amiga-bootcamp/05_reversing/ida_setup.md

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# IDA Pro Setup for Amiga 68k Binaries

## Requirements

| Component | Version / Notes |
|---|---|
| IDA Pro | 7.0+ (7.5+ recommended for Hex-Rays decompiler quality) |
| Processor module | M68k — included in IDA standard install |
| HUNK loader | Included in some IDA builds; community plugin if absent |
| Hex-Rays decompiler | 68k decompiler license required for pseudocode |

---

## Step 1: Install the HUNK Loader Plugin

IDA does not ship with an Amiga HUNK loader in all versions. The community loader is available at:

- https://github.com/wiemerc/ida-amiga (Python-based, IDA 7.x)
- Alternative: load as raw binary at base address 0, then manually define hunk segments

### Installing the plugin:

```bash
cp amiga_hunk.py ~/.idapro/plugins/        # macOS/Linux
cp amiga_hunk.py %APPDATA%\Hex-Rays\IDA Pro\plugins\   # Windows
```

Restart IDA. The loader appears in the format list when opening `.library`, `.device`, or executables with `$3F3` magic.

---

## Step 2: Processor Configuration

When loading, select:
- **Processor**: Motorola 680x0
- **Variant**: 68020 for A1200/A4000 targets, 68000 for A500 targets
- **Endianness**: Big-endian (automatic for 68k)

Changing processor after load:
`Edit → Plugins → Change processor type`

---

## Step 3: Segment Setup (Manual Load Fallback)

If not using the HUNK plugin, define segments manually after loading as raw binary:

```python
# IDA Python: create segments for a 2-hunk binary
# (code at 0, data at 0x1234)
import idc, idaapi

CODE_BASE = 0x00000000
DATA_BASE = 0x00001234

idc.add_segm(0, CODE_BASE, CODE_BASE + 0x1230, "CODE", "CODE")
idc.add_segm(0, DATA_BASE, DATA_BASE + 0x200,  "DATA", "DATA")
idc.set_segm_class(idc.get_segm_attr(CODE_BASE, idc.SEGATTR_SEL), "CODE")
```

---

## Step 4: Define SysBase and Library Bases

Tell IDA about global library pointers so it can track A6:

```python
# Mark $00000004 as SysBase (exec pointer)
idc.create_dword(4)
idc.set_name(4, "SysBase", idc.SN_NOWARN)
idc.set_cmt(4, "exec.library base pointer (absolute address 4)", 0)
```

For each library base found during analysis:
```python
idc.set_name(ea_of_libbase_var, "_DOSBase", idc.SN_NOWARN)
```

---

## Step 5: Apply FLIRT Signatures

FLIRT (Fast Library Identification and Recognition Technology) signatures identify known library startup and runtime functions. Amiga-specific signature files:

- `m68k_amiga_sasc6.sig` — SAS/C 6.x standard library
- `m68k_amiga_gcc_libnix.sig` — GCC libnix
- `m68k_amiga_vbcc.sig` — VBCC

Apply via: `File → Load file → FLIRT signature file`

If no prebuilt sigs are available, create them with IDA's PELF tool from known `.lib` files.

---

## Step 6: Import AmigaOS Types

Apply AmigaOS structure definitions:

### Option A: Type Library (.til)

If an AmigaOS `.til` is available:
```
View → Open Subviews → Type Libraries → Insert → select amigaos.til
```

### Option B: Parse Headers Directly

```
File → Load file → Parse C header file
```

Load NDK39 headers (adjust path to your NDK location):
```
NDK39/include/exec/execbase.h
NDK39/include/dos/dosextens.h
NDK39/include/graphics/gfxbase.h
```

Set pre-processor defines:
```c
#define __AMIGA__
#define __mc68000__
```

---

## Step 7: Annotate JMP Table Calls

Run the LVO annotation script:

```python
import idautils, idc, idaapi, re

# Build LVO→name dict from NDK fd files (partial)
EXEC_LVO = {
    -198: "AllocMem",   -210: "FreeMem",
    -282: "AddTask",    -288: "RemTask",
    -366: "PutMsg",     -372: "GetMsg",
    -552: "OpenLibrary",-414: "CloseLibrary",
    -420: "SetFunction",-624: "CopyMem",
    # ... extend from lvo_table.md
}

def annotate_lvos():
    for seg_ea in idautils.Segments():
        for func_ea in idautils.Functions(seg_ea, idc.get_segm_end(seg_ea)):
            for ea in idautils.FuncItems(func_ea):
                if idc.print_insn_mnem(ea).lower() == 'jsr':
                    op = idc.print_operand(ea, 0)
                    m = re.match(r'(-\d+)\(A6\)', op, re.IGNORECASE)
                    if m:
                        lvo = int(m.group(1))
                        name = EXEC_LVO.get(lvo)
                        if name:
                            idc.set_cmt(ea, f"exec: {name}", 0)

annotate_lvos()
```

---

## Step 8: Hex-Rays Decompiler Tips for 68k

The Hex-Rays 68k decompiler needs type information to produce clean pseudocode:

1. **Set function types** — mark return type and argument registers for library call wrappers
2. **Suppress spurious variables** — many D-register temps appear; use `Collapse variable` or retype
3. **Add `__asm` register hints** for known argument registers

Example — marking a library function prototype:
```c
// In IDA Local Types:
APTR __cdecl AllocMem_wrap(ULONG byteSize, ULONG requirements);
```

Then apply to call sites via `Y` (set type) on the JSR instruction.

