352 lines
7.7 KiB
Markdown
352 lines
7.7 KiB
Markdown
---
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name: binary-analysis-patterns
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description: Master binary analysis patterns including disassembly, decompilation, control flow analysis, and code pattern recognition. Use when analyzing executables, understanding compiled code, or performing static analysis on binaries.
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---
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# Binary Analysis Patterns
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Comprehensive patterns and techniques for analyzing compiled binaries, understanding assembly code, and reconstructing program logic.
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## When to Use This Skill
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- Reverse-engineering an unknown executable to understand its behavior
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- Analyzing malware or obfuscated binaries with Ghidra / IDA Pro / Binary Ninja
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- Recognizing common assembly idioms (function prologues, switch tables, vtable dispatch)
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- Reconstructing high-level control flow from compiled code
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- Identifying compiler-introduced patterns (stack canaries, PIC trampolines)
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## Detailed section: Disassembly Fundamentals
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Originally a 2047-byte section in this SKILL.md. Moved to `references/details.md` to fit Codex's 8 KB skill body cap.
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## Control Flow Patterns
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### Conditional Branches
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```asm
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; if (a == b)
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cmp eax, ebx
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jne skip_block
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; ... if body ...
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skip_block:
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; if (a < b) - signed
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cmp eax, ebx
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jge skip_block ; Jump if greater or equal
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; ... if body ...
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skip_block:
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; if (a < b) - unsigned
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cmp eax, ebx
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jae skip_block ; Jump if above or equal
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; ... if body ...
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skip_block:
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```
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### Loop Patterns
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```asm
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; for (int i = 0; i < n; i++)
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xor ecx, ecx ; i = 0
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loop_start:
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cmp ecx, [n] ; i < n
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jge loop_end
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; ... loop body ...
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inc ecx ; i++
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jmp loop_start
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loop_end:
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; while (condition)
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jmp loop_check
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loop_body:
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; ... body ...
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loop_check:
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cmp eax, ebx
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jl loop_body
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; do-while
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loop_body:
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; ... body ...
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cmp eax, ebx
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jl loop_body
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```
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### Switch Statement Patterns
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```asm
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; Jump table pattern
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mov eax, [switch_var]
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cmp eax, max_case
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ja default_case
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jmp [jump_table + eax*8]
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; Sequential comparison (small switch)
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cmp eax, 1
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je case_1
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cmp eax, 2
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je case_2
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cmp eax, 3
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je case_3
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jmp default_case
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```
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## Data Structure Patterns
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### Array Access
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```asm
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; array[i] - 4-byte elements
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mov eax, [rbx + rcx*4] ; rbx=base, rcx=index
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; array[i] - 8-byte elements
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mov rax, [rbx + rcx*8]
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; Multi-dimensional array[i][j]
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; arr[i][j] = base + (i * cols + j) * element_size
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imul eax, [cols]
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add eax, [j]
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mov edx, [rbx + rax*4]
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```
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### Structure Access
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```c
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struct Example {
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int a; // offset 0
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char b; // offset 4
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// padding // offset 5-7
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long c; // offset 8
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short d; // offset 16
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};
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```
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```asm
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; Accessing struct fields
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mov rdi, [struct_ptr]
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mov eax, [rdi] ; s->a (offset 0)
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movzx eax, byte [rdi+4] ; s->b (offset 4)
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mov rax, [rdi+8] ; s->c (offset 8)
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movzx eax, word [rdi+16] ; s->d (offset 16)
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```
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### Linked List Traversal
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```asm
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; while (node != NULL)
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list_loop:
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test rdi, rdi ; node == NULL?
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jz list_done
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; ... process node ...
