* feat(units): add mil unit support across all position/coordinate commands
KiCad natively supports mils, so the MCP server should too. Added "mil"
as a valid unit option in tool schemas and updated all unit-to-nanometer
scale conversions across component, routing, outline, view, and IPC
handler code paths. 1 mil = 25400 nm (0.0254 mm).
Also fixes a pre-existing mypy overload error in pin_locator.py (str cast
on dict.get key) that was blocking pre-commit on any Python file change.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
* feat(units): add mil to TypeScript tool schemas
The Python-side mil support was added but the actual input validation
happens in the TypeScript/Zod schemas. Updated all z.enum(["mm", "inch"])
to include "mil" across board, component, routing, design-rules, and
export tool definitions.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
* fix(tools): replace CP-1252 mojibake with correct Unicode in board.ts
Replace U+00C3 U+00D7 (×) with U+00D7 (×) in add_logo size output string.
Character was mangled when file was saved as CP-1252 instead of UTF-8.
* fix: restore em-dash and fix pre-commit mypy in component/routing
component.py: replace CP-1252 mojibake (â€") with correct Unicode
em-dash (—) in the 'Add to board first' comment. Addresses
maintainer review on PR #162.
routing.py: annotate ex/ey as float at first assignment site in
_point_to_segment_distance_nm so mypy pre-commit hook passes
cleanly on this branch.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
---------
Co-authored-by: Claude Sonnet 4.6 <noreply@anthropic.com>
Drop GND stitching vias across the board with collision checking
against every non-GND segment, via, and pad on every copper layer.
PTH vias penetrate the full stackup, so an F.Cu-only check (the most
common shortcut) silently creates shorts on inner / B.Cu copper —
this implementation explicitly walks all layers.
grid Regular grid across the board interior. Default
spacing 5mm.
around_refs Densify around specified footprints (e.g. MCUs,
switching regulators, RF parts). Configurable
density via densifyRadius.
in_zones Restrict placements to candidates inside the filled
polygons of GND copper zones, so each new via lands
on copper that's already a GND equipotential.
Recommended on boards where the GND zone is fragmented:
these vias actually stitch real polygons rather than
floating on silkscreen.
All three strategies use the same collision check + intra-call
clump-prevention, so passing `["grid", "around_refs", "in_zones"]`
is a safe kitchen-sink configuration.
- Auto-detect GND net (tries GND / GROUND / VSS / /GND in order)
OR explicit `gndNet` parameter.
- Per-via geometry control: viaSize, viaDrill, clearance.
- edgeMargin: keep-out distance from board edge.
- maxVias: cap on total placements (useful for incremental work).
- dryRun: return placements without modifying the board — for
previewing before committing.
- Validates viaDrill < viaSize, rejects unknown strategy names,
surfaces clear errors when GND net can't be resolved or the
board outline is missing.
Approach ported from morningfire-pcb-automation
(https://github.com/NiNjA-CodE/morningfire-pcb-automation,
scripts/ground/add_gnd_vias.py). The original parses the PCB text
with regex and writes vias by string concatenation; this port reads
obstacles via the pcbnew API (handles rotated footprints, integrates
with the live in-memory board so two sequential calls see each
other's placements, picks up net codes from the loaded board) and
adds the in_zones strategy, the maxVias cap, and dry-run mode.
Credit is in the docstring, the TypeScript wrapper comment, the MCP
tool description (visible to clients), and the CHANGELOG entry.
tests/test_add_gnd_stitching_vias.py — 18 cases, all passing.
Uses mocked pcbnew objects so the suite runs under both the conftest
stub and a real pcbnew install.
