module FFI CURRENT_PROCESS = USE_THIS_PROCESS_AS_LIBRARY = Object.new module Library CURRENT_PROCESS = FFI::CURRENT_PROCESS LIBC = FFI::Platform::LIBC def ffi_lib(*names) 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 { |n| [ n, FFI.map_library_name(n) ].uniq }.flatten.compact lib = nil errors = {} libnames.each do |libname| begin lib = FFI::DynamicLibrary.open(libname, lib_flags) break if lib rescue Exception => ex errors[libname] = ex end end if lib.nil? raise LoadError.new(errors.values.join('. ')) end # return the found lib lib end end @ffi_libs = ffi_libs end def ffi_convention(convention) @ffi_convention = convention end def ffi_libraries raise LoadError.new("no library specified") if !defined?(@ffi_libs) || @ffi_libs.empty? @ffi_libs end FlagsMap = { :global => DynamicLibrary::RTLD_GLOBAL, :local => DynamicLibrary::RTLD_LOCAL, :lazy => DynamicLibrary::RTLD_LAZY, :now => DynamicLibrary::RTLD_NOW } def ffi_lib_flags(*flags) lib_flags = flags.inject(0) { |result, f| result | FlagsMap[f] } if (lib_flags & (DynamicLibrary::RTLD_LAZY | DynamicLibrary::RTLD_NOW)) == 0 lib_flags |= DynamicLibrary::RTLD_LAZY end if (lib_flags & (DynamicLibrary::RTLD_GLOBAL | DynamicLibrary::RTLD_LOCAL) == 0) lib_flags |= DynamicLibrary::RTLD_LOCAL end @ffi_lib_flags = lib_flags end ## # Attach C function +name+ to this module. # # If you want to provide an alternate name for the module function, supply # it after the +name+, otherwise the C function name will be used.# # # After the +name+, the C function argument types are provided as an Array. # # The C function return type is provided last. def attach_function(mname, a2, a3, a4=nil, a5 = nil) 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.map! { |e| find_type(e) } options = Hash.new options[:convention] = defined?(@ffi_convention) ? @ffi_convention : :default options[:type_map] = defined?(@ffi_typedefs) ? @ffi_typedefs : nil options[:enums] = defined?(@ffi_enum_map) ? @ffi_enum_map : nil options.merge!(opts) if opts.is_a?(Hash) # Try to locate the function in any of the libraries invokers = [] load_error = nil ffi_libraries.each do |lib| begin invokers << FFI.create_invoker(lib, cname.to_s, arg_types, find_type(ret_type), options) rescue LoadError => ex load_error = ex end if invokers.empty? end invoker = invokers.compact.shift raise load_error if load_error && invoker.nil? #raise FFI::NotFoundError.new(cname.to_s, *libraries) unless invoker invoker.attach(self, mname.to_s) invoker # Return a version that can be called via #call end 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 = type.new(address) 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 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 options = Hash.new options[:convention] = defined?(@ffi_convention) ? @ffi_convention : :default options[:enums] = @ffi_enums if defined?(@ffi_enums) cb = FFI::CallbackInfo.new(find_type(ret), params.map { |e| find_type(e) }, options) # Add to the symbol -> type map (unless there was no name) unless name.nil? __cb_map[name] = cb # Also put in the type map, so it can be used for typedefs __type_map[name] = cb end cb end def __type_map defined?(@ffi_typedefs) ? @ffi_typedefs : (@ffi_typedefs = Hash.new) end def __cb_map defined?(@ffi_callbacks) ? @ffi_callbacks: (@ffi_callbacks = Hash.new) end def typedef(current, add, info=nil) __type_map[add] = if current.kind_of?(FFI::Type) current else __type_map[current] || FFI.find_type(current) end end def enum(*args) # # enum can be called as: # enum :zero, :one, :two # unnamed enum # enum [ :zero, :one, :two ] # equivalent to above # enum :foo, [ :zero, :one, :two ] create an enum named :foo # 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 = FFI::Enum.new(values, name)) @ffi_enum_map = Hash.new unless defined?(@ffi_enum_map) # append all the enum values to a global :name => value map @ffi_enum_map.merge!(e.symbol_map) # If called as enum :foo, [ :zero, :one, :two ], add a typedef alias typedef(e, name) if name e end def enum_type(name) @ffi_enums.find(name) if defined?(@ffi_enums) end def enum_value(symbol) @ffi_enums.__map_symbol(symbol) end def find_type(name) if name.kind_of?(FFI::Type) name elsif name.is_a?(Class) && name < FFI::Struct FFI::NativeType::POINTER elsif defined?(@ffi_typedefs) && @ffi_typedefs.has_key?(name) @ffi_typedefs[name] elsif defined?(@ffi_callbacks) && @ffi_callbacks.has_key?(name) @ffi_callbacks[name] end || FFI.find_type(name) end end end