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mov rdi, [rdi+8] ; node = node->next (assuming next at offset 8)
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jmp list_loop
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list_done:
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```
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## Common Code Patterns
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### String Operations
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```asm
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; strlen pattern
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xor ecx, ecx
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strlen_loop:
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cmp byte [rdi + rcx], 0
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je strlen_done
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inc ecx
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jmp strlen_loop
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strlen_done:
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; ecx contains length
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; strcpy pattern
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strcpy_loop:
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mov al, [rsi]
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mov [rdi], al
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test al, al
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jz strcpy_done
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inc rsi
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inc rdi
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jmp strcpy_loop
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strcpy_done:
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; memcpy using rep movsb
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mov rdi, dest
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mov rsi, src
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mov rcx, count
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rep movsb
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```
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### Arithmetic Patterns
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```asm
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; Multiplication by constant
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; x * 3
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lea eax, [rax + rax*2]
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; x * 5
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lea eax, [rax + rax*4]
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; x * 10
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lea eax, [rax + rax*4] ; x * 5
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add eax, eax ; * 2
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; Division by power of 2 (signed)
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mov eax, [x]
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cdq ; Sign extend to EDX:EAX
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and edx, 7 ; For divide by 8
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add eax, edx ; Adjust for negative
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sar eax, 3 ; Arithmetic shift right
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; Modulo power of 2
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and eax, 7 ; x % 8
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```
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### Bit Manipulation
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```asm
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; Test specific bit
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test eax, 0x80 ; Test bit 7
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jnz bit_set
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; Set bit
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or eax, 0x10 ; Set bit 4
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; Clear bit
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and eax, ~0x10 ; Clear bit 4
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; Toggle bit
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xor eax, 0x10 ; Toggle bit 4
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; Count leading zeros
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bsr eax, ecx ; Bit scan reverse
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xor eax, 31 ; Convert to leading zeros
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; Population count (popcnt)
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popcnt eax, ecx ; Count set bits
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```
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## Decompilation Patterns
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### Variable Recovery
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```asm
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; Local variable at rbp-8
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mov qword [rbp-8], rax ; Store to local
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mov rax, [rbp-8] ; Load from local
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; Stack-allocated array
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lea rax, [rbp-0x40] ; Array starts at rbp-0x40
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mov [rax], edx ; array[0] = value
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mov [rax+4], ecx ; array[1] = value
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```
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### Function Signature Recovery
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```asm
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; Identify parameters by register usage
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func:
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; rdi used as first param (System V)
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mov [rbp-8], rdi ; Save param to local
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; rsi used as second param
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mov [rbp-16], rsi
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; Identify return by RAX at end
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mov rax, [result]
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ret
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```
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### Type Recovery
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```asm
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; 1-byte operations suggest char/bool
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movzx eax, byte [rdi] ; Zero-extend byte
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movsx eax, byte [rdi] ; Sign-extend byte
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; 2-byte operations suggest short
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movzx eax, word [rdi]
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movsx eax, word [rdi]
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; 4-byte operations suggest int/float
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mov eax, [rdi]
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movss xmm0, [rdi] ; Float
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; 8-byte operations suggest long/double/pointer
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mov rax, [rdi]
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movsd xmm0, [rdi] ; Double
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```
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## Ghidra Analysis Tips
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### Improving Decompilation
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```java
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// In Ghidra scripting
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// Fix function signature
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Function func = getFunctionAt(toAddr(0x401000));
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func.setReturnType(IntegerDataType.dataType, SourceType.USER_DEFINED);
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// Create structure type
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StructureDataType struct = new StructureDataType("MyStruct", 0);
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struct.add(IntegerDataType.dataType, "field_a", null);
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struct.add(PointerDataType.dataType, "next", null);
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// Apply to memory
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createData(toAddr(0x601000), struct);
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```
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### Pattern Matching Scripts
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```python
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# Find all calls to dangerous functions
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for func in currentProgram.getFunctionManager().getFunctions(True):
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for ref in getReferencesTo(func.getEntryPoint()):
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if func.getName() in ["strcpy", "sprintf", "gets"]:
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print(f"Dangerous call at {ref.getFromAddress()}")
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```
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## IDA Pro Patterns
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### IDAPython Analysis
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```python
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import idaapi
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import idautils
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import idc
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# Find all function calls
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def find_calls(func_name):
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for func_ea in idautils.Functions():
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for head in idautils.Heads(func_ea, idc.find_func_end(func_ea)):
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if idc.print_insn_mnem(head) == "call":
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target = idc.get_operand_value(head, 0)
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if idc.get_func_name(target) == func_name:
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print(f"Call to {func_name} at {hex(head)}")
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# Rename functions based on strings
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def auto_rename():
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for s in idautils.Strings():
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for xref in idautils.XrefsTo(s.ea):
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func = idaapi.get_func(xref.frm)
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if func and "sub_" in idc.get_func_name(func.start_ea):
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# Use string as hint for naming
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pass
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```
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## Best Practices
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### Analysis Workflow
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1. **Initial triage**: File type, architecture, imports/exports
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2. **String analysis**: Identify interesting strings, error messages
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3. **Function identification**: Entry points, exports, cross-references
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4. **Control flow mapping**: Understand program structure
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5. **Data structure recovery**: Identify structs, arrays, globals
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6. **Algorithm identification**: Crypto, hashing, compression
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7. **Documentation**: Comments, renamed symbols, type definitions
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### Common Pitfalls
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- **Optimizer artifacts**: Code may not match source structure
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- **Inline functions**: Functions may be expanded inline
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- **Tail call optimization**: `jmp` instead of `call` + `ret`
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- **Dead code**: Unreachable code from optimization
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- **Position-independent code**: RIP-relative addressing
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