# # Copyright (C) 2008-2010 Wayne Meissner # # This file is part of ruby-ffi. # # All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are met: # # * Redistributions of source code must retain the above copyright notice, this # list of conditions and the following disclaimer. # * Redistributions in binary form must reproduce the above copyright notice # this list of conditions and the following disclaimer in the documentation # and/or other materials provided with the distribution. # * Neither the name of the Ruby FFI project nor the names of its contributors # may be used to endorse or promote products derived from this software # without specific prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" # AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE # IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE # DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE # FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR # SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, # OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.# module FFI CURRENT_PROCESS = USE_THIS_PROCESS_AS_LIBRARY = Object.new # @param [#to_s] lib library name # @return [String] library name formatted for current platform # Transform a generic library name to a platform library name # @example # # Linux # FFI.map_library_name 'c' # -> "libc.so.6" # FFI.map_library_name 'jpeg' # -> "libjpeg.so" # # Windows # FFI.map_library_name 'c' # -> "msvcrt.dll" # FFI.map_library_name 'jpeg' # -> "jpeg.dll" def self.map_library_name(lib) # Mangle the library name to reflect the native library naming conventions lib = Library::LIBC if lib == 'c' if lib && File.basename(lib) == lib lib = Platform::LIBPREFIX + lib unless lib =~ /^#{Platform::LIBPREFIX}/ r = Platform::IS_WINDOWS || Platform::IS_MAC ? "\\.#{Platform::LIBSUFFIX}$" : "\\.so($|\\.[1234567890]+)" lib += ".#{Platform::LIBSUFFIX}" unless lib =~ /#{r}/ end lib end # Exception raised when a function is not found in libraries class NotFoundError < LoadError def initialize(function, *libraries) super("Function '#{function}' not found in [#{libraries[0].nil? ? 'current process' : libraries.join(", ")}]") end end # This module is the base to use native functions. # # A basic usage may be: # require 'ffi' # # module Hello # extend FFI::Library # ffi_lib FFI::Library::LIBC # attach_function 'puts', [ :string ], :int # end # # Hello.puts("Hello, World") # # module Library CURRENT_PROCESS = FFI::CURRENT_PROCESS LIBC = FFI::Platform::LIBC # @param mod extended object # @return [nil] # @raise {RuntimeError} if +mod+ is not a Module # Test if extended object is a Module. If not, raise RuntimeError. def self.extended(mod) raise RuntimeError.new("must only be extended by module") unless mod.kind_of?(Module) end # @param [Array] names names of libraries to load # @return [Array] # @raise {LoadError} if a library cannot be opened # Load native libraries. def ffi_lib(*names) raise LoadError.new("library names list must not be empty") if names.empty? lib_flags = defined?(@ffi_lib_flags) ? @ffi_lib_flags : FFI::DynamicLibrary::RTLD_LAZY | FFI::DynamicLibrary::RTLD_LOCAL ffi_libs = names.map do |name| if name == FFI::CURRENT_PROCESS FFI::DynamicLibrary.open(nil, FFI::DynamicLibrary::RTLD_LAZY | FFI::DynamicLibrary::RTLD_LOCAL) else libnames = (name.is_a?(::Array) ? name : [ name ]).map(&:to_s).map { |n| [ n, FFI.map_library_name(n) ].uniq }.flatten.compact lib = nil errors = {} libnames.each do |libname| begin orig = libname lib = FFI::DynamicLibrary.open(libname, lib_flags) break if lib rescue Exception => ex ldscript = false if ex.message =~ /(([^ \t()])+\.so([^ \t:()])*):([ \t])*(invalid ELF header|file too short|invalid file format)/ if File.read($1) =~ /(?:GROUP|INPUT) *\( *([^ \)]+)/ libname = $1 ldscript = true end end if ldscript retry else # TODO better library lookup logic unless libname.start_with?("/") || FFI::Platform.windows? path = ['/usr/lib/','/usr/local/lib/','/opt/local/lib/'].find do |pth| File.exist?(pth + libname) end if path libname = path + libname retry end end libr = (orig == libname ? orig : "#{orig} #{libname}") errors[libr] = ex end end end if lib.nil? raise LoadError.new(errors.values.join(".