gecko/toolkit/components/osfile/osfile_shared_allthreads.jsm
Kyle Huey 1482122303 Bug 798491: Add an option to stick all chrome JSMs/JS components in the same compartment. r=mrbkap,philikon
--HG--
extra : rebase_source : 98337b6a8c07d05e8c961a452dd05a7d75c3c60b
2012-10-31 09:13:28 -07:00

888 lines
27 KiB
JavaScript

/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this file,
* You can obtain one at http://mozilla.org/MPL/2.0/. */
{
if (typeof Components != "undefined") {
this.EXPORTED_SYMBOLS = ["OS"];
}
(function(exports) {
"use strict";
/*
* This block defines |OS.Shared.Type|. However, |OS| can exist already
* (in particular, if this code is executed in a worker thread, it is
* defined).
*/
if (!exports.OS) {
exports.OS = {};
}
if (!exports.OS.Shared) {
exports.OS.Shared = {};
}
if (exports.OS.Shared.Type) {
return; // Avoid double-initialization
}
// Import components after having initialized |exports.OS|, to ensure
// that everybody uses the same definition of |OS|.
if (typeof Components != "undefined") {
Components.utils.import("resource://gre/modules/ctypes.jsm");
Components.classes["@mozilla.org/net/osfileconstantsservice;1"].
getService(Components.interfaces.nsIOSFileConstantsService).init();
}
// Define a lazy getter for a property
let defineLazyGetter = function defineLazyGetter(object, name, getter) {
Object.defineProperty(object, name, {
configurable: true,
get: function lazy() {
delete this[name];
let value = getter.call(this);
Object.defineProperty(object, name, {
value: value
});
return value;
}
});
};
exports.OS.Shared.defineLazyGetter = defineLazyGetter;
/**
* A variable controlling whether we should printout logs.
*/
exports.OS.Shared.DEBUG = false;
let LOG;
if (typeof console != "undefined" && console.log) {
LOG = console.log.bind(console, "OS");
} else {
LOG = function() {
let text = "OS";
for (let i = 0; i < arguments.length; ++i) {
text += (" " + arguments[i]);
}
dump(text + "\n");
};
}
exports.OS.Shared.LOG = LOG;
/**
* An OS error.
*
* This class is provided mostly for type-matching. If you need more
* details about an error, you should use the platform-specific error
* codes provided by subclasses of |OS.Shared.Error|.
*
* @param {string} operation The operation that failed.
*
* @constructor
*/
function OSError(operation) {
Error.call(this);
this.operation = operation;
}
exports.OS.Shared.Error = OSError;
/**
* Abstraction above js-ctypes types.
*
* Use values of this type to register FFI functions. In addition to the
* usual features of js-ctypes, values of this type perform the necessary
* transformations to ensure that C errors are handled nicely, to connect
* resources with their finalizer, etc.
*
* @param {string} name The name of the type. Must be unique.
* @param {CType} implementation The js-ctypes implementation of the type.
*
* @constructor
*/
function Type(name, implementation) {
if (!(typeof name == "string")) {
throw new TypeError("Type expects as first argument a name, got: "
+ name);
}
if (!(implementation instanceof ctypes.CType)) {
throw new TypeError("Type expects as second argument a ctypes.CType"+
", got: " + implementation);
}
Object.defineProperty(this, "name", { value: name });
Object.defineProperty(this, "implementation", { value: implementation });
}
Type.prototype = {
/**
* Serialize a value of |this| |Type| into a format that can
* be transmitted as a message (not necessarily a string).
*
* In the default implementation, the method returns the
* value unchanged.
*/
toMsg: function default_toMsg(value) {
return value;
},
/**
* Deserialize a message to a value of |this| |Type|.
*
* In the default implementation, the method returns the
* message unchanged.
*/
fromMsg: function default_fromMsg(msg) {
return msg;
},
/**
* Import a value from C.
