-- --
-- B o d y --
-- --
--- Copyright (C) 2001-2005, AdaCore --
+-- Copyright (C) 2001-2010, AdaCore --
-- --
-- GNAT is free software; you can redistribute it and/or modify it under --
-- terms of the GNU General Public License as published by the Free Soft- --
-- --
------------------------------------------------------------------------------
-with Ada.Streams; use Ada.Streams;
-with Ada.Exceptions; use Ada.Exceptions;
+with Ada.Streams; use Ada.Streams;
+with Ada.Exceptions; use Ada.Exceptions;
+with Ada.Finalization;
with Ada.Unchecked_Conversion;
with Interfaces.C.Strings;
-with GNAT.Sockets.Constants;
-with GNAT.Sockets.Thin; use GNAT.Sockets.Thin;
-with GNAT.Task_Lock;
+with GNAT.Sockets.Thin_Common; use GNAT.Sockets.Thin_Common;
+with GNAT.Sockets.Thin; use GNAT.Sockets.Thin;
with GNAT.Sockets.Linker_Options;
pragma Warnings (Off, GNAT.Sockets.Linker_Options);
-- Need to include pragma Linker_Options which is platform dependent
-with System; use System;
+with System; use System;
+with System.Communication; use System.Communication;
+with System.CRTL; use System.CRTL;
+with System.Task_Lock;
package body GNAT.Sockets is
- use type C.int, System.Address;
+ package C renames Interfaces.C;
- Finalized : Boolean := False;
- Initialized : Boolean := False;
+ use type C.int;
ENOERROR : constant := 0;
- -- Correspondance tables
+ Netdb_Buffer_Size : constant := SOSC.Need_Netdb_Buffer * 1024;
+ Need_Netdb_Lock : constant Boolean := SOSC.Need_Netdb_Lock /= 0;
+ -- The network database functions gethostbyname, gethostbyaddr,
+ -- getservbyname and getservbyport can either be guaranteed task safe by
+ -- the operating system, or else return data through a user-provided buffer
+ -- to ensure concurrent uses do not interfere.
- Families : constant array (Family_Type) of C.int :=
- (Family_Inet => Constants.AF_INET,
- Family_Inet6 => Constants.AF_INET6);
+ -- Correspondence tables
Levels : constant array (Level_Type) of C.int :=
- (Socket_Level => Constants.SOL_SOCKET,
- IP_Protocol_For_IP_Level => Constants.IPPROTO_IP,
- IP_Protocol_For_UDP_Level => Constants.IPPROTO_UDP,
- IP_Protocol_For_TCP_Level => Constants.IPPROTO_TCP);
+ (Socket_Level => SOSC.SOL_SOCKET,
+ IP_Protocol_For_IP_Level => SOSC.IPPROTO_IP,
+ IP_Protocol_For_UDP_Level => SOSC.IPPROTO_UDP,
+ IP_Protocol_For_TCP_Level => SOSC.IPPROTO_TCP);
Modes : constant array (Mode_Type) of C.int :=
- (Socket_Stream => Constants.SOCK_STREAM,
- Socket_Datagram => Constants.SOCK_DGRAM);
+ (Socket_Stream => SOSC.SOCK_STREAM,
+ Socket_Datagram => SOSC.SOCK_DGRAM);
Shutmodes : constant array (Shutmode_Type) of C.int :=
- (Shut_Read => Constants.SHUT_RD,
- Shut_Write => Constants.SHUT_WR,
- Shut_Read_Write => Constants.SHUT_RDWR);
+ (Shut_Read => SOSC.SHUT_RD,
+ Shut_Write => SOSC.SHUT_WR,
+ Shut_Read_Write => SOSC.SHUT_RDWR);
Requests : constant array (Request_Name) of C.int :=
- (Non_Blocking_IO => Constants.FIONBIO,
- N_Bytes_To_Read => Constants.FIONREAD);
+ (Non_Blocking_IO => SOSC.FIONBIO,
+ N_Bytes_To_Read => SOSC.FIONREAD);
Options : constant array (Option_Name) of C.int :=
- (Keep_Alive => Constants.SO_KEEPALIVE,
- Reuse_Address => Constants.SO_REUSEADDR,
- Broadcast => Constants.SO_BROADCAST,
- Send_Buffer => Constants.SO_SNDBUF,
- Receive_Buffer => Constants.SO_RCVBUF,
- Linger => Constants.SO_LINGER,
- Error => Constants.SO_ERROR,
- No_Delay => Constants.TCP_NODELAY,
- Add_Membership => Constants.IP_ADD_MEMBERSHIP,
- Drop_Membership => Constants.IP_DROP_MEMBERSHIP,
- Multicast_If => Constants.IP_MULTICAST_IF,
- Multicast_TTL => Constants.IP_MULTICAST_TTL,
- Multicast_Loop => Constants.IP_MULTICAST_LOOP,
- Send_Timeout => Constants.SO_SNDTIMEO,
- Receive_Timeout => Constants.SO_RCVTIMEO);
+ (Keep_Alive => SOSC.SO_KEEPALIVE,
+ Reuse_Address => SOSC.SO_REUSEADDR,
+ Broadcast => SOSC.SO_BROADCAST,
+ Send_Buffer => SOSC.SO_SNDBUF,
+ Receive_Buffer => SOSC.SO_RCVBUF,
+ Linger => SOSC.SO_LINGER,
+ Error => SOSC.SO_ERROR,
+ No_Delay => SOSC.TCP_NODELAY,
+ Add_Membership => SOSC.IP_ADD_MEMBERSHIP,
+ Drop_Membership => SOSC.IP_DROP_MEMBERSHIP,
+ Multicast_If => SOSC.IP_MULTICAST_IF,
+ Multicast_TTL => SOSC.IP_MULTICAST_TTL,
+ Multicast_Loop => SOSC.IP_MULTICAST_LOOP,
+ Receive_Packet_Info => SOSC.IP_PKTINFO,
+ Send_Timeout => SOSC.SO_SNDTIMEO,
+ Receive_Timeout => SOSC.SO_RCVTIMEO);
+ -- ??? Note: for OpenSolaris, Receive_Packet_Info should be IP_RECVPKTINFO,
+ -- but for Linux compatibility this constant is the same as IP_PKTINFO.
Flags : constant array (0 .. 3) of C.int :=
- (0 => Constants.MSG_OOB, -- Process_Out_Of_Band_Data
- 1 => Constants.MSG_PEEK, -- Peek_At_Incoming_Data
- 2 => Constants.MSG_WAITALL, -- Wait_For_A_Full_Reception
- 3 => Constants.MSG_EOR); -- Send_End_Of_Record
+ (0 => SOSC.MSG_OOB, -- Process_Out_Of_Band_Data
+ 1 => SOSC.MSG_PEEK, -- Peek_At_Incoming_Data
+ 2 => SOSC.MSG_WAITALL, -- Wait_For_A_Full_Reception
+ 3 => SOSC.MSG_EOR); -- Send_End_Of_Record
Socket_Error_Id : constant Exception_Id := Socket_Error'Identity;
Host_Error_Id : constant Exception_Id := Host_Error'Identity;
Hex_To_Char : constant String (1 .. 16) := "0123456789ABCDEF";
-- Use to print in hexadecimal format
- function To_In_Addr is new Ada.Unchecked_Conversion (C.int, In_Addr);
- function To_Int is new Ada.Unchecked_Conversion (In_Addr, C.int);
-
- function Err_Code_Image (E : Integer) return String;
- -- Return the value of E surrounded with brackets
-
-----------------------
-- Local subprograms --
-----------------------
-- Return the int value corresponding to the specified flags combination
function Set_Forced_Flags (F : C.int) return C.int;
- -- Return F with the bits from Constants.MSG_Forced_Flags forced set
+ -- Return F with the bits from SOSC.MSG_Forced_Flags forced set
function Short_To_Network
(S : C.unsigned_short) return C.unsigned_short;
function Network_To_Short
(S : C.unsigned_short) return C.unsigned_short
renames Short_To_Network;
- -- Symetric operation
+ -- Symmetric operation
function Image
(Val : Inet_Addr_VN_Type;
function Is_IP_Address (Name : String) return Boolean;
-- Return true when Name is an IP address in standard dot notation
- function To_In_Addr (Addr : Inet_Addr_Type) return Thin.In_Addr;
+ procedure Netdb_Lock;
+ pragma Inline (Netdb_Lock);
+ procedure Netdb_Unlock;
+ pragma Inline (Netdb_Unlock);
+ -- Lock/unlock operation used to protect netdb access for platforms that
+ -- require such protection.
+
+ function To_In_Addr (Addr : Inet_Addr_Type) return In_Addr;
procedure To_Inet_Addr
(Addr : In_Addr;
Result : out Inet_Addr_Type);
-- Conversion functions
- function To_Host_Entry (E : Hostent) return Host_Entry_Type;
+ function To_Host_Entry (E : Hostent_Access) return Host_Entry_Type;
-- Conversion function
- function To_Service_Entry (E : Servent) return Service_Entry_Type;
+ function To_Service_Entry (E : Servent_Access) return Service_Entry_Type;
-- Conversion function
+ function Value (S : System.Address) return String;
+ -- Same as Interfaces.C.Strings.Value but taking a System.Address (on VMS,
+ -- chars_ptr is a 32-bit pointer, and here we need a 64-bit version).
