Metadata-Version: 2.4
Name: silica-eda
Version: 0.1.1
Summary: AI-native EDA environment — MCP server for hardware design and verification
Author-email: Christopher Simaan <dev@getsilica.dev>
License: Apache-2.0
License-File: LICENSE
Keywords: ai,eda,fpga,hardware,mcp,rtl,systemverilog,verilog
Classifier: Development Status :: 3 - Alpha
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: Apache Software License
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Requires-Python: >=3.11
Requires-Dist: mcp<2.0.0,>=1.9.0
Requires-Dist: tomli-w>=1.0.0
Provides-Extra: dev
Requires-Dist: pytest-asyncio>=0.23; extra == 'dev'
Requires-Dist: pytest>=8.0; extra == 'dev'
Requires-Dist: ruff>=0.4; extra == 'dev'
Description-Content-Type: text/markdown

# Silica

AI-native EDA environment — an MCP server that gives any LLM deep integration with the full EDA toolchain: simulation, synthesis, linting, formal verification, and autonomous debug loops.

## What it does

Silica wraps open source EDA tools (Verilator, Yosys, Verible, Icarus) in a structured MCP interface. You describe what you want to the model; Silica gives it the tool access and reasoning skills to find and fix RTL bugs, synthesize designs, and run verification workflows autonomously.

The core value: **closed autonomous loops**. Run sim → parse failure → reason about RTL → propose fix → re-run — without human copy-paste.

## Quick start

### 1. Install Silica

```bash
pip install silica-eda
```

### 2. Run the setup wizard

```bash
silica setup
```

The wizard detects which MCP clients and EDA tools you already have installed, lets you choose what to enable, and writes the MCP client config for you. It covers Claude Desktop, Claude Code, Cursor, Zed, Windsurf, OpenCode, and Gemini CLI.

When it's done, check your config anytime with:

```bash
silica config
```

### 3. Install missing tools (if any)

The wizard prints install commands for any open source tools you selected but don't have yet. For example on macOS:

```bash
brew install verilator yosys icarus-verilog verible
```

**Ubuntu / Debian**
```bash
sudo apt update && sudo apt install verilator yosys iverilog
# Verible: sudo apt install verible  (Ubuntu 22.04+)
# or grab the release binary: https://github.com/chipsalliance/verible/releases
```

**Fedora / RHEL**
```bash
sudo dnf install verilator yosys iverilog
```

**Arch**
```bash
sudo pacman -S verilator yosys iverilog verible
```

**Windows**
WSL2 is the recommended path:
```powershell
wsl --install   # installs Ubuntu by default
```
Then follow the Ubuntu instructions above inside WSL. Claude Desktop and Cursor both support MCP servers running inside WSL via the `wsl -e silica serve` command pattern.

### 4. Start the server

```bash
silica serve
```

Your MCP client will launch this automatically — you typically don't need to run it manually.

### 5. Test the UART example

Ask Claude:

> Run the UART TX simulation in examples/uart/ and tell me if it passes.

Or introduce a bug and ask Claude to find and fix it autonomously:

> In examples/uart/uart_tx.sv, change line 54 to use `==` instead of `== CLKS_PER_BIT - 1` for the baud counter comparison. Then run the simulation, find the bug, and fix it.

## Manual client setup

If you prefer to configure your MCP client by hand instead of using `silica setup`:

**Claude Desktop** — `~/Library/Application Support/Claude/claude_desktop_config.json` (macOS) or `~/.config/Claude/claude_desktop_config.json` (Linux):

```json
{
  "mcpServers": {
    "silica": {
      "command": "silica",
      "args": ["serve"]
    }
  }
}
```

**Claude Code**
```bash
claude mcp add silica silica serve
```

**Cursor** — `~/.cursor/mcp.json`:
```json
{
  "mcpServers": {
    "silica": {
      "command": "silica",
      "args": ["serve"]
    }
  }
}
```