*
* In this default implementation, return the value
* unchanged.
*/
importFromC: function default_importFromC(value) {
return value;
},
/**
* A pointer/array used to pass data to the foreign function.
*/
get in_ptr() {
delete this.in_ptr;
let ptr_t = new PtrType(
"[in] " + this.name + "*",
this.implementation.ptr,
this);
Object.defineProperty(this, "in_ptr",
{
get: function() {
return ptr_t;
}
});
return ptr_t;
},
/**
* A pointer/array used to receive data from the foreign function.
*/
get out_ptr() {
delete this.out_ptr;
let ptr_t = new PtrType(
"[out] " + this.name + "*",
this.implementation.ptr,
this);
Object.defineProperty(this, "out_ptr",
{
get: function() {
return ptr_t;
}
});
return ptr_t;
},
/**
* A pointer/array used to both pass data to the foreign function
* and receive data from the foreign function.
*
* Whenever possible, prefer using |in_ptr| or |out_ptr|, which
* are generally faster.
*/
get inout_ptr() {
delete this.inout_ptr;
let ptr_t = new PtrType(
"[inout] " + this.name + "*",
this.implementation.ptr,
this);
Object.defineProperty(this, "inout_ptr",
{
get: function() {
return ptr_t;
}
});
return ptr_t;
},
/**
* Attach a finalizer to a type.
*/
releaseWith: function releaseWith(finalizer) {
let parent = this;
let type = this.withName("[auto " + this.name + ", " + finalizer + "] ");
type.importFromC = function importFromC(value, operation) {
return ctypes.CDataFinalizer(
parent.importFromC(value, operation),
finalizer);
};
return type;
},
/**
* Return an alias to a type with a different name.
*/
withName: function withName(name) {
return Object.create(this, {name: {value: name}});
},
/**
* Cast a C value to |this| type.
*
* Throw an error if the value cannot be casted.
*/
cast: function cast(value) {
return ctypes.cast(value, this.implementation);
},
/**
* Return the number of bytes in a value of |this| type.
*
* This may not be defined, e.g. for |void_t|, array types
* without length, etc.
*/
get size() {
return this.implementation.size;
}
};
/**
* Utility function used to determine whether an object is a typed array
*/
let isTypedArray = function isTypedArray(obj) {
return typeof obj == "object"
&& "byteOffset" in obj;
};
exports.OS.Shared.isTypedArray = isTypedArray;
/**
* A |Type| of pointers.
*
* @param {string} name The name of this type.
* @param {CType} implementation The type of this pointer.
* @param {Type} targetType The target type.
*/
function PtrType(name, implementation, targetType) {
Type.call(this, name, implementation);
if (targetType == null || !targetType instanceof Type) {
throw new TypeError("targetType must be an instance of Type");
}
/**
* The type of values targeted by this pointer type.
*/
Object.defineProperty(this, "targetType", {
value: targetType
});
}
PtrType.prototype = Object.create(Type.prototype);
/**
* Convert a value to a pointer.
*
* Protocol:
* - |null| returns |null|
* - a string returns |{string: value}|
* - a typed array returns |{ptr: address_of_buffer}|
* - a C array returns |{ptr: address_of_buffer}|
* everything else raises an error
*/
PtrType.prototype.toMsg = function ptr_toMsg(value) {
if (value == null) {
return null;
}
if (typeof value == "string") {
return { string: value };
}
let normalized;
if (isTypedArray(value)) { // Typed array
normalized = Types.uint8_t.in_ptr.implementation(value.buffer);
if (value.byteOffset != 0) {
normalized = exports.OS.Shared.offsetBy(normalized, value.byteOffset);
}
} else if ("addressOfElement" in value) { // C array
normalized = value.addressOfElement(0);
} else if ("isNull" in value) { // C pointer
normalized = value;
} else {
throw new TypeError("Value " + value +
" cannot be converted to a pointer");
}
let cast = Types.uintptr_t.cast(normalized);
return {ptr: cast.value.toString()};
};
/**
* Convert a message back to a pointer.
