ida-pro-mcp-fusion
IDA Pro MCP โ Fusion Edition
Simple MCP Server to allow vibe reversing in IDA Pro โ the Fusion Edition fuses the latest upstream with a persistent SQLite cache and a multi-binary headless supervisor (76 tools).
Registry name: io.github.rison1337/ida-pro-mcp-fusion
Repository: https://github.com/rison1337/ida-pro-mcp-fusion
Official MCP Registry: https://registry.modelcontextprotocol.io/v0.1/servers?search=io.github.rison1337/ida-pro-mcp-fusion
MCPB bundle: https://github.com/rison1337/ida-pro-mcp-fusion/releases/download/v2.0.0/ida-pro-mcp-fusion-2.0.0.mcpb
https://github.com/user-attachments/assets/6ebeaa92-a9db-43fa-b756-eececce2aca0
The binaries and prompt for the video are available in the mcp-reversing-dataset repository.
Enhanced fork of mrexodia/ida-pro-mcp, rebased on the latest upstream and merged with the best ideas from
QiuChenly/ida-pro-mcp-enhancement and
winmin/ida-headless-mcp.
Everything upstream still works โ this fork only adds capability. See the What this fork adds section below.
โจ What this fork adds
This fork keeps 100% of upstream behaviour and layers three things on top of it:
๐๏ธ Persistent SQLite cache
A per-database <binary>.i64.mcp.sqlite cache of strings, functions, globals, imports, cross-references and call-graph edges. Reads are served straight from SQLite instead of round-tripping through IDA's single-threaded API โ a large speedup for big binaries and repeated triage. Ships 9 dedicated cache tools:
cache_status ยท refresh_cache ยท cache_refresh_if_stale ยท cache_list_funcs ยท cache_entity_query ยท cache_xrefs ยท cache_callgraph ยท cache_callgraph_hotspots ยท cache_find_regex
Freshness is tracked via the IDB mtime plus a schema version, so a stale cache rebuilds automatically and outdated rows are never served.
๐งต Multi-binary headless supervisor
Upstream exposes idb_open and idb_list; this fork grows the idalib supervisor into a pool of persistent workers and adds 2 new session tools:
idb_batch_open(new) โ open many binaries at once, warm Hex-Rays, and build each persistent cache, with aclose_after_cacheoption for batches larger than--max-workers(plussession_prefixand auto-analysis-timeout retry).idb_close(new) โ cleanly close a session and terminate its owned worker.
Combined with --max-workers, this turns the server into a headless analysis farm you can drive across dozens of samples from a single MCP endpoint.
๐ 76 tools, one endpoint
Concretely, this fork adds 11 tools over upstream โ the 9-tool cache_* suite plus idb_close and idb_batch_open โ bringing the live count to 76, spanning discovery, decompilation, disassembly, CFG, xrefs / call-graph, search, data reads, type & struct editing, signatures, IDB modification, the SQLite cache, and multi-session management.
Capability | upstream | QiuChenly | winmin | this fork |
Live tools | ~65 | ~50 | 66 | 76 |
Based on latest upstream | โ | โ๏ธ | โ๏ธ | โ |
Persistent SQLite cache | โ๏ธ | โ | โ๏ธ | โ |
Multi-worker headless pool | basic | โ๏ธ | โ | โ |
Batch open + cache build | โ๏ธ | โ๏ธ | partial | โ |
Tool counts are approximate and depend on each project's upstream base and enabled profile; QiuChenly/winmin forked from an earlier upstream, so this fork's 76 reflects the newest upstream plus the 11 additions above.
Related MCP server: ida-pro-mcp
Prerequisites
Python (3.11 or higher)
Use
idapyswitchto switch to the newest Python version
uv /
uvxIf
uvxis not available, install uv first:python -m pip install uv
IDA Pro (8.3 or higher, 9 recommended), IDA Free is not supported
Supported MCP Client (pick one you like)
Other MCP Clients: Run
ida-pro-mcp --configto get the JSON config for your client.
