','y','.','d','l','l','?',0};
static const WCHAR wszColon[] = {':',0};
static const WCHAR wszAcceptType[] = {'a','p','p','l','i','c','a','t','i','o','n','/','r','p','c',0};
LPCWSTR wszAcceptTypes[] = { wszAcceptType, NULL };
DWORD flags;
WCHAR *url;
RPC_STATUS status;
BOOL secure, credentials;
HttpTimerThreadData *timer_data;
HANDLE thread;
TRACE("(%s, %s)\n", Connection->NetworkAddr, Connection->Endpoint);
if (Connection->server)
{
ERR("ncacn_http servers not supported yet\n");
return RPC_S_SERVER_UNAVAILABLE;
}
if (httpc->in_request)
return RPC_S_OK;
httpc->async_data->completion_event = CreateEventW(NULL, FALSE, FALSE, NULL);
UuidCreate(&httpc->connection_uuid);
UuidCreate(&httpc->in_pipe_uuid);
UuidCreate(&httpc->out_pipe_uuid);
status = rpcrt4_http_internet_connect(httpc);
if (status != RPC_S_OK)
return status;
url = HeapAlloc(GetProcessHeap(), 0, sizeof(wszRpcProxyPrefix) + (strlen(Connection->NetworkAddr) + 1 + strlen(Connection->Endpoint))*sizeof(WCHAR));
if (!url)
return RPC_S_OUT_OF_MEMORY;
memcpy(url, wszRpcProxyPrefix, sizeof(wszRpcProxyPrefix));
MultiByteToWideChar(CP_ACP, 0, Connection->NetworkAddr, -1, url+ARRAY_SIZE(wszRpcProxyPrefix)-1,
strlen(Connection->NetworkAddr)+1);
lstrcatW(url, wszColon);
MultiByteToWideChar(CP_ACP, 0, Connection->Endpoint, -1, url+lstrlenW(url), strlen(Connection->Endpoint)+1);
secure = is_secure(httpc);
credentials = has_credentials(httpc);
flags = INTERNET_FLAG_KEEP_CONNECTION | INTERNET_FLAG_PRAGMA_NOCACHE | INTERNET_FLAG_NO_CACHE_WRITE |
INTERNET_FLAG_NO_AUTO_REDIRECT;
if (secure) flags |= INTERNET_FLAG_SECURE;
if (credentials) flags |= INTERNET_FLAG_NO_AUTH;
status = set_auth_cookie(httpc, Connection->CookieAuth);
if (status != RPC_S_OK)
{
HeapFree(GetProcessHeap(), 0, url);
return status;
}
httpc->in_request = HttpOpenRequestW(httpc->session, wszVerbIn, url, NULL, NULL, wszAcceptTypes,
flags, (DWORD_PTR)httpc->async_data);
if (!httpc->in_request)
{
ERR("HttpOpenRequestW failed with error %d\n", GetLastError());
HeapFree(GetProcessHeap(), 0, url);
return RPC_S_SERVER_UNAVAILABLE;
}
if (credentials)
{
status = authorize_request(httpc, httpc->in_request);
if (status != RPC_S_OK)
{
HeapFree(GetProcessHeap(), 0, url);
return status;
}
status = rpcrt4_http_check_response(httpc->in_request);
if (status != RPC_S_OK)
{
HeapFree(GetProcessHeap(), 0, url);
return status;
}
drain_content(httpc->in_request, httpc->async_data, httpc->cancel_event);
}
httpc->out_request = HttpOpenRequestW(httpc->session, wszVerbOut, url, NULL, NULL, wszAcceptTypes,
flags, (DWORD_PTR)httpc->async_data);
HeapFree(GetProcessHeap(), 0, url);
if (!httpc->out_request)
{
ERR("HttpOpenRequestW failed with error %d\n", GetLastError());
return RPC_S_SERVER_UNAVAILABLE;
}
if (credentials)
{
status = authorize_request(httpc, httpc->out_request);
if (status != RPC_S_OK)
return status;
}
status = rpcrt4_http_prepare_in_pipe(httpc->in_request, httpc->async_data, httpc->cancel_event,
&httpc->connection_uuid, &httpc->in_pipe_uuid,
&Connection->assoc->http_uuid, credentials);
if (status != RPC_S_OK)
return status;
status = rpcrt4_http_prepare_out_pipe(httpc->out_request, httpc->async_data, httpc->cancel_event,