---

## References

- IDA Pro 7.x documentation — processor modules, FLIRT
- ida-amiga plugin: https://github.com/wiemerc/ida-amiga
- Ghidra Amiga plugin: https://github.com/lab313ru/ghidra_amiga_ldr
- Ghidra m68k fixer: https://github.com/lab313ru/m68k_fixer
- BartmanAbyss Ghidra Amiga: https://github.com/BartmanAbyss/ghidra-amiga — Amiga HUNK loader + helpers for Ghidra
- IDA Pro m68k extensions: https://github.com/LucienMP/idapro_m68k — GDB step-over, type info
- NDK39: header files for type import
docs(amiga): complete AmigaOS 3.1/3.2 developer reference — 172 files across 17 sections Comprehensive technical documentation covering: - Hardware: OCS/ECS/AGA custom chip registers, Copper & Blitter deep dives - Boot sequence: cold boot through startup-sequence - Binary format: HUNK executable spec, relocation, debug info - Linking & ABI: .fd files, LVO tables, register calling conventions - Exec kernel: tasks, interrupts, memory, signals, semaphores - AmigaDOS: file I/O, FFS/OFS layout, CLI/Shell scripting - Graphics: planar bitmaps, Copper programming, HAM/EHB modes - Intuition: screens, windows, IDCMP, BOOPSI - Devices: trackdisk, SCSI, serial, timer, audio, keyboard - Libraries: utility, expansion, IFFParse, locale, ARexx - Networking: bsdsocket API, SANA-II, TCP/IP stack comparison - Toolchain: GCC, vasm/vlink, SAS/C, NDK, debugging - Reverse engineering: IDA/Ghidra setup, compiler fingerprints, case studies - CPU & MMU: 68040/060 emulation libs, PMMU, cache management - Driver development: SANA-II, Picasso96/RTG, AHI audio All files include breadcrumb navigation. No local paths or proprietary content. 2026-04-23 12:16:52 -04:00			`[← Home](../README.md) · [Reverse Engineering](README.md)`

			`# IDA Pro Setup for Amiga 68k Binaries`

			`## Requirements`

			`\| Component \| Version / Notes \|`
			`\|---\|---\|`
			`\| IDA Pro \| 7.0+ (7.5+ recommended for Hex-Rays decompiler quality) \|`
			`\| Processor module \| M68k — included in IDA standard install \|`
			`\| HUNK loader \| Included in some IDA builds; community plugin if absent \|`
			`\| Hex-Rays decompiler \| 68k decompiler license required for pseudocode \|`

			`---`

			`## Step 1: Install the HUNK Loader Plugin`

			`IDA does not ship with an Amiga HUNK loader in all versions. The community loader is available at:`

			`- https://github.com/wiemerc/ida-amiga (Python-based, IDA 7.x)`
			`- Alternative: load as raw binary at base address 0, then manually define hunk segments`

			`### Installing the plugin:`

			```bash
			`cp amiga_hunk.py ~/.idapro/plugins/ # macOS/Linux`
			`cp amiga_hunk.py %APPDATA%\Hex-Rays\IDA Pro\plugins\ # Windows`
			```

			Restart IDA. The loader appears in the format list when opening `.library`, `.device`, or executables with `$3F3` magic.

			`---`

			`## Step 2: Processor Configuration`

			`When loading, select:`
			`- Processor: Motorola 680x0`
			`- Variant: 68020 for A1200/A4000 targets, 68000 for A500 targets`
			`- Endianness: Big-endian (automatic for 68k)`

			`Changing processor after load:`
			`Edit → Plugins → Change processor type`

			`---`

			`## Step 3: Segment Setup (Manual Load Fallback)`

			`If not using the HUNK plugin, define segments manually after loading as raw binary:`

			```python
			`# IDA Python: create segments for a 2-hunk binary`
			`# (code at 0, data at 0x1234)`
			`import idc, idaapi`

			`CODE_BASE = 0x00000000`
			`DATA_BASE = 0x00001234`

			`idc.add_segm(0, CODE_BASE, CODE_BASE + 0x1230, "CODE", "CODE")`
			`idc.add_segm(0, DATA_BASE, DATA_BASE + 0x200, "DATA", "DATA")`
			`idc.set_segm_class(idc.get_segm_attr(CODE_BASE, idc.SEGATTR_SEL), "CODE")`
			```