- grid strategy fills empty board with correct count
- collision blocks via near a signal track (with extent assertion)
- GND-net obstacles are correctly ignored
- around_refs densifies near footprints with bounded extent
- in_zones rejects candidates outside HitTestFilledArea
- dryRun does NOT call board.Add
- actual run calls board.Add per placement
- maxVias caps total placements
- intra-call clump prevention (asserts pairwise distance)
- viaDrill >= viaSize is rejected
- unknown strategy name is rejected
- missing GND net returns clear error payload
- no board loaded returns clear error
- named GND net (e.g. VSS) is honoured even when GND also exists
- direct unit tests for _point_to_segment_distance_nm helper
Real-board smoke test on TuneForge_TF001 (4-layer, 44 footprints):
- GND net auto-detected
- grid spacing 4mm: 141 placements, 129 blocked by collision
- grid + in_zones: 140 placed, 15 rejected by zone membership,
115 blocked by collision
python/commands/routing.py (+impl, ~370 LOC)
python/kicad_interface.py (+handler registration)
python/schemas/tool_schemas.py (+MCP schema)
src/tools/routing.ts (+TypeScript surface, builds clean)
tests/test_add_gnd_stitching_vias.py (+18 tests)
CHANGELOG.md (+Unreleased -> New MCP Tools)
Detects courtyard overlaps between footprints and flags courtyards that
extend past the board outline. Returns overlap pairs with intersection
extents (mm), per-component boundary violations, and a placement summary.
The killer feature for AI-driven workflows is the `positions` parameter,
which accepts hypothetical placements `{ref: [x, y]}` or
`{ref: [x, y, rotation_degrees]}`. The tool evaluates the proposed
placement WITHOUT writing to the board file — so an AI agent can validate
a move_component / place_component before committing it, instead of the
current loop of write -> run DRC -> parse violations -> revert.
## Implementation
- Uses the real courtyard polygons from pcbnew (`fp.GetCourtyard(F_CrtYd)`
or B_CrtYd) for accurate AABBs even on custom and rotated footprints.
- Falls back to `fp.GetBoundingBox()` when no F/B.Courtyard polygon is
present.
- For virtual rotation, rotates the four AABB corners and re-axis-aligns.
Conservative: the rotated-AABB is always >= the rotated-polygon, so
overlap reports are never false-negatives (may be marginally
over-cautious on diagonal rectangles, which is the right error bias
for a placement validator).
- Optional `margin` parameter expands every courtyard by N mm — useful
for enforcing a manufacturing keepout wider than the symbol's
declared courtyard.
## Attribution
The approach is ported from morningfire-pcb-automation
(https://github.com/NiNjA-CodE/morningfire-pcb-automation), specifically
`scripts/placement/check_overlaps.py`. The upstream uses a static
per-footprint-type courtyard lookup table; this implementation reads
the real polygons from pcbnew so it works on any footprint without
maintaining a table. Attribution is in the function docstring, the
TypeScript wrapper, the tool's description (visible to MCP clients),
and the CHANGELOG entry.
## Tests
12 pytest cases in tests/test_check_courtyard_overlaps.py, all passing:
- No overlaps when spaced; overlap detected on intersect
- Margin pushes borderline pairs into overlap
- `refs` filter restricts the check
- Boundary violations are flagged; `include_boundary=false` suppresses
- Virtual position does not mutate the footprint (asserts
`SetPosition` is never called)
- Virtual rotation swaps a tall-narrow courtyard's x/y extents
- No-board-loaded returns clean error payload
- Bad position spec (wrong arity) returns clean error payload
- GetCourtyard() OutlineCount=0 -> fallback to GetBoundingBox()
- `board_outline` override replaces the Edge.Cuts bbox
Tests use mocked pcbnew objects so they run under both the conftest stub
and a real pcbnew install. Real-board smoke test on a 44-footprint
production board succeeds: 1 known overlap detected (SW1<->SW2), 0
boundary violations, virtual placement test reports 6 expected overlaps.
## Files touched
- python/commands/component.py (impl + helpers)
- python/kicad_interface.py (tool registration)
- python/schemas/tool_schemas.py (MCP schema entry)
- src/tools/component.ts (TypeScript surface, builds clean)
- tests/test_check_courtyard_overlaps.py (12 cases)
- CHANGELOG.md (Unreleased -> New MCP Tools)
query_traces silently omits PCB_ZONE_T objects, so layer-usage audits
miss power planes and GND pours entirely. query_zones complements it by
iterating board.Zones() and returning each zone's net, layers, priority,
fill state, min thickness, bounding box, and filled area, with the same
net/layer/boundingBox filter surface as query_traces.
* Feat: save 2D board view to file instead of returning base64
The 2D view was returning base64-encoded image data in JSON, which
often exceeded token/message size limits. Now saves the rendered
image (PNG/JPG/SVG) next to the PCB file and returns the file path.
This makes the output usable by tools that can read image files
directly.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
* feat(board): add opt-in responseMode param to get_board_2d_view
Add a responseMode string parameter (enum: inline | file, default inline)
so callers can choose how the rendered image is delivered.