&httpc->connection_uuid, &httpc->out_pipe_uuid,
&httpc->flow_control_increment, credentials);
if (status != RPC_S_OK)
return status;
httpc->flow_control_mark = httpc->flow_control_increment / 2;
httpc->last_sent_time = GetTickCount();
httpc->timer_cancelled = CreateEventW(NULL, FALSE, FALSE, NULL);
timer_data = HeapAlloc(GetProcessHeap(), 0, sizeof(*timer_data));
if (!timer_data)
return ERROR_OUTOFMEMORY;
timer_data->timer_param = httpc->in_request;
timer_data->last_sent_time = &httpc->last_sent_time;
timer_data->timer_cancelled = httpc->timer_cancelled;
/* FIXME: should use CreateTimerQueueTimer when implemented */
thread = CreateThread(NULL, 0, rpcrt4_http_timer_thread, timer_data, 0, NULL);
if (!thread)
{
HeapFree(GetProcessHeap(), 0, timer_data);
return GetLastError();
}
CloseHandle(thread);
return RPC_S_OK;
}
static RPC_STATUS rpcrt4_ncacn_http_handoff(RpcConnection *old_conn, RpcConnection *new_conn)
{
assert(0);
return RPC_S_SERVER_UNAVAILABLE;
}
static int rpcrt4_ncacn_http_read(RpcConnection *Connection,
void *buffer, unsigned int count)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
return rpcrt4_http_async_read(httpc->out_request, httpc->async_data, httpc->cancel_event, buffer, count);
}
static RPC_STATUS rpcrt4_ncacn_http_receive_fragment(RpcConnection *Connection, RpcPktHdr **Header, void **Payload)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
RPC_STATUS status;
DWORD hdr_length;
LONG dwRead;
RpcPktCommonHdr common_hdr;
*Header = NULL;
TRACE("(%p, %p, %p)\n", Connection, Header, Payload);
again:
/* read packet common header */
dwRead = rpcrt4_ncacn_http_read(Connection, &common_hdr, sizeof(common_hdr));
if (dwRead != sizeof(common_hdr)) {
WARN("Short read of header, %d bytes\n", dwRead);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
if (!memcmp(&common_hdr, "HTTP/1.1", sizeof("HTTP/1.1")) ||
!memcmp(&common_hdr, "HTTP/1.0", sizeof("HTTP/1.0")))
{
FIXME("server returned %s\n", debugstr_a((const char *)&common_hdr));
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
status = RPCRT4_ValidateCommonHeader(&common_hdr);
if (status != RPC_S_OK) goto fail;
hdr_length = RPCRT4_GetHeaderSize((RpcPktHdr*)&common_hdr);
if (hdr_length == 0) {
WARN("header length == 0\n");
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
*Header = HeapAlloc(GetProcessHeap(), 0, hdr_length);
if (!*Header)
{
status = RPC_S_OUT_OF_RESOURCES;
goto fail;
}
memcpy(*Header, &common_hdr, sizeof(common_hdr));
/* read the rest of packet header */
dwRead = rpcrt4_ncacn_http_read(Connection, &(*Header)->common + 1, hdr_length - sizeof(common_hdr));
if (dwRead != hdr_length - sizeof(common_hdr)) {
WARN("bad header length, %d bytes, hdr_length %d\n", dwRead, hdr_length);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
if (common_hdr.frag_len - hdr_length)
{
*Payload = HeapAlloc(GetProcessHeap(), 0, common_hdr.frag_len - hdr_length);
if (!*Payload)
{
status = RPC_S_OUT_OF_RESOURCES;
goto fail;
}
dwRead = rpcrt4_ncacn_http_read(Connection, *Payload, common_hdr.frag_len - hdr_length);
if (dwRead != common_hdr.frag_len - hdr_length)
{