Installation (Fusion Edition)
For MCP clients that can run a stdio command, use the GitHub-backed uvx command:
If uvx is not available yet, install uv first:
python -m pip install uv{
"mcpServers": {
"ida-pro-mcp-fusion": {
"command": "uvx",
"args": [
"--from",
"git+https://github.com/rison1337/ida-pro-mcp-fusion",
"idalib-mcp",
"--stdio"
]
}
}
}Claude Code:
claude mcp add ida-pro-mcp-fusion -- uvx --from git+https://github.com/rison1337/ida-pro-mcp-fusion idalib-mcp --stdioManual pip/uv install from this fork:
pip install https://github.com/rison1337/ida-pro-mcp-fusion/archive/refs/heads/main.zipInstallation (upstream Claude plugin)
To install the headless IDA Pro MCP in Claude Code:
claude plugin marketplace add mrexodia/claude-marketplace
claude plugin install ida-pro-mcp@mrexodiaTo update to the latest version:
claude plugin update ida-pro-mcp@mrexodiaNote: The Claude plugin commands above install the upstream marketplace package. For this Fusion fork, use the uvx --from git+https://github.com/rison1337/ida-pro-mcp-fusion ... command shown above. Both modes require having idalib activated globally and uv installed:
# windows
uv run "C:\Program Files\IDA Professional 9.3\idalib\python\py-activate-idalib.py"
# macos
uv run "/Applications/IDA Professional 9.3.app/Contents/MacOS/idalib/python/py-activate-idalib.py"Installation (GUI)
Note: the MCP plugin is no longer recommended and will eventually be deprecated. Use idalib-mcp instead.
If you want to configure the MCP server manually from the IDA GUI:
pip uninstall ida-pro-mcp
pip install https://github.com/rison1337/ida-pro-mcp-fusion/archive/refs/heads/main.zipConfigure the MCP servers and install the IDA Plugin:
ida-pro-mcp --installImportant: Make sure you completely restart IDA and your MCP client for the installation to take effect. Some clients (like Claude) run in the background and need to be quit from the tray icon.
Prompt Engineering
LLMs are prone to hallucinations and you need to be specific with your prompting. For reverse engineering the conversion between integers and bytes are especially problematic. Below is a minimal example prompt, feel free to start a discussion or open an issue if you have good results with a different prompt:
Your task is to analyze a crackme in IDA Pro. You can use the MCP tools to retrieve information. In general use the following strategy:
- Inspect the decompilation and add comments with your findings
- Rename variables to more sensible names
- Change the variable and argument types if necessary (especially pointer and array types)
- Change function names to be more descriptive
- If more details are necessary, disassemble the function and add comments with your findings
- NEVER convert number bases yourself. Use the `int_convert` MCP tool if needed!
- Do not attempt brute forcing, derive any solutions purely from the disassembly and simple python scripts
- Create a report.md with your findings and steps taken at the end
- When you find a solution, prompt to user for feedback with the password you foundThis prompt was just the first experiment, please share if you found ways to improve the output!
Another prompt by @can1357:
Your task is to create a complete and comprehensive reverse engineering analysis. Reference AGENTS.md to understand the project goals and ensure the analysis serves our purposes.
Use the following systematic methodology:
1. **Decompilation Analysis**
- Thoroughly inspect the decompiler output
- Add detailed comments documenting your findings
- Focus on understanding the actual functionality and purpose of each component (do not rely on old, incorrect comments)
2. **Improve Readability in the Database**
- Rename variables to sensible, descriptive names
- Correct variable and argument types where necessary (especially pointers and array types)
- Update function names to be descriptive of their actual purpose
3. **Deep Dive When Needed**
- If more details are necessary, examine the disassembly and add comments with findings
- Document any low-level behaviors that aren't clear from the decompilation alone
- Use sub-agents to perform detailed analysis
4. **Important Constraints**
- NEVER convert number bases yourself - use the int_convert MCP tool if needed
- Use MCP tools to retrieve information as necessary
- Derive all conclusions from actual analysis, not assumptions
5. **Documentation**
- Produce comprehensive RE/*.md files with your findings
- Document the steps taken and methodology used
- When asked by the user, ensure accuracy over previous analysis file
- Organize findings in a way that serves the project goals outlined in AGENTS.md or CLAUDE.mdLive stream discussing prompting and showing some real-world malware analysis:

Tips for Enhancing LLM Accuracy
Large Language Models (LLMs) are powerful tools, but they can sometimes struggle with complex mathematical calculations or exhibit "hallucinations" (making up facts). Make sure to tell the LLM to use the int_convert MCP tool and you might also need math-mcp for certain operations.
Another thing to keep in mind is that LLMs will not perform well on obfuscated code. Before trying to use an LLM to solve the problem, take a look around the binary and spend some time (automatically) removing the following things:
String encryption
Import hashing
Control flow flattening
Code encryption
Anti-decompilation tricks
You should also use a tool like Lumina or FLIRT to try and resolve all the open source library code and the C++ STL, this will further improve the accuracy.
Transports & Headless MCP
You can run an SSE server to connect to the user interface like this:
uv run ida-pro-mcp --transport http://127.0.0.1:8744/sseAfter installing idalib you can also run a headless MCP server. You can start with an initial binary:
uv run idalib-mcp --host 127.0.0.1 --port 8745 path/to/executableOr start without a binary and open arbitrary files later with idb_open(...):
uv run idalib-mcp --host 127.0.0.1 --port 8745For stdio-based clients, use:
uv run idalib-mcp --stdioDatabase workers are persistent: each one runs as a detached process that
outlives the supervisor that spawned it. When a new supervisor (over stdio
or HTTP) calls idb_open for a binary that is already open under a worker
on this host, the supervisor adopts that worker transparently โ there is
no separate "shared" mode to enable. Workers self-exit when no request has
hit them for an idle interval.