+
function To_Timeval (Val : Timeval_Duration) return Timeval;
-- Separate Val in seconds and microseconds
(Stream : in out Stream_Socket_Stream_Type;
Item : Ada.Streams.Stream_Element_Array);
+ procedure Stream_Write
+ (Socket : Socket_Type;
+ Item : Ada.Streams.Stream_Element_Array;
+ To : access Sock_Addr_Type);
+ -- Common implementation for the Write operation of Datagram_Socket_Stream_
+ -- Type and Stream_Socket_Stream_Type.
+
+ procedure Wait_On_Socket
+ (Socket : Socket_Type;
+ For_Read : Boolean;
+ Timeout : Selector_Duration;
+ Selector : access Selector_Type := null;
+ Status : out Selector_Status);
+ -- Common code for variants of socket operations supporting a timeout:
+ -- block in Check_Selector on Socket for at most the indicated timeout.
+ -- If For_Read is True, Socket is added to the read set for this call, else
+ -- it is added to the write set. If no selector is provided, a local one is
+ -- created for this call and destroyed prior to returning.
+
+ type Sockets_Library_Controller is new Ada.Finalization.Limited_Controlled
+ with null record;
+ -- This type is used to generate automatic calls to Initialize and Finalize
+ -- during the elaboration and finalization of this package. A single object
+ -- of this type must exist at library level.
+
+ function Err_Code_Image (E : Integer) return String;
+ -- Return the value of E surrounded with brackets
+
+ procedure Initialize (X : in out Sockets_Library_Controller);
+ procedure Finalize (X : in out Sockets_Library_Controller);
+
+ procedure Normalize_Empty_Socket_Set (S : in out Socket_Set_Type);
+ -- If S is the empty set (detected by Last = No_Socket), make sure its
+ -- fd_set component is actually cleared. Note that the case where it is
+ -- not can occur for an uninitialized Socket_Set_Type object.
+
+ function Is_Open (S : Selector_Type) return Boolean;
+ -- Return True for an "open" Selector_Type object, i.e. one for which
+ -- Create_Selector has been called and Close_Selector has not been called,
+ -- or the null selector.
+
---------
-- "+" --
---------
--------------------
procedure Abort_Selector (Selector : Selector_Type) is
- Buf : aliased Character := ASCII.NUL;
Res : C.int;
begin
- -- Send an empty array to unblock C select system call
+ if not Is_Open (Selector) then
+ raise Program_Error with "closed selector";
+
+ elsif Selector.Is_Null then
+ raise Program_Error with "null selector";
+
+ end if;
+
+ -- Send one byte to unblock select system call
+
+ Res := Signalling_Fds.Write (C.int (Selector.W_Sig_Socket));
- Res := C_Send (C.int (Selector.W_Sig_Socket), Buf'Address, 1,
- Constants.MSG_Forced_Flags);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
end if;
Address.Port := Port_Type (Network_To_Short (Sin.Sin_Port));
end Accept_Socket;
+ -------------------
+ -- Accept_Socket --
+ -------------------
+
+ procedure Accept_Socket
+ (Server : Socket_Type;
+ Socket : out Socket_Type;
+ Address : out Sock_Addr_Type;
+ Timeout : Selector_Duration;
+ Selector : access Selector_Type := null;
+ Status : out Selector_Status)
+ is
+ begin
+ if Selector /= null and then not Is_Open (Selector.all) then
+ raise Program_Error with "closed selector";
+ end if;
+
+ -- Wait for socket to become available for reading
+
+ Wait_On_Socket
+ (Socket => Server,
+ For_Read => True,
+ Timeout => Timeout,
+ Selector => Selector,
+ Status => Status);
+
+ -- Accept connection if available
+
+ if Status = Completed then
+ Accept_Socket (Server, Socket, Address);
+ else
+ Socket := No_Socket;
+ end if;
+ end Accept_Socket;
+
---------------
-- Addresses --
---------------
Res : C.int;
Sin : aliased Sockaddr_In;
Len : constant C.int := Sin'Size / 8;
+ -- This assumes that Address.Family = Family_Inet???
begin
if Address.Family = Family_Inet6 then
- raise Socket_Error;
+ raise Socket_Error with "IPv6 not supported";
end if;
- Set_Length (Sin'Unchecked_Access, Len);
- Set_Family (Sin'Unchecked_Access, Families (Address.Family));
+ Set_Family (Sin.Sin_Family, Address.Family);
+ Set_Address (Sin'Unchecked_Access, To_In_Addr (Address.Addr));
Set_Port
(Sin'Unchecked_Access,
Short_To_Network (C.unsigned_short (Address.Port)));
--------------------
procedure Check_Selector
- (Selector : in out Selector_Type;
+ (Selector : Selector_Type;
R_Socket_Set : in out Socket_Set_Type;
W_Socket_Set : in out Socket_Set_Type;
Status : out Selector_Status;
Timeout : Selector_Duration := Forever)
is
- E_Socket_Set : Socket_Set_Type; -- (No_Socket, No_Socket_Set)
+ E_Socket_Set : Socket_Set_Type;
begin
Check_Selector
(Selector, R_Socket_Set, W_Socket_Set, E_Socket_Set, Status, Timeout);
end Check_Selector;
+ --------------------
+ -- Check_Selector --
+ --------------------
+
procedure Check_Selector
- (Selector : in out Selector_Type;
+ (Selector : Selector_Type;
R_Socket_Set : in out Socket_Set_Type;
W_Socket_Set : in out Socket_Set_Type;
E_Socket_Set : in out Socket_Set_Type;
is
Res : C.int;
Last : C.int;
- RSig : Socket_Type renames Selector.R_Sig_Socket;
- RSet : Socket_Set_Type;
- WSet : Socket_Set_Type;
- ESet : Socket_Set_Type;
+ RSig : Socket_Type := No_Socket;
TVal : aliased Timeval;
TPtr : Timeval_Access;
begin
- begin
- Status := Completed;
-
- -- No timeout or Forever is indicated by a null timeval pointer
-
- if Timeout = Forever then
- TPtr := null;
- else
- TVal := To_Timeval (Timeout);
- TPtr := TVal'Unchecked_Access;
- end if;
-
- -- Copy R_Socket_Set in RSet and add read signalling socket
-
- RSet := (Set => New_Socket_Set (R_Socket_Set.Set),
- Last => R_Socket_Set.Last);
- Set (RSet, RSig);
-
- -- Copy W_Socket_Set in WSet
-
- WSet := (Set => New_Socket_Set (W_Socket_Set.Set),
- Last => W_Socket_Set.Last);
-
- -- Copy E_Socket_Set in ESet
-
- ESet := (Set => New_Socket_Set (E_Socket_Set.Set),
- Last => E_Socket_Set.Last);
-
- Last := C.int'Max (C.int'Max (C.int (RSet.Last),
- C.int (WSet.Last)),
- C.int (ESet.Last));
+ if not Is_Open (Selector) then
+ raise Program_Error with "closed selector";
+ end if;
- Res :=
- C_Select
- (Last + 1,
- RSet.Set,
- WSet.Set,
- ESet.Set,
- TPtr);
+ Status := Completed;
- if Res = Failure then
- Raise_Socket_Error (Socket_Errno);
- end if;
-
- -- If Select was resumed because of read signalling socket, read this
- -- data and remove socket from set.
+ -- No timeout or Forever is indicated by a null timeval pointer
- if Is_Set (RSet, RSig) then
- Clear (RSet, RSig);
+ if Timeout = Forever then
+ TPtr := null;
+ else
+ TVal := To_Timeval (Timeout);
+ TPtr := TVal'Unchecked_Access;
+ end if;
- declare
- Buf : Character;
+ -- Add read signalling socket, if present
- begin
- Res := C_Recv (C.int (RSig), Buf'Address, 1, 0);
+ if not Selector.Is_Null then
+ RSig := Selector.R_Sig_Socket;
+ Set (R_Socket_Set, RSig);
+ end if;
- if Res = Failure then
- Raise_Socket_Error (Socket_Errno);
- end if;
- end;
+ Last := C.int'Max (C.int'Max (C.int (R_Socket_Set.Last),
+ C.int (W_Socket_Set.Last)),
+ C.int (E_Socket_Set.Last));
- Status := Aborted;
+ -- Zero out fd_set for empty Socket_Set_Type objects
- elsif Res = 0 then
- Status := Expired;
- end if;
+ Normalize_Empty_Socket_Set (R_Socket_Set);
+ Normalize_Empty_Socket_Set (W_Socket_Set);
+ Normalize_Empty_Socket_Set (E_Socket_Set);
- -- Update RSet, WSet and ESet in regard to their new socket sets
+ Res :=
+ C_Select
+ (Last + 1,
+ R_Socket_Set.Set'Access,
+ W_Socket_Set.Set'Access,
+ E_Socket_Set.Set'Access,
+ TPtr);
- Narrow (RSet);
- Narrow (WSet);
- Narrow (ESet);
+ if Res = Failure then
+ Raise_Socket_Error (Socket_Errno);
+ end if;
- -- Reset RSet as it should be if R_Sig_Socket was not added
+ -- If Select was resumed because of read signalling socket, read this
+ -- data and remove socket from set.
