123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305306307308309310311312313314315316317318319320321322323324325326327328329330331332333334335336337338339340341342343344345346347348349350351352353354355356357358359360361362363364365366367368369370371372373374375376377378379380381382383384385386387388389390391392393394395396397398399400401402403404405406407408409410411412413414415416417418419420421422423424425426427428429430431432433434435436437438439440441442443444445446447448449450451452453454455456457 |
- .TH INTRO 2
- .SH NAME
- intro \- introduction to library functions
- .SH SYNOPSIS
- .nf
- .B #include <u.h>
- .PP
- .B #include <libc.h>
- .PP
- .B #include <auth.h>
- .PP
- .B #include <bio.h>
- .PP
- .B #include <draw.h>
- .PP
- .B #include <fcall.h>
- .PP
- .B #include <frame.h>
- .PP
- .B #include <mach.h>
- .PP
- .B #include <ndb.h>
- .PP
- .B #include <regexp.h>
- .PP
- .B #include <stdio.h>
- .PP
- .B #include <thread.h>
- .fi
- .SH DESCRIPTION
- This section describes functions
- in various libraries.
- For the most part, each library is defined by a single C include
- file, such as those listed above, and a single archive file containing
- the library proper. The name of the archive is
- .BI /$objtype/lib/lib x .a \f1,
- where
- .I x
- is the base of the include file name, stripped of a leading
- .B lib
- if present.
- For example,
- .B <draw.h>
- defines the contents of library
- .BR /$objtype/lib/libdraw.a ,
- which may be abbreviated when named to the loader as
- .BR -ldraw .
- In practice, each include file contains a
- .B #pragma
- that directs the loader to pick up the associated archive
- automatically, so it is rarely necessary to tell the loader
- which
- libraries a program needs.
- .PP
- The library to which a function belongs is defined by the
- header file that defines its interface.
- The `C library',
- .IR libc ,
- contains most of the basic subroutines such
- as
- .IR strlen .
- Declarations for all of these functions are
- in
- .BR <libc.h> ,
- which must be preceded by
- .RI ( needs )
- an include of
- .BR <u.h> .
- The graphics library,
- .IR draw ,
- is defined by
- .BR <draw.h> ,
- which needs
- .B <libc.h>
- and
- .BR <u.h> .
- The Buffered I/O library,
- .IR libbio ,
- is defined by
- .BR <bio.h> ,
- which needs
- .B <libc.h>
- and
- .BR <u.h> .
- The ANSI C Standard I/O library,
- .IR libstdio ,
- is defined by
- .BR <stdio.h> ,
- which needs
- .BR <u.h> .
- There are a few other, less commonly used libraries defined on
- individual pages of this section.
- .PP
- The include file
- .BR <u.h> ,
- a prerequisite of several other include files,
- declares the architecture-dependent and -independent types, including:
- .IR uchar ,
- .IR ushort ,
- .IR uint ,
- and
- .IR ulong ,
- the unsigned integer types;
- .IR schar ,
- the signed char type;
- .I vlong
- and
- .IR uvlong ,
- the signed and unsigned very long integral types;
- .IR Rune ,
- the Unicode character type;
- .IR u8int ,
- .IR u16int ,
- .IR u32int ,
- and
- .IR u64int ,
- the unsigned integral types with specific widths;
- .IR usize ,
- the unsigned integral type with the same width as a pointer;
- .IR jmp_buf ,
- the type of the argument to
- .I setjmp
- and
- .IR longjmp ,
- plus macros that define the layout of
- .IR jmp_buf
- (see
- .IR setjmp (2));
- definitions of the bits in the floating-point control register
- as used by
- .IR getfcr (2);
- and
- the macros
- .B va_arg
- and friends for accessing arguments of variadic functions (identical to the
- macros defined in
- .B <stdarg.h>
- in ANSI C).
- .SS "Name space
- Files are collected into a hierarchical organization called a
- .I "file tree
- starting in a
- .I directory
- called the
- .IR root .
- File names, also called
- .IR paths ,
- consist of a number of
- .BR / -separated
- .I "path elements"
- with the slashes corresponding to directories.