Note: The idalib feature was contributed by Willi Ballenthin.
Headless idalib Session Model
idalib-mcp is a supervisor that keeps each open database in its own idalib worker process. Workers register themselves in a host-local discovery directory and outlive the supervisor that spawned them; any subsequent supervisor that wants the same path adopts the running worker. A worker self-exits when no request has hit it for its idle TTL (default 1 hour). There is no idb_close tool โ clients that no longer care about a database simply stop using it, and only the user can close a GUI window.
idb_open picks the backend via its mode parameter:
prefer_headless(default): spawn an idalib worker (or adopt one that already has the file open).force_headless: same, but never adopt a running GUI even if one has the file.prefer_gui: adopt a running GUI for the file; otherwise spawn an idalib worker.force_gui: adopt a running GUI for the file; otherwise launch a new IDA GUI process.
Every tool call must carry an explicit database argument. There is no implicit "current database" โ callers name the session they want to operate on.
uv run idalib-mcp --stdio --max-workers 4Typical flow:
idb_open("/path/to/binary_a.exe", preferred_session_id="binary_a")
idb_open("/path/to/library.dll", preferred_session_id="library")
decompile("main", database="binary_a")
xrefs_to("ImportantExport", database="library")database must be the session ID returned by idb_open (or shown in idb_list); filenames and paths are not accepted.
Management tools
idb_open(input_path, mode="prefer_headless", run_auto_analysis=True, build_caches=True, init_hexrays=True, preferred_session_id=""): Open a binary, warm up subsystems (strings cache, Hex-Rays), and return its session ID. If a worker or GUI for this path is already running on the host, that instance is adopted andpreferred_session_idis ignored.idb_list(): List open sessions and running GUI IDA instances. Each entry hasadopted(True if this supervisor manages it, False for GUIs/workers discovered but not yet opened viaidb_open),backend(workerorgui),is_active, and process IDs.idb_save(session_id, path=""): Save a session's IDB to disk. Forwarded as a regular worker tool (database=<id>injected) โ same signature in both backends.Per-database health: call
server_health(database=<id>)(forwarded).idb_list()reportsis_activefrom the supervisor's TCP/RPC probe.
Worker controls:
--max-workers N: maximum simultaneous database workers (0= unlimited, default4).IDA_MCP_MAX_WORKERS: environment default for--max-workers.
MCP Resources
Resources represent browsable state (read-only data) following MCP's philosophy.
Core IDB State:
ida://idb/metadata- IDB file info (path, arch, base, size, hashes)ida://idb/segments- Memory segments with permissionsida://idb/entrypoints- Entry points (main, TLS callbacks, etc.)
UI State:
ida://cursor- Current cursor position and functionida://selection- Current selection range
Type Information:
ida://types- All local typesida://structs- All structures/unionsida://struct/{name}- Structure definition with fields
Lookups:
ida://import/{name}- Import details by nameida://export/{name}- Export details by nameida://xrefs/from/{addr}- Cross-references from address
Core Functions
lookup_funcs(queries): Get function(s) by address or name (auto-detects, accepts list or comma-separated string).int_convert(inputs): Convert numbers to different formats (decimal, hex, bytes, ASCII, binary).list_funcs(queries): List functions (paginated, filtered).list_globals(queries): List global variables (paginated, filtered).imports(offset, count): List all imported symbols with module names (paginated).decompile(addr): Decompile function at the given address.disasm(addr): Disassemble function with full details (arguments, stack frame, etc).xrefs_to(addrs): Get all cross-references to address(es).xrefs_to_field(queries): Get cross-references to specific struct field(s).callees(addrs): Get functions called by function(s) at address(es).
Modification Operations
add_bookmark(addr, name, prefix): Add or replace the IDA bookmark at an address; setprefix=""for no prefix.set_comments(items): Set comments at address(es) in both disassembly and decompiler views.patch_asm(items): Patch assembly instructions at address(es).declare_type(decls): Declare C type(s) in the local type library.define_func(items): Define function(s) at address(es). Optionally specifyendfor explicit bounds.define_code(items): Convert bytes to code instruction(s) at address(es).undefine(items): Undefine item(s) at address(es), converting back to raw bytes. Optionally specifyendorsize.