WARN("bad data length, %d/%d\n", dwRead, common_hdr.frag_len - hdr_length);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
}
else
*Payload = NULL;
if ((*Header)->common.ptype == PKT_HTTP)
{
if (!RPCRT4_IsValidHttpPacket(*Header, *Payload, common_hdr.frag_len - hdr_length))
{
ERR("invalid http packet of length %d bytes\n", (*Header)->common.frag_len);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
if ((*Header)->http.flags == 0x0001)
{
TRACE("http idle packet, waiting for real packet\n");
if ((*Header)->http.num_data_items != 0)
{
ERR("HTTP idle packet should have no data items instead of %d\n", (*Header)->http.num_data_items);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
}
else if ((*Header)->http.flags == 0x0002)
{
ULONG bytes_transmitted;
ULONG flow_control_increment;
UUID pipe_uuid;
status = RPCRT4_ParseHttpFlowControlHeader(*Header, *Payload,
Connection->server,
&bytes_transmitted,
&flow_control_increment,
&pipe_uuid);
if (status != RPC_S_OK)
goto fail;
TRACE("received http flow control header (0x%x, 0x%x, %s)\n",
bytes_transmitted, flow_control_increment, debugstr_guid(&pipe_uuid));
/* FIXME: do something with parsed data */
}
else
{
FIXME("unrecognised http packet with flags 0x%04x\n", (*Header)->http.flags);
status = RPC_S_PROTOCOL_ERROR;
goto fail;
}
RPCRT4_FreeHeader(*Header);
*Header = NULL;
HeapFree(GetProcessHeap(), 0, *Payload);
*Payload = NULL;
goto again;
}
/* success */
status = RPC_S_OK;
httpc->bytes_received += common_hdr.frag_len;
TRACE("httpc->bytes_received = 0x%x\n", httpc->bytes_received);
if (httpc->bytes_received > httpc->flow_control_mark)
{
RpcPktHdr *hdr = RPCRT4_BuildHttpFlowControlHeader(httpc->common.server,
httpc->bytes_received,
httpc->flow_control_increment,
&httpc->out_pipe_uuid);
if (hdr)
{
DWORD bytes_written;
BOOL ret2;
TRACE("sending flow control packet at 0x%x\n", httpc->bytes_received);
ret2 = InternetWriteFile(httpc->in_request, hdr, hdr->common.frag_len, &bytes_written);
RPCRT4_FreeHeader(hdr);
if (ret2)
httpc->flow_control_mark = httpc->bytes_received + httpc->flow_control_increment / 2;
}
}
fail:
if (status != RPC_S_OK) {
RPCRT4_FreeHeader(*Header);
*Header = NULL;
HeapFree(GetProcessHeap(), 0, *Payload);
*Payload = NULL;
}
return status;
}
static int rpcrt4_ncacn_http_write(RpcConnection *Connection,
const void *buffer, unsigned int count)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
DWORD bytes_written;
BOOL ret;
httpc->last_sent_time = ~0U; /* disable idle packet sending */
ret = InternetWriteFile(httpc->in_request, buffer, count, &bytes_written);
httpc->last_sent_time = GetTickCount();
TRACE("%p %p %u -> %s\n", httpc->in_request, buffer, count, ret ? "TRUE" : "FALSE");
return ret ? bytes_written : -1;
}
static int rpcrt4_ncacn_http_close(RpcConnection *Connection)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
TRACE("\n");
SetEvent(httpc->timer_cancelled);
if (httpc->in_request)
InternetCloseHandle(httpc->in_request);
httpc->in_request = NULL;
if (httpc->out_request)
InternetCloseHandle(httpc->out_request);
httpc->out_request = NULL;
if (httpc->app_info)
InternetCloseHandle(httpc->app_info);
httpc->app_info = NULL;
