aj/OpenNest
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

Compare commits

base: aj/OpenNest:57cb37a46bd8039b77b7e19b29a60044865340a1
Branches Tags
aj/OpenNest:master
aj/OpenNest:v0.2.0 aj/OpenNest:v0.1.0
...
compare: aj/OpenNest:master
Branches Tags
aj/OpenNest:master
aj/OpenNest:v0.2.0 aj/OpenNest:v0.1.0

32 Commits
57cb37a46b ... master

Author SHA1 Message Date
aj e493d83899 feat(io): add Gravograph .CHR font reader with text-to-geometry 
Add ChrFont, a reader for Gravograph .CHR engraving fonts, plus UI to
convert placed text into engraved geometry in the CAD converter.

The .CHR files are obfuscated with a single-byte XOR. Different
GravoStyle releases use different keys (0x2F in older versions, 0xCF in
the 7000 series, and others across the font library), so the key is
auto-detected from byte 1 of the file: the font name is ASCII stored as
UTF-16LE, so the high byte of its first character is 0x00 in plaintext
and the raw byte equals the key. This reads every font in a GravoStyle
install regardless of version, not just one hardcoded key.

UI: right-clicking a text item in EntityView raises TextConvertRequested;
CadConverterForm renders it via ChrFont with H/V alignment and adds the
result on an ENGRAVE layer.

Tests use Xunit.SkippableFact and a gitignored test-config.json so the
suite points at a local .CHR file without committing proprietary assets.

Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
 2026-05-28 14:37:48 -04:00
aj 987a5e25bc Add Gravograph IS post processor 2026-05-23 12:40:53 -04:00
aj 86582d28c3 fix(io): map DXF text vertical alignment for correct rendering 
TextEntity import was only mapping HorizontalAlignment to CadText,
leaving VAlign at its default (Near/top). Middle-center text rendered
shifted to the bottom instead of vertically centered.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-23 07:17:47 -04:00
aj f064368008 fix(io): remove zero-sweep arcs during DXF import 
DXF files can contain degenerate arcs where start angle equals end angle
(zero sweep), often left as construction artifacts by CAD software.
These create spurious shapes in ShapeBuilder — e.g. SULLYS-033.dxf
showed 5 loops instead of 4 (3 cutouts + perimeter).

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-23 06:50:20 -04:00
aj 9148797897 fix(ui): remove cut-off preview debounce for immediate cursor tracking 
The 16ms timer delay made the preview feel laggy. Regenerate directly
on mouse move instead.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-23 06:50:17 -04:00
aj da77cc9270 Fix best-fit viewer bounds for angled pairs 2026-05-18 22:17:47 -04:00
aj 27f0685058 fix(engine): skip intersecting parts as obstacles during compactor push 
Parts that already overlap the moving group are now excluded from the
obstacle list so they don't block the push direction.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-17 19:07:42 -04:00
aj 53988acefc fix(io): deduplicate circles and full-circle arcs during DXF import 
Duplicate circle entities at the same location inflated pierce counts
and cut pricing (e.g. SULLYS-035 showed 9 pierces instead of 8).

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-08 13:21:03 -04:00
aj a8d90be2ea feat: add layer filter overloads to Dxf.GetGeometry() 
Add optional Func<string, bool> layerFilter parameter to ConvertEntities
and two new GetGeometry overloads (path and stream) that accept a layer
filter. This lets callers control which layers to exclude instead of
being limited to the hardcoded IsNonCutLayer check. Existing overloads
without the filter continue to use the default IsNonCutLayer behavior.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-05-08 13:21:02 -04:00
aj c25b6bc23a feat(ui): render DXF text annotations in CAD converter preview 
Extract MText and TextEntity from the CadDocument during DXF import
and render them in the EntityView. Handles text alignment (left/center/
right via InsertPoint vs AlignmentPoint) and replaces AutoCAD control
codes (%%p → ±, %%d → °, %%c → ⌀). MText formatting codes are
stripped before display.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-29 21:45:44 -04:00
aj 1c994718fb feat(io): add DWG file import support via ACadSharp DwgReader 
ACadSharp already includes DwgReader, so this wires it up across the
entire import pipeline — Dxf.Import, CadConverter drag-drop, nest
import dialog, console CLI, BOM analyzer, and training data collector.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-27 23:53:29 -04:00
aj 9d58e6fba8 fix(ui): stay on drawings tab after DXF import 
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-27 23:53:29 -04:00
aj 2bae5340f0 test: add nest invariance tests for fill count across import orientations 
Verify that filling an L-shaped part produces consistent counts
regardless of the orientation it was imported at, and that all
placed parts stay within the plate work area.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 21:32:56 -04:00
aj 0b322817d7 fix(core): use chain tolerance for entity gap check to prevent spurious rapids 
Ellipse-to-arc conversion creates tiny floating-point gaps (~0.00002")
between consecutive arc segments. ShapeBuilder chains these with
ChainTolerance (0.0001"), but ConvertGeometry checked gaps with Epsilon
(0.00001"). Gaps between these thresholds generated spurious rapid moves
that broke GraphicsPath figures, causing diagonal fill artifacts from
GDI+'s implicit figure closing.

Root cause fix: align ConvertGeometry's gap check with ShapeBuilder's
ChainTolerance so precision gaps are absorbed instead of generating rapids.

Defense-in-depth: GraphicsHelper no longer breaks figures at near-zero
rapids, protecting against any programs with residual tiny rapids.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 21:32:08 -04:00
aj e41f335c63 feat: remove duplicate arcs matching circles on same layer during DXF import 
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
 2026-04-23 10:44:54 -04:00
aj 0ab33af5d3 feat: add WeldEndpoints to ShapeBuilder for gap repair on import 
Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 10:40:43 -04:00
aj e04c9381f3 feat: add IComparable<Box> and comparison operators to Box 
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
 2026-04-23 10:36:23 -04:00
aj ceb9cc0b44 refactor: move Fraction from OpenNest.IO.Bom to OpenNest.Math 
Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
 2026-04-23 10:33:57 -04:00
aj 4cecaba83a fix(core): emit line instead of arc for near-zero sweep to avoid full-circle misinterpretation 
Near-zero-sweep arcs with large radius (e.g. from ellipse converter) have
nearly-coincident start/end points. Downstream code (ConvertProgram, Program
BoundingBox) treats coincident start/end as a full 360° circle, inflating the
bounding box and rendering wrong geometry. Emit a LinearMove when sweep is
negligible — geometrically equivalent and avoids the ambiguity. Also fix the
ellipse converter to produce lines instead of degenerate arcs at the source.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 08:50:38 -04:00
aj 4053f1f989 fix(core): arc bounding box inflated for near-zero sweep arcs 
Arcs with sweep angles smaller than Tolerance.Epsilon were treated as
full circles by IsBetweenRad's shortcut check, causing UpdateBounds to
expand the bounding box to Center ± Radius. This made zoom-to-fit zoom
out far beyond the actual part extents.

Skip cardinal angle expansion when sweep is near-zero so the bounding
box uses only the arc's start/end points.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 08:22:20 -04:00
aj ca67b1bd29 fix(io): handle flipped OCS normal on DXF ellipse import 
Ellipses with extrusion direction Z=-1 had their parametric direction
reversed, causing the curve to appear mirrored. Negate start/end
parameters when Normal.Z < 0 to correct the minor-axis traversal.

Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com>
 2026-04-23 08:22:20 -04:00
aj 199095ee43 fix(engine): canonicalize PlaceBestFitPairs builds to match BestFitCache frame 2026-04-23 08:22:20 -04:00
aj eb493d501a feat(engine): wrap single-item Fill with canonicalize/un-rotate bookends 2026-04-23 08:22:20 -04:00
aj 6c98732117 feat(engine): BestFitCache operates in canonical frame; TryPlaceBestFitPair builds from canonical drawing 2026-04-23 08:22:20 -04:00
aj a2e9fd4d14 feat(engine): extract ML features from canonical drawing frame 2026-04-23 08:22:20 -04:00
aj d228b6b812 refactor(engine): share MBR between PartClassifier and CanonicalAngle 2026-04-23 08:22:20 -04:00
aj c634aecd4b docs(core): refresh SourceInfo.Angle doc now that setter wiring lands 2026-04-23 08:22:19 -04:00
aj 14b7c1cf32 feat(core): store Source.Angle; recompute when Program changes 2026-04-23 08:22:19 -04:00
aj 402af91af5 feat(engine): add CanonicalFrame helper for drawing-to-canonical rotation 2026-04-23 08:22:19 -04:00
aj 9a6b656e3c feat(core): add CanonicalAngle helper for MBR-aligning angle 2026-04-23 08:22:19 -04:00
aj d2f9597b0c refactor(fill): use native entity geometry for linear copy distance 
Replaces PartBoundary polygon edges with PartGeometry.GetOffsetPerimeterEntities
(inflated Line/Arc entities) so arcs are handled exactly without the polygon
sampling error that previously required a bboxDim + PartSpacing clamp. Adds
bbox DirectionalGap / PerpendicularOverlap early-outs to skip pair checks
that can't produce a valid slide, and removes the now-unused PartBoundary
cache, GetPatternLines/GetOffsetPatternLines helpers, and ComputeCopyDistance
clamp.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
 2026-04-16 23:26:21 -04:00
aj c40dcf0e25 chore: remove unused debug logging to desktop 
NfpSlideStrategy wrote to nfp-slide-debug.log on the Desktop on every
call. The console's SetUpLog created test-harness-logs/ next to input
files but nothing in the codebase wrote to Trace, so those files were
always empty. Drop both along with the --no-log flag.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
 2026-04-16 23:24:40 -04:00
67 changed files with 4411 additions and 329 deletions
Expand all files Collapse all files
.gitignore
+3
View File
@@ -213,3 +213,6 @@ docs/superpowers/
# Launch settings
**/Properties/launchSettings.json
# Local test config (contains user-specific paths to proprietary test assets)
OpenNest.Tests/test-config.json
OpenNest.Console/Program.cs
+4 -28
View File
@@ -41,7 +41,6 @@ static class NestConsole
}
}
using var log = SetUpLog(options);
var nest = LoadOrCreateNest(options);
if (nest == null)
@@ -68,10 +67,6 @@ static class NestConsole
var overlapCount = CheckOverlaps(plate, options);
// Flush and close the log before printing results.
Trace.Flush();
log?.Dispose();
PrintResults(success, plate, elapsed);
Save(nest, options);
PostProcess(nest, options);
@@ -112,9 +107,6 @@ static class NestConsole
case "--no-save":
o.NoSave = true;
break;
case "--no-log":
o.NoLog = true;
break;
case "--keep-parts":
o.KeepParts = true;
break;
@@ -153,28 +145,14 @@ static class NestConsole
return o;
}
static StreamWriter SetUpLog(Options options)
{
if (options.NoLog)
return null;
var baseDir = Path.GetDirectoryName(options.InputFiles[0]);
var logDir = Path.Combine(baseDir, "test-harness-logs");
Directory.CreateDirectory(logDir);
var logFile = Path.Combine(logDir, $"debug-{DateTime.Now:yyyyMMdd-HHmmss}.log");
var writer = new StreamWriter(logFile) { AutoFlush = true };
Trace.Listeners.Add(new TextWriterTraceListener(writer));
Console.WriteLine($"Debug log: {logFile}");
return writer;
}
static Nest LoadOrCreateNest(Options options)
{
var nestFile = options.InputFiles.FirstOrDefault(f =>
f.EndsWith(NestFormat.FileExtension, StringComparison.OrdinalIgnoreCase)
|| f.EndsWith(".zip", StringComparison.OrdinalIgnoreCase));
var dxfFiles = options.InputFiles.Where(f =>
f.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase)).ToList();
f.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase) ||
f.EndsWith(".dwg", StringComparison.OrdinalIgnoreCase)).ToList();
// If we have a nest file, load it and optionally add DXFs.
if (nestFile != null)
@@ -210,7 +188,7 @@ static class NestConsole
// DXF-only mode: create a fresh nest.
if (dxfFiles.Count == 0)
{
Console.Error.WriteLine("Error: no nest (.nest) or DXF (.dxf) files specified");
Console.Error.WriteLine("Error: no nest (.nest) or CAD (.dxf/.dwg) files specified");
return null;
}
@@ -484,7 +462,7 @@ static class NestConsole
Console.Error.WriteLine("Usage: OpenNest.Console <input-files...> [options]");
Console.Error.WriteLine();
Console.Error.WriteLine("Arguments:");
Console.Error.WriteLine(" input-files One or more .nest nest files or .dxf drawing files");
Console.Error.WriteLine(" input-files One or more .nest nest files or .dxf/.dwg drawing files");
Console.Error.WriteLine();
Console.Error.WriteLine("Modes:");
Console.Error.WriteLine(" <nest.nest> Load nest and fill (existing behavior)");
@@ -503,7 +481,6 @@ static class NestConsole
Console.Error.WriteLine(" --keep-parts Don't clear existing parts before filling");
Console.Error.WriteLine(" --check-overlaps Run overlap detection after fill (exit code 1 if found)");
Console.Error.WriteLine(" --no-save Skip saving output file");
Console.Error.WriteLine(" --no-log Skip writing debug log file");
Console.Error.WriteLine(" --post <name> Run a post processor after nesting");
Console.Error.WriteLine(" --post-output <path> Output file for post processor (default: <input>.cnc)");
Console.Error.WriteLine(" --posts-dir <path> Directory containing post processor DLLs (default: Posts/)");
@@ -522,7 +499,6 @@ static class NestConsole
public Size? PlateSize;
public bool CheckOverlaps;
public bool NoSave;
public bool NoLog;
public bool KeepParts;
public bool AutoNest;
public string TemplateFile;
OpenNest.Core/CanonicalAngle.cs
+78
View File
@@ -0,0 +1,78 @@
using OpenNest.Converters;
using OpenNest.Geometry;
using System.Linq;
namespace OpenNest
{
/// <summary>
/// Computes the rotation that maps a drawing to its canonical (MBR-axis-aligned) frame.
/// Lives in OpenNest.Core so Drawing.Program setter can invoke it directly without
/// a circular dependency on OpenNest.Engine.
/// </summary>
public static class CanonicalAngle
{
/// <summary>Angles with |v| below this (radians) are snapped to 0.</summary>
public const double SnapToZero = 0.001;
/// <summary>
/// Derives the canonical angle from a pre-computed MBR. Used both by Compute (which
/// computes the MBR itself) and by PartClassifier (which already has one). Single formula
/// across both callers.
/// </summary>
public static double FromMbr(BoundingRectangleResult mbr)
{
if (mbr.Area <= OpenNest.Math.Tolerance.Epsilon)
return 0.0;
// The MBR edge angle can represent any of four equivalent orientations
// (edge-i, edge-i + π/2, edge-i + π, edge-i - π/2) depending on which hull
// edge the algorithm happened to pick. Normalize -mbr.Angle to the
// representative in [-π/4, π/4] so snap-to-zero works for inputs near
// ANY of the equivalent orientations.
var angle = -mbr.Angle;
const double halfPi = System.Math.PI / 2.0;
angle -= halfPi * System.Math.Round(angle / halfPi);
if (System.Math.Abs(angle) < SnapToZero)
return 0.0;
return angle;
}
public static double Compute(Drawing drawing)
{
if (drawing?.Program == null)
return 0.0;
var entities = ConvertProgram.ToGeometry(drawing.Program)
.Where(e => e.Layer != SpecialLayers.Rapid);
var shapes = ShapeBuilder.GetShapes(entities);
if (shapes.Count == 0)
return 0.0;
var perimeter = shapes[0];
var perimeterArea = perimeter.Area();
for (var i = 1; i < shapes.Count; i++)
{
var area = shapes[i].Area();
if (area > perimeterArea)
{
perimeter = shapes[i];
perimeterArea = area;
}
}
var polygon = perimeter.ToPolygonWithTolerance(0.1);
if (polygon == null || polygon.Vertices.Count < 3)
return 0.0;
var hull = ConvexHull.Compute(polygon.Vertices);
if (hull.Vertices.Count < 3)
return 0.0;
var mbr = RotatingCalipers.MinimumBoundingRectangle(hull);
return FromMbr(mbr);
}
}
}
OpenNest.Core/Converters/ConvertGeometry.cs
+14 -4
View File
@@ -1,5 +1,6 @@
using OpenNest.CNC;
using OpenNest.Geometry;
using OpenNest.Math;
using System.Collections.Generic;
namespace OpenNest.Converters
@@ -81,12 +82,21 @@ namespace OpenNest.Converters
var startpt = arc.StartPoint();
var endpt = arc.EndPoint();
if (startpt != lastpt)
if (startpt.DistanceTo(lastpt) > Tolerance.ChainTolerance)
pgm.MoveTo(startpt);
lastpt = endpt;
pgm.ArcTo(endpt, arc.Center, arc.IsReversed ? RotationType.CW : RotationType.CCW);
var sweep = System.Math.Abs(arc.SweepAngle());
if (sweep < Tolerance.Epsilon || sweep.IsEqualTo(Angle.TwoPI))
{
pgm.LineTo(endpt);
}
else
{
pgm.ArcTo(endpt, arc.Center, arc.IsReversed ? RotationType.CW : RotationType.CCW);
}
return lastpt;
}
@@ -94,7 +104,7 @@ namespace OpenNest.Converters
{
var startpt = new Vector(circle.Center.X + circle.Radius, circle.Center.Y);
if (startpt != lastpt)
if (startpt.DistanceTo(lastpt) > Tolerance.ChainTolerance)
pgm.MoveTo(startpt);
pgm.ArcTo(startpt, circle.Center, circle.Rotation);
@@ -105,7 +115,7 @@ namespace OpenNest.Converters
private static Vector AddLine(Program pgm, Vector lastpt, Line line)
{
if (line.StartPoint != lastpt)
if (line.StartPoint.DistanceTo(lastpt) > Tolerance.ChainTolerance)
pgm.MoveTo(line.StartPoint);
var move = new LinearMove(line.EndPoint);
OpenNest.Core/Drawing.cs
+31 -1
View File
@@ -54,9 +54,9 @@ namespace OpenNest
Id = Interlocked.Increment(ref nextId);
Name = name;
Material = new Material();
Program = pgm;
Constraints = new NestConstraints();
Source = new SourceInfo();
Program = pgm;
}
public int Id { get; }
@@ -78,9 +78,29 @@ namespace OpenNest
{
program = value;
UpdateArea();
RecomputeCanonicalAngle();
}
}
/// <summary>
/// Recomputes and stores the canonical angle from the current Program.
/// Callers that mutate Program in place (rather than reassigning it) must invoke this explicitly.
/// Cut-off drawings are left with Angle=0.
/// </summary>
public void RecomputeCanonicalAngle()
{
if (Source == null)
Source = new SourceInfo();
if (program == null || IsCutOff)
{
Source.Angle = 0.0;
return;
}
Source.Angle = CanonicalAngle.Compute(this);
}
public Color Color { get; set; }
public bool IsCutOff { get; set; }
@@ -163,5 +183,15 @@ namespace OpenNest
/// Offset distances to the original location.
/// </summary>
public Vector Offset { get; set; }
/// <summary>
/// Rotation (radians) that maps the source program geometry to its canonical
/// (MBR-axis-aligned) frame. Populated automatically by the <see cref="Drawing.Program"/>
/// setter via <see cref="CanonicalAngle.Compute"/>. A value of 0 means the drawing is
/// already canonical or <see cref="Drawing.IsCutOff"/> is true. Callers that mutate
/// <see cref="Drawing.Program"/> in place must invoke
/// <see cref="Drawing.RecomputeCanonicalAngle"/> to refresh.
/// </summary>
public double Angle { get; set; }
}
}
OpenNest.Core/Geometry/Arc.cs
+20 -14
View File
@@ -93,6 +93,9 @@ namespace OpenNest.Geometry
}
}
public bool IsFullCircle() =>
SweepAngle() >= Angle.TwoPI - Tolerance.Epsilon;
/// <summary>
/// Angle in radians between start and end angles.