Memory Reading Operations
get_bytes(addrs): Read raw bytes at address(es).get_int(queries): Read integer values using ty (i8/u64/i16le/i16be/etc).get_string(addrs): Read null-terminated string(s).get_global_value(queries): Read global variable value(s) by address or name (auto-detects, compile-time values).
Stack Frame Operations
stack_frame(addrs): Get stack frame variables for function(s).declare_stack(items): Create stack variable(s) at specified offset(s).delete_stack(items): Delete stack variable(s) by name.
Structure Operations
read_struct(queries): Read structure field values at specific address(es).search_structs(filter): Search structures by name pattern.
Debugger Operations (Extension)
Debugger tools are hidden by default. Enable with ?ext=dbg query parameter:
http://127.0.0.1:13337/mcp?ext=dbgControl:
dbg_start(): Start debugger process.dbg_exit(): Exit debugger process.dbg_continue(): Continue execution.dbg_run_to(addr): Run to address.dbg_step_into(): Step into instruction.dbg_step_over(): Step over instruction.
Breakpoints:
dbg_bps(): List all breakpoints.dbg_add_bp(addrs): Add breakpoint(s).dbg_delete_bp(addrs): Delete breakpoint(s).dbg_toggle_bp(items): Enable/disable breakpoint(s).
Registers:
dbg_regs(): All registers, current thread.dbg_regs_all(): All registers, all threads.dbg_regs_remote(tids): All registers, specific thread(s).dbg_gpregs(): GP registers, current thread.dbg_gpregs_remote(tids): GP registers, specific thread(s).dbg_regs_named(names): Named registers, current thread.dbg_regs_named_remote(tid, names): Named registers, specific thread.
Stack & Memory:
dbg_stacktrace(): Call stack with module/symbol info.dbg_read(regions): Read memory from debugged process.dbg_write(regions): Write memory to debugged process.
Advanced Analysis Operations
py_eval(code): Execute arbitrary Python code in IDA context (returns dict with result/stdout/stderr, supports Jupyter-style evaluation).analyze_funcs(addrs): Comprehensive function analysis (decompilation, assembly, xrefs, callees, callers, strings, constants, basic blocks).
Pattern Matching & Search
find_regex(queries): Search strings with case-insensitive regex (paginated).find_bytes(patterns, limit=1000, offset=0): Find byte pattern(s) in binary (e.g., "48 8B ?? ??"). Max limit: 10000.find_insns(sequences, limit=1000, offset=0): Find instruction sequence(s) in code. Max limit: 10000.find(type, targets, limit=1000, offset=0): Advanced search (immediate values, strings, data/code references). Max limit: 10000.
Control Flow Analysis
basic_blocks(addrs): Get basic blocks with successors and predecessors.
Type Operations
set_type(edits): Apply type(s) to functions, globals, locals, or stack variables.infer_types(addrs): Infer types at address(es) using Hex-Rays or heuristics.
Export Operations
export_funcs(addrs, format): Export function(s) in specified format (json, c_header, or prototypes).
Graph Operations
callgraph(roots, max_depth): Build call graph from root function(s) with configurable depth.
Batch Operations
rename(batch): Unified batch rename operation for functions, globals, locals, and stack variables (accepts dict with optionalfunc,data,local,stackkeys).patch(patches): Patch multiple byte sequences at once.put_int(items): Write integer values using ty (i8/u64/i16le/i16be/etc).
Key Features:
Type-safe API: All functions use strongly-typed parameters with TypedDict schemas for better IDE support and LLM structured outputs
Batch-first design: Most operations accept both single items and lists
Consistent error handling: All batch operations return
[{..., error: null|string}, ...]Cursor-based pagination: Search functions return
cursor: {next: offset}or{done: true}(default limit: 1000, enforced max: 10000 to prevent token overflow)Performance: Strings are cached with MD5-based invalidation to avoid repeated
build_strlistcalls in large projects
Development
Adding new features is a super easy and streamlined process. All you have to do is add a new @tool function to the modular API files in src/ida_pro_mcp/ida_mcp/api_*.py and your function will be available in the MCP server without any additional boilerplate! Below is a video where I add the get_metadata function in less than 2 minutes (including testing):
https://github.com/user-attachments/assets/951de823-88ea-4235-adcb-9257e316ae64
To test the MCP server itself:
npx -y @modelcontextprotocol/inspectorThis will open a web interface at http://localhost:5173 and allow you to interact with the MCP tools for testing.
For testing I create a symbolic link to the IDA plugin and then POST a JSON-RPC request directly to http://localhost:13337/mcp. After enabling symbolic links you can run the following command:
uv run ida-pro-mcp --installGenerate the changelog of direct commits to main:
git log --first-parent --no-merges 1.2.0..main "--pretty=- %s"This server cannot be installed
Maintenance
Latest Blog Posts
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