- inline (default, pre-PR behavior): image bytes are base64-encoded
and returned in the imageData response field -- backward-compatible.
- file: image is written next to the .kicad_pcb as
<board>_2d_view.<ext> and filePath is returned -- resolves the
MCP message-size limit problem on large boards.
Rendering logic is shared between both modes; only response packaging
differs. Updated tool schema (Python + TypeScript) and replaced the
existing test file with 5 focused unit tests covering inline/file modes
for PNG and SVG formats plus the default-is-inline contract.
---------
Co-authored-by: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
`BoardOutlineCommands.add_mounting_hole` produced footprints with an empty
library:name id (`(footprint "" ...)` in the .kicad_pcb), which KiCad's GUI
Move tool refuses to select — users couldn't drag the resulting MHs in the
editor. It also emitted the pad with the default `*.Cu` + `*.Mask` LSET on
NPTHs; with `padDiameter > diameter` that creates phantom copper annular
rings on every Cu layer and trips clearance DRC against neighbouring nets.
Repro: call `add_mounting_hole` with `position={x:117,y:84.5,unit:"mm"},
diameter:3.2, padDiameter:3.5`. The resulting MH is unselectable and DRC
reports phantom F.Cu pad shorts to neighbouring component pads.
Changes:
- Set a real FPID via `module.SetFPID(pcbnew.LIB_ID(lib, name))`. Default
is `MountingHole:MountingHole_<diameter:g>mm` (e.g. 3.2 → 3.2mm); a new
optional `footprintLibId` parameter overrides.
- For NPTH (the default `plated:false`), restrict the pad's LSET to
`F.Mask` + `B.Mask` only. PTH path is unchanged — the default Cu+Mask
LSET is correct there.
- Update the schema in `tool_schemas.py`: previously advertised
`x`/`y`/`diameter` at the top level, but the impl reads
`position={x,y,unit}`, `padDiameter`, `plated`. Schema now matches the
implementation and exposes the new `footprintLibId` param.
- New `tests/test_add_mounting_hole.py` regression suite (7 tests) asserting
SetFPID is invoked with non-empty lib:name (default + override forms),
NPTH SetLayerSet excludes any Cu layer, and PTH does not call
SetLayerSet (preserves default Cu+Mask).
Replaces the manual add_schematic_junction tool with automatic junction
management. WireManager.sync_junctions inserts/removes junction dots
based on wire endpoints plus component pin positions and is invoked
after add_wire, add_polyline_wire, delete_wire, move, and rotate.
- Pin-aware: parses lib_symbols and applies KiCad's mirror/rotate/
translate transform to compute world pin coordinates
- Multi-unit safe: filters lib_symbols sub-units by the placed
symbol's (unit N) field plus the unit-0 common body
- Removes the now-unused WireManager.add_junction static method
- Updates CHANGELOG [Unreleased] with the tool removal notice
- Adds .mcp.json to .gitignore (machine-local paths)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Mechanical application of the `.gitattributes` rules from the prior commit.
All 50 files differ only in line endings — verified by
`git diff --cached --ignore-all-space` being empty.
Before: main had 42 CRLF + 27 LF Python files plus mixed-ending in YAML,
templates, and shell scripts. After: every text file is LF (except the
Windows-native *.ps1, *.bat scripts which remain CRLF per gitattributes).
This eliminates the noisy-diff failure mode seen in PR #102, where a
small logic change produced a 918-line diff due to whole-file CRLF→LF
conversion.
export_netlist was returning "Unknown command" because no Python handler
existed. generate_netlist was timing out (30s) due to an O(nets × components
× pins) wire-graph algorithm with a new PinLocator instantiated per net.
Both handlers now delegate to `kicad-cli sch export netlist`:
- export_netlist: new handler; writes KiCad XML / Spice / Cadstar / OrcadPCB2
to the caller-supplied outputPath. Added schematicPath parameter to the TS
tool definition (was absent, making file export impossible).
- generate_netlist: replaces the slow wire-graph with kicad-cli + XML parse;
returns the same {components, nets} JSON the TS handler already expected.
Also adds _find_kicad_cli_static() so both handlers share CLI discovery
without depending on ExportCommands (which requires a loaded pcbnew board).