- if Is_Empty (RSet) then
- Empty (RSet);
- end if;
+ if RSig /= No_Socket and then Is_Set (R_Socket_Set, RSig) then
+ Clear (R_Socket_Set, RSig);
- if Is_Empty (WSet) then
- Empty (WSet);
- end if;
+ Res := Signalling_Fds.Read (C.int (RSig));
- if Is_Empty (ESet) then
- Empty (ESet);
+ if Res = Failure then
+ Raise_Socket_Error (Socket_Errno);
end if;
- -- Deliver RSet, WSet and ESet
-
- Empty (R_Socket_Set);
- R_Socket_Set := RSet;
+ Status := Aborted;
- Empty (W_Socket_Set);
- W_Socket_Set := WSet;
-
- Empty (E_Socket_Set);
- E_Socket_Set := ESet;
-
- exception
-
- when Socket_Error =>
+ elsif Res = 0 then
+ Status := Expired;
+ end if;
- -- The local socket sets must be emptied before propagating
- -- Socket_Error so the associated storage is freed.
+ -- Update socket sets in regard to their new contents
- Empty (RSet);
- Empty (WSet);
- Empty (ESet);
- raise;
- end;
+ Narrow (R_Socket_Set);
+ Narrow (W_Socket_Set);
+ Narrow (E_Socket_Set);
end Check_Selector;
-----------
Last : aliased C.int := C.int (Item.Last);
begin
if Item.Last /= No_Socket then
- Remove_Socket_From_Set (Item.Set, C.int (Socket));
- Last_Socket_In_Set (Item.Set, Last'Unchecked_Access);
+ Remove_Socket_From_Set (Item.Set'Access, C.int (Socket));
+ Last_Socket_In_Set (Item.Set'Access, Last'Unchecked_Access);
Item.Last := Socket_Type (Last);
end if;
end Clear;
procedure Close_Selector (Selector : in out Selector_Type) is
begin
+ -- Nothing to do if selector already in closed state
- -- Close the signalling sockets used internally for the implementation
- -- of Abort_Selector. Exceptions are ignored because these sockets
- -- are implementation artefacts of no interest to the user, and
- -- there is little that can be done if either Close_Socket call fails
- -- (which theoretically should not happen anyway). We also want to try
- -- to perform the second Close_Socket even if the first one failed.
+ if Selector.Is_Null or else not Is_Open (Selector) then
+ return;
+ end if;
- begin
- Close_Socket (Selector.R_Sig_Socket);
- exception
- when Socket_Error =>
- null;
- end;
+ -- Close the signalling file descriptors used internally for the
+ -- implementation of Abort_Selector.
- begin
- Close_Socket (Selector.W_Sig_Socket);
- exception
- when Socket_Error =>
- null;
- end;
+ Signalling_Fds.Close (C.int (Selector.R_Sig_Socket));
+ Signalling_Fds.Close (C.int (Selector.W_Sig_Socket));
+
+ -- Reset R_Sig_Socket and W_Sig_Socket to No_Socket to ensure that any
+ -- (erroneous) subsequent attempt to use this selector properly fails.
+
+ Selector.R_Sig_Socket := No_Socket;
+ Selector.W_Sig_Socket := No_Socket;
end Close_Selector;
------------------
procedure Connect_Socket
(Socket : Socket_Type;
- Server : in out Sock_Addr_Type)
+ Server : Sock_Addr_Type)
is
Res : C.int;
Sin : aliased Sockaddr_In;
begin
if Server.Family = Family_Inet6 then
- raise Socket_Error;
+ raise Socket_Error with "IPv6 not supported";
end if;
- Set_Length (Sin'Unchecked_Access, Len);
- Set_Family (Sin'Unchecked_Access, Families (Server.Family));
+ Set_Family (Sin.Sin_Family, Server.Family);
Set_Address (Sin'Unchecked_Access, To_In_Addr (Server.Addr));
Set_Port
(Sin'Unchecked_Access,
end Connect_Socket;
--------------------
+ -- Connect_Socket --
+ --------------------
+
+ procedure Connect_Socket
+ (Socket : Socket_Type;
+ Server : Sock_Addr_Type;
+ Timeout : Selector_Duration;
+ Selector : access Selector_Type := null;
+ Status : out Selector_Status)
+ is
+ Req : Request_Type;
+ -- Used to set Socket to non-blocking I/O
+
+ begin
+ if Selector /= null and then not Is_Open (Selector.all) then
+ raise Program_Error with "closed selector";
+ end if;
+
+ -- Set the socket to non-blocking I/O
+
+ Req := (Name => Non_Blocking_IO, Enabled => True);
+ Control_Socket (Socket, Request => Req);
+
+ -- Start operation (non-blocking), will raise Socket_Error with
+ -- EINPROGRESS.
+
+ begin
+ Connect_Socket (Socket, Server);
+ exception
+ when E : Socket_Error =>
+ if Resolve_Exception (E) = Operation_Now_In_Progress then
+ null;
+ else
+ raise;
+ end if;
+ end;
+
+ -- Wait for socket to become available for writing
+
+ Wait_On_Socket
+ (Socket => Socket,
+ For_Read => False,
+ Timeout => Timeout,
+ Selector => Selector,
+ Status => Status);
+
+ -- Reset the socket to blocking I/O
+
+ Req := (Name => Non_Blocking_IO, Enabled => False);
+ Control_Socket (Socket, Request => Req);
+ end Connect_Socket;
+
+ --------------------
-- Control_Socket --
--------------------
when N_Bytes_To_Read =>
null;
-
end case;
- Res := C_Ioctl
- (C.int (Socket),
- Requests (Request.Name),
- Arg'Unchecked_Access);
+ Res := Socket_Ioctl
+ (C.int (Socket), Requests (Request.Name), Arg'Unchecked_Access);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
procedure Copy
(Source : Socket_Set_Type;
- Target : in out Socket_Set_Type)
+ Target : out Socket_Set_Type)
is
begin
- Empty (Target);
- if Source.Last /= No_Socket then
- Target.Set := New_Socket_Set (Source.Set);
- Target.Last := Source.Last;
- end if;
+ Target := Source;
end Copy;
---------------------
---------------------
procedure Create_Selector (Selector : out Selector_Type) is
- S0 : C.int;
- S1 : C.int;
- S2 : C.int;
- Res : C.int;
- Sin : aliased Sockaddr_In;
- Len : aliased C.int := Sin'Size / 8;
- Err : Integer;
+ Two_Fds : aliased Fd_Pair;
+ Res : C.int;
begin
- -- We open two signalling sockets. One of them is used to send data to
- -- the other, which is included in a C_Select socket set. The
- -- communication is used to force the call to C_Select to complete, and
- -- the waiting task to resume its execution.
-
- -- Create a listening socket
-
- S0 := C_Socket (Constants.AF_INET, Constants.SOCK_STREAM, 0);
-
- if S0 = Failure then
- Raise_Socket_Error (Socket_Errno);
- end if;
-
- -- Bind the socket to any unused port on localhost
-
- Sin.Sin_Addr.S_B1 := 127;
- Sin.Sin_Addr.S_B2 := 0;
- Sin.Sin_Addr.S_B3 := 0;
- Sin.Sin_Addr.S_B4 := 1;
- Sin.Sin_Port := 0;
-
- Res := C_Bind (S0, Sin'Address, Len);
-
- if Res = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Raise_Socket_Error (Err);
- end if;
-
- -- Get the port used by the socket
-
- Res := C_Getsockname (S0, Sin'Address, Len'Access);
+ if Is_Open (Selector) then
+ -- Raise exception to prevent socket descriptor leak
- if Res = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Raise_Socket_Error (Err);
- end if;
-
- -- Set backlog to 1 to guarantee that exactly one call to connect(2)
- -- can succeed.
-
- Res := C_Listen (S0, 1);
-
- if Res = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Raise_Socket_Error (Err);
+ raise Program_Error with "selector already open";
end if;
- S1 := C_Socket (Constants.AF_INET, Constants.SOCK_STREAM, 0);
-
- if S1 = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Raise_Socket_Error (Err);
- end if;
-
- -- Do a connect and accept the connection
-
- Res := C_Connect (S1, Sin'Address, Len);
-
- if Res = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Res := C_Close (S1);
- Raise_Socket_Error (Err);
- end if;
-
- -- Since the call to connect(2) has suceeded and the backlog limit on
- -- the listening socket is 1, we know that there is now exactly one
- -- pending connection on S0, which is the one from S1.
-
- S2 := C_Accept (S0, Sin'Address, Len'Access);
-
- if S2 = Failure then
- Err := Socket_Errno;
- Res := C_Close (S0);
- Res := C_Close (S1);
- Raise_Socket_Error (Err);
- end if;
+ -- We open two signalling file descriptors. One of them is used to send
+ -- data to the other, which is included in a C_Select socket set. The
+ -- communication is used to force a call to C_Select to complete, and
+ -- the waiting task to resume its execution.
- Res := C_Close (S0);
+ Res := Signalling_Fds.Create (Two_Fds'Access);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
end if;
- Selector.R_Sig_Socket := Socket_Type (S1);
- Selector.W_Sig_Socket := Socket_Type (S2);
+ Selector.R_Sig_Socket := Socket_Type (Two_Fds (Read_End));
+ Selector.W_Sig_Socket := Socket_Type (Two_Fds (Write_End));
end Create_Selector;
-------------------
-- Empty --
-----------
- procedure Empty (Item : in out Socket_Set_Type) is
+ procedure Empty (Item : out Socket_Set_Type) is
begin
- if Item.Set /= No_Socket_Set then
- Free_Socket_Set (Item.Set);
- Item.Set := No_Socket_Set;
- end if;
-
+ Reset_Socket_Set (Item.Set'Access);
Item.Last := No_Socket;
end Empty;
-- Finalize --
--------------
+ procedure Finalize (X : in out Sockets_Library_Controller) is
+ pragma Unreferenced (X);
+
+ begin
+ -- Finalization operation for the GNAT.Sockets package
+
+ Thin.Finalize;
+ end Finalize;
+
+ --------------
+ -- Finalize --
+ --------------
+
procedure Finalize is
begin
- if not Finalized
- and then Initialized
- then
- Finalized := True;
- Thin.Finalize;
- end if;
+ -- This is a dummy placeholder for an obsolete API.