*/
PtrType.prototype.fromMsg = function ptr_fromMsg(msg) {
if (msg == null) {
return null;
}
if ("string" in msg) {
return msg.string;
}
if ("ptr" in msg) {
let address = ctypes.uintptr_t(msg.ptr);
return this.cast(address);
}
throw new TypeError("Message " + msg.toSource() +
" does not represent a pointer");
};
exports.OS.Shared.Type = Type;
let Types = Type;
/*
* Some values are large integers on 64 bit platforms. Unfortunately,
* in practice, 64 bit integers cannot be manipulated in JS. We
* therefore project them to regular numbers whenever possible.
*/
let projectLargeInt = function projectLargeInt(x) {
return parseInt(x.toString(), 10);
};
let projectLargeUInt = function projectLargeUInt(x) {
return parseInt(x.toString(), 10);
};
let projectValue = function projectValue(x) {
if (!(x instanceof ctypes.CData)) {
return x;
}
if (!("value" in x)) { // Sanity check
throw new TypeError("Number " + x.toSource() + " has no field |value|");
}
return x.value;
};
function projector(type, signed) {
if (exports.OS.Shared.DEBUG) {
LOG("Determining best projection for", type,
"(size: ", type.size, ")", signed?"signed":"unsigned");
}
if (type instanceof Type) {
type = type.implementation;
}
if (!type.size) {
throw new TypeError("Argument is not a proper C type");
}
// Determine if type is projected to Int64/Uint64
if (type.size == 8 // Usual case
// The following cases have special treatment in js-ctypes
// Regardless of their size, the value getter returns
// a Int64/Uint64
|| type == ctypes.size_t // Special cases
|| type == ctypes.ssize_t
|| type == ctypes.intptr_t
|| type == ctypes.uintptr_t
|| type == ctypes.off_t){
if (signed) {
if (exports.OS.Shared.DEBUG) {
LOG("Projected as a large signed integer");
}
return projectLargeInt;
} else {
if (exports.OS.Shared.DEBUG) {
LOG("Projected as a large unsigned integer");
}
return projectLargeUInt;
}
}
if (exports.OS.Shared.DEBUG) {
LOG("Projected as a regular number");
}
return projectValue;
};
exports.OS.Shared.projectValue = projectValue;
/**
* Get the appropriate type for an unsigned int of the given size.
*
* This function is useful to define types such as |mode_t| whose
* actual width depends on the OS/platform.
*
* @param {number} size The number of bytes requested.
*/
Types.uintn_t = function uintn_t(size) {
switch (size) {
case 1: return Types.uint8_t;
case 2: return Types.uint16_t;
case 4: return Types.uint32_t;
case 8: return Types.uint64_t;
default:
throw new Error("Cannot represent unsigned integers of " + size + " bytes");
}
};
/**
* Get the appropriate type for an signed int of the given size.
*
* This function is useful to define types such as |mode_t| whose
* actual width depends on the OS/platform.
*
* @param {number} size The number of bytes requested.
*/
Types.intn_t = function intn_t(size) {
switch (size) {
case 1: return Types.int8_t;
case 2: return Types.int16_t;
case 4: return Types.int32_t;
case 8: return Types.int64_t;
default:
throw new Error("Cannot represent integers of " + size + " bytes");
}
};
/**
* Actual implementation of common C types.
*/
/**
* The void value.
*/
Types.void_t =
new Type("void",
ctypes.void_t);
/**
* Shortcut for |void*|.
*/
Types.voidptr_t =
new PtrType("void*",
ctypes.voidptr_t,
Types.void_t);
// void* is a special case as we can cast any pointer to/from it
// so we have to shortcut |in_ptr|/|out_ptr|/|inout_ptr| and
// ensure that js-ctypes' casting mechanism is invoked directly
["in_ptr", "out_ptr", "inout_ptr"].forEach(function(key) {
Object.defineProperty(Types.void_t, key,
{
value: Types.voidptr_t
});
});
/**
* A Type of integers.
