Windows Sockets Windows Sockets An Open Interface for Network Programming under Microsoft Windows Version 1.1 20 January 1993 Martin Hall Mark Towfiq Geoff Arnold David Treadwell Henry Sanders Copyright 1992 by Martin Hall, Mark Towfiq Geoff Arnold, David Treadwell and Henry Sanders All rights reserved. This document may be freely redistributed in any form, electronic or otherwise, provided that it is distributed in its entirety and that the copyright and this notice are included. Comments or questions may be submitted via electronic mail to winsock@microdyne.com. Requests to be added to the Windows Sockets mailing list should be addressed to winsock-request@microdyne.com. This specification, archives of the mailing list, and other information on Windows Sockets are available via anonymous FTP from the host microdyne.com, directory /pub/winsock. Questions about products conforming to this specification should be addressed to the vendors of the products. Portions of the Windows Sockets specification are derived from material which is Copyright (c) 1982- 1986 by the Regents of the University of California. All rights are reserved. The Berkeley Software License Agreement specifies the terms and conditions for redistribution. Revision history: 1.0 Rev.A June 11, 1992 1.0 Rev.B June 16, 1992 1.0 Rev. C October 12, 1992 1.1 January, 1993 ii Windows Sockets Version 1.1 ACKNOWLEDGMENTS..........................................1 1. INTRODUCTION.........................................3 1.1 What is Windows Sockets?........................3 1.2 Berkeley Sockets................................3 1.3 Microsoft Windows and Windows-specific extensions 3 1.4 The Status of this Specification................4 1.5 Revision History................................4 1.5.1 Windows Sockets Version 1.0..............4 1.5.2 Windows Sockets Version 1.1..............4 2. PROGRAMMING WITH SOCKETS.............................6 2.1 Windows Sockets Stack Installation Checking.....6 2.2 Sockets.........................................6 2.2.1 Basic concepts...........................6 2.2.2 Client-server model......................6 2.2.3 Out-of-band data.........................7 2.2.4 Broadcasting.............................7 2.3 Byte Ordering...................................8 2.4 Socket Options..................................8 2.5 Database Files..................................9 2.6 Deviation from Berkeley Sockets.................9 2.6.1 socket data type and error values........10 2.6.2 select() and FD_*........................10 2.6.3 Error codes - errno, h_errno & WSAGetLastError() ...............................................10 2.6.4 Pointers.................................11 2.6.5 Renamed functions........................11 2.6.5.1 close() & closesocket()...........11 2.6.5.1 ioctl() & ioctlsocket()...........11 2.6.6 Blocking routines & EINPROGRESS..........11 2.6.7 Maximum number of sockets supported......11 2.6.8 Include files............................12 2.6.9 Return values on API failure.............12 2.6.10 Raw Sockets.............................12 2.7 Windows Sockets in Multithreaded Versions of Windows ....................................................12 3. SOCKET LIBRARY OVERVIEW..............................14 3.1 Socket Functions................................14 3.1.1 Blocking/Non blocking & Data Volatility..14 3.2 Database Functions..............................15 3.3 Microsoft Windows-specific Extension Functions..16 3.3.1 Asynchronous select() Mechanism..........17 3.3.2 Asynchronous Support Routines............17 3.3.3 Hooking Blocking Methods.................17 3.3.4 Error Handling...........................18 3.3.5 Accessing a Windows Sockets DLL from an Intermediate DLL...............................18 3.3.6 Internal use of Messages by Windows Sockets Implementations................................18 3.3.7 Private API Interfaces...................19 4. SOCKET LIBRARY REFERENCE.............................20 4.1 Socket Routines.................................20 4.1.1 accept().................................21 4.1.2 bind()...................................23 4.1.3 closesocket()............................25 4.1.4 connect()................................27 4.1.5 getpeername()............................29 4.1.6 getsockname()............................30 4.1.7 getsockopt().............................31 4.1.8 htonl()..................................33 4.1.9 htons()..................................34 iii 4.1.10 inet_addr().............................35 4.1.11 inet_ntoa().............................36 4.1.12 ioctlsocket()...........................37 4.1.13 listen()................................39 4.1.14 ntohl().................................41 4.1.15 ntohs().................................42 4.1.16 recv()..................................43 4.1.17 recvfrom()..............................45 4.1.18 select()................................48 4.1.19 send()..................................50 4.1.20 sendto()................................52 4.1.21 setsockopt()............................55 4.1.22 shutdown()..............................58 4.1.23 socket()................................60 4.2 Database Routines...............................62 4.2.1 gethostbyaddr()..........................62 4.2.2 gethostbyname()..........................64 4.2.3 gethostname()............................65 4.2.4 getprotobyname().........................66 4.2.5 getprotobynumber().......................68 4.2.6 getservbyname()..........................69 4.2.7 getservbyport()..........................71 4.3 Microsoft Windows-specific Extensions...........72 4.3.1 WSAAsyncGetHostByAddr()..................72 4.3.2 WSAAsyncGetHostByName()..................75 4.3.3 WSAAsyncGetProtoByName().................78 4.3.4 WSAAsyncGetProtoByNumber()...............81 4.3.5 WSAAsyncGetServByName()..................84 4.3.6 WSAAsyncGetServByPort()..................87 4.3.7 WSAAsyncSelect().........................90 4.3.8 WSACancelAsyncRequest()..................96 4.3.9 WSACancelBlockingCall()..................98 4.3.10 WSACleanup()............................100 4.3.11 WSAGetLastError().......................102 4.3.12 WSAIsBlocking().........................103 4.3.13 WSASetBlockingHook()....................104 4.3.14 WSASetLastError().......................106 4.3.15 WSAStartup()............................107 4.3.16 WSAUnhookBlockingHook().................111 Appendix A. Error Codes and Header Files................112 A.1 Error Codes.....................................112 A.2 Header Files....................................114 A.2.1 Berkeley Header Files....................114 A.2.2 Windows Sockets Header File - winsock.h..115 Appendix B. Notes for Windows Sockets Suppliers.........127 B.1 Introduction....................................127 B.2 Windows Sockets Components......................127 B.2.1 Development Components...................127 B.2.2 Run Time Components......................127 B.3 Multithreadedness and blocking routines.........127 B.4 Database Files..................................128 B.5 FD_ISSET........................................128 B.6 Error Codes.....................................128 B.7 DLL Ordinal Numbers.............................128 B.8 Validation Suite................................129 Appendix C. For Further Reference.......................131 Appendix D. Background Information......................131 D.1 Legal Status of Windows Sockets.................131 D.2 The Story Behind the Windows Sockets Icon.......131 iv Introduction 1 ACKNOWLEDGMENTS The authors would like to thank their companies for allowing them the time and resources to make this specification possible: JSB Corporation, Microdyne Corporation, FTP Software, Sun Microsystems, and Microsoft Corporation. Special thanks should also be extended to the other efforts contributing to the success of Windows Sockets. The original draft was heavily influenced by existing specifications offered and detailed by JSB Corporation and Net Manage, Inc. The "version 1.0 debate" hosted by Microsoft in Seattle allowed many of the members of the working group to hash out final details for 1.0 vis-a-vis. Sun Microsystems was kind enough to allow first time implementors to "plug and play" beta software during the first Windows Sock-A-Thon of Windows Sockets application and implementations at Interops Fall '92. Microsoft has shared WSAT (the Windows Sockets API Tester) with other Windows Sockets implementors as a standard Windows Sockets test suite to aid in testing their implementations. Finally, Sun Microsystems and FTP Software plan to host the Windows Sock-A-Thon II in Boston February '93. Without the contributions of the individuals and corporations involved in the working group, Windows Sockets would never have been as thoroughly reviewed and completed as quickly. In just one year, several competitors in the networking business developed a useful specification with something to show for it! Many thanks to all which participated, either in person or on e-mail to the Windows Sockets effort. The authors would like to thank everyone who participated in any way, and apologize in advance for anyone we have omitted. List of contributors: Martin Hall (Chairman) JSB Corporation martinh@jsbus.com Mark Towfiq (Coordinator) Microdyne Corporation towfiq@microdyne.com Geoff Arnold (Editor 1.0) Sun Microsystems geoff@east.sun.com David Treadwell (Editor 1.1) Microsoft Corporation davidtr@microsoft.com Henry Sanders Microsoft Corporation henrysa@microsoft.com J. Allard Microsoft jallard@microsoft. Corporation com Chris Arap-Bologna Distinct chris@distinct.com Larry Backman FTP Software backman@ftp.com Alistair Banks Microsoft alistair@microsoft Corporation .com Rob Barrow JSB Corporation robb@jsb.co.uk Carl Beame Beame & Whiteside beame@mcmaster,ca Dave Beaver Microsoft dbeaver@microsoft. Corporation com 1 2 Introduction Amatzia BenArtzi NetManage, Inc. amatzia@netmanage. com Mark Beyer Ungermann-Bass mbeyer@ub.com Nelson Bolyard Silicon Graphics, nelson@sgi.com Inc. Pat Bonner Hewlett-Packard p_bonner@cnd.hp.co m Derek Brown FTP Software db@wco.ftp.com Malcolm Butler ICL mcab@oasis.icl.co. uk Mike Calbaum Fronteir mike@frontiertech. Technologies com Isaac Chan Microsoft isaacc@microsoft.c Corporation om Khoji Darbani Informix khoji@informix.com Nestor Fesas Hughes LAN Systems nestor@hls.com Karanja Gakio FTP Software karanja@ftp.com Vikas Garg Distinct vikas@distinct.com Gary Gere Gupta ggere@gupta.com Jim Gilroy Microsoft jamesg@microsoft.c Corporation om Bill Hayes Hewlett-Packard billh@hpchdpc.cnd. hp.com Paul Hill MIT pbh@athena.mit.edu Tmima Koren Net Manage, Inc. tmima@netmanage.co m Hoek Law Citicorp law@dcc.tti.com Graeme Le Roux Moresdawn P/L - Kevin Lewis Novell kevinl@novell.com Roger Lin 3Com roger_lin@3mail.3c om.com Terry Lister Hewlett-Packard tel@cnd.hp.com Jeng Long Jiang Wollongong long@twg.com Lee Murach Network Research lee@nrc.com Pete Ostenson Microsoft peteo@microsoft.co Corporation m David Pool Spry, Inc. dave@spry.com Bob Quinn FTP Software rcq@ftp.com Glenn Reitsma Hughes LAN Systems glennr@hls.com Brad Rice Age rice@age.com Allen Rochkind 3Com - Jonathan Rosen IBM jrosen@vnet.ibm.co m Steve Stokes Novell stoke@novell.com Joseph Tsai 3Com joe_tsai@3mail.3co m.com James Van Bokkelen FTP Software jbvb@ftp.com Miles Wu Wollongong wu@twg.com Boris Yanovsky NetManage, Inc. boris@netmanage.co m Introduction 3 1. INTRODUCTION 1.1 What is Windows Sockets? The Windows Sockets specification defines a network programming interface for Microsoft Windows1 which is based on the "socket" paradigm popularized in the Berkeley Software Distribution (BSD) from the University of California at Berkeley. It encompasses both familiar Berkeley socket style routines and a set of Windows-specific extensions designed to allow the programmer to take advantage of the message-driven nature of Windows. The Windows Sockets Specification is intended to provide a single API to which application developers can program and multiple network software vendors can conform. Furthermore, in the context of a particular version of Microsoft Windows, it defines a binary interface (ABI) such that an application written to the Windows Sockets API can work with a conformant protocol implementation from any network software vendor. This specification thus defines the library calls and associated semantics to which an application developer can program and which a network software vendor can implement. Network software which conforms to this Windows Sockets specification will be considered "Windows Sockets Compliant". Suppliers of interfaces which are "Windows Sockets Compliant" shall be referred to as "Windows Sockets Suppliers". To be Windows Sockets Compliant, a vendor must implement 100% of this Windows Sockets specification. Applications which are capable of operating with any "Windows Sockets Compliant" protocol implementation will be considered as having a "Windows Sockets Interface" and will be referred to as "Windows Sockets Applications". This version of the Windows Sockets specification defines and documents the use of the API in conjunction with the Internet Protocol Suite (IPS, generally referred to as TCP/IP). Specifically, all Windows Sockets implementations support both stream (TCP) and datagram (UDP) sockets. While the use of this API with alternative protocol stacks is not precluded (and is expected to be the subject of future revisions of the specification), such usage is beyond the scope of this version of the specification. 1.2 Berkeley Sockets The Windows Sockets Specification has been built upon the Berkeley Sockets programming model which is the de facto standard for TCP/IP networking. It is intended to provide a high degree of familiarity for programmers who are used to programming with sockets in UNIX2 and other environments, and to simplify the task of porting existing sockets-based source code. The Windows Sockets API is consistent with release 4.3 of the Berkeley Software Distribution (4.3BSD). 1 Windows is a trademark of Microsoft Corporation. 2 UNIX is a trademark of Unix System Laboratories, Inc. 3 4 Introduction Portions of the Windows Sockets specification are derived from material which is Copyright (c) 1982-1986 by the Regents of the University of California. All rights are reserved. The Berkeley Software License Agreement specifies the terms and conditions for redistribution. 1.3 Microsoft Windows and Windows-specific extensions This API is intended to be usable within all implementations and versions of Microsoft Windows from Microsoft Windows Version 3.0 onwards. It thus provides for Windows Sockets implementations and Windows Sockets applications in both 16 and 32 bit operating environments. Windows Sockets makes provisions for multithreaded Windows processes. A process contains one or more threads of execution. In the Windows 3.1 non-multithreaded world, a task corresponds to a process with a single thread. All references to threads in this document refer to actual "threads" in multithreaded Windows environments. In non multithreaded environments (such as Windows 3.0), use of the term thread refers to a Windows process. The Microsoft Windows extensions included in Windows Sockets are provided to allow application developers to create software which conforms to the Windows programming model. It is expected that this will facilitate the creation of robust and high-performance applications, and will improve the cooperative multitasking of applications within non-preemptive versions of Windows. With the exception of WSAStartup() and WSACleanup() their use is not mandatory. 1.4 The Status of this Specification Windows Sockets is an independent specification which was created and exists for the benefit of application developers and network vendors and, indirectly, computer users. Each published (non-draft) version of this specification represents a fully workable API for implementation by network vendors and programming use by application developers. Discussion of this specification and suggested improvements continue and are welcomed. Such discussion occurs mainly via the Internet electronic mail forum winsock@microdyne.com. Meetings of interested parties occur on an irregular basis. Details of these meetings are publicized to the electronic mail forum. 1.5 Revision History 1.5.1 Windows Sockets Version 1.0 Windows Sockets Version 1.0 represented the results of considerable work within the vendor and user community as discussed in Appendix C. This version of the specification was released in order that network software suppliers and application developers could begin to construct implementations and applications which conformed to the Windows Sockets standard. 1.5.2 Windows Sockets Version 1.1 Windows Sockets Version 1.1 follows the guidelines and structure laid out by version 1.0, making changes only where absolutely necessary as Introduction 5 indicated by the experiences of a number of companies that created Windows Sockets implementations based on the version 1.0 specification. Version 1.1 contains several clarifications and minor fixes to version 1.0. Additionally, the following more significant changes were incorporated into version 1.1: o Inclusion of the gethostname() routine to simplify retrieval of the host's name and address. o Definition of DLL ordinal values below 1000 as reserved for Windows Sockets and ordinals above 1000 as unrestricted. This allows Windows Sockets vendors to include private interfaces to their DLLs without risking that the ordinals chosen will conflict with a future version of Windows Sockets. o Addition of a reference count to WSAStartup() and WSACleanup(), requiring correspondences between the calls. This allows applications and third-party DLLs to make use of a Windows Sockets implementation without being concerned about the calls to these APIs made by the other. o Change of return type of inet_addr() from struct in_addr to unsigned long. This was required due to different handling of four-byte structure returns between the Microsoft and Borland C compilers. o Change of WSAAsyncSelect() semantics from "edge-triggered" to "level-triggered". The level-triggered semantics significantly simplify an application's use of this routine. o Change the ioctlsocket() FIONBIO semantics to fail if a WSAAsyncSelect() call is outstanding on the socket. o Addition of the TCP_NODELAY socket option for RFC 1122 conformance. All changes between the 1.0 and 1.1 specifications are flagged with change bars at the left of the page. 5 6 Programming with Sockets 2. PROGRAMMING WITH SOCKETS 2.1 Windows Sockets Stack Installation Checking To detect the presence of one (or many) Windows Sockets implementations on a system, an application which has been linked with the Windows Sockets Import Library may simply call the WSAStartup() routine. If an application wishes to be a little more sophisticated it can examine the $PATH environment variable and search for instances of Windows Sockets implementations (WINSOCK.DLL). For each instance it can issue a LoadLibrary() call and use the WSAStartup() routine to discover implementation specific data. This version of the Windows Sockets specification does not attempt to address explicitly the issue of multiple concurrent Windows Sockets implementations. Nothing in the specification should be interpreted as restricting multiple Windows Sockets DLLs from being present and used concurrently by one or more Windows Sockets applications. For further details of where to obtain Windows Sockets components, see Appendix B.2. 2.2 Sockets The following material is derived from the document "An Advanced 4.3BSD Interprocess Communication Tutorial" by Samuel J. Leffler, Robert S. Fabry, William N. Joy, Phil Lapsley, Steve Miller, and Chris Torek. 2.2.1 Basic concepts The basic building block for communication is the socket. A socket is an endpoint of communication to which a name may be bound. Each socket in use has a type and an associated process. Sockets exist within communication domains. A communication domain is an abstraction introduced to bundle common properties of threads communicating through sockets. Sockets normally exchange data only with sockets in the same domain (it may be possible to cross domain boundaries, but only if some translation process is performed). The Windows Sockets facilities support a single communication domain: the Internet domain, which is used by processes which communicate using the Internet Protocol Suite. (Future versions of this specification may include additional domains.) Sockets are typed according to the communication properties visible to a user. Applications are presumed to communicate only between sockets of the same type, although there is nothing that prevents communication between sockets of different types should the underlying communication protocols support this. Two types of sockets currently are available to a user. A stream socket provides for the bi-directional, reliable, sequenced, and unduplicated flow of data without record boundaries. A datagram socket supports bi-directional flow of data which is not promised to be sequenced, reliable, or unduplicated. That is, a process receiving messages on a datagram socket may find messages duplicated, and, possibly, in an order different from the order in Programming with Sockets 7 which it was sent. An important characteristic of a datagram socket is that record boundaries in data are preserved. Datagram sockets closely model the facilities found in many contemporary packet switched networks such as Ethernet. 2.2.2 Client-server model The most commonly used paradigm in constructing distributed applications is the client/server model. In this scheme client applications request services from a server application. This implies an asymmetry in establishing communication between the client and server. The client and server require a well-known set of conventions before service may be rendered (and accepted). This set of conventions comprises a protocol which must be implemented at both ends of a connection. Depending on the situation, the protocol may be symmetric or asymmetric. In a symmetric protocol, either side may play the master or slave roles. In an asymmetric protocol, one side is immutably recognized as the master, with the other as the slave. An example of a symmetric protocol is the TELNET protocol used in the Internet for remote terminal emulation. An example of an asymmetric protocol is the Internet file transfer protocol, FTP. No matter whether the specific protocol used in obtaining a service is symmetric or asymmetric, when accessing a service there is a "client process'' and a "server process''. A server application normally listens at a well-known address for service requests. That is, the server process remains dormant until a connection is requested by a client's connection to the server's address. At such a time the server process "wakes up'' and services the client, performing whatever appropriate actions the client requests of it. While connection-based services are the norm, some services are based on the use of datagram sockets. 2.2.3 Out-of-band data Note: The following discussion of out-of-band data, also referred to as TCP Urgent data, follows the model used in the Berkeley software distribution. Users and implementors should be aware of the fact that there are at present two conflicting interpretations of RFC 793 (in which the concept is introduced), and that the implementation of out- of-band data in the Berkeley Software Distribution does not conform to the Host Requirements laid down in RFC 1122. To minimize interoperability problems, applications writers are advised not to use out-of-band data unless this is required in order to interoperate with an existing service. Windows Sockets suppliers are urged to document the out-of-band semantics (BSD or RFC 1122) which their product implements. It is beyond the scope of this specification to mandate a particular set of semantics for out-of-band data handling. The stream socket abstraction includes the notion of "out of band'' data. Out-of-band data is a logically independent transmission 7 8 Programming with Sockets channel associated with each pair of connected stream sockets. Out- of-band data is delivered to the user independently of normal data. The abstraction defines that the out-of-band data facilities must support the reliable delivery of at least one out-of-band message at a time. This message may contain at least one byte of data, and at least one message may be pending delivery to the user at any one time. For communications protocols which support only in-band signaling (i.e. the urgent data is delivered in sequence with the normal data), the system normally extracts the data from the normal data stream and stores it separately. This allows users to choose between receiving the urgent data in order and receiving it out of sequence without having to buffer all the intervening data. It is possible to "peek'' at out-of-band data. An application may prefer to process out-of-band data "in-line", as part of the normal data stream. This is achieved by setting the socket option SO_OOBINLINE (see section 4.1.21, setsockopt()). In this case, the application may wish to determine whether any of the unread data is "urgent" (the term usually applied to in-line out-of- band data). To facilitate this, the Windows Sockets implementation will maintain a logical "mark" in the data stream indicate the point at which the out-of-band data was sent. An application can use the SIOCATMARK ioctlsocket() command (see section 4.1.12) to determine whether there is any unread data preceding the mark. For example, it might use this to resynchronize with its peer by ensuring that all data up to the mark in the data stream is discarded when appropriate. The WSAAsyncSelect() routine is particularly well suited to handling notification of the presence of out-of-band-data. 2.2.4 Broadcasting By using a datagram socket, it is possible to send broadcast packets on many networks supported by the system. The network itself must support broadcast: the system provides no simulation of broadcast in software. Broadcast messages can place a high load on a network, since they force every host on the network to service them. Consequently, the ability to send broadcast packets has been limited to sockets which are explicitly marked as allowing broadcasting. Broadcast is typically used for one of two reasons: it is desired to find a resource on a local network without prior knowledge of its address, or important functions such as routing require that information be sent to all accessible neighbors. The destination address of the message to be broadcast depends on the network(s) on which the message is to be broadcast. The Internet domain supports a shorthand notation for broadcast on the local network, the address INADDR_BROADCAST. Received broadcast messages contain the senders address and port, as datagram sockets must be bound before use. Some types of network support the notion of different types of broadcast. For example, the IEEE 802.5 token ring architecture supports the use of link-level broadcast indicators, which control whether broadcasts are forwarded by bridges. The Windows Sockets specification does not provide any mechanism whereby an application can determine the type of underlying network, nor any way to control the semantics of broadcasting. Programming with Sockets 9 2.3 Byte Ordering The Intel byte ordering is like that of the DEC VAX3, and therefore differs from the Internet and 680004-type processor byte ordering. Thus care must be taken to ensure correct orientation. Any reference to IP addresses or port numbers passed to or from a Windows Sockets routine must be in network order. This includes the IP address and port fields of a struct sockaddr_in (but not the sin_family field). Consider an application which normally contacts a server on the TCP port corresponding to the "time" service, but which provides a mechanism for the user to specify that an alternative port is to be used. The port number returned by getservbyname() is already in network order, which is the format required constructing an address, so no translation is required. However if the user elects to use a different port, entered as an integer, the application must convert this from host to network order (using the htons() function) before using it to construct an address. Conversely, if the application wishes to display the number of the port within an address (returned via, e.g., getpeername()), the port number must be converted from network to host order (using ntohs()) before it can be displayed. Since the Intel and Internet byte orders are different, the conversions described above are unavoidable. Application writers are cautioned that they should use the standard conversion functions provided as part of the Windows Sockets API rather than writing their own conversion code, since future implementations of Windows Sockets are likely to run on systems for which the host order is identical to the network byte order. Only applications which use the standard conversion functions are likely to be portable. 