+ -- The real finalization actions are in Initialize primitive operation
+ -- of Sockets_Library_Controller.
+
+ null;
end Finalize;
---------
begin
if Item.Last /= No_Socket then
Get_Socket_From_Set
- (Item.Set, L'Unchecked_Access, S'Unchecked_Access);
+ (Item.Set'Access, Last => L'Access, Socket => S'Access);
Item.Last := Socket_Type (L);
Socket := Socket_Type (S);
else
-- Get_Address --
-----------------
- function Get_Address (Stream : Stream_Access) return Sock_Addr_Type is
+ function Get_Address
+ (Stream : not null Stream_Access) return Sock_Addr_Type
+ is
begin
- if Stream = null then
- raise Socket_Error;
- elsif Stream.all in Datagram_Socket_Stream_Type then
+ if Stream.all in Datagram_Socket_Stream_Type then
return Datagram_Socket_Stream_Type (Stream.all).From;
else
return Get_Peer_Name (Stream_Socket_Stream_Type (Stream.all).Socket);
is
pragma Unreferenced (Family);
- HA : aliased In_Addr := To_In_Addr (Address);
- Res : Hostent_Access;
- Err : Integer;
+ HA : aliased In_Addr := To_In_Addr (Address);
+ Buflen : constant C.int := Netdb_Buffer_Size;
+ Buf : aliased C.char_array (1 .. Netdb_Buffer_Size);
+ Res : aliased Hostent;
+ Err : aliased C.int;
begin
- -- This C function is not always thread-safe. Protect against
- -- concurrent access.
-
- Task_Lock.Lock;
- Res := C_Gethostbyaddr (HA'Address, HA'Size / 8, Constants.AF_INET);
+ Netdb_Lock;
- if Res = null then
- Err := Host_Errno;
- Task_Lock.Unlock;
- Raise_Host_Error (Err);
+ if C_Gethostbyaddr (HA'Address, HA'Size / 8, SOSC.AF_INET,
+ Res'Access, Buf'Address, Buflen, Err'Access) /= 0
+ then
+ Netdb_Unlock;
+ Raise_Host_Error (Integer (Err));
end if;
- -- Translate from the C format to the API format
-
- declare
- HE : constant Host_Entry_Type := To_Host_Entry (Res.all);
-
- begin
- Task_Lock.Unlock;
- return HE;
- end;
+ return H : constant Host_Entry_Type :=
+ To_Host_Entry (Res'Unchecked_Access)
+ do
+ Netdb_Unlock;
+ end return;
end Get_Host_By_Address;
----------------------
----------------------
function Get_Host_By_Name (Name : String) return Host_Entry_Type is
- HN : constant C.char_array := C.To_C (Name);
- Res : Hostent_Access;
- Err : Integer;
-
begin
-- Detect IP address name and redirect to Inet_Addr
return Get_Host_By_Address (Inet_Addr (Name));
end if;
- -- This C function is not always thread-safe. Protect against
- -- concurrent access.
-
- Task_Lock.Lock;
- Res := C_Gethostbyname (HN);
+ declare
+ HN : constant C.char_array := C.To_C (Name);
+ Buflen : constant C.int := Netdb_Buffer_Size;
+ Buf : aliased C.char_array (1 .. Netdb_Buffer_Size);
+ Res : aliased Hostent;
+ Err : aliased C.int;
- if Res = null then
- Err := Host_Errno;
- Task_Lock.Unlock;
- Raise_Host_Error (Err);
- end if;
+ begin
+ Netdb_Lock;
- -- Translate from the C format to the API format
+ if C_Gethostbyname
+ (HN, Res'Access, Buf'Address, Buflen, Err'Access) /= 0
+ then
+ Netdb_Unlock;
+ Raise_Host_Error (Integer (Err));
+ end if;
- declare
- HE : constant Host_Entry_Type := To_Host_Entry (Res.all);
- begin
- Task_Lock.Unlock;
- return HE;
+ return H : constant Host_Entry_Type :=
+ To_Host_Entry (Res'Unchecked_Access)
+ do
+ Netdb_Unlock;
+ end return;
end;
end Get_Host_By_Name;
(Name : String;
Protocol : String) return Service_Entry_Type
is
- SN : constant C.char_array := C.To_C (Name);
- SP : constant C.char_array := C.To_C (Protocol);
- Res : Servent_Access;
+ SN : constant C.char_array := C.To_C (Name);
+ SP : constant C.char_array := C.To_C (Protocol);
+ Buflen : constant C.int := Netdb_Buffer_Size;
+ Buf : aliased C.char_array (1 .. Netdb_Buffer_Size);
+ Res : aliased Servent;
begin
- -- This C function is not always thread-safe. Protect against
- -- concurrent access.
+ Netdb_Lock;
- Task_Lock.Lock;
- Res := C_Getservbyname (SN, SP);
-
- if Res = null then
- Task_Lock.Unlock;
- Ada.Exceptions.Raise_Exception
- (Service_Error'Identity, "Service not found");
+ if C_Getservbyname (SN, SP, Res'Access, Buf'Address, Buflen) /= 0 then
+ Netdb_Unlock;
+ raise Service_Error with "Service not found";
end if;
-- Translate from the C format to the API format
- declare
- SE : constant Service_Entry_Type := To_Service_Entry (Res.all);
-
- begin
- Task_Lock.Unlock;
- return SE;
- end;
+ return S : constant Service_Entry_Type :=
+ To_Service_Entry (Res'Unchecked_Access)
+ do
+ Netdb_Unlock;
+ end return;
end Get_Service_By_Name;
-------------------------
(Port : Port_Type;
Protocol : String) return Service_Entry_Type
is
- SP : constant C.char_array := C.To_C (Protocol);
- Res : Servent_Access;
+ SP : constant C.char_array := C.To_C (Protocol);
+ Buflen : constant C.int := Netdb_Buffer_Size;
+ Buf : aliased C.char_array (1 .. Netdb_Buffer_Size);
+ Res : aliased Servent;
begin
- -- This C function is not always thread-safe. Protect against
- -- concurrent access.
-
- Task_Lock.Lock;
- Res := C_Getservbyport
- (C.int (Short_To_Network (C.unsigned_short (Port))), SP);
+ Netdb_Lock;
- if Res = null then
- Task_Lock.Unlock;
- Ada.Exceptions.Raise_Exception
- (Service_Error'Identity, "Service not found");
+ if C_Getservbyport
+ (C.int (Short_To_Network (C.unsigned_short (Port))), SP,
+ Res'Access, Buf'Address, Buflen) /= 0
+ then
+ Netdb_Unlock;
+ raise Service_Error with "Service not found";
end if;
-- Translate from the C format to the API format
- declare
- SE : constant Service_Entry_Type := To_Service_Entry (Res.all);
-
- begin
- Task_Lock.Unlock;
- return SE;
- end;
+ return S : constant Service_Entry_Type :=
+ To_Service_Entry (Res'Unchecked_Access)
+ do
+ Netdb_Unlock;
+ end return;
end Get_Service_By_Port;
---------------------
begin
Res := C_Getsockname (C.int (Socket), Sin'Address, Len'Access);
+
if Res /= Failure then
To_Inet_Addr (Sin.Sin_Addr, Addr.Addr);
Addr.Port := Port_Type (Network_To_Short (Sin.Sin_Port));
is
use type C.unsigned_char;
- V8 : aliased Two_Int;
+ V8 : aliased Two_Ints;
V4 : aliased C.int;
V1 : aliased C.unsigned_char;
VT : aliased Timeval;
begin
case Name is
- when Multicast_Loop |
- Multicast_TTL =>
+ when Multicast_Loop |
+ Multicast_TTL |
+ Receive_Packet_Info =>
Len := V1'Size / 8;
Add := V1'Address;
(C.int (Socket),
Levels (Level),
Options (Name),
- Add, Len'Unchecked_Access);
+ Add, Len'Access);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
when Multicast_TTL =>
Opt.Time_To_Live := Integer (V1);
- when Multicast_Loop =>
+ when Multicast_Loop |
+ Receive_Packet_Info =>
Opt.Enabled := (V1 /= 0);
when Send_Timeout |
Receive_Timeout =>
Opt.Timeout := To_Duration (VT);
-
end case;
return Opt;
-- Start of processing for Image
begin
- if Hex then
- Separator := ':';
- else
- Separator := '.';
- end if;
+ Separator := (if Hex then ':' else '.');
for J in Val'Range loop
if Hex then
return Socket'Img;
end Image;
+ -----------
+ -- Image --
+ -----------
+
+ function Image (Item : Socket_Set_Type) return String is
+ Socket_Set : Socket_Set_Type := Item;
+
+ begin
+ declare
+ Last_Img : constant String := Socket_Set.Last'Img;
+ Buffer : String
+ (1 .. (Integer (Socket_Set.Last) + 1) * Last_Img'Length);
+ Index : Positive := 1;
+ Socket : Socket_Type;
+
+ begin
+ while not Is_Empty (Socket_Set) loop
+ Get (Socket_Set, Socket);
+
+ declare
+ Socket_Img : constant String := Socket'Img;
+ begin
+ Buffer (Index .. Index + Socket_Img'Length - 1) := Socket_Img;
+ Index := Index + Socket_Img'Length;
+ end;
+ end loop;
+
+ return "[" & Last_Img & "]" & Buffer (1 .. Index - 1);
+ end;
+ end Image;
+
---------------
-- Inet_Addr --
---------------
function Inet_Addr (Image : String) return Inet_Addr_Type is
+ use Interfaces.C;
use Interfaces.C.Strings;
- Img : chars_ptr;
+ Img : aliased char_array := To_C (Image);
+ Addr : aliased C.int;
Res : C.int;
Result : Inet_Addr_Type;
begin
- -- Special case for the all-ones broadcast address: this address
- -- has the same in_addr_t value as Failure, and thus cannot be
- -- properly returned by inet_addr(3).