*
* @param {string} name The name of this type.
* @param {CType} implementation The underlying js-ctypes implementation.
* @param {bool} signed |true| if this is a type of signed integers,
* |false| otherwise.
*
* @constructor
*/
function IntType(name, implementation, signed) {
Type.call(this, name, implementation);
this.importFromC = projector(implementation, signed);
this.project = this.importFromC;
};
IntType.prototype = Object.create(Type.prototype);
IntType.prototype.toMsg = function toMsg(value) {
if (typeof value == "number") {
return value;
}
return this.project(value);
};
/**
* A C char (one byte)
*/
Types.char =
new Type("char",
ctypes.char);
/**
* A C wide char (two bytes)
*/
Types.jschar =
new Type("jschar",
ctypes.jschar);
/**
* Base string types.
*/
Types.cstring = Types.char.in_ptr.withName("[in] C string");
Types.wstring = Types.jschar.in_ptr.withName("[in] wide string");
Types.out_cstring = Types.char.out_ptr.withName("[out] C string");
Types.out_wstring = Types.jschar.out_ptr.withName("[out] wide string");
/**
* A C integer (8-bits).
*/
Types.int8_t =
new IntType("int8_t", ctypes.int8_t, true);
Types.uint8_t =
new IntType("uint8_t", ctypes.uint8_t, false);
/**
* A C integer (16-bits).
*
* Also known as WORD under Windows.
*/
Types.int16_t =
new IntType("int16_t", ctypes.int16_t, true);
Types.uint16_t =
new IntType("uint16_t", ctypes.uint16_t, false);
/**
* A C integer (32-bits).
*
* Also known as DWORD under Windows.
*/
Types.int32_t =
new IntType("int32_t", ctypes.int32_t, true);
Types.uint32_t =
new IntType("uint32_t", ctypes.uint32_t, false);
/**
* A C integer (64-bits).
*/
Types.int64_t =
new IntType("int64_t", ctypes.int64_t, true);
Types.uint64_t =
new IntType("uint64_t", ctypes.uint64_t, false);
/**
* A C integer
*
* Size depends on the platform.
*/
Types.int = Types.intn_t(ctypes.int.size).
withName("int");
Types.unsigned_int = Types.intn_t(ctypes.unsigned_int.size).
withName("unsigned int");
/**
* A C long integer.
*
* Size depends on the platform.
*/
Types.long =
Types.intn_t(ctypes.long.size).withName("long");
Types.unsigned_long =
Types.intn_t(ctypes.unsigned_long.size).withName("unsigned long");
/**
* An unsigned integer with the same size as a pointer.
*
* Used to cast a pointer to an integer, whenever necessary.
*/
Types.uintptr_t =
Types.uintn_t(ctypes.uintptr_t.size).withName("uintptr_t");
/**
* A boolean.
* Implemented as a C integer.
*/
Types.bool = Types.int.withName("bool");
Types.bool.importFromC = function projectBool(x) {
return !!(x.value);
};
/**
* A user identifier.
*
* Implemented as a C integer.
*/
Types.uid_t =
Types.int.withName("uid_t");
/**
* A group identifier.
*
* Implemented as a C integer.
*/
Types.gid_t =
Types.int.withName("gid_t");
/**
* An offset (positive or negative).
*
* Implemented as a C integer.
*/
Types.off_t =
new IntType("off_t", ctypes.off_t, true);
/**
* A size (positive).
*
* Implemented as a C size_t.
*/
Types.size_t =
new IntType("size_t", ctypes.size_t, false);
/**
* An offset (positive or negative).
* Implemented as a C integer.