2.4 Socket Options The socket options supported by Windows Sockets are listed in the pages describing setsockopt() and getsockopt(). A Windows Sockets implementation must recognize all of these options, and (for getsockopt()) return plausible values for each. The default value for each option is shown in the following table. 3 VAX is a trademark of Digital Equipment Corporation. 4 68000 is a trademark of Motorola, Inc. 9 10 Programming with Sockets Value Type Meaning Default Not e SO_ACCEPTCO BOOL Socket is FALSE N N listen()ing. unless a listen() has been performed SO_BROADCAS BOOL Socket is FALSE T configured for the transmission of broadcast messages. SO_DEBUG BOOL Debugging is FALSE (i) enabled. SO_DONTLING BOOL If true, the TRUE ER SO_LINGER option is disabled. SO_DONTROUT BOOL Routing is FALSE (i) E disabled. SO_ERROR int Retrieve error 0 status and clear. SO_KEEPALIV BOOL Keepalives are FALSE E being sent. SO_LINGER struct Returns the l_onoff is linger current linger 0 FAR * options. SO_OOBINLIN BOOL Out-of-band data FALSE E is being received in the normal data stream. SO_RCVBUF int Buffer size for Implementat (i) receives ion dependent SO_REUSEADD BOOL The address to FALSE R which this socket is bound can be used by others. SO_SNDBUF int Buffer size for Implementat (i) sends ion dependent Programming with Sockets 11 SO_TYPE int The type of the As created socket (e.g. via SOCK_STREAM). socket() TCP_NODELAY BOOL Disables the Nagle Implementat algorithm for send ion coalescing. dependent Notes: (i) An implementation may silently ignore this option on setsockopt() and return a constant value for getsockopt(), or it may accept a value for setsockopt() and return the corresponding value in getsockopt() without using the value in any way. 2.5 Database Files The getXbyY() and WSAAsyncGetXByY() classes of routines are provided 5 for retrieving network specific information. The getXbyY() routines were originally designed (in the first Berkeley UNIX releases) as mechanisms for looking up information in text databases. Although the information may be retrieved by the Windows Sockets implementation in different ways, a Windows Sockets application requests such information in a consistent manner through either the getXbyY() or the WSAAsyncGetXByY() class of routines. 2.6 Deviation from Berkeley Sockets There are a few limited instances where the Windows Sockets API has had to divert from strict adherence to the Berkeley conventions, usually because of difficulties of implementation in a Windows environment. 2.6.1 socket data type and error values A new data type, SOCKET, has been defined. The definition of this type was necessary for future enhancements to the Windows Sockets specification, such as being able to use sockets as file handles in Windows NT . Definition of this type also facilitates porting of 6 applications to a Win/32 environment, as the type will automatically be promoted from 16 to 32 bits. In UNIX, all handles, including socket handles, are small, non- negative integers, and some applications make assumptions that this will be true. Windows Sockets handles have no restrictions, other than that the value INVALID_SOCKET is not a valid socket. Socket handles may take any value in the range 0 to INVALID_SOCKET-1. This specification uses the function name getXbyY() to represent the 5 set of routines gethostbyaddr(), gethostbyname(), etc. Similarly WSAAsyncGetXByY() represents WSAAsyncGetHostByAddr(), etc. NT and Windows/NT are trademarks of Microsoft Corporation. 6 11 12 Programming with Sockets Because the SOCKET type is unsigned, compiling existing source code from, for example, a UNIX environment may lead to compiler warnings about signed/unsigned data type mismatches. This means, for example, that checking for errors when the socket() and accept() routines return should not be done by comparing the return value with -1, or seeing if the value is negative (both common, and legal, approaches in BSD). Instead, an application should use the manifest constant INVALID_SOCKET as defined in winsock.h. For example: TYPICAL BSD STYLE: s = socket(...); if (s == -1) /* or s < 0 */ {...} PREFERRED STYLE: s = socket(...); if (s == INVALID_SOCKET) {...} 2.6.2 select() and FD_* Because a SOCKET is no longer represented by the UNIX-style "small non-negative integer", the implementation of the select() function was changed in the Windows Sockets API. Each set of sockets is still represented by the fd_set type, but instead of being stored as a bitmask the set is implemented as an array of SOCKETs. To avoid potential problems, applications must adhere to the use of the FD_XXX macros to set, initialize, clear, and check the fd_set structures. 2.6.3 Error codes - errno, h_errno & WSAGetLastError() Error codes set by the Windows Sockets implementation are NOT made available via the errno variable. Additionally, for the getXbyY() class of functions, error codes are NOT made available via the h_errno variable. Instead, error codes are accessed by using the WSAGetLastError() API described in section 4.3.11. This function is provided in Windows Sockets as a precursor (and eventually an alias) for the Win32 function GetLastError(). This is intended to provide a reliable way for a thread in a multi-threaded process to obtain per- thread error information. For compatibility with BSD, an application may choose to include a line of the form: #define errno WSAGetLastError() This will allow networking code which was written to use the global errno to work correctly in a single-threaded environment. There are, obviously, some drawbacks. If a source file includes code which inspects errno for both socket and non-socket functions, this mechanism cannot be used. Furthermore, it is not possible for an application to assign a new value to errno. (In Windows Sockets the function WSASetLastError() may be used for this purpose.) Programming with Sockets 13 TYPICAL BSD STYLE: r = recv(...); if (r == -1 && errno == EWOULDBLOCK) {...} PREFERRED STYLE: r = recv(...); if (r == -1 /* (but see below) */ && WSAGetLastError() == EWOULDBLOCK) {...} Although error constants consistent with 4.3 Berkeley Sockets are provided for compatibility purposes, applications should, where possible, use the "WSA" error code definitions. For example, a more accurate version of the above source code fragment is: r = recv(...); if (r == -1 /* (but see below) */ && WSAGetLastError() == WSAEWOULDBLOCK) {...} 2.6.4 Pointers All pointers used by applications with Windows Sockets should be FAR. To facilitate this, data type definitions such as LPHOSTENT are provided. 2.6.5 Renamed functions In two cases it was necessary to rename functions which are used in Berkeley Sockets in order to avoid clashes with other APIs. 2.6.5.1 close() & closesocket() In Berkeley Sockets, sockets are represented by standard file descriptors, and so the close() function can be used to close sockets as well as regular files. While nothing in the Windows Sockets API prevents an implementation from using regular file handles to identify sockets, nothing requires it either. Socket descriptors are not presumed to correspond to regular file handles, and file operations such as read(), write(), and close() cannot be assumed to work correctly when applied to sockets. Sockets must be closed by using the closesocket() routine. Using the close() routine to close a socket is incorrect and the effects of doing so are undefined by this specification. 2.6.5.1 ioctl() & ioctlsocket() Various C language run-time systems use the ioctl() routine for purposes unrelated to Windows Sockets. For this reason we have defined the routine ioctlsocket() which is used to handle socket functions which in the Berkeley Software Distribution are performed using ioctl() and fcntl(). 2.6.6 Blocking routines & EINPROGRESS Although blocking operations on sockets are supported under Windows Sockets, their use is strongly discouraged. Programmers who are constrained to use blocking mode for example, as part of an existing application which is to be ported should be aware of the semantics 13 14 Programming with Sockets of blocking operations in Windows Sockets. See section 3.1.1 for more details. 2.6.7 Maximum number of sockets supported The maximum number of sockets supported by a particular Windows Sockets supplier is implementation specific. An application should make no assumptions about the availability of a certain number of sockets. This topic is addressed further in section 4.3.15, WSAStartup(). However, independent of the number of sockets supported by a particular implementation is the issue of the maximum number of sockets which an application can actually make use of. The maximum number of sockets which a Windows Sockets application can make use of is determined at compile time by the manifest constant FD_SETSIZE. This value is used in constructing the fd_set structures used in select() (see section 4.1.18). The default value in winsock.h is 64. If an application is designed to be capable of working with more than 64 sockets, the implementor should define the manifest FD_SETSIZE in every source file before including winsock.h. One way of doing this may be to include the definition within the compiler options in the makefile, for example adding -DFD_SETSIZE=128 as an option to the compiler command line for Microsoft C. It must be emphasized that defining FD_SETSIZE as a particular value has no effect on the actual number of sockets provided by a Windows Sockets implementation. 2.6.8 Include files For ease of portability of existing Berkeley sockets based source code, a number of standard Berkeley include files are supported. However, these Berkeley header files merely include the winsock.h include file, and it is therefore sufficient (and recommended) that Windows Sockets application source files should simply include winsock.h. 2.6.9 Return values on API failure The manifest constant SOCKET_ERROR is provided for checking API failure. Although use of this constant is not mandatory, it is recommended. The following example illustrates the use of the SOCKET_ERROR constant: TYPICAL BSD STYLE: r = recv(...); if (r == -1 /* or r < 0 */ && errno == EWOULDBLOCK) {...} PREFERRED STYLE: r = recv(...); if (r == SOCKET_ERROR && WSAGetLastError() == WSAEWOULDBLOCK) {...} 2.6.10 Raw Sockets The Windows Sockets specification does not mandate that a Windows Sockets DLL support raw sockets, that is, sockets opened with SOCK_RAW. However, a Windows Sockets DLL is allowed and encouraged to supply raw socket support. A Windows Sockets-compliant application that wishes to use raw sockets should attempt to open the socket with Programming with Sockets 15 the socket() call (see section 4.1.23), and if it fails either attempt to use another socket type or indicate the failure to the user. 2.7 Windows Sockets in Multithreaded Versions of Windows The Windows Sockets interface is designed to work for both single- threaded versions of Windows (such as Windows 3.1) and preemptive multithreaded versions of Windows (such as Windows NT). In a multithreaded environment the sockets interface is basically the same, but the author of a multithreaded application must be aware that it is the responsibility of the application, not the Windows Sockets implementation, to synchronize access to a socket between threads. This is the same rule as applies to other forms of I/O such as file I/O. Failure to synchronize calls on a socket leads to unpredictable results; for example if there are two simultaneous calls to send(), there is no guarantee as to the order in which the data will be sent. Closing a socket in one thread that has an outstanding blocking call on the same socket in another thread will cause the blocking call to fail with WSAEINTR, just as if the operation were canceled. This also applies if there is a select() call outstanding and the application closes one of the sockets being selected. There is no default blocking hook installed in preemptive multithreaded versions of Windows. This is because the machine will not be blocked if a single application is waiting for an operation to complete and hence not calling PeekMessage() or GetMessage() which cause the application to yield in nonpremptive Windows. However, for backwards compatibility the WSASetBlockingHook() call is implemented in multithreaded versions of Windows, and any application whose behavior depends on the default blocking hook may install their own blocking hook which duplicates the default hook's semantics, if desired. 15 16 Socket Library Overview 3. SOCKET LIBRARY OVERVIEW 3.1 Socket Functions The Windows Sockets specification includes the following Berkeley- style socket routines: Socket Library Overview 17 accept() * An incoming connection is acknowledged and associated with an immediately created socket. The original socket is returned to the listening state. bind() Assign a local name to an unnamed socket. closesocket() * Remove a socket from the per- process object reference table. Only blocks if SO_LINGER is set. connect() * Initiate a connection on the specified socket. getpeername() Retrieve the name of the peer connected to the specified socket. getsockname() Retrieve the current name for the specified socket getsockopt() Retrieve options associated with the specified socket. htonl() Convert a 32-bit quantity from host byte order to network byte order. htons() Convert a 16-bit quantity from host byte order to network byte order. inet_addr() Converts a character string representing a number in the Internet standard ".'' notation to an Internet address value. inet_ntoa() Converts an Internet address value to an ASCII string in ".'' notation i.e. "a.b.c.d''. ioctlsocket() Provide control for sockets. listen() Listen for incoming connections on a specified socket. ntohl() Convert a 32-bit quantity from network byte order to host byte order. ntohs() Convert a 16-bit quantity from network byte order to host byte order. 17 18 Socket Library Overview recv() * Receive data from a connected socket. recvfrom() * Receive data from either a connected or unconnected socket. select() * Perform synchronous I/O multiplexing. send() * Send data to a connected socket. sendto() * Send data to either a connected or unconnected socket. setsockopt() Store options associated with the specified socket. shutdown() Shut down part of a full-duplex connection. socket() Create an endpoint for communication and return a socket. * = The routine can block if acting on a blocking socket. 3.1.1 Blocking/Non blocking & Data Volatility One major issue in porting applications from a Berkeley sockets environment to a Windows environment involves "blocking"; that is, invoking a function which does not return until the associated operation is completed. The problem arises when the operation may take an arbitrarily long time to complete: an obvious example is a recv() which may block until data has been received from the peer system. The default behavior within the Berkeley sockets model is for a socket to operate in a blocking mode unless the programmer explicitly requests that operations be treated as non-blocking. It is strongly recommended that programmers use the nonblocking (asynchronous) operations if at all possible, as they work significantly better within the nonpreemptive Windows environment. Use blocking operations only if absolutely necessary, and carefully read and understand this section if you must use blocking operations. Even on a blocking socket, some operations (e.g. bind(), getsockopt(), getpeername()) can be completed immediately. For such operations there is no difference between blocking and non-blocking operation. Other operations (e.g. recv()) may be completed immediately or may take an arbitrary time to complete, depending on various transport conditions. When applied to a blocking socket, these operations are referred to as blocking operations. All routines which can block are listed with an asterisk in the tables above and below. Within a Windows Sockets implementation, a blocking operation which cannot be completed immediately is handled as follows. The DLL initiates the operation, and then enters a loop in which it dispatches any Windows messages (yielding the processor to another thread if Socket Library Overview 19 necessary) and then checks for the completion of the Windows Sockets function. If the function has completed, or if WSACancelBlockingCall() has been invoked, the blocking function completes with an appropriate result. Refer to section 4.3.13, WSASetBlockingHook(), for a complete description of this mechanism, including pseudocode for the various functions. If a Windows message is received for a process for which a blocking operation is in progress, there is a risk that the application will attempt to issue another Windows Sockets call. Because of the difficulty of managing this condition safely, the Windows Sockets specification does not support such application behavior. Two functions are provided to assist the programmer in this situation. WSAIsBlocking() may be called to determine whether or not a blocking Windows Sockets call is in progress. WSACancelBlockingCall() may be called to cancel an in-progress blocking call, if any. Any other Windows Sockets function which is called in this situation will fail with the error WSAEINPROGRESS. It should be emphasized that this restriction applies to both blocking and non-blocking operations. Although this mechanism is sufficient for simple applications, it cannot support the complex message-dispatching requirements of more advanced applications (for example, those using the MDI model). For such applications, the Windows Sockets API includes the function WSASetBlockingHook(), which allows the programmer to define a special routine which will be called instead of the default message dispatch routine described above. The Windows Sockets DLL calls the blocking hook only if all of the following are true: the routine is one which is defined as being able to block, the specified socket is a blocking socket, and the request cannot be completed immediately. (A socket is set to blocking by default, but the IOCTL FIONBIO and WSAAsyncSelect() both set a socket to nonblocking mode.) If an application uses only non-blocking sockets and uses the WSAAsyncSelect() and/or the WSAAsyncGetXByY() routines instead of select() and the getXbyY() routines, then the blocking hook will never be called and the application does not need to be concerned with the reentrancy issues the blocking hook can introduce. If an application invokes an asynchronous or non-blocking operation which takes a pointer to a memory object (e.g. a buffer, or a global variable) as an argument, it is the responsibility of the application to ensure that the object is available to the Windows Sockets implementation throughout the operation. The application must not invoke any Windows function which might affect the mapping or addressability of the memory involved. In a multithreaded system, the application is also responsible for coordinating access to the object using appropriate synchronization mechanisms. A Windows Sockets implementation cannot, and will not, address these issues. The possible consequences of failing to observe these rules are beyond the scope of this specification. 3.2 Database Functions The Windows Sockets specification defines the following "database" routines. As noted earlier, a Windows Sockets supplier may choose to 19 20 Socket Library Overview implement these in a manner which does not depend on local database files. The pointer returned by certain database routines such as gethostbyname() points to a structure which is allocated by the Windows Sockets library. The data which is pointed to is volatile and is good only until the next Windows Sockets API call from that thread. Additionally, the application must never attempt to modify this structure or to free any of its components. Only one copy of this structure is allocated for a thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. gethostbyaddr() * Retrieve the name(s) and address corresponding to a network address. gethostbyname() * Retrieve the name(s) and address corresponding to a host name. gethostname() Retrieve the name of the local host. getprotobyname() * Retrieve the protocol name and number corresponding to a protocol name. getprotobynumber() * Retrieve the protocol name and number corresponding to a protocol number. getservbyname() * Retrieve the service name and port corresponding to a service name. getservbyport() * Retrieve the service name and port corresponding to a port. * = The routine can block under some circumstances. 3.3 Microsoft Windows-specific Extension Functions The Windows Sockets specification provides a number of extensions to the standard set of Berkeley Sockets routines. Principally, these extended APIs allow message-based, asynchronous access to network events. While use of this extended API set is not mandatory for socket-based programming (with the exception of WSAStartup() and WSACleanup()), it is recommended for conformance with the Microsoft Windows programming paradigm. Socket Library Overview 21 WSAAsyncGetHostByAdd A set of functions which provide r() asynchronous WSAAsyncGetHostByNam versions of the standard Berkeley e() WSAAsyncGetProtoByNa getXbyY() functions. For me() example, the WSAAsyncGetProtoByNu WSAAsyncGetHostByName() function mber() provides an WSAAsyncGetServByNam asynchronous message based e() implementation of WSAAsyncGetServByPor the standard Berkeley t() gethostbyname() function. WSAAsyncSelect() Perform asynchronous version of select() WSACancelAsyncReques Cancel an outstanding instance of t() a WSAAsyncGetXByY() function. WSACancelBlockingCal Cancel an outstanding "blocking" l() API call WSACleanup() Sign off from the underlying Windows Sockets DLL. WSAGetLastError() Obtain details of last Windows Sockets API error WSAIsBlocking() Determine if the underlying Windows Sockets DLL is already blocking an existing call for this thread WSASetBlockingHook() "Hook" the blocking method used by the underlying Windows Sockets implementation WSASetLastError() Set the error to be returned by a subsequent WSAGetLastError() WSAStartup() Initialize the underlying Windows Sockets DLL. WSAUnhookBlockingHoo Restore the original blocking k() function 3.3.1 Asynchronous select() Mechanism The WSAAsyncSelect() API allows an application to register an interest in one or many network events. This API is provided to supersede the need to do polled network I/O. Any situation in which select() or 21 22 Socket Library Overview non-blocking I/O routines (such as send() and recv()) are either already used or are being considered is usually a candidate for the WSAAsyncSelect() API. When declaring interest in such condition(s), you supply a window handle to be used for notification. The corresponding window then receives message-based notification of the conditions in which you declared an interest. WSAAsyncSelect() allows interest to be declared in the following conditions for a particular socket: Socket readiness for reading Socket readiness for writing Out-of-band data ready for reading Socket readiness for accepting incoming connection Completion of non-blocking connect() Connection closure 3.3.2 Asynchronous Support Routines The asynchronous "database" functions allow applications to request information in an asynchronous manner. Some network implementations and/or configurations perform network based operations to resolve such requests. The WSAAsyncGetXByY() functions allow application developers to request services which would otherwise block the operation of the whole Windows environment if the standard Berkeley function were used. The WSACancelAsyncRequest() function allows an application to cancel any outstanding asynchronous request. 3.3.3 Hooking Blocking Methods As noted in section 3.1.1 above, Windows Sockets implements blocking operations in such a way that Windows message processing can continue, which may result in the application which issued the call receiving a Windows message. In certain situations an application may want to influence or change the way in which this pseudo-blocking process is implemented. The WSASetBlockingHook() provides the ability to substitute a named routine which the Windows Sockets implementation is to use when relinquishing the processor during a "blocking" operation. 3.3.4 Error Handling For compatibility with thread-based environments, details of API errors are obtained through the WSAGetLastError() API. Although the accepted "Berkeley-Style" mechanism for obtaining socket-based network errors is via "errno", this mechanism cannot guarantee the integrity of an error ID in a multi-threaded environment. WSAGetLastError() allows you to retrieve an error code on a per thread basis. WSAGetLastError() returns error codes which avoid conflict with standard Microsoft C error codes. Certain error codes returned by certain Windows Sockets routines fall into the standard range of error codes as defined by Microsoft C. If you are NOT using an application development environment which defines error codes consistent with Microsoft C, you are advised to use the Windows Sockets error codes prefixed by "WSA" to ensure accurate error code detection. Note that this specification defines a recommended set of error codes, and lists the possible errors which may be returned as a result of each function. It may be the case in some implementations that other Windows Sockets error codes will be returned in addition to those listed, and applications should be prepared to handle errors other Socket Library Overview 23 than those enumerated under each API description. However a Windows Sockets implementation must not return any value which is not enumerated in the table of legal Windows Sockets errors given in Appendix A.1. 