Cleaned up generate_netlist schema in tool_schemas.py (removed outputPath and
format fields the handler never used), updated MCP tool descriptions and
SCHEMATIC_TOOLS_REFERENCE.md to clearly distinguish the two tools.
26 unit tests added covering parameter validation, subprocess mocking,
format mapping, XML→JSON parsing, and error/timeout propagation.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
Half of all valid KiCAD schematic pin positions are on the 50-mil
(1.27mm) grid but not the 100-mil (2.54mm) grid — e.g. 26.67mm = 21 ×
1.27mm. Snapping to 2.54mm displaced those coordinates by 1.27mm,
moving labels off their pins and increasing floating-label count.
KiCAD source confirms: DEFAULT_CONNECTION_GRID_MILS = 50 and the ERC
off-grid check uses exact integer modulo against this value, so any
displacement breaks connectivity unconditionally.
Also update the kicad-source absolute path in CLAUDE.md.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
get_pin_net was a superset of get_wire_connections with the same
coordinate-based flood-fill but two extra response fields (net, query_point)
and a reference+pin input mode. Having both tools confused LLM tool selection.
get_wire_connections now:
- Returns net (label name or null) and query_point in all response paths
- Accepts reference+pin input in addition to x/y coordinates,
resolving the pin endpoint via PinLocator internally
get_pin_net tool, handler, schema, TS registration, and tests removed.
test_wire_connectivity.py updated with coverage for all new behaviour.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
Answers "what net is pin X of component Y on?" without requiring
callers to triangulate from list_schematic_nets or know a wire
coordinate first.
Accepts either {reference, pin} (resolved via PinLocator) or {x, y}
coordinate. Returns net label name (or null for unnamed nets), all
connected pins, wire segments, and the resolved query point.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
Adds a new MCP tool that snaps wire endpoints, junction positions, and
net label coordinates to the nearest grid point (default 2.54 mm). Off-grid
coordinates cause wires that appear visually connected to fail ERC checks
because KiCAD uses exact IU integer matching internally; this tool eliminates
that class of error before running ERC.
- python/commands/schematic_snap.py: core snap logic with in-place sexp mutation
- python/kicad_interface.py: route + handler
- python/schemas/tool_schemas.py: JSON schema (gridSize, elements params)
- src/tools/schematic.ts: TypeScript MCP tool registration
- tests/test_snap_to_grid.py: 20 unit + integration tests (all passing)
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
Detects wire segments with at least one dangling endpoint — an endpoint
not connected to a component pin, net label, or another wire. These
cause ERC 'wire end unconnected' violations and are a common symptom of
incomplete routing or stray stub wires.
Algorithm uses exact KiCad IU (10 000 IU/mm) coordinate matching,
consistent with wire_connectivity.py:
1. Build an endpoint-frequency map for all wires (IU precision)
2. Collect anchored IU points: component pins (via PinLocator),
net labels / global_labels, power symbol pins
(via _parse_virtual_connections)
3. An endpoint is dangling when it is touched by exactly one wire AND
is not an anchored point; the containing wire is reported
Does not require the KiCad UI to be running.
Changes:
python/commands/schematic_analysis.py — find_orphaned_wires() function
python/kicad_interface.py — handler + route registration
python/schemas/tool_schemas.py — MCP schema entry
src/tools/schematic.ts — TypeScript server.tool() call
tests/test_schematic_analysis.py — 7 integration tests
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
add_schematic_net_label now accepts optional componentRef + pinNumber to
snap the label directly to the exact pin endpoint via PinLocator, removing
all approximation risk. The response always includes actual_position and,
when snapping was used, snapped_to_pin — so the caller gets confirmation
of exactly where the label landed.
connect_to_net return type changed from bool to Dict, returning
pin_location, label_location, and wire_stub on success so agents no
longer need a separate verification call to confirm placement.
connect_passthrough updated to check result.get("success") against the
new dict return. tool_schemas.py and schematic.ts updated to match
(position is now optional, componentRef/pinNumber/labelType/orientation
added, connect_to_net schema field names corrected).
17 new unit tests in tests/test_net_label_pin_snapping.py.
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
Add isort configuration (profile=black, line_length=100) to pyproject.toml,
add isort pre-commit hook, and auto-sort imports across all Python source files.
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
Add [tool.black] config to pyproject.toml and Black hook to
.pre-commit-config.yaml (rev 26.3.1), then auto-format all Python
source and test files with line-length=100, target-version=py310.