/// </summary>
@@ -404,26 +407,29 @@ namespace OpenNest.Geometry
maxY = startpt.Y;
}
var angle1 = StartAngle;
var angle2 = EndAngle;
var sweep = SweepAngle();
if (sweep > Tolerance.Epsilon)
{
var angle1 = StartAngle;
var angle2 = EndAngle;
// switch the angle to counter clockwise.
if (IsReversed)
Generic.Swap(ref angle1, ref angle2);
if (IsReversed)
Generic.Swap(ref angle1, ref angle2);
if (Angle.IsBetweenRad(Angle.HalfPI, angle1, angle2))
maxY = Center.Y + Radius;
if (Angle.IsBetweenRad(Angle.HalfPI, angle1, angle2))
maxY = Center.Y + Radius;
if (Angle.IsBetweenRad(System.Math.PI, angle1, angle2))
minX = Center.X - Radius;
if (Angle.IsBetweenRad(System.Math.PI, angle1, angle2))
minX = Center.X - Radius;
const double oneHalfPI = System.Math.PI * 1.5;
const double oneHalfPI = System.Math.PI * 1.5;
if (Angle.IsBetweenRad(oneHalfPI, angle1, angle2))
minY = Center.Y - Radius;
if (Angle.IsBetweenRad(oneHalfPI, angle1, angle2))
minY = Center.Y - Radius;
if (Angle.IsBetweenRad(Angle.TwoPI, angle1, angle2))
maxX = Center.X + Radius;
if (Angle.IsBetweenRad(Angle.TwoPI, angle1, angle2))
maxX = Center.X + Radius;
}
boundingBox.X = minX;
boundingBox.Y = minY;
OpenNest.Core/Geometry/Box.cs
+17 -2
View File
@@ -1,8 +1,9 @@
using OpenNest.Math;
using System;
using OpenNest.Math;
namespace OpenNest.Geometry
{
public class Box
public class Box : IComparable<Box>
{
public static readonly Box Empty = new Box();
@@ -214,5 +215,19 @@ namespace OpenNest.Geometry
{
return string.Format("[Box: X={0}, Y={1}, Width={2}, Length={3}]", X, Y, Width, Length);
}
public int CompareTo(Box other)
{
var cmp = Width.CompareTo(other.Width);
return cmp != 0 ? cmp : Length.CompareTo(other.Length);
}
public static bool operator >(Box a, Box b) => a.CompareTo(b) > 0;
public static bool operator <(Box a, Box b) => a.CompareTo(b) < 0;
public static bool operator >=(Box a, Box b) => a.CompareTo(b) >= 0;
public static bool operator <=(Box a, Box b) => a.CompareTo(b) <= 0;
}
}
OpenNest.Core/Geometry/EllipseConverter.cs
+5 -1
View File
@@ -173,7 +173,11 @@ namespace OpenNest.Geometry
if (maxDev <= tolerance)
{
results.Add(CreateArc(arcCenter, radius, center, semiMajor, semiMinor, rotation, t0, t1));
var arc = CreateArc(arcCenter, radius, center, semiMajor, semiMinor, rotation, t0, t1);
if (arc.SweepAngle() < Tolerance.Epsilon)
results.Add(new Line(p0, p1));
else
results.Add(arc);
}
else
{
OpenNest.Core/Geometry/GeometryOptimizer.cs
+32
View File
@@ -17,6 +17,38 @@ namespace OpenNest.Geometry
(list, item, i) => list.GetCollinearLines(item, i),
(Line a, Line b, out Line joined) => TryJoinLines(a, b, out joined));
public static void Deduplicate(IList<Circle> circles)
{
for (var i = circles.Count - 1; i >= 1; i--)
{
for (var j = i - 1; j >= 0; j--)
{
if (circles[i].Center.DistanceTo(circles[j].Center) <= Tolerance.Epsilon
&& circles[i].Radius.IsEqualTo(circles[j].Radius))
{
circles.RemoveAt(i);
break;
}
}
}
}
public static void Deduplicate(IList<Circle> circles, IList<Arc> arcs)
{
for (var i = circles.Count - 1; i >= 0; i--)
{
for (var j = arcs.Count - 1; j >= 0; j--)
{
if (arcs[j].Center.DistanceTo(circles[i].Center) <= Tolerance.Epsilon
&& arcs[j].Radius.IsEqualTo(circles[i].Radius)
&& arcs[j].IsFullCircle())
{
arcs.RemoveAt(j);
}
}
}
}
private delegate bool TryJoin<T>(T a, T b, out T joined);
private static void MergePass<T>(IList<T> items,
OpenNest.Core/Geometry/ShapeBuilder.cs
+92 -1
View File
@@ -1,12 +1,13 @@
using OpenNest.Math;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
namespace OpenNest.Geometry
{
public static class ShapeBuilder
{
public static List<Shape> GetShapes(IEnumerable<Entity> entities)
public static List<Shape> GetShapes(IEnumerable<Entity> entities, double? weldTolerance = null)
{
var lines = new List<Line>();
var arcs = new List<Arc>();
@@ -57,6 +58,9 @@ namespace OpenNest.Geometry
entityList.AddRange(lines);
entityList.AddRange(arcs);
if (weldTolerance.HasValue)
WeldEndpoints(entityList, weldTolerance.Value);
while (entityList.Count > 0)
{
var next = entityList[0];
@@ -107,6 +111,93 @@ namespace OpenNest.Geometry
return shapes;
}
public static void WeldEndpoints(List<Entity> entities, double tolerance)
{
var endpointGroups = new List<List<(Entity entity, bool isStart, Vector point)>>();
foreach (var entity in entities)
{
var (start, end) = GetEndpoints(entity);
if (!start.IsValid() || !end.IsValid())
continue;
AddToGroup(endpointGroups, entity, true, start, tolerance);
AddToGroup(endpointGroups, entity, false, end, tolerance);
}
foreach (var group in endpointGroups)
{
if (group.Count <= 1)
continue;
var avgX = group.Average(g => g.point.X);
var avgY = group.Average(g => g.point.Y);
var weldedPoint = new Vector(avgX, avgY);
foreach (var (entity, isStart, _) in group)
ApplyWeld(entity, isStart, weldedPoint);
}
}
private static void AddToGroup(
List<List<(Entity entity, bool isStart, Vector point)>> groups,
Entity entity, bool isStart, Vector point, double tolerance)
{
foreach (var group in groups)
{
if (group[0].point.DistanceTo(point) <= tolerance)
{
group.Add((entity, isStart, point));
return;
}
}
groups.Add(new List<(Entity, bool, Vector)> { (entity, isStart, point) });
}
private static (Vector start, Vector end) GetEndpoints(Entity entity)
{
switch (entity.Type)
{
case EntityType.Arc:
var arc = (Arc)entity;
return (arc.StartPoint(), arc.EndPoint());
case EntityType.Line:
var line = (Line)entity;
return (line.StartPoint, line.EndPoint);
default:
return (Vector.Invalid, Vector.Invalid);
}
}
private static void ApplyWeld(Entity entity, bool isStart, Vector weldedPoint)
{
switch (entity.Type)
{
case EntityType.Line:
var line = (Line)entity;
if (isStart)
line.StartPoint = weldedPoint;
else
line.EndPoint = weldedPoint;
break;
case EntityType.Arc:
var arc = (Arc)entity;
var deltaX = weldedPoint.X - arc.Center.X;
var deltaY = weldedPoint.Y - arc.Center.Y;
var angle = System.Math.Atan2(deltaY, deltaX);
if (isStart)
arc.StartAngle = angle;
else
arc.EndAngle = angle;
break;
}
}
internal static Entity GetConnected(Vector pt, IEnumerable<Entity> geometry)
{
var tol = Tolerance.ChainTolerance;
OpenNest.IO/Bom/Fraction.cs → OpenNest.Core/Math/Fraction.cs
+1 -1
View File
@@ -3,7 +3,7 @@ using System.Linq;
using System.Text;
using System.Text.RegularExpressions;
namespace OpenNest.IO.Bom
namespace OpenNest.Math
{
public static class Fraction
{
OpenNest.Engine/BestFit/BestFitCache.cs
+10 -4
View File
@@ -24,6 +24,9 @@ namespace OpenNest.Engine.BestFit
if (_cache.TryGetValue(key, out var cached))
return cached;
// Operate on the canonical frame so cached pair positions are orientation-invariant.
var canonical = CanonicalFrame.AsCanonicalCopy(drawing);
IPairEvaluator evaluator = null;
ISlideComputer slideComputer = null;
@@ -31,7 +34,7 @@ namespace OpenNest.Engine.BestFit
{
if (CreateEvaluator != null)
{
try { evaluator = CreateEvaluator(drawing, spacing); }
try { evaluator = CreateEvaluator(canonical, spacing); }
catch { /* fall back to default evaluator */ }
}
@@ -42,7 +45,7 @@ namespace OpenNest.Engine.BestFit
}
var finder = new BestFitFinder(plateWidth, plateHeight, evaluator, slideComputer);
var results = finder.FindBestFits(drawing, spacing, StepSize);
var results = finder.FindBestFits(canonical, spacing, StepSize);
_cache.TryAdd(key, results);
return results;
@@ -86,9 +89,12 @@ namespace OpenNest.Engine.BestFit
try
{
// Operate on the canonical frame so cached pair positions are orientation-invariant.
var canonical = CanonicalFrame.AsCanonicalCopy(drawing);
if (CreateEvaluator != null)
{
try { evaluator = CreateEvaluator(drawing, spacing); }
try { evaluator = CreateEvaluator(canonical, spacing); }
catch { /* fall back to default evaluator */ }
}
@@ -100,7 +106,7 @@ namespace OpenNest.Engine.BestFit
// Compute candidates and evaluate once with the largest plate.
var finder = new BestFitFinder(maxWidth, maxHeight, evaluator, slideComputer);
var baseResults = finder.FindBestFits(drawing, spacing, StepSize);
var baseResults = finder.FindBestFits(canonical, spacing, StepSize);
// Cache a filtered copy for each plate size.
foreach (var size in needed)
OpenNest.Engine/BestFit/BestFitResult.cs
+65
View File
@@ -1,6 +1,9 @@
using OpenNest.Engine;
using OpenNest.Converters;
using OpenNest.Geometry;
using OpenNest.Math;
using System.Collections.Generic;
using System.Linq;
namespace OpenNest.Engine.BestFit
{
@@ -54,6 +57,68 @@ namespace OpenNest.Engine.BestFit
return new List<Part> { part1, part2 };
}
public List<Part> BuildCanonicalParts()
{
return NormalizeToCutOrigin(BuildParts(Candidate.Drawing));
}
public List<Part> BuildSourceParts(Drawing drawing)
{
var parts = BuildCanonicalParts();
var sourceAngle = drawing?.Source?.Angle ?? 0.0;
for (var i = 0; i < parts.Count; i++)
{
var p = parts[i];
var rebound = Part.CreateAtOrigin(drawing, p.Rotation);
var delta = p.BoundingBox.Location - rebound.BoundingBox.Location;
rebound.Offset(delta);
rebound.UpdateBounds();
parts[i] = rebound;
}
return NormalizeToCutOrigin(CanonicalFrame.FromCanonical(parts, sourceAngle));
}
public Box GetCutBounds(List<Part> parts)
{
return GetCutBoundingBox(parts);
}
private static List<Part> NormalizeToCutOrigin(List<Part> parts)
{
if (parts == null || parts.Count == 0)
return parts;
var bounds = GetCutBoundingBox(parts);
var offset = new Vector(-bounds.Left, -bounds.Bottom);
foreach (var part in parts)
part.Offset(offset);
return parts;
}
private static Box GetCutBoundingBox(List<Part> parts)
{
var entities = new List<IBoundable>();
foreach (var part in parts)
{
var partEntities = ConvertProgram.ToGeometry(part.Program)
.Where(e => e.Layer != SpecialLayers.Rapid)
.ToList();
foreach (var entity in partEntities)
{
entity.Offset(part.Location);
entities.Add(entity);
}
}
return entities.GetBoundingBox();
}
}
public enum BestFitSortField
OpenNest.Engine/BestFit/NfpSlideStrategy.cs
-66
View File
@@ -1,18 +1,10 @@
using OpenNest.Geometry;
using OpenNest.Math;
using System.Collections.Generic;
using System.IO;
namespace OpenNest.Engine.BestFit
{
public class NfpSlideStrategy : IBestFitStrategy
{
private static readonly string LogPath = Path.Combine(
System.Environment.GetFolderPath(System.Environment.SpecialFolder.Desktop),
"nfp-slide-debug.log");
private static readonly object LogLock = new object();
private readonly double _part2Rotation;
private readonly Polygon _stationaryPerimeter;
private readonly Polygon _stationaryHull;
@@ -46,12 +38,6 @@ namespace OpenNest.Engine.BestFit
var hull = ConvexHull.Compute(result.Polygon.Vertices);
Log($"=== Create: drawing={drawing.Name}, rotation={Angle.ToDegrees(part2Rotation):F1}deg ===");
Log($" Perimeter: {result.Polygon.Vertices.Count} verts, bounds={FormatBounds(result.Polygon)}");
Log($" Hull: {hull.Vertices.Count} verts, bounds={FormatBounds(hull)}");
Log($" Correction: ({result.Correction.X:F4}, {result.Correction.Y:F4})");
Log($" ProgramBBox: {drawing.Program.BoundingBox()}");
return new NfpSlideStrategy(part2Rotation, type, description,
result.Polygon, hull, result.Correction);
}
@@ -63,40 +49,17 @@ namespace OpenNest.Engine.BestFit
if (stepSize <= 0)
return candidates;
Log($"--- GenerateCandidates: drawing={drawing.Name}, part2Rot={Angle.ToDegrees(_part2Rotation):F1}deg, spacing={spacing}, stepSize={stepSize} ---");
// Orbiting polygon: same shape rotated to Part2's angle.
var orbitingPerimeter = PolygonHelper.RotatePolygon(_stationaryPerimeter, _part2Rotation, reNormalize: true);
var orbitingPoly = ConvexHull.Compute(orbitingPerimeter.Vertices);
Log($" Stationary hull: {_stationaryHull.Vertices.Count} verts, bounds={FormatBounds(_stationaryHull)}");
Log($" Orbiting perimeter (rotated): {orbitingPerimeter.Vertices.Count} verts, bounds={FormatBounds(orbitingPerimeter)}");
Log($" Orbiting hull: {orbitingPoly.Vertices.Count} verts, bounds={FormatBounds(orbitingPoly)}");
var nfp = NoFitPolygon.ComputeConvex(_stationaryHull, orbitingPoly);
if (nfp == null || nfp.Vertices.Count < 3)
{
Log($" NFP failed or degenerate (verts={nfp?.Vertices.Count ?? 0})");
return candidates;
}
var verts = nfp.Vertices;
var vertCount = nfp.IsClosed() ? verts.Count - 1 : verts.Count;
Log($" NFP: {verts.Count} verts (closed={nfp.IsClosed()}, walking {vertCount}), bounds={FormatBounds(nfp)}");
Log($" Correction: ({_correction.X:F4}, {_correction.Y:F4})");
// Log NFP vertices
for (var v = 0; v < vertCount; v++)
Log($" NFP vert[{v}]: ({verts[v].X:F4}, {verts[v].Y:F4}) -> corrected: ({verts[v].X - _correction.X:F4}, {verts[v].Y - _correction.Y:F4})");
// Compare with what RotationSlideStrategy would produce
var part1 = Part.CreateAtOrigin(drawing);
var part2 = Part.CreateAtOrigin(drawing, _part2Rotation);
Log($" Part1 (rot=0): loc=({part1.Location.X:F4}, {part1.Location.Y:F4}), bbox={part1.BoundingBox}");
Log($" Part2 (rot={Angle.ToDegrees(_part2Rotation):F1}): loc=({part2.Location.X:F4}, {part2.Location.Y:F4}), bbox={part2.BoundingBox}");
var testNumber = 0;
for (var i = 0; i < vertCount; i++)
@@ -125,20 +88,6 @@ namespace OpenNest.Engine.BestFit
}
}
// Log overlap check for vertex candidates (first few)
var checkCount = System.Math.Min(vertCount, 8);
for (var c = 0; c < checkCount; c++)
{
var cand = candidates[c];
var p2 = Part.CreateAtOrigin(drawing, cand.Part2Rotation);
p2.Location = cand.Part2Offset;
var overlaps = part1.Intersects(p2, out _);
Log($" Candidate[{c}]: offset=({cand.Part2Offset.X:F4}, {cand.Part2Offset.Y:F4}), overlaps={overlaps}");
}
Log($" Total candidates: {candidates.Count}");
Log("");
return candidates;
}
@@ -160,20 +109,5 @@ namespace OpenNest.Engine.BestFit
Spacing = spacing
};
}
private static string FormatBounds(Polygon polygon)
{
polygon.UpdateBounds();
var bb = polygon.BoundingBox;
return $"[({bb.Left:F4}, {bb.Bottom:F4})-({bb.Right:F4}, {bb.Top:F4}), {bb.Width:F2}x{bb.Length:F2}]";
}
private static void Log(string message)
{
lock (LogLock)
{
File.AppendAllText(LogPath, message + "\n");
}
}
}
}
OpenNest.Engine/CanonicalFrame.cs
+76
View File
@@ -0,0 +1,76 @@
using OpenNest.CNC;
using OpenNest.Geometry;
using OpenNest.Math;
using System.Collections.Generic;
namespace OpenNest.Engine
{
/// <summary>
/// Produces transient canonical (MBR-axis-aligned) copies of drawings for engine consumption
/// and un-rotates placed parts back to the drawing's original frame.
/// </summary>
public static class CanonicalFrame
{
/// <summary>
/// Returns a new Drawing whose Program geometry is rotated to the canonical frame.
/// The source drawing is not mutated.
/// </summary>
public static Drawing AsCanonicalCopy(Drawing drawing)
{
if (drawing == null)
return null;
var angle = drawing.Source?.Angle ?? 0.0;
// Clone program (never mutate the source).
var pgm = (drawing.Program.Clone() as OpenNest.CNC.Program)
?? new OpenNest.CNC.Program();
if (!Tolerance.IsEqualTo(angle, 0))
pgm.Rotate(angle, pgm.BoundingBox().Center);
var copy = new Drawing(drawing.Name ?? string.Empty, pgm)
{
Color = drawing.Color,
Constraints = drawing.Constraints,
Material = drawing.Material,
Priority = drawing.Priority,
Customer = drawing.Customer,
IsCutOff = drawing.IsCutOff,
Source = new SourceInfo
{
Path = drawing.Source?.Path,
Offset = drawing.Source?.Offset ?? new Vector(0, 0),
Angle = 0.0,
},
};
return copy;
}
/// <summary>
/// Composes the source drawing's canonical angle onto each placed part so the
/// returned list is in the drawing's original (visible) frame.
///
/// Derivation: let sourceAngle = S (rotation mapping source -> canonical).
/// Canonical part at rotation R shows visible orientation R.
/// Source part at rotation R' shows visible orientation R' + (-S), because the
/// source geometry is already rotated by -S relative to canonical.
/// Setting equal gives R' = R + S, so we ADD sourceAngle to each placed part.
///
/// Rotation is performed around the part's Location so its placement position is preserved;
/// only the orientation composes.
/// </summary>
public static List<Part> FromCanonical(List<Part> placed, double sourceAngle)
{
if (placed == null || placed.Count == 0)
return placed;
if (Tolerance.IsEqualTo(sourceAngle, 0))
return placed;
foreach (var p in placed)
p.Rotate(sourceAngle, p.Location);
return placed;
}
}
}
OpenNest.Engine/DefaultNestEngine.cs
+63 -19
View File
@@ -47,14 +47,29 @@ namespace OpenNest
PhaseResults.Clear();
AngleResults.Clear();
// Fast path: for very small quantities, skip the full strategy pipeline.
if (item.Quantity > 0 && item.Quantity <= 2)
// Replace the item's Drawing with a canonical copy for the duration of this fill.
// All internal methods see canonical geometry; this wrapper un-canonicalizes the final result.
var sourceAngle = item.Drawing?.Source?.Angle ?? 0.0;
var originalDrawing = item.Drawing;
var canonicalItem = new NestItem
{
var fast = TryFillSmallQuantity(item, workArea);
if (fast != null && fast.Count >= item.Quantity)
Drawing = CanonicalFrame.AsCanonicalCopy(item.Drawing),
Quantity = item.Quantity,
Priority = item.Priority,
RotationStart = item.RotationStart,
RotationEnd = item.RotationEnd,
StepAngle = item.StepAngle,
};
// Fast path for qty 1-2.
if (canonicalItem.Quantity > 0 && canonicalItem.Quantity <= 2)
{
var fast = TryFillSmallQuantity(canonicalItem, workArea);
if (fast != null && fast.Count >= canonicalItem.Quantity)
{
Debug.WriteLine($"[Fill] Fast path: placed {fast.Count} parts for qty={item.Quantity}");
Debug.WriteLine($"[Fill] Fast path: placed {fast.Count} parts for qty={canonicalItem.Quantity}");
WinnerPhase = NestPhase.Pairs;
fast = RebindAndUnCanonicalize(fast, originalDrawing, sourceAngle);
ReportProgress(progress, new ProgressReport
{
Phase = WinnerPhase,
@@ -68,32 +83,30 @@ namespace OpenNest
}
}
// For low quantities, shrink the work area in both dimensions to avoid
// running expensive strategies against the full plate.
var effectiveWorkArea = workArea;
if (item.Quantity > 0)
if (canonicalItem.Quantity > 0)
{
effectiveWorkArea = ShrinkWorkArea(item, workArea, Plate.PartSpacing);
effectiveWorkArea = ShrinkWorkArea(canonicalItem, workArea, Plate.PartSpacing);
if (effectiveWorkArea != workArea)
Debug.WriteLine($"[Fill] Low-qty shrink: {item.Quantity} requested, " +
Debug.WriteLine($"[Fill] Low-qty shrink: {canonicalItem.Quantity} requested, " +
$"from {workArea.Width:F1}x{workArea.Length:F1} " +
$"to {effectiveWorkArea.Width:F1}x{effectiveWorkArea.Length:F1}");
}
var best = RunFillPipeline(item, effectiveWorkArea, progress, token);
var best = RunFillPipeline(canonicalItem, effectiveWorkArea, progress, token);
// Fallback: if the reduced area didn't yield enough, retry with full area.
if (item.Quantity > 0 && best.Count < item.Quantity && effectiveWorkArea != workArea)
if (canonicalItem.Quantity > 0 && best.Count < canonicalItem.Quantity && effectiveWorkArea != workArea)
{
Debug.WriteLine($"[Fill] Low-qty fallback: got {best.Count}, need {item.Quantity}, retrying full area");
Debug.WriteLine($"[Fill] Low-qty fallback: got {best.Count}, need {canonicalItem.Quantity}, retrying full area");
PhaseResults.Clear();
AngleResults.Clear();
best = RunFillPipeline(item, workArea, progress, token);
best = RunFillPipeline(canonicalItem, workArea, progress, token);
}
if (item.Quantity > 0 && best.Count > item.Quantity)
best = ShrinkFiller.TrimToCount(best, item.Quantity, TrimAxis);
if (canonicalItem.Quantity > 0 && best.Count > canonicalItem.Quantity)
best = ShrinkFiller.TrimToCount(best, canonicalItem.Quantity, TrimAxis);
best = RebindAndUnCanonicalize(best, originalDrawing, sourceAngle);
ReportProgress(progress, new ProgressReport
{
@@ -108,6 +121,31 @@ namespace OpenNest
return best;
}
/// <summary>
/// Single exit point for canonical -> source frame conversion. Rebinds every Part to the
/// original Drawing (so consumers see the user's drawing identity, not the transient canonical copy)
/// and composes sourceAngle onto each Part's rotation via CanonicalFrame.FromCanonical.
/// </summary>
private static List<Part> RebindAndUnCanonicalize(List<Part> parts, Drawing original, double sourceAngle)
{
if (parts == null || parts.Count == 0)
return parts;
for (var i = 0; i < parts.Count; i++)
{
var p = parts[i];
// Rebind to `original` while preserving world pose. CreateAtOrigin rotates
// at the origin (keeping bbox at world (0,0)) then we offset to match p's bbox.
var rebound = Part.CreateAtOrigin(original, p.Rotation);
var delta = p.BoundingBox.Location - rebound.BoundingBox.Location;
rebound.Offset(delta);
rebound.UpdateBounds();
parts[i] = rebound;
}
return CanonicalFrame.FromCanonical(parts, sourceAngle);
}
/// <summary>
/// Fast path for qty 1-2: place a single part or a best-fit pair
/// without running the full strategy pipeline.