			`---`

			`## Step 4: Define SysBase and Library Bases`

			`Tell IDA about global library pointers so it can track A6:`

			```python
			`# Mark $00000004 as SysBase (exec pointer)`
			`idc.create_dword(4)`
			`idc.set_name(4, "SysBase", idc.SN_NOWARN)`
			`idc.set_cmt(4, "exec.library base pointer (absolute address 4)", 0)`
			```

			`For each library base found during analysis:`
			```python
			`idc.set_name(ea_of_libbase_var, "_DOSBase", idc.SN_NOWARN)`
			```

			`---`

			`## Step 5: Apply FLIRT Signatures`

			`FLIRT (Fast Library Identification and Recognition Technology) signatures identify known library startup and runtime functions. Amiga-specific signature files:`

			- `m68k_amiga_sasc6.sig` — SAS/C 6.x standard library
			- `m68k_amiga_gcc_libnix.sig` — GCC libnix
			- `m68k_amiga_vbcc.sig` — VBCC

			Apply via: `File → Load file → FLIRT signature file`

			If no prebuilt sigs are available, create them with IDA's PELF tool from known `.lib` files.

			`---`

			`## Step 6: Import AmigaOS Types`

			`Apply AmigaOS structure definitions:`

			`### Option A: Type Library (.til)`

			If an AmigaOS `.til` is available:
			```
			`View → Open Subviews → Type Libraries → Insert → select amigaos.til`
			```

			`### Option B: Parse Headers Directly`

			```
			`File → Load file → Parse C header file`
			```

			`Load NDK39 headers (adjust path to your NDK location):`
			```
			`NDK39/include/exec/execbase.h`
			`NDK39/include/dos/dosextens.h`
			`NDK39/include/graphics/gfxbase.h`
			```

			`Set pre-processor defines:`
			```c
			`#define __AMIGA__`
			`#define __mc68000__`
			```

			`---`

			`## Step 7: Annotate JMP Table Calls`

			`Run the LVO annotation script:`

			```python
			`import idautils, idc, idaapi, re`

			`# Build LVO→name dict from NDK fd files (partial)`
			`EXEC_LVO = {`
			`-198: "AllocMem", -210: "FreeMem",`
			`-282: "AddTask", -288: "RemTask",`
			`-366: "PutMsg", -372: "GetMsg",`
			`-552: "OpenLibrary",-414: "CloseLibrary",`
			`-420: "SetFunction",-624: "CopyMem",`
			`# ... extend from lvo_table.md`
			`}`

			`def annotate_lvos():`
			`for seg_ea in idautils.Segments():`
			`for func_ea in idautils.Functions(seg_ea, idc.get_segm_end(seg_ea)):`
			`for ea in idautils.FuncItems(func_ea):`
			`if idc.print_insn_mnem(ea).lower() == 'jsr':`
			`op = idc.print_operand(ea, 0)`
			`m = re.match(r'(-\d+)\(A6\)', op, re.IGNORECASE)`
			`if m:`
			`lvo = int(m.group(1))`
			`name = EXEC_LVO.get(lvo)`
			`if name:`
			`idc.set_cmt(ea, f"exec: {name}", 0)`

			`annotate_lvos()`
			```

			`---`

			`## Step 8: Hex-Rays Decompiler Tips for 68k`

			`The Hex-Rays 68k decompiler needs type information to produce clean pseudocode:`

			`1. Set function types — mark return type and argument registers for library call wrappers`
			2. Suppress spurious variables — many D-register temps appear; use `Collapse variable` or retype
			3. Add `__asm` register hints for known argument registers

			`Example — marking a library function prototype:`
			```c
			`// In IDA Local Types:`
			`APTR __cdecl AllocMem_wrap(ULONG byteSize, ULONG requirements);`
			```

			Then apply to call sites via `Y` (set type) on the JSR instruction.

			`---`

			`## References`

			`- IDA Pro 7.x documentation — processor modules, FLIRT`
			`- ida-amiga plugin: https://github.com/wiemerc/ida-amiga`
			`- Ghidra Amiga plugin: https://github.com/lab313ru/ghidra_amiga_ldr`
			`- Ghidra m68k fixer: https://github.com/lab313ru/m68k_fixer`
			`- BartmanAbyss Ghidra Amiga: https://github.com/BartmanAbyss/ghidra-amiga — Amiga HUNK loader + helpers for Ghidra`
			`- IDA Pro m68k extensions: https://github.com/LucienMP/idapro_m68k — GDB step-over, type info`
			`- NDK39: header files for type import`