if (httpc->session)
InternetCloseHandle(httpc->session);
httpc->session = NULL;
RpcHttpAsyncData_Release(httpc->async_data);
if (httpc->cancel_event)
CloseHandle(httpc->cancel_event);
HeapFree(GetProcessHeap(), 0, httpc->servername);
httpc->servername = NULL;
return 0;
}
static void rpcrt4_ncacn_http_close_read(RpcConnection *conn)
{
rpcrt4_ncacn_http_close(conn); /* FIXME */
}
static void rpcrt4_ncacn_http_cancel_call(RpcConnection *Connection)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
SetEvent(httpc->cancel_event);
}
static RPC_STATUS rpcrt4_ncacn_http_is_server_listening(const char *endpoint)
{
FIXME("\n");
return RPC_S_ACCESS_DENIED;
}
static int rpcrt4_ncacn_http_wait_for_incoming_data(RpcConnection *Connection)
{
RpcConnection_http *httpc = (RpcConnection_http *) Connection;
BOOL ret;
RPC_STATUS status;
prepare_async_request(httpc->async_data);
ret = InternetQueryDataAvailable(httpc->out_request,
&httpc->async_data->inet_buffers.dwBufferLength, IRF_ASYNC, 0);
status = wait_async_request(httpc->async_data, ret, httpc->cancel_event);
return status == RPC_S_OK ? 0 : -1;
}
static size_t rpcrt4_ncacn_http_get_top_of_tower(unsigned char *tower_data,
const char *networkaddr,
const char *endpoint)
{
return rpcrt4_ip_tcp_get_top_of_tower(tower_data, networkaddr,
EPM_PROTOCOL_HTTP, endpoint);
}
static RPC_STATUS rpcrt4_ncacn_http_parse_top_of_tower(const unsigned char *tower_data,
size_t tower_size,
char **networkaddr,
char **endpoint)
{
return rpcrt4_ip_tcp_parse_top_of_tower(tower_data, tower_size,
networkaddr, EPM_PROTOCOL_HTTP,
endpoint);
}
static const struct connection_ops conn_protseq_list[] = {
{ "ncacn_np",
{ EPM_PROTOCOL_NCACN, EPM_PROTOCOL_SMB },
rpcrt4_conn_np_alloc,
rpcrt4_ncacn_np_open,
rpcrt4_ncacn_np_handoff,
rpcrt4_conn_np_read,
rpcrt4_conn_np_write,
rpcrt4_conn_np_close,
rpcrt4_conn_np_close_read,
rpcrt4_conn_np_cancel_call,
rpcrt4_ncacn_np_is_server_listening,
rpcrt4_conn_np_wait_for_incoming_data,
rpcrt4_ncacn_np_get_top_of_tower,
rpcrt4_ncacn_np_parse_top_of_tower,
NULL,
RPCRT4_default_is_authorized,
RPCRT4_default_authorize,
RPCRT4_default_secure_packet,
rpcrt4_conn_np_impersonate_client,
rpcrt4_conn_np_revert_to_self,
RPCRT4_default_inquire_auth_client,
},
{ "ncalrpc",
{ EPM_PROTOCOL_NCALRPC, EPM_PROTOCOL_PIPE },
rpcrt4_conn_np_alloc,
rpcrt4_ncalrpc_open,
rpcrt4_ncalrpc_handoff,
rpcrt4_conn_np_read,
rpcrt4_conn_np_write,
rpcrt4_conn_np_close,
rpcrt4_conn_np_close_read,
rpcrt4_conn_np_cancel_call,
rpcrt4_ncalrpc_np_is_server_listening,
rpcrt4_conn_np_wait_for_incoming_data,
rpcrt4_ncalrpc_get_top_of_tower,
rpcrt4_ncalrpc_parse_top_of_tower,
NULL,
rpcrt4_ncalrpc_is_authorized,
rpcrt4_ncalrpc_authorize,
rpcrt4_ncalrpc_secure_packet,
rpcrt4_conn_np_impersonate_client,
rpcrt4_conn_np_revert_to_self,
rpcrt4_ncalrpc_inquire_auth_client,
},
{ "ncacn_ip_tcp",
{ EPM_PROTOCOL_NCACN, EPM_PROTOCOL_TCP },
rpcrt4_conn_tcp_alloc,
rpcrt4_ncacn_ip_tcp_open,
rpcrt4_conn_tcp_handoff,
rpcrt4_conn_tcp_read,
rpcrt4_conn_tcp_write,
rpcrt4_conn_tcp_close,
rpcrt4_conn_tcp_close_read,
rpcrt4_conn_tcp_cancel_call,
rpcrt4_conn_tcp_is_server_listening,
rpcrt4_conn_tcp_wait_for_incoming_data,