@@ -139,6 +177,10 @@ namespace OpenNest
var bestFits = BestFitCache.GetOrCompute(
drawing, Plate.Size.Length, Plate.Size.Width, Plate.PartSpacing);
// Build pair candidates with a canonical drawing so their geometry matches
// the coordinate frame of the cached fit results.
var canonicalDrawing = CanonicalFrame.AsCanonicalCopy(drawing);
List<Part> bestPlacement = null;
foreach (var fit in bestFits)
@@ -152,7 +194,7 @@ namespace OpenNest
if (fit.LongestSide > System.Math.Max(workArea.Width, workArea.Length) + Tolerance.Epsilon)
continue;
var landscape = fit.BuildParts(drawing);
var landscape = fit.BuildParts(canonicalDrawing);
var portrait = RotatePair90(landscape);
var lFits = TryOffsetToWorkArea(landscape, workArea);
@@ -174,6 +216,8 @@ namespace OpenNest
bestPlacement = candidate;
}
// Parts are returned in canonical frame, bound to the canonical drawing.
// The outer Fill wrapper (Task 7) rebinds to `drawing` and composes sourceAngle onto rotation.
return bestPlacement;
}
OpenNest.Engine/Fill/Compactor.cs
+36 -3
View File
@@ -1,6 +1,7 @@
using OpenNest.Geometry;
using System.Collections.Generic;
using System.Linq;
using OpenNest.Math;
namespace OpenNest.Engine.Fill
{
@@ -14,7 +15,7 @@ namespace OpenNest.Engine.Fill
public static double Push(List<Part> movingParts, Plate plate, PushDirection direction)
{
var obstacleParts = plate.Parts
.Where(p => !movingParts.Contains(p))
.Where(p => !movingParts.Contains(p) && !IntersectsAny(p, movingParts))
.ToList();
return Push(movingParts, obstacleParts, plate.WorkArea(), plate.PartSpacing, direction);
@@ -26,7 +27,7 @@ namespace OpenNest.Engine.Fill
public static double Push(List<Part> movingParts, Plate plate, double angle)
{
var obstacleParts = plate.Parts
.Where(p => !movingParts.Contains(p))
.Where(p => !movingParts.Contains(p) && !IntersectsAny(p, movingParts))
.ToList();
var direction = new Vector(System.Math.Cos(angle), System.Math.Sin(angle));
@@ -99,6 +100,13 @@ namespace OpenNest.Engine.Fill
: PartGeometry.GetPerimeterEntities(obstacleParts[i]);
var d = SpatialQuery.DirectionalDistance(movingEntities, obstacleEntities[i], direction);
if (d <= Tolerance.Epsilon
&& partSpacing <= Tolerance.Epsilon
&& CanNudgeWithoutOverlap(moving, obstacleParts[i], direction))
{
continue;
}
if (d < distance)
distance = d;
}
@@ -115,6 +123,31 @@ namespace OpenNest.Engine.Fill
return 0;
}
private static bool IntersectsAny(Part candidate, List<Part> parts)
{
for (var i = 0; i < parts.Count; i++)
{
if (candidate.Intersects(parts[i], out _))
return true;
}
return false;
}
private static bool CanNudgeWithoutOverlap(Part moving, Part obstacle, Vector direction)
{
var nudge = direction * (Tolerance.Epsilon * 10);
moving.Offset(nudge);
try
{
return !moving.Intersects(obstacle, out _);
}
finally
{
moving.Offset(-nudge);
}
}
public static double Push(List<Part> movingParts, List<Part> obstacleParts,
Box workArea, double partSpacing, PushDirection direction)
{
@@ -130,7 +163,7 @@ namespace OpenNest.Engine.Fill
public static double PushBoundingBox(List<Part> movingParts, Plate plate, PushDirection direction)
{
var obstacleParts = plate.Parts
.Where(p => !movingParts.Contains(p))
.Where(p => !movingParts.Contains(p) && !IntersectsAny(p, movingParts))
.ToList();
return PushBoundingBox(movingParts, obstacleParts, plate.WorkArea(), plate.PartSpacing, direction);
OpenNest.Engine/Fill/FillLinear.cs
+55 -130
View File
@@ -61,92 +61,91 @@ namespace OpenNest.Engine.Fill
: NestDirection.Horizontal;
}
/// <summary>
/// Computes the slide distance for the push algorithm, returning the
/// geometry-aware copy distance along the given axis.
/// </summary>
private double ComputeCopyDistance(double bboxDim, double slideDistance)
{
if (slideDistance >= double.MaxValue || slideDistance < 0)
return bboxDim + PartSpacing;
// The geometry-aware slide can produce a copy distance smaller than
// the part itself when inflated corner/arc vertices interact spuriously.
// Clamp to bboxDim + PartSpacing to prevent bounding box overlap.
return System.Math.Max(bboxDim - slideDistance, bboxDim + PartSpacing);
}
/// <summary>
/// Finds the geometry-aware copy distance between two identical parts along an axis.
/// Both parts are inflated by half-spacing for symmetric spacing.
/// Uses native Line/Arc entities (inflated by half-spacing) so curves are handled
/// exactly without polygon sampling error.
/// </summary>
private double FindCopyDistance(Part partA, NestDirection direction, PartBoundary boundary)
private double FindCopyDistance(Part partA, NestDirection direction)
{
var bboxDim = GetDimension(partA.BoundingBox, direction);
var pushDir = GetPushDirection(direction);
var startOffset = bboxDim + PartSpacing + Tolerance.Epsilon;
var offset = MakeOffset(direction, startOffset);
var locationBOffset = MakeOffset(direction, bboxDim);
var stationaryEntities = PartGeometry.GetOffsetPerimeterEntities(partA, HalfSpacing);
var movingEntities = PartGeometry.GetOffsetPerimeterEntities(
partA.CloneAtOffset(offset), HalfSpacing);
// Use the most efficient array-based overload to avoid all allocations.
var slideDistance = SpatialQuery.DirectionalDistance(
boundary.GetEdges(pushDir), partA.Location + locationBOffset,
boundary.GetEdges(SpatialQuery.OppositeDirection(pushDir)), partA.Location,
pushDir);
movingEntities, stationaryEntities, pushDir);
return ComputeCopyDistance(bboxDim, slideDistance);
if (slideDistance >= double.MaxValue || slideDistance < 0)
return bboxDim + PartSpacing;
return startOffset - slideDistance;
}
/// <summary>
/// Finds the geometry-aware copy distance between two identical patterns along an axis.
/// Checks every pair of parts across adjacent patterns so that multi-part
/// patterns (e.g. interlocking pairs) maintain spacing between ALL parts.
/// Both sides are inflated by half-spacing for symmetric spacing.
/// Checks every pair of parts across adjacent pattern copies so multi-part patterns
/// (e.g. interlocking pairs) maintain spacing between ALL parts. Uses native entity
/// geometry inflated by half-spacing — same primitive the Compactor uses — so arcs
/// are exact and no bbox clamp is needed.
/// </summary>
private double FindPatternCopyDistance(Pattern patternA, NestDirection direction, PartBoundary[] boundaries)
private double FindPatternCopyDistance(Pattern patternA, NestDirection direction)
{
if (patternA.Parts.Count <= 1)
return FindSinglePartPatternCopyDistance(patternA, direction, boundaries[0]);
if (patternA.Parts.Count == 1)
return FindCopyDistance(patternA.Parts[0], direction);
var bboxDim = GetDimension(patternA.BoundingBox, direction);
var pushDir = GetPushDirection(direction);
var opposite = SpatialQuery.OppositeDirection(pushDir);
var dirVec = SpatialQuery.DirectionToOffset(pushDir, 1.0);
// bboxDim already spans max(upper) - min(lower) across all parts,
// so the start offset just needs to push beyond that plus spacing.
var startOffset = bboxDim + PartSpacing + Tolerance.Epsilon;
var offset = MakeOffset(direction, startOffset);
var maxCopyDistance = FindMaxPairDistance(
patternA.Parts, boundaries, offset, pushDir, opposite, startOffset);
var parts = patternA.Parts;
var stationaryBoxes = new Box[parts.Count];
var movingBoxes = new Box[parts.Count];
var stationaryEntities = new List<Entity>[parts.Count];
var movingEntities = new List<Entity>[parts.Count];
// The copy distance must be at least bboxDim + PartSpacing to prevent
// bounding box overlap. Cross-pair slides can underestimate when the
// circumscribed polygon boundary overshoots the true arc, creating
// spurious contacts between diagonal parts in adjacent copies.
return System.Math.Max(maxCopyDistance, bboxDim + PartSpacing);
}
for (var i = 0; i < parts.Count; i++)
{
stationaryBoxes[i] = parts[i].BoundingBox;
movingBoxes[i] = stationaryBoxes[i].Translate(offset);
}
/// <summary>
/// Tests every pair of parts across adjacent pattern copies and returns the
/// maximum copy distance found. Returns 0 if no valid slide was found.
/// </summary>
private static double FindMaxPairDistance(
List<Part> parts, PartBoundary[] boundaries, Vector offset,
PushDirection pushDir, PushDirection opposite, double startOffset)
{
var maxCopyDistance = 0.0;
for (var j = 0; j < parts.Count; j++)
{
var movingEdges = boundaries[j].GetEdges(pushDir);
var locationB = parts[j].Location + offset;
var movingBox = movingBoxes[j];
for (var i = 0; i < parts.Count; i++)
{
var stationaryBox = stationaryBoxes[i];
// Skip if stationary is already ahead of moving in the push direction
// (sliding forward would take them further apart).
if (SpatialQuery.DirectionalGap(movingBox, stationaryBox, opposite) > 0)
continue;
// Skip if bboxes can't overlap along the axis perpendicular to the push.
if (!SpatialQuery.PerpendicularOverlap(movingBox, stationaryBox, dirVec))
continue;
stationaryEntities[i] ??= PartGeometry.GetOffsetPerimeterEntities(
parts[i], HalfSpacing);
movingEntities[j] ??= PartGeometry.GetOffsetPerimeterEntities(
parts[j].CloneAtOffset(offset), HalfSpacing);
var slideDistance = SpatialQuery.DirectionalDistance(
movingEdges, locationB,
boundaries[i].GetEdges(opposite), parts[i].Location,
pushDir);
movingEntities[j], stationaryEntities[i], pushDir);
if (slideDistance >= double.MaxValue || slideDistance < 0)
continue;
@@ -161,86 +160,15 @@ namespace OpenNest.Engine.Fill
return maxCopyDistance;
}
/// <summary>
/// Fast path for single-part patterns — no cross-part conflicts possible.
/// </summary>
private double FindSinglePartPatternCopyDistance(Pattern patternA, NestDirection direction, PartBoundary boundary)
{
var template = patternA.Parts[0];
return FindCopyDistance(template, direction, boundary);
}
/// <summary>
/// Gets offset boundary lines for all parts in a pattern using a shared boundary.
/// </summary>
private static List<Line> GetPatternLines(Pattern pattern, PartBoundary boundary, PushDirection direction)
{
var lines = new List<Line>();
foreach (var part in pattern.Parts)
lines.AddRange(boundary.GetLines(part.Location, direction));
return lines;
}
/// <summary>
/// Gets boundary lines for all parts in a pattern, with an additional
/// location offset applied. Avoids cloning the pattern.
/// </summary>
private static List<Line> GetOffsetPatternLines(Pattern pattern, Vector offset, PartBoundary boundary, PushDirection direction)
{
var lines = new List<Line>();
foreach (var part in pattern.Parts)
lines.AddRange(boundary.GetLines(part.Location + offset, direction));
return lines;
}
/// <summary>
/// Creates boundaries for all parts in a pattern. Parts that share the same
/// program geometry (same drawing and rotation) reuse the same boundary instance.
/// </summary>
private PartBoundary[] CreateBoundaries(Pattern pattern)
{
var boundaries = new PartBoundary[pattern.Parts.Count];
var cache = new List<(Drawing drawing, double rotation, PartBoundary boundary)>();
for (var i = 0; i < pattern.Parts.Count; i++)
{
var part = pattern.Parts[i];
PartBoundary found = null;
foreach (var entry in cache)
{
if (entry.drawing == part.BaseDrawing && entry.rotation.IsEqualTo(part.Rotation))
{
found = entry.boundary;
break;
}
}
if (found == null)
{
found = new PartBoundary(part, HalfSpacing);
cache.Add((part.BaseDrawing, part.Rotation, found));
}
boundaries[i] = found;
}
return boundaries;
}
/// <summary>
/// Tiles a pattern along the given axis, returning the cloned parts
/// (does not include the original pattern's parts). For multi-part
/// patterns, also adds individual parts from the next incomplete copy
/// that still fit within the work area.
/// </summary>
private List<Part> TilePattern(Pattern basePattern, NestDirection direction, PartBoundary[] boundaries)
private List<Part> TilePattern(Pattern basePattern, NestDirection direction)
{
var copyDistance = FindPatternCopyDistance(basePattern, direction, boundaries);
var copyDistance = FindPatternCopyDistance(basePattern, direction);
if (copyDistance <= 0)
return new List<Part>();
@@ -394,11 +322,10 @@ namespace OpenNest.Engine.Fill
private List<Part> FillGrid(Pattern pattern, NestDirection direction)
{
var perpAxis = PerpendicularAxis(direction);
var boundaries = CreateBoundaries(pattern);
// Step 1: Tile along primary axis
var row = new List<Part>(pattern.Parts);
row.AddRange(TilePattern(pattern, direction, boundaries));
row.AddRange(TilePattern(pattern, direction));
if (pattern.Parts.Count > 1 && HasOverlappingParts(row, out var a1, out var b1))
{
@@ -410,7 +337,7 @@ namespace OpenNest.Engine.Fill
// If primary tiling didn't produce copies, just tile along perpendicular
if (row.Count <= pattern.Parts.Count)
{
row.AddRange(TilePattern(pattern, perpAxis, boundaries));
row.AddRange(TilePattern(pattern, perpAxis));
if (pattern.Parts.Count > 1 && HasOverlappingParts(row, out var a2, out var b2))
{
@@ -427,9 +354,8 @@ namespace OpenNest.Engine.Fill
rowPattern.Parts.AddRange(row);
rowPattern.UpdateBounds();
var rowBoundaries = CreateBoundaries(rowPattern);
var gridResult = new List<Part>(rowPattern.Parts);
gridResult.AddRange(TilePattern(rowPattern, perpAxis, rowBoundaries));
gridResult.AddRange(TilePattern(rowPattern, perpAxis));
if (HasOverlappingParts(gridResult, out var a3, out var b3))
{
@@ -481,9 +407,8 @@ namespace OpenNest.Engine.Fill
return seed;
var template = seed.Parts[0];
var boundary = new PartBoundary(template, HalfSpacing);
var copyDistance = FindCopyDistance(template, direction, boundary);
var copyDistance = FindCopyDistance(template, direction);
if (copyDistance <= 0)
return seed;
OpenNest.Engine/ML/FeatureExtractor.cs
+9 -6
View File
@@ -27,7 +27,10 @@ namespace OpenNest.Engine.ML
{
public static PartFeatures Extract(Drawing drawing)
{
var entities = OpenNest.Converters.ConvertProgram.ToGeometry(drawing.Program)
// Normalize to canonical frame so features are invariant to import orientation.
var canonical = CanonicalFrame.AsCanonicalCopy(drawing);
var entities = OpenNest.Converters.ConvertProgram.ToGeometry(canonical.Program)
.Where(e => e.Layer != SpecialLayers.Rapid)
.ToList();
@@ -45,18 +48,18 @@ namespace OpenNest.Engine.ML
var features = new PartFeatures
{
Area = drawing.Area,
Convexity = drawing.Area / (hullArea > 0 ? hullArea : 1.0),
Area = canonical.Area,
Convexity = canonical.Area / (hullArea > 0 ? hullArea : 1.0),
AspectRatio = bb.Length / (bb.Width > 0 ? bb.Width : 1.0),
BoundingBoxFill = drawing.Area / (bb.Area() > 0 ? bb.Area() : 1.0),
BoundingBoxFill = canonical.Area / (bb.Area() > 0 ? bb.Area() : 1.0),
VertexCount = polygon.Vertices.Count,
Bitmask = GenerateBitmask(polygon, 32)
};
// Circularity = 4 * PI * Area / Perimeter^2
var perimeterLen = polygon.Perimeter();
features.Circularity = (4 * System.Math.PI * drawing.Area) / (perimeterLen * perimeterLen);
features.PerimeterToAreaRatio = drawing.Area > 0 ? perimeterLen / drawing.Area : 0;
features.Circularity = (4 * System.Math.PI * canonical.Area) / (perimeterLen * perimeterLen);
features.PerimeterToAreaRatio = canonical.Area > 0 ? perimeterLen / canonical.Area : 0;
return features;
}
OpenNest.Engine/NestEngineBase.cs
+35 -1
View File
@@ -334,6 +334,12 @@ namespace OpenNest
var bestFits = BestFitCache.GetOrCompute(
item.Drawing, Plate.Size.Length, Plate.Size.Width, Plate.PartSpacing);
// BestFitCache stores pair coordinates in canonical frame. Build candidates
// from a canonical drawing copy so geometry and coords share a frame; rebind
// + un-rotate winning pair to the original drawing's frame before returning.
var canonicalDrawing = CanonicalFrame.AsCanonicalCopy(item.Drawing);
var sourceAngle = item.Drawing?.Source?.Angle ?? 0.0;
List<Part> bestPlacement = null;
Box bestTarget = null;
@@ -342,7 +348,7 @@ namespace OpenNest
if (!fit.Keep)
continue;
var parts = fit.BuildParts(item.Drawing);
var parts = fit.BuildParts(canonicalDrawing);
var pairBbox = ((IEnumerable<IBoundable>)parts).GetBoundingBox();
var pairW = pairBbox.Width;
var pairL = pairBbox.Length;
@@ -374,6 +380,10 @@ namespace OpenNest
if (bestPlacement == null) continue;
// Rebind to the original drawing and compose sourceAngle onto rotation so the
// final placed parts sit in the user's visible frame.
bestPlacement = RebindPairToOriginal(bestPlacement, item.Drawing, sourceAngle);
result.AddRange(bestPlacement);
item.Quantity = 0;
@@ -388,6 +398,30 @@ namespace OpenNest
return result;
}
/// <summary>
/// Rebinds each canonical-frame Part in the pair to the original Drawing at its current
/// world pose, then composes sourceAngle onto each via CanonicalFrame.FromCanonical so
/// the returned list is in the original drawing's visible frame. Mirrors
/// DefaultNestEngine.RebindAndUnCanonicalize.
/// </summary>
private static List<Part> RebindPairToOriginal(List<Part> parts, Drawing original, double sourceAngle)
{
if (parts == null || parts.Count == 0)
return parts;
for (var i = 0; i < parts.Count; i++)
{
var p = parts[i];
var rebound = Part.CreateAtOrigin(original, p.Rotation);
var delta = p.BoundingBox.Location - rebound.BoundingBox.Location;
rebound.Offset(delta);
rebound.UpdateBounds();
parts[i] = rebound;
}
return CanonicalFrame.FromCanonical(parts, sourceAngle);
}
/// <summary>
/// Determines whether a drawing should use grid-fill (true) or bin-pack (false).
/// Low-quantity items whose total area is a small fraction of the plate are
OpenNest.Engine/PartClassifier.cs
+2 -2
View File
@@ -64,8 +64,8 @@ namespace OpenNest.Engine
var mbrArea = mbr.Area;
var mbrPerimeter = 2 * (mbr.Width + mbr.Height);
// Store primary angle (negated to align MBR with axes, same as RotationAnalysis).
result.PrimaryAngle = -mbr.Angle;
// Share the single angle formula with CanonicalAngle (no duplicate MBR compute).
result.PrimaryAngle = CanonicalAngle.FromMbr(mbr);
// Drawing perimeter for circularity and perimeter ratio.
var drawingPerimeter = polygon.Perimeter();
OpenNest.IO/Bom/BomAnalyzer.cs
+7 -2
View File
@@ -42,6 +42,11 @@ namespace OpenNest.IO.Bom
var nameWithoutExt = Path.GetFileNameWithoutExtension(file);
dxfFiles[nameWithoutExt] = file;
}
foreach (var file in Directory.GetFiles(dxfFolder, "*.dwg"))
{
var nameWithoutExt = Path.GetFileNameWithoutExtension(file);
dxfFiles.TryAdd(nameWithoutExt, file);
}
}
// Partition items into: skipped, unmatched, or matched (grouped)
@@ -57,8 +62,8 @@ namespace OpenNest.IO.Bom
var lookupName = item.FileName;
// Strip .dxf extension if the BOM includes it
if (lookupName.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase))
if (lookupName.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase)
|| lookupName.EndsWith(".dwg", StringComparison.OrdinalIgnoreCase))
lookupName = Path.GetFileNameWithoutExtension(lookupName);
if (!folderExists)
OpenNest.IO/CadImportResult.cs
+7
View File
@@ -1,4 +1,5 @@
using System.Collections.Generic;
using ACadSharp;
using OpenNest.Bending;
using OpenNest.Geometry;
@@ -38,5 +39,11 @@ namespace OpenNest.IO
/// Default drawing name (filename without extension, unless overridden).
/// </summary>
public string Name { get; set; }
/// <summary>
/// The raw CAD document from the source file. Available for callers
/// that need access to non-geometry entities (e.g., text annotations).