3.3.5 Accessing a Windows Sockets DLL from an Intermediate DLL A Windows Sockets DLL may be accessed both directly from an application and through an "intermediate" DLL. An example of such an intermediate DLL would be a virtual network API layer that supports generalized network functionality for applications and uses Windows Sockets. Such a DLL could be used by several applications simultaneously, and the DLL must take special precautions with respect to the WSAStartup() and WSACleanup() calls to ensure that these routines are called in the context of each task that will make Windows Sockets calls. This is because the Windows Sockets DLL will need a call to WSAStartup() for each task in order to set up task-specific data structures, and a call to WSACleanup() to free any resources allocated for the task. There are (at least) two ways to accomplish this. The simplest method is for the intermediate DLL to have calls similar to WSAStartup() and WSACleanup() that applications call as appropriate. The DLL would then call WSAStartup() or WSACleanup() from within these routines. Another mechanism is for the intermediate DLL to build a table of task handles, which are obtained from the GetCurrentTask() Windows API, and at each entry point into the intermediate DLL check whether WSAStartup() has been called for the current task, then call WSAStartup() if necessary. If a DLL makes a blocking call and does not install its own blocking hook, then the DLL author must be aware that control may be returned to the application either by an application-installed blocking hook or by the default blocking hook. Thus, it is possible that the application will cancel the DLL's blocking operation via WSACancelBlockingCall(). If this occurs, the DLL's blocking operation will fail with the error code WSAEINTR, and the DLL must return control to the calling task as quickly as possible, as the used has likely pressed a cancel or close button and the task has requested control of the CPU. It is recommended that DLLs which make blocking calls install their own blocking hooks with WSASetBlockingHook() to prevent unforeseen interactions between the application and the DLL. Note that this is not necessary for DLLs in Windows NT because of its different process and DLL structure. Under Windows NT, the intermediate DLL could simply call WSAStartup() in its DLL initialization routine, which is called whenever a new process which uses the DLL starts. 3.3.6 Internal use of Messages by Windows Sockets Implementations In order to implement Windows Sockets purely as a DLL, it may be necessary for the DLL to post messages internally for communication and timing. This is perfectly legal; however, a Windows Sockets DLL must not post messages to a window handle opened by a client application except for those messages requested by the application. A Windows Sockets DLL that needs to use messages for its own purposes must open a hidden window and post any necessary messages to the handle for that window. 23 24 Socket Library Overview 3.3.7 Private API Interfaces The winsock.def file in Appendix B.7 lists the ordinals defined for the Windows Sockets APIs. In addition to the ordinal values listed, all ordinals 999 and below are reserved for future Windows Sockets use. It may be convenient for a Windows Sockets implementation to export additional, private interfaces from the Windows Sockets DLL. This is perfectly acceptable, as long as the ordinals for these exports are above 1000. Note that any application that uses a particular Windows Sockets DLL's private APIs will most likely not work on any other vendor's Windows Sockets implementation. Only the APIs defined in this document are guaranteed to be present in every Windows Sockets implementation. If an application uses private interfaces of a particular vendor's Windows Sockets DLL, it is recommended that the DLL not be statically linked with the application but rather dynamically loaded with the Windows routines LoadLibrary() and GetProcAddress(). This allows the application to give an informative error message if it is run on a system with a Windows Sockets DLL that does not support the same set of extended functionality. Socket Library Reference 25 4. SOCKET LIBRARY REFERENCE 4.1 Socket Routines This chapter presents the socket library routines in alphabetical order, and describes each routine in detail. In each routine it is indicated that the header file winsock.h must be included. Appendix A.2 lists the Berkeley-compatible header files which are supported. These are provided for compatibility purposes only, and each of them will simply include winsock.h. The Windows header file windows.h is also needed, but winsock.h will include it if necessary. 26 accept 4.1.1 accept() Description Accept a connection on a socket. #include SOCKET PASCAL FAR accept ( SOCKET s, struct sockaddr FAR * addr, int FAR * addrlen ); s A descriptor identifying a socket which is listening for connections after a listen(). addr An optional pointer to a buffer which receives the address of the connecting entity, as known to the communications layer. The exact format of the addr argument is determined by the address family established when the socket was created. addrlen An optional pointer to an integer which contains the length of the address addr. Remarks This routine extracts the first connection on the queue of pending connections on s, creates a new socket with the same properties as s and returns a handle to the new socket. If no pending connections are present on the queue, and the socket is not marked as non-blocking, accept() blocks the caller until a connection is present. If the socket is marked non-blocking and no pending connections are present on the queue, accept() returns an error as described below. The accepted socket may not be used to accept more connections. The original socket remains open. The argument addr is a result parameter that is filled in with the address of the connecting entity, as known to the communications layer. The exact format of the addr parameter is determined by the address family in which the communication is occurring. The addrlen is a value-result parameter; it should initially contain the amount of space pointed to by addr; on return it will contain the actual length (in bytes) of the address returned. This call is used with connection-based socket types such as SOCK_STREAM. If addr and/or addrlen are equal to NULL, then no information about the remote address of the accepted socket is returned. Return Value If no error occurs, accept() returns a value of type SOCKET which is a descriptor for the accepted packet. Otherwise, a value of INVALID_SOCKET is returned, and a specific error code may be retrieved by calling WSAGetLastError(). The integer referred to by addrlen initially contains the amount of space pointed to by addr. On return it will contain the actual length in bytes of the address returned. accept 27 Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEFAULT The addrlen argument is too small (less than the sizeof a struct sockaddr). WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets call is in progress. WSAEINVAL listen() was not invoked prior to accept(). WSAEMFILE The queue is empty upon entry to accept() and there are no descriptors available. WSAENOBUFS No buffer space is available. WSAENOTSOCK The descriptor is not a socket. WSAEOPNOTSUPP The referenced socket is not a type that supports connection-oriented service. WSAEWOULDBLOCK The socket is marked as non-blocking and no connections are present to be accepted. See Also bind(), connect(), listen(), select(), socket(), WSAAsyncSelect() 28 bind 4.1.2 bind() Description Associate a local address with a socket. #include int PASCAL FAR bind ( SOCKET s, const struct sockaddr FAR * name, int namelen ); s A descriptor identifying an unbound socket. name The address to assign to the socket. The sockaddr structure is defined as follows: struct sockaddr { u_short sa_family; char sa_data[14]; }; namelen The length of the name. Remarks This routine is used on an unconnected datagram or stream socket, before subsequent connect()s or listen()s. When a socket is created with socket(), it exists in a name space (address family), but it has no name assigned. bind() establishes the local association (host address/port number) of the socket by assigning a local name to an unnamed socket. In the Internet address family, a name consists of several components. For SOCK_DGRAM and SOCK_STREAM, the name consists of three parts: a host address, the protocol number (set implicitly to UDP or TCP, respectively), and a port number which identifies the application. If an application does not care what address is assigned to it, it may specify an Internet address equal to INADDR_ANY, a port equal to 0, or both. If the Internet address is equal to INADDR_ANY, any appropriate network interface will be used; this simplifies application programming in the presence of multi- homed hosts. If the port is specified as 0, the Windows Sockets implementation will assign a unique port to the application with a value between 1024 and 5000. The application may use getsockname() after bind() to learn the address that has been assigned to it, but note that getsockname() will not necessarily fill in the Internet address until the socket is connected, since several Internet addresses may be valid if the host is multi-homed. If an application desires to bind to an arbitrary port outside of the range 1024 to 5000, such as the case of rsh which must bind to any reserved port, code similar to the following may be used: SOCKADDR_IN sin; SOCKET s; u_short alport = IPPORT_RESERVED; bind 29 sin.sin_family = AF_INET; sin.sin_addr.s_addr = 0; for (;;) { sin.sin_port = htons(alport); if (bind(s, (LPSOCKADDR)&sin, sizeof (sin)) == 0) { /* it worked */ } if ( GetLastError() != WSAEADDRINUSE) { /* fail */ } alport--; if (alport == IPPORT_RESERVED/2 ) { /* fail--all unassigned reserved ports are */ /* in use. */ } } Return Value If no error occurs, bind() returns 0. Otherwise, it returns SOCKET_ERROR, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEADDRINUSE The specified address is already in use. (See the SO_REUSEADDR socket option under setsockopt().) WSAEFAULT The namelen argument is too small (less than the size of a struct sockaddr). WSAEINPROGRESS A blocking Windows Sockets call is in progress. WSAEAFNOSUPPORT The specified address family is not supported by this protocol. WSAEINVAL The socket is already bound to an address. WSAENOBUFS Not enough buffers available, too many connections. WSAENOTSOCK The descriptor is not a socket. See Also connect(), listen(), getsockname(), setsockopt(), socket(), WSACancelBlockingCall(). 30 closesocket 4.1.3 closesocket() Description Close a socket. #include int PASCAL FAR closesocket ( SOCKET s ); s A descriptor identifying a socket. Remarks This function closes a socket. More precisely, it releases the socket descriptor s, so that further references to s will fail with the error WSAENOTSOCK. If this is the last reference to the underlying socket, the associated naming information and queued data are discarded. The semantics of closesocket() are affected by the socket options SO_LINGER and SO_DONTLINGER as follows: Option Interval Type of close Wait for close? SO_DONTLINGER Don't care Graceful No SO_LINGER Zero Hard No SO_LINGER Non-zero Graceful Yes If SO_LINGER is set (i.e. the l_onoff field of the linger structure is non-zero; see sections 2.4, 4.1.7 and 4.1.21) with a zero timeout interval (l_linger is zero), closesocket() is not blocked even if queued data has not yet been sent or acknowledged. This is called a "hard" or "abortive" close, because the socket's virtual circuit is reset immediately, and any unsent data is lost. Any recv() call on the remote side of the circuit will fail with WSAECONNRESET. If SO_LINGER is set with a non-zero timeout interval, the closesocket() call blocks until the remaining data has been sent or until the timeout expires. This is called a graceful disconnect. Note that if the socket is set to non- blocking and SO_LINGER is set to a non-zero timeout, the call to closesocket() will fail with an error of WSAEWOULDBLOCK. If SO_DONTLINGER is set on a stream socket (i.e. the l_onoff field of the linger structure is zero; see sections 2.4, 4.1.7 and 4.1.21), the closesocket() call will return immediately. However, any data queued for transmission will be sent if possible before the underlying socket is closed. This is also called a graceful disconnect. Note that in this case the Windows Sockets implementation may not release the socket and other resources for an arbitrary period, which may affect applications which expect to use all available sockets. Return Value If no error occurs, closesocket() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a closesocket 31 specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOTSOCK The descriptor is not a socket. WSAEINPROGRESS A blocking Windows Sockets call is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEWOULDBLOCK The socket is marked as nonblocking and SO_LINGER is set to a nonzero timeout value. See Also accept(), socket(), ioctlsocket(), setsockopt(), WSAAsyncSelect(). 32 connect 4.1.4 connect() Description Establish a connection to a peer. #include int PASCAL FAR connect ( SOCKET s, const struct sockaddr FAR * name, int namelen ); s A descriptor identifying an unconnected socket. name The name of the peer to which the socket is to be connected. namelen The length of the name. Remarks This function is used to create a connection to the specified foreign association. The parameter s specifies an unconnected datagram or stream socket If the socket is unbound, unique values are assigned to the local association by the system, and the socket is marked as bound. Note that if the address field of the name structure is all zeroes, connect() will return the error WSAEADDRNOTAVAIL. For stream sockets (type SOCK_STREAM), an active connection is initiated to the foreign host using name (an address in the name space of the socket). When the socket call completes successfully, the socket is ready to send/receive data. For a datagram socket (type SOCK_DGRAM), a default destination is set, which will be used on subsequent send() and recv() calls. Return Value If no error occurs, connect() returns 0. Otherwise, it returns SOCKET_ERROR, and a specific error code may be retrieved by calling WSAGetLastError(). On a blocking socket, the return value indicates success or failure of the connection attempt. On a non-blocking socket, if the return value is SOCKET_ERROR an application should call WSAGetLastError(). If this indicates an error code of WSAEWOULDBLOCK, then your application can either: 1. Use select() to determine the completion of the connection request by checking if the socket is writeable, or 2. If your application is using the message-based WSAAsyncSelect() to indicate interest in connection events, then your application will receive an FD_CONNECT message when the connect operation is complete. connect 33 Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEADDRINUSE The specified address is already in use. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets call is in progress. WSAEADDRNOTAVAIL The specified address is not available from the local machine. WSAEAFNOSUPPORT Addresses in the specified family cannot be used with this socket. WSAECONNREFUSED The attempt to connect was forcefully rejected. WSAEDESTADDREQ A destination address is required. WSAEFAULT The namelen argument is incorrect. WSAEINVAL The socket is not already bound to an address. WSAEISCONN The socket is already connected. WSAEMFILE No more file descriptors are available. WSAENETUNREACH The network can't be reached from this host at this time. WSAENOBUFS No buffer space is available. The socket cannot be connected. WSAENOTSOCK The descriptor is not a socket. WSAETIMEDOUT Attempt to connect timed out without establishing a connection WSAEWOULDBLOCK The socket is marked as non-blocking and the connection cannot be completed immediately. It is possible to select() the socket while it is connecting by select()ing it for writing. See Also accept(), bind(), getsockname(), socket(), select() and WSAAsyncSelect().. 34 getpeername 4.1.5 getpeername() Description Get the address of the peer to which a socket is connected. #include int PASCAL FAR getpeername ( SOCKET s, struct sockaddr FAR * name, int FAR * namelen ); s A descriptor identifying a connected socket. name The structure which is to receive the name of the peer. namelen A pointer to the size of the name structure. Remarks getpeername() retrieves the name of the peer connected to the socket s and stores it in the struct sockaddr identified by name. It is used on a connected datagram or stream socket. On return, the namelen argument contains the actual size of the name returned in bytes. Return Value If no error occurs, getpeername() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEFAULT The namelen argument is not large enough. WSAEINPROGRESS A blocking Windows Sockets call is in progress. WSAENOTCONN The socket is not connected. WSAENOTSOCK The descriptor is not a socket. See Also bind(), socket(), getsockname(). getsockname 35 4.1.6 getsockname() Description Get the local name for a socket. #include int PASCAL FAR getsockname ( SOCKET s, struct sockaddr FAR * name, int FAR * namelen ); s A descriptor identifying a bound socket. name Receives the address (name) of the socket. namelen The size of the name buffer. Remarks getsockname() retrieves the current name for the specified socket descriptor in name. It is used on a bound and/or connected socket specified by the s parameter. The local association is returned. This call is especially useful when a connect() call has been made without doing a bind() first; this call provides the only means by which you can determine the local association which has been set by the system. On return, the namelen argument contains the actual size of the name returned in bytes. If a socket was bound to INADDR_ANY, indicating that any of the host's IP addresses should be used for the socket, getsockname() will not necessarily return information about the host IP address, unless the socket has been connected with connect() or accept(). A Windows Sockets application must not assume that the IP address will be changed from INADDR_ANY unless the socket is connected. This is because for a multi-homed host the IP address that will be used for the socket is unknown unless the socket is connected. Return Value If no error occurs, getsockname() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEFAULT The namelen argument is not large enough. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. 36 getsockname WSAENOTSOCK The descriptor is not a socket. WSAEINVAL The socket has not been bound to an address with bind(). See Also bind(), socket(), getpeername(). getsockopt 37 4.1.7 getsockopt() Description Retrieve a socket option. #include PASCAL FAR int getsockopt ( SOCKET s, int level, int optname, char FAR * optval, int FAR * optlen ); s A descriptor identifying a socket. level The level at which the option is defined; the only supported level are s SOL_SOCKET and IPPROTO_TCP. optname The socket option for which the value is to be retrieved. optval A pointer to the buffer in which the value for the requested option is to be returned. optlen A pointer to the size of the optval buffer. Remarks getsockopt() retrieves the current value for a socket option associated with a socket of any type, in any state, and stores the result in optval. Options may exist at multiple protocol levels, but they are always present at the uppermost "socket'' level. Options affect socket operations, such as whether an operation blocks or not, the routing of packets, out-of-band data transfer, etc. The value associated with the selected option is returned in the buffer optval. The integer pointed to by optlen should originally contain the size of this buffer; on return, it will be set to the size of the value returned. For SO_LINGER, this will be the size of a struct linger; for all other options it will be the size of an integer. If the option was never set with setsockopt(), then getsockopt() returns the default value for the option. The following options are supported for getsockopt(). The Type identifies the type of data addressed by optval. The TCP_NODELAY option uses level IPPROTO_TCP; all other options use level SOL_SOCKET. Value Type Meaning SO_ACCEPTCO BOOL Socket is listen()ing. N N SO_BROADCAS BOOL Socket is configured for the T transmission of broadcast messages. SO_DEBUG BOOL Debugging is enabled. SO_DONTLING BOOL If true, the SO_LINGER ER option is disabled. SO_DONTROUT BOOL Routing is disabled. E 38 getsockopt SO_ERROR int Retrieve error status and clear. SO_KEEPALIV BOOL Keepalives are being sent. E SO_LINGER struct Returns the current linger linger options. FAR * SO_OOBINLIN BOOL Out-of-band data is being E received in the normal data stream. SO_RCVBUF int Buffer size for receives SO_REUSEADD BOOL The socket may be bound to R an address which is already in use. SO_SNDBUF int Buffer size for sends SO_TYPE int The type of the socket (e.g. SOCK_STREAM). TCP_NODELAY BOOL Disables the Nagle algorithm for send coalescing. BSD options not supported for getsockopt() are: Value Type Meaning SO_RCVLOWAT int Receive low water mark SO_RCVTIMEO int Receive timeout SO_SNDLOWAT int Send low water mark SO_SNDTIMEO int Send timeout IP_OPTIONS Get options in IP header. TCP_MAXSEG int Get TCP maximum segment size. Calling getsockopt() with an unsupported option will result in an error code of WSAENOPROTOOPT being returned from WSAGetLastError(). Return Value If no error occurs, getsockopt() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEFAULT The optlen argument was invalid. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. getsockopt 39 WSAENOPROTOOPT The option is unknown or unsupported. In particular, SO_BROADCAST is not supported on sockets of type SOCK_STREAM, while SO_ACCEPTCONN, SO_DONTLINGER, SO_KEEPALIVE, SO_LINGER and SO_OOBINLINE are not supported on sockets of type SOCK_DGRAM. WSAENOTSOCK The descriptor is not a socket. See Also setsockopt(), WSAAsyncSelect(), socket(). 40 htonl 4.1.8 htonl() Description Convert a u_long from host to network byte order. #include u_long PASCAL FAR htonl ( u_long hostlong ); hostlong A 32-bit number in host byte order. Remarks This routine takes a 32-bit number in host byte order and returns a 32-bit number in network byte order. Return Value htonl() returns the value in network byte order. See Also htons(), ntohl(), ntohs(). htons 41 4.1.9 htons() Description Convert a u_short from host to network byte order. #include u_short PASCAL FAR htons ( u_short hostshort ); hostshort A 16-bit number in host byte order. Remarks This routine takes a 16-bit number in host byte order and returns a 16-bit number in network byte order. Return Value htons() returns the value in network byte order. See Also htonl(), ntohl(), ntohs(). 42 inet_addr 4.1.10 inet_addr() Description Convert a string containing a dotted address into an in_addr. #include unsigned long PASCAL FAR inet_addr ( const char FAR * cp ); cp A character string representing a number expressed in the Internet standard ".'' notation. Remarks This function interprets the character string specified by the cp parameter. This string represents a numeric Internet address expressed in the Internet standard ".'' notation. The value returned is a number suitable for use as an Internet address. All Internet addresses are returned in network order (bytes ordered from left to right). Internet Addresses Values specified using the ".'' notation take one of the following forms: a.b.c.d a.b.c a.b a When four parts are specified, each is interpreted as a byte of data and assigned, from left to right, to the four bytes of an Internet address. Note that when an Internet address is viewed as a 32-bit integer quantity on the Intel architecture, the bytes referred to above appear as "d.c.b.a''. That is, the bytes on an Intel processor are ordered from right to left. Note: The following notations are only used by Berkeley, and nowhere else on the Internet. In the interests of compatibility with their software, they are supported as specified. When a three part address is specified, the last part is interpreted as a 16-bit quantity and placed in the right most two bytes of the network address. This makes the three part address format convenient for specifying Class B network addresses as "128.net.host''. When a two part address is specified, the last part is interpreted as a 24-bit quantity and placed in the right most three bytes of the network address. This makes the two part address format convenient for specifying Class A network addresses as "net.host''. When only one part is given, the value is stored directly in the network address without any byte rearrangement. Return Value If no error occurs, inet_addr() returns an unsigned long containing a suitable binary representation of the inet_addr 43 Internet address given. If the passed-in string does not contain a legitimate Internet address, for example if a portion of an "a.b.c.d" address exceeds 255, inet_addr() returns the value INADDR_NONE. See Also inet_ntoa() 44 inet_ntoa 4.1.11 inet_ntoa() Description Convert a network address into a string in dotted format. #include char FAR * PASCAL FAR inet_ntoa ( struct in_addr in ); in A structure which represents an Internet host address. Remarks This function takes an Internet address structure specified by the in parameter. It returns an ASCII string representing the address in ".'' notation as "a.b.c.d''. Note that the string returned by inet_ntoa() resides in memory which is allocated by the Windows Sockets implementation. The application should not make any assumptions about the way in which the memory is allocated. The data is guaranteed to be valid until the next Windows Sockets API call within the same thread, but no longer. Return Value If no error occurs, inet_ntoa() returns a char pointer to a static buffer containing the text address in standard ".'' notation. Otherwise, it returns NULL. The data should be copied before another Windows Sockets call is made. See Also inet_addr(). ioctlsocket 45 4.1.12 ioctlsocket() Description Control the mode of a socket. #include int PASCAL FAR ioctlsocket ( SOCKET s, long cmd, u_long FAR * argp ); s A descriptor identifying a socket. cmd The command to perform on the socket s. argp A pointer to a parameter for cmd. Remarks This routine may be used on any socket in any state. It is used to get or retrieve operating parameters associated with the socket, independent of the protocol and communications subsystem. The following commands are supported: Command Semantics FIONBIO Enable or disable non-blocking mode on the socket s. argp points at an unsigned long, which is non- zero if non-blocking mode is to be enabled and zero if it is to be disabled. When a socket is created, it operates in blocking mode (i.e. non- blocking mode is disabled). This is consistent with BSD sockets. The WSAAsyncSelect() routine automatically sets a socket to nonblocking mode. If WSAAsyncSelect() has been issued on a socket, then any attempt to use ioctlsocket() to set the socket back to blocking mode will fail with WSAEINVAL. To set the socket back to blocking mode, an application must first disable WSAAsyncSelect() by calling WSAAsyncSelect() with the lEvent parameter equal to 0. FIONREAD Determine the amount of data which can be read atomically from socket s. argp points at an unsigned long in which ioctlsocket() stores the result. If s is of type SOCK_STREAM, FIONREAD returns the total amount of data which may be read in a single recv(); this is normally the same as the total amount of data queued on the socket. If s is of type SOCK_DGRAM, FIONREAD returns the size of the first datagram queued on the socket. SIOCATMARK Determine whether or not all out-of-band data has been read. This applies only to a socket of type SOCK_STREAM which has been configured for in- line reception of any out-of-band data (SO_OOBINLINE). If no out-of-band data is waiting to be read, the operation returns TRUE. Otherwise it returns FALSE, and the next recv() or 46 ioctlsocket recvfrom() performed on the socket will retrieve some or all of the data preceding the "mark"; the application should use the SIOCATMARK operation to determine whether any remains. If there is any normal data preceding the "urgent" (out of band) data, it will be received in order. (Note that a recv() or recvfrom() will never mix out-of-band and normal data in the same call.) argp points at a BOOL in which ioctlsocket() stores the result. Compatibility This function is a subset of ioctl() as used in Berkeley sockets. In particular, there is no command which is equivalent to FIOASYNC, while SIOCATMARK is the only socket-level command which is supported. Return Value Upon successful completion, the ioctlsocket() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL cmd is not a valid command, or argp is not an acceptable parameter for cmd, or the command is not applicable to the type of socket supplied WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAENOTSOCK The descriptor s is not a socket. See Also socket(), setsockopt(), getsockopt(), WSAAsyncSelect(). listen 47 4.1.13 listen() Description Establish a socket to listen for incoming connection. #include int PASCAL FAR listen ( SOCKET s, int backlog ); s A descriptor identifying a bound, unconnected socket. backlog The maximum length to which the queue of pending connections may grow. Remarks To accept connections, a socket is first created with socket(), a backlog for incoming connections is specified with listen(), and then the connections are accepted with accept(). listen() applies only to sockets that support connections, i.e. those of type SOCK_STREAM. The socket s is put into "passive'' mode where incoming connections are acknowledged and queued pending acceptance by the process. This function is typically used by servers that could have more than one connection request at a time: if a connection request arrives with the queue full, the client will receive an error with an indication of WSAECONNREFUSED. listen() attempts to continue to function rationally when there are no available descriptors. It will accept connections until the queue is emptied. If descriptors become available, a later call to listen() or accept() will re-fill the queue to the current or most recent "backlog'', if possible, and resume listening for incoming connections. Compatibility backlog is currently limited (silently) to 5. As in 4.3BSD, illegal values (less than 1 or greater than 5) are replaced by the nearest legal value. Return Value If no error occurs, listen() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEADDRINUSE An attempt has been made to listen() on an address in use. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINVAL The socket has not been bound with bind() or is already connected. 48 listen WSAEISCONN The socket is already connected. WSAEMFILE No more file descriptors are available. WSAENOBUFS No buffer space is available. WSAENOTSOCK The descriptor is not a socket. WSAEOPNOTSUPP The referenced socket is not of a type that supports the listen() operation. See Also accept(), connect(), socket(). ntohl 49 4.1.14 ntohl() Description Convert a u_long from network to host byte order. #include u_long PASCAL FAR ntohl ( u_long netlong ); netlong A 32-bit number in network byte order. Remarks This routine takes a 32-bit number in network byte order and returns a 32-bit number in host byte order. Return Value ntohl() returns the value in host byte order. See Also htonl(), htons(), ntohs(). 50 ntohs 4.1.15 ntohs() Description Convert a u_short from network to host byte order. #include u_short PASCAL FAR ntohs ( u_short netshort ); netshort A 16-bit number in network byte order. Remarks This routine takes a 16-bit number in network byte order and returns a 16-bit number in host byte order. Return Value ntohs() returns the value in host byte order. See Also htonl(), htons(), ntohl(). recv 51 4.1.16 recv() Description Receive data from a socket. #include int PASCAL FAR recv ( SOCKET s, char FAR * buf, int len, int flags ); s A descriptor identifying a connected socket. buf A buffer for the incoming data. len The length of buf. flags Specifies the way in which the call is made. Remarks This function is used on connected datagram or stream sockets specified by the s parameter and is used to read incoming data. For sockets of type SOCK_STREAM, as much information as is currently available up to the size of the buffer supplied is returned. If the socket has been configured for in-line reception of out-of-band data (socket option SO_OOBINLINE) and out-of-band data is unread, only out-of-band data will be returned. The application may use the ioctlsocket() SIOCATMARK to determine whether any more out-of-band data remains to be read. For datagram sockets, data is extracted from the first enqueued datagram, up to the size of the buffer supplied. If the datagram is larger than the buffer supplied, the buffer is filled with the first part of the datagram, the excess data is lost, and recv() returns the error WSAEMSGSIZE. If no incoming data is available at the socket, the recv() call waits for data to arrive unless the socket is non- blocking. In this case a value of SOCKET_ERROR is returned with the error code set to WSAEWOULDBLOCK. The select() or WSAAsyncSelect() calls may be used to determine when more data arrives. If the socket is of type SOCK_STREAM and the remote side has shut down the connection gracefully, a recv() will complete immediately with 0 bytes received. If the connection has been reset, a recv() will fail with the error WSAECONNRESET. Flags may be used to influence the behavior of the function invocation beyond the options specified for the associated socket. That is, the semantics of this function are determined by the socket options and the flags parameter. The latter is constructed by or-ing any of the following values: Value Meaning 52 recv MSG_PEEK Peek at the incoming data. The data is copied into the buffer but is not removed from the input queue. MSG_OOB Process out-of-band data (See section 2.2.3 for a discussion of this topic.) Return Value If no error occurs, recv() returns the number of bytes received. If the connection has been closed, it returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOTCONN The socket is not connected. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAENOTSOCK The descriptor is not a socket. WSAEOPNOTSUPP MSG_OOB was specified, but the socket is not of type SOCK_STREAM. WSAESHUTDOWN The socket has been shutdown; it is not possible to recv() on a socket after shutdown() has been invoked with how set to 0 or 2. WSAEWOULDBLOCK The socket is marked as non-blocking and the receive operation would block. WSAEMSGSIZE The datagram was too large to fit into the specified buffer and was truncated. WSAEINVAL The socket has not been bound with bind(). WSAECONNABORTED The virtual circuit was aborted due to timeout or other failure. WSAECONNRESET The virtual circuit was reset by the remote side. recv 53 See Also recvfrom(), read(), ,recv(), send(), select(), WSAAsyncSelect(), socket() 54 recvfrom 4.1.17 recvfrom() Description Receive a datagram and store the source address. #include int PASCAL FAR recvfrom ( SOCKET s, char FAR * buf, int len, int flags, struct sockaddr FAR * from, int FAR * fromlen ); s A descriptor identifying a bound socket. buf A buffer for the incoming data. len The length of buf. flags Specifies the way in which the call is made. from An optional pointer to a buffer which will hold the source address upon return. fromlen An optional pointer to the size of the from buffer. Remarks This function is used to read incoming data on a (possibly connected) socket and capture the address from which the data was sent. For sockets of type SOCK_STREAM, as much information as is currently available up to the size of the buffer supplied is returned. If the socket has been configured for in-line reception of out-of-band data (socket option SO_OOBINLINE) and out-of-band data is unread, only out-of-band data will be returned. The application may use the ioctlsocket() SIOCATMARK to determine whether any more out-of-band data remains to be read. The from and fromlen parameters are ignored for SOCK_STREAM sockets. For datagram sockets, data is extracted from the first enqueued datagram, up to the size of the buffer supplied. If the datagram is larger than the buffer supplied, the buffer is filled with the first part of the message, the excess data is lost, and recvfrom() returns the error code WSAEMSGSIZE. If from is non-zero, and the socket is of type SOCK_DGRAM, the network address of the peer which sent the data is copied to the corresponding struct sockaddr. The value pointed to by fromlen is initialized to the size of this structure, and is modified on return to indicate the actual size of the address stored there. If no incoming data is available at the socket, the recvfrom() call waits for data to arrive unless the socket is non-blocking. In this case a value of SOCKET_ERROR is returned with the error code set to WSAEWOULDBLOCK. The recvfrom 55 select() or WSAAsyncSelect() calls may be used to determine when more data arrives. If the socket is of type SOCK_STREAM and the remote side has shut down the connection gracefully, a recvfrom() will complete immediately with 0 bytes received. If the connection has been reset recv() will fail with the error WSAECONNRESET. Flags may be used to influence the behavior of the function invocation beyond the options specified for the associated socket. That is, the semantics of this function are determined by the socket options and the flags parameter. The latter is constructed by or-ing any of the following values: Value Meaning MSG_PEEK Peek at the incoming data. The data is copied into the buffer but is not removed from the input queue. MSG_OOB Process out-of-band data (See section 2.2.3 for a discussion of this topic.) Return Value If no error occurs, recvfrom() returns the number of bytes received. If the connection has been closed, it returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEFAULT The fromlen argument was invalid: the from buffer was too small to accommodate the peer address. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINVAL The socket has not been bound with bind(). WSAENOTCONN The socket is not connected (SOCK_STREAM only). WSAENOTSOCK The descriptor is not a socket. 56 recvfrom WSAEOPNOTSUPP MSG_OOB was specified, but the socket is not of type SOCK_STREAM. WSAESHUTDOWN The socket has been shutdown; it is not possible to recvfrom() on a socket after shutdown() has been invoked with how set to 0 or 2. WSAEWOULDBLOCK The socket is marked as non-blocking and the recvfrom() operation would block. WSAEMSGSIZE The datagram was too large to fit into the specified buffer and was truncated. WSAECONNABORTED The virtual circuit was aborted due to timeout or other failure. WSAECONNRESET The virtual circuit was reset by the remote side. See Also recv(), send(), socket(), WSAAsyncSelect(). select 57 4.1.18 select() Description Determine the status of one or more sockets, waiting if necessary. #include int PASCAL FAR select ( int nfds, fd_set FAR * readfds, fd_set FAR * writefds, fd_set FAR * exceptfds, const struct timeval FAR * timeout ); nfds This argument is ignored and included only for the sake of compatibility. readfds An optional pointer to a set of sockets to be checked for readability. writefds An optional pointer to a set of sockets to be checked for writability exceptfds An optional pointer to a set of sockets to be checked for errors. timeout The maximum time for select() to wait, or NULL for blocking operation. Remarks This function is used to determine the status of one or more sockets. For each socket, the caller may request information on read, write or error status. The set of sockets for which a given status is requested is indicated by an fd_set structure. Upon return, the structure is updated to reflect the subset of these sockets which meet the specified condition, and select() returns the number of sockets meeting the conditions. A set of macros is provided for manipulating an fd_set. These macros are compatible with those used in the Berkeley software, but the underlying representation is completely different. The parameter readfds identifies those sockets which are to be checked for readability. If the socket is currently listen()ing, it will be marked as readable if an incoming connection request has been received, so that an accept() is guaranteed to complete without blocking. For other sockets, readability means that queued data is available for reading or, for sockets of type SOCK_STREAM, that the virtual socket corresponding to the socket has been closed, so that a recv() or recvfrom() is guaranteed to complete without blocking. If the virtual circuit was closed gracefully, then a recv() will return immediately with 0 bytes read; if the virtual circuit was reset, then a recv() will complete immediately with the error code WSAECONNRESET. The presence of out-of-band data will be checked if the socket option SO_OOBINLINE has been enabled (see setsockopt()). The parameter writefds identifies those sockets which are to be checked for writability. If a socket is connect()ing 58 select (non-blocking), writability means that the connection establishment successfully completed. If the socket is not in the process of connect()ing, writability means that a send() or sendto() will complete without blocking. [It is not specified how long this guarantee can be assumed to be valid, particularly in a multithreaded environment.] The parameter exceptfds identifies those sockets which are to be checked for the presence of out-of-band data or any exceptional error conditions. Note that out-of-band data will only be reported in this way if the option SO_OOBINLINE is FALSE. For a SOCK_STREAM, the breaking of the connection by the peer or due to KEEPALIVE failure will be indicated as an exception. This specification does not define which other errors will be included. If a socket is connect()ing (non-blocking), failure of the connect attempt is indicated in exceptfds. Any of readfds, writefds, or exceptfds may be given as NULL if no descriptors are of interest. Four macros are defined in the header file winsock.h for manipulating the descriptor sets. The variable FD_SETSIZE determines the maximum number of descriptors in a set. (The default value of FD_SETSIZE is 64, which may be modified by #defining FD_SETSIZE to another value before #including winsock.h.) Internally, an fd_set is represented as an array of SOCKETs; the last valid entry is followed by an element set to INVALID_SOCKET. The macros are: FD_CLR(s, *set) Removes the descriptor s from set. FD_ISSET(s, *set) Nonzero if s is a member of the set, zero otherwise. FD_SET(s, *set) Adds descriptor s to set. FD_ZERO(*set) Initializes the set to the NULL set. The parameter timeout controls how long the select() may take to complete. If timeout is a null pointer, select() will block indefinitely until at least one descriptor meets the specified criteria. Otherwise, timeout points to a struct timeval which specifies the maximum time that select() should wait before returning. If the timeval is initialized to {0, 0}, select() will return immediately; this is used to "poll" the state of the selected sockets. If this is the case, then the select() call is considered nonblocking and the standard assumptions for nonblocking calls apply. For example, the blocking hook must not be called, and the Windows Sockets implementation must not yield. Return Value select() returns the total number of descriptors which are ready and contained in the fd_set structures, 0 if the time limit expired, or SOCKET_ERROR if an error occurred. select 59 If the return value is SOCKET_ERROR, WSAGetLastError() may be used to retrieve a specific error code. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL The timeout value is not valid. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAENOTSOCK One of the descriptor sets contains an entry which is not a socket. See Also WSAAsyncSelect(), accept(), connect(), recv(), recvfrom(), send(). 60 send 4.1.19 send() Description Send data on a connected socket. #include int PASCAL FAR send ( SOCKET s, const char FAR * buf, int len, int flags ); s A descriptor identifying a connected socket. buf A buffer containing the data to be transmitted. len The length of the data in buf. flags Specifies the way in which the call is made. Remarks send() is used on connected datagram or stream sockets and is used to write outgoing data on a socket. For datagram sockets, care must be taken not to exceed the maximum IP packet size of the underlying subnets, which is given by the iMaxUdpDg element in the WSAData structure returned by WSAStartup(). If the data is too long to pass atomically through the underlying protocol the error WSAEMSGSIZE is returned, and no data is transmitted. Note that the successful completion of a send() does not indicate that the data was successfully delivered. If no buffer space is available within the transport system to hold the data to be transmitted, send() will block unless the socket has been placed in a non-blocking I/O mode. On non-blocking SOCK_STREAM sockets, the number of bytes written may be between 1 and the requested length, depending on buffer availability on both the local and foreign hosts. The select() call may be used to determine when it is possible to send more data. Flags may be used to influence the behavior of the function invocation beyond the options specified for the associated socket. That is, the semantics of this function are determined by the socket options and the flags parameter. The latter is constructed by or-ing any of the following values: Value Meaning MSG_DONTROUTE Specifies that the data should not be subject to routing. A Windows Sockets supplier may choose to ignore this flag; see also the discussion of the SO_DONTROUTE option in section 2.4. MSG_OOB Send out-of-band data (SOCK_STREAM only; see also section 2.2.3) send 61 Return Value If no error occurs, send() returns the total number of characters sent. (Note that this may be less than the number indicated by len.) Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEACCES The requested address is a broadcast address, but the appropriate flag was not set. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEFAULT The buf argument is not in a valid part of the user address space. WSAENETRESET The connection must be reset because the Windows Sockets implementation dropped it. WSAENOBUFS The Windows Sockets implementation reports a buffer deadlock. WSAENOTCONN The socket is not connected. WSAENOTSOCK The descriptor is not a socket. WSAEOPNOTSUPP MSG_OOB was specified, but the socket is not of type SOCK_STREAM. WSAESHUTDOWN The socket has been shutdown; it is not possible to send() on a socket after shutdown() has been invoked with how set to 1 or 2. WSAEWOULDBLOCK The socket is marked as non-blocking and the requested operation would block. WSAEMSGSIZE The socket is of type SOCK_DGRAM, and the datagram is larger than the maximum supported by the Windows Sockets implementation. WSAEINVAL The socket has not been bound with bind(). 62 send WSAECONNABORTED The virtual circuit was aborted due to timeout or other failure. WSAECONNRESET The virtual circuit was reset by the remote side. See Also recv(), recvfrom(), socket(), sendto(), WSAStartup(). sendto 63 4.1.20 sendto() Description Send data to a specific destination. #include int PASCAL FAR sendto ( SOCKET s, const char FAR * buf, int len, int flags, const struct sockaddr FAR * to, int tolen ); s A descriptor identifying a socket. buf A buffer containing the data to be transmitted. len The length of the data in buf. flags Specifies the way in which the call is made. to An optional pointer to the address of the target socket. tolen The size of the address in to. Remarks sendto() is used on datagram or stream sockets and is used to write outgoing data on a socket. For datagram sockets, care must be taken not to exceed the maximum IP packet size of the underlying subnets, which is given by the iMaxUdpDg element in the WSAData structure returned by WSAStartup(). If the data is too long to pass atomically through the underlying protocol the error WSAEMSGSIZE is returned, and no data is transmitted. Note that the successful completion of a sendto() does not indicate that the data was successfully delivered. sendto() is normally used on a SOCK_DGRAM socket to send a datagram to a specific peer socket identified by the to parameter. On a SOCK_STREAM socket, the to and tolen parameters are ignored; in this case the sendto() is equivalent to send(). To send a broadcast (on a SOCK_DGRAM only), the address in the to parameter should be constructed using the special IP address INADDR_BROADCAST (defined in winsock.h) together with the intended port number. It is generally inadvisable for a broadcast datagram to exceed the size at which fragmentation may occur, which implies that the data portion of the datagram (excluding headers) should not exceed 512 bytes. If no buffer space is available within the transport system to hold the data to be transmitted, sendto() will block unless the socket has been placed in a non-blocking I/O mode. On non-blocking SOCK_STREAM sockets, the number of bytes written may be between 1 and the requested length, depending on buffer availability on both the local and 64 sendto foreign hosts. The select() call may be used to determine when it is possible to send more data. Flags may be used to influence the behavior of the function invocation beyond the options specified for the associated socket. That is, the semantics of this function are determined by the socket options and the flags parameter. The latter is constructed by or-ing any of the following values: Value Meaning MSG_DONTROUTE Specifies that the data should not be subject to routing. A Windows Sockets supplier may choose to ignore this flag; see also the discussion of the SO_DONTROUTE option in section . MSG_OOB Send out-of-band data (SOCK_STREAM only; see also section ) Return Value If no error occurs, sendto() returns the total number of characters sent. (Note that this may be less than the number indicated by len.) Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEACCES The requested address is a broadcast address, but the appropriate flag was not set. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEFAULT The buf or to parameters are not part of the user address space, or the to argument is too small (less than the sizeof a struct sockaddr). WSAENETRESET The connection must be reset because the Windows Sockets implementation dropped it. WSAENOBUFS The Windows Sockets implementation reports a buffer deadlock. sendto 65 WSAENOTCONN The socket is not connected (SOCK_STREAM only). WSAENOTSOCK The descriptor is not a socket. WSAEOPNOTSUPP MSG_OOB was specified, but the socket is not of type SOCK_STREAM. WSAESHUTDOWN The socket has been shutdown; it is not possible to sendto() on a socket after shutdown() has been invoked with how set to 1 or 2. WSAEWOULDBLOCK The socket is marked as non-blocking and the requested operation would block. WSAEMSGSIZE The socket is of type SOCK_DGRAM, and the datagram is larger than the maximum supported by the Windows Sockets implementation. WSAECONNABORTED The virtual circuit was aborted due to timeout or other failure. WSAECONNRESET The virtual circuit was reset by the remote side. WSAEADDRNOTAVAIL The specified address is not available from the local machine. WSAEAFNOSUPPORT Addresses in the specified family cannot be used with this socket. WSAEDESTADDRREQ A destination address is required. WSAENETUNREACH The network can't be reached from this host at this time. See Also recv(), recvfrom(), socket(), send(), WSAStartup(). 