**Windows (WSL2)**
```json
{
  "mcpServers": {
    "silica": {
      "command": "wsl",
      "args": ["-e", "silica", "serve"]
    }
  }
}
```

## CLI reference

| Command | Description |
|---|---|
| `silica serve` | Start the MCP server (stdio transport). Default if no subcommand given. |
| `silica setup` | Interactive first-run configuration wizard. |
| `silica config` | Show current configuration and live tool status. |

## MCP Tools (v0.1)

| Tool | Description |
|---|---|
| `run_simulation` | Simulate RTL (Verilator / Icarus). Returns structured errors and optional VCD trace path. |
| `synthesize` | Synthesize to gates (Yosys). Returns utilization. |
| `lint` | Static analysis (Verible / Verilator). Returns structured warnings. |
| `run_formal` | Formal verification (SymbiYosys). Returns pass/fail/error status. |
| `launch_waveform` | Open a VCD trace in Surfer or GTKWave (fire-and-forget). |
| `read_rtl` | Read source file with line numbers. |
| `write_rtl` | Propose RTL changes — always dry_run=True before writing. |
| `get_project_structure` | Scan for RTL and constraint files. |
| `search_rtl` | Grep across project RTL with context. |
| `get_constraints` | Read constraint files (.xdc, .sdc, .lpf). |

## Workflow Skills

Silica ships reasoning scripts that teach the model how to interpret tool output and form hypotheses — not just how to call tools. Available as MCP prompts:

- `debug_simulation_failure` — step-by-step triage from error list to verified fix
- `write_testbench` — generate a complete testbench from a module interface
- `generate_assertions` — write SVA assertions from design intent
- `close_timing` — work through timing violations with synthesis feedback

## Architecture

```
silica/
├── silica/
│   ├── server.py              # FastMCP server; registers all tools and prompts
│   ├── cli.py                 # subcommand dispatch (serve / setup / config)
│   ├── tools_registry.py      # canonical list of all supported EDA tools
│   ├── clients_registry.py    # canonical list of all supported MCP clients
│   ├── terminal.py            # OSC 8 hyperlink support
│   ├── config.py              # ~/.silica/config.toml load/save
│   ├── setup.py               # interactive setup wizard + config viewer
│   ├── tools/                 # MCP tool definitions
│   │   ├── _config_dispatch.py  # config-aware auto tool selection
│   │   ├── simulation.py      # run_simulation()
│   │   ├── synthesis.py       # synthesize()
│   │   ├── lint.py            # lint()
│   │   ├── formal.py          # run_formal()
│   │   ├── waveform.py        # launch_waveform()
│   │   └── project.py         # read_rtl(), write_rtl(), get_project_structure(), ...
│   └── adapters/              # per-tool CLI wrappers + output parsers
│       ├── _hints.py          # platform-aware install hint strings
│       ├── verilator.py
│       ├── icarus.py
│       ├── yosys.py
│       ├── verible.py
│       └── sby.py
└── examples/
    └── uart/                  # 8N1 UART TX — reference design for end-to-end testing
```

## Toolchain coverage (v0.1)

| Category | Open source | Commercial (detected if on PATH) |
|---|---|---|
| Simulation | Verilator, Icarus Verilog | VCS (Synopsys), Questa (Siemens), Xcelium (Cadence) |
| Synthesis | Yosys | Vivado (AMD/Xilinx), Quartus (Intel), DC Shell (Synopsys) |
| Formal | SymbiYosys | JasperGold (Cadence), VC Formal (Synopsys) |
| Lint | Verible, svlint | SpyGlass (Synopsys) |
| Waveform | GTKWave, Surfer | Verdi (Synopsys) |

## Development

```bash
git clone https://github.com/simaanc/silica-eda
cd silica-eda
pip install -e ".[dev]"

# Run the server locally (for debugging)
silica serve

# Run the UART end-to-end test
iverilog -g2012 -o /tmp/uart_sim examples/uart/uart_tx_tb.sv examples/uart/uart_tx.sv
vvp /tmp/uart_sim
```

## License

Apache-2.0