/// </summary>
public CadDocument Document { get; set; }
}
}
OpenNest.IO/CadImporter.cs
+39
View File
@@ -5,6 +5,7 @@ using OpenNest.Bending;
using OpenNest.Converters;
using OpenNest.Geometry;
using OpenNest.IO.Bending;
using OpenNest.Math;
namespace OpenNest.IO
{
@@ -25,6 +26,9 @@ namespace OpenNest.IO
var dxf = Dxf.Import(path);
RemoveDuplicateArcs(dxf.Entities);
RemoveZeroSweepArcs(dxf.Entities);
var bends = new List<Bend>();
if (options.DetectBends && dxf.Document != null)
{
@@ -44,6 +48,7 @@ namespace OpenNest.IO
Bounds = dxf.Entities.GetBoundingBox(),
SourcePath = path,
Name = options.Name ?? Path.GetFileNameWithoutExtension(path),
Document = dxf.Document,
};
}
@@ -136,5 +141,39 @@ namespace OpenNest.IO
return drawing;
}
internal static void RemoveZeroSweepArcs(List<Entity> entities)
{
entities.RemoveAll(e =>
e is Arc arc && arc.StartAngle.IsEqualTo(arc.EndAngle, Tolerance.ChainTolerance));
}
internal static void RemoveDuplicateArcs(List<Entity> entities)
{
var circles = entities.OfType<Circle>().ToList();
var arcs = entities.OfType<Arc>().ToList();
var arcsToRemove = new List<Arc>();
foreach (var arc in arcs)
{
foreach (var circle in circles)
{
if (arc.Layer?.Name != circle.Layer?.Name)
continue;
if (!arc.Center.DistanceTo(circle.Center).IsEqualTo(0))
continue;
if (!arc.Radius.IsEqualTo(circle.Radius))
continue;
arcsToRemove.Add(arc);
break;
}
}
foreach (var arc in arcsToRemove)
entities.Remove(arc);
}
}
}
OpenNest.IO/ChrFont.cs
+369
View File
@@ -0,0 +1,369 @@
using System;
using System.Collections.Generic;
using System.IO;
using System.Text;
using OpenNest.Geometry;
namespace OpenNest.IO
{
public class ChrFont
{
private readonly Dictionary<int, ChrGlyph> glyphs = new();
public string Name { get; internal set; }
public string Version { get; internal set; }
public double CapHeight { get; internal set; } = 5000;
internal void AddGlyph(int charCode, ChrGlyph glyph)
{
glyphs[charCode] = glyph;
}
public bool HasGlyph(int charCode) => glyphs.ContainsKey(charCode);
public ChrGlyph GetGlyph(int charCode) =>
glyphs.TryGetValue(charCode, out var g) ? g : null;
public double MeasureTextWidth(string text, double height)
{
var scale = height / CapHeight;
double width = 0;
foreach (var ch in text)
{
var glyph = GetGlyph(ch);
if (glyph == null)
{
var space = GetGlyph(' ');
width += (space?.AdvanceWidth ?? CapHeight * 0.6) * scale;
continue;
}
width += glyph.AdvanceWidth * scale;
}
return width;
}
public List<Entity> RenderText(string text, double height, Vector position, Layer layer = null)
{
var scale = height / CapHeight;
var entities = new List<Entity>();
var cursorX = position.X;
foreach (var ch in text)
{
var glyph = GetGlyph(ch);
if (glyph == null)
{
var space = GetGlyph(' ');
cursorX += (space?.AdvanceWidth ?? CapHeight * 0.6) * scale;
continue;
}
var glyphEntities = glyph.ToEntities(scale, cursorX, position.Y, layer);
entities.AddRange(glyphEntities);
cursorX += glyph.AdvanceWidth * scale;
}
return entities;
}
public static ChrFont Read(string path, byte? xorKey = null)
{
var raw = File.ReadAllBytes(path);
// The whole file is obfuscated with a single-byte XOR. Different
// GravoStyle versions use different keys (0x2F in older releases,
// 0xCF in 7000-series). The font name at offset 0 is ASCII stored
// as UTF-16LE, so the high byte of its first character is 0x00 in
// plaintext — which means raw[1] is exactly the XOR key. Detect it
// from the file unless the caller forces a specific key.
var key = xorKey ?? (raw.Length > 1 ? raw[1] : (byte)0x2F);
var data = new byte[raw.Length];
for (var i = 0; i < raw.Length; i++)
data[i] = (byte)(raw[i] ^ key);
return Parse(data);
}
private static ChrFont Parse(byte[] data)
{
var font = new ChrFont();
font.Name = Encoding.Unicode.GetString(data, 0, 26).TrimEnd('\0').Trim();
font.Version = Encoding.ASCII.GetString(data, 26, 12).TrimEnd('\0').Trim();
var charTable = new List<(int charCode, int offset)>();
var i = 0x40;
while (i + 5 < data.Length)
{
var charCode = data[i] | (data[i + 1] << 8);
var offset = data[i + 2] | (data[i + 3] << 8) | (data[i + 4] << 16) | (data[i + 5] << 24);
if (charCode < 0x20 || offset == 0 || offset >= data.Length)
break;
charTable.Add((charCode, offset));
i += 6;
}
for (var c = 0; c < charTable.Count; c++)
{
var (charCode, offset) = charTable[c];
var nextOffset = c + 1 < charTable.Count
? FindNextOffset(charTable, offset, data.Length)
: data.Length;
var glyph = ParseGlyph(data, offset, nextOffset);
if (glyph != null)
font.AddGlyph(charCode, glyph);
}
if (font.glyphs.Count > 0)
{
foreach (var g in font.glyphs.Values)
{
if (g.CapHeight > 0)
{
font.CapHeight = g.CapHeight;
break;
}
}
}
return font;
}
private static int FindNextOffset(List<(int charCode, int offset)> table, int currentOffset, int fileLength)
{
var best = fileLength;
foreach (var (_, off) in table)
{
if (off > currentOffset && off < best)
best = off;
}
return best;
}
private static ChrGlyph ParseGlyph(byte[] data, int offset, int endOffset)
{
if (offset + 92 > data.Length)
return null;
var glyph = new ChrGlyph();
glyph.CapHeight = ReadBE16(data, offset + 15 * 2);
var bearing = System.Math.Abs(ReadBE16(data, offset + 18 * 2));
glyph.AdvanceWidth = ReadBE16(data, offset + 22 * 2) + bearing;
var strokeStart = offset + 92;
var pos = strokeStart;
var currentStroke = new List<ChrStrokePoint>();
while (pos + 5 < endOffset)
{
var cmd = ReadBE16(data, pos);
var x = ReadBE16(data, pos + 2);
var y = ReadBE16(data, pos + 4);
pos += 6;
if (System.Math.Abs(x) > 15000 || System.Math.Abs(y) > 15000)
break;
if (cmd < -1000)
break;
var type = cmd switch
{
1 => ChrPointType.Vertex,
4 => ChrPointType.Control,
5 => ChrPointType.EndPoint,
_ => ChrPointType.Vertex,
};
currentStroke.Add(new ChrStrokePoint(type, x, y));
if (type == ChrPointType.EndPoint)
{
if (currentStroke.Count > 0)
glyph.Strokes.Add(currentStroke);
currentStroke = new List<ChrStrokePoint>();
}
}
if (currentStroke.Count > 0)
glyph.Strokes.Add(currentStroke);
return glyph;
}
private static int ReadBE16(byte[] data, int offset)
{
var val = (data[offset] << 8) | data[offset + 1];
if (val > 32767) val -= 65536;
return val;
}
}
internal enum ChrPointType
{
Vertex,
Control,
EndPoint,
}
internal struct ChrStrokePoint
{
public ChrPointType Type;
public double X;
public double Y;
public ChrStrokePoint(ChrPointType type, double x, double y)
{
Type = type;
X = x;
Y = y;
}
}
public class ChrGlyph
{
internal readonly List<List<ChrStrokePoint>> Strokes = new();
public double AdvanceWidth { get; internal set; }
public double CapHeight { get; internal set; }
private const int ArcSamples = 16;
public List<Entity> ToEntities(double scale, double offsetX, double offsetY, Layer layer = null)
{
var entities = new List<Entity>();
layer ??= Layer.Default;
foreach (var stroke in Strokes)
{
if (stroke.Count < 2) continue;
var segments = BuildSegments(stroke);
foreach (var seg in segments)
{
if (seg.Points.Count < 2) continue;
var scaled = new List<Vector>(seg.Points.Count);
foreach (var pt in seg.Points)
scaled.Add(new Vector(pt.X * scale + offsetX, pt.Y * scale + offsetY));
var converted = PointsToLines(scaled);
foreach (var e in converted)
{
e.Layer = layer;
entities.Add(e);
}
}
}
return entities;
}
private static List<Entity> PointsToLines(List<Vector> points)
{
var entities = new List<Entity>();
for (var i = 0; i < points.Count - 1; i++)
{
if (points[i].DistanceTo(points[i + 1]) < 0.001)
continue;
entities.Add(new Line(points[i], points[i + 1]));
}
return entities;
}
private static List<StrokeSegment> BuildSegments(List<ChrStrokePoint> stroke)
{
var segments = new List<StrokeSegment>();
var current = new StrokeSegment();
var i = 0;
while (i < stroke.Count)
{
var pt = stroke[i];
if (pt.Type == ChrPointType.Vertex || pt.Type == ChrPointType.EndPoint)
{
if (i + 1 < stroke.Count && stroke[i + 1].Type == ChrPointType.Control)
{
var p0 = new Vector(pt.X, pt.Y);
var pMid = new Vector(stroke[i + 1].X, stroke[i + 1].Y);
var p2End = i + 2 < stroke.Count ? stroke[i + 2] : stroke[i + 1];
var p1 = new Vector(p2End.X, p2End.Y);
SampleCircularArc(current.Points, p0, pMid, p1, ArcSamples);
current.HasCurves = true;
i += 2;
}
else
{
current.Points.Add(new Vector(pt.X, pt.Y));
i++;
}
}
else
{
i++;
}
}
if (current.Points.Count >= 2)
segments.Add(current);
return segments;
}
private class StrokeSegment
{
public readonly List<Vector> Points = new();
public bool HasCurves;
}
private static void SampleCircularArc(List<Vector> output, Vector p0, Vector pMid, Vector p1, int samples)
{
if (output.Count == 0 || output[^1].DistanceTo(p0) > 0.01)
output.Add(p0);
double ax = p0.X, ay = p0.Y;
double bx = pMid.X, by = pMid.Y;
double cx = p1.X, cy = p1.Y;
var d = 2 * (ax * (by - cy) + bx * (cy - ay) + cx * (ay - by));
if (System.Math.Abs(d) < 1e-6)
{
output.Add(pMid);
output.Add(p1);
return;
}
var ux = ((ax * ax + ay * ay) * (by - cy) + (bx * bx + by * by) * (cy - ay) + (cx * cx + cy * cy) * (ay - by)) / d;
var uy = ((ax * ax + ay * ay) * (cx - bx) + (bx * bx + by * by) * (ax - cx) + (cx * cx + cy * cy) * (bx - ax)) / d;
var radius = System.Math.Sqrt((ax - ux) * (ax - ux) + (ay - uy) * (ay - uy));
var a0 = System.Math.Atan2(ay - uy, ax - ux);
var am = System.Math.Atan2(by - uy, bx - ux);
var a1 = System.Math.Atan2(cy - uy, cx - ux);
var ccwSweep = a1 - a0;
while (ccwSweep <= 0) ccwSweep += 2 * System.Math.PI;
var midRel = am - a0;
while (midRel < 0) midRel += 2 * System.Math.PI;
var sweep = midRel < ccwSweep ? ccwSweep : ccwSweep - 2 * System.Math.PI;
for (var i = 1; i <= samples; i++)
{
var t = (double)i / samples;
var angle = a0 + sweep * t;
output.Add(new Vector(ux + radius * System.Math.Cos(angle), uy + radius * System.Math.Sin(angle)));
}
}
}
}
OpenNest.IO/Dxf.cs
+57 -7
View File
@@ -27,8 +27,7 @@ namespace OpenNest.IO
/// </summary>
public static DxfImportResult Import(string path)
{
using var reader = new DxfReader(path);
var doc = reader.Read();
var doc = ReadDocument(path);
return new DxfImportResult
{
@@ -41,8 +40,7 @@ namespace OpenNest.IO
{
try
{
using var reader = new DxfReader(path);
var doc = reader.Read();
var doc = ReadDocument(path);
return ConvertEntities(doc);
}
catch (Exception ex)
@@ -67,6 +65,36 @@ namespace OpenNest.IO
}
}
public static List<Entity> GetGeometry(string path, Func<string, bool> layerFilter)
{
try
{
using var reader = new DxfReader(path);
var doc = reader.Read();
return ConvertEntities(doc, layerFilter);
}
catch (Exception ex)
{
Debug.WriteLine(ex.Message);
return new List<Entity>();
}
}
public static List<Entity> GetGeometry(Stream stream, Func<string, bool> layerFilter)
{
try
{
using var reader = new DxfReader(stream);
var doc = reader.Read();
return ConvertEntities(doc, layerFilter);
}
catch (Exception ex)
{
Debug.WriteLine(ex.Message);
return new List<Entity>();
}
}
#endregion
#region Export
@@ -113,15 +141,34 @@ namespace OpenNest.IO
#region Private
private static List<Entity> ConvertEntities(CadDocument doc)
private static bool IsDwg(string path) =>
Path.GetExtension(path).Equals(".dwg", StringComparison.OrdinalIgnoreCase);
private static CadDocument ReadDocument(string path)
{
if (IsDwg(path))
{
using var reader = new DwgReader(path);
return reader.Read();
}
else
{
using var reader = new DxfReader(path);
return reader.Read();
}
}
private static List<Entity> ConvertEntities(CadDocument doc, Func<string, bool> layerFilter = null)
{
var entities = new List<Entity>();
var lines = new List<Line>();
var arcs = new List<Arc>();
var circles = new List<Circle>();
var filter = layerFilter ?? IsNonCutLayer;
foreach (var entity in doc.Entities)
{
if (IsNonCutLayer(entity.Layer?.Name))
if (filter(entity.Layer?.Name))
continue;
switch (entity)
@@ -135,7 +182,7 @@ namespace OpenNest.IO
break;
case ACadSharp.Entities.Circle circle:
entities.Add(circle.ToOpenNest());
circles.Add(circle.ToOpenNest());
break;
case ACadSharp.Entities.Spline spline:
@@ -166,7 +213,10 @@ namespace OpenNest.IO
GeometryOptimizer.Optimize(lines);
GeometryOptimizer.Optimize(arcs);
GeometryOptimizer.Deduplicate(circles);
GeometryOptimizer.Deduplicate(circles, arcs);
entities.AddRange(circles);
entities.AddRange(lines);
entities.AddRange(arcs);
OpenNest.IO/Extensions.cs
+12 -3
View File
@@ -181,13 +181,22 @@ namespace OpenNest.IO
{
var center = new Vector(ellipse.Center.X, ellipse.Center.Y);
var majorAxis = new Vector(ellipse.MajorAxisEndPoint.X, ellipse.MajorAxisEndPoint.Y);
var semiMajor = System.Math.Sqrt(majorAxis.X * majorAxis.X + majorAxis.Y * majorAxis.Y);
var semiMinor = semiMajor * ellipse.RadiusRatio;
var rotation = System.Math.Atan2(majorAxis.Y, majorAxis.X);
var startParam = ellipse.StartParameter;
var endParam = ellipse.EndParameter;
if (ellipse.Normal.Z < 0)
{
var newStart = OpenNest.Math.Angle.TwoPI - endParam;
var newEnd = OpenNest.Math.Angle.TwoPI - startParam;
startParam = newStart;
endParam = newEnd;
}
var semiMajor = System.Math.Sqrt(majorAxis.X * majorAxis.X + majorAxis.Y * majorAxis.Y);
var semiMinor = semiMajor * ellipse.RadiusRatio;
var rotation = System.Math.Atan2(majorAxis.Y, majorAxis.X);
var layer = ellipse.Layer.ToOpenNest();
var color = ellipse.ResolveColor();
var lineTypeName = ellipse.ResolveLineTypeName();
OpenNest.IO/OpenNest.IO.csproj
+3
View File
@@ -4,6 +4,9 @@
<RootNamespace>OpenNest.IO</RootNamespace>
<AssemblyName>OpenNest.IO</AssemblyName>
</PropertyGroup>
<ItemGroup>
<InternalsVisibleTo Include="OpenNest.Tests" />
</ItemGroup>
<ItemGroup>
<ProjectReference Include="..\OpenNest.Core\OpenNest.Core.csproj" />
<ProjectReference Include="..\OpenNest.Engine\OpenNest.Engine.csproj" />
OpenNest.Posts.GravographIS/GravographISPort.cs
+99
View File
@@ -0,0 +1,99 @@
using System;
using System.IO.Ports;
using System.Threading;
namespace OpenNest.Posts.GravographIS
{
/// <summary>
/// Serial streamer for the Gravograph IS8000. 9600 8-N-1; flow control is
/// configurable and defaults to RTS/CTS (the controller is buffered and drops
/// CTS to apply backpressure). The job is sent in modest chunks rather than as
/// one giant write so the handshake can pause the write mid-stream.
/// </summary>
public sealed class GravographISPort : IDisposable
{
private SerialPort port;
public const int DefaultBaudRate = 9600;
public const int DefaultChunkSize = 256;
public const int DefaultWriteTimeoutMs = 30000;
public int ChunkSize { get; set; } = DefaultChunkSize;
public int WriteTimeoutMs { get; set; } = DefaultWriteTimeoutMs;
public bool IsOpen => port != null && port.IsOpen;
/// <summary>
/// Opens the port at the controller's required line settings (9600 8-N-1)
/// with the given <paramref name="handshake"/>. Throws if the port is
/// already open or if opening fails.
/// </summary>
public void Open(string portName, Handshake handshake = Handshake.RequestToSend)
{
if (string.IsNullOrWhiteSpace(portName))
throw new ArgumentException("Port name is required.", nameof(portName));
if (port != null)
throw new InvalidOperationException("Port is already open.");
port = new SerialPort(portName, DefaultBaudRate, Parity.None, 8, StopBits.One)
{
Handshake = handshake,
WriteTimeout = WriteTimeoutMs,
ReadTimeout = WriteTimeoutMs,
// DTR/RTS are needed for some USB-serial bridges and for RTS/CTS flow:
DtrEnable = true,
RtsEnable = handshake != Handshake.RequestToSend &&
handshake != Handshake.RequestToSendXOnXOff,
};
port.Open();
}
/// <summary>
/// Streams the encoded job to the port in chunks. Cancellable. The chunked
/// write is intentional — Write() blocks until the OS accepts the bytes,
/// which with RTS/CTS or XOn/XOff yields cleanly when the controller's
/// buffer is full.
/// </summary>
public void StreamJob(byte[] data, CancellationToken cancellationToken = default)
{
if (data == null) throw new ArgumentNullException(nameof(data));
if (port == null || !port.IsOpen)
throw new InvalidOperationException("Port is not open.");
var chunk = ChunkSize > 0 ? ChunkSize : DefaultChunkSize;
var offset = 0;
while (offset < data.Length)
{
cancellationToken.ThrowIfCancellationRequested();
var count = System.Math.Min(chunk, data.Length - offset);
port.Write(data, offset, count);
offset += count;
}
// Block until the OS has handed the last bytes to the line. SerialPort
// doesn't expose flush-and-drain directly; BaseStream.Flush is a no-op
// on Windows, so this is best-effort.
try { port.BaseStream.Flush(); }
catch { /* ignored — Flush is advisory on SerialPort */ }
}
public void Close()
{
if (port == null) return;
try
{
if (port.IsOpen) port.Close();
}
finally
{
port.Dispose();
port = null;
}
}
public void Dispose() => Close();
}
}
OpenNest.Posts.GravographIS/GravographISPostProcessor.cs
+61
View File
@@ -0,0 +1,61 @@
using System;
using System.IO;
using System.IO.Ports;
using System.Threading;
namespace OpenNest.Posts.GravographIS
{
/// <summary>
/// IPostProcessor implementation for the Gravograph IS8000. <see cref="Post(Nest, Stream)"/>
/// writes the binary HPGL bytes. For serial streaming, use <see cref="Stream(Nest, string, Handshake, CancellationToken)"/>.
/// </summary>
public sealed class GravographISPostProcessor : IPostProcessor
{
public string Name => "Gravograph IS8000";
public string Author => "OpenNest";
public string Description => "Gravograph IS8000 mechanical engraver (binary HPGL over serial)";
public GravographISWriterOptions WriterOptions { get; } = new GravographISWriterOptions();
public NestPolylineExtractor Extractor { get; } = new NestPolylineExtractor();
public double StitchTolerance { get; set; } = PolylinePrePass.DefaultStitchTolerance;
public bool AllowReverse { get; set; } = true;
public void Post(Nest nest, Stream outputStream)
{
if (nest == null) throw new ArgumentNullException(nameof(nest));
if (outputStream == null) throw new ArgumentNullException(nameof(outputStream));
var polylines = Extractor.Extract(nest);
var prepared = PolylinePrePass.Prepare(polylines, StitchTolerance, AllowReverse);
new GravographISWriter(WriterOptions).Write(prepared, outputStream);
}
public void Post(Nest nest, string outputFile)
{
using var fs = new FileStream(outputFile, FileMode.Create, FileAccess.Write);
Post(nest, fs);
}
/// <summary>
/// Buffers the encoded job in memory, then streams it to the named COM port.
/// </summary>
public void Stream(Nest nest, string portName,
Handshake handshake = Handshake.RequestToSend,
CancellationToken cancellationToken = default)
{
byte[] bytes;
using (var ms = new MemoryStream())
{
Post(nest, ms);
bytes = ms.ToArray();
}
using var port = new GravographISPort();
port.Open(portName, handshake);
port.StreamJob(bytes, cancellationToken);
}
}
}
OpenNest.Posts.GravographIS/GravographISWriter.cs
+327
View File
@@ -0,0 +1,327 @@
using System;
using System.Collections.Generic;
using System.IO;
using OpenNest.Geometry;
namespace OpenNest.Posts.GravographIS
{
/// <summary>
/// Encodes polylines (in inches) into the Gravograph IS8000 native "binary HPGL"
/// wire format. The byte stream is byte-exact against captures from GravoStyle'98.
///
/// Scale: 80 steps/mm = 2032 steps/inch. Y (and Z) are negated on the wire.
/// Deltas are signed big-endian int16 (max ±32767 steps ≈ ±16 inches per move).
/// </summary>
public sealed class GravographISWriter
{
// 93-byte preamble — captured from GravoStyle'98 with the trailing
// job-specific travel block stripped. The VS, VZ and DZ operands are
// patched by the writer to reflect feed and depth options.
//
// The original capture ended with a DR command (FF FD 44 52 00 00)
// followed by three 8-byte int16 records — same format as PU/PD —
// that carried a chunked travel from the head's parked position to
// the original job's first vertex (cumulative ΔX ≈ 1", ΔY ≈ 47").