66 setsockopt 4.1.21 setsockopt() Description Set a socket option. #include int PASCAL FAR setsockopt ( SOCKET s, int level, int optname, const char FAR * optval, int optlen ); s A descriptor identifying a socket. level The level at which the option is defined; the only supported levels are SOL_SOCKET and IPPROTO_TCP. optname The socket option for which the value is to be set. optval A pointer to the buffer in which the value for the requested option is supplied. optlen The size of the optval buffer. Remarks setsockopt() sets the current value for a socket option associated with a socket of any type, in any state. Although options may exist at multiple protocol levels, this specification only defines options that exist at the uppermost "socket'' level. Options affect socket operations, such as whether expedited data is received in the normal data stream, whether broadcast messages may be sent on the socket, etc. There are two types of socket options: Boolean options that enable or disable a feature or behavior, and options which require an integer value or structure. To enable a Boolean option, optval points to a nonzero integer. To disable the option optval points to an integer equal to zero. optlen should be equal to sizeof(int) for Boolean options. For other options, optval points to the an integer or structure that contains the desired value for the option, and optlen is the length of the integer or structure. SO_LINGER controls the action taken when unsent data is queued on a socket and a closesocket() is performed. See closesocket() for a description of the way in which the SO_LINGER settings affect the semantics of closesocket(). The application sets the desired behavior by creating a struct linger (pointed to by the optval argument) with the following elements: struct linger { int l_onoff; int l_linger; } To enable SO_LINGER, the application should set l_onoff to a non-zero value, set l_linger to 0 or the desired timeout (in setsockopt 67 seconds), and call setsockopt(). To enable SO_DONTLINGER (i.e. disable SO_LINGER) l_onoff should be set to zero and setsockopt() should be called. By default, a socket may not be bound (see bind()) to a local address which is already in use. On occasions, however, it may be desirable to "re-use" an address in this way. Since every connection is uniquely identified by the combination of local and remote addresses, there is no problem with having two sockets bound to the same local address as long as the remote addresses are different. To inform the Windows Sockets implementation that a bind() on a socket should not be disallowed because the desired address is already in use by another socket, the application should set the SO_REUSEADDR socket option for the socket before issuing the bind(). Note that the option is interpreted only at the time of the bind(): it is therefore unnecessary (but harmless) to set the option on a socket which is not to be bound to an existing address, and setting or resetting the option after the bind() has no effect on this or any other socket. An application may request that the Windows Sockets implementation enable the use of "keep-alive" packets on TCP connections by turning on the SO_KEEPALIVE socket option. A Windows Sockets implementation need not support the use of keep-alives: if it does, the precise semantics are implementation-specific but should conform to section 4.2.3.6 of RFC 1122: Requirements for Internet Hosts -- Communication Layers. If a connection is dropped as the result of "keep-alives" the error code WSAENETRESET is returned to any calls in progress on the socket, and any subsequent calls will fail with WSAENOTCONN. The TCP_NODELAY option disables the Nagle algorithm. The Nagle algorithm is used to reduce the number of small packets sent by a host by buffering unacknowledged send data until a full-size packet can be sent. However, for some applications this algorithm can impede performance, and TCP_NODELAY may be used to turn it off. Application writers should not set TCP_NODELAY unless the impact of doing so is well-understood and desired, since setting TCP_NODELAY can have a significant negative impact of network performance. TCP_NODELAY is the only supported socket option which uses level IPPROTO_TCP; all other options use level SOL_SOCKET. Windows Sockets suppliers are encouraged (but not required) to supply output debug information if the SO_DEBUG option is set by an application. The mechanism for generating the debug information and the form it takes are beyond the scope of this specification. The following options are supported for setsockopt(). The Type identifies the type of data addressed by optval. Value Type Meaning 68 setsockopt SO_BROADCAS BOOL Allow transmission of T broadcast messages on the socket. SO_DEBUG BOOL Record debugging information. SO_DONTLING BOOL Don't block close waiting ER for unsent data to be sent. Setting this option is equivalent to setting SO_LINGER with l_onoff set to zero. SO_DONTROUT BOOL Don't route: send directly E to interface. SO_KEEPALIV BOOL Send keepalives E SO_LINGER struct Linger on close if unsent linger data is present FAR * SO_OOBINLIN BOOL Receive out-of-band data in E the normal data stream. SO_RCVBUF int Specify buffer size for receives SO_REUSEADD BOOL Allow the socket to be bound R to an address which is already in use. (See bind().) SO_SNDBUF int Specify buffer size for sends. TCP_NODELAY BOOL Disables the Nagle algorithm for send coalescing. BSD options not supported for setsockopt() are: Value Type Meaning SO_ACCEPTCO BOOL Socket is listening NN SO_ERROR int Get error status and clear SO_RCVLOWAT int Receive low water mark SO_RCVTIMEO int Receive timeout SO_SNDLOWAT int Send low water mark SO_SNDTIMEO int Send timeout SO_TYPE int Type of the socket IP_OPTIONS Set options field in IP header. Return Value If no error occurs, setsockopt() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. setsockopt 69 WSAEFAULT optval is not in a valid part of the process address space. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINVAL level is not valid, or the information in optval is not valid. WSAENETRESET Connection has timed out when SO_KEEPALIVE is set. WSAENOPROTOOPT The option is unknown or unsupported. In particular, SO_BROADCAST is not supported on sockets of type SOCK_STREAM, while SO_DONTLINGER, SO_KEEPALIVE, SO_LINGER and SO_OOBINLINE are not supported on sockets of type SOCK_DGRAM. WSAENOTCONN Connection has been reset when SO_KEEPALIVE is set. WSAENOTSOCK The descriptor is not a socket. See Also bind(), getsockopt(), ioctlsocket(), socket(), WSAAsyncSelect(). 70 shutdown 4.1.22 shutdown() Description Disable sends and/or receives on a socket. #include int PASCAL FAR shutdown ( SOCKET s, int how ); s A descriptor identifying a socket. how A flag that describes what types of operation will no longer be allowed. Remarks shutdown() is used on all types of sockets to disable reception, transmission, or both. If how is 0, subsequent receives on the socket will be disallowed. This has no effect on the lower protocol layers. For TCP, the TCP window is not changed and incoming data will be accepted (but not acknowledged) until the window is exhausted. For UDP, incoming datagrams are accepted and queued. In no case will an ICMP error packet be generated. If how is 1, subsequent sends are disallowed. For TCP sockets, a FIN will be sent. Setting how to 2 disables both sends and receives as described above. Note that shutdown() does not close the socket, and resources attached to the socket will not be freed until closesocket() is invoked. Comments shutdown() does not block regardless of the SO_LINGER setting on the socket. An application should not rely on being able to re-use a socket after it has been shut down. In particular, a Windows Sockets implementation is not required to support the use of connect() on such a socket. Return Value If no error occurs, shutdown() returns 0. Otherwise, a value of SOCKET_ERROR is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL how is not valid. shutdown 71 WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAENOTCONN The socket is not connected (SOCK_STREAM only). WSAENOTSOCK The descriptor is not a socket. See Also connect(), socket(). 72 socket 4.1.23 socket() Description Create a socket. #include SOCKET PASCAL FAR socket ( int af, int type, int protocol ); af An address format specification. The only format currently supported is PF_INET, which is the ARPA Internet address format. type A type specification for the new socket. protocol A particular protocol to be used with the socket, or 0 if the caller does not wish to specify a protocol. Remarks socket() allocates a socket descriptor of the specified address family, data type and protocol, as well as related resources. If a protocol is not specified (i.e. equal to 0), the default for the specified connection mode is used. Only a single protocol exists to support a particular socket type using a given address format. However, the address family may be given as AF_UNSPEC (unspecified), in which case the protocol parameter must be specified. The protocol number to use is particular to the "communication domain'' in which communication is to take place. The following type specifications are supported: Type Explanation SOCK_STREAM Provides sequenced, reliable, two-way, connection-based byte streams with an out-of-band data transmission mechanism. Uses TCP for the Internet address family. SOCK_DGRAM Supports datagrams, which are connectionless, unreliable buffers of a fixed (typically small) maximum length. Uses UDP for the Internet address family. Sockets of type SOCK_STREAM are full-duplex byte streams. A stream socket must be in a connected state before any data may be sent or received on it. A connection to another socket is created with a connect() call. Once connected, data may be transferred using send() and recv() calls. When a session has been completed, a closesocket() must be performed. Out-of-band data may also be transmitted as described in send() and received as described in recv(). The communications protocols used to implement a SOCK_STREAM ensure that data is not lost or duplicated. If data for socket 73 which the peer protocol has buffer space cannot be successfully transmitted within a reasonable length of time, the connection is considered broken and subsequent calls will fail with the error code set to WSAETIMEDOUT. SOCK_DGRAM sockets allow sending and receiving of datagrams to and from arbitrary peers using sendto() and recvfrom(). If such a socket is connect()ed to a specific peer, datagrams may be send to that peer send() and may be received from (only) this peer using recv(). Return Value If no error occurs, socket() returns a descriptor referencing the new socket. Otherwise, a value of INVALID_SOCKET is returned, and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEAFNOSUPPORT The specified address family is not supported. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEMFILE No more file descriptors are available. WSAENOBUFS No buffer space is available. The socket cannot be created. WSAEPROTONOSUPPORT The specified protocol is not supported. WSAEPROTOTYPE The specified protocol is the wrong type for this socket. WSAESOCKTNOSUPPORT The specified socket type is not supported in this address family. See Also accept(), bind(), connect(), getsockname(), getsockopt(), setsockopt(), listen(), recv(), recvfrom(), select(), send(), sendto(), shutdown(), ioctlsocket(). 74 gethostbyaddr 4.2 Database Routines 4.2.1 gethostbyaddr() Description Get host information corresponding to an address. #include struct hostent FAR * PASCAL FAR gethostbyaddr ( const char FAR * addr, int len, int type ); addr A pointer to an address in network byte order. len The length of the address, which must be 4 for PF_INET addresses. type The type of the address, which must be PF_INET. Remarks gethostbyaddr() returns a pointer to the following structure which contains the name(s) and address which correspond to the given address. struct hostent { char FAR * h_name; char FAR * FAR * h_aliases; short h_addrtype; short h_length; char FAR * FAR * h_addr_list; }; The members of this structure are: Element Usage h_name Official name of the host (PC). h_aliases A NULL-terminated array of alternate names. h_addrtype The type of address being returned; for Windows Sockets this is always PF_INET. h_length The length, in bytes, of each address; for PF_INET, this is always 4. h_addr_list A NULL-terminated list of addresses for the host. Addresses are returned in network byte order. The macro h_addr is defined to be h_addr_list[0] for compatibility with older software. The pointer which is returned points to a structure which is allocated by the Windows Sockets implementation. The application must never attempt to modify this structure or to free any of its components. Furthermore, only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. Return Value If no error occurs, gethostbyaddr() returns a pointer to the hostent structure described above. Otherwise it gethostbyaddr 75 returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetHostByAddr(), gethostbyname(), 76 gethostbyname 4.2.2 gethostbyname() Description Get host information corresponding to a hostname. #include struct hostent FAR * PASCAL FAR gethostbyname ( const char FAR * name ); name A pointer to the name of the host. Remarks gethostbyname() returns a pointer to a hostent structure as described under gethostbyaddr(). The contents of this structure correspond to the hostname name. The pointer which is returned points to a structure which is allocated by the Windows Sockets implementation. The application must never attempt to modify this structure or to free any of its components. Furthermore, only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. A gethostbyname() implementation must not resolve IP address strings passed to it. Such a request should be treated exactly as if an unknown host name were passed. An application with an IP address string to resolve should use inet_addr() to convert the string to an IP address, then gethostbyaddr() to obtain the hostent structure. Return Value If no error occurs, gethostbyname() returns a pointer to the hostent structure described above. Otherwise it returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. gethostname 77 WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetHostByName(), gethostbyaddr() 78 gethostbyname 4.2.3 gethostname() Description Return the standard host name for the local machine. #include int PASCAL FAR gethostname ( char FAR * name, int namelen ); name A pointer to a buffer that will receive the host name. namelen The length of the buffer. Remarks This routine returns the name of the local host into the buffer specified by the name parameter. The host name is returned as a null-terminated string. The form of the host name is dependent on the Windows Sockets implementation--it may be a simple host name, or it may be a fully qualified domain name. However, it is guaranteed that the name returned will be successfully parsed by gethostbyname() and WSAAsyncGetHostByName(). Return Value If no error occurs, gethostname() returns 0, otherwise it returns SOCKET_ERROR and a specific error code may be retrieved by calling WSAGetLastError(). Error Codes WSAEFAULT The namelen parameter is too small WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. See Also gethostbyname(), WSAAsyncGetHostByName(). getprotobyname 79 4.2.4 getprotobyname() Description Get protocol information corresponding to a protocol name. #include struct protoent FAR * PASCAL FAR getprotobyname ( const char FAR * name ); name A pointer to a protocol name. Remarks getprotobyname() returns a pointer to the following structure which contains the name(s) and protocol number which correspond to the given protocol name. struct protoent { char FAR * p_name; char FAR * FAR * p_aliases; short p_proto; }; The members of this structure are: Element Usage p_name Official name of the protocol. p_aliases A NULL-terminated array of alternate names. p_proto The protocol number, in host byte order. The pointer which is returned points to a structure which is allocated by the Windows Sockets library. The application must never attempt to modify this structure or to free any of its components. Furthermore only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. Return Value If no error occurs, getprotobyname() returns a pointer to the protoent structure described above. Otherwise it returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. 80 getprotobyname WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetProtoByName(), getprotobynumber() getprotobynumber 81 4.2.5 getprotobynumber() Description Get protocol information corresponding to a protocol number. #include struct protoent FAR * PASCAL FAR getprotobynumber ( int number ); number A protocol number, in host byte order. Remarks This function returns a pointer to a protoent structure as described above in getprotobyname(). The contents of the structure correspond to the given protocol number. The pointer which is returned points to a structure which is allocated by the Windows Sockets implementation. The application must never attempt to modify this structure or to free any of its components. Furthermore, only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. Return Value If no error occurs, getprotobynumber() returns a pointer to the protoent structure described above. Otherwise it returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetProtoByNumber(), getprotobyname() 82 getservbyname 4.2.6 getservbyname() Description Get service information corresponding to a service name and protocol. #include struct servent FAR * PASCAL FAR getservbyname ( const char FAR * name, const char FAR * proto ); name A pointer to a service name. proto An optional pointer to a protocol name. If this is NULL, getservbyname() returns the first service entry for which the name matches the s_name or one of the s_aliases. Otherwise getservbyname() matches both the name and the proto. Remarks getservbyname() returns a pointer to the following structure which contains the name(s) and service number which correspond to the given service name. struct servent { char FAR * s_name; char FAR * FAR * s_aliases; short s_port; char FAR * s_proto; }; The members of this structure are: Element Usage s_name Official name of the service. s_aliases A NULL-terminated array of alternate names. s_port The port number at which the service may be contacted. Port numbers are returned in network byte order. s_proto The name of the protocol to use when contacting the service. The pointer which is returned points to a structure which is allocated by the Windows Sockets library. The application must never attempt to modify this structure or to free any of its components. Furthermore only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. Return Value If no error occurs, getservbyname() returns a pointer to the servent structure described above. Otherwise it returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. getservbyname 83 WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetServByName(), getservbyport() 84 getservbyport 4.2.7 getservbyport() Description Get service information corresponding to a port and protocol. #include struct servent FAR * PASCAL FAR getservbyport ( int port, const char FAR * proto ); port The port for a service, in network byte order. proto An optional pointer to a protocol name. If this is NULL, getservbyport() returns the first service entry for which the port matches the s_port. Otherwise getservbyport() matches both the port and the proto. Remarks getservbyport() returns a pointer a servent structure as described above for getservbyname(). The pointer which is returned points to a structure which is allocated by the Windows Sockets implementation. The application must never attempt to modify this structure or to free any of its components. Furthermore, only one copy of this structure is allocated per thread, and so the application should copy any information which it needs before issuing any other Windows Sockets API calls. Return Value If no error occurs, getservbyport() returns a pointer to the servent structure described above. Otherwise it returns a NULL pointer and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEINTR The (blocking) call was canceled via WSACancelBlockingCall(). See Also WSAAsyncGetServByPort(), getservbyname() WSAAsyncGetHostByAddr 85 4.3 Microsoft Windows-specific Extensions 4.3.1 WSAAsyncGetHostByAddr() Description Get host information corresponding to an address - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetHostByAddr ( HWND hWnd, unsigned int wMsg, const char FAR * addr, int len, int type, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. addr A pointer to the network address for the host. Host addresses are stored in network byte order. len The length of the address, which must be 4 for PF_INET. type The type of the address, which must be PF_INET. buf A pointer to the data area to receive the hostent data. Note that this must be larger than the size of a hostent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a hostent structure but any and all of the data which is referenced by members of the hostent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of gethostbyaddr(), and is used to retrieve host name and address information corresponding to a network address. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original 86 WSAAsyncGetHostByAddr function call contains a hostent structure. To access the elements of this structure, the original buffer address should be cast to a hostent structure pointer and accessed as appropriate. Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetHostByAddr() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetHostByAddr() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncGetHostByAddr() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a hostent structure together with the contents of data areas referenced by members of the same hostent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation WSAAsyncGetHostByAddr 87 fails, the Windows Sockets implementation must re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also gethostbyaddr(), WSACancelAsyncRequest() 88 WSAAsyncGetHostByName 4.3.2 WSAAsyncGetHostByName() Description Get host information corresponding to a hostname - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetHostByName ( HWND hWnd, unsigned int wMsg, const char FAR * name, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. name A pointer to the name of the host. buf A pointer to the data area to receive the hostent data. Note that this must be larger than the size of a hostent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a hostent structure but any and all of the data which is referenced by members of the hostent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of gethostbyname(), and is used to retrieve host name and address information corresponding to a hostname. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original function call contains a hostent structure. To access the elements of this structure, the original buffer address should be cast to a hostent structure pointer and accessed as appropriate. Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. WSAAsyncGetHostByName 89 In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetHostByName() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetHostByName() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncGetHostByName() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a hostent structure together with the contents of data areas referenced by members of the same hostent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation fails, the Windows Sockets implementation must re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. 90 WSAAsyncGetHostByName Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also gethostbyname(), WSACancelAsyncRequest() WSAAsyncGetProtoByName 91 4.3.3 WSAAsyncGetProtoByName() Description Get protocol information corresponding to a protocol name - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetProtoByName ( HWND hWnd, unsigned int wMsg, const char FAR * name, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. name A pointer to the protocol name to be resolved. buf A pointer to the data area to receive the protoent data. Note that this must be larger than the size of a protoent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a protoent structure but any and all of the data which is referenced by members of the protoent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of getprotobyname(), and is used to retrieve the protocol name and number corresponding to a protocol name. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original function call contains a protoent structure. To access the elements of this structure, the original buffer address should be cast to a protoent structure pointer and accessed as appropriate. Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. 92 WSAAsyncGetProtoByName In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetProtoByName() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetProtoByName() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncGetProtoByName() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a protoent structure together with the contents of data areas referenced by members of the same protoent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation fails, the Windows Sockets implementation must re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. WSAAsyncGetProtoByName 93 Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also getprotobyname(), WSACancelAsyncRequest() 94 WSAAsyncGetProtoByNumber 4.3.4 WSAAsyncGetProtoByNumber() Description Get protocol information corresponding to a protocol number - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetProtoByNumber ( HWND hWnd, unsigned int wMsg, int number, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. number The protocol number to be resolved, in host byte order. buf A pointer to the data area to receive the protoent data. Note that this must be larger than the size of a protoent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a protoent structure but any and all of the data which is referenced by members of the protoent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of getprotobynumber(), and is used to retrieve the protocol name and number corresponding to a protocol number. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original function call contains a protoent structure. To access the elements of this structure, the original buffer address should be cast to a protoent structure pointer and accessed as appropriate. WSAAsyncGetProtoByNumber 95 Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetProtoByNumber() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetProtoByNumber() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncGetProtoByNumber() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a protoent structure together with the contents of data areas referenced by members of the same protoent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation fails, the Windows Sockets implementation must re-post that message as long as the window exists. 96 WSAAsyncGetProtoByNumber Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also getprotobynumber(), WSACancelAsyncRequest() WSAAsyncGetServByName 97 4.3.5 WSAAsyncGetServByName() Description Get service information corresponding to a service name and port - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetServByName ( HWND hWnd, unsigned int wMsg, const char FAR * name, const char FAR * proto, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. name A pointer to a service name. proto A pointer to a protocol name. This may be NULL, in which case WSAAsyncGetServByName() will search for the first service entry for which s_name or one of the s_aliases matches the given name. Otherwise WSAAsyncGetServByName() matches both name and proto. buf A pointer to the data area to receive the servent data. Note that this must be larger than the size of a servent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a servent structure but any and all of the data which is referenced by members of the servent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of getservbyname(), and is used to retrieve service information corresponding to a service name. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original function call contains a hostent structure. To access the 98 WSAAsyncGetServByName elements of this structure, the original buffer address should be cast to a hostent structure pointer and accessed as appropriate. Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetServByName() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetServByName() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncServByName() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a hostent structure together with the contents of data areas referenced by members of the same hostent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation WSAAsyncGetServByName 99 fails, the Windows Sockets implementation must re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also getservbyname(), WSACancelAsyncRequest() 100 WSAAsyncGetServByPort 4.3.6 WSAAsyncGetServByPort() Description Get service information corresponding to a port and protocol - asynchronous version. #include HANDLE PASCAL FAR WSAAsyncGetServByPort ( HWND hWnd, unsigned int wMsg, int port, const char FAR * proto, char FAR * buf, int buflen ); hWnd The handle of the window which should receive a message when the asynchronous request completes. wMsg The message to be received when the asynchronous request completes. port The port for the service, in network byte order. proto A pointer to a protocol name. This may be NULL, in which case WSAAsyncGetServByPort() will search for the first service entry for which s_port match the given port. Otherwise WSAAsyncGetServByPort() matches both port and proto. buf A pointer to the data area to receive the servent data. Note that this must be larger than the size of a servent structure. This is because the data area supplied is used by the Windows Sockets implementation to contain not only a servent structure but any and all of the data which is referenced by members of the servent structure. It is recommended that you supply a buffer of MAXGETHOSTSTRUCT bytes. buflen The size of data area buf above. Remarks This function is an asynchronous version of getservbyport(), and is used to retrieve service information corresponding to a port number. The Windows Sockets implementation initiates the operation and returns to the caller immediately, passing back an asynchronous task handle which the application may use to identify the operation. When the operation is completed, the results (if any) are copied into the buffer provided by the caller and a message is sent to the application's window. When the asynchronous operation is complete the application's window hWnd receives message wMsg. The wParam argument contains the asynchronous task handle as returned by the original function call. The high 16 bits of lParam contain any error code. The error code may be any error as defined in winsock.h. An error code of zero indicates successful completion of the asynchronous operation. On successful completion, the buffer supplied to the original function call contains a servent structure. To access the elements of this structure, the original buffer address WSAAsyncGetServByPort 101 should be cast to a servent structure pointer and accessed as appropriate. Note that if the error code is WSAENOBUFS, it indicates that the size of the buffer specified by buflen in the original call was too small to contain all the resultant information. In this case, the low 16 bits of lParam contain the size of buffer required to supply ALL the requisite information. If the application decides that the partial data is inadequate, it may reissue the WSAAsyncGetServByPort() function call with a buffer large enough to receive all the desired information (i.e. no smaller than the low 16 bits of lParam). The error code and buffer length should be extracted from the lParam using the macros WSAGETASYNCERROR and WSAGETASYNCBUFLEN, defined in winsock.h as: #define WSAGETASYNCERROR(lParam) HIWORD(lParam) #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. Return Value The return value specifies whether or not the asynchronous operation was successfully initiated. Note that it does not imply success or failure of the operation itself. If the operation was successfully initiated, WSAAsyncGetServByPort() returns a nonzero value of type HANDLE which is the asynchronous task handle for the request. This value can be used in two ways. It can be used to cancel the operation using WSACancelAsyncRequest(). It can also be used to match up asynchronous operations and completion messages, by examining the wParam message argument. If the asynchronous operation could not be initiated, WSAAsyncGetServByPort() returns a zero value, and a specific error number may be retrieved by calling WSAGetLastError(). Comments The buffer supplied to this function is used by the Windows Sockets implementation to construct a servent structure together with the contents of data areas referenced by members of the same servent structure. To avoid the WSAENOBUFS error noted above, the application should provide a buffer of at least MAXGETHOSTSTRUCT bytes (as defined in winsock.h). Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets implementation to ensure that messages are successfully posted to the application. If a PostMessage() operation 102 WSAAsyncGetServByPort fails, the Windows Sockets implementation must re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKEASYNCREPLY macro when constructing the lParam in the message. Error Codes The following error codes may be set when an application window receives a message. As described above, they may be extracted from the lParam in the reply message using the WSAGETASYNCERROR macro. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAENOBUFS No/insufficient buffer space is available WSAHOST_NOT_FOUND Authoritative Answer Host not found. WSATRY_AGAIN Non-Authoritative Host not found, or SERVERFAIL. WSANO_RECOVERY Non recoverable errors, FORMERR, REFUSED, NOTIMP. WSANO_DATA Valid name, no data record of requested type. The following errors may occur at the time of the function call, and indicate that the asynchronous operation could not be initiated. WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEWOULDBLOCK The asynchronous operation cannot be scheduled at this time due to resource or other constraints within the Windows Sockets implementation. See Also getservbyport(), WSACancelAsyncRequest() WSAAsyncSelect 103 4.3.7 WSAAsyncSelect() Description Request event notification for a socket. #include int PASCAL FAR WSAAsyncSelect ( SOCKET s, HWND hWnd, unsigned int wMsg, long lEvent ); s A descriptor identifying the socket for which event notification is required. hWnd A handle identifying the window which should receive a message when a network event occurs. wMsg The message to be received when a network event occurs. lEvent A bitmask which specifies a combination of network events in which the application is interested. Remarks This function is used to request that the Windows Sockets DLL should send a message to the window hWnd whenever it detects any of the network events specified by the lEvent parameter. The message which should be sent is specified by the wMsg parameter. The socket for which notification is required is identified by s. This function automatically sets socket s to non-blocking mode. The lEvent parameter is constructed by or'ing any of the values specified in the following list. Value Meaning FD_READ Want to receive notification of readiness for reading FD_WRITE Want to receive notification of readiness for writing FD_OOB Want to receive notification of the arrival of out-of-band data FD_ACCEPT Want to receive notification of incoming connections FD_CONNECT Want to receive notification of completed connection FD_CLOSE Want to receive notification of socket closure Issuing a WSAAsyncSelect() for a socket cancels any previous WSAAsyncSelect() for the same socket. For example, to receive notification for both reading and writing, the application must call WSAAsyncSelect() with both FD_READ and FD_WRITE, as follows: rc = WSAAsyncSelect(s, hWnd, wMsg, FD_READ|FD_WRITE); 104 WSAAsyncSelect It is not possible to specify different messages for different events. The following code will not work; the second call will cancel the effects of the first, and only FD_WRITE events will be reported with message wMsg2: rc = WSAAsyncSelect(s, hWnd, wMsg1, FD_READ); rc = WSAAsyncSelect(s, hWnd, wMsg2, FD_WRITE); To cancel all notification i.e., to indicate that the Windows Sockets implementation should send no further messages related to network events on the socket lEvent should be set to zero. rc = WSAAsyncSelect(s, hWnd, 0, 0); Although in this instance WSAAsyncSelect() immediately disables event message posting for the socket, it is possible that messages may be waiting in the application's message queue. The application must therefore be prepared to receive network event messages even after cancellation. Closing a socket with closesocket() also cancels WSAAsyncSelect() message sending, but the same caveat about messages in the queue prior to the closesocket() still applies. Since an accept()'ed socket has the same properties as the listening socket used to accept it, any WSAAsyncSelect() events set for the listening socket apply to the accepted socket. For example, if a listening socket has WSAAsyncSelect() events FD_ACCEPT, FD_READ, and FD_WRITE, then any socket accepted on that listening socket will also have FD_ACCEPT, FD_READ, and FD_WRITE events with the same wMsg value used for messages. If a different wMsg or events are desired, the application should call WSAAsyncSelect(), passing the accepted socket and the desired new information.7 When one of the nominated network events occurs on the specified socket s, the application's window hWnd receives message wMsg. The wParam argument identifies the socket on which a network event has occurred. The low word of lParam specifies the network event that has occurred. The high word of lParam contains any error code. The error code be any error as defined in winsock.h. The error and event codes may be extracted from the lParam using the macros WSAGETSELECTERROR and WSAGETSELECTEVENT, defined in winsock.h as: 7Note that there is a timing window between the accept() accept() accept() call and the call to WSAAsyncSelect() WSAAsyncSelect() WSAAsyncSelect() to change the events or wMsg. An application which desires a different wMsg for the listening and accept() accept() accept()'ed sockets should ask for only FD_ACCEPT events on the listening socket, then set appropriate events after the accept() accept() accept(). Since FD_ACCEPT is never sent for a connected socket and FD_READ, FD_WRITE, FD_OOB, and FD_CLOSE are never sent for listening sockets, this will not impose difficulties. WSAAsyncSelect 105 #define WSAGETSELECTERROR(lParam) HIWORD(lParam) #define WSAGETSELECTEVENT(lParam) LOWORD(lParam) The use of these macros will maximize the portability of the source code for the application. The possible network event codes which may be returned are as follows: Value Meaning FD_READ Socket s ready for reading FD_WRITE Socket s ready for writing FD_OOB Out-of-band data ready for reading on socket s. FD_ACCEPT Socket s ready for accepting a new incoming connection FD_CONNECT Connection on socket s completed FD_CLOSE Connection identified by socket s has been closed Return Value The return value is 0 if the application's declaration of interest in the network event set was successful. Otherwise the value SOCKET_ERROR is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Comments Although WSAAsyncSelect() can be called with interest in multiple events, the application window will receive a single message for each network event. As in the case of the select() function, WSAAsyncSelect() will frequently be used to determine when a data transfer operation (send() or recv()) can be issued with the expectation of immediate success. Nevertheless, a robust application must be prepared for the possibility that it may receive a message and issue a Windows Sockets API call which returns WSAEWOULDBLOCK immediately. For example, the following sequence of events is possible: (i) data arrives on socket s; Windows Sockets posts WSAAsyncSelect message (ii) application processes some other message (iii) while processing, application issues an ioctlsocket(s, FIONREAD...) and notices that there is data ready to be read (iv) application issues a recv(s,...) to read the data (v) application loops to process next message, eventually reaching the WSAAsyncSelect message indicating that data is ready to read (vi) application issues recv(s,...), which fails with the error WSAEWOULDBLOCK. Other sequences are possible. The Windows Sockets DLL will not continually flood an application with messages for a particular network event. 106 WSAAsyncSelect Having successfully posted notification of a particular event to an application window, no further message(s) for that network event will be posted to the application window until the application makes the function call which implicitly reenables notification of that network event. Event Re-enabling function FD_READ recv() or recvfrom() FD_WRITE send() or sendto() FD_OOB recv() FD_ACCEPT accept() FD_CONNECT NONE FD_CLOSE NONE Any call to the reenabling routine, even one which fails, results in reenabling of message posting for the relevant event. For FD_READ, FD_OOB, and FD_ACCEPT events, message posting is "level-triggered." This means that if the reenabling routine is called and the relevant event is still valid after the call, a WSAAsyncSelect() message is posted to the application. This allows an application to be event-driven and not concern itself with the amount of data that arrives at any one time. Consider the following sequence: (i) Windows Sockets DLL receives 100 bytes of data on socket s and posts an FD_READ message. (ii) The application issues recv( s, buffptr, 50, 0) to read 50 bytes. (iii) The Windows Sockets DLL posts another FD_READ message since there is still data to be read. With these semantics, an application need not read all available data in response to an FD_READ message--a single recv() in response to each FD_READ message is appropriate. If an application issues multiple recv() calls in response to a single FD_READ, it may receive multiple FD_READ messages. Such an application may wish to disable FD_READ messages before starting the recv() calls by calling WSAAsyncSelect() with the FD_READ event not set. If an event is true when the application initially calls WSAAsyncSelect() or when the reenabling function is called, then a message is posted as appropriate. For example, if an application calls listen(), a connect attempt is made, then the application calls WSAAsyncSelect() specifying that it wants to receive FD_ACCEPT messages for the socket, the Windows Sockets implementation posts an FD_ACCEPT message immediately. The FD_WRITE event is handled slightly differently. An FD_WRITE message is posted when a socket is first connected with connect() or accepted with accept(), and then after a send() or sendto() fails with WSAEWOULDBLOCK and buffer space becomes available. Therefore, an application can assume that sends are possible starting from the first WSAAsyncSelect 107 FD_WRITE message and lasting until a send returns WSAEWOULDBLOCK. After such a failure the application will be notified that sends are again possible with an FD_WRITE message. The FD_OOB event is used only when a socket is configured to receive out-of-band data separately. If the socket is configured to receive out-of-band data in-line, the out-of- band (expedited) data is treated as normal data and the application should register an interest in, and will receive, FD_READ events, not FD_OOB events. An application may set or inspect the way in which out-of-band data is to be handled by using setsockopt() or getsockopt() for the SO_OOBINLINE option. The error code in an FD_CLOSE message indicates whether the socket close was graceful or abortive. If the error code is 0, then the close was graceful; if the error code is WSAECONNRESET, then the socket's virtual socket was reset. This only applies to sockets of type SOCK_STREAM. The FD_CLOSE message is posted when a close indication is received for the virtual circuit corresponding to the socket. In TCP terms, this means that the FD_CLOSE is posted when the connection goes into the FIN WAIT or CLOSE WAIT states. This results from the remote end performing a shutdown() on the send side or a closesocket(). Please note your application will receive ONLY an FD_CLOSE message to indicate closure of a virtual circuit. It will NOT receive an FD_READ message to indicate this condition. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL Indicates that one of the specified parameters was invalid WSAEINPROGRESS A blocking Windows Sockets operation is in progress. Additional error codes may be set when an application window receives a message. This error code is extracted from the lParam in the reply message using the WSAGETSELECTERROR macro. Possible error codes for each network event are: Event: FD_CONNECT Error Code Meaning WSAEADDRINUSE The specified address is already in use. WSAEADDRNOTAVAIL The specified address is not available from the local machine. 108 WSAAsyncSelect WSAEAFNOSUPPORT Addresses in the specified family cannot be used with this socket. WSAECONNREFUSED The attempt to connect was forcefully rejected. WSAEDESTADDRREQ A destination address is required. WSAEFAULT The namelen argument is incorrect. WSAEINVAL The socket is already bound to an address. WSAEISCONN The socket is already connected. WSAEMFILE No more file descriptors are available. WSAENETUNREACH The network can't be reached from this host at this time. WSAENOBUFS No buffer space is available. The socket cannot be connected. WSAENOTCONN The socket is not connected. WSAENOTSOCK The descriptor is a file, not a socket. WSAETIMEDOUT Attempt to connect timed out without establishing a connection Event: FD_CLOSE Error Code Meaning WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAECONNRESET The connection was reset by the remote side. WSAECONNABORTED The connection was aborted due to timeout or other failure. Event: FD_READ Event: FD_WRITE Event: FD_OOB Event: FD_ACCEPT Error Code Meaning WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. Notes For Windows Sockets Suppliers It is the responsibility of the Windows Sockets Supplier to ensure that messages are successfully posted to the application. If a PostMessage() operation fails, the WSAAsyncSelect 109 Windows Sockets implementation MUST re-post that message as long as the window exists. Windows Sockets suppliers should use the WSAMAKESELECTREPLY macro when constructing the lParam in the message. When a socket is closed, the Windows Sockets Supplier should purge any messages remaining for posting to the application window. However the application must be prepared to receive, and discard, any messages which may have been posted prior to the closesocket(). See Also select() 110 WSACancelAsyncRequest 4.3.8 WSACancelAsyncRequest() Description Cancel an incomplete asynchronous operation. #include int PASCAL FAR WSACancelAsyncRequest ( HANDLE hAsyncTaskHandle ); hAsyncTaskHandle Specifies the asynchronous operation to be canceled. Remarks The WSACancelAsyncRequest() function is used to cancel an asynchronous operation which was initiated by one of the WSAAsyncGetXByY() functions such as WSAAsyncGetHostByName(). The operation to be canceled is identified by the hAsyncTaskHandle parameter, which should be set to the asynchronous task handle as returned by the initiating function. Return Value The value returned by WSACancelAsyncRequest() is 0 if the operation was successfully canceled. Otherwise the value SOCKET_ERROR is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Comments An attempt to cancel an existing asynchronous WSAAsyncGetXByY() operation can fail with an error code of WSAEALREADY for two reasons. First, the original operation has already completed and the application has dealt with the resultant message. Second, the original operation has already completed but the resultant message is still waiting in the application window queue. Notes For Windows Sockets Suppliers It is unclear whether the application can usefully distinguish between WSAEINVAL and WSAEALREADY, since in both cases the error indicates that there is no asynchronous operation in progress with the indicated handle. [Trivial exception: 0 is always an invalid asynchronous task handle.] The Windows Sockets specification does not prescribe how a conformant Windows Sockets implementation should distinguish between the two cases. For maximum portability, a Windows Sockets application should treat the two errors as equivalent. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL Indicates that the specified asynchronous task handle was invalid WSACancelAsyncRequest 111 WSAEINPROGRESS A blocking Windows Sockets operation is in progress. WSAEALREADY The asynchronous routine being canceled has already completed. See Also WSAAsyncGetHostByAddr(), WSAAsyncGetHostByName(), WSAAsyncGetProtoByNumber(), WSAAsyncGetProtoByName(), WSAAsyncGetHostByName(), WSAAsyncGetServByPort(), WSAAsyncGetServByName(). 112 WSACancelBlockingCall 4.3.9 WSACancelBlockingCall() Description Cancel a blocking call which is currently in progress. #include int PASCAL FAR WSACancelBlockingCall ( void ); Remarks This function cancels any outstanding blocking operation for this task. It is normally used in two situations: (1) An application is processing a message which has been received while a blocking call is in progress. In this case, WSAIsBlocking() will be true. (2) A blocking call is in progress, and Windows Sockets has called back to the application's "blocking hook" function (as established by WSASetBlockingHook()). In each case, the original blocking call will terminate as soon as possible with the error WSAEINTR. (In (1), the termination will not take place until Windows message scheduling has caused control to revert to the blocking routine in Windows Sockets. In (2), the blocking call will be terminated as soon as the blocking hook function completes.) In the case of a blocking connect() operation, the Windows Sockets implementation will terminate the blocking call as soon as possible, but it may not be possible for the socket resources to be released until the connection has completed (and then been reset) or timed out. This is likely to be noticeable only if the application immediately tries to open a new socket (if no sockets are available), or to connect() to the same peer. Cancelling an accept() or a select() call does not adversely impact the sockets passed to these calls. Only the particular call fails; any operation that was legal before the cancel is legal after the cancel, and the state of the socket is not affected in any way. Cancelling any operation other than accept() and select() can leave the socket in an indeterminate state. If an application cancels a blocking operation on a socket, the only operation that the application can depend on being able to perform on the socket is a call to closesocket(), although other operations may work on some Windows Sockets implementations. If an application desires maximum portability, it must be careful not to depend on performing operations after a cancel. An application may reset the connection by setting the timeout on SO_LINGER to 0. If a cancel operation compromised the integrity of a SOCK_STREAM's data stream in any way, the Windows Sockets implementation must reset the connection and fail all future operations other than closesocket() with WSAECONNABORTED. WSACancelBlockingCall 113 Return Value The value returned by WSACancelBlockingCall() is 0 if the operation was successfully canceled. Otherwise the value SOCKET_ERROR is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Comments Note that it is possible that the network operation completes before the WSACancelBlockingCall() is processed, for example if data is received into the user buffer at interrupt time while the application is in a blocking hook. In this case, the blocking operation will return successfully as if WSACancelBlockingCall() had never been called. Note that the WSACancelBlockingCall() still succeeds in this case; the only way to know with certainty that an operation was actually canceled is to check for a return code of WSAEINTR from the blocking call. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINVAL Indicates that there is no outstanding blocking call. 114 WSACleanup 4.3.10 WSACleanup() Description Terminate use of the Windows Sockets DLL. #include int PASCAL FAR WSACleanup ( void ); Remarks An application or DLL is required to perform a (successful) WSAStartup() call before it can use Windows Sockets services. When it has completed the use of Windows Sockets, the application or DLL must call WSACleanup() to deregister itself from a Windows Sockets implementation and allow the implementation to free any resources allocated on behalf of the application or DLL. Any open SOCK_STREAM sockets that are connected when WSACleanup() is called are reset; sockets which have been closed with closesocket() but which still have pending data to be sent are not affected--the pending data is still sent. There must be a call to WSACleanup() for every call to WSAStartup() made by a task. Only the final WSACleanup() for that task does the actual cleanup; the preceding calls simply decrement an internal reference count in the Windows Sockets DLL. A naive application may ensure that WSACleanup() was called enough times by calling WSACleanup() in a loop until it returns WSANOTINITIALISED. Return Value The return value is 0 if the operation was successful. Otherwise the value SOCKET_ERROR is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Comments Attempting to call WSACleanup() from within a blocking hook and then failing to check the return code is a common Windows Sockets programming error. If an application needs to quit while a blocking call is outstanding, the application must first cancel the blocking call with WSACancelBlockingCall() then issue the WSACleanup() call once control has been returned to the application. Notes For Windows Sockets Suppliers Well-behaved Windows Sockets applications will make a WSACleanup() call to indicate deregistration from a Windows Sockets implementation. This function can thus, for example, be utilized to free up resources allocated to the specific application. A Windows Sockets implementation must be prepared to deal with an application which terminates without invoking WSACleanup() - for example, as a result of an error. In a multithreaded environment, WSACleanup() terminates Windows Sockets operations for all threads. A Windows Sockets implementation must ensure that WSACleanup() leaves things in a state in which the WSACleanup 115 application can invoke WSAStartup() to re-establish Windows Sockets usage. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. See Also WSAStartup() 116 WSAGetLastError 4.3.11 WSAGetLastError() Description Get the error status for the last operation which failed. #include int PASCAL FAR WSAGetLastError ( void ); Remarks This function returns the last network error that occurred. When a particular Windows Sockets API function indicates that an error has occurred, this function should be called to retrieve the appropriate error code. Return Value The return value indicates the error code for the last Windows Sockets API routine performed by this thread. Notes For Windows Sockets Suppliers The use of the WSAGetLastError() function to retrieve the last error code, rather than relying on a global error variable (cf. errno), is required in order to provide compatibility with future multi-threaded environments. Note that in a nonpreemptive Windows environment WSAGetLastError() is used to retrieve only Windows Sockets API errors. In a preemptive environment, WSAGetLastError() will invoke GetLastError(), which is used to retrieve the error status for all Win32 API functions on a per-thread basis. For portability, an application should use WSAGetLastError() immediately after the Windows Sockets API function which failed. See Also WSASetLastError() WSAIsBlocking 117 4.3.12 WSAIsBlocking() Description Determine if a blocking call is in progress. #include BOOL PASCAL FAR WSAIsBlocking ( void ); Remarks This function allows a task to determine if it is executing while waiting for a previous blocking call to complete. Return Value The return value is TRUE if there is an outstanding blocking function awaiting completion. Otherwise, it is FALSE. Comments Although a call issued on a blocking socket appears to an application program as though it "blocks", the Windows Sockets DLL has to relinquish the processor to allow other applications to run. This means that it is possible for the application which issued the blocking call to be re-entered, depending on the message(s) it receives. In this instance, the WSAIsBlocking() function can be used to ascertain whether the task has been re-entered while waiting for an outstanding blocking call to complete. Note that Windows Sockets prohibits more than one outstanding call per thread. Notes For Windows Sockets Suppliers A Windows Sockets implementation must prohibit more than one outstanding blocking call per thread. 