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ruby--ruby/ext/dl
ttate 74b4c81396 Merge Nakada's patch and define StringValuePtr for ruby-1.6.
CV ----------------------------------------------------------------------


git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@2330 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2002-04-03 11:59:01 +00:00
..
lib/dl Add ruby-dl 2002-04-02 10:56:13 +00:00
sample Add ruby-dl 2002-04-02 10:56:13 +00:00
test Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
.cvsignore Add ruby-dl. 2002-04-02 10:58:19 +00:00
depend Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
dl.c Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
dl.def Add ruby-dl 2002-04-02 10:56:13 +00:00
dl.h Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
extconf.rb Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
h2rb Add ruby-dl 2002-04-02 10:56:13 +00:00
handle.c Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
install.rb Add ruby-dl 2002-04-02 10:56:13 +00:00
MANIFEST Add ruby-dl 2002-04-02 10:56:13 +00:00
mkcall.rb Add ruby-dl 2002-04-02 10:56:13 +00:00
mkcallback.rb Add ruby-dl 2002-04-02 10:56:13 +00:00
mkcbtable.rb Add ruby-dl 2002-04-02 10:56:13 +00:00
ptr.c Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
README Add ruby-dl 2002-04-02 10:56:13 +00:00
README.html Add ruby-dl 2002-04-02 10:56:13 +00:00
sym.c Merge Nakada's patch and define StringValuePtr for ruby-1.6. 2002-04-03 11:59:01 +00:00
type.rb Add ruby-dl 2002-04-02 10:56:13 +00:00

                                    Ruby/DL                                    
                                                                               
                    an interface to dynamic linking loader                     
-------------------------------------------------------------------------------

Ruby/DL

`Ruby/DL' provides an interface to the dynamic linking loader.
-------------------------------------------------------------------------------

Installing

    $ ruby extconf.rb    # to create the Makefile
    $ make               # to build the library 'dl.so'
    $ make libtest.so    # to build the C library 'libtest.so' for the test script
    $ make test          # to run the test script
    $ make install       # to install the library
    $ make clean         # to remove the created files without Makefile
    $ make distclean     # to remove the all created files

-------------------------------------------------------------------------------

Functions and Classes

after loading the `dl' library, we get access to the module called `DL'. the DL
module has the following constants, functions and classes.

Constants

VERSION
MAJOR_VERSION
MINOR_VERSION
PATCH_VERSION
RTLD_GLOBAL
RTLD_LAZY
RTLD_NOW
MAX_ARG
MAX_CBARG
MAX_CBENT

Functions

handle = dlopen(lib){|handle| ... }
    is quite equal to `Handle.new(lib)'
sym = set_callback(cbtype, entry){|args| ... }
sym = set_callback(cbtype, entry, proc)
    makes entry-th pre-defined function to call the proc or given block. the 
    entry-th pre-defined function is specified by cbtype and entry. cbtype is a
    prototype of the callback. see also the section `Type specifiers' about 
    cbtype.
sym = get_callback(cbtype, entry)
    returns the Proc object which is given by the above function
    `set_callback'.
ptr = malloc(size, [free = nil])
    allocates the size bytes, and returns the pointer as a PtrData object ptr.
ptr = strdup(str)
    returns a PtrData object ptr which represents the pointer to a new string
    which is a duplicate of the string str.
size = sizeof(type)
    returns the size of type. `sizeof("C") + sizeof("L")' is not equal to
    `sizeof("CL")'. the latter is assumed to returns the enough size of the
    structure `struct foo { char c; long l; }', but the size may not equal to
    `sizeof(foo)' of C.

class Handle

handle = Handle.new(lib){|handle| ... }
    opens a library lib and returns a Handle object handle. if a block is
    given, the handle is automatically closed as the block ends.
Handle#close
    closes the handle opened by the above Handle.new(lib).
sym = Handle#sym(func, prototype = "0")
sym = Handle#[func, prototype = nil]
    obtains the pointer to a function called func and returns a Symbol object
    or a DataPtr object. prototype is a string which consists of type
    specifiers, it indicates the function's prototype. see also the section
    `Type specifiers'.