rpcrt4_ncacn_ip_tcp_get_top_of_tower,
rpcrt4_ncacn_ip_tcp_parse_top_of_tower,
NULL,
RPCRT4_default_is_authorized,
RPCRT4_default_authorize,
RPCRT4_default_secure_packet,
RPCRT4_default_impersonate_client,
RPCRT4_default_revert_to_self,
RPCRT4_default_inquire_auth_client,
},
{ "ncacn_http",
{ EPM_PROTOCOL_NCACN, EPM_PROTOCOL_HTTP },
rpcrt4_ncacn_http_alloc,
rpcrt4_ncacn_http_open,
rpcrt4_ncacn_http_handoff,
rpcrt4_ncacn_http_read,
rpcrt4_ncacn_http_write,
rpcrt4_ncacn_http_close,
rpcrt4_ncacn_http_close_read,
rpcrt4_ncacn_http_cancel_call,
rpcrt4_ncacn_http_is_server_listening,
rpcrt4_ncacn_http_wait_for_incoming_data,
rpcrt4_ncacn_http_get_top_of_tower,
rpcrt4_ncacn_http_parse_top_of_tower,
rpcrt4_ncacn_http_receive_fragment,
RPCRT4_default_is_authorized,
RPCRT4_default_authorize,
RPCRT4_default_secure_packet,
RPCRT4_default_impersonate_client,
RPCRT4_default_revert_to_self,
RPCRT4_default_inquire_auth_client,
},
};
static const struct protseq_ops protseq_list[] =
{
{
"ncacn_np",
rpcrt4_protseq_np_alloc,
rpcrt4_protseq_np_signal_state_changed,
rpcrt4_protseq_np_get_wait_array,
rpcrt4_protseq_np_free_wait_array,
rpcrt4_protseq_np_wait_for_new_connection,
rpcrt4_protseq_ncacn_np_open_endpoint,
},
{
"ncalrpc",
rpcrt4_protseq_np_alloc,
rpcrt4_protseq_np_signal_state_changed,
rpcrt4_protseq_np_get_wait_array,
rpcrt4_protseq_np_free_wait_array,
rpcrt4_protseq_np_wait_for_new_connection,
rpcrt4_protseq_ncalrpc_open_endpoint,
},
{
"ncacn_ip_tcp",
rpcrt4_protseq_sock_alloc,
rpcrt4_protseq_sock_signal_state_changed,
rpcrt4_protseq_sock_get_wait_array,
rpcrt4_protseq_sock_free_wait_array,
rpcrt4_protseq_sock_wait_for_new_connection,
rpcrt4_protseq_ncacn_ip_tcp_open_endpoint,
},
};
const struct protseq_ops *rpcrt4_get_protseq_ops(const char *protseq)
{
unsigned int i;
for(i = 0; i < ARRAY_SIZE(protseq_list); i++)
if (!strcmp(protseq_list[i].name, protseq))
return &protseq_list[i];
return NULL;
}
static const struct connection_ops *rpcrt4_get_conn_protseq_ops(const char *protseq)
{
unsigned int i;
for(i = 0; i < ARRAY_SIZE(conn_protseq_list); i++)
if (!strcmp(conn_protseq_list[i].name, protseq))
return &conn_protseq_list[i];
return NULL;
}
/**** interface to rest of code ****/
RPC_STATUS RPCRT4_OpenClientConnection(RpcConnection* Connection)
{
TRACE("(Connection == ^%p)\n", Connection);
assert(!Connection->server);
return Connection->ops->open_connection_client(Connection);
}
RPC_STATUS RPCRT4_CloseConnection(RpcConnection* Connection)
{
TRACE("(Connection == ^%p)\n", Connection);
if (SecIsValidHandle(&Connection->ctx))
{
DeleteSecurityContext(&Connection->ctx);
SecInvalidateHandle(&Connection->ctx);
}
rpcrt4_conn_close(Connection);
return RPC_S_OK;
}
RPC_STATUS RPCRT4_CreateConnection(RpcConnection** Connection, BOOL server,
LPCSTR Protseq, LPCSTR NetworkAddr, LPCSTR Endpoint,
LPCWSTR NetworkOptions, RpcAuthInfo* AuthInfo, RpcQualityOfService *QOS, LPCWSTR CookieAuth)
{
static LONG next_id;
const struct connection_ops *ops;
RpcConnection* NewConnection;
ops = rpcrt4_get_conn_protseq_ops(Protseq);
if (!ops)
{
FIXME("not supported for protseq %s\n", Protseq);
return RPC_S_PROTSEQ_NOT_SUPPORTED;
}