118 WSASetBlockingHook 4.3.13 WSASetBlockingHook() Description Establish an application-specific blocking hook function. #include FARPROC PASCAL FAR WSASetBlockingHook ( FARPROC lpBlockFunc ); lpBlockFunc A pointer to the procedure instance address of the blocking function to be installed. Remarks This function installs a new function which a Windows Sockets implementation should use to implement blocking socket function calls. A Windows Sockets implementation includes a default mechanism by which blocking socket functions are implemented. The function WSASetBlockingHook() gives the application the ability to execute its own function at "blocking" time in place of the default function. When an application invokes a blocking Windows Sockets API operation, the Windows Sockets implementation initiates the operation and then enters a loop which is similar to the following pseudocode: for(;;) { /* flush messages for good user response */ while(BlockingHook()) ; /* check for WSACancelBlockingCall() */ if(operation_cancelled()) break; /* check to see if operation completed */ if(operation_complete()) break; /* normal completion */ } Note that Windows Sockets implementations may perform the above steps in a different order; for example, the check for operation complete may occur before calling the blocking hook. The default BlockingHook() function is equivalent to: BOOL DefaultBlockingHook(void) { MSG msg; BOOL ret; /* get the next message if any */ ret = (BOOL)PeekMessage(&msg,NULL,0,0,PM_REMOVE); /* if we got one, process it */ if (ret) { TranslateMessage(&msg); DispatchMessage(&msg); } /* TRUE if we got a message */ return ret; WSASetBlockingHook 119 } The WSASetBlockingHook() function is provided to support those applications which require more complex message processing - for example, those employing the MDI (multiple document interface) model. It is not intended as a mechanism for performing general applications functions. In particular, the only Windows Sockets API function which may be issued from a custom blocking hook function is WSACancelBlockingCall(), which will cause the blocking loop to terminate. This function must be implemented on a per-task basis for non-multithreaded versions of Windows and on a per-thread basis for multithreaded versions of Windows such as Windows NT. It thus provides for a particular task or thread to replace the blocking mechanism without affecting other tasks or threads. In multithreaded versions of Windows, there is no default blocking hook--blocking calls block the thread that makes the call. However, an application may install a specific blocking hook by calling WSASetBlockingHook(). This allows easy portability of applications that depend on the blocking hook behavior. Return Value The return value is a pointer to the procedure-instance of the previously installed blocking function. The application or library that calls the WSASetBlockingHook () function should save this return value so that it can be restored if necessary. (If "nesting" is not important, the application may simply discard the value returned by WSASetBlockingHook() and eventually use WSAUnhookBlockingHook() to restore the default mechanism.) If the operation fails, a NULL pointer is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. WSAENETDOWN The Windows Sockets implementation has detected that the network subsystem has failed. WSAEINPROGRESS A blocking Windows Sockets operation is in progress. See Also WSAUnhookBlockingHook() 120 WSASetLastError 4.3.14 WSASetLastError() Description Set the error code which can be retrieved by WSAGetLastError(). #include void PASCAL FAR WSASetLastError ( int iError ); Remarks This function allows an application to set the error code to be returned by a subsequent WSAGetLastError() call for the current thread. Note that any subsequent Windows Sockets routine called by the application will override the error code as set by this routine. iError Specifies the error code to be returned by a subsequent WSAGetLastError() call. Notes For Windows Sockets Suppliers In a Win32 environment, this function will invoke SetLastError(). Return Value None. Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. See Also WSAGetLastError() WSAStartup 121 4.3.15 WSAStartup() Description #include int PASCAL FAR WSAStartup ( WORD wVersionRequested, LPWSADATA lpWSAData ); wVersionRequested The highest version of Windows Sockets API support that the caller can use. The high order byte specifies the minor version (revision) number; the low-order byte specifies the major version number. lpWSAData A pointer to the WSADATA data structure that is to receive details of the Windows Sockets implementation. Remarks This function MUST be the first Windows Sockets function called by an application or DLL. It allows an application or DLL to specify the version of Windows Sockets API required and to retrieve details of the specific Windows Sockets implementation. The application or DLL may only issue further Windows Sockets API functions after a successful WSAStartup() invocation. In order to support future Windows Sockets implementations and applications which may have functionality differences from Windows Sockets 1.1, a negotiation takes place in WSAStartup(). The caller of WSAStartup() and the Windows Sockets DLL indicate to each other the highest version that they can support, and each confirms that the other's highest version is acceptable. Upon entry to WSAStartup(), the Windows Sockets DLL examines the version requested by the application. If this version is higher than the lowest version supported by the DLL, the call succeeds and the DLL returns in wHighVersion the highest version it supports and in wVersion the minimum of its high version and wVersionRequested. The Windows Sockets DLL then assumes that the application will use wVersion. If the wVersion field of the WSADATA structure is unacceptable to the caller, it should call WSACleanup() and either search for another Windows Sockets DLL or fail to initialize. This negotiation allows both a Windows Sockets DLL and a Windows Sockets application to support a range of Windows Sockets versions. An application can successfully utilize a Windows Sockets DLL if there is any overlap in the version ranges. The following chart gives examples of how WSAStartup() works in conjunction with different application and Windows Sockets DLL versions: 122 WSAStartup App versions DLL Versions wVersionRequested wVersion wHighVersion End Result 1.1 1.1 1.1 1.1 1.1 use 1.1 1.0 1.1 1.0 1.1 1.0 1.0 use 1.0 1.0 1.0 1.1 1.0 1.0 1.1 use 1.0 1.1 1.0 1.1 1.1 1.1 1.1 use 1.1 1.1 1.0 1.1 1.0 1.0 Application fails 1.0 1.1 1.0 --- --- WSAVERNOTSUPPORTED 1.0 1.1 1.0 1.1 1.1 1.1 1.1 use 1.1 1.1 2.0 1.1 2.0 1.1 1.1 use 1.1 2.0 1.1 2.0 1.1 1.1 Application fails The following code fragment demonstrates how an application which supports only version 1.1 of Windows Sockets makes a WSAStartup() call: WORD wVersionRequested; WSADATA wsaData; int err; wVersionRequested = MAKEWORD( 1, 1 ); err = WSAStartup( wVersionRequested, &wsaData ); if ( err != 0 ) { /* Tell the user that we couldn't find a useable */ /* winsock.dll. */ return; } /* Confirm that the Windows Sockets DLL supports 1.1.*/ /* Note that if the DLL supports versions greater */ WSAStartup 123 /* than 1.1 in addition to 1.1, it will still return */ /* 1.1 in wVersion since that is the version we */ /* requested. */ if ( LOBYTE( wsaData.wVersion ) != 1 || HIBYTE( wsaData.wVersion ) != 1 ) { /* Tell the user that we couldn't find a useable */ /* winsock.dll. */ WSACleanup( ); return; } /* The Windows Sockets DLL is acceptable. Proceed. */ And this code fragment demonstrates how a Windows Sockets DLL which supports only version 1.1 performs the WSAStartup() negotiation: /* Make sure that the version requested is >= 1.1. */ /* The low byte is the major version and the high */ /* byte is the minor version. */ if ( LOBYTE( wVersionRequested ) < 1 || ( LOBYTE( wVersionRequested ) == 1 && HIBYTE( wVersionRequested ) < 1 ) { return WSAVERNOTSUPPORTED; } /* Since we only support 1.1, set both wVersion and */ /* wHighVersion to 1.1. */ lpWsaData->wVersion = MAKEWORD( 1, 1 ); lpWsaData->wHighVersion = MAKEWORD( 1, 1 ); Once an application or DLL has made a successful WSAStartup() call, it may proceed to make other Windows Sockets API calls as needed. When it has finished using the services of the Windows Sockets DLL, the application or DLL must call WSACleanup() in order to allow the Windows Sockets DLL to free any resources for the application. Details of the actual Windows Sockets implementation are described in the WSAData structure defined as follows: struct WSAData { WORD wVersion; WORD wHighVersion; char szDescription[WSADESCRIPTION_LEN+1]; char szSystemStatus[WSASYSSTATUS_LEN+1]; unsigned short iMaxSockets; unsigned short iMaxUdpDg; char FAR * lpVendorInfo; }; The members of this structure are: Element Usage 124 WSAStartup wVersion The version of the Windows Sockets specification that the Windows Sockets DLL expects the caller to use. wHighVersion The highest version of the Windows Sockets specification that this DLL can support (also encoded as above). Normally this will be the same as wVersion. szDescription A null-terminated ASCII string into which the Windows Sockets DLL copies a description of the Windows Sockets implementation, including vendor identification. The text (up to 256 characters in length) may contain any characters, but vendors are cautioned against including control and formatting characters: the most likely use that an application will put this to is to display it (possibly truncated) in a status message. szSystemStatus A null-terminated ASCII string into which the Windows Sockets DLL copies relevant status or configuration information. The Windows Sockets DLL should use this field only if the information might be useful to the user or support staff: it should not be considered as an extension of the szDescription field. iMaxSockets The maximum number of sockets which a single process can potentially open. A Windows Sockets implementation may provide a global pool of sockets for allocation to any process; alternatively it may allocate per-process resources for sockets. The number may well reflect the way in which the Windows Sockets DLL or the networking software was configured. Application writers may use this number as a crude indication of whether the Windows Sockets implementation is usable by the application. For example, an X Windows server might check iMaxSockets when first started: if it is less than 8, the application would display an error message instructing the user to reconfigure the networking software. (This is a situation in which the szSystemStatus text might be used.) Obviously there is no guarantee that a particular application can actually allocate iMaxSockets sockets, since there may be other Windows Sockets applications in use. iMaxUdpDg The size in bytes of the largest UDP datagram that can be sent or received by a Windows Sockets application. If the implementation imposes no limit, iMaxUdpDg is zero. In many implementations of Berkeley sockets, there is an implicit limit of 8192 bytes on UDP datagrams (which are fragmented if necessary). A Windows Sockets implementation may impose a limit based, for instance, on the allocation of fragment reassembly buffers. The minimum value of iMaxUdpDg for a compliant Windows Sockets implementation is 512. Note that regardless of the value of iMaxUdpDg, it is inadvisable to attempt to send a broadcast WSAStartup 125 datagram which is larger than the Maximum Transmission Unit (MTU) for the network. (The Windows Sockets API does not provide a mechanism to discover the MTU, but it must be no less than 512 bytes.) lpVendorInfo A far pointer to a vendor-specific data structure. The definition of this structure (if supplied) is beyond the scope of this specification. An application or DLL may call WSAStartup() more than once if it needs to obtain the WSAData structure information more than once. However, the wVersionRequired parameter is assumed to be the same on all calls to WSAStartup(); that is, an application or DLL cannot change the version of Windows Sockets it expects after the initial call to WSAStartup(). There must be one WSACleanup() call corresponding to every WSAStartup() call to allow third-party DLLs to make use of a Windows Sockets DLL on behalf of an application. This means, for example, that if an application calls WSAStartup() three times, it must call WSACleanup() three times. The first two calls to WSACleanup() do nothing except decrement an internal counter; the final WSACleanup() call for the task does all necessary resource deallocation for the task. Return Value WSAStartup() returns zero if successful. Otherwise it returns one of the error codes listed below. Note that the normal mechanism whereby the application calls WSAGetLastError() to determine the error code cannot be used, since the Windows Sockets DLL may not have established the client data area where the "last error" information is stored. Notes For Windows Sockets Suppliers Each Windows Sockets application MUST make a WSAStartup() call before issuing any other Windows Sockets API calls. This function can thus be utilized for initialization purposes. Further issues are discussed in the notes for WSACleanup(). Error Codes WSASYSNOTREADY Indicates that the underlying network subsystem is not ready for network communication. WSAVERNOTSUPPORTED The version of Windows Sockets API support requested is not provided by this particular Windows Sockets implementation. 126 WSAStartup WSAEINVAL The Windows Sockets version specified by the application is not supported by this DLL. See Also send(), sendto(), WSACleanup() WSAUnhookBlockingHook 127 4.3.16 WSAUnhookBlockingHook() Description Restore the default blocking hook function. #include int PASCAL FAR WSAUnhookBlockingHook ( void ); Remarks This function removes any previous blocking hook that has been installed and reinstalls the default blocking mechanism. WSAUnhookBlockingHook() will always install the default mechanism, not the previous mechanism. If an application wish to nest blocking hooks - i.e. to establish a temporary blocking hook function and then revert to the previous mechanism (whether the default or one established by an earlier WSASetBlockingHook()) - it must save and restore the value returned by WSASetBlockingHook(); it cannot use WSAUnhookBlockingHook(). In multithreaded versions of Windows such as Windows NT, there is no default blocking hook. Calling WSAUnhookBlockingHook() disables any blocking hook installed by the application and any blocking calls made block the thread which made the call. Return Value The return value is 0 if the operation was successful. Otherwise the value SOCKET_ERROR is returned, and a specific error number may be retrieved by calling WSAGetLastError(). Error Codes WSANOTINITIALISED A successful WSAStartup() must occur before using this API. See Also WSASetBlockingHook() 128 Appendix A1: Error Codes Appendix A. Error Codes and Header Files A.1 Error Codes The following is a list of possible error codes returned by the WSAGetLastError() call, along with their explanations. The error numbers are consistently set across all Windows Sockets-compliant implementations. Appendix A1: Error Codes 129 Windows Berkeley Err Interpretation Sockets code equivalent or WSAEINTR EINTR As in standard C 100 04 WSAEBADF EBADF As in standard C 100 09 WSAEACCES EACCES As in standard C 100 13 WSAEFAULT EFAULT As in standard C 100 14 WSAEINVAL EINVAL As in standard C 100 22 WSAEMFILE EMFILE As in standard C 100 24 WSAEWOULDBLOC EWOULDBLOCK As in BSD 100 K 35 WSAEINPROGRES EINPROGRESS This error is returned 100 S if any 36 Windows Sockets API function is called while a blocking function is in progress. WSAEALREADY EALREADY As in BSD 100 37 WSAENOTSOCK ENOTSOCK As in BSD 100 38 WSAEDESTADDRR EDESTADDRREQ 100 As in BSD EQ 39 WSAEMSGSIZE EMSGSIZE As in BSD 100 40 WSAEPROTOTYPE EPROTOTYPE As in BSD 100 41 WSAENOPROTOOP ENOPROTOOPT As in BSD 100 T 42 WSAEPROTONOSU EPROTONOSUPPO 100 As in BSD PPORT RT 43 WSAESOCKTNOSU ESOCKTNOSUPPO As in BSD 100 PPORT RT 44 WSAEOPNOTSUPP EOPNOTSUPP As in BSD 100 45 WSAEPFNOSUPPO EPFNOSUPPORT 100 As in BSD RT 46 WSAEAFNOSUPPO EAFNOSUPPORT 100 As in BSD RT 47 WSAEADDRINUSE EADDRINUSE 100 As in BSD 48 WSAEADDRNOTAV EADDRNOTAVAIL As in BSD 100 AIL 49 130 Appendix A1: Error Codes WSAENETDOWN ENETDOWN As in BSD. This error 100 50 may be reported at any time if the Windows Sockets implementation detects an underlying failure. WSAENETUNREAC ENETUNREACH As in BSD 100 H 51 WSAENETRESET ENETRESET As in BSD 100 52 WSAECONNABORT ECONNABORTED As in BSD 100 ED 53 WSAECONNRESET ECONNRESET As in BSD 100 54 WSAENOBUFS ENOBUFS As in BSD 100 55 WSAEISCONN EISCONN As in BSD 100 56 WSAENOTCONN ENOTCONN As in BSD 100 57 WSAESHUTDOWN ESHUTDOWN As in BSD 100 58 WSAETOOMANYRE ETOOMANYREFS As in BSD 100 FS 59 WSAETIMEDOUT ETIMEDOUT 100 As in BSD 60 WSAECONNREFUS ECONNREFUSED As in BSD 100 ED 61 WSAELOOP ELOOP As in BSD 100 62 WSAENAMETOOLO ENAMETOOLONG As in BSD 100 NG 63 WSAEHOSTDOWN EHOSTDOWN As in BSD 100 64 WSAEHOSTUNREA EHOSTUNREACH As in BSD 100 CH 65 WSASYSNOTREAD Returned by 100 Y 91 WSAStartup() indicating that the network subsystem is unusable. WSAVERNOTSUPP Returned by 100 ORTED 92 WSAStartup() indicating that the Windows Sockets DLL cannot support this app. WSANOTINITIAL Returned by any 100 ISED function except 93 WSAStartup() indicating that a successful WSAStartup() has not yet been performed. WSAHOST_NOT_F HOST_NOT_FOUN As in BSD. 110 OUND D 01 Appendix A1: Error Codes 131 WSATRY_AGAIN TRY_AGAIN As in BSD 110 02 WSANO_RECOVER NO_RECOVERY As in BSD 110 Y 03 WSANO_DATA NO_DATA As in BSD 110 04 The first set of definitions is present to resolve contentions between standard C error codes which may be defined inconsistently between various C compilers. The second set of definitions provides Windows Sockets versions of regular Berkeley Sockets error codes. The third set of definitions consists of extended Windows Sockets- specific error codes. The fourth set of errors are returned by Windows Sockets getXbyY() and WSAAsyncGetXByY() functions, and correspond to the errors which in Berkeley software would be returned in the h_errno variable. They correspond to various failures which may be returned by the Domain Name Service. If the Windows Sockets implementation does not use the DNS, it will use the most appropriate code. In general, a Windows Sockets application should interpret WSAHOST_NOT_FOUND and WSANO_DATA as indicating that the key (name, address, etc.) was not found,, while WSATRY_AGAIN and WSANO_RECOVERY suggest that the name service itself is non-operational. The error numbers are derived from the winsock.h header file listed in section A.2.2, and are based on the fact that Windows Sockets error numbers are computed by adding 10000 to the "normal" Berkeley error number. Note that this table does not include all of the error codes defined in winsock.h. This is because it includes only errors which might reasonably be returned by a Windows Sockets implementation: winsock.h, on the other hand, includes a full set of BSD definitions to ensure compatibility with ported software. 132 Appendix A2: Header Files A.2 Header Files A.2.1 Berkeley Header Files A Windows Sockets supplier who provides a development kit to support the development of Windows Sockets applications must supply a set of vestigial header files with names that match a number of the header files in the Berkeley software distribution. These files are provided for source code compatibility only, and each consists of three lines: #ifndef _WINSOCKAPI_ #include #endif The header files provided for compatibility are: netdb.h arpa/inet.h sys/time.h sys/socket.h netinet/in.h The file winsock.h contains all of the type and structure definitions, constants, macros, and function prototypes used by the Windows Sockets specification. An application writer may choose to ignore the compatibility headers and include winsock.h in each source file. winsock.h 133 A.2.2 Windows Sockets Header File - winsock.h The winsock.h header file includes a number of types and definitions from the standard Windows header file windows.h. The windows.h in the Windows 3.0 SDK (Software Developer's Kit) lacks a #include guard, so if you need to include windows.h as well as winsock.h, you should define the symbol _INC_WINDOWS before #including winsock.h, as follows: #include #define _INC_WINDOWS #include Users of the SDK for Windows 3.1 and later need not do this. A Windows Sockets DLL vendor MUST NOT make any modifications to this header file which could impact binary compatibility of Windows Sockets applications. The constant values, function parameters and return codes, and the like must remain consistent across all Windows Sockets DLL vendors. /* WINSOCK.H--definitions to be used with the WINSOCK.DLL * * This header file corresponds to version 1.1 of the Windows Sockets specification. * * This file includes parts which are Copyright (c) 1982-1986 Regents * of the University of California. All rights reserved. The * Berkeley Software License Agreement specifies the terms and * conditions for redistribution. */ #ifndef _WINSOCKAPI_ #define _WINSOCKAPI_ /* * Pull in WINDOWS.H if necessary */ #ifndef _INC_WINDOWS #include #endif /* _INC_WINDOWS */ /* * Basic system type definitions, taken from the BSD file sys/types.h. */ typedef unsigned char u_char; typedef unsigned short u_short; typedef unsigned int u_int; typedef unsigned long u_long; /* * The new type to be used in all * instances which refer to sockets. */ typedef u_int SOCKET; /* * Select uses arrays of SOCKETs. These macros manipulate such * arrays. FD_SETSIZE may be defined by the user before including * this file, but the default here should be >= 64. * * CAVEAT IMPLEMENTOR and USER: THESE MACROS AND TYPES MUST BE * INCLUDED IN WINSOCK.H EXACTLY AS SHOWN HERE. */ #ifndef FD_SETSIZE #define FD_SETSIZE 64 #endif /* FD_SETSIZE */ typedef struct fd_set { u_short fd_count; /* how many are SET? */ SOCKET fd_array[FD_SETSIZE]; /* an array of SOCKETs */ } fd_set; extern int PASCAL FAR __WSAFDIsSet(SOCKET, fd_set FAR *); #define FD_CLR(fd, set) do { \ u_int __i; \ for (__i = 0; __i < ((fd_set FAR *)(set))->fd_count ; __i++) { \ if (((fd_set FAR *)(set))->fd_array[__i] == fd) { \ while (__i < ((fd_set FAR *)(set))->fd_count-1) { \ ((fd_set FAR *)(set))->fd_array[__i] = \ ((fd_set FAR *)(set))->fd_array[__i+1]; \ __i++; \ } \ ((fd_set FAR *)(set))->fd_count--; \ break; \ } \ } \ } while(0) #define FD_SET(fd, set) do { \ if (((fd_set FAR *)(set))->fd_count < FD_SETSIZE) \ ((fd_set FAR *)(set))->fd_array[((fd_set FAR *)(set))->fd_count++]=fd;\ } while(0) #define FD_ZERO(set) (((fd_set FAR *)(set))->fd_count=0) #define FD_ISSET(fd, set) __WSAFDIsSet((SOCKET)fd, (fd_set FAR *)set) /* * Structure used in select() call, taken from the BSD file sys/time.h. */ struct timeval { long tv_sec; /* seconds */ long tv_usec; /* and microseconds */ }; /* * Operations on timevals. * * NB: timercmp does not work for >= or <=. */ #define timerisset(tvp) ((tvp)->tv_sec || (tvp)->tv_usec) #define timercmp(tvp, uvp, cmp) \ ((tvp)->tv_sec cmp (uvp)->tv_sec || \ (tvp)->tv_sec == (uvp)->tv_sec && (tvp)->tv_usec cmp (uvp)->tv_usec) #define timerclear(tvp) (tvp)->tv_sec = (tvp)->tv_usec = 0 /* * Commands for ioctlsocket(), taken from the BSD file fcntl.h. * * * Ioctl's have the command encoded in the lower word, * and the size of any in or out parameters in the upper * word. The high 2 bits of the upper word are used * to encode the in/out status of the parameter; for now * we restrict parameters to at most 128 bytes. */ #define IOCPARM_MASK 0x7f /* parameters must be < 128 bytes */ #define IOC_VOID 0x20000000 /* no parameters */ #define IOC_OUT 0x40000000 /* copy out parameters */ #define IOC_IN 0x80000000 /* copy in parameters */ #define IOC_INOUT (IOC_IN|IOC_OUT) /* 0x20000000 distinguishes new & old ioctl's */ #define _IO(x,y) (IOC_VOID|(x<<8)|y) #define _IOR(x,y,t) (IOC_OUT|(((long)sizeof(t)&IOCPARM_MASK)<<16)|(x<<8)|y) #define _IOW(x,y,t) (IOC_IN|(((long)sizeof(t)&IOCPARM_MASK)<<16)|(x<<8)|y) #define FIONREAD _IOR('f', 127, u_long) /* get # bytes to read */ #define FIONBIO _IOW('f', 126, u_long) /* set/clear non-blocking i/o */ #define FIOASYNC _IOW('f', 125, u_long) /* set/clear async i/o */ /* Socket I/O Controls */ #define SIOCSHIWAT _IOW('s', 0, u_long) /* set high watermark */ #define SIOCGHIWAT _IOR('s', 1, u_long) /* get high watermark */ #define SIOCSLOWAT _IOW('s', 2, u_long) /* set low watermark */ #define SIOCGLOWAT _IOR('s', 3, u_long) /* get low watermark */ #define SIOCATMARK _IOR('s', 7, u_long) /* at oob mark? */ /* * Structures returned by network data base library, taken from the * BSD file netdb.h. All addresses are supplied in host order, and * returned in network order (suitable for use in system calls). */ struct hostent { char FAR * h_name; /* official name of host */ char FAR * FAR * h_aliases; /* alias list */ short h_addrtype; /* host address type */ short h_length; /* length of address */ char FAR * FAR * h_addr_list; /* list of addresses */ #define h_addr h_addr_list[0] /* address, for backward compat */ }; /* * It is assumed here that a network number * fits in 32 bits. */ struct netent { char FAR * n_name; /* official name of net */ char FAR * FAR * n_aliases; /* alias list */ short n_addrtype; /* net address type */ u_long n_net; /* network # */ }; struct servent { char FAR * s_name; /* official service name */ char FAR * FAR * s_aliases; /* alias list */ short s_port; /* port # */ char FAR * s_proto; /* protocol to use */ }; struct protoent { char FAR * p_name; /* official protocol name */ char FAR * FAR * p_aliases; /* alias list */ short p_proto; /* protocol # */ }; /* * Constants and structures defined by the internet system, * Per RFC 790, September 1981, taken from the BSD file netinet/in.h. */ /* * Protocols */ #define IPPROTO_IP 0 /* dummy for IP */ #define IPPROTO_ICMP 1 /* control message protocol */ #define IPPROTO_GGP 2 /* gateway^2 (deprecated) */ #define IPPROTO_TCP 6 /* tcp */ #define IPPROTO_PUP 12 /* pup */ #define IPPROTO_UDP 17 /* user datagram protocol */ #define IPPROTO_IDP 22 /* xns idp */ #define IPPROTO_ND 77 /* UNOFFICIAL net disk proto */ #define IPPROTO_RAW 255 /* raw IP packet */ #define IPPROTO_MAX 256 /* * Port/socket numbers: network standard functions */ #define IPPORT_ECHO 7 #define IPPORT_DISCARD 9 #define IPPORT_SYSTAT 11 #define IPPORT_DAYTIME 13 #define IPPORT_NETSTAT 15 #define IPPORT_FTP 21 #define IPPORT_TELNET 23 #define IPPORT_SMTP 25 #define IPPORT_TIMESERVER 37 #define IPPORT_NAMESERVER 42 #define IPPORT_WHOIS 43 #define IPPORT_MTP 57 /* * Port/socket numbers: host specific functions */ #define IPPORT_TFTP 69 #define IPPORT_RJE 77 #define IPPORT_FINGER 79 #define IPPORT_TTYLINK 87 #define IPPORT_SUPDUP 95 /* * UNIX TCP sockets */ #define IPPORT_EXECSERVER 512 #define IPPORT_LOGINSERVER 513 #define IPPORT_CMDSERVER 514 #define IPPORT_EFSSERVER 520 /* * UNIX UDP sockets */ #define IPPORT_BIFFUDP 512 #define IPPORT_WHOSERVER 513 #define