- A path element must contain only printable
- characters (those outside the control spaces of
- .SM ASCII
- and Latin-1).
- A path element cannot contain a slash.
- .PP
- When a process presents a file name to Plan 9, it is
- .I evaluated
- by the following algorithm.
- Start with a directory that depends on the first
- character of the path:
- .L /
- means the root of the main hierarchy,
- .L #
- means the separate root of a kernel device's file tree (see Section 3),
- and anything else means the process's current working directory.
- Then for each path element, look up the element
- in the directory, advance to that directory,
- do a possible translation (see below), and repeat.
- The last step may yield a directory or regular file.
- The collection of files reachable from the root is called the
- .I "name space
- of a process.
- .PP
- A program can use
- .I bind
- or
- .I mount
- (see
- .IR bind (2))
- to say that whenever a specified file is reached during evaluation,
- evaluation instead continues from a second specified file.
- Also, the same system calls create
- .IR "union directories" ,
- which are concatenations of ordinary directories
- that are searched sequentially until the desired element is found.
- Using
- .I bind
- and
- .I mount
- to do name space adjustment affects only
- the current process group (see below).
- Certain conventions about the layout of the name space should
- be preserved; see
- .IR namespace (4).
- .SS "File I/O"
- Files are opened for input or output
- by
- .I open
- or
- .I create
- (see
- .IR open (2)).
- These calls return an integer called a
- .IR "file descriptor"
- which identifies the file
- to subsequent I/O calls,
- notably
- .IR read (2)
- and
- .IR write .
- The system allocates the numbers by selecting the lowest unused descriptor.
- They are allocated dynamically; there is no visible limit to the number of file
- descriptors a process may have open.
- They may be reassigned using
- .IR dup (2).
- File descriptors are indices into a
- kernel resident
- .IR "file descriptor table" .
- Each process has an associated file descriptor table.
- In some cases (see
- .I rfork
- in
- .IR fork (2))
- a file descriptor table may be shared by several processes.
- .PP
- By convention,
- file descriptor 0 is the standard input,
- 1 is the standard output,
- and 2 is the standard error output.
- With one exception, the operating system is unaware of these conventions;
- it is permissible to close file 0,
- or even to replace it by a file open only for writing,
- but many programs will be confused by such chicanery.
- The exception is that the system prints messages about broken processes
- to file descriptor 2.
- .PP
- Files are normally read or written in sequential order.
- The I/O position in the file is called the
- .IR "file offset"
- and may be set arbitrarily using the
- .IR seek (2)
- system call.
- .PP
- Directories may be opened and read much like regular files.
- They contain an integral number of records, called
- .IR "directory entries" .
- Each entry is a machine-independent representation of
- the information about an existing file in the directory,
- including the name, ownership,
- permission,
- access dates,
- and so on.
- The entry
- corresponding to an arbitrary file can be retrieved by
- .IR stat (2)
- or
- .IR fstat ;
- .I wstat
- and
- .I fwstat
- write back entries, thus changing the properties of a file.
- An entry may be translated into a more convenient, addressable
- form called a
- .B Dir
- structure;
- .IR dirstat ,
- .IR dirfstat,
- .IR dirwstat ,
- and
- .I dirfwstat
- execute the appropriate translations (see
- .IR stat (2)).
- .PP
- New files are made with
- .I create
- (see
- .IR open (2))
- and deleted with
- .IR remove (2).
- Directories may not directly be written;
- .IR create ,
- .IR remove ,
- .IR wstat ,
- and
- .I fwstat
- alter them.
- .PP
- The operating system kernel records the file name used to access each open file or directory.
- If the file is opened by a local name (one that does not begin
- .B /
- or
- .BR # ),
- the system makes the stored name absolute by prefixing
- the string associated with the current directory.
- Similar lexical adjustments are made for path names containing
- .B .
- (dot) or
- .B ..
- (dot-dot).
- By this process, the system maintains a record of the route by which each file was accessed.
- Although there is a possibility for error\(emthe name is not maintained after the file is opened,
- so removals and renamings can confound it\(emthis simple method usually
- permits the system to return, via the
- .IR fd2path (2)
- system call and related calls such as
- .IR getwd (2),
- a valid name that may be used to find a file again.