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
- Rename add_schematic_connection → add_schematic_wire with waypoints[] parameter
- Add snapToPins (default true) to snap wire endpoints to nearest pin
- Expose add_schematic_junction as an MCP tool
- Break existing wires at new wire endpoints for T-junction support
- Remove orphaned add_connection / add_wire / get_pin_location from ConnectionManager
- Update tool registry to reflect renamed schematic tools in TS layer
- Add 76 tests for wire/junction handler dispatch, schema validation, and WireManager corner cases
- Apply Black and Prettier formatting to changed files
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
- Fix critical bug: use pin_data[0]/[1] instead of pin_data["x"]/["y"]
(get_all_symbol_pins returns List[float], not dict)
- Use index-based wire tracking to avoid fragile float list equality
- Check all polyline points (not just endpoints) during flood-fill
- Add spatial index (0.05mm grid) to replace O(n²) frontier scan
- Skip already-processed refs to avoid redundant calls for multi-unit symbols
- Include wires_out in early return when schematic has no symbols
- Add get_wire_connections schema entry to tool_schemas.py
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
KiCad's native ERC already checks for unconnected pins with better
accuracy (hierarchical sheets, bus connections, custom rules). Remove
the reimplemented version and its dead helper _parse_no_connects.
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
Eliminate repeated file parsing by extracting _extract_lib_symbols helper
that walks already-parsed sexp_data once instead of re-reading the file
per symbol via PinLocator. Support diagonal wire overlap detection using
cross-product parallelism and 1D projection. Fix wire region inclusion to
use AABB intersection for pass-through wires. Normalize view region
coordinates. Clarify tolerance docstrings across Python, TS, and schema.
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
Wires that start at a component pin but continue through the body were
incorrectly suppressed as "valid connections." Now nudges the pin endpoint
toward the other end and re-tests intersection — if the shortened segment
still hits the bbox, the wire passes through and is flagged.
Renamed the tool from check_wire_collisions to find_wires_crossing_symbols
across all layers (Python, handler, schema, TypeScript) to clarify that it
finds wires crossing over component symbols, which is unacceptable in
schematics.
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
Add five new read-only schematic analysis MCP tools:
- get_schematic_view_region: export cropped schematic region as PNG/SVG
- find_unconnected_pins: list pins with no wire/label/power connection
- find_overlapping_elements: detect duplicate symbols, stacked labels, collinear wire overlaps
- get_elements_in_region: list all symbols/wires/labels in a bounding box
- check_wire_collisions: detect wires passing through component bodies
Includes Python handler dispatch, tool schemas, TypeScript server bindings,
the schematic_analysis command module, and a full test suite (28 tests passing).
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
- add_schematic_net_label: warn in description that coords must be exact pin endpoints; recommend connect_to_net instead
- connect_to_net: stub wire direction now follows pin angle (was hardcoded +X)
- pin_locator.py: add get_pin_angle() and _get_lib_id() helpers
- new tool: get_schematic_pin_locations(schematicPath, reference) → returns exact x/y of every pin endpoint, so Claude can place labels correctly
Implements advanced trace manipulation and routing pattern copying:
- Enhanced delete_trace with net-based bulk deletion and layer filtering
- Added modify_trace to change width, layer, or net by UUID/position
- Added copy_routing_pattern to replicate routing between component groups
Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>
Issue #32 - Unknown command errors:
- Register get_board_extents in command_routes (was implemented but not registered)
- Implement find_component command with pattern matching on reference/value/footprint
- Add schemas for both commands
Issue #30 - PCB routing replication (Phase 1):
- Implement get_component_pads: returns all pads with positions, nets, shapes
- Implement get_pad_position: returns specific pad coordinates and properties
- Implement query_traces: query traces by net, layer, or bounding box
- Add schemas for all new commands
Issue #26 - Schematic workflow:
- Add missing schemas for add_schematic_connection, add_schematic_net_label,
connect_to_net, get_net_connections, and generate_netlist
Issue #19 - macOS Python path detection:
- Add Python 3.13 to version detection
- Add alternative KiCAD installation paths (user Applications, capitalization variants)
- Add Homebrew Python fallback paths for Apple Silicon and Intel Macs
- Expand platform_helper.py with same improvements
Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>