IPPORT_ROUTESERVER 520 /* 520+1 also used */ /* * Ports < IPPORT_RESERVED are reserved for * privileged processes (e.g. root). */ #define IPPORT_RESERVED 1024 /* * Link numbers */ #define IMPLINK_IP 155 #define IMPLINK_LOWEXPER 156 #define IMPLINK_HIGHEXPER 158 /* * Internet address (old style... should be updated) */ struct in_addr { union { struct { u_char s_b1,s_b2,s_b3,s_b4; } S_un_b; struct { u_short s_w1,s_w2; } S_un_w; u_long S_addr; } S_un; #define s_addr S_un.S_addr /* can be used for most tcp & ip code */ #define s_host S_un.S_un_b.s_b2 /* host on imp */ #define s_net S_un.S_un_b.s_b1 /* network */ #define s_imp S_un.S_un_w.s_w2 /* imp */ #define s_impno S_un.S_un_b.s_b4 /* imp # */ #define s_lh S_un.S_un_b.s_b3 /* logical host */ }; /* * Definitions of bits in internet address integers. * On subnets, the decomposition of addresses to host and net parts * is done according to subnet mask, not the masks here. */ #define IN_CLASSA(i) (((long)(i) & 0x80000000) == 0) #define IN_CLASSA_NET 0xff000000 #define IN_CLASSA_NSHIFT 24 #define IN_CLASSA_HOST 0x00ffffff #define IN_CLASSA_MAX 128 #define IN_CLASSB(i) (((long)(i) & 0xc0000000) == 0x80000000) #define IN_CLASSB_NET 0xffff0000 #define IN_CLASSB_NSHIFT 16 #define IN_CLASSB_HOST 0x0000ffff #define IN_CLASSB_MAX 65536 #define IN_CLASSC(i) (((long)(i) & 0xc0000000) == 0xc0000000) #define IN_CLASSC_NET 0xffffff00 #define IN_CLASSC_NSHIFT 8 #define IN_CLASSC_HOST 0x000000ff #define INADDR_ANY (u_long)0x00000000 #define INADDR_LOOPBACK 0x7f000001 #define INADDR_BROADCAST (u_long)0xffffffff #define INADDR_NONE 0xffffffff /* * Socket address, internet style. */ struct sockaddr_in { short sin_family; u_short sin_port; struct in_addr sin_addr; char sin_zero[8]; }; #define WSADESCRIPTION_LEN 256 #define WSASYS_STATUS_LEN 128 typedef struct WSAData { WORD wVersion; WORD wHighVersion; char szDescription[WSADESCRIPTION_LEN+1]; char szSystemStatus[WSASYS_STATUS_LEN+1]; unsigned short iMaxSockets; unsigned short iMaxUdpDg; char FAR * lpVendorInfo; } WSADATA; typedef WSADATA FAR *LPWSADATA; /* * Options for use with [gs]etsockopt at the IP level. */ #define IP_OPTIONS 1 /* set/get IP per-packet options */ /* * Definitions related to sockets: types, address families, options, * taken from the BSD file sys/socket.h. */ /* * This is used instead of -1, since the * SOCKET type is unsigned. */ #define INVALID_SOCKET (SOCKET)(~0) #define SOCKET_ERROR (-1) /* * Types */ #define SOCK_STREAM 1 /* stream socket */ #define SOCK_DGRAM 2 /* datagram socket */ #define SOCK_RAW 3 /* raw-protocol interface */ #define SOCK_RDM 4 /* reliably-delivered message */ #define SOCK_SEQPACKET 5 /* sequenced packet stream */ /* * Option flags per-socket. */ #define SO_DEBUG 0x0001 /* turn on debugging info recording */ #define SO_ACCEPTCONN 0x0002 /* socket has had listen() */ #define SO_REUSEADDR 0x0004 /* allow local address reuse */ #define SO_KEEPALIVE 0x0008 /* keep connections alive */ #define SO_DONTROUTE 0x0010 /* just use interface addresses */ #define SO_BROADCAST 0x0020 /* permit sending of broadcast msgs */ #define SO_USELOOPBACK 0x0040 /* bypass hardware when possible */ #define SO_LINGER 0x0080 /* linger on close if data present */ #define SO_OOBINLINE 0x0100 /* leave received OOB data in line */ #define SO_DONTLINGER (u_int)(~SO_LINGER) /* * Additional options. */ #define SO_SNDBUF 0x1001 /* send buffer size */ #define SO_RCVBUF 0x1002 /* receive buffer size */ #define SO_SNDLOWAT 0x1003 /* send low-water mark */ #define SO_RCVLOWAT 0x1004 /* receive low-water mark */ #define SO_SNDTIMEO 0x1005 /* send timeout */ #define SO_RCVTIMEO 0x1006 /* receive timeout */ #define SO_ERROR 0x1007 /* get error status and clear */ #define SO_TYPE 0x1008 /* get socket type */ /* * TCP options. */ #define TCP_NODELAY 0x0001 /* * Address families. */ #define AF_UNSPEC 0 /* unspecified */ #define AF_UNIX 1 /* local to host (pipes, portals) */ #define AF_INET 2 /* internetwork: UDP, TCP, etc. */ #define AF_IMPLINK 3 /* arpanet imp addresses */ #define AF_PUP 4 /* pup protocols: e.g. BSP */ #define AF_CHAOS 5 /* mit CHAOS protocols */ #define AF_NS 6 /* XEROX NS protocols */ #define AF_ISO 7 /* ISO protocols */ #define AF_OSI AF_ISO /* OSI is ISO */ #define AF_ECMA 8 /* european computer manufacturers */ #define AF_DATAKIT 9 /* datakit protocols */ #define AF_CCITT 10 /* CCITT protocols, X.25 etc */ #define AF_SNA 11 /* IBM SNA */ #define AF_DECnet 12 /* DECnet */ #define AF_DLI 13 /* Direct data link interface */ #define AF_LAT 14 /* LAT */ #define AF_HYLINK 15 /* NSC Hyperchannel */ #define AF_APPLETALK 16 /* AppleTalk */ #define AF_NETBIOS 17 /* NetBios-style addresses */ #define AF_MAX 18 /* * Structure used by kernel to store most * addresses. */ struct sockaddr { u_short sa_family; /* address family */ char sa_data[14]; /* up to 14 bytes of direct address */ }; /* * Structure used by kernel to pass protocol * information in raw sockets. */ struct sockproto { u_short sp_family; /* address family */ u_short sp_protocol; /* protocol */ }; /* * Protocol families, same as address families for now. */ #define PF_UNSPEC AF_UNSPEC #define PF_UNIX AF_UNIX #define PF_INET AF_INET #define PF_IMPLINK AF_IMPLINK #define PF_PUP AF_PUP #define PF_CHAOS AF_CHAOS #define PF_NS AF_NS #define PF_ISO AF_ISO #define PF_OSI AF_OSI #define PF_ECMA AF_ECMA #define PF_DATAKIT AF_DATAKIT #define PF_CCITT AF_CCITT #define PF_SNA AF_SNA #define PF_DECnet AF_DECnet #define PF_DLI AF_DLI #define PF_LAT AF_LAT #define PF_HYLINK AF_HYLINK #define PF_APPLETALK AF_APPLETALK #define PF_MAX AF_MAX /* * Structure used for manipulating linger option. */ struct linger { u_short l_onoff; /* option on/off */ u_short l_linger; /* linger time */ }; /* * Level number for (get/set)sockopt() to apply to socket itself. */ #define SOL_SOCKET 0xffff /* options for socket level */ /* * Maximum queue length specifiable by listen. */ #define SOMAXCONN 5 #define MSG_OOB 0x1 /* process out-of-band data */ #define MSG_PEEK 0x2 /* peek at incoming message */ #define MSG_DONTROUTE 0x4 /* send without using routing tables */ #define MSG_MAXIOVLEN 16 /* * Define constant based on rfc883, used by gethostbyxxxx() calls. */ #define MAXGETHOSTSTRUCT 1024 /* * Define flags to be used with the WSAAsyncSelect() call. */ #define FD_READ 0x01 #define FD_WRITE 0x02 #define FD_OOB 0x04 #define FD_ACCEPT 0x08 #define FD_CONNECT 0x10 #define FD_CLOSE 0x20 /* * All Windows Sockets error constants are biased by WSABASEERR from * the "normal" */ #define WSABASEERR 10000 /* * Windows Sockets definitions of regular Microsoft C error constants */ #define WSAEINTR (WSABASEERR+4) #define WSAEBADF (WSABASEERR+9) #define WSAEACCES (WSABASEERR+13) #define WSAEFAULT (WSABASEERR+14) #define WSAEINVAL (WSABASEERR+22) #define WSAEMFILE (WSABASEERR+24) /* * Windows Sockets definitions of regular Berkeley error constants */ #define WSAEWOULDBLOCK (WSABASEERR+35) #define WSAEINPROGRESS (WSABASEERR+36) #define WSAEALREADY (WSABASEERR+37) #define WSAENOTSOCK (WSABASEERR+38) #define WSAEDESTADDRREQ (WSABASEERR+39) #define WSAEMSGSIZE (WSABASEERR+40) #define WSAEPROTOTYPE (WSABASEERR+41) #define WSAENOPROTOOPT (WSABASEERR+42) #define WSAEPROTONOSUPPORT (WSABASEERR+43) #define WSAESOCKTNOSUPPORT (WSABASEERR+44) #define WSAEOPNOTSUPP (WSABASEERR+45) #define WSAEPFNOSUPPORT (WSABASEERR+46) #define WSAEAFNOSUPPORT (WSABASEERR+47) #define WSAEADDRINUSE (WSABASEERR+48) #define WSAEADDRNOTAVAIL (WSABASEERR+49) #define WSAENETDOWN (WSABASEERR+50) #define WSAENETUNREACH (WSABASEERR+51) #define WSAENETRESET (WSABASEERR+52) #define WSAECONNABORTED (WSABASEERR+53) #define WSAECONNRESET (WSABASEERR+54) #define WSAENOBUFS (WSABASEERR+55) #define WSAEISCONN (WSABASEERR+56) #define WSAENOTCONN (WSABASEERR+57) #define WSAESHUTDOWN (WSABASEERR+58) #define WSAETOOMANYREFS (WSABASEERR+59) #define WSAETIMEDOUT (WSABASEERR+60) #define WSAECONNREFUSED (WSABASEERR+61) #define WSAELOOP (WSABASEERR+62) #define WSAENAMETOOLONG (WSABASEERR+63) #define WSAEHOSTDOWN (WSABASEERR+64) #define WSAEHOSTUNREACH (WSABASEERR+65) #define WSAENOTEMPTY (WSABASEERR+66) #define WSAEPROCLIM (WSABASEERR+67) #define WSAEUSERS (WSABASEERR+68) #define WSAEDQUOT (WSABASEERR+69) #define WSAESTALE (WSABASEERR+70) #define WSAEREMOTE (WSABASEERR+71) /* * Extended Windows Sockets error constant definitions */ #define WSASYSNOTREADY (WSABASEERR+91) #define WSAVERNOTSUPPORTED (WSABASEERR+92) #define WSANOTINITIALISED (WSABASEERR+93) /* * Error return codes from gethostbyname() and gethostbyaddr() * (when using the resolver). Note that these errors are * retrieved via WSAGetLastError() and must therefore follow * the rules for avoiding clashes with error numbers from * specific implementations or language run-time systems. * For this reason the codes are based at WSABASEERR+1001. * Note also that [WSA]NO_ADDRESS is defined only for * compatibility purposes. */ #define h_errno WSAGetLastError() /* Authoritative Answer: Host not found */ #define WSAHOST_NOT_FOUND (WSABASEERR+1001) #define HOST_NOT_FOUND WSAHOST_NOT_FOUND /* Non-Authoritative: Host not found, or SERVERFAIL */ #define WSATRY_AGAIN (WSABASEERR+1002) #define TRY_AGAIN WSATRY_AGAIN /* Non recoverable errors, FORMERR, REFUSED, NOTIMP */ #define WSANO_RECOVERY (WSABASEERR+1003) #define NO_RECOVERY WSANO_RECOVERY /* Valid name, no data record of requested type */ #define WSANO_DATA (WSABASEERR+1004) #define NO_DATA WSANO_DATA /* no address, look for MX record */ #define WSANO_ADDRESS WSANO_DATA #define NO_ADDRESS WSANO_ADDRESS /* * Windows Sockets errors redefined as regular Berkeley error constants */ #define EWOULDBLOCK WSAEWOULDBLOCK #define EINPROGRESS WSAEINPROGRESS #define EALREADY WSAEALREADY #define ENOTSOCK WSAENOTSOCK #define EDESTADDRREQ WSAEDESTADDRREQ #define EMSGSIZE WSAEMSGSIZE #define EPROTOTYPE WSAEPROTOTYPE #define ENOPROTOOPT WSAENOPROTOOPT #define EPROTONOSUPPORT WSAEPROTONOSUPPORT #define ESOCKTNOSUPPORT WSAESOCKTNOSUPPORT #define EOPNOTSUPP WSAEOPNOTSUPP #define EPFNOSUPPORT WSAEPFNOSUPPORT #define EAFNOSUPPORT WSAEAFNOSUPPORT #define EADDRINUSE WSAEADDRINUSE #define EADDRNOTAVAIL WSAEADDRNOTAVAIL #define ENETDOWN WSAENETDOWN #define ENETUNREACH WSAENETUNREACH #define ENETRESET WSAENETRESET #define ECONNABORTED WSAECONNABORTED #define ECONNRESET WSAECONNRESET #define ENOBUFS WSAENOBUFS #define EISCONN WSAEISCONN #define ENOTCONN WSAENOTCONN #define ESHUTDOWN WSAESHUTDOWN #define ETOOMANYREFS WSAETOOMANYREFS #define ETIMEDOUT WSAETIMEDOUT #define ECONNREFUSED WSAECONNREFUSED #define ELOOP WSAELOOP #define ENAMETOOLONG WSAENAMETOOLONG #define EHOSTDOWN WSAEHOSTDOWN #define EHOSTUNREACH WSAEHOSTUNREACH #define ENOTEMPTY WSAENOTEMPTY #define EPROCLIM WSAEPROCLIM #define EUSERS WSAEUSERS #define EDQUOT WSAEDQUOT #define ESTALE WSAESTALE #define EREMOTE WSAEREMOTE /* Socket function prototypes */ #ifdef __cplusplus extern "C" { #endif SOCKET PASCAL FAR accept (SOCKET s, struct sockaddr FAR *addr, int FAR *addrlen); int PASCAL FAR bind (SOCKET s, const struct sockaddr FAR *addr, int namelen); int PASCAL FAR closesocket (SOCKET s); int PASCAL FAR connect (SOCKET s, const struct sockaddr FAR *name, int namelen); int PASCAL FAR ioctlsocket (SOCKET s, long cmd, u_long FAR *argp); int PASCAL FAR getpeername (SOCKET s, struct sockaddr FAR *name, int FAR * namelen); int PASCAL FAR getsockname (SOCKET s, struct sockaddr FAR *name, int FAR * namelen); int PASCAL FAR getsockopt (SOCKET s, int level, int optname, char FAR * optval, int FAR *optlen); u_long PASCAL FAR htonl (u_long hostlong); u_short PASCAL FAR htons (u_short hostshort); unsigned long PASCAL FAR inet_addr (const char FAR * cp); char FAR * PASCAL FAR inet_ntoa (struct in_addr in); int PASCAL FAR listen (SOCKET s, int backlog); u_long PASCAL FAR ntohl (u_long netlong); u_short PASCAL FAR ntohs (u_short netshort); int PASCAL FAR recv (SOCKET s, char FAR * buf, int len, int flags); int PASCAL FAR recvfrom (SOCKET s, char FAR * buf, int len, int flags, struct sockaddr FAR *from, int FAR * fromlen); int PASCAL FAR select (int nfds, fd_set FAR *readfds, fd_set FAR *writefds, fd_set FAR *exceptfds, const struct timeval FAR *timeout); int PASCAL FAR send (SOCKET s, const char FAR * buf, int len, int flags); int PASCAL FAR sendto (SOCKET s, const char FAR * buf, int len, int flags, const struct sockaddr FAR *to, int tolen); int PASCAL FAR setsockopt (SOCKET s, int level, int optname, const char FAR * optval, int optlen); int PASCAL FAR shutdown (SOCKET s, int how); SOCKET PASCAL FAR socket (int af, int type, int protocol); /* Database function prototypes */ struct hostent FAR * PASCAL FAR gethostbyaddr(const char FAR * addr, int len, int type); struct hostent FAR * PASCAL FAR gethostbyname(const char FAR * name); int PASCAL FAR gethostname (char FAR * name, int namelen); struct servent FAR * PASCAL FAR getservbyport(int port, const char FAR * proto); struct servent FAR * PASCAL FAR getservbyname(const char FAR * name, const char FAR * proto); struct protoent FAR * PASCAL FAR getprotobynumber(int proto); struct protoent FAR * PASCAL FAR getprotobyname(const char FAR * name); /* Microsoft Windows Extension function prototypes */ int PASCAL FAR WSAStartup(WORD wVersionRequired, LPWSADATA lpWSAData); int PASCAL FAR WSACleanup(void); void PASCAL FAR WSASetLastError(int iError); int PASCAL FAR WSAGetLastError(void); BOOL PASCAL FAR WSAIsBlocking(void); int PASCAL FAR WSAUnhookBlockingHook(void); FARPROC PASCAL FAR WSASetBlockingHook(FARPROC lpBlockFunc); int PASCAL FAR WSACancelBlockingCall(void); HANDLE PASCAL FAR WSAAsyncGetServByName(HWND hWnd, u_int wMsg, const char FAR * name, const char FAR * proto, char FAR * buf, int buflen); HANDLE PASCAL FAR WSAAsyncGetServByPort(HWND hWnd, u_int wMsg, int port, const char FAR * proto, char FAR * buf, int buflen); HANDLE PASCAL FAR WSAAsyncGetProtoByName(HWND hWnd, u_int wMsg, const char FAR * name, char FAR * buf, int buflen); HANDLE PASCAL FAR WSAAsyncGetProtoByNumber(HWND hWnd, u_int wMsg, int number, char FAR * buf, int buflen); HANDLE PASCAL FAR WSAAsyncGetHostByName(HWND hWnd, u_int wMsg, const char FAR * name, char FAR * buf, int buflen); HANDLE PASCAL FAR WSAAsyncGetHostByAddr(HWND hWnd, u_int wMsg, const char FAR * addr, int len, int type, const char FAR * buf, int buflen); int PASCAL FAR WSACancelAsyncRequest(HANDLE hAsyncTaskHandle); int PASCAL FAR WSAAsyncSelect(SOCKET s, HWND hWnd, u_int wMsg, long lEvent); #ifdef __cplusplus } #endif /* Microsoft Windows Extended data types */ typedef struct sockaddr SOCKADDR; typedef struct sockaddr *PSOCKADDR; typedef struct sockaddr FAR *LPSOCKADDR; typedef struct sockaddr_in SOCKADDR_IN; typedef struct sockaddr_in *PSOCKADDR_IN; typedef struct sockaddr_in FAR *LPSOCKADDR_IN; typedef struct linger LINGER; typedef struct linger *PLINGER; typedef struct linger FAR *LPLINGER; typedef struct in_addr IN_ADDR; typedef struct in_addr *PIN_ADDR; typedef struct in_addr FAR *LPIN_ADDR; typedef struct fd_set FD_SET; typedef struct fd_set *PFD_SET; typedef struct fd_set FAR *LPFD_SET; typedef struct hostent HOSTENT; typedef struct hostent *PHOSTENT; typedef struct hostent FAR *LPHOSTENT; typedef struct servent SERVENT; typedef struct servent *PSERVENT; typedef struct servent FAR *LPSERVENT; typedef struct protoent PROTOENT; typedef struct protoent *PPROTOENT; typedef struct protoent FAR *LPPROTOENT; typedef struct timeval TIMEVAL; typedef struct timeval *PTIMEVAL; typedef struct timeval FAR *LPTIMEVAL; /* * Windows message parameter composition and decomposition * macros. * * WSAMAKEASYNCREPLY is intended for use by the Windows Sockets implementation * when constructing the response to a WSAAsyncGetXByY() routine. */ #define WSAMAKEASYNCREPLY(buflen,error) MAKELONG(buflen,error) /* * WSAMAKESELECTREPLY is intended for use by the Windows Sockets implementation * when constructing the response to WSAAsyncSelect(). */ #define WSAMAKESELECTREPLY(event,error) MAKELONG(event,error) /* * WSAGETASYNCBUFLEN is intended for use by the Windows Sockets application * to extract the buffer length from the lParam in the response * to a WSAGetXByY(). */ #define WSAGETASYNCBUFLEN(lParam) LOWORD(lParam) /* * WSAGETASYNCERROR is intended for use by the Windows Sockets application * to extract the error code from the lParam in the response * to a WSAGetXByY(). */ #define WSAGETASYNCERROR(lParam) HIWORD(lParam) /* * WSAGETSELECTEVENT is intended for use by the Windows Sockets application * to extract the event code from the lParam in the response * to a WSAAsyncSelect(). */ #define WSAGETSELECTEVENT(lParam) LOWORD(lParam) /* * WSAGETSELECTERROR is intended for use by the Windows Sockets application * to extract the error code from the lParam in the response * to a WSAAsyncSelect(). */ #define WSAGETSELECTERROR(lParam) HIWORD(lParam) #endif /* _WINSOCKAPI_ */ Appendix B: Notes for Windows Sockets Suppliers 149 Appendix B. Notes for Windows Sockets Suppliers B.1 Introduction A Windows Sockets implementation must implement ALL the functionality described in the Windows Sockets documentation. Validation of compliance is discussed in section B.8. Windows Sockets Version 1.1 implementations must support both TCP and UDP type sockets. An implementation may support raw sockets (of type SOCK_RAW), but their use is deprecated. Certain APIs documented above have special notes for Windows Sockets implementors. A Windows Sockets implementation should pay special attention to conforming to the API as documented. The Special Notes are provided for assistance and clarification. B.2 Windows Sockets Components B.2.1 Development Components The Windows Sockets development components for use by Windows Sockets application developers will be provided by each Windows Sockets supplier. These Windows Sockets development components are: Component Description Windows Sockets Documentation This document WINSOCK.LIB file Windows Sockets API Import Library WINSOCK.H file Windows Sockets Header File NETDB.H file Berkeley Compatible Header File ARPA/INET.H file Berkeley Compatible Header File SYS/TIME.H file Berkeley Compatible Header File SYS/SOCKET.H file Berkeley Compatible Header File NETINET/IN.H file Berkeley Compatible Header File B.2.2 Run Time Components The run time component provided by each Windows Sockets supplier is: Component Description WINSOCK.DLL The Windows Sockets API implementation DLL B.3 Multithreadedness and blocking routines. Data areas returned by, for example, the getXbyY() routines MUST be on a per thread basis. Note that an application MUST be prevented from making multiple nested Windows Sockets function calls. Only one outstanding function call will be allowed for a particular task. Any Windows Sockets call performed when an existing blocking call is already outstanding will fail with an error code of WSAEINPROGRESS. There are two exceptions to this restriction: WSACancelBlockingCall() and WSAIsBlocking() may be called at any time. Windows Sockets suppliers should note that although preliminary drafts of this specification indicated that the restriction only applied to blocking function calls, and that it would be permissible to make non-blocking calls while a blocking call was in progress, this is no longer true. 150 Appendix B: Notes for Windows Sockets Suppliers Regarding the implementation of blocking routines, the solution in Windows Sockets is to simulate the blocking mechanism by having each routine call PeekMessage() as it waits for the completion of its operation. In anticipation of this, the function WSASetBlockingHook() is provided to allow the programmer to define a special routine to be called instead of the default PeekMessage() loop. The blocking hook functions are discussed in more detail in 4.3.13, WSASetBlockingHook(). B.4 Database Files The database routines in the getXbyY() family (gethostbyaddr(), etc.) were originally designed (in the first Berkeley UNIX releases) as mechanisms for looking up information in text databases. A Windows Sockets supplier may choose to employ local files OR a name service to provide some or all of this information. If local files exist, the format of the files must be identical to that used in BSD UNIX, allowing for the differences in text file formats. B.5 FD_ISSET It is necessary to implement the FD_ISSET Berkeley macro using a supporting function: __WSAFDIsSet(). It is the responsibility of a Windows Sockets implementation to make this available as part of the Windows Sockets API. Unlike the other functions exported by a Windows Sockets DLL, however, this function is not intended to be invoked directly by Windows Sockets applications: it should be used only to support the FD_ISSET macro. The source code for this function is listed below: int FAR __WSAFDIsSet(SOCKET fd, fd_set FAR *set) { int i = set->fd_count; while (i--) if (set->fd_array[i] == fd) return 1; return 0; } B.6 Error Codes In order to avoid conflict between various compiler environments Windows Sockets implementations MUST return the error codes listed in the API specification, using the manifest constants beginning with "WSA". The Berkeley-compatible error code definitions are provided solely for compatibility purposes for applications which are being ported from other platforms. B.7 DLL Ordinal Numbers The winsock.def file for use by every Windows Sockets implementation is as follows. Ordinal values starting at 1000 are reserved for Windows Sockets implementors to use for exporting private interfaces to their DLLs. A Windows Sockets implementation must not use any Appendix B: Notes for Windows Sockets Suppliers 151 ordinals 999 and below except for those APIs listed below. An application which wishes to work with any Windows Sockets DLL must use only those routines listed below; using a private export makes an application dependent on a particular Windows Sockets implementation. ; ; File: winsock.def ; System: MS-Windows 3.x ; Summary: Module definition file for Windows Sockets DLL. ; LIBRARY WINSOCK ; Application's module name DESCRIPTION 'BSD Socket API for Windows' EXETYPE WINDOWS ; required for all windows applications STUB 'WINSTUB.EXE' ; generates error message if application ; is run without Windows ;CODE can be FIXED in memory because of potential upcalls CODE PRELOAD FIXED ;DATA must be SINGLE and at a FIXED location since this is a DLL DATA PRELOAD FIXED SINGLE HEAPSIZE 1024 STACKSIZE 16384 ; All functions that will be called by any Windows routine ; must be exported. Any additional exports beyond those defined ; here must have ordinal numbers 1000 or above. EXPORTS accept @1 bind @2 closesocket @3 connect @4 getpeername @5 getsockname @6 getsockopt @7 htonl @8 htons @9 inet_addr @10 inet_ntoa @11 ioctlsocket @12 listen @13 ntohl @14 ntohs @15 recv @16 recvfrom @17 select @18 send @19 sendto @20 setsockopt @21 152 Appendix B: Notes for Windows Sockets Suppliers shutdown @22 socket @23 gethostbyaddr @51 gethostbyname @52 getprotobyname @53 getprotobynumber @54 getservbyname @55 getservbyport @56 gethostname @57 WSAAsyncSelect @101 WSAAsyncGetHostByAddr @102 WSAAsyncGetHostByName @103 WSAAsyncGetProtoByNumber @104 WSAAsyncGetProtoByName @105 WSAAsyncGetServByPort @106 WSAAsyncGetServByName @107 WSACancelAsyncRequest @108 WSASetBlockingHook @109 WSAUnhookBlockingHook @110 WSAGetLastError @111 WSASetLastError @112 WSACancelBlockingCall @113 WSAIsBlocking @114 WSAStartup @115 WSACleanup @116 __WSAFDIsSet @151 WEP @500 RESIDENTNAME ;eof B.8 Validation Suite An alpha version of the Windows Sockets Test and Validation Suite to ensure Windows Sockets compatibility will be available at Fall 1992 Interop from Microsoft. This alpha version includes functionality testing of the Windows Sockets interface and is supported by a comprehensive scripting language. The final version of the suite is expected to be available in January 1993, and it will include a more sophisticated user interface. Beta versions may be available in the interim. Further documentation on the test suite is available from Microsoft. Appendix B: Notes for Windows Sockets Suppliers 153 Appendix C. For Further Reference This specification is intended to cover the Windows Sockets interface to TCP/IP in detail. Many details of TCP/IP and Windows, however, are intentionally omitted in the interest of brevity, and this specification often assumes background knowledge of these topics. For more information, the following references may be helpful: Braden, R.[1989], RFC 1122, Requirements for Internet Hosts-- Communication Layers, Internet Engineering Task Force. Comer, D. [1991], Internetworking with TCP/IP Volume I: Principles, Protocols, and Architecture, Prentice Hall, Englewood Cliffs, New Jersey. Comer, D. and Stevens, D. [1991], Internetworking with TCP/IP Volume II: Design, Implementation, and Internals, Prentice Hall, Englewood Cliffs, New Jersey. Comer, D. and Stevens, D. [1991], Internetworking with TCP/IP Volume III: Client-Server Programming and Applications, Prentice Hall, Englewood Cliffs, New Jersey. Leffler, S. et al., An Advanced 4.3BSD Interprocess Communication Tutorial. Petzold, C. [1992], Programming Windows 3.1, Microsoft Press, Redmond, Washington. Stevens, W.R. [1990], Unix Network Programming, Prentice Hall, Englewood Cliffs, New Jersey. Appendix D. Background Information D.1 Legal Status of Windows Sockets The copyright for the Windows Sockets specification is owned by the specification authors listed on the title page. Permission is granted to redistribute this specification in any form, provided that the contents of the specification are not modified. Windows Sockets implementors are encouraged to include this specification with their product documentation. The Windows Sockets logo on the title page of this document is meant for use on both Windows Sockets implementations and for applications that use the Windows Sockets interface. Use of the logo is encouraged on packaging, documentation, collateral, and advertising. The logo is available on microdyne.com in pub/winsock as winsock.bmp. The suggested color for the logo's title bar is blue, the electrical socket grey, and the text and outline black. D.2 The Story Behind the Windows Sockets Icon 154 Appendix B: Notes for Windows Sockets Suppliers (by Alistair Banks, Microsoft Corporation) We thought we'd do a "Wind Sock" at one stage--but you try to get that into 32x32 bits! It would have had to look wavy and colorful, and... well, it just didn't work. Also, our graphics designers have "opinions" about the icons truly representing what they are--people would have thought this was "The colorful wavy tube specification 1.0!" I tried to explain "API" "Programming Interface" to the artist--we ended up with toolbox icons with little flying windows Then we came to realise that we should be going after the shortened form of the name, rather the name in full... Windows Sockets... And so we went for that - so she drew (now remember I'm English and you're probably American) "Windows Spanner", a.k.a. a socket wrench. In the U.S. you'd have been talking about the "Windows Socket spec" OK, but in England that would have been translated as "Windows Spanner Spec 1.0" - so we went to Electrical sockets - well the first ones came out looking like "Windows Pignose Spec 1.0"!!!! So how do you use 32x32, get an international electrical socket! You take the square type (American & English OK, Europe & Australia are too rounded)--you choose the American one, because it's on the wall in front of you (and it's more compact (but less safe, IMHO) and then you turn it upside down, thereby compromising its nationality! [IMHO = "In My Humble Opinion"--ed.]