\n")) end # return the found lib lib end end @ffi_libs = ffi_libs end # Set the calling convention for {#attach_function} and {#callback} # # @see http://en.wikipedia.org/wiki/Stdcall#stdcall # @note +:stdcall+ is typically used for attaching Windows API functions # # @param [Symbol] convention one of +:default+, +:stdcall+ # @return [Symbol] the new calling convention def ffi_convention(convention = nil) @ffi_convention ||= :default @ffi_convention = convention if convention @ffi_convention end # @see #ffi_lib # @return [Array] array of currently loaded FFI libraries # @raise [LoadError] if no libraries have been loaded (using {#ffi_lib}) # Get FFI libraries loaded using {#ffi_lib}. def ffi_libraries raise LoadError.new("no library specified") if !defined?(@ffi_libs) || @ffi_libs.empty? @ffi_libs end # Flags used in {#ffi_lib}. # # This map allows you to supply symbols to {#ffi_lib_flags} instead of # the actual constants. FlagsMap = { :global => DynamicLibrary::RTLD_GLOBAL, :local => DynamicLibrary::RTLD_LOCAL, :lazy => DynamicLibrary::RTLD_LAZY, :now => DynamicLibrary::RTLD_NOW } # Sets library flags for {#ffi_lib}. # # @example # ffi_lib_flags(:lazy, :local) # => 5 # # @param [Symbol, …] flags (see {FlagsMap}) # @return [Fixnum] the new value def ffi_lib_flags(*flags) @ffi_lib_flags = flags.inject(0) { |result, f| result | FlagsMap[f] } end ## # @overload attach_function(func, args, returns, options = {}) # @example attach function without an explicit name # module Foo # extend FFI::Library # ffi_lib FFI::Library::LIBC # attach_function :malloc, [:size_t], :pointer # end # # now callable via Foo.malloc # @overload attach_function(name, func, args, returns, options = {}) # @example attach function with an explicit name # module Bar # extend FFI::Library # ffi_lib FFI::Library::LIBC # attach_function :c_malloc, :malloc, [:size_t], :pointer # end # # now callable via Bar.c_malloc # # Attach C function +func+ to this module. # # # @param [#to_s] name name of ruby method to attach as # @param [#to_s] func name of C function to attach # @param [Array] args an array of types # @param [Symbol] returns type of return value # @option options [Boolean] :blocking (@blocking) set to true if the C function is a blocking call # @option options [Symbol] :convention (:default) calling convention (see {#ffi_convention}) # @option options [FFI::Enums] :enums # @option options [Hash] :type_map # # @return [FFI::VariadicInvoker] # # @raise [FFI::NotFoundError] if +func+ cannot be found in the attached libraries (see {#ffi_lib}) def attach_function(name, func, args, returns = nil, options = nil) mname, a2, a3, a4, a5 = name, func, args, returns, options cname, arg_types, ret_type, opts = (a4 && (a2.is_a?(String) || a2.is_a?(Symbol))) ? [ a2, a3, a4, a5 ] : [ mname.to_s, a2, a3, a4 ] # Convert :foo to the native type arg_types = arg_types.map { |e| find_type(e) } options = { :convention => ffi_convention, :type_map => defined?(@ffi_typedefs) ? @ffi_typedefs : nil, :blocking => defined?(@blocking) && @blocking, :enums => defined?(@ffi_enums) ? @ffi_enums : nil, } @blocking = false options.merge!(opts) if opts && opts.is_a?(Hash) # Try to locate the function in any of the libraries invokers = [] ffi_libraries.each do |lib| if invokers.empty? begin function = nil function_names(cname, arg_types).find do |fname| function = lib.find_function(fname) end raise LoadError unless function invokers << if arg_types.length > 0 && arg_types[arg_types.length - 1] == FFI::NativeType::VARARGS VariadicInvoker.new(function, arg_types, find_type(ret_type), options) else Function.new(find_type(ret_type), arg_types, function, options) end rescue LoadError end end end invoker = invokers.compact.shift raise FFI::NotFoundError.new(cname.to_s, ffi_libraries.map { |lib| lib.name }) unless invoker invoker.attach(self, mname.to_s) invoker end # @param [#to_s] name function name # @param [Array] arg_types function's argument types # @return [Array] # This function returns a list of possible names to lookup. # @note Function names on windows may be decorated if they are using stdcall. See # * http://en.wikipedia.org/wiki/Name_mangling#C_name_decoration_in_Microsoft_Windows # * http://msdn.microsoft.com/en-us/library/zxk0tw93%28v=VS.100%29.aspx # * http://en.wikibooks.org/wiki/X86_Disassembly/Calling_Conventions#STDCALL # Note that decorated names can be overridden