-
- if Image = "255.255.255.255" then
- return Broadcast_Inet_Addr;
-
-- Special case for an empty Image as on some platforms (e.g. Windows)
-- calling Inet_Addr("") will not return an error.
- elsif Image = "" then
- Raise_Socket_Error (Constants.EINVAL);
+ if Image = "" then
+ Raise_Socket_Error (SOSC.EINVAL);
end if;
- Img := New_String (Image);
- Res := C_Inet_Addr (Img);
- Free (Img);
+ Res := Inet_Pton (SOSC.AF_INET, Img'Address, Addr'Address);
- if Res = Failure then
- Raise_Socket_Error (Constants.EINVAL);
+ if Res < 0 then
+ Raise_Socket_Error (Socket_Errno);
+
+ elsif Res = 0 then
+ Raise_Socket_Error (SOSC.EINVAL);
end if;
- To_Inet_Addr (To_In_Addr (Res), Result);
+ To_Inet_Addr (To_In_Addr (Addr), Result);
return Result;
end Inet_Addr;
-- Initialize --
----------------
- procedure Initialize (Process_Blocking_IO : Boolean := False) is
+ procedure Initialize (X : in out Sockets_Library_Controller) is
+ pragma Unreferenced (X);
+
begin
- if not Initialized then
- Initialized := True;
- Thin.Initialize (Process_Blocking_IO);
+ Thin.Initialize;
+ end Initialize;
+
+ ----------------
+ -- Initialize --
+ ----------------
+
+ procedure Initialize (Process_Blocking_IO : Boolean) is
+ Expected : constant Boolean := not SOSC.Thread_Blocking_IO;
+
+ begin
+ if Process_Blocking_IO /= Expected then
+ raise Socket_Error with
+ "incorrect Process_Blocking_IO setting, expected " & Expected'Img;
end if;
+
+ -- This is a dummy placeholder for an obsolete API
+
+ -- Real initialization actions are in Initialize primitive operation
+ -- of Sockets_Library_Controller.
+
+ null;
+ end Initialize;
+
+ ----------------
+ -- Initialize --
+ ----------------
+
+ procedure Initialize is
+ begin
+ -- This is a dummy placeholder for an obsolete API
+
+ -- Real initialization actions are in Initialize primitive operation
+ -- of Sockets_Library_Controller.
+
+ null;
end Initialize;
--------------
return True;
end Is_IP_Address;
+ -------------
+ -- Is_Open --
+ -------------
+
+ function Is_Open (S : Selector_Type) return Boolean is
+ begin
+ if S.Is_Null then
+ return True;
+
+ else
+ -- Either both controlling socket descriptors are valid (case of an
+ -- open selector) or neither (case of a closed selector).
+
+ pragma Assert ((S.R_Sig_Socket /= No_Socket)
+ =
+ (S.W_Sig_Socket /= No_Socket));
+
+ return S.R_Sig_Socket /= No_Socket;
+ end if;
+ end Is_Open;
+
------------
-- Is_Set --
------------
begin
return Item.Last /= No_Socket
and then Socket <= Item.Last
- and then Is_Socket_In_Set (Item.Set, C.int (Socket)) /= 0;
+ and then Is_Socket_In_Set (Item.Set'Access, C.int (Socket)) /= 0;
end Is_Set;
-------------------
procedure Listen_Socket
(Socket : Socket_Type;
- Length : Positive := 15)
+ Length : Natural := 15)
is
Res : constant C.int := C_Listen (C.int (Socket), C.int (Length));
begin
procedure Narrow (Item : in out Socket_Set_Type) is
Last : aliased C.int := C.int (Item.Last);
begin
- if Item.Set /= No_Socket_Set then
- Last_Socket_In_Set (Item.Set, Last'Unchecked_Access);
+ if Item.Last /= No_Socket then
+ Last_Socket_In_Set (Item.Set'Access, Last'Unchecked_Access);
Item.Last := Socket_Type (Last);
end if;
end Narrow;
+ ----------------
+ -- Netdb_Lock --
+ ----------------
+
+ procedure Netdb_Lock is
+ begin
+ if Need_Netdb_Lock then
+ System.Task_Lock.Lock;
+ end if;
+ end Netdb_Lock;
+
+ ------------------
+ -- Netdb_Unlock --
+ ------------------
+
+ procedure Netdb_Unlock is
+ begin
+ if Need_Netdb_Lock then
+ System.Task_Lock.Unlock;
+ end if;
+ end Netdb_Unlock;
+
+ --------------------------------
+ -- Normalize_Empty_Socket_Set --
+ --------------------------------
+
+ procedure Normalize_Empty_Socket_Set (S : in out Socket_Set_Type) is
+ begin
+ if S.Last = No_Socket then
+ Reset_Socket_Set (S.Set'Access);
+ end if;
+ end Normalize_Empty_Socket_Set;
+
-------------------
-- Official_Name --
-------------------
return To_String (S.Official);
end Official_Name;
+ --------------------
+ -- Wait_On_Socket --
+ --------------------
+
+ procedure Wait_On_Socket
+ (Socket : Socket_Type;
+ For_Read : Boolean;
+ Timeout : Selector_Duration;
+ Selector : access Selector_Type := null;
+ Status : out Selector_Status)
+ is
+ type Local_Selector_Access is access Selector_Type;
+ for Local_Selector_Access'Storage_Size use Selector_Type'Size;
+
+ S : Selector_Access;
+ -- Selector to use for waiting
+
+ R_Fd_Set : Socket_Set_Type;
+ W_Fd_Set : Socket_Set_Type;
+
+ begin
+ -- Create selector if not provided by the user
+
+ if Selector = null then
+ declare
+ Local_S : constant Local_Selector_Access := new Selector_Type;
+ begin
+ S := Local_S.all'Unchecked_Access;
+ Create_Selector (S.all);
+ end;
+
+ else
+ S := Selector.all'Access;
+ end if;
+
+ if For_Read then
+ Set (R_Fd_Set, Socket);
+ else
+ Set (W_Fd_Set, Socket);
+ end if;
+
+ Check_Selector (S.all, R_Fd_Set, W_Fd_Set, Status, Timeout);
+
+ if Selector = null then
+ Close_Selector (S.all);
+ end if;
+ end Wait_On_Socket;
+
-----------------
-- Port_Number --
-----------------
----------------------
procedure Raise_Host_Error (H_Error : Integer) is
-
- function Host_Error_Message return String;
- -- We do not use a C function like strerror because hstrerror that would
- -- correspond is obsolete. Return appropriate string for error value.
-
- ------------------------
- -- Host_Error_Message --
- ------------------------
-
- function Host_Error_Message return String is
- begin
- case H_Error is
- when Constants.HOST_NOT_FOUND => return "Host not found";
- when Constants.TRY_AGAIN => return "Try again";
- when Constants.NO_RECOVERY => return "No recovery";
- when Constants.NO_DATA => return "No address";
- when others => return "Unknown error";
- end case;
- end Host_Error_Message;
-
- -- Start of processing for Raise_Host_Error
-
begin
- Ada.Exceptions.Raise_Exception (Host_Error'Identity,
+ raise Host_Error with
Err_Code_Image (H_Error)
- & Host_Error_Message);
+ & C.Strings.Value (Host_Error_Messages.Host_Error_Message (H_Error));
end Raise_Host_Error;
------------------------
procedure Raise_Socket_Error (Error : Integer) is
use type C.Strings.chars_ptr;
begin
- Ada.Exceptions.Raise_Exception (Socket_Error'Identity,
+ raise Socket_Error with
Err_Code_Image (Error)
- & C.Strings.Value (Socket_Error_Message (Error)));
+ & C.Strings.Value (Socket_Error_Message (Error));
end Raise_Socket_Error;
----------
Index,
Stream.From);
- Last := Index;
+ Last := Index;
-- Exit when all or zero data received. Zero means that the socket
-- peer is closed.