NewConnection = ops->alloc();
NewConnection->ref = 1;
NewConnection->server = server;
NewConnection->ops = ops;
NewConnection->NetworkAddr = RPCRT4_strdupA(NetworkAddr);
NewConnection->Endpoint = RPCRT4_strdupA(Endpoint);
NewConnection->NetworkOptions = RPCRT4_strdupW(NetworkOptions);
NewConnection->CookieAuth = RPCRT4_strdupW(CookieAuth);
NewConnection->MaxTransmissionSize = RPC_MAX_PACKET_SIZE;
NewConnection->NextCallId = 1;
SecInvalidateHandle(&NewConnection->ctx);
if (AuthInfo) RpcAuthInfo_AddRef(AuthInfo);
NewConnection->AuthInfo = AuthInfo;
NewConnection->auth_context_id = InterlockedIncrement( &next_id );
if (QOS) RpcQualityOfService_AddRef(QOS);
NewConnection->QOS = QOS;
list_init(&NewConnection->conn_pool_entry);
list_init(&NewConnection->protseq_entry);
TRACE("connection: %p\n", NewConnection);
*Connection = NewConnection;
return RPC_S_OK;
}
static RpcConnection *rpcrt4_spawn_connection(RpcConnection *old_connection)
{
RpcConnection *connection;
RPC_STATUS err;
err = RPCRT4_CreateConnection(&connection, old_connection->server, rpcrt4_conn_get_name(old_connection),
old_connection->NetworkAddr, old_connection->Endpoint, NULL,
old_connection->AuthInfo, old_connection->QOS, old_connection->CookieAuth);
if (err != RPC_S_OK)
return NULL;
rpcrt4_conn_handoff(old_connection, connection);
if (old_connection->protseq)
{
EnterCriticalSection(&old_connection->protseq->cs);
connection->protseq = old_connection->protseq;
list_add_tail(&old_connection->protseq->connections, &connection->protseq_entry);
LeaveCriticalSection(&old_connection->protseq->cs);
}
return connection;
}
void rpcrt4_conn_release_and_wait(RpcConnection *connection)
{
HANDLE event = NULL;
if (connection->ref > 1)
event = connection->wait_release = CreateEventW(NULL, TRUE, FALSE, NULL);
RPCRT4_ReleaseConnection(connection);
if(event)
{
WaitForSingleObject(event, INFINITE);
CloseHandle(event);
}
}
RpcConnection *RPCRT4_GrabConnection(RpcConnection *connection)
{
LONG ref = InterlockedIncrement(&connection->ref);
TRACE("%p ref=%u\n", connection, ref);
return connection;
}
void RPCRT4_ReleaseConnection(RpcConnection *connection)
{
LONG ref;
/* protseq stores a list of active connections, but does not own references to them.
* It may need to grab a connection from the list, which could lead to a race if
* connection is being released, but not yet removed from the list. We handle that
* by synchronizing on CS here. */
if (connection->protseq)
{
EnterCriticalSection(&connection->protseq->cs);
ref = InterlockedDecrement(&connection->ref);
if (!ref)
list_remove(&connection->protseq_entry);
LeaveCriticalSection(&connection->protseq->cs);
}
else
{
ref = InterlockedDecrement(&connection->ref);
}
TRACE("%p ref=%u\n", connection, ref);
if (!ref)
{
RPCRT4_CloseConnection(connection);
RPCRT4_strfree(connection->Endpoint);
RPCRT4_strfree(connection->NetworkAddr);
HeapFree(GetProcessHeap(), 0, connection->NetworkOptions);
HeapFree(GetProcessHeap(), 0, connection->CookieAuth);
if (connection->AuthInfo) RpcAuthInfo_Release(connection->AuthInfo);
if (connection->QOS) RpcQualityOfService_Release(connection->QOS);
/* server-only */