via def files. Also note that the # windows api, although using, doesn't have decorated names. def function_names(name, arg_types) result = [name.to_s] if ffi_convention == :stdcall # Get the size of each parameter size = arg_types.inject(0) do |mem, arg| size = arg.size # The size must be a multiple of 4 size += (4 - size) % 4 mem + size end result << "_#{name.to_s}@#{size}" # win32 result << "#{name.to_s}@#{size}" # win64 end result end # @overload attach_variable(mname, cname, type) # @param [#to_s] mname name of ruby method to attach as # @param [#to_s] cname name of C variable to attach # @param [DataConverter, Struct, Symbol, Type] type C variable's type # @example # module Bar # extend FFI::Library # ffi_lib 'my_lib' # attach_variable :c_myvar, :myvar, :long # end # # now callable via Bar.c_myvar # @overload attach_variable(cname, type) # @param [#to_s] mname name of ruby method to attach as # @param [DataConverter, Struct, Symbol, Type] type C variable's type # @example # module Bar # extend FFI::Library # ffi_lib 'my_lib' # attach_variable :myvar, :long # end # # now callable via Bar.myvar # @return [DynamicLibrary::Symbol] # @raise {FFI::NotFoundError} if +cname+ cannot be found in libraries # # Attach C variable +cname+ to this module. def attach_variable(mname, a1, a2 = nil) cname, type = a2 ? [ a1, a2 ] : [ mname.to_s, a1 ] address = nil ffi_libraries.each do |lib| begin address = lib.find_variable(cname.to_s) break unless address.nil? rescue LoadError end end raise FFI::NotFoundError.new(cname, ffi_libraries) if address.nil? || address.null? if type.is_a?(Class) && type < FFI::Struct # If it is a global struct, just attach directly to the pointer s = s = type.new(address) # Assigning twice to suppress unused variable warning self.module_eval <<-code, __FILE__, __LINE__ @@ffi_gvar_#{mname} = s def self.#{mname} @@ffi_gvar_#{mname} end code else sc = Class.new(FFI::Struct) sc.layout :gvar, find_type(type) s = sc.new(address) # # Attach to this module as mname/mname= # self.module_eval <<-code, __FILE__, __LINE__ @@ffi_gvar_#{mname} = s def self.#{mname} @@ffi_gvar_#{mname}[:gvar] end def self.#{mname}=(value) @@ffi_gvar_#{mname}[:gvar] = value end code end address end # @overload callback(name, params, ret) # @param name callback name to add to type map # @param [Array] params array of parameters' types # @param [DataConverter, Struct, Symbol, Type] ret callback return type # @overload callback(params, ret) # @param [Array] params array of parameters' types # @param [DataConverter, Struct, Symbol, Type] ret callback return type # @return [FFI::CallbackInfo] def callback(*args) raise ArgumentError, "wrong number of arguments" if args.length < 2 || args.length > 3 name, params, ret = if args.length == 3 args else [ nil, args[0], args[1] ] end native_params = params.map { |e| find_type(e) } raise ArgumentError, "callbacks cannot have variadic parameters" if native_params.include?(FFI::Type::VARARGS) options = Hash.new options[:convention] = ffi_convention options[:enums] = @ffi_enums if defined?(@ffi_enums) cb = FFI::CallbackInfo.new(find_type(ret), native_params, options) # Add to the symbol -> type map (unless there was no name) unless name.nil? typedef cb, name end cb end # Register or get an already registered type definition. # # To register a new type definition, +old+ should be a {FFI::Type}. +add+ # is in this case the type definition. # # If +old+ is a {DataConverter}, a {Type::Mapped} is returned. # # If +old+ is +:enum+ # * and +add+ is an +Array+, a call to {#enum} is made with +add+ as single parameter; # * in others cases, +info+ is used to create a named enum. # # If +old+ is a key for type map, #typedef get +old+ type definition. # # @param [DataConverter, Symbol, Type] old # @param [Symbol] add # @param [Symbol] info # @return [FFI::Enum, FFI::Type] def typedef(old, add, info=nil) @ffi_typedefs = Hash.new unless defined?(@ffi_typedefs) @ffi_typedefs[add] = if old.kind_of?(FFI::Type) old elsif @ffi_typedefs.has_key?(old) @ffi_typedefs[old] elsif old.is_a?(DataConverter) FFI::Type::Mapped.new(old) elsif old == :enum if add.kind_of?(Array) self.enum(add) else self.enum(info, add) end else FFI.find_type(old) end end private # Generic enum builder # @param [Class] klass can be one of FFI::Enum or FFI::Bitmask # @param args (see #enum or #bitmask) def generic_enum(klass, *args) native_type = args.first.kind_of?(FFI::Type) ? args.shift : nil name, values = if args[0].kind_of?(Symbol) && args[1].kind_of?(Array) [ args[0], args[1] ] elsif args[0].kind_of?(Array) [ nil, args[0] ] else [ nil, args ] end @ffi_enums = FFI::Enums.new unless defined?(@ffi_enums) @ffi_enums << (e = native_type ? klass.new(native_type, values, name) : klass.new(values, name)) # If called with a name, add a typedef alias typedef(e, name) if name e end public # @overload enum(name, values) # Create a named enum. # @example # enum :foo, [:zero, :one, :two] # named enum # @param [Symbol] name name for new enum # @param [Array] values values for enum # @overload enum(*args) # Create an unnamed enum. # @example # enum :zero, :one, :two # unnamed enum # @param args values for enum # @overload enum(values) # Create an unnamed enum. # @example # enum [:zero, :one, :two] # unnamed enum, equivalent to above example # @param [Array] values values for enum # @overload enum(native_type, name, values) # Create a named enum and specify the native type. # @example # enum FFI::Type::UINT64, :foo, [:zero, :one, :two] # named enum # @param [FFI::Type] native_type native type for new enum # @param [Symbol] name name for new enum # @param [Array] values values for enum # @overload enum(native_type, *args) # Create an unnamed enum and specify the native type. # @example # enum FFI::Type::UINT64, :zero, :one, :two # unnamed enum # @param [FFI::Type] native_type native type for new enum # @param args values for enum # @overload enum(native_type, values) # Create an unnamed enum and specify the native type. # @example # enum Type::UINT64, [:zero, :one, :two] # unnamed enum, equivalent to above example # @param [FFI::Type] native_type native type for new enum # @param [Array] values values for enum # @return [FFI::Enum] # Create a new {FFI::Enum}. def enum(*args) generic_enum(FFI::Enum, *args) end # @overload bitmask(name, values) # Create a named bitmask # @example # bitmask :foo, [:red, :green, :blue] # bits 0,1,2 are used # bitmask :foo, [:red, :green, 5, :blue] # bits 0,5,6 are used # @param [Symbol] name for new bitmask # @param [Array] values for new bitmask # @overload bitmask(*args) # Create an unamed bitmask # @example # bm = bitmask :red, :green, :blue # bits 0,1,2 are used # bm = bitmask :red, :green, 5, blue # bits 0,5,6 are used # @param [Symbol, Integer] args values for new bitmask # @overload bitmask(values) # Create an unamed bitmask # @example # bm = bitmask [:red, :green, :blue] # bits 0,1,2 are used # bm = bitmask [:red, :green, 5, blue] # bits 0,5,6 are used # @param [Array] values for new bitmask # @overload bitmask(native_type, name, values) # Create a named enum and specify the native type. # @example # bitmask FFI::Type::UINT64, :foo, [:red, :green, :blue] # @param [FFI::Type] native_type native type for new bitmask # @param [Symbol] name for new bitmask # @param [Array] values for new bitmask # @overload bitmask(native_type, *args) # @example # bitmask FFI::Type::UINT64, :red, :green, :blue # @param [FFI::Type] native_type native type for new bitmask # @param [Symbol, Integer] args values for new bitmask # @overload bitmask(native_type, values) # Create a named enum and specify the native type. # @example # bitmask FFI::Type::UINT64, [:red, :green, :blue] # @param [FFI::Type] native_type native type for new bitmask # @param [Array] values for new bitmask # @return [FFI::Bitmask] # Create a new FFI::Bitmask def bitmask(*args) generic_enum(FFI::Bitmask, *args) end # @param name # @return [FFI::Enum] # Find an enum by name. def enum_type(name) @ffi_enums.find(name) if defined?(@ffi_enums) end # @param symbol # @return [FFI::Enum] # Find an enum by a symbol it contains. def enum_value(symbol) @ffi_enums.__map_symbol(symbol) end # @param [DataConverter, Type, Struct, Symbol] t type to find # @return [Type] # Find a type definition. def find_type(t) if t.kind_of?(Type) t elsif defined?(@ffi_typedefs) && @ffi_typedefs.has_key?(t) @ffi_typedefs[t] elsif t.is_a?(Class) && t < Struct Type::POINTER elsif t.is_a?(DataConverter) # Add a typedef so next time the converter is used, it hits the cache typedef Type::Mapped.new(t), t end || FFI.find_type(t) end end end