// Those frozen deltas have nothing to do with our job geometry, so
// replaying them sends the head to a fixed point regardless of where
// the operator set zero. Stripped for the same reason as the captured
// fixed return-to-home block.
private static readonly byte[] PreambleTemplate = new byte[]
{
0x21, 0x41, 0x53, 0x20, 0x33, 0x38, 0x3b, 0x01, 0x90, 0x01,
0xf4, 0x01, 0x90, 0x01, 0xf4, 0x01, 0x90, 0x01, 0xf4, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x09, 0x00, 0x00, 0x03, 0xe8, 0x05, 0x06, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0xff, 0xfd, 0x32, 0x44, 0x00,
0x00, 0xff, 0xfd, 0x4d, 0x43, 0x00, 0x01, 0xff, 0xfd, 0x4f,
0x55, 0xff, 0xfb, 0xff, 0xfd, 0x4f, 0x55, 0xff, 0xfa, 0xff,
0xfd, 0x50, 0x5a, 0x00, 0x00, 0xff, 0xfd, 0x56, 0x53, 0x00,
0x23, 0xff, 0xfd, 0x56, 0x5a, 0x00, 0x23, 0xff, 0xfd, 0x44,
0x5a, 0x01, 0xfc,
};
// Stripped 36-byte postamble: lift, aux off, motor off, operator beep,
// job-finish. The 24-byte return-to-home block that appears in GravoStyle's
// captured postamble between MC and OP is intentionally OMITTED — those
// three 8-byte int16 records carry chunked job-specific return deltas
// (each record is [word1:int16][param:int16][ΔX:int16][ΔY:int16], same
// format as PU/PD records; the original capture chunked the long Y return
// across three records because each delta has to fit in int16). Reusing
// GravoStyle's frozen deltas on different geometry overshoots the X-axis
// limit. We emit calculated return deltas for the current job instead.
// The writer now replaces the captured fixed return block with a calculated
// lift + PU travel to the operator-set origin before these final commands.
private static readonly byte[] EndJobBytes = new byte[]
{
0xff, 0xfd, 0x4f, 0x55, 0xff, 0xfa, // OU 0xFFFA aux off
0xff, 0xfd, 0x4f, 0x55, 0xff, 0xfb, // OU 0xFFFB aux off
0xff, 0xfd, 0x4d, 0x43, 0x00, 0x00, // MC 0x0000 motor off
0xff, 0xfd, 0x4f, 0x50, 0x00, 0x00, // OP 0x0000 operator beep
0xff, 0xfd, 0x4a, 0x46, 0x00, 0x00, // JF 0x0000 job finish
};
// 80 steps/mm × 25.4 mm/in
internal const int StepsPerInch = 2032;
public GravographISWriterOptions Options { get; }
public GravographISWriter()
: this(new GravographISWriterOptions())
{
}
public GravographISWriter(GravographISWriterOptions options)
{
Options = options ?? throw new ArgumentNullException(nameof(options));
}
/// <summary>
/// Writes the full byte stream (preamble + geometry + postamble) for the given
/// polylines. Polyline coordinates are in inches, relative to the operator-set
/// work origin. The writer emits a leading DR travel to the first polyline
/// start before lowering for the first cut.
/// </summary>
public void Write(IEnumerable<IReadOnlyList<Vector>> polylines, Stream output)
{
if (polylines == null) throw new ArgumentNullException(nameof(polylines));
if (output == null) throw new ArgumentNullException(nameof(output));
var preamble = (byte[])PreambleTemplate.Clone();
PatchOperand(preamble, (byte)'V', (byte)'S', (short)Options.FeedMmPerSec);
PatchOperand(preamble, (byte)'V', (byte)'Z', (short)Options.FeedMmPerSec);
PatchOperand(preamble, (byte)'D', (byte)'Z', DepthInStepsAsInt16());
output.Write(preamble, 0, preamble.Length);
// Cumulative head position from the operator-set upper-left origin, in
// wire steps. The first polyline gets a leading DR travel from this
// origin before PD lowers for cutting. Used by the envelope guard to
// catch bad records before they ship to the engraver.
var headX = 0;
var headY = 0;
var envelopeXSteps = (int)System.Math.Round(Options.WorkEnvelopeXMm * StepsPerMm,
MidpointRounding.AwayFromZero);
var envelopeYSteps = (int)System.Math.Round(Options.WorkEnvelopeYMm * StepsPerMm,
MidpointRounding.AwayFromZero);
var firstPolyline = true;
var polyIndex = 0;
foreach (var poly in polylines)
{
polyIndex++;
if (poly == null || poly.Count < 2)
continue;
var (startX, startY) = ToWire(poly[0]);
WriteTravel(output,
firstPolyline ? (byte)'D' : (byte)'P',
firstPolyline ? (byte)'R' : (byte)'U',
checked(startX - headX), checked(startY - headY),
ref headX, ref headY, envelopeXSteps, envelopeYSteps, polyIndex);
// PD command + single records-follow flag, then one record per segment.
output.WriteByte(0xFF);
output.WriteByte(0xFD);
output.WriteByte((byte)'P');
output.WriteByte((byte)'D');
output.WriteByte(0x00);
output.WriteByte(0x00);
var prevX = startX;
var prevY = startY;
for (int i = 1; i < poly.Count; i++)
{
var (cx, cy) = ToWire(poly[i]);
var dx = checked(cx - prevX);
var dy = checked(cy - prevY);
EnsureEnvelope(headX + dx, headY + dy, envelopeXSteps, envelopeYSteps,
polyIndex, segment: i, isTravel: false);
WriteRecord(output, dx, dy);
prevX = cx;
prevY = cy;
headX += dx;
headY += dy;
}
firstPolyline = false;
}
WriteLiftOnly(output);
if (Options.ReturnToOriginAtEnd && !firstPolyline)
{
WriteTravel(output, (byte)'P', (byte)'U',
checked(-headX), checked(-headY),
ref headX, ref headY, envelopeXSteps, envelopeYSteps, polyIndex);
}
output.Write(EndJobBytes, 0, EndJobBytes.Length);
}
private const double StepsPerMm = 80.0;
private void EnsureEnvelope(int wireX, int wireY,
int envXSteps, int envYSteps,
int polyIndex, int segment, bool isTravel)
{
if (!Options.EnvelopeGuardEnabled) return;
// Wire frame: X is identity to input; Y is negated. With the operator
// origin set at the upper-left of the work envelope and an OpenNest
// quadrant-4 plate, valid part coordinates are +X/right and -Y/down:
// wireX ∈ [0, +envXSteps]
// wireY ∈ [0, +envYSteps]
if (wireX >= 0 && wireX <= envXSteps && wireY >= 0 && wireY <= envYSteps)
return;
var inputX = wireX / (double)StepsPerInch;
var inputY = -wireY / (double)StepsPerInch;
var kind = isTravel ? "pen-up travel" : "cut segment";
throw new InvalidOperationException(
$"Polyline {polyIndex} {kind} (segment {segment}) would place the head at " +
$"({inputX:F3}\", {inputY:F3}\"), outside the {Options.WorkEnvelopeXMm}×{Options.WorkEnvelopeYMm} mm " +
$"work envelope from upper-left origin. Refusing to emit the record.");
}
private short DepthInStepsAsInt16()
{
var steps = (long)System.Math.Round(Options.DepthInches * StepsPerInch, MidpointRounding.AwayFromZero);
if (steps < short.MinValue || steps > short.MaxValue)
throw new ArgumentOutOfRangeException(nameof(Options.DepthInches), $"Depth {Options.DepthInches} in. → {steps} steps overflows int16.");
return (short)steps;
}
private static (int x, int y) ToWire(Vector v)
{
// Inches -> steps. With upper-left origin in OpenNest quadrant 4,
// negative input Y is down; Y is negated on the wire.
var x = (int)System.Math.Round(v.X * StepsPerInch, MidpointRounding.AwayFromZero);
var y = (int)System.Math.Round(-v.Y * StepsPerInch, MidpointRounding.AwayFromZero);
return (x, y);
}
private void WriteTravel(Stream s, byte c0, byte c1, int dx, int dy,
ref int headX, ref int headY,
int envelopeXSteps, int envelopeYSteps,
int polyIndex)
{
if (dx == 0 && dy == 0)
return;
s.WriteByte(0xFF);
s.WriteByte(0xFD);
s.WriteByte(c0);
s.WriteByte(c1);
s.WriteByte(0x00);
s.WriteByte(0x00);
var chunks = System.Math.Max(
(int)System.Math.Ceiling(System.Math.Abs(dx) / (double)short.MaxValue),
(int)System.Math.Ceiling(System.Math.Abs(dy) / (double)short.MaxValue));
if (chunks < 1) chunks = 1;
var emittedX = 0;
var emittedY = 0;
for (var i = 1; i <= chunks; i++)
{
var targetX = (int)System.Math.Round(dx * (i / (double)chunks), MidpointRounding.AwayFromZero);
var targetY = (int)System.Math.Round(dy * (i / (double)chunks), MidpointRounding.AwayFromZero);
var chunkX = checked(targetX - emittedX);
var chunkY = checked(targetY - emittedY);
EnsureEnvelope(headX + chunkX, headY + chunkY, envelopeXSteps, envelopeYSteps,
polyIndex, segment: 0, isTravel: true);
WriteRecord(s, chunkX, chunkY);
emittedX = targetX;
emittedY = targetY;
headX += chunkX;
headY += chunkY;
}
}
private static void WriteLiftOnly(Stream s)
{
s.WriteByte(0xFF);
s.WriteByte(0xFD);
s.WriteByte((byte)'P');
s.WriteByte((byte)'U');
s.WriteByte(0x00);
s.WriteByte(0x01);
}
private static void WriteCommandWithRecord(Stream s, byte c0, byte c1, int dx, int dy)
{
s.WriteByte(0xFF);
s.WriteByte(0xFD);
s.WriteByte(c0);
s.WriteByte(c1);
// Records-follow flag (0x0000) emitted once per PU/PD packet.
s.WriteByte(0x00);
s.WriteByte(0x00);
WriteRecord(s, dx, dy);
}
private static void WriteRecord(Stream s, int dx, int dy)
{
if (dx < short.MinValue || dx > short.MaxValue ||
dy < short.MinValue || dy > short.MaxValue)
{
throw new InvalidOperationException(
$"Move delta ({dx}, {dy}) steps overflows signed int16 — split moves upstream.");
}
int word1;
int param;
var absDx = (double)System.Math.Abs(dx);
var absDy = (double)System.Math.Abs(dy);
var len = System.Math.Sqrt(absDx * absDx + absDy * absDy);
if (len < 1.0)
{
// Zero-length lift (PU 00 01) is the dedicated form; for a record-carrying
// packet a true zero-length move shouldn't occur, but stay numerically safe.
word1 = 16384;
param = 1;
}
else
{
var maxAbs = System.Math.Max(absDx, absDy);
word1 = (int)System.Math.Round(16384.0 * maxAbs / len, MidpointRounding.AwayFromZero);
param = (int)System.Math.Round(len / 22.4, MidpointRounding.AwayFromZero);
if (param < 1) param = 1;
if (param > 180) param = 180;
if (word1 > 16384) word1 = 16384;
}
WriteBigEndianInt16(s, (short)word1);
WriteBigEndianInt16(s, (short)param);
WriteBigEndianInt16(s, (short)dx);
WriteBigEndianInt16(s, (short)dy);
}
private static void WriteBigEndianInt16(Stream s, short value)
{
s.WriteByte((byte)((value >> 8) & 0xFF));
s.WriteByte((byte)(value & 0xFF));
}
// Locates the operand of a command (FF FD <c0> <c1> <hi> <lo>) and overwrites it.
// Throws if the command isn't present — that would mean the preamble was mis-edited.
private static void PatchOperand(byte[] buffer, byte c0, byte c1, short value)
{
for (int i = 0; i <= buffer.Length - 6; i++)
{
if (buffer[i] == 0xFF && buffer[i + 1] == 0xFD &&
buffer[i + 2] == c0 && buffer[i + 3] == c1)
{
buffer[i + 4] = (byte)((value >> 8) & 0xFF);
buffer[i + 5] = (byte)(value & 0xFF);
return;
}
}
throw new InvalidOperationException(
$"Command '{(char)c0}{(char)c1}' not found in preamble template.");
}
}
}
OpenNest.Posts.GravographIS/GravographISWriterOptions.cs
+24
View File
@@ -0,0 +1,24 @@
namespace OpenNest.Posts.GravographIS
{
public sealed class GravographISWriterOptions
{
public double DepthInches { get; set; } = 0.25;
public int FeedMmPerSec { get; set; } = 35;
// IS8000 work envelope in millimeters, from the operator-set upper-left
// work origin. Defaults to the catalog 0.610 m x 1.220 m bed. With an
// OpenNest quadrant-4 plate, motion is allowed right (+X) and down (-Y).
public double WorkEnvelopeXMm { get; set; } = 610.0;
public double WorkEnvelopeYMm { get; set; } = 1220.0;
// When true, the writer throws an InvalidOperationException naming the
// offending polyline and segment before any out-of-envelope record is
// emitted. Disable only for off-machine encoding tests.
public bool EnvelopeGuardEnabled { get; set; } = true;
// When true, lift at the end of the last cut and return to the
// operator-set origin before shutting the job down.
public bool ReturnToOriginAtEnd { get; set; } = true;
}
}
OpenNest.Posts.GravographIS/NestPolylineExtractor.cs
+179
View File
@@ -0,0 +1,179 @@
using System;
using System.Collections.Generic;
using OpenNest.CNC;
using OpenNest.Geometry;
namespace OpenNest.Posts.GravographIS
{
/// <summary>
/// Lifts polylines out of an OpenNest <see cref="Nest"/> for the Gravograph
/// backend. Walks each <see cref="Part"/>'s <see cref="Program"/>, breaks
/// polylines at rapid moves, and tessellates arcs to a chord-deviation
/// tolerance (the wire format takes line segments only).
/// </summary>
public sealed class NestPolylineExtractor
{
public double ArcChordToleranceInches { get; set; } = 0.001;
/// <summary>
/// Extracts polylines from every non-cutoff part in every plate of the nest,
/// returning them in plate coordinates (inches).
/// </summary>
public List<List<Vector>> Extract(Nest nest)
{
if (nest == null) throw new ArgumentNullException(nameof(nest));
var result = new List<List<Vector>>();
foreach (var plate in nest.Plates)
{
foreach (var part in plate.Parts)
{
if (part.BaseDrawing != null && part.BaseDrawing.IsCutOff)
continue;
ExtractPart(part, result);
}
}
return result;
}
/// <summary>
/// Extracts polylines for a single part. Public so callers driving the
/// writer directly (e.g. from a console one-off) can use it.
/// </summary>
public List<List<Vector>> ExtractPart(Part part)
{
var list = new List<List<Vector>>();
ExtractPart(part, list);
return list;
}
private void ExtractPart(Part part, List<List<Vector>> sink)
{
var program = part.Program;
if (program == null) return;
// The walk below treats Motion.EndPoint as absolute. Convert a working
// copy to absolute mode so G91 programs (the form OpenNest's UI writes)
// produce correct geometry. Cloning keeps part.Program untouched.
if (program.Mode == Mode.Incremental)
{
program = (Program)program.Clone();
program.Mode = Mode.Absolute;
}
var offset = part.Location;
var pos = new Vector(0, 0);
List<Vector> current = null;
foreach (var code in program.Codes)
{
if (code is Motion m && m.Suppressed)
continue;
switch (code)
{
case RapidMove rapid:
{
FlushCurrent(sink, ref current);
pos = rapid.EndPoint;
break;
}
case LinearMove linear:
{
if (current == null)
{
current = new List<Vector> { pos + offset };
}
var end = linear.EndPoint;
current.Add(end + offset);
pos = end;
break;
}
case ArcMove arc:
{
if (current == null)
{
current = new List<Vector> { pos + offset };
}
TessellateArc(pos, arc, offset, ArcChordToleranceInches, current);
pos = arc.EndPoint;
break;
}
}
}
FlushCurrent(sink, ref current);
}
private static void FlushCurrent(List<List<Vector>> sink, ref List<Vector> current)
{
if (current != null && current.Count >= 2)
sink.Add(current);
current = null;
}
// Sample points along an arc to within chordTol of the true curve. start is
// the arc's start point (current pen position), arc.CenterPoint is absolute
// (G-code I/J in this codebase are stored as the absolute center), arc.EndPoint
// is absolute end. The starting point is assumed to already be in the polyline;
// intermediate samples and the endpoint are appended.
private static void TessellateArc(Vector start, ArcMove arc, Vector offset,
double chordTol, List<Vector> sink)
{
var c = arc.CenterPoint;
var r = c.DistanceTo(start);
if (r < 1e-9)
{
sink.Add(arc.EndPoint + offset);
return;
}
var a0 = System.Math.Atan2(start.Y - c.Y, start.X - c.X);
var a1 = System.Math.Atan2(arc.EndPoint.Y - c.Y, arc.EndPoint.X - c.X);
double sweep;
if (arc.Rotation == RotationType.CW)
{
sweep = a0 - a1;
if (sweep <= 0) sweep += 2 * System.Math.PI;
}
else
{
sweep = a1 - a0;
if (sweep <= 0) sweep += 2 * System.Math.PI;
}
// Treat a near-zero sweep with coincident start/end as a full circle.
if (sweep < 1e-9 &&
System.Math.Abs(start.X - arc.EndPoint.X) < 1e-9 &&
System.Math.Abs(start.Y - arc.EndPoint.Y) < 1e-9)
{
sweep = 2 * System.Math.PI;
}
// Max angle step from chord-deviation tolerance: dev = r * (1 - cos(t/2)).
var maxAngleStep = 2.0 * System.Math.Acos(System.Math.Max(0.0, 1.0 - chordTol / r));
if (double.IsNaN(maxAngleStep) || maxAngleStep <= 0)
maxAngleStep = System.Math.PI / 32;
var steps = (int)System.Math.Ceiling(sweep / maxAngleStep);
if (steps < 1) steps = 1;
var direction = arc.Rotation == RotationType.CW ? -1.0 : 1.0;
for (int i = 1; i < steps; i++)
{
var t = sweep * (i / (double)steps);
var ang = a0 + direction * t;
var pt = new Vector(c.X + r * System.Math.Cos(ang), c.Y + r * System.Math.Sin(ang));
sink.Add(pt + offset);
}
sink.Add(arc.EndPoint + offset);
}
}
}
OpenNest.Posts.GravographIS/OpenNest.Posts.GravographIS.csproj
+20
View File
@@ -0,0 +1,20 @@
<Project Sdk="Microsoft.NET.Sdk">
<PropertyGroup>
<TargetFramework>net8.0-windows</TargetFramework>
<RootNamespace>OpenNest.Posts.GravographIS</RootNamespace>
</PropertyGroup>
<ItemGroup>
<ProjectReference Include="..\OpenNest.Core\OpenNest.Core.csproj" />
<PackageReference Include="System.IO.Ports" Version="8.0.0" />
</ItemGroup>
<ItemGroup>
<InternalsVisibleTo Include="OpenNest.Tests" />
</ItemGroup>
<Target Name="CopyToPostsDir" AfterTargets="Build">
<PropertyGroup>
<PostsDir>..\OpenNest\bin\$(Configuration)\$(TargetFramework)\Posts\</PostsDir>
</PropertyGroup>
<MakeDir Directories="$(PostsDir)" />
<Copy SourceFiles="$(TargetPath)" DestinationFolder="$(PostsDir)" SkipUnchangedFiles="true" ContinueOnError="true" />
</Target>
</Project>
OpenNest.Posts.GravographIS/PolylinePrePass.cs
+196
View File
@@ -0,0 +1,196 @@
using System;
using System.Collections.Generic;
using OpenNest.Geometry;
namespace OpenNest.Posts.GravographIS
{
/// <summary>
/// Geometry pre-pass for the Gravograph IS8000 backend. The machine is a dumb
/// executor — it never reorders geometry and always lifts between separate
/// entities — so we stitch shared-endpoint polylines together and reorder by
/// nearest-neighbor before encoding.
/// </summary>
public static class PolylinePrePass
{
public const double DefaultStitchTolerance = 1e-6;
/// <summary>
/// Joins polylines whose endpoints coincide (within <paramref name="tolerance"/>)
/// into single continuous polylines. Polylines with fewer than two points are
/// dropped. Direction is reversed as needed to make a join. Each input polyline
/// is copied — the inputs are not mutated.
/// </summary>
public static List<List<Vector>> Stitch(
IEnumerable<IReadOnlyList<Vector>> polylines,
double tolerance = DefaultStitchTolerance)
{
if (polylines == null) throw new ArgumentNullException(nameof(polylines));
var segs = new List<List<Vector>>();
foreach (var p in polylines)
{
if (p == null || p.Count < 2)
continue;
segs.Add(new List<Vector>(p));
}
bool changed;
do
{
changed = false;
for (int i = 0; i < segs.Count; i++)
{
var a = segs[i];
for (int j = 0; j < segs.Count; j++)
{
if (i == j) continue;
var b = segs[j];
// a-end ↔ b-start: append b to a (skip duplicated joint)
if (Near(a[a.Count - 1], b[0], tolerance))
{
for (int k = 1; k < b.Count; k++) a.Add(b[k]);
segs.RemoveAt(j);
if (j < i) i--;
changed = true;
break;
}
// a-end ↔ b-end: append reversed b to a
if (Near(a[a.Count - 1], b[b.Count - 1], tolerance))
{
for (int k = b.Count - 2; k >= 0; k--) a.Add(b[k]);
segs.RemoveAt(j);
if (j < i) i--;
changed = true;
break;
}
// a-start ↔ b-end: prepend b to a
if (Near(a[0], b[b.Count - 1], tolerance))
{
var combined = new List<Vector>(b.Count + a.Count - 1);
combined.AddRange(b);
for (int k = 1; k < a.Count; k++) combined.Add(a[k]);
segs[i] = combined;
segs.RemoveAt(j);
if (j < i) i--;
changed = true;
break;
}
// a-start ↔ b-start: prepend reversed b to a
if (Near(a[0], b[0], tolerance))
{
var combined = new List<Vector>(b.Count + a.Count - 1);
for (int k = b.Count - 1; k >= 0; k--) combined.Add(b[k]);
for (int k = 1; k < a.Count; k++) combined.Add(a[k]);
segs[i] = combined;
segs.RemoveAt(j);
if (j < i) i--;
changed = true;
break;
}
}
if (changed) break;
}
}
while (changed);
return segs;
}
/// <summary>
/// Greedy nearest-neighbor ordering of polylines starting from
/// <paramref name="origin"/> (defaults to 0,0 = the work origin = the first
/// polyline's first point on the wire). When <paramref name="allowReverse"/>
/// is true a polyline may be reversed if its tail is closer than its head.