*/
Types.ssize_t =
new IntType("ssize_t", ctypes.ssize_t, true);
/**
* Encoding/decoding strings
*/
Types.uencoder =
new Type("uencoder", ctypes.StructType("uencoder"));
Types.udecoder =
new Type("udecoder", ctypes.StructType("udecoder"));
/**
* Utility class, used to build a |struct| type
* from a set of field names, types and offsets.
*
* @param {string} name The name of the |struct| type.
* @param {number} size The total size of the |struct| type in bytes.
*/
function HollowStructure(name, size) {
if (!name) {
throw new TypeError("HollowStructure expects a name");
}
if (!size || size < 0) {
throw new TypeError("HollowStructure expects a (positive) size");
}
// A mapping from offsets in the struct to name/type pairs
// (or nothing if no field starts at that offset).
this.offset_to_field_info = [];
// The name of the struct
this.name = name;
// The size of the struct, in bytes
this.size = size;
// The number of paddings inserted so far.
// Used to give distinct names to padding fields.
this._paddings = 0;
}
HollowStructure.prototype = {
/**
* Add a field at a given offset.
*
* @param {number} offset The offset at which to insert the field.
* @param {string} name The name of the field.
* @param {CType|Type} type The type of the field.
*/
add_field_at: function add_field_at(offset, name, type) {
if (offset == null) {
throw new TypeError("add_field_at requires a non-null offset");
}
if (!name) {
throw new TypeError("add_field_at requires a non-null name");
}
if (!type) {
throw new TypeError("add_field_at requires a non-null type");
}
if (type instanceof Type) {
type = type.implementation;
}
if (this.offset_to_field_info[offset]) {
throw new Error("HollowStructure " + this.name +
" already has a field at offset " + offset);
}
if (offset + type.size > this.size) {
throw new Error("HollowStructure " + this.name +
" cannot place a value of type " + type +
" at offset " + offset +
" without exceeding its size of " + this.size);
}
let field = {name: name, type:type};
this.offset_to_field_info[offset] = field;
},
/**
* Create a pseudo-field that will only serve as padding.
*
* @param {number} size The number of bytes in the field.
* @return {Object} An association field-name => field-type,
* as expected by |ctypes.StructType|.
*/
_makePaddingField: function makePaddingField(size) {
let field = ({});
field["padding_" + this._paddings] =
ctypes.ArrayType(ctypes.uint8_t, size);
this._paddings++;
return field;
},
/**
* Convert this |HollowStructure| into a |Type|.
*/
getType: function getType() {
// Contents of the structure, in the format expected
// by ctypes.StructType.
let struct = [];
let i = 0;
while (i < this.size) {
let currentField = this.offset_to_field_info[i];
if (!currentField) {
// No field was specified at this offset, we need to
// introduce some padding.
// Firstly, determine how many bytes of padding
let padding_length = 1;
while (i + padding_length < this.size
&& !this.offset_to_field_info[i + padding_length]) {
++padding_length;
}
// Then add the padding
struct.push(this._makePaddingField(padding_length));
// And proceed
i += padding_length;
} else {
// We have a field at this offset.
// Firstly, ensure that we do not have two overlapping fields
for (let j = 1; j < currentField.type.size; ++j) {
let candidateField = this.offset_to_field_info[i + j];
if (candidateField) {
throw new Error("Fields " + currentField.name +
" and " + candidateField.name +
" overlap at position " + (i + j));
}
}
// Then add the field
let field = ({});
field[currentField.name] = currentField.type;
struct.push(field);
// And proceed
i += currentField.type.size;
}
}
let result = new Type(this.name, ctypes.StructType(this.name, struct));
if (result.implementation.size != this.size) {
throw new Error("Wrong size for type " + this.name +
": expected " + this.size +
", found " + result.implementation.size +
" (" + result.implementation.toSource() + ")");
}
return result;
}
};
exports.OS.Shared.HollowStructure = HollowStructure;
/**
* Declare a function through js-ctypes
*
* @param {ctypes.library} lib The ctypes library holding the function.