if (connection->server_binding) RPCRT4_ReleaseBinding(connection->server_binding);
else if (connection->assoc) RpcAssoc_ConnectionReleased(connection->assoc);
if (connection->wait_release) SetEvent(connection->wait_release);
HeapFree(GetProcessHeap(), 0, connection);
}
}
RPC_STATUS RPCRT4_IsServerListening(const char *protseq, const char *endpoint)
{
const struct connection_ops *ops;
ops = rpcrt4_get_conn_protseq_ops(protseq);
if (!ops)
{
FIXME("not supported for protseq %s\n", protseq);
return RPC_S_INVALID_BINDING;
}
return ops->is_server_listening(endpoint);
}
RPC_STATUS RpcTransport_GetTopOfTower(unsigned char *tower_data,
size_t *tower_size,
const char *protseq,
const char *networkaddr,
const char *endpoint)
{
twr_empty_floor_t *protocol_floor;
const struct connection_ops *protseq_ops = rpcrt4_get_conn_protseq_ops(protseq);
*tower_size = 0;
if (!protseq_ops)
return RPC_S_INVALID_RPC_PROTSEQ;
if (!tower_data)
{
*tower_size = sizeof(*protocol_floor);
*tower_size += protseq_ops->get_top_of_tower(NULL, networkaddr, endpoint);
return RPC_S_OK;
}
protocol_floor = (twr_empty_floor_t *)tower_data;
protocol_floor->count_lhs = sizeof(protocol_floor->protid);
protocol_floor->protid = protseq_ops->epm_protocols[0];
protocol_floor->count_rhs = 0;
tower_data += sizeof(*protocol_floor);
*tower_size = protseq_ops->get_top_of_tower(tower_data, networkaddr, endpoint);
if (!*tower_size)
return EPT_S_NOT_REGISTERED;
*tower_size += sizeof(*protocol_floor);
return RPC_S_OK;
}
RPC_STATUS RpcTransport_ParseTopOfTower(const unsigned char *tower_data,
size_t tower_size,
char **protseq,
char **networkaddr,
char **endpoint)
{
const twr_empty_floor_t *protocol_floor;
const twr_empty_floor_t *floor4;
const struct connection_ops *protseq_ops = NULL;
RPC_STATUS status;
unsigned int i;
if (tower_size < sizeof(*protocol_floor))
return EPT_S_NOT_REGISTERED;
protocol_floor = (const twr_empty_floor_t *)tower_data;
tower_data += sizeof(*protocol_floor);
tower_size -= sizeof(*protocol_floor);
if ((protocol_floor->count_lhs != sizeof(protocol_floor->protid)) ||
(protocol_floor->count_rhs > tower_size))
return EPT_S_NOT_REGISTERED;
tower_data += protocol_floor->count_rhs;
tower_size -= protocol_floor->count_rhs;
floor4 = (const twr_empty_floor_t *)tower_data;
if ((tower_size < sizeof(*floor4)) ||
(floor4->count_lhs != sizeof(floor4->protid)))
return EPT_S_NOT_REGISTERED;
for(i = 0; i < ARRAY_SIZE(conn_protseq_list); i++)
if ((protocol_floor->protid == conn_protseq_list[i].epm_protocols[0]) &&
(floor4->protid == conn_protseq_list[i].epm_protocols[1]))
{
protseq_ops = &conn_protseq_list[i];
break;
}
if (!protseq_ops)
return EPT_S_NOT_REGISTERED;
status = protseq_ops->parse_top_of_tower(tower_data, tower_size, networkaddr, endpoint);
if ((status == RPC_S_OK) && protseq)
{
*protseq = I_RpcAllocate(strlen(protseq_ops->name) + 1);
strcpy(*protseq, protseq_ops->name);
}
return status;
}
/***********************************************************************
* RpcNetworkIsProtseqValidW (RPCRT4.@)
*
* Checks if the given protocol sequence is known by the RPC system.
* If it is, returns RPC_S_OK, otherwise RPC_S_PROTSEQ_NOT_SUPPORTED.
*
*/
RPC_STATUS WINAPI RpcNetworkIsProtseqValidW(RPC_WSTR protseq)
{
char ps[0x10];
WideCharToMultiByte(CP_ACP, 0, protseq, -1,
ps, sizeof ps, NULL, NULL);
if (rpcrt4_get_conn_protseq_ops(ps))
return RPC_S_OK;
FIXME("Unknown protseq %s\n", debugstr_w(protseq));
return RPC_S_INVALID_RPC_PROTSEQ;
}
/***********************************************************************
* RpcNetworkIsProtseqValidA (RPCRT4.@)
*/
RPC_STATUS WINAPI RpcNetworkIsProtseqValidA(RPC_CSTR protseq)
{
UNICODE_STRING protseqW;
if (RtlCreateUnicodeStringFromAsciiz(&protseqW, (char*)protseq))
{
RPC_STATUS ret = RpcNetworkIsProtseqValidW(protseqW.Buffer);
RtlFreeUnicodeString(&protseqW);
return ret;
}
return RPC_S_OUT_OF_MEMORY;
}
/***********************************************************************
* RpcProtseqVectorFreeA (RPCRT4.@)
*/
RPC_STATUS WINAPI RpcProtseqVectorFreeA(RPC_PROTSEQ_VECTORA **protseqs)
{
TRACE("(%p)\n", protseqs);
if (*protseqs)
{
unsigned int i;
for (i = 0; i < (*protseqs)->Count; i++)
HeapFree(GetProcessHeap(), 0, (*protseqs)->Protseq[i]);
HeapFree(GetProcessHeap(), 0, *protseqs);
*protseqs = NULL;
}
return RPC_S_OK;
}
/***********************************************************************
* RpcProtseqVectorFreeW (RPCRT4.@)
*/
RPC_STATUS WINAPI RpcProtseqVectorFreeW(RPC_PROTSEQ_VECTORW **protseqs)
{
TRACE("(%p)\n", protseqs);
if (*protseqs)
{
unsigned int i;
for (i = 0; i < (*protseqs)->Count; i++)
HeapFree(GetProcessHeap(), 0, (*protseqs)->Protseq[i]);
HeapFree(GetProcessHeap(), 0, *protseqs);
*protseqs = NULL;
}
return RPC_S_OK;
}
/***********************************************************************
* RpcNetworkInqProtseqsW (RPCRT4.@)
*/
RPC_STATUS WINAPI RpcNetworkInqProtseqsW( RPC_PROTSEQ_VECTORW** protseqs )
{
RPC_PROTSEQ_VECTORW *pvector;
unsigned int i;
RPC_STATUS status = RPC_S_OUT_OF_MEMORY;
TRACE("(%p)\n", protseqs);
*protseqs = HeapAlloc(GetProcessHeap(), 0, sizeof(RPC_PROTSEQ_VECTORW)+(sizeof(unsigned short*)*ARRAY_SIZE(protseq_list)));
if (!*protseqs)
goto end;
pvector = *protseqs;
pvector->Count = 0;
for (i = 0; i < ARRAY_SIZE(protseq_list); i++)
{
pvector->Protseq[i] = HeapAlloc(GetProcessHeap(), 0, (strlen(protseq_list[i].name)+1)*sizeof(unsigned short));
if (pvector->Protseq[i] == NULL)
goto end;
MultiByteToWideChar(CP_ACP, 0, (CHAR*)protseq_list[i].name, -1,
(WCHAR*)pvector->Protseq[i], strlen(protseq_list[i].name) + 1);
pvector->Count++;
}
status = RPC_S_OK;
end:
if (status != RPC_S_OK)
RpcProtseqVectorFreeW(protseqs);
return status;
}
/***********************************************************************
* RpcNetworkInqProtseqsA (RPCRT4.@)
*/
RPC_STATUS WINAPI RpcNetworkInqProtseqsA(RPC_PROTSEQ_VECTORA** protseqs)
{
RPC_PROTSEQ_VECTORA *pvector;
unsigned int i;
RPC_STATUS status = RPC_S_OUT_OF_MEMORY;
TRACE("(%p)\n", protseqs);
*protseqs = HeapAlloc(GetProcessHeap(), 0, sizeof(RPC_PROTSEQ_VECTORW)+(sizeof(unsigned char*)*ARRAY_SIZE(protseq_list)));
if (!*protseqs)
goto end;
pvector = *protseqs;
pvector->Count = 0;
for (i = 0; i < ARRAY_SIZE(protseq_list); i++)
{
pvector->Protseq[i] = HeapAlloc(GetProcessHeap(), 0, strlen(protseq_list[i].name)+1);
if (pvector->Protseq[i] == NULL)
goto end;
strcpy((char*)pvector->Protseq[i], protseq_list[i].name);
pvector->Count++;
}
status = RPC_S_OK;
end:
if (status != RPC_S_OK)
RpcProtseqVectorFreeA(protseqs);
return status;
}