- This is also the source of the names reported in the name space listing of
- .IR ns (1)
- or
- .B /dev/ns
- (see
- .IR proc (3)).
- .PP
- .IR Pipe (2)
- creates a connected pair of file descriptors,
- useful for bidirectional local communication.
- .SS "Process execution and control"
- A new process is created
- when an existing one calls
- .I rfork
- with the
- .B RFPROC
- bit set, usually just by calling
- .IR fork (2).
- The new (child) process starts out with
- copies of the address space and most other attributes
- of the old (parent) process.
- In particular,
- the child starts out running
- the same program as the parent;
- .IR exec (2)
- will bring in a different one.
- .PP
- Each process has a unique integer process id;
- a set of open files, indexed by file descriptor;
- and a current working directory
- (changed by
- .IR chdir (2)).
- .PP
- Each process has a set of attributes \(em memory, open files,
- name space, etc. \(em that may be shared or unique.
- Flags to
- .IR rfork
- control the sharing of these attributes.
- .PP
- The memory of a process is divided into
- .IR segments .
- Every program has at least a
- .I text
- (instruction) and
- .I stack
- segment.
- Most also have an initialized
- .I data
- segment and a segment of zero-filled data called
- .IR bss .
- Processes may
- .IR segattach (2)
- other segments for special purposes.
- .PP
- A process terminates by calling
- .IR exits (2).
- A parent process may call
- .IR wait (2)
- to wait for some child to terminate.
- A string of status information
- may be passed from
- .I exits
- to
- .IR wait .
- A process can go to sleep for a specified time by calling
- .IR sleep (2).
- .PP
- There is a
- .I notification
- mechanism for telling a process about events such as address faults,
- floating point faults, and messages from other processes.
- A process uses
- .IR notify (2)
- to register the function to be called (the
- .IR "notification handler" )
- when such events occur.
- .SS Multithreading
- By calling
- .I rfork
- with the
- .B RFMEM
- bit set, a program may create several independently executing processes sharing the same
- memory (except for the stack segment, which is unique to each process).
- Where possible according to the ANSI C standard,
- the main C library works properly in multiprocess programs;
- .IR malloc ,
- .IR print ,
- and the other routines use locks (see
- .IR lock (2))
- to synchronize access to their data structures.
- The graphics library defined in
- .B <draw.h>
- is also multi-process capable; details are in
- .IR graphics (2).
- In general, though, multiprocess programs should use some form of synchronization
- to protect shared data.
- .PP
- The thread library, defined in
- .BR <thread.h> ,
- provides support for multiprocess programs.
- It includes a data structure called a
- .B Channel
- that can be used to send messages between processes,
- and coroutine-like
- .IR threads ,
- which enable multiple threads of control within a single process.
- The threads within a process are scheduled by the library, but there is
- no pre-emptive scheduling within a process; thread switching occurs
- only at communication or synchronization points.
- .PP
- Most programs using the thread library
- comprise multiple processes
- communicating over channels, and within some processes,
- multiple threads. Since Plan 9 I/O calls may block, a system
- call may block all the threads in a process.
- Therefore, a program that shouldn't block unexpectedly will use a process
- to serve the I/O request, passing the result to the main processes
- over a channel when the request completes.
- For examples of this design, see
- .IR ioproc (2)
- or
- .IR mouse (2).
- .SH SEE ALSO
- .IR nm (1),
- .IR 8l (1),
- .IR 8c (1)
- .SH DIAGNOSTICS
- Math functions in
- .I libc
- return
- special values when the function is undefined for the
- given arguments or when the value is not representable
- (see
- .IR nan (2)).
- .PP
- Some of the functions in
- .I libc
- are system calls and many others employ system calls in their implementation.
- All system calls return integers,
- with \-1 indicating that an error occurred;
- .IR errstr (2)
- recovers a string describing the error.
- Some user-level library functions also use the
- .I errstr
- mechanism to report errors.
- Functions that may affect the value of the error string are said to ``set
- .IR errstr '';
- it is understood that the error string is altered only if an error occurs.
|