*/ DEVICE_CMD Close_Clipboard(REBREQ *req) /* ***********************************************************************/ { SET_CLOSED(req); return DR_DONE; }
*/ static void Cleanup_File(REBREQ *file) /* ***********************************************************************/ { if (GET_FLAG(file->modes, RFM_NAME_MEM)) { //NOTE: file->special.file.path will get GC'd file->special.file.path = 0; CLR_FLAG(file->modes, RFM_NAME_MEM); } SET_CLOSED(file); }
*/ void Set_Port_Open(REBSER *port, REBFLG flag) /* ** Standard method for setting a port open/closed. ** A convention. Not all ports use this method. ** ***********************************************************************/ { REBVAL *state = BLK_SKIP(port, STD_PORT_STATE); if (IS_BINARY(state)) { if (flag) SET_OPEN(VAL_BIN_DATA(state)); else SET_CLOSED(VAL_BIN_DATA(state)); } }
// // Close_Signal: C // DEVICE_CMD Close_Signal(REBREQ *req) { //RL_Print("Close_Signal\n"); if (sigprocmask(SIG_UNBLOCK, &req->special.signal.mask, NULL) < 0) { goto error; } SET_CLOSED(req); return DR_DONE; error: req->error = errno; return DR_ERROR; }
*/ DEVICE_CMD Close_DNS(REBREQ *sock) /* ** Note: valid even if not open. ** ***********************************************************************/ { // Terminate a pending request: #ifdef HAS_ASYNC_DNS if (GET_FLAG(sock->flags, RRF_PENDING)) { CLR_FLAG(sock->flags, RRF_PENDING); if (sock->handle) WSACancelAsyncRequest(sock->handle); } #endif if (sock->net.host_info) OS_Free(sock->net.host_info); sock->net.host_info = 0; sock->handle = 0; SET_CLOSED(sock); return DR_DONE; // Removes it from device's pending list (if needed) }
// // Transport_Actor: C // static REB_R Transport_Actor(struct Reb_Call *call_, REBSER *port, REBCNT action, enum Transport_Types proto) { REBREQ *sock; // IO request REBVAL *spec; // port spec REBVAL *arg; // action argument value REBVAL *val; // e.g. port number value REBINT result; // IO result REBCNT refs; // refinement argument flags REBCNT len; // generic length REBSER *ser; // simplifier Validate_Port(port, action); *D_OUT = *D_ARG(1); arg = DS_ARGC > 1 ? D_ARG(2) : NULL; sock = cast(REBREQ*, Use_Port_State(port, RDI_NET, sizeof(*sock))); if (proto == TRANSPORT_UDP) { SET_FLAG(sock->modes, RST_UDP); } //Debug_Fmt("Sock: %x", sock); spec = OFV(port, STD_PORT_SPEC); if (!IS_OBJECT(spec)) fail (Error(RE_INVALID_PORT)); // sock->timeout = 4000; // where does this go? !!! // HOW TO PREVENT OVERWRITE DURING BUSY OPERATION!!! // Should it just ignore it or cause an error? // Actions for an unopened socket: if (!IS_OPEN(sock)) { switch (action) { // Ordered by frequency case A_OPEN: arg = Obj_Value(spec, STD_PORT_SPEC_NET_HOST); val = Obj_Value(spec, STD_PORT_SPEC_NET_PORT_ID); if (OS_DO_DEVICE(sock, RDC_OPEN)) fail (Error_On_Port(RE_CANNOT_OPEN, port, -12)); SET_OPEN(sock); // Lookup host name (an extra TCP device step): if (IS_STRING(arg)) { sock->common.data = VAL_BIN(arg); sock->special.net.remote_port = IS_INTEGER(val) ? VAL_INT32(val) : 80; result = OS_DO_DEVICE(sock, RDC_LOOKUP); // sets remote_ip field if (result < 0) fail (Error_On_Port(RE_NO_CONNECT, port, sock->error)); return R_OUT; } // Host IP specified: else if (IS_TUPLE(arg)) { sock->special.net.remote_port = IS_INTEGER(val) ? VAL_INT32(val) : 80; memcpy(&sock->special.net.remote_ip, VAL_TUPLE(arg), 