/// </summary>
public static List<List<Vector>> Reorder(
IEnumerable<IReadOnlyList<Vector>> polylines,
bool allowReverse = true,
Vector? origin = null)
{
if (polylines == null) throw new ArgumentNullException(nameof(polylines));
var pool = new List<List<Vector>>();
foreach (var p in polylines)
{
if (p == null || p.Count < 2)
continue;
pool.Add(new List<Vector>(p));
}
var ordered = new List<List<Vector>>(pool.Count);
var current = origin ?? new Vector(0, 0);
while (pool.Count > 0)
{
var bestIdx = -1;
var bestReverse = false;
var bestDistSq = double.PositiveInfinity;
for (int i = 0; i < pool.Count; i++)
{
var p = pool[i];
var dHead = SquaredDistance(current, p[0]);
if (dHead < bestDistSq)
{
bestDistSq = dHead;
bestIdx = i;
bestReverse = false;
}
if (allowReverse)
{
var dTail = SquaredDistance(current, p[p.Count - 1]);
if (dTail < bestDistSq)
{
bestDistSq = dTail;
bestIdx = i;
bestReverse = true;
}
}
}
var pick = pool[bestIdx];
pool.RemoveAt(bestIdx);
if (bestReverse)
pick.Reverse();
ordered.Add(pick);
current = pick[pick.Count - 1];
}
return ordered;
}
/// <summary>
/// Convenience: stitch then reorder.
/// </summary>
public static List<List<Vector>> Prepare(
IEnumerable<IReadOnlyList<Vector>> polylines,
double stitchTolerance = DefaultStitchTolerance,
bool allowReverse = true,
Vector? origin = null)
{
var stitched = Stitch(polylines, stitchTolerance);
return Reorder(stitched, allowReverse, origin);
}
private static bool Near(Vector a, Vector b, double tol)
{
var dx = a.X - b.X;
var dy = a.Y - b.Y;
return (dx * dx + dy * dy) <= tol * tol;
}
private static double SquaredDistance(Vector a, Vector b)
{
var dx = a.X - b.X;
var dy = a.Y - b.Y;
return dx * dx + dy * dy;
}
}
}
OpenNest.Tests/BestFit/BestFitResultFrameTests.cs
+72
View File
@@ -0,0 +1,72 @@
using OpenNest.Engine;
using OpenNest.Engine.BestFit;
using OpenNest.Geometry;
using OpenNest.Math;
using OpenNest.Shapes;
namespace OpenNest.Tests.BestFit;
public class BestFitResultFrameTests
{
[Fact]
public void BuildCanonicalParts_NonAxisAlignedPairNormalizesActualBounds()
{
var drawing = new TShape { Width = 10, Height = 8 }.GetDrawing();
var canonical = CanonicalFrame.AsCanonicalCopy(drawing);
var result = EvaluateOffsetPair(canonical, new Vector(40, 30));
Assert.True(IsNonAxisAligned(result.OptimalRotation),
$"Expected a non-axis-aligned result, got {Angle.ToDegrees(result.OptimalRotation):F2} degrees.");
var parts = result.BuildCanonicalParts();
var bounds = result.GetCutBounds(parts);
Assert.Equal(0, bounds.Left, 3);
Assert.Equal(0, bounds.Bottom, 3);
Assert.Equal(result.BoundingWidth, bounds.Length, 2);
Assert.Equal(result.BoundingHeight, bounds.Width, 2);
}
[Fact]
public void BuildSourceParts_RebindsCanonicalResultToRotatedSourceDrawing()
{
var drawing = new TShape { Width = 10, Height = 8 }.GetDrawing();
drawing.Program.Rotate(Angle.ToRadians(30), drawing.Program.BoundingBox().Center);
drawing.RecomputeCanonicalAngle();
var canonical = CanonicalFrame.AsCanonicalCopy(drawing);
var result = EvaluateOffsetPair(canonical, new Vector(40, 30));
var parts = result.BuildSourceParts(drawing);
var bounds = result.GetCutBounds(parts);
Assert.All(parts, p => Assert.Same(drawing, p.BaseDrawing));
Assert.Equal(0, bounds.Left, 3);
Assert.Equal(0, bounds.Bottom, 3);
Assert.False(parts[0].Intersects(parts[1], out _));
}
private static BestFitResult EvaluateOffsetPair(Drawing drawing, Vector offset)
{
var candidate = new PairCandidate
{
Drawing = drawing,
Part1Rotation = 0,
Part2Rotation = System.Math.PI,
Part2Offset = offset,
Spacing = 0.25
};
return new PairEvaluator().Evaluate(candidate);
}
private static bool IsNonAxisAligned(double angle)
{
var normalized = Angle.NormalizeRad(angle);
var nearestQuadrant = Angle.HalfPI * System.Math.Round(normalized / Angle.HalfPI);
var delta = System.Math.Abs(normalized - nearestQuadrant);
delta = System.Math.Min(delta, Angle.HalfPI - delta);
return delta > Angle.ToRadians(1);
}
}
OpenNest.Tests/Engine/CanonicalAngleTests.cs
+156
View File
@@ -0,0 +1,156 @@
using System.Linq;
using OpenNest.CNC;
using OpenNest.Converters;
using OpenNest.Engine;
using OpenNest.Geometry;
using OpenNest.Math;
namespace OpenNest.Tests.Engine;
public class CanonicalAngleTests
{
private const double AngleTol = 0.002; // ~0.11°
private static Drawing MakeRect(double w, double h)
{
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new RapidMove(new Vector(0, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, 0)));
return new Drawing("rect", pgm);
}
private static Drawing RotateCopy(Drawing src, double angle)
{
var pgm = src.Program.Clone() as OpenNest.CNC.Program;
pgm.Rotate(angle, pgm.BoundingBox().Center);
return new Drawing("rotated", pgm);
}
[Fact]
public void AxisAlignedRectangle_ReturnsZero()
{
var d = MakeRect(100, 50);
Assert.Equal(0.0, CanonicalAngle.Compute(d), precision: 6);
}
// Program.BoundingBox() has a pre-existing bug where minX/minY initialize to 0 and can
// only decrease, so programs whose extents stay in the positive half-plane report a
// too-large AABB. To validate MBR-axis-alignment without tripping that bug, extract the
// outer perimeter polygon and compute its true AABB from vertices.
private static (double length, double width) TrueAabb(OpenNest.CNC.Program pgm)
{
var entities = ConvertProgram.ToGeometry(pgm).Where(e => e.Layer != SpecialLayers.Rapid);
var shapes = ShapeBuilder.GetShapes(entities);
var outer = shapes.OrderByDescending(s => s.Area()).First();
var poly = outer.ToPolygonWithTolerance(0.1);
var minX = poly.Vertices.Min(v => v.X);
var maxX = poly.Vertices.Max(v => v.X);
var minY = poly.Vertices.Min(v => v.Y);
var maxY = poly.Vertices.Max(v => v.Y);
return (maxX - minX, maxY - minY);
}
[Theory]
[InlineData(0.3)]
[InlineData(0.7)]
[InlineData(1.2)]
public void Rectangle_ReturnsNegatedRotation_Modulo90(double theta)
{
var rotated = RotateCopy(MakeRect(100, 50), theta);
var angle = CanonicalAngle.Compute(rotated);
// Applying the returned angle should leave MBR axis-aligned.
var canonical = rotated.Program.Clone() as OpenNest.CNC.Program;
canonical.Rotate(angle, canonical.BoundingBox().Center);
var (length, width) = TrueAabb(canonical);
var longer = System.Math.Max(length, width);
var shorter = System.Math.Min(length, width);
Assert.InRange(longer, 100 - 0.1, 100 + 0.1);
Assert.InRange(shorter, 50 - 0.1, 50 + 0.1);
}
[Fact]
public void NearZeroInput_SnapsToZero()
{
var rotated = RotateCopy(MakeRect(100, 50), 0.0005);
Assert.Equal(0.0, CanonicalAngle.Compute(rotated), precision: 6);
}
[Fact]
public void DegeneratePolygon_ReturnsZero()
{
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new RapidMove(new Vector(0, 0)));
pgm.Codes.Add(new LinearMove(new Vector(10, 10)));
var d = new Drawing("line", pgm);
Assert.Equal(0.0, CanonicalAngle.Compute(d), precision: 6);
}
[Fact]
public void EmptyProgram_ReturnsZero()
{
var d = new Drawing("empty", new OpenNest.CNC.Program());
Assert.Equal(0.0, CanonicalAngle.Compute(d), precision: 6);
}
}
public class DrawingCanonicalAngleWiringTests
{
private static OpenNest.CNC.Program RotatedRectProgram(double w, double h, double theta)
{
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new RapidMove(new Vector(0, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, 0)));
if (!OpenNest.Math.Tolerance.IsEqualTo(theta, 0))
pgm.Rotate(theta, pgm.BoundingBox().Center);
return pgm;
}
[Fact]
public void Constructor_ComputesAngleOnProgramAssignment()
{
var pgm = RotatedRectProgram(100, 50, 0.5);
var d = new Drawing("r", pgm);
Assert.InRange(d.Source.Angle, -0.52, -0.48);
}
[Fact]
public void SetProgram_RecomputesAngle()
{
var d = new Drawing("r", RotatedRectProgram(100, 50, 0.0));
Assert.Equal(0.0, d.Source.Angle, precision: 6);
d.Program = RotatedRectProgram(100, 50, 0.5);
Assert.InRange(d.Source.Angle, -0.52, -0.48);
}
[Fact]
public void IsCutOff_SkipsAngleComputation()
{
var d = new Drawing("cut", RotatedRectProgram(100, 50, 0.5)) { IsCutOff = true };
// Re-assign after flag is set so the setter observes IsCutOff.
d.Program = RotatedRectProgram(100, 50, 0.5);
Assert.Equal(0.0, d.Source.Angle, precision: 6);
}
[Fact]
public void RecomputeCanonicalAngle_UpdatesAfterMutation()
{
var d = new Drawing("r", RotatedRectProgram(100, 50, 0.0));
Assert.Equal(0.0, d.Source.Angle, precision: 6);
// Mutate in-place (doesn't trigger setter).
d.Program.Rotate(0.5, d.Program.BoundingBox().Center);
Assert.Equal(0.0, d.Source.Angle, precision: 6); // still stale
d.RecomputeCanonicalAngle();
Assert.InRange(d.Source.Angle, -0.52, -0.48);
}
}
OpenNest.Tests/Engine/CanonicalFrameTests.cs
+84
View File
@@ -0,0 +1,84 @@
using OpenNest.CNC;
using OpenNest.Engine;
using OpenNest.Geometry;
using OpenNest.Math;
namespace OpenNest.Tests.Engine;
public class CanonicalFrameTests
{
private static Drawing MakeRect(double w, double h, double rotation)
{
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new RapidMove(new Vector(0, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, 0)));
pgm.Codes.Add(new LinearMove(new Vector(w, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, h)));
pgm.Codes.Add(new LinearMove(new Vector(0, 0)));
if (!Tolerance.IsEqualTo(rotation, 0))
pgm.Rotate(rotation, pgm.BoundingBox().Center);
return new Drawing("rect", pgm) { Source = new SourceInfo { Angle = -rotation } };
}
[Fact]
public void AsCanonicalCopy_AxisAlignsMbr()
{
var d = MakeRect(100, 50, 0.6);
var canonical = CanonicalFrame.AsCanonicalCopy(d);
var bb = canonical.Program.BoundingBox();
var longer = System.Math.Max(bb.Length, bb.Width);
var shorter = System.Math.Min(bb.Length, bb.Width);
Assert.InRange(longer, 100 - 0.1, 100 + 0.1);
Assert.InRange(shorter, 50 - 0.1, 50 + 0.1);
Assert.Equal(0.0, canonical.Source.Angle, precision: 6);
}
[Fact]
public void AsCanonicalCopy_DoesNotMutateSource()
{
var d = MakeRect(100, 50, 0.6);
var originalBbox = d.Program.BoundingBox();
var originalAngle = d.Source.Angle;
CanonicalFrame.AsCanonicalCopy(d);
var afterBbox = d.Program.BoundingBox();
Assert.Equal(originalBbox.Width, afterBbox.Width, precision: 6);
Assert.Equal(originalBbox.Length, afterBbox.Length, precision: 6);
Assert.Equal(originalAngle, d.Source.Angle, precision: 6);
}
[Fact]
public void FromCanonical_ComposesSourceAngleOntoRotation()
{
var d = MakeRect(100, 50, 0.0);
var part = new Part(d);
part.Rotate(0.2); // engine returned a canonical-frame part at R = 0.2
var placed = CanonicalFrame.FromCanonical(new List<Part> { part }, sourceAngle: -0.5);
// R' = R + sourceAngle = 0.2 + (-0.5) = -0.3
// Part.Rotation comes from Program.Rotation which is normalized to [0, 2PI),
// so compare after normalizing the expected value as well.
Assert.Single(placed);
Assert.Equal(Angle.NormalizeRad(-0.3), placed[0].Rotation, precision: 4);
}
[Fact]
public void RoundTrip_RestoresGeometry()
{
var d = MakeRect(100, 50, 0.4);
var canonical = CanonicalFrame.AsCanonicalCopy(d);
// Place a part at origin in the canonical frame.
var part = Part.CreateAtOrigin(canonical);
var canonicalBbox = part.BoundingBox;
var placed = CanonicalFrame.FromCanonical(new List<Part> { part }, d.Source.Angle);
var originalBbox = d.Program.BoundingBox();
Assert.Equal(originalBbox.Width, placed[0].BoundingBox.Width, precision: 2);
Assert.Equal(originalBbox.Length, placed[0].BoundingBox.Length, precision: 2);
}
}
OpenNest.Tests/Engine/NestInvarianceTests.cs
+84
View File
@@ -0,0 +1,84 @@
using OpenNest.CNC;
using OpenNest.Engine;
using OpenNest.Engine.BestFit;
using OpenNest.Geometry;
using OpenNest.Math;
using System.Threading;
namespace OpenNest.Tests.Engine;
public class NestInvarianceTests
{
private static OpenNest.CNC.Program MakeLShapedProgram()
{
// L-shape: 100x50 outer rect with a 50x30 notch removed from top-right.
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new RapidMove(new Vector(0, 0)));
pgm.Codes.Add(new LinearMove(new Vector(100, 0)));
pgm.Codes.Add(new LinearMove(new Vector(100, 20)));
pgm.Codes.Add(new LinearMove(new Vector(50, 20)));
pgm.Codes.Add(new LinearMove(new Vector(50, 50)));
pgm.Codes.Add(new LinearMove(new Vector(0, 50)));
pgm.Codes.Add(new LinearMove(new Vector(0, 0)));
return pgm;
}
private static Drawing MakeImportedAt(double rotation)
{
var pgm = MakeLShapedProgram();
if (!Tolerance.IsEqualTo(rotation, 0))
pgm.Rotate(rotation, pgm.BoundingBox().Center);
return new Drawing("L", pgm);
}
private static Plate MakePlate() => new Plate(new Size(500, 500))
{
Quadrant = 1,
PartSpacing = 2,
};
private static int RunFillCount(Drawing drawing, Plate plate)
{
BestFitCache.Clear();
var engine = new DefaultNestEngine(plate);
var item = new NestItem { Drawing = drawing };
var parts = engine.Fill(item, plate.WorkArea(), progress: null, token: CancellationToken.None);
return parts?.Count ?? 0;
}
[Theory]
[InlineData(0.0)]
[InlineData(0.3)]
[InlineData(0.8)]
[InlineData(1.2)]
public void Fill_SameCount_AcrossImportOrientations(double theta)
{
var baseline = RunFillCount(MakeImportedAt(0.0), MakePlate());
var rotated = RunFillCount(MakeImportedAt(theta), MakePlate());
// Allow +/-1 tolerance for sweep quantization edge effects near plate boundaries.
Assert.InRange(rotated, baseline - 1, baseline + 1);
}
[Fact]
public void Fill_PlacedPartsStayWithinWorkArea_AcrossImportOrientations()
{
var plate = MakePlate();
var workArea = plate.WorkArea();
foreach (var theta in new[] { 0.0, 0.3, 0.8, 1.2 })
{
BestFitCache.Clear();
var engine = new DefaultNestEngine(plate);
var item = new NestItem { Drawing = MakeImportedAt(theta) };
var parts = engine.Fill(item, workArea, progress: null, token: CancellationToken.None);
Assert.NotNull(parts);
foreach (var p in parts)
{
Assert.InRange(p.BoundingBox.Left, workArea.Left - 0.5, workArea.Right + 0.5);
Assert.InRange(p.BoundingBox.Bottom, workArea.Bottom - 0.5, workArea.Top + 0.5);
}
}
}
}
OpenNest.Tests/Fill/CompactorTests.cs
+107
View File
@@ -97,6 +97,33 @@ namespace OpenNest.Tests.Fill
return part;
}
private static Drawing MakeTriangleDrawing(params Vector[] points)
{
var pgm = new OpenNest.CNC.Program();
pgm.Codes.Add(new OpenNest.CNC.RapidMove(points[0]));
for (var i = 1; i < points.Length; i++)
pgm.Codes.Add(new OpenNest.CNC.LinearMove(points[i]));
pgm.Codes.Add(new OpenNest.CNC.LinearMove(points[0]));
return new Drawing("triangle", pgm);
}
private static Part MakeTrianglePart(params Vector[] points)
{
var part = new Part(MakeTriangleDrawing(points));
part.UpdateBounds();
return part;
}
private static Part MakeTrianglePart(double x, double y, params Vector[] points)
{
var part = MakeTrianglePart(points);
part.Location = new Vector(x, y);
part.UpdateBounds();
return part;
}
[Fact]
public void Push_Left_MovesPartTowardEdge()
{
@@ -171,6 +198,86 @@ namespace OpenNest.Tests.Fill
Assert.NotEqual(distNoSpacing, distWithSpacing);
}
[Fact]
public void Push_Up_AllowsSharedDiagonalEdgeToSeparate()
{
var workArea = new Box(0, 0, 20, 20);
var obstacle = MakeTrianglePart(
new Vector(0, 0),
new Vector(10, 0),
new Vector(0, 10));
var movingPart = MakeTrianglePart(
new Vector(0, 10),
new Vector(10, 0),
new Vector(10, 10));
var distance = Compactor.Push(
new List<Part> { movingPart },
new List<Part> { obstacle },
workArea,
0,
PushDirection.Up);
Assert.True(distance > 0);
Assert.True(movingPart.BoundingBox.Top > 19.9);
Assert.False(movingPart.Intersects(obstacle, out _));
}
[Fact]
public void Push_Up_MovesAfterRightTriangleIsPushedLeftIntoSharedEdge()
{
var workArea = new Box(0, 0, 24, 24);
var leftTriangle = MakeTrianglePart(
2, 2,
new Vector(0, 0),
new Vector(8, 0),
new Vector(4, 10));
var rightTriangle = MakeTrianglePart(
14, 4,
new Vector(0, 10),
new Vector(8, 10),
new Vector(4, 0));
var moving = new List<Part> { rightTriangle };
var obstacles = new List<Part> { leftTriangle };
var leftDistance = Compactor.Push(moving, obstacles, workArea, 0, PushDirection.Left);
var yBeforePushUp = rightTriangle.Location.Y;
var bottomBeforePushUp = rightTriangle.BoundingBox.Bottom;
var upDistance = Compactor.Push(moving, obstacles, workArea, 0, PushDirection.Up);
Assert.True(leftDistance > 0);
Assert.True(upDistance > 0);
Assert.True(rightTriangle.Location.Y > yBeforePushUp);
Assert.True(rightTriangle.BoundingBox.Bottom > bottomBeforePushUp);
Assert.False(rightTriangle.Intersects(leftTriangle, out _));
}
[Fact]
public void Push_Left_BlocksWhenSharedDiagonalEdgeWouldOverlap()
{
var workArea = new Box(0, 0, 20, 20);
var obstacle = MakeTrianglePart(
new Vector(0, 0),
new Vector(10, 0),
new Vector(0, 10));
var movingPart = MakeTrianglePart(
new Vector(0, 10),
new Vector(10, 0),
new Vector(10, 10));
var distance = Compactor.Push(
new List<Part> { movingPart },
new List<Part> { obstacle },
workArea,
0,
PushDirection.Left);
Assert.Equal(0, distance);
Assert.Equal(0, movingPart.BoundingBox.Left);
}
[Fact]
public void Push_AngleLeft_MovesPartTowardEdge()
{
OpenNest.Tests/Geometry/BoxComparisonTests.cs
+97
View File
@@ -0,0 +1,97 @@
using System;
using System.Collections.Generic;
using OpenNest.Geometry;
using Xunit;
namespace OpenNest.Tests.Geometry;
public class BoxComparisonTests
{
[Fact]
public void GreaterThan_TallerBox_ReturnsTrue()
{
var tall = new Box(0, 0, 10, 20);
var short_ = new Box(0, 0, 10, 10);
Assert.True(tall > short_);
Assert.False(short_ > tall);
}
[Fact]
public void GreaterThan_SameWidthLongerBox_ReturnsTrue()
{
var longer = new Box(0, 0, 20, 10);
var shorter = new Box(0, 0, 10, 10);
Assert.True(longer > shorter);
Assert.False(shorter > longer);
}
[Fact]
public void LessThan_ShorterBox_ReturnsTrue()
{
var tall = new Box(0, 0, 10, 20);
var short_ = new Box(0, 0, 10, 10);
Assert.True(short_ < tall);
Assert.False(tall < short_);
}
[Fact]
public void GreaterThanOrEqual_EqualBoxes_ReturnsTrue()
{
var a = new Box(0, 0, 10, 20);
var b = new Box(0, 0, 10, 20);
Assert.True(a >= b);
Assert.True(b >= a);
}
[Fact]
public void LessThanOrEqual_EqualBoxes_ReturnsTrue()
{
var a = new Box(0, 0, 10, 20);
var b = new Box(0, 0, 10, 20);
Assert.True(a <= b);
Assert.True(b <= a);
}
[Fact]
public void CompareTo_TallerBox_ReturnsPositive()
{
var tall = new Box(0, 0, 10, 20);
var short_ = new Box(0, 0, 10, 10);
Assert.True(tall.CompareTo(short_) > 0);
Assert.True(short_.CompareTo(tall) < 0);
}
[Fact]
public void CompareTo_EqualBoxes_ReturnsZero()
{
var a = new Box(0, 0, 10, 20);
var b = new Box(0, 0, 10, 20);
Assert.Equal(0, a.CompareTo(b));
}
[Fact]
public void Sort_OrdersByWidthThenLength()
