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INTRODUCTION The term "decompiler" is most commonly applied to a program which translates Executable programs (the output from a Compiler ) into Source Code in a (relatively) High Level Language (which when compiled will produce an executable whose behavior is the same as the original executable program). By comparison, a Disassembler translates an executable program into Assembly Language (an assembler could be used to assemble it back into an executable program). Decompilation is the act of using a decompiler, although the term can also refer to the decompiled output. It can be used for the recovery of lost source code, and is also useful in some cases for ) often include extensive Metadata and high-level features that make decompilation quite feasible. Machine Language has typically much less metadata, and is therefore much harder to decompile. Some compilers and post compilation tools produce Obfuscated Code (that is, attempt to produce output that is very difficult to decompile). This is done to make it more difficult to Reverse Engineer the executable. PHASES Decompilers can be thought of as composed of a series of phases each of which contributes specific aspects of the overall decompilation process. Loader The first decompilation phase is the loader, which parses the input machine code program's binary file format. The loader should be able to discover basic facts about the input program, such as the architecture (Pentium, PowerPC, etc), and the entry point. In many cases, it should be able to find the equivalent of the main function of a C program, which is the start of the user written code. This excludes the runtime initialisation code, which should not be decompiled if possible.Disassembly The next logical phase is the disassembly of machine code instructions into a machine independent intermediate representation (IR). For example, the Pentium machine instruction mov eax, {Link without Title} might be translated to the IR eax := m {Link without Title} ; Idioms Idiomatic machine code sequences are sequences of code whose combined semantics is not immediately apparent from the instructions' individual semantics. Either as part of the disassembly phase, or as part of later analyses, these idiomatic sequences need to be translated into known equivalent IR. For example, the X86 Assembly Code : cdq eax ; edx is set to the sign-extension of eax xor eax, edx sub eax, edx could be translated to eax := abs(eax); Some idiomatic sequences are machine independent; some involve only one instruction. For example, xor eax, eax clears the eax register (sets it to zero). This can be implemented with a machine independent simplification rule, such as a xor a = 0.In general, it is best to delay detection of idiomatic sequences if possible, to later stages that are less affected by instruction ordering. For example, the instruction scheduling phase of a compiler may insert other instructions into an idiomatic sequence, or change the ordering of instructions in the sequence. A pattern matching process in the disassembly phase would probably not recognize the altered pattern. Later phases group instruction expressions into more complex epressions, and modify them into a canonical (standardized) form, making it more likely that even the altered idiom will match a higher level pattern later in the decompilation. Program analysis Various program analyses can be applied to the IR. In particular, expression propagation combines the semantics of several instructions into more complex expressions. For example, mov eax, {Link without Title} add eax, {Link without Title} sub {Link without Title} ,eax could result in the following IR after expression propagation: m := m[ebx+12 - (m + m[ebx+8 ); The resulting expression is more like high level language, and has also eliminated the use of the machine register eax . Later analyses may eliminate the ebx register.Type analysis A good machine code decompiler will perform type analysis. Here, the way registers or memory locations are used result in constraints on the possible type of the location. For example, an and instruction implies that the operand is an integer; programs do not use such an operation on floating point values (except in special library code) or on pointers. An add instruction results in three constraints, since the operands may be both integer, or one integer and one pointer (with integer and pointer results respectively; the third constraint comes from the ordering of the two operands when the types are different).Various high level expressions can be recognized which trigger recognition of structures or arrays. However, it is difficult to distinguish many of the possibilities, because of the freedom that machine code or even some high level languages such as C allow with casts and pointer arithmetic. The example from the previous section could result in the following high level code:
struct T1 { int v0004; int v0008; int v000C; }; ebx->v000C -= ebx->v0004 + ebx->v0008; Structuring The penultimate decompilation phase involves structuring of the IR into higher level constructs such as while loops and if/then/else conditional statements. For example, the machine codexor eax, eax l0002: or ebx, ebx jge l0003 add eax, {Link without Title} mov ebx, {Link without Title} jmp l0002 l0003: mov {Link without Title} ,eax could be translated into: eax = 0; while (ebx < 0) { eax += ebx->v0000; ebx = ebx->v0004; } v10040000 = eax; Unstructured code is more difficult to translate into structured code than already structured code. Solutions include replicating some code, or adding boolean variables. See chapter 6 of C. Cifuentes. ''Reverse Compilation Techniques''. PhD thesis, Queensland University of Technology, 1994. (available as compressed postscript ). Code generation The final phase is the generation of the high level code in the back end of the decompiler. Just as a compiler may have several back ends for generating machine code for different architectures, a decompiler may have several back ends for generating high level code in different high level languages. Just before code generation, it may be desirable to allow an interactive editing of the IR, perhaps using some form of Graphical User Interface . This would allow the user to enter comments, and non-generic variable and function names. However, these are almost as easily entered in a post decompilation edit. The user may want to change structural aspects, such as converting a while loop to a for loop. These are less readily modified with a simple text editor, although source code refactoring tools may assist with this process. The user may need to enter information that failed to be identified during the type analysis phase, e.g. modifying a memory expression to an array or structure expression. Finally, incorrect IR may need to be corrected, or changes made to cause the output code to be more readable.LEGALITY The majority of computer programs are covered by Copyright laws. Although the precise scope of what is covered by copyright differs from region to region, copyright law generally provides the author (the programmer(s) or employer) with a collection of exclusive rights to the program. These rights include the right to make copies, including copies made into the computer's RAM . Since the decompilation process involves making multiple such copies, it is generally prohibited without the authorization of the copyright holder. However, because decompilation is often a necessary step in achieving software Interoperability , copyright laws in both the United States and Europe permit decompilation to a limited extent. In the United States, the copyright Fair Use defense has been successfully invoked in decompilation cases. For example, in '' Sega v. Accolade '', the court held that Accolade could lawfully engage in decompilation in order to circumvent the software locking mechanism used by Sega's game consoles The Legality of Decompilation In Europe, the 1991 Software Directive explicitly provides for a right to decompile in order to achieve interoperability. The result of a heated debate between, on the one side, software protectionists, and, on the other, academics as well as independent software developers, Article 6 permits decompilation only if a number of conditions are met:
In addition, Article 6 prescribes that the information obtained through decompilation may not be used for other purposes and that it may not be given to others. Overall, the decompilation right provided by Article 6 is interesting, as it seems to support the second interpretation. REFERENCES SEE ALSO
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