Item : out Ada.Streams.Stream_Element_Array;
Last : out Ada.Streams.Stream_Element_Offset)
is
+ pragma Warnings (Off, Stream);
+
First : Ada.Streams.Stream_Element_Offset := Item'First;
Index : Ada.Streams.Stream_Element_Offset := First - 1;
Max : constant Ada.Streams.Stream_Element_Offset := Item'Last;
Last : out Ada.Streams.Stream_Element_Offset;
Flags : Request_Flag_Type := No_Request_Flag)
is
- use type Ada.Streams.Stream_Element_Offset;
-
Res : C.int;
begin
- Res := C_Recv
- (C.int (Socket),
- Item (Item'First)'Address,
- Item'Length,
- To_Int (Flags));
+ Res :=
+ C_Recv (C.int (Socket), Item'Address, Item'Length, To_Int (Flags));
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
end if;
- Last := Item'First + Ada.Streams.Stream_Element_Offset (Res - 1);
+ Last := Last_Index (First => Item'First, Count => size_t (Res));
end Receive_Socket;
--------------------
From : out Sock_Addr_Type;
Flags : Request_Flag_Type := No_Request_Flag)
is
- use type Ada.Streams.Stream_Element_Offset;
-
Res : C.int;
Sin : aliased Sockaddr_In;
Len : aliased C.int := Sin'Size / 8;
Res :=
C_Recvfrom
(C.int (Socket),
- Item (Item'First)'Address,
+ Item'Address,
Item'Length,
To_Int (Flags),
- Sin'Unchecked_Access,
- Len'Unchecked_Access);
+ Sin'Address,
+ Len'Access);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
end if;
- Last := Item'First + Ada.Streams.Stream_Element_Offset (Res - 1);
+ Last := Last_Index (First => Item'First, Count => size_t (Res));
To_Inet_Addr (Sin.Sin_Addr, From.Addr);
From.Port := Port_Type (Network_To_Short (Sin.Sin_Port));
end Receive_Socket;
+ --------------------
+ -- Receive_Vector --
+ --------------------
+
+ procedure Receive_Vector
+ (Socket : Socket_Type;
+ Vector : Vector_Type;
+ Count : out Ada.Streams.Stream_Element_Count;
+ Flags : Request_Flag_Type := No_Request_Flag)
+ is
+ Res : ssize_t;
+
+ Msg : Msghdr :=
+ (Msg_Name => System.Null_Address,
+ Msg_Namelen => 0,
+ Msg_Iov => Vector'Address,
+
+ -- recvmsg(2) returns EMSGSIZE on Linux (and probably on other
+ -- platforms) when the supplied vector is longer than IOV_MAX,
+ -- so use minimum of the two lengths.
+
+ Msg_Iovlen => SOSC.Msg_Iovlen_T'Min
+ (Vector'Length, SOSC.IOV_MAX),
+
+ Msg_Control => System.Null_Address,
+ Msg_Controllen => 0,
+ Msg_Flags => 0);
+
+ begin
+ Res :=
+ C_Recvmsg
+ (C.int (Socket),
+ Msg'Address,
+ To_Int (Flags));
+
+ if Res = ssize_t (Failure) then
+ Raise_Socket_Error (Socket_Errno);
+ end if;
+
+ Count := Ada.Streams.Stream_Element_Count (Res);
+ end Receive_Vector;
+
-------------------
-- Resolve_Error --
-------------------
(Error_Value : Integer;
From_Errno : Boolean := True) return Error_Type
is
- use GNAT.Sockets.Constants;
+ use GNAT.Sockets.SOSC;
begin
if not From_Errno then
case Error_Value is
- when Constants.HOST_NOT_FOUND => return Unknown_Host;
- when Constants.TRY_AGAIN => return Host_Name_Lookup_Failure;
- when Constants.NO_RECOVERY =>
- return Non_Recoverable_Error;
- when Constants.NO_DATA => return Unknown_Server_Error;
- when others => return Cannot_Resolve_Error;
+ when SOSC.HOST_NOT_FOUND => return Unknown_Host;
+ when SOSC.TRY_AGAIN => return Host_Name_Lookup_Failure;
+ when SOSC.NO_RECOVERY => return Non_Recoverable_Error;
+ when SOSC.NO_DATA => return Unknown_Server_Error;
+ when others => return Cannot_Resolve_Error;
end case;
end if;
- case Error_Value is
- when ENOERROR => return Success;
- when EACCES => return Permission_Denied;
- when EADDRINUSE => return Address_Already_In_Use;
- when EADDRNOTAVAIL => return Cannot_Assign_Requested_Address;
- when EAFNOSUPPORT =>
- return Address_Family_Not_Supported_By_Protocol;
- when EALREADY => return Operation_Already_In_Progress;
- when EBADF => return Bad_File_Descriptor;
- when ECONNABORTED => return Software_Caused_Connection_Abort;
- when ECONNREFUSED => return Connection_Refused;
- when ECONNRESET => return Connection_Reset_By_Peer;
- when EDESTADDRREQ => return Destination_Address_Required;
- when EFAULT => return Bad_Address;
- when EHOSTDOWN => return Host_Is_Down;
- when EHOSTUNREACH => return No_Route_To_Host;
- when EINPROGRESS => return Operation_Now_In_Progress;
- when EINTR => return Interrupted_System_Call;
- when EINVAL => return Invalid_Argument;
- when EIO => return Input_Output_Error;
- when EISCONN => return Transport_Endpoint_Already_Connected;
- when ELOOP => return Too_Many_Symbolic_Links;
- when EMFILE => return Too_Many_Open_Files;
- when EMSGSIZE => return Message_Too_Long;
- when ENAMETOOLONG => return File_Name_Too_Long;
- when ENETDOWN => return Network_Is_Down;
- when ENETRESET =>
- return Network_Dropped_Connection_Because_Of_Reset;
- when ENETUNREACH => return Network_Is_Unreachable;
- when ENOBUFS => return No_Buffer_Space_Available;
- when ENOPROTOOPT => return Protocol_Not_Available;
- when ENOTCONN => return Transport_Endpoint_Not_Connected;
- when ENOTSOCK => return Socket_Operation_On_Non_Socket;
- when EOPNOTSUPP => return Operation_Not_Supported;
- when EPFNOSUPPORT => return Protocol_Family_Not_Supported;
- when EPROTONOSUPPORT => return Protocol_Not_Supported;
- when EPROTOTYPE => return Protocol_Wrong_Type_For_Socket;
- when ESHUTDOWN =>
- return Cannot_Send_After_Transport_Endpoint_Shutdown;
- when ESOCKTNOSUPPORT => return Socket_Type_Not_Supported;
- when ETIMEDOUT => return Connection_Timed_Out;
- when ETOOMANYREFS => return Too_Many_References;
- when EWOULDBLOCK => return Resource_Temporarily_Unavailable;
- when others => null;
- end case;
+ -- Special case: EAGAIN may be the same value as EWOULDBLOCK, so we
+ -- can't include it in the case statement below.
+
+ pragma Warnings (Off);
+ -- Condition "EAGAIN /= EWOULDBLOCK" is known at compile time
+
+ if EAGAIN /= EWOULDBLOCK and then Error_Value = EAGAIN then
+ return Resource_Temporarily_Unavailable;
+ end if;
+
+ -- This is not a case statement because if a particular error
+ -- number constant is not defined, s-oscons-tmplt.c defines
+ -- it to -1. If multiple constants are not defined, they
+ -- would each be -1 and result in a "duplicate value in case" error.
+ --
+ -- But we have to leave warnings off because the compiler is also
+ -- smart enough to note that when two errnos have the same value,
+ -- the second if condition is useless.