{
var boxes = new List<Box>
{
new Box(0, 0, 20, 10),
new Box(0, 0, 5, 30),
new Box(0, 0, 10, 10),
};
boxes.Sort();
Assert.Equal(10, boxes[0].Width);
Assert.Equal(10, boxes[0].Length);
Assert.Equal(10, boxes[1].Width);
Assert.Equal(20, boxes[1].Length);
Assert.Equal(30, boxes[2].Width);
}
}
OpenNest.Tests/Geometry/EllipseConverterTests.cs
+100
View File
@@ -1,14 +1,19 @@
using OpenNest.Geometry;
using OpenNest.IO;
using OpenNest.Math;
using Xunit;
using Xunit.Abstractions;
using System.Linq;
namespace OpenNest.Tests.Geometry;
public class EllipseConverterTests
{
private readonly ITestOutputHelper _output;
private const double Tol = 1e-10;
public EllipseConverterTests(ITestOutputHelper output) => _output = output;
[Fact]
public void EvaluatePoint_AtZero_ReturnsMajorAxisEnd()
{
@@ -244,6 +249,101 @@ public class EllipseConverterTests
}
}
[Fact]
public void DxfImport_ArcBoundingBoxes_Diagnostic()
{
var path = @"C:\Users\aisaacs\Desktop\11ga tab.dxf";
if (!System.IO.File.Exists(path)) return;
var result = Dxf.Import(path);
var all = (System.Collections.Generic.IEnumerable<IBoundable>)result.Entities;
var bbox = all.GetBoundingBox();
_output.WriteLine($"Overall: X={bbox.X:F4} Y={bbox.Y:F4} W={bbox.Length:F4} H={bbox.Width:F4}");
for (var i = 0; i < result.Entities.Count; i++)
{
var e = result.Entities[i];
var b = e.BoundingBox;
var flag = (b.Length > 1 || b.Width > 1) ? " ***" : "";
_output.WriteLine($"{i + 1,3}. {e.GetType().Name,-8} X={b.X:F4} Y={b.Y:F4} W={b.Length:F4} H={b.Width:F4}{flag}");
}
}
[Fact]
public void ToOpenNest_FlippedNormalZ_ProducesCorrectArcs()
{
var normal = new ACadSharp.Entities.Ellipse
{
Center = new CSMath.XYZ(-0.275, -0.245, 0),
MajorAxisEndPoint = new CSMath.XYZ(0.0001, 1.245, 0),
RadiusRatio = 0.28,
StartParameter = 0.017,
EndParameter = 1.571,
Normal = new CSMath.XYZ(0, 0, 1)
};
var flipped = new ACadSharp.Entities.Ellipse
{
Center = new CSMath.XYZ(0.275, -0.245, 0),
MajorAxisEndPoint = new CSMath.XYZ(-0.0001, 1.245, 0),
RadiusRatio = 0.28,
StartParameter = 0.017,
EndParameter = 1.571,
Normal = new CSMath.XYZ(0, 0, -1)
};
var normalArcs = normal.ToOpenNest();
var flippedArcs = flipped.ToOpenNest();
Assert.True(normalArcs.Count > 0);
Assert.True(flippedArcs.Count > 0);
Assert.True(normalArcs.All(e => e is Arc));
Assert.True(flippedArcs.All(e => e is Arc));
var normalFirst = (Arc)normalArcs.First();
var flippedFirst = (Arc)flippedArcs.First();
var normalStart = GetArcStart(normalFirst);
var flippedStart = GetArcStart(flippedFirst);
Assert.True(normalStart.X < 0, $"Normal ellipse start X should be negative, got {normalStart.X}");
Assert.True(flippedStart.X > 0, $"Flipped ellipse should bulge right, got {flippedStart.X}");
var normalBbox = GetBoundingBox(normalArcs.Cast<Arc>());
var flippedBbox = GetBoundingBox(flippedArcs.Cast<Arc>());
Assert.True(flippedBbox.minX > 0, $"Flipped ellipse should stay on positive X side, minX={flippedBbox.minX}");
Assert.True(normalBbox.maxX < 0, $"Normal ellipse should stay on negative X side, maxX={normalBbox.maxX}");
}
private static (double minX, double maxX) GetBoundingBox(IEnumerable<Arc> arcs)
{
var minX = double.MaxValue;
var maxX = double.MinValue;
foreach (var arc in arcs)
{
var s = GetArcStart(arc);
var e = GetArcEnd(arc);
minX = System.Math.Min(minX, System.Math.Min(s.X, e.X));
maxX = System.Math.Max(maxX, System.Math.Max(s.X, e.X));
}
return (minX, maxX);
}
private static Vector GetArcStart(Arc arc)
{
var angle = arc.IsReversed ? arc.EndAngle : arc.StartAngle;
return new Vector(
arc.Center.X + arc.Radius * System.Math.Cos(angle),
arc.Center.Y + arc.Radius * System.Math.Sin(angle));
}
private static Vector GetArcEnd(Arc arc)
{
var angle = arc.IsReversed ? arc.StartAngle : arc.EndAngle;
return new Vector(
arc.Center.X + arc.Radius * System.Math.Cos(angle),
arc.Center.Y + arc.Radius * System.Math.Sin(angle));
}
private static double MaxDeviationFromEllipse(Arc arc, Vector ellipseCenter,
double semiMajor, double semiMinor, double rotation, int samples)
{
OpenNest.Tests/Geometry/WeldEndpointsTests.cs
+72
View File
@@ -0,0 +1,72 @@
using System.Collections.Generic;
using OpenNest.Geometry;
using OpenNest.Math;
using Xunit;
namespace OpenNest.Tests.Geometry;
public class WeldEndpointsTests
{
[Fact]
public void WeldEndpoints_SnapsNearbyLineEndpoints()
{
var line1 = new Line(0, 0, 10, 0);
var line2 = new Line(10.0000005, 0, 20, 0);
var entities = new List<Entity> { line1, line2 };
ShapeBuilder.WeldEndpoints(entities, 0.000001);
Assert.True(line1.EndPoint.DistanceTo(line2.StartPoint) <= Tolerance.Epsilon);
}
[Fact]
public void WeldEndpoints_SnapsArcEndpointByAdjustingAngle()
{
var line = new Line(0, 0, 10, 0);
var arc = new Arc(15, 0, 5, Angle.ToRadians(180.001), Angle.ToRadians(90));
var entities = new List<Entity> { line, arc };
ShapeBuilder.WeldEndpoints(entities, 0.01);
var arcStart = arc.StartPoint();
Assert.True(line.EndPoint.DistanceTo(arcStart) <= 0.01);
}
[Fact]
public void WeldEndpoints_DoesNotWeldDistantEndpoints()
{
var line1 = new Line(0, 0, 10, 0);
var line2 = new Line(10.1, 0, 20, 0);
var entities = new List<Entity> { line1, line2 };
ShapeBuilder.WeldEndpoints(entities, 0.000001);
Assert.True(line1.EndPoint.DistanceTo(line2.StartPoint) > 0.01);
}
[Fact]
public void GetShapes_WithWeldTolerance_WeldsBeforeChaining()
{
var line1 = new Line(0, 0, 10, 0);
var line2 = new Line(10.0000005, 0, 10.0000005, 10);
var entities = new List<Entity> { line1, line2 };
var shapes = ShapeBuilder.GetShapes(entities, weldTolerance: 0.000001);
Assert.Single(shapes);
Assert.Equal(2, shapes[0].Entities.Count);
}
[Fact]
public void GetShapes_WithoutWeldTolerance_DefaultBehavior()
{
var line1 = new Line(0, 0, 10, 0);
var line2 = new Line(10, 0, 10, 10);
var entities = new List<Entity> { line1, line2 };
var shapes = ShapeBuilder.GetShapes(entities);
Assert.Single(shapes);
Assert.Equal(2, shapes[0].Entities.Count);
}
}
OpenNest.Tests/GravographIS/EnvelopeGuardTests.cs
+165
View File
@@ -0,0 +1,165 @@
using System.Collections.Generic;
using System.IO;
using OpenNest.Geometry;
using OpenNest.Posts.GravographIS;
namespace OpenNest.Tests.GravographIS;
public class EnvelopeGuardTests
{
// 0.610 m / 0.0125 mm/step = 48 800 steps = 24.0157 inches
// 1.220 m / 0.0125 mm/step = 97 600 steps = 48.0315 inches
[Fact]
public void NegativeX_FromOrigin_Throws()
{
// Operator origin is upper-left; quadrant 4 walks right/down. A cut that walks
// left of origin in -X must be refused.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(-1, 0) },
};
var ex = Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
});
Assert.Contains("Polyline 1", ex.Message);
Assert.Contains("cut segment", ex.Message);
Assert.Contains("segment 1", ex.Message);
}
[Fact]
public void PositiveY_FromOrigin_Throws()
{
// Positive input-Y is above the upper-left origin in quadrant 4.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(0, 1) },
};
var ex = Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
});
Assert.Contains("Polyline 1", ex.Message);
}
[Fact]
public void XExceedsEnvelope_Throws_AndNamesSegment()
{
// 25" in X is past the 0.610 m (~24.02") envelope.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(10, 0), new Vector(25, 0) },
};
var ex = Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
});
Assert.Contains("Polyline 1", ex.Message);
Assert.Contains("segment 2", ex.Message); // 0→10 ok; 10→25 trips
Assert.Contains("25.000\"", ex.Message);
}
[Fact]
public void YExceedsEnvelope_Throws()
{
// -49" in Y is past the 1.220 m (~48.03") envelope.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(0, -49) },
};
Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
});
}
[Fact]
public void PenUpTravel_OutsideEnvelope_AlsoThrows_AndIsLabeledTravel()
{
// Polyline 1 ends in-envelope; the PU travel to polyline 2 leaves it.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(30, 0), new Vector(30, -1) },
};
var ex = Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
});
Assert.Contains("Polyline 2", ex.Message);
Assert.Contains("pen-up travel", ex.Message);
}
[Fact]
public void RightAtEnvelopeCorner_IsAllowed()
{
// Walk to (24", -48") in int16-sized hops (each delta < 16.1"). The
// catalog envelope is 24.02" × 48.03", so this lands just inside.
var polylines = new List<IReadOnlyList<Vector>>
{
new[]
{
new Vector(0, 0),
new Vector(8, -16),
new Vector(16, -32),
new Vector(24, -48),
},
};
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms); // no throw
Assert.True(ms.Length > 0);
}
[Fact]
public void EnvelopeGuard_CanBeDisabled_ForOffMachineEncoding()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(-5, 0) },
};
var opts = new GravographISWriterOptions { EnvelopeGuardEnabled = false };
using var ms = new MemoryStream();
new GravographISWriter(opts).Write(polylines, ms); // no throw
Assert.True(ms.Length > 0);
}
[Fact]
public void CustomEnvelope_TightensTheCheck()
{
// Restrict to 1" × 1" — a 2" line in -Y now overshoots.
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(0, -2) },
};
var opts = new GravographISWriterOptions
{
WorkEnvelopeXMm = 25.4,
WorkEnvelopeYMm = 25.4,
};
Assert.Throws<System.InvalidOperationException>(() =>
{
using var ms = new MemoryStream();
new GravographISWriter(opts).Write(polylines, ms);
});
}
}
OpenNest.Tests/GravographIS/GravographISWriterTests.cs
+223
View File
@@ -0,0 +1,223 @@
using System.Collections.Generic;
using System.IO;
using OpenNest.Geometry;
using OpenNest.Posts.GravographIS;
namespace OpenNest.Tests.GravographIS;
public class GravographISWriterTests
{
// 93-byte preamble captured from GravoStyle'98 (VS/VZ=35, DZ=508 → matches defaults).
// The original capture ended with a DR command (FF FD 44 52) followed by three
// 8-byte int16 records carrying a chunked job-specific travel (~1" X, ~47" Y).
// Stripped from the writer (see GravographISWriter.PreambleTemplate) because
// those frozen deltas send the head to a fixed point regardless of the job. The
// writer now emits a job-specific leading DR travel from operator zero instead.
private const string PreambleHex =
"21 41 53 20 33 38 3b 01 90 01 f4 01 90 01 f4 01 90 01 f4 00 00 00 00 00 00 00 00 00 00 " +
"00 00 00 09 00 00 03 e8 05 06 00 00 00 00 00 00 ff fd 32 44 00 00 ff fd 4d 43 00 01 ff fd " +
"4f 55 ff fb ff fd 4f 55 ff fa ff fd 50 5a 00 00 ff fd 56 53 00 23 ff fd 56 5a 00 23 ff fd " +
"44 5a 01 fc";
// Legacy 36-byte tail with lift, aux off, motor off, operator beep, job finish.
// Byte-exact capture tests disable dynamic return-to-origin to preserve this form.
private const string PostambleHex =
"ff fd 50 55 00 01 ff fd 4f 55 ff fa ff fd 4f 55 ff fb ff fd 4d 43 00 00 " +
"ff fd 4f 50 00 00 ff fd 4a 46 00 00";
[Fact]
public void TestA_SingleTwoInchVerticalLine_IsByteExact()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(1, 1), new Vector(1, 3) },
};
var writer = new GravographISWriter(new GravographISWriterOptions
{
DepthInches = 0.25,
FeedMmPerSec = 35,
EnvelopeGuardEnabled = false,
ReturnToOriginAtEnd = false,
});
using var ms = new MemoryStream();
writer.Write(polylines, ms);
const string GeomHex =
"ff fd 44 52 00 00 2d 41 00 80 07 f0 f8 10 " +
"ff fd 50 44 00 00 40 00 00 b4 00 00 f0 20";
var expected = HexToBytes(PreambleHex + " " + GeomHex + " " + PostambleHex);
Assert.Equal(expected, ms.ToArray());
}
[Fact]
public void TestB_FourLines_IsByteExact()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(1, 1), new Vector(1, 3) },
new[] { new Vector(4, 1), new Vector(4, 3) },
new[] { new Vector(4, 5), new Vector(4, 7) },
new[] { new Vector(1, 5), new Vector(1, 7) },
};
var writer = new GravographISWriter(new GravographISWriterOptions
{
DepthInches = 0.25,
FeedMmPerSec = 35,
EnvelopeGuardEnabled = false,
ReturnToOriginAtEnd = false,
});
using var ms = new MemoryStream();
writer.Write(polylines, ms);
const string GeomHex =
"ff fd 44 52 00 00 2d 41 00 80 07 f0 f8 10 " +
"ff fd 50 44 00 00 40 00 00 b4 00 00 f0 20 " +
"ff fd 50 55 00 00 35 40 00 b4 17 d0 0f e0 " +
"ff fd 50 44 00 00 40 00 00 b4 00 00 f0 20 " +
"ff fd 50 55 00 00 40 00 00 b4 00 00 f0 20 " +
"ff fd 50 44 00 00 40 00 00 b4 00 00 f0 20 " +
"ff fd 50 55 00 00 35 40 00 b4 e8 30 0f e0 " +
"ff fd 50 44 00 00 40 00 00 b4 00 00 f0 20";
var expected = HexToBytes(PreambleHex + " " + GeomHex + " " + PostambleHex);
Assert.Equal(expected, ms.ToArray());
}
[Fact]
public void LeadingDR_TravelsToFirstPolylineStartBeforePD()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(2, 2), new Vector(3, 2) },
};
using var ms = new MemoryStream();
new GravographISWriter(new GravographISWriterOptions { EnvelopeGuardEnabled = false }).Write(polylines, ms);
var bytes = ms.ToArray();
// First command after the 93-byte preamble must be DR to the first point,
// followed by PD for the first cut.
Assert.Equal(0xFF, bytes[93]);
Assert.Equal(0xFD, bytes[94]);
Assert.Equal((byte)'D', bytes[95]);
Assert.Equal((byte)'R', bytes[96]);
Assert.Equal(0xFF, bytes[107]);
Assert.Equal(0xFD, bytes[108]);
Assert.Equal((byte)'P', bytes[109]);
Assert.Equal((byte)'D', bytes[110]);
}
[Fact]
public void LeadingDR_LongTravel_IsChunked()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(1, 47), new Vector(2, 47) },
};
using var ms = new MemoryStream();
new GravographISWriter(new GravographISWriterOptions { EnvelopeGuardEnabled = false }).Write(polylines, ms);
var bytes = ms.ToArray();
Assert.Equal((byte)'D', bytes[95]);
Assert.Equal((byte)'R', bytes[96]);
Assert.Equal((byte)'P', bytes[125]);
Assert.Equal((byte)'D', bytes[126]);
}
[Fact]
public void OptionsPatchVsVzDz()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(0.5, 0) },
};
using var ms = new MemoryStream();
new GravographISWriter(new GravographISWriterOptions
{
DepthInches = 0.125, // 254 steps = 0x00FE
FeedMmPerSec = 50, // 0x0032
}).Write(polylines, ms);
var bytes = ms.ToArray();
AssertOperand(bytes, (byte)'V', (byte)'S', 0x00, 0x32);
AssertOperand(bytes, (byte)'V', (byte)'Z', 0x00, 0x32);
AssertOperand(bytes, (byte)'D', (byte)'Z', 0x00, 0xFE);
}
[Fact]
public void ReturnsToOriginAfterFinalLift_ByDefault()
{
var polylines = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0), new Vector(1, -1) },
};
using var ms = new MemoryStream();
new GravographISWriter().Write(polylines, ms);
var bytes = ms.ToArray();
var liftIndex = LastIndexOfCommand(bytes, (byte)'P', (byte)'U', 0x00, 0x01);
Assert.True(liftIndex >= 0);
Assert.Equal(0xFF, bytes[liftIndex + 6]);
Assert.Equal(0xFD, bytes[liftIndex + 7]);
Assert.Equal((byte)'P', bytes[liftIndex + 8]);
Assert.Equal((byte)'U', bytes[liftIndex + 9]);
var dx = ReadInt16(bytes, liftIndex + 16);
var dy = ReadInt16(bytes, liftIndex + 18);
Assert.Equal(-GravographISWriter.StepsPerInch, dx);
Assert.Equal(-GravographISWriter.StepsPerInch, dy);
}
private static void AssertOperand(byte[] bytes, byte c0, byte c1, byte hi, byte lo)
{
for (var i = 0; i < bytes.Length - 5; i++)
{
if (bytes[i] == 0xFF && bytes[i + 1] == 0xFD && bytes[i + 2] == c0 && bytes[i + 3] == c1)
{
Assert.Equal(hi, bytes[i + 4]);
Assert.Equal(lo, bytes[i + 5]);
return;
}
}
Assert.Fail($"Command {(char)c0}{(char)c1} not found in stream.");
}
private static int LastIndexOfCommand(byte[] bytes, byte c0, byte c1, byte hi, byte lo)
{
for (var i = bytes.Length - 6; i >= 0; i--)
{
if (bytes[i] == 0xFF && bytes[i + 1] == 0xFD &&
bytes[i + 2] == c0 && bytes[i + 3] == c1 &&
bytes[i + 4] == hi && bytes[i + 5] == lo)
{
return i;
}
}
return -1;
}
private static short ReadInt16(byte[] bytes, int offset)
{
return unchecked((short)((bytes[offset] << 8) | bytes[offset + 1]));
}
internal static byte[] HexToBytes(string hex)
{
var clean = hex.Replace(" ", string.Empty).Replace("\n", string.Empty).Replace("\r", string.Empty);
var bytes = new byte[clean.Length / 2];
for (var i = 0; i < bytes.Length; i++)
bytes[i] = System.Convert.ToByte(clean.Substring(i * 2, 2), 16);
return bytes;
}
}
OpenNest.Tests/GravographIS/NestPolylineExtractorTests.cs
+37
View File
@@ -0,0 +1,37 @@
using OpenNest;
using OpenNest.CNC;
using OpenNest.Geometry;
using OpenNest.Posts.GravographIS;
namespace OpenNest.Tests.GravographIS;
public class NestPolylineExtractorTests
{
[Fact]
public void ExtractPart_IncrementalProgram_ProducesAbsoluteCoordinates()
{
// 1x1 square in G91 (incremental) mode — the form OpenNest's UI writes
// to .nest files. Without absolute-mode handling the extractor plotted
// each EndPoint as if it were absolute, producing a 2x2 diamond.
var program = new Program(Mode.Incremental);
program.Codes.Add(new RapidMove(new Vector(0, 0)));
program.Codes.Add(new LinearMove(1, 0));
program.Codes.Add(new LinearMove(0, 1));
program.Codes.Add(new LinearMove(-1, 0));
program.Codes.Add(new LinearMove(0, -1));
var drawing = new Drawing("Square 1x1", program);
var part = new Part(drawing, new Vector(0.25, 46.75));
var polylines = new NestPolylineExtractor().ExtractPart(part);
Assert.Single(polylines);
var poly = polylines[0];
Assert.Equal(5, poly.Count);
Assert.Equal(new Vector(0.25, 46.75), poly[0]);
Assert.Equal(new Vector(1.25, 46.75), poly[1]);
Assert.Equal(new Vector(1.25, 47.75), poly[2]);
Assert.Equal(new Vector(0.25, 47.75), poly[3]);
Assert.Equal(new Vector(0.25, 46.75), poly[4]);
}
}
OpenNest.Tests/GravographIS/PolylinePrePassTests.cs
+164
View File
@@ -0,0 +1,164 @@
using System.Collections.Generic;
using OpenNest.Geometry;
using OpenNest.Posts.GravographIS;
namespace OpenNest.Tests.GravographIS;
public class PolylinePrePassTests
{
[Fact]
public void Stitch_TwoConnectedSegments_BecomeOnePolyline()
{
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(1, 0), new Vector(1, 1) },
};
var stitched = PolylinePrePass.Stitch(inputs);
Assert.Single(stitched);
Assert.Equal(3, stitched[0].Count);
Assert.Equal(new Vector(0, 0), stitched[0][0]);
Assert.Equal(new Vector(1, 0), stitched[0][1]);
Assert.Equal(new Vector(1, 1), stitched[0][2]);
}
[Fact]
public void Stitch_FourSegmentsFormingClosedSquare_BecomeOnePolyline()
{
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(1, 0), new Vector(1, 1) },
new[] { new Vector(1, 1), new Vector(0, 1) },
new[] { new Vector(0, 1), new Vector(0, 0) },
};
var stitched = PolylinePrePass.Stitch(inputs);
Assert.Single(stitched);
// Four edges + closing return-to-start = five vertices.
Assert.Equal(5, stitched[0].Count);
}
[Fact]
public void Stitch_ReversesOneSegmentToMakeAJoin()
{
// Second segment is given backward; stitcher should reverse it.