4); break; } // No host, must be a LISTEN socket: else if (IS_NONE(arg)) { SET_FLAG(sock->modes, RST_LISTEN); sock->common.data = 0; // where ACCEPT requests are queued sock->special.net.local_port = IS_INTEGER(val) ? VAL_INT32(val) : 8000; break; } else fail (Error_On_Port(RE_INVALID_SPEC, port, -10)); case A_CLOSE: return R_OUT; case A_OPENQ: return R_FALSE; case A_UPDATE: // allowed after a close break; default: fail (Error_On_Port(RE_NOT_OPEN, port, -12)); } } // Actions for an open socket: switch (action) { // Ordered by frequency case A_UPDATE: // Update the port object after a READ or WRITE operation. // This is normally called by the WAKE-UP function. arg = OFV(port, STD_PORT_DATA); if (sock->command == RDC_READ) { if (ANY_BINSTR(arg)) VAL_TAIL(arg) += sock->actual; } else if (sock->command == RDC_WRITE) { SET_NONE(arg); // Write is done. } return R_NONE; case A_READ: // Read data into a buffer, expanding the buffer if needed. // If no length is given, program must stop it at some point. refs = Find_Refines(call_, ALL_READ_REFS); if ( !GET_FLAG(sock->modes, RST_UDP) && !GET_FLAG(sock->state, RSM_CONNECT) ) { fail (Error_On_Port(RE_NOT_CONNECTED, port, -15)); } // Setup the read buffer (allocate a buffer if needed): arg = OFV(port, STD_PORT_DATA); if (!IS_STRING(arg) && !IS_BINARY(arg)) { Val_Init_Binary(arg, Make_Binary(NET_BUF_SIZE)); } ser = VAL_SERIES(arg); sock->length = SERIES_AVAIL(ser); // space available if (sock->length < NET_BUF_SIZE/2) Extend_Series(ser, NET_BUF_SIZE); sock->length = SERIES_AVAIL(ser); sock->common.data = STR_TAIL(ser); // write at tail //if (SERIES_TAIL(ser) == 0) sock->actual = 0; // Actual for THIS read, not for total. //Print("(max read length %d)", sock->length); result = OS_DO_DEVICE(sock, RDC_READ); // recv can happen immediately if (result < 0) fail (Error_On_Port(RE_READ_ERROR, port, sock->error)); break; case A_WRITE: // Write the entire argument string to the network. // The lower level write code continues until done. refs = Find_Refines(call_, ALL_WRITE_REFS); if (!GET_FLAG(sock->modes, RST_UDP) && !GET_FLAG(sock->state, RSM_CONNECT)) fail (Error_On_Port(RE_NOT_CONNECTED, port, -15)); // Determine length. Clip /PART to size of string if needed. spec = D_ARG(2); len = VAL_LEN(spec); if (refs & AM_WRITE_PART) { REBCNT n = Int32s(D_ARG(ARG_WRITE_LIMIT), 0); if (n <= len) len = n; } // Setup the write: *OFV(port, STD_PORT_DATA) = *spec; // keep it GC safe sock->length = len; sock->common.data = VAL_BIN_DATA(spec); sock->actual = 0; //Print("(write length %d)", len); result = OS_DO_DEVICE(sock, RDC_WRITE); // send can happen immediately if (result < 0) fail (Error_On_Port(RE_WRITE_ERROR, port, sock->error)); if (result == DR_DONE) SET_NONE(OFV(port, STD_PORT_DATA)); break; case A_PICK: // FIRST server-port returns new port connection. len = Get_Num_Arg(arg); // Position if (len == 1 && GET_FLAG(sock->modes, RST_LISTEN) && sock->common.data) Accept_New_Port(D_OUT, port, sock); // sets D_OUT else fail (Error_Out_Of_Range(arg)); break; case A_QUERY: // Get specific information - the scheme's info object. // Special notation allows just getting part of the info. Ret_Query_Net(port, sock, D_OUT); break; case A_OPENQ: // Connect for clients, bind for servers: if (sock->state & ((1<<RSM_CONNECT) | (1<<RSM_BIND))) return R_TRUE; return