+ if Error_Value = ENOERROR then
+ return Success;
+ elsif Error_Value = EACCES then
+ return Permission_Denied;
+ elsif Error_Value = EADDRINUSE then
+ return Address_Already_In_Use;
+ elsif Error_Value = EADDRNOTAVAIL then
+ return Cannot_Assign_Requested_Address;
+ elsif Error_Value = EAFNOSUPPORT then
+ return Address_Family_Not_Supported_By_Protocol;
+ elsif Error_Value = EALREADY then
+ return Operation_Already_In_Progress;
+ elsif Error_Value = EBADF then
+ return Bad_File_Descriptor;
+ elsif Error_Value = ECONNABORTED then
+ return Software_Caused_Connection_Abort;
+ elsif Error_Value = ECONNREFUSED then
+ return Connection_Refused;
+ elsif Error_Value = ECONNRESET then
+ return Connection_Reset_By_Peer;
+ elsif Error_Value = EDESTADDRREQ then
+ return Destination_Address_Required;
+ elsif Error_Value = EFAULT then
+ return Bad_Address;
+ elsif Error_Value = EHOSTDOWN then
+ return Host_Is_Down;
+ elsif Error_Value = EHOSTUNREACH then
+ return No_Route_To_Host;
+ elsif Error_Value = EINPROGRESS then
+ return Operation_Now_In_Progress;
+ elsif Error_Value = EINTR then
+ return Interrupted_System_Call;
+ elsif Error_Value = EINVAL then
+ return Invalid_Argument;
+ elsif Error_Value = EIO then
+ return Input_Output_Error;
+ elsif Error_Value = EISCONN then
+ return Transport_Endpoint_Already_Connected;
+ elsif Error_Value = ELOOP then
+ return Too_Many_Symbolic_Links;
+ elsif Error_Value = EMFILE then
+ return Too_Many_Open_Files;
+ elsif Error_Value = EMSGSIZE then
+ return Message_Too_Long;
+ elsif Error_Value = ENAMETOOLONG then
+ return File_Name_Too_Long;
+ elsif Error_Value = ENETDOWN then
+ return Network_Is_Down;
+ elsif Error_Value = ENETRESET then
+ return Network_Dropped_Connection_Because_Of_Reset;
+ elsif Error_Value = ENETUNREACH then
+ return Network_Is_Unreachable;
+ elsif Error_Value = ENOBUFS then
+ return No_Buffer_Space_Available;
+ elsif Error_Value = ENOPROTOOPT then
+ return Protocol_Not_Available;
+ elsif Error_Value = ENOTCONN then
+ return Transport_Endpoint_Not_Connected;
+ elsif Error_Value = ENOTSOCK then
+ return Socket_Operation_On_Non_Socket;
+ elsif Error_Value = EOPNOTSUPP then
+ return Operation_Not_Supported;
+ elsif Error_Value = EPFNOSUPPORT then
+ return Protocol_Family_Not_Supported;
+ elsif Error_Value = EPIPE then
+ return Broken_Pipe;
+ elsif Error_Value = EPROTONOSUPPORT then
+ return Protocol_Not_Supported;
+ elsif Error_Value = EPROTOTYPE then
+ return Protocol_Wrong_Type_For_Socket;
+ elsif Error_Value = ESHUTDOWN then
+ return Cannot_Send_After_Transport_Endpoint_Shutdown;
+ elsif Error_Value = ESOCKTNOSUPPORT then
+ return Socket_Type_Not_Supported;
+ elsif Error_Value = ETIMEDOUT then
+ return Connection_Timed_Out;
+ elsif Error_Value = ETOOMANYREFS then
+ return Too_Many_References;
+ elsif Error_Value = EWOULDBLOCK then
+ return Resource_Temporarily_Unavailable;
+ else
+ return Cannot_Resolve_Error;
+ end if;
+ pragma Warnings (On);
- return Cannot_Resolve_Error;
end Resolve_Error;
-----------------------
if Id = Socket_Error_Id then
return Resolve_Error (Val);
+
elsif Id = Host_Error_Id then
return Resolve_Error (Val, False);
+
else
return Cannot_Resolve_Error;
end if;
end Resolve_Exception;
- --------------------
- -- Receive_Vector --
- --------------------
+ -----------------
+ -- Send_Socket --
+ -----------------
- procedure Receive_Vector
+ procedure Send_Socket
(Socket : Socket_Type;
- Vector : Vector_Type;
- Count : out Ada.Streams.Stream_Element_Count)
+ Item : Ada.Streams.Stream_Element_Array;
+ Last : out Ada.Streams.Stream_Element_Offset;
+ Flags : Request_Flag_Type := No_Request_Flag)
is
- Res : C.int;
-
begin
- Res :=
- C_Readv
- (C.int (Socket),
- Vector (Vector'First)'Address,
- Vector'Length);
-
- if Res = Failure then
- Raise_Socket_Error (Socket_Errno);
- end if;
-
- Count := Ada.Streams.Stream_Element_Count (Res);
- end Receive_Vector;
+ Send_Socket (Socket, Item, Last, To => null, Flags => Flags);
+ end Send_Socket;
-----------------
-- Send_Socket --
(Socket : Socket_Type;
Item : Ada.Streams.Stream_Element_Array;
Last : out Ada.Streams.Stream_Element_Offset;
+ To : Sock_Addr_Type;
Flags : Request_Flag_Type := No_Request_Flag)
is
- use type Ada.Streams.Stream_Element_Offset;
-
- Res : C.int;
-
begin
- Res :=
- C_Send
- (C.int (Socket),
- Item (Item'First)'Address,
- Item'Length,
- Set_Forced_Flags (To_Int (Flags)));
-
- if Res = Failure then
- Raise_Socket_Error (Socket_Errno);
- end if;
-
- Last := Item'First + Ada.Streams.Stream_Element_Offset (Res - 1);
+ Send_Socket
+ (Socket, Item, Last, To => To'Unrestricted_Access, Flags => Flags);
end Send_Socket;
-----------------
(Socket : Socket_Type;
Item : Ada.Streams.Stream_Element_Array;
Last : out Ada.Streams.Stream_Element_Offset;
- To : Sock_Addr_Type;
+ To : access Sock_Addr_Type;
Flags : Request_Flag_Type := No_Request_Flag)
is
- use type Ada.Streams.Stream_Element_Offset;
+ Res : C.int;
- Res : C.int;
- Sin : aliased Sockaddr_In;
- Len : constant C.int := Sin'Size / 8;
+ Sin : aliased Sockaddr_In;
+ C_To : System.Address;
+ Len : C.int;
begin
- Set_Length (Sin'Unchecked_Access, Len);
- Set_Family (Sin'Unchecked_Access, Families (To.Family));
- Set_Address (Sin'Unchecked_Access, To_In_Addr (To.Addr));
- Set_Port
- (Sin'Unchecked_Access,
- Short_To_Network (C.unsigned_short (To.Port)));
+ if To /= null then
+ Set_Family (Sin.Sin_Family, To.Family);
+ Set_Address (Sin'Unchecked_Access, To_In_Addr (To.Addr));
+ Set_Port
+ (Sin'Unchecked_Access,
+ Short_To_Network (C.unsigned_short (To.Port)));
+ C_To := Sin'Address;
+ Len := Sin'Size / 8;
+
+ else
+ C_To := System.Null_Address;
+ Len := 0;
+ end if;
Res := C_Sendto
(C.int (Socket),
- Item (Item'First)'Address,
+ Item'Address,
Item'Length,
Set_Forced_Flags (To_Int (Flags)),
- Sin'Unchecked_Access,
+ C_To,
Len);
if Res = Failure then
Raise_Socket_Error (Socket_Errno);
end if;
- Last := Item'First + Ada.Streams.Stream_Element_Offset (Res - 1);
+ Last := Last_Index (First => Item'First, Count => size_t (Res));
end Send_Socket;
-----------------
procedure Send_Vector
(Socket : Socket_Type;
Vector : Vector_Type;
- Count : out Ada.Streams.Stream_Element_Count)
+ Count : out Ada.Streams.Stream_Element_Count;
+ Flags : Request_Flag_Type := No_Request_Flag)
is
- Res : C.int;
- Iov_Count : C.int;
- This_Iov_Count : C.int;
+ use SOSC;
+ use Interfaces.C;
+
+ Res : ssize_t;
+ Iov_Count : SOSC.Msg_Iovlen_T;
+ This_Iov_Count : SOSC.Msg_Iovlen_T;
+ Msg : Msghdr;
begin
Count := 0;
pragma Warnings (Off);
-- Following test may be compile time known on some targets
- if Vector'Length - Iov_Count > Constants.IOV_MAX then
- This_Iov_Count := Constants.IOV_MAX;
- else
- This_Iov_Count := Vector'Length - Iov_Count;
- end if;
+ This_Iov_Count :=
+ (if Vector'Length - Iov_Count > SOSC.IOV_MAX
+ then SOSC.IOV_MAX
+ else Vector'Length - Iov_Count);
pragma Warnings (On);
+ Msg :=
+ (Msg_Name => System.Null_Address,
+ Msg_Namelen => 0,
+ Msg_Iov => Vector
+ (Vector'First + Integer (Iov_Count))'Address,
+ Msg_Iovlen => This_Iov_Count,
+ Msg_Control => System.Null_Address,
+ Msg_Controllen => 0,
+ Msg_Flags => 0);
+
Res :=
- C_Writev
+ C_Sendmsg
(C.int (Socket),
- Vector (Vector'First + Integer (Iov_Count))'Address,
- This_Iov_Count);
+ Msg'Address,
+ Set_Forced_Flags (To_Int (Flags)));
- if Res = Failure then
+ if Res = ssize_t (Failure) then
Raise_Socket_Error (Socket_Errno);
end if;
procedure Set (Item : in out Socket_Set_Type; Socket : Socket_Type) is
begin
- if Item.Set = No_Socket_Set then
- Item.Set := New_Socket_Set (No_Socket_Set);
+ if Item.Last = No_Socket then
+
+ -- Uninitialized socket set, make sure it is properly zeroed out
+
+ Reset_Socket_Set (Item.Set'Access);
Item.Last := Socket;
elsif Item.Last < Socket then
Item.Last := Socket;
end if;
- Insert_Socket_In_Set (Item.Set, C.int (Socket));
+ Insert_Socket_In_Set (Item.Set'Access, C.int (Socket));
end Set;
----------------------
function To_int is
new Ada.Unchecked_Conversion (C.unsigned, C.int);
begin
- return To_int (To_unsigned (F) or Constants.MSG_Forced_Flags);
+ return To_int (To_unsigned (F) or SOSC.MSG_Forced_Flags);
end Set_Forced_Flags;
-----------------------
Level : Level_Type := Socket_Level;
Option : Option_Type)
is
- V8 : aliased Two_Int;
+ V8 : aliased Two_Ints;
V4 : aliased C.int;
V1 : aliased C.unsigned_char;
VT : aliased Timeval;
Len := V1'Size / 8;
Add := V1'Address;
- when Multicast_Loop =>
+ when Multicast_Loop |
+ Receive_Packet_Info =>
V1 := C.unsigned_char (Boolean'Pos (Option.Enabled));
Len := V1'Size / 8;
Add := V1'Address;
return Stream_Access (S);
end Stream;
+ ------------------
+ -- Stream_Write --
+ ------------------
+
+ procedure Stream_Write
+ (Socket : Socket_Type;
+ Item : Ada.Streams.Stream_Element_Array;
+ To : access Sock_Addr_Type)
+ is
+ First : Ada.Streams.Stream_Element_Offset;
+ Index : Ada.Streams.Stream_Element_Offset;
+ Max : constant Ada.Streams.Stream_Element_Offset := Item'Last;
+
+ begin
+ First := Item'First;
+ Index := First - 1;
+ while First <= Max loop
+ Send_Socket (Socket, Item (First .. Max), Index, To);
+
+ -- Exit when all or zero data sent. Zero means that the socket has
+ -- been closed by peer.