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(2, 0), new Vector(1, 0) },
};
var stitched = PolylinePrePass.Stitch(inputs);
Assert.Single(stitched);
Assert.Equal(3, stitched[0].Count);
Assert.Equal(new Vector(0, 0), stitched[0][0]);
Assert.Equal(new Vector(2, 0), stitched[0][stitched[0].Count - 1]);
}
[Fact]
public void Stitch_DisjointSegments_StayDistinct()
{
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(5, 5), new Vector(6, 5) },
};
var stitched = PolylinePrePass.Stitch(inputs);
Assert.Equal(2, stitched.Count);
}
[Fact]
public void Stitch_DropsZeroAndSinglePointPolylines()
{
var inputs = new List<IReadOnlyList<Vector>>
{
new Vector[] { },
new[] { new Vector(0, 0) },
new[] { new Vector(0, 0), new Vector(1, 0) },
};
var stitched = PolylinePrePass.Stitch(inputs);
Assert.Single(stitched);
Assert.Equal(2, stitched[0].Count);
}
[Fact]
public void Reorder_ReducesTotalPenUpTravelVsWorstCase()
{
// Three short polylines at (0,0), (10,0), (5,0). The greedy NN starting
// from origin should pick (0,0)→(5,0)→(10,0) (travels of 4 + 4 ≈ 8) over
// the worst-case input order (0,0)→(10,0)→(5,0) (travels 9 + 4 ≈ 13).
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(0, 0), new Vector(1, 0) },
new[] { new Vector(10, 0), new Vector(11, 0) },
new[] { new Vector(5, 0), new Vector(6, 0) },
};
var reordered = PolylinePrePass.Reorder(inputs);
Assert.Equal(3, reordered.Count);
var travelBefore = TotalPenUpTravel(inputs);
var travelAfter = TotalPenUpTravel(reordered);
Assert.True(travelAfter < travelBefore,
$"Expected reorder to reduce pen-up travel; before={travelBefore}, after={travelAfter}");
}
[Fact]
public void Reorder_ReversesPolylineIfTailIsCloser()
{
// Origin (0,0); a single polyline whose tail is much closer to origin
// than its head. Reorder should flip it.
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(10, 0), new Vector(0.5, 0) },
};
var reordered = PolylinePrePass.Reorder(inputs, allowReverse: true);
Assert.Single(reordered);
Assert.Equal(new Vector(0.5, 0), reordered[0][0]);
Assert.Equal(new Vector(10, 0), reordered[0][1]);
}
[Fact]
public void Reorder_ReverseDisabled_KeepsDirection()
{
var inputs = new List<IReadOnlyList<Vector>>
{
new[] { new Vector(10, 0), new Vector(0.5, 0) },
};
var reordered = PolylinePrePass.Reorder(inputs, allowReverse: false);
Assert.Single(reordered);
Assert.Equal(new Vector(10, 0), reordered[0][0]);
Assert.Equal(new Vector(0.5, 0), reordered[0][1]);
}
private static double TotalPenUpTravel(IEnumerable<IReadOnlyList<Vector>> polylines)
{
var total = 0.0;
Vector? last = null;
foreach (var p in polylines)
{
if (p == null || p.Count < 2) continue;
if (last.HasValue)
{
var dx = p[0].X - last.Value.X;
var dy = p[0].Y - last.Value.Y;
total += System.Math.Sqrt(dx * dx + dy * dy);
}
last = p[p.Count - 1];
}
return total;
}
}
OpenNest.Tests/IO/ChrFontTests.cs
+180
View File
@@ -0,0 +1,180 @@
using OpenNest.Geometry;
using OpenNest.IO;
namespace OpenNest.Tests.IO;
public class ChrFontTests
{
private ChrFont LoadFont()
{
var path = TestConfig.GetExistingPath("ChrFontPath");
Skip.If(path == null, "ChrFontPath not configured in test-config.json or file not found");
return ChrFont.Read(path);
}
[SkippableFact]
public void Read_ParsesFontName()
{
var font = LoadFont();
Assert.Equal("US BLOCK 1L", font.Name);
}
[SkippableFact]
public void Read_ParsesVersion()
{
var font = LoadFont();
Assert.StartsWith("C1.", font.Version);
}
[SkippableFact]
public void Read_HasAsciiGlyphs()
{
var font = LoadFont();
Assert.True(font.HasGlyph('A'));
Assert.True(font.HasGlyph('Z'));
Assert.True(font.HasGlyph('0'));
Assert.True(font.HasGlyph(' '));
}
[SkippableFact]
public void Read_HasExtendedGlyphs()
{
var font = LoadFont();
Assert.True(font.HasGlyph(0xC7)); // C-cedilla
}
[SkippableFact]
public void Glyph_L_ProducesLines()
{
var font = LoadFont();
var glyph = font.GetGlyph('L');
Assert.NotNull(glyph);
var entities = glyph.ToEntities(1.0, 0, 0);
Assert.True(entities.Count >= 2, $"Expected at least 2 entities for 'L', got {entities.Count}");
Assert.All(entities, e => Assert.Equal(EntityType.Line, e.Type));
}
[SkippableFact]
public void Glyph_O_ProducesEntities()
{
var font = LoadFont();
var glyph = font.GetGlyph('O');
Assert.NotNull(glyph);
var entities = glyph.ToEntities(1.0, 0, 0);
Assert.True(entities.Count > 0);
}
[SkippableFact]
public void RenderText_ProducesEntities()
{
var font = LoadFont();
var entities = font.RenderText("HELLO", 1.0, new Vector(0, 0));
Assert.True(entities.Count > 0, "RenderText should produce entities");
}
[SkippableFact]
public void RenderText_ScalesCorrectly()
{
var font = LoadFont();
var small = font.RenderText("A", 0.5, Vector.Zero);
var large = font.RenderText("A", 2.0, Vector.Zero);
var smallBox = small.GetBoundingBox();
var largeBox = large.GetBoundingBox();
Assert.True(largeBox.Width > smallBox.Width);
Assert.True(largeBox.Length > smallBox.Length);
}
[SkippableFact]
public void RenderText_AdvancesCursor()
{
var font = LoadFont();
var abEntities = font.RenderText("AB", 1.0, Vector.Zero);
var aEntities = font.RenderText("A", 1.0, Vector.Zero);
var abBox = abEntities.GetBoundingBox();
var aBox = aEntities.GetBoundingBox();
Assert.True(abBox.Length > aBox.Length * 1.5,
$"AB width ({abBox.Length:F1}) should be significantly wider than A width ({aBox.Length:F1})");
}
[SkippableFact]
public void RenderText_MatchesGravographReference()
{
var font = LoadFont();
var height = 5.08;
var centerX = 50.8;
var centerY = 34.925;
var entities = font.RenderText("Text", height, Vector.Zero);
var rawBox = entities.GetBoundingBox();
var shiftX = centerX - (rawBox.Left + rawBox.Right) / 2;
var shiftY = centerY - (rawBox.Top + rawBox.Bottom) / 2;
foreach (var e in entities)
e.Offset(new Vector(shiftX, shiftY));
Assert.True(entities.Count > 0, "Should produce entities for 'Text'");
var box = entities.GetBoundingBox();
var refLeft = 43.53;
var refRight = 58.07;
var refBottom = 32.39;
var refTop = 37.47;
var tolerance = 0.5;
Assert.True(System.Math.Abs(box.Left - refLeft) < tolerance,
$"Left: ours={box.Left:F2}, ref={refLeft:F2}, diff={System.Math.Abs(box.Left - refLeft):F2}");
Assert.True(System.Math.Abs(box.Right - refRight) < tolerance,
$"Right: ours={box.Right:F2}, ref={refRight:F2}, diff={System.Math.Abs(box.Right - refRight):F2}");
Assert.True(System.Math.Abs(box.Bottom - refBottom) < tolerance,
$"Bottom: ours={box.Bottom:F2}, ref={refBottom:F2}, diff={System.Math.Abs(box.Bottom - refBottom):F2}");
Assert.True(System.Math.Abs(box.Top - refTop) < tolerance,
$"Top: ours={box.Top:F2}, ref={refTop:F2}, diff={System.Math.Abs(box.Top - refTop):F2}");
var actualCapHeight = box.Top - box.Bottom;
Assert.True(System.Math.Abs(actualCapHeight - height) < 0.5,
$"Cap height: ours={actualCapHeight:F2}, expected={height:F2}");
}
[SkippableFact]
public void MeasureTextWidth_IsConsistent()
{
var font = LoadFont();
var height = 5.08;
var measuredWidth = font.MeasureTextWidth("Text", height);
var entities = font.RenderText("Text", height, Vector.Zero);
var box = entities.GetBoundingBox();
Assert.True(measuredWidth >= box.Length,
$"Measured={measuredWidth:F2} should be >= rendered={box.Length:F2}");
Assert.True(measuredWidth - box.Length < 2.0,
$"Measured={measuredWidth:F2}, rendered={box.Length:F2}, diff={measuredWidth - box.Length:F2}");
}
[SkippableFact]
public void Glyph_t_HasCurveAtBottom()
{
var font = LoadFont();
var glyph = font.GetGlyph('t');
Assert.NotNull(glyph);
var entities = glyph.ToEntities(1.0, 0, 0);
var lines = entities.Cast<Line>().ToList();
Assert.True(lines.Count >= 10, $"Expected at least 10 entities for 't', got {lines.Count}");
var curveLines = lines.Skip(1).Take(lines.Count - 3).ToList();
Assert.True(curveLines.Count >= 14, $"Expected at least 14 curve segments, got {curveLines.Count}");
var lastCurve = curveLines[^1];
Assert.True(lastCurve.EndPoint.X > curveLines[0].StartPoint.X,
$"Curve should end to the right of where it starts: start X={curveLines[0].StartPoint.X:F1}, end X={lastCurve.EndPoint.X:F1}");
}
}
OpenNest.Tests/IO/RemoveDuplicateArcsTests.cs
+96
View File
@@ -0,0 +1,96 @@
using System.Collections.Generic;
using System.Linq;
using OpenNest.Geometry;
using OpenNest.IO;
using OpenNest.Math;
using Xunit;
namespace OpenNest.Tests.IO;
public class RemoveDuplicateArcsTests
{
[Fact]
public void RemoveDuplicateArcs_RemovesArcMatchingCircle_SameLayer()
{
var layer = new Layer("0");
var circle = new Circle(10, 10, 5) { Layer = layer };
var arc = new Arc(10, 10, 5, 0, Angle.ToRadians(90)) { Layer = layer };
var line = new Line(0, 0, 10, 0) { Layer = layer };
var entities = new List<Entity> { circle, arc, line };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Equal(2, entities.Count);
Assert.Contains(circle, entities);
Assert.Contains(line, entities);
Assert.DoesNotContain(arc, entities);
}
[Fact]
public void RemoveDuplicateArcs_KeepsArcOnDifferentLayer()
{
var layer1 = new Layer("cut");
var layer2 = new Layer("etch");
var circle = new Circle(10, 10, 5) { Layer = layer1 };
var arc = new Arc(10, 10, 5, 0, Angle.ToRadians(90)) { Layer = layer2 };
var entities = new List<Entity> { circle, arc };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Equal(2, entities.Count);
Assert.Contains(arc, entities);
}
[Fact]
public void RemoveDuplicateArcs_KeepsArcWithDifferentRadius()
{
var layer = new Layer("0");
var circle = new Circle(10, 10, 5) { Layer = layer };
var arc = new Arc(10, 10, 3, 0, Angle.ToRadians(90)) { Layer = layer };
var entities = new List<Entity> { circle, arc };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Equal(2, entities.Count);
}
[Fact]
public void RemoveDuplicateArcs_KeepsArcWithDifferentCenter()
{
var layer = new Layer("0");
var circle = new Circle(10, 10, 5) { Layer = layer };
var arc = new Arc(20, 20, 5, 0, Angle.ToRadians(90)) { Layer = layer };
var entities = new List<Entity> { circle, arc };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Equal(2, entities.Count);
}
[Fact]
public void RemoveDuplicateArcs_NoCircles_NoChange()
{
var arc = new Arc(10, 10, 5, 0, Angle.ToRadians(90));
var line = new Line(0, 0, 10, 0);
var entities = new List<Entity> { arc, line };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Equal(2, entities.Count);
}
[Fact]
public void RemoveDuplicateArcs_MultipleArcsMatchOneCircle_RemovesAll()
{
var layer = new Layer("0");
var circle = new Circle(10, 10, 5) { Layer = layer };
var arc1 = new Arc(10, 10, 5, 0, Angle.ToRadians(90)) { Layer = layer };
var arc2 = new Arc(10, 10, 5, Angle.ToRadians(90), Angle.ToRadians(180)) { Layer = layer };
var entities = new List<Entity> { circle, arc1, arc2 };
CadImporter.RemoveDuplicateArcs(entities);
Assert.Single(entities);
Assert.Contains(circle, entities);
}
}
OpenNest.Tests/Math/FractionTests.cs
+46
View File
@@ -0,0 +1,46 @@
using OpenNest.Math;
using Xunit;
namespace OpenNest.Tests.Math;
public class FractionTests
{
[Theory]
[InlineData("3/8", 0.375)]
[InlineData("1 3/4", 1.75)]
[InlineData("1-3/4", 1.75)]
[InlineData("1/2", 0.5)]
public void Parse_ValidFraction_ReturnsDouble(string input, double expected)
{
var result = Fraction.Parse(input);
Assert.Equal(expected, result, 8);
}
[Theory]
[InlineData("3/8", true)]
[InlineData("abc", false)]
[InlineData("1 3/4", true)]
public void IsValid_ReturnsExpected(string input, bool expected)
{
Assert.Equal(expected, Fraction.IsValid(input));
}
[Fact]
public void TryParse_InvalidInput_ReturnsFalse()
{
var result = Fraction.TryParse("abc", out var value);
Assert.False(result);
Assert.Equal(0, value);
}
[Fact]
public void ReplaceFractionsWithDecimals_ReplacesFractionInString()
{
var result = Fraction.ReplaceFractionsWithDecimals("length is 1 3/4 inches");
Assert.Contains("1.75", result);
Assert.DoesNotContain("3/4", result);
}
}
OpenNest.Tests/OpenNest.Tests.csproj
+5
View File
@@ -14,6 +14,7 @@
<PackageReference Include="Microsoft.NET.Test.Sdk" Version="17.8.0" />
<PackageReference Include="xunit" Version="2.5.3" />
<PackageReference Include="xunit.runner.visualstudio" Version="2.5.3" />
<PackageReference Include="Xunit.SkippableFact" Version="1.4.13" />
</ItemGroup>
<ItemGroup>
@@ -27,6 +28,7 @@
<ProjectReference Include="..\OpenNest.Engine\OpenNest.Engine.csproj" />
<ProjectReference Include="..\OpenNest.IO\OpenNest.IO.csproj" />
<ProjectReference Include="..\OpenNest.Posts.Cincinnati\OpenNest.Posts.Cincinnati.csproj" />
<ProjectReference Include="..\OpenNest.Posts.GravographIS\OpenNest.Posts.GravographIS.csproj" />
<ProjectReference Include="..\OpenNest\OpenNest.csproj" />
</ItemGroup>
@@ -37,6 +39,9 @@
<Content Include="Splitting\TestData\**\*">
<CopyToOutputDirectory>PreserveNewest</CopyToOutputDirectory>
</Content>
<Content Include="test-config.json" Condition="Exists('test-config.json')">
<CopyToOutputDirectory>PreserveNewest</CopyToOutputDirectory>
</Content>
</ItemGroup>
</Project>
OpenNest.Tests/TestHelpers.cs
+29
View File
@@ -1,8 +1,37 @@
using System.Text.Json;
using OpenNest.CNC;
using OpenNest.Geometry;
namespace OpenNest.Tests;
internal static class TestConfig
{
private static readonly Lazy<Dictionary<string, string>> Config = new(() =>
{
var dir = AppContext.BaseDirectory;
for (var i = 0; i < 6; i++)
{
var path = Path.Combine(dir, "test-config.json");
if (File.Exists(path))
{
var json = File.ReadAllText(path);
return JsonSerializer.Deserialize<Dictionary<string, string>>(json) ?? new();
}
dir = Path.GetDirectoryName(dir)!;
}
return new();
});
public static string? Get(string key) =>
Config.Value.TryGetValue(key, out var val) ? val : null;
public static string? GetExistingPath(string key)
{
var path = Get(key);
return path != null && File.Exists(path) ? path : null;
}
}
internal static class TestHelpers
{
public static Part MakePartAt(double x, double y, double size = 1)
OpenNest.Training/Program.cs
+4 -2
View File
@@ -89,8 +89,10 @@ int RunDataCollection(string dir, string dbPath, string saveDir, double s, strin
new Size(48, 24), new Size(120, 10)
};
var dxfFiles = Directory.GetFiles(dir, "*.dxf", SearchOption.AllDirectories);
Console.WriteLine($"Found {dxfFiles.Length} DXF files");
var dxfFiles = Directory.GetFiles(dir, "*.dxf", SearchOption.AllDirectories)
.Concat(Directory.GetFiles(dir, "*.dwg", SearchOption.AllDirectories))
.ToArray();
Console.WriteLine($"Found {dxfFiles.Length} CAD files");
var resolvedDb = dbPath.EndsWith(".db", StringComparison.OrdinalIgnoreCase) ? dbPath : dbPath + ".db";
Console.WriteLine($"Database: {Path.GetFullPath(resolvedDb)}");
Console.WriteLine($"Sheet sizes: {sheetSuite.Length} configurations");
OpenNest.sln
+15
View File
@@ -30,6 +30,8 @@ Project("{2150E333-8FDC-42A3-9474-1A3956D46DE8}") = "PostProcessors", "PostProce
EndProject
Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "OpenNest.Posts.Cincinnati", "OpenNest.Posts.Cincinnati\OpenNest.Posts.Cincinnati.csproj", "{FB1B2EB2-9D80-4499-BA93-B4E2F295A532}"
EndProject
Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "OpenNest.Posts.GravographIS", "OpenNest.Posts.GravographIS\OpenNest.Posts.GravographIS.csproj", "{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}"
EndProject
Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "OpenNest.Data", "OpenNest.Data\OpenNest.Data.csproj", "{A0B4B48E-1DF0-4DD3-B42C-B9B7779EA8B0}"
EndProject
Global
@@ -186,12 +188,25 @@ Global
{A0B4B48E-1DF0-4DD3-B42C-B9B7779EA8B0}.Release|x64.Build.0 = Release|Any CPU
{A0B4B48E-1DF0-4DD3-B42C-B9B7779EA8B0}.Release|x86.ActiveCfg = Release|Any CPU
{A0B4B48E-1DF0-4DD3-B42C-B9B7779EA8B0}.Release|x86.Build.0 = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|Any CPU.ActiveCfg = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|Any CPU.Build.0 = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|x64.ActiveCfg = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|x64.Build.0 = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|x86.ActiveCfg = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Debug|x86.Build.0 = Debug|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|Any CPU.ActiveCfg = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|Any CPU.Build.0 = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|x64.ActiveCfg = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|x64.Build.0 = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|x86.ActiveCfg = Release|Any CPU
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40}.Release|x86.Build.0 = Release|Any CPU
EndGlobalSection
GlobalSection(SolutionProperties) = preSolution
HideSolutionNode = FALSE
EndGlobalSection
GlobalSection(NestedProjects) = preSolution
{FB1B2EB2-9D80-4499-BA93-B4E2F295A532} = {4052CFAC-1F12-48BE-872D-F503C3B65D7E}
{3A6B8E7E-9B5F-4D2C-8AE3-2C9F5E3D1A40} = {4052CFAC-1F12-48BE-872D-F503C3B65D7E}
EndGlobalSection
GlobalSection(ExtensibilityGlobals) = postSolution
SolutionGuid = {86FE17B3-F764-40AE-BCAA-F26B470CA05C}
OpenNest/Actions/ActionCutOff.cs
-18
View File
@@ -16,15 +16,11 @@ namespace OpenNest.Actions
private CutOffSettings settings;
private CutOffAxis lockedAxis = CutOffAxis.Vertical;
private Dictionary<Part, Entity> perimeterCache;
private readonly Timer debounceTimer;
private bool regeneratePending;
public ActionCutOff(PlateView plateView)
: base(plateView)
{
settings = plateView.CutOffSettings;
debounceTimer = new Timer { Interval = 16 };
debounceTimer.Tick += OnDebounce;
ConnectEvents();
}
@@ -40,8 +36,6 @@ namespace OpenNest.Actions
public override void DisconnectEvents()
{
debounceTimer.Stop();
debounceTimer.Dispose();
plateView.MouseMove -= OnMouseMove;
plateView.MouseDown -= OnMouseDown;
plateView.KeyDown -= OnKeyDown;
@@ -58,18 +52,6 @@ namespace OpenNest.Actions
private void OnMouseMove(object sender, MouseEventArgs e)
{
regeneratePending = true;
debounceTimer.Start();
}
private void OnDebounce(object sender, System.EventArgs e)
{
debounceTimer.Stop();
if (!regeneratePending)
return;
regeneratePending = false;
var pt = plateView.CurrentPoint;
previewCutOff = new CutOff(pt, lockedAxis);
previewCutOff.Regenerate(plateView.Plate, settings, perimeterCache);
OpenNest/ArchUnits.cs
+1 -1
View File
@@ -1,4 +1,4 @@
using OpenNest.IO.Bom;
using OpenNest.Math;
using System;
using System.Drawing;
using System.Text;
OpenNest/Controls/CadText.cs
+16
View File
@@ -0,0 +1,16 @@
using System.Drawing;
using OpenNest.Geometry;
namespace OpenNest.Controls
{
public class CadText
{
public Vector Position { get; set; }
public string Value { get; set; }
public double Height { get; set; }
public double Rotation { get; set; }
public string LayerName { get; set; }
public StringAlignment HAlign { get; set; }
public StringAlignment VAlign { get; set; }
}
}
OpenNest/Controls/EntityView.cs
+76
View File
@@ -29,15 +29,18 @@ namespace OpenNest.Controls
public List<Entity> SimplifierToleranceRight { get; set; }
public List<Entity> OriginalEntities { get; set; }
public bool ShowEntityLabels { get; set; }
public List<CadText> Texts { get; set; } = new List<CadText>();
private readonly Pen gridPen = new Pen(Color.FromArgb(70, 70, 70));
private readonly Dictionary<