class Symbol

sym = Symbol.new(addr, type = nil, name = nil)
    creates the Symbol object sym with the type type if type is not nil. addr
    is the address where the function is allocated. If type is nil, it returns
    a DataPtr object.
Symbol::char2type(char)
    takes a character char that represents a type and returns the type
    specifier of the C language.
str = Symbol#proto()
    returns the function prototype.
str = Symbol#name()
    Returns the function name.
str = Symbol#cproto()
str = Symbol#to_s()
    returns the prototype of the C language.
str = Symbol#inspect()
    returns the inspectable string.
r,rs = Symbol#call(arg1,arg2,...,argN)
r,rs = Symbol#[](arg1,arg2,...,argN)
    calls the function with parameters arg1, arg2, ..., argN. and the result
    consists of the return value r and parameters rs. rs is an array.
ptr = Symbol#to_ptr
    returns the corresponding PtrData object ptr.

class PtrData

ptr = PtrData.new(addr, [free = nil])
    returns the PtrData object representing the pointer which indicates the
    address addr. GC frees the memory using the free function.
PtrData#free=(sym)
    if you specify a symbol object sym, GC frees the memory using the function
    represented by sym.
sym = PtrData#free
    returns a symbol object sym which is used when GC frees the memory. it
    usually configured by `PtrData#free=' or `PtrData.new'.
size = PtrData#size, PtrData#size=(size)
    gets and sets allocated size of the memory.
ary = PtrData#to_a(type, [size])
    returns an array of the type which specified with type. type must be one of
    'S','P','I','L','D' and 'F'.
str = PtrData#to_s([len])
    returns a string which length is len. if len is omitted, the end of the
    string is '\0'.
ptr = PtrData#ptr,+@
    returns the pointed value as a PtrData object ptr.
ptr = PtrData#ref,-@
    returns the reference as a PtrData object ptr.
ptr = PtrData#+
    returns the PtrData object
ptr = PtrData#-
    returns the PtrData object
PtrData#struct!(type, *members)
    defines the data type to get access to a structure member with a symbol.
    (see also PtrData#[])
PtrData#union!(type, *members)
    defines the data type to get access to a union member with a symbol. (see
    also PtrData#[])
val = PtrData#[key], PtrData#[key, num = 0]
    if the key is a string or symbol, this method returns the value of the
    structure/union member which has the type defined by PtrData#
    {struct!,union!}. if the key is a integer value and this object represents
    the pointer ptr, it returns the value of `(ptr + key).to_s(num)'
PtrData#[key,num]=val, PtrData#[key]=val
    if the key is a string or symbol, this method substitute the value of the
    structure/union member with val. if the key is a integer value and val is a
    string, this method copies num bytes of val to the memory area ptr using
    memcpy(3).

-------------------------------------------------------------------------------

Type specifiers

the prototype consists of the following type specifiers, first element of 
prototype represents the type of return value, and remaining elements represent
the type of each argument.

    C : a character (char)
    c : a pointer to a character (char *)
    H : a short integer (short)
    h : a pointer to a short integer (short *)
    I : an integer (char, short, int)
    i : a pointer to an integer (char *, short *, int *)
    L : a long integer (long)
    l : a pointer to a long integer (long *)
    F : a real (float)
    f : a pointer to a real (float *)
    D : a real (double)
    d : a pointer to a real (double *)
    S : an immutable string (const char *)
    s : a mutable string (char *)
    A : an array (const type[])
    a : a mutable array (type[])
    P : a pointer (void *)
    p : a mutable object (void *)
    0 : void function (this must be a first character of the prototype)

the cbtype consists of type specifiers 0, I, L, D and P.
for example:

    DL.set_callback('IPP',0){|ptr1,ptr2|
      str1 = ptr1.ptr.to_s
      str2 = ptr2.ptr.to_s
      return str1 <=> str2
    }

-------------------------------------------------------------------------------
ttate@kt.jaist.ac.jp