* @param {string} symbol The name of the function, as defined in the
* library.
* @param {ctypes.abi} abi The abi to use, or |null| for default.
* @param {Type} returnType The type of values returned by the function.
* @param {...Type} argTypes The type of arguments to the function.
*
* @return null if the function could not be defined (generally because
* it does not exist), or a JavaScript wrapper performing the call to C
* and any type conversion required.
*/// Note: Future versions will use a different implementation of this
// function on the main thread, osfile worker thread and regular worker
// thread
let declareFFI = function declareFFI(lib, symbol, abi,
returnType /*, argTypes ...*/) {
if (exports.OS.Shared.DEBUG) {
LOG("Attempting to declare FFI ", symbol);
}
// We guard agressively, to avoid any late surprise
if (typeof symbol != "string") {
throw new TypeError("declareFFI expects as first argument a string");
}
abi = abi || ctypes.default_abi;
if (Object.prototype.toString.call(abi) != "[object CABI]") {
// Note: This is the only known manner of checking whether an object
// is an abi.
throw new TypeError("declareFFI expects as second argument an abi or null");
}
if (!returnType.importFromC) {
throw new TypeError("declareFFI expects as third argument an instance of Type");
}
let signature = [symbol, abi];
let argtypes = [];
for (let i = 3; i < arguments.length; ++i) {
let current = arguments[i];
if (!current) {
throw new TypeError("Missing type for argument " + ( i - 3 ) +
" of symbol " + symbol);
}
if (!current.implementation) {
throw new TypeError("Missing implementation for argument " + (i - 3)
+ " of symbol " + symbol
+ " ( " + current.name + " )" );
}
signature.push(current.implementation);
}
try {
let fun = lib.declare.apply(lib, signature);
let result = function ffi(/*arguments*/) {
let result = fun.apply(fun, arguments);
return returnType.importFromC(result, symbol);
};
if (exports.OS.Shared.DEBUG) {
result.fun = fun; // Also return the raw FFI function.
}
if (exports.OS.Shared.DEBUG) {
LOG("Function", symbol, "declared");
}
return result;
} catch (x) {
// Note: Not being able to declare a function is normal.
// Some functions are OS (or OS version)-specific.
if (exports.OS.Shared.DEBUG) {
LOG("Could not declare function " + symbol, x);
}
return null;
}
};
exports.OS.Shared.declareFFI = declareFFI;
// A bogus array type used to perform pointer arithmetics
let gOffsetByType;
/**
* Advance a pointer by a number of items.
*
* This method implements adding an integer to a pointer in C.
*
* Example:
* // ptr is a uint16_t*,
* offsetBy(ptr, 3)
* // returns a uint16_t* with the address ptr + 3 * 2 bytes
*
* @param {C pointer} pointer The start pointer.
* @param {number} length The number of items to advance. Must not be
* negative.
*
* @return {C pointer} |pointer| advanced by |length| items
*/
exports.OS.Shared.offsetBy =
function offsetBy(pointer, length) {
if (length === undefined || length < 0) {
throw new TypeError("offsetBy expects a positive number");
}
if (!("isNull" in pointer)) {
throw new TypeError("offsetBy expects a pointer");
}
if (length == 0) {
return pointer;
}
let type = pointer.constructor;
let size = type.targetType.size;
if (size == 0 || size == null) {
throw new TypeError("offsetBy cannot be applied to a pointer without size");
}
let bytes = length * size;
if (!gOffsetByType || gOffsetByType.size <= bytes) {
gOffsetByType = ctypes.uint8_t.array(bytes * 2);
}
let addr = ctypes.cast(pointer, gOffsetByType.ptr).
contents.addressOfElement(bytes);
return ctypes.cast(addr, type);
};
// Encodings
})(this);
}