+
+ exit when Index < First or else Index = Max;
+
+ First := Index + 1;
+ end loop;
+
+ -- For an empty array, we have First > Max, and hence Index >= Max (no
+ -- error, the loop above is never executed). After a succesful send,
+ -- Index = Max. The only remaining case, Index < Max, is therefore
+ -- always an actual send failure.
+
+ if Index < Max then
+ Raise_Socket_Error (Socket_Errno);
+ end if;
+ end Stream_Write;
+
----------
-- To_C --
----------
-- To_Host_Entry --
-------------------
- function To_Host_Entry (E : Hostent) return Host_Entry_Type is
+ function To_Host_Entry (E : Hostent_Access) return Host_Entry_Type is
use type C.size_t;
+ use C.Strings;
- Official : constant String :=
- C.Strings.Value (E.H_Name);
-
- Aliases : constant Chars_Ptr_Array :=
- Chars_Ptr_Pointers.Value (E.H_Aliases);
- -- H_Aliases points to a list of name aliases. The list is terminated by
- -- a NULL pointer.
+ Aliases_Count, Addresses_Count : Natural;
- Addresses : constant In_Addr_Access_Array :=
- In_Addr_Access_Pointers.Value (E.H_Addr_List);
- -- H_Addr_List points to a list of binary addresses (in network byte
- -- order). The list is terminated by a NULL pointer.
- --
- -- H_Length is not used because it is currently only set to 4.
+ -- H_Length is not used because it is currently only set to 4
-- H_Addrtype is always AF_INET
- Result : Host_Entry_Type
- (Aliases_Length => Aliases'Length - 1,
- Addresses_Length => Addresses'Length - 1);
- -- The last element is a null pointer
-
- Source : C.size_t;
- Target : Natural;
-
begin
- Result.Official := To_Name (Official);
-
- Source := Aliases'First;
- Target := Result.Aliases'First;
- while Target <= Result.Aliases_Length loop
- Result.Aliases (Target) :=
- To_Name (C.Strings.Value (Aliases (Source)));
- Source := Source + 1;
- Target := Target + 1;
+ Aliases_Count := 0;
+ while Hostent_H_Alias (E, C.int (Aliases_Count)) /= Null_Address loop
+ Aliases_Count := Aliases_Count + 1;
end loop;
- Source := Addresses'First;
- Target := Result.Addresses'First;
- while Target <= Result.Addresses_Length loop
- To_Inet_Addr (Addresses (Source).all, Result.Addresses (Target));
- Source := Source + 1;
- Target := Target + 1;
+ Addresses_Count := 0;
+ while Hostent_H_Addr (E, C.int (Addresses_Count)) /= Null_Address loop
+ Addresses_Count := Addresses_Count + 1;
end loop;
- return Result;
+ return Result : Host_Entry_Type
+ (Aliases_Length => Aliases_Count,
+ Addresses_Length => Addresses_Count)
+ do
+ Result.Official := To_Name (Value (Hostent_H_Name (E)));
+
+ for J in Result.Aliases'Range loop
+ Result.Aliases (J) :=
+ To_Name (Value (Hostent_H_Alias
+ (E, C.int (J - Result.Aliases'First))));
+ end loop;
+
+ for J in Result.Addresses'Range loop
+ declare
+ Addr : In_Addr;
+ for Addr'Address use
+ Hostent_H_Addr (E, C.int (J - Result.Addresses'First));
+ pragma Import (Ada, Addr);
+ begin
+ To_Inet_Addr (Addr, Result.Addresses (J));
+ end;
+ end loop;
+ end return;
end To_Host_Entry;
----------------
-- To_In_Addr --
----------------
- function To_In_Addr (Addr : Inet_Addr_Type) return Thin.In_Addr is
+ function To_In_Addr (Addr : Inet_Addr_Type) return In_Addr is
begin
if Addr.Family = Family_Inet then
return (S_B1 => C.unsigned_char (Addr.Sin_V4 (1)),
S_B4 => C.unsigned_char (Addr.Sin_V4 (4)));
end if;
- raise Socket_Error;
+ raise Socket_Error with "IPv6 not supported";
end To_In_Addr;
------------------
if Current mod 2 /= 0 then
if Flags (J) = -1 then
- Raise_Socket_Error (Constants.EOPNOTSUPP);
+ Raise_Socket_Error (SOSC.EOPNOTSUPP);
end if;
Result := Result + Flags (J);
-- To_Service_Entry --
----------------------
- function To_Service_Entry (E : Servent) return Service_Entry_Type is
+ function To_Service_Entry (E : Servent_Access) return Service_Entry_Type is
+ use C.Strings;
use type C.size_t;
- Official : constant String :=
- C.Strings.Value (E.S_Name);
-
- Aliases : constant Chars_Ptr_Array :=
- Chars_Ptr_Pointers.Value (E.S_Aliases);
- -- S_Aliases points to a list of name aliases. The list is
- -- terminated by a NULL pointer.
-
- Protocol : constant String :=
- C.Strings.Value (E.S_Proto);
-
- Result : Service_Entry_Type
- (Aliases_Length => Aliases'Length - 1);
- -- The last element is a null pointer
-
- Source : C.size_t;
- Target : Natural;
+ Aliases_Count : Natural;
begin
- Result.Official := To_Name (Official);
-
- Source := Aliases'First;
- Target := Result.Aliases'First;
- while Target <= Result.Aliases_Length loop
- Result.Aliases (Target) :=
- To_Name (C.Strings.Value (Aliases (Source)));
- Source := Source + 1;
- Target := Target + 1;
+ Aliases_Count := 0;
+ while Servent_S_Alias (E, C.int (Aliases_Count)) /= Null_Address loop
+ Aliases_Count := Aliases_Count + 1;
end loop;
- Result.Port :=
- Port_Type (Network_To_Short (C.unsigned_short (E.S_Port)));
+ return Result : Service_Entry_Type (Aliases_Length => Aliases_Count) do
+ Result.Official := To_Name (Value (Servent_S_Name (E)));
- Result.Protocol := To_Name (Protocol);
+ for J in Result.Aliases'Range loop
+ Result.Aliases (J) :=
+ To_Name (Value (Servent_S_Alias
+ (E, C.int (J - Result.Aliases'First))));
+ end loop;
- return Result;
+ Result.Protocol := To_Name (Value (Servent_S_Proto (E)));
+ Result.Port :=
+ Port_Type (Network_To_Short (Servent_S_Port (E)));
+ end return;
end To_Service_Entry;
---------------
end To_Timeval;
-----------
+ -- Value --
+ -----------
+
+ function Value (S : System.Address) return String is
+ Str : String (1 .. Positive'Last);
+ for Str'Address use S;
+ pragma Import (Ada, Str);
+
+ Terminator : Positive := Str'First;
+
+ begin
+ while Str (Terminator) /= ASCII.NUL loop
+ Terminator := Terminator + 1;
+ end loop;
+
+ return Str (1 .. Terminator - 1);
+ end Value;
+
+ -----------
-- Write --
-----------
(Stream : in out Datagram_Socket_Stream_Type;
Item : Ada.Streams.Stream_Element_Array)
is
- First : Ada.Streams.Stream_Element_Offset := Item'First;
- Index : Ada.Streams.Stream_Element_Offset := First - 1;
- Max : constant Ada.Streams.Stream_Element_Offset := Item'Last;
-
begin
- loop
- Send_Socket
- (Stream.Socket,
- Item (First .. Max),
- Index,
- Stream.To);
-
- -- Exit when all or zero data sent. Zero means that the socket has
- -- been closed by peer.
-
- exit when Index < First or else Index = Max;
-
- First := Index + 1;
- end loop;
-
- if Index /= Max then
- raise Socket_Error;
- end if;
+ Stream_Write (Stream.Socket, Item, To => Stream.To'Unrestricted_Access);
end Write;
-----------
(Stream : in out Stream_Socket_Stream_Type;
Item : Ada.Streams.Stream_Element_Array)
is
- First : Ada.Streams.Stream_Element_Offset := Item'First;
- Index : Ada.Streams.Stream_Element_Offset := First - 1;
- Max : constant Ada.Streams.Stream_Element_Offset := Item'Last;
-
begin
- loop
- Send_Socket (Stream.Socket, Item (First .. Max), Index);
-
- -- Exit when all or zero data sent. Zero means that the socket has
- -- been closed by peer.
-
- exit when Index < First or else Index = Max;
-
- First := Index + 1;
- end loop;
-
- if Index /= Max then
- raise Socket_Error;
- end if;
+ Stream_Write (Stream.Socket, Item, To => null);
end Write;
+ Sockets_Library_Controller_Object : Sockets_Library_Controller;
+ pragma Unreferenced (Sockets_Library_Controller_Object);
+ -- The elaboration and finalization of this object perform the required
+ -- initialization and cleanup actions for the sockets library.
+
end GNAT.Sockets;