R_FALSE; case A_CLOSE: if (IS_OPEN(sock)) { OS_DO_DEVICE(sock, RDC_CLOSE); SET_CLOSED(sock); } break; case A_LENGTH: arg = OFV(port, STD_PORT_DATA); len = ANY_SERIES(arg) ? VAL_TAIL(arg) : 0; SET_INTEGER(D_OUT, len); break; case A_OPEN: result = OS_DO_DEVICE(sock, RDC_CONNECT); if (result < 0) fail (Error_On_Port(RE_NO_CONNECT, port, sock->error)); break; case A_DELETE: // Temporary to TEST error handler! { REBVAL *event = Append_Event(); // sets signal VAL_SET(event, REB_EVENT); // (has more space, if we need it) VAL_EVENT_TYPE(event) = EVT_ERROR; VAL_EVENT_DATA(event) = 101; VAL_EVENT_REQ(event) = sock; } break; default: fail (Error_Illegal_Action(REB_PORT, action)); } return R_OUT; }
*/ static REB_R Console_Actor(struct Reb_Call *call_, REBSER *port, REBCNT action) /* ***********************************************************************/ { REBREQ *req; REBINT result; REBVAL *arg = D_ARG(2); REBSER *ser; Validate_Port(port, action); arg = D_ARG(2); *D_OUT = *D_ARG(1); req = cast(REBREQ*, Use_Port_State(port, RDI_STDIO, sizeof(REBREQ))); switch (action) { case A_READ: // If not open, open it: if (!IS_OPEN(req)) { if (OS_DO_DEVICE(req, RDC_OPEN)) Trap_Port_DEAD_END(RE_CANNOT_OPEN, port, req->error); } // If no buffer, create a buffer: arg = OFV(port, STD_PORT_DATA); if (!IS_STRING(arg) && !IS_BINARY(arg)) { Set_Binary(arg, MAKE_OS_BUFFER(OUT_BUF_SIZE)); } ser = VAL_SERIES(arg); RESET_SERIES(ser); req->common.data = BIN_HEAD(ser); req->length = SERIES_AVAIL(ser); #ifdef nono // Is the buffer large enough? req->length = SERIES_AVAIL(ser); // space available if (req->length < OUT_BUF_SIZE/2) Extend_Series(ser, OUT_BUF_SIZE); req->length = SERIES_AVAIL(ser); // Don't make buffer too large: Bug #174 ????? if (req->length > 1024) req->length = 1024; //??? req->common.data = STR_TAIL(ser); // write at tail //??? if (SERIES_TAIL(ser) == 0) req->actual = 0; //??? #endif result = OS_DO_DEVICE(req, RDC_READ); if (result < 0) Trap_Port_DEAD_END(RE_READ_ERROR, port, req->error); #ifdef nono // Does not belong here!! // Remove or replace CRs: result = 0; for (n = 0; n < req->actual; n++) { chr = GET_ANY_CHAR(ser, n); if (chr == CR) { chr = LF; // Skip LF if it follows: if ((n+1) < req->actual && LF == GET_ANY_CHAR(ser, n+1)) n++; } SET_ANY_CHAR(ser, result, chr); result++; } #endif // !!! Among many confusions in this file, it said "Another copy???" //Set_String(D_OUT, Copy_OS_Str(ser->data, result)); Set_Binary(D_OUT, Copy_Bytes(req->common.data, req->actual)); break; case A_OPEN: // ?? why??? //if (OS_DO_DEVICE(req, RDC_OPEN)) Trap_Port_DEAD_END(RE_CANNOT_OPEN, port); SET_OPEN(req); break; case A_CLOSE: SET_CLOSED(req); //OS_DO_DEVICE(req, RDC_CLOSE); break; case A_OPENQ: if (IS_OPEN(req)) return R_TRUE; return R_FALSE; default: Trap_Action_DEAD_END(REB_PORT, action); } return R_OUT; }
*/ static REB_R Event_Actor(struct Reb_Call *call_, REBSER *port, REBCNT action) /* ** Internal port handler for events. ** ***********************************************************************/ { REBVAL *spec; REBVAL *state; REB_R result; REBVAL *arg; REBVAL save_port; Validate_Port(port, action); arg = D_ARG(2); *D_OUT = *D_ARG(1); // Validate and fetch relevant PORT fields: state = BLK_SKIP(port, STD_PORT_STATE); spec = BLK_SKIP(port, STD_PORT_SPEC); if (!IS_OBJECT(spec)) Trap1_DEAD_END(RE_INVALID_SPEC, spec); // Get or setup internal state data: if (!IS_BLOCK(state)) Set_Block(state, Make_Block(EVENTS_CHUNK - 1)); switch (action) { case A_UPDATE: return R_NONE; // Normal block actions done on events: case A_POKE: if (!IS_EVENT(D_ARG(3))) Trap_Arg_DEAD_END(D_ARG(3)); goto act_blk; case A_INSERT: case A_APPEND: //case A_PATH: // not allowed: port/foo is port object field access //case A_PATH_SET: // not allowed: above if (!IS_EVENT(arg)) Trap_Arg_DEAD_END(arg); case A_PICK: act_blk: save_port = *D_ARG(1); // save for return *D_ARG(1) = *state; result = T_Block(call_, action); SET_SIGNAL(SIG_EVENT_PORT); if (action == A_INSERT || action == A_APPEND || action == A_REMOVE) { *D_OUT = save_port; break; } return result; // return condition case A_CLEAR: VAL_TAIL(state) = 0; VAL_BLK_TERM(state); CLR_SIGNAL(SIG_EVENT_PORT); break; case A_LENGTHQ: SET_INTEGER(D_OUT, VAL_TAIL(state)); break; case A_OPEN: if (!req) { //!!! req = OS_MAKE_DEVREQ(RDI_EVENT); if (req) { SET_OPEN(req); OS_DO_DEVICE(req, RDC_CONNECT); // stays queued } } break; case A_CLOSE: OS_ABORT_DEVICE(req); OS_DO_DEVICE(req, RDC_CLOSE); // free req!!! SET_CLOSED(req); req = 0; break; case A_FIND: // add it default: Trap_Action_DEAD_END(REB_PORT, action); } return R_OUT; }
// // Serial_Actor: C // static REB_R Serial_Actor(REBFRM *frame_, REBCTX *port, REBSYM action) { REBREQ *req; // IO request REBVAL *spec; // port spec REBVAL *arg; // action argument value REBVAL *val; // e.g. port number value REBINT result; // IO result REBCNT refs; // refinement argument flags REBCNT len; // generic length REBSER *ser; // simplifier REBVAL *path; Validate_Port(port, action); *D_OUT = *D_ARG(1); // Validate PORT fields: spec = CTX_VAR(port, STD_PORT_SPEC); if (!IS_OBJECT(spec)) fail (Error(RE_INVALID_PORT)); path = Obj_Value(spec, STD_PORT_SPEC_HEAD_REF); if (!path) fail (Error(RE_INVALID_SPEC, spec)); //if (!IS_FILE(path)) fail (Error(RE_INVALID_SPEC, path)); req = cast(REBREQ*, Use_Port_State(port, RDI_SERIAL, sizeof(*req))); // Actions for an unopened serial port: if (!IS_OPEN(req)) { switch (action) { case SYM_OPEN: arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_PATH); if (! (IS_FILE(arg) || IS_STRING(arg) || IS_BINARY(arg))) fail (Error(RE_INVALID_PORT_ARG, arg)); req->special.serial.path = ALLOC_N(REBCHR, MAX_SERIAL_DEV_PATH); OS_STRNCPY( req->special.serial.path, // // !!! This is assuming VAL_DATA contains native chars. // Should it? (2 bytes on windows, 1 byte on linux/mac) // SER_AT(REBCHR, VAL_SERIES(arg), VAL_INDEX(arg)), MAX_SERIAL_DEV_PATH ); arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_SPEED); if (! IS_INTEGER(arg)) fail (Error(RE_INVALID_PORT_ARG, arg)); req->special.serial.baud = VAL_INT32(arg); //Secure_Port(SYM_SERIAL, ???, path, ser); arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_DATA_SIZE); if (!IS_INTEGER(arg) || VAL_INT64(arg) < 5 || VAL_INT64(arg) > 8 ) { fail (Error(RE_INVALID_PORT_ARG, arg)); } req->special.serial.data_bits = VAL_INT32(arg); arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_STOP_BITS); if (!IS_INTEGER(arg) || VAL_INT64(arg) < 1 || VAL_INT64(arg) > 2 ) { fail (Error(RE_INVALID_PORT_ARG, arg)); } req->special.serial.stop_bits = VAL_INT32(arg); arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_PARITY); if (IS_BLANK(arg)) { req->special.serial.parity = SERIAL_PARITY_NONE; } else { if (!IS_WORD(arg)) fail (Error(RE_INVALID_PORT_ARG, arg)); switch (VAL_WORD_SYM(arg)) { case SYM_ODD: req->special.serial.parity = SERIAL_PARITY_ODD; break; case SYM_EVEN: req->special.serial.parity = SERIAL_PARITY_EVEN; break; default: fail (Error(RE_INVALID_PORT_ARG, arg)); } } arg = Obj_Value(spec, STD_PORT_SPEC_SERIAL_FLOW_CONTROL); if (IS_BLANK(arg)) { req->special.serial.flow_control = SERIAL_FLOW_CONTROL_NONE; } else { if (!IS_WORD(arg)) fail (Error(RE_INVALID_PORT_ARG, arg)); switch (VAL_WORD_SYM(arg)) { case SYM_HARDWARE: req->special.serial.flow_control = SERIAL_FLOW_CONTROL_HARDWARE; break; case SYM_SOFTWARE: req->special.serial.flow_control = SERIAL_FLOW_CONTROL_SOFTWARE; break; default: fail (Error(RE_INVALID_PORT_ARG, arg)); } } if (OS_DO_DEVICE(req, RDC_OPEN)) fail (Error_On_Port(RE_CANNOT_OPEN, port, -12)); SET_OPEN(req); return R_OUT; case SYM_CLOSE: return R_OUT; case SYM_OPEN_Q: return R_FALSE; default: fail (Error_On_Port(RE_NOT_OPEN, port, -12)); } } // Actions for an open socket: switch (action) { case SYM_READ: refs = Find_Refines(frame_, ALL_READ_REFS); // Setup the read buffer (allocate a buffer if needed): arg = CTX_VAR(port, STD_PORT_DATA); if (!IS_STRING(arg) && !IS_BINARY(arg)) { Val_Init_Binary(arg, Make_Binary(32000)); } ser = VAL_SERIES(arg); req->length = SER_AVAIL(ser); // space available if (req->length < 32000/2) Extend_Series(ser, 32000); req->length = SER_AVAIL(ser); // This used STR_TAIL (obsolete, equivalent to BIN_TAIL) but was it // sure the series was byte sized? Added in a check. assert(BYTE_SIZE(ser)); req->common.data = BIN_TAIL(ser); // write at tail //if (SER_LEN(ser) == 0) req->actual = 0; // Actual for THIS read, not for total. #ifdef DEBUG_SERIAL printf("(max read length %d)", req->length); #endif result = OS_DO_DEVICE(req, RDC_READ); // recv can happen immediately if (result < 0) fail (Error_On_Port(RE_READ_ERROR, port, req->error)); #ifdef DEBUG_SERIAL for (len = 0; len < req->actual; len++) { if (len % 16 == 0) printf("\n"); printf("%02x ", req->common.data[len]); } printf("\n"); #endif *D_OUT = *arg; return R_OUT; case SYM_WRITE: refs = Find_Refines(frame_, ALL_WRITE_REFS); // Determine length. Clip /PART to size of string if needed. spec = D_ARG(2); len = VAL_LEN_AT(spec); if (refs & AM_WRITE_PART) { REBCNT n = Int32s(D_ARG(ARG_WRITE_LIMIT), 0); if (n <= len) len = n; } // Setup the write: *CTX_VAR(port, STD_PORT_DATA) = *spec; // keep it GC safe req->length = len; req->common.data = VAL_BIN_AT(spec); req->actual = 0; //Print("(write length %d)", len); result = OS_DO_DEVICE(req, RDC_WRITE); // send can happen immediately if (result < 0) fail (Error_On_Port(RE_WRITE_ERROR, port, req->error)); break; case SYM_UPDATE: // Update the port object after a READ or WRITE operation. // This is normally called by the WAKE-UP function. arg = CTX_VAR(port, STD_PORT_DATA); if (req->command == RDC_READ) { if (ANY_BINSTR(arg)) { SET_SERIES_LEN( VAL_SERIES(arg), VAL_LEN_HEAD(arg) + req->actual ); } } else if (req->command == RDC_WRITE) { SET_BLANK(arg); // Write is done. } return R_BLANK; case SYM_OPEN_Q: return R_TRUE; case SYM_CLOSE: if (IS_OPEN(req)) { OS_DO_DEVICE(req, RDC_CLOSE); SET_CLOSED(req); } break; default: fail (Error_Illegal_Action(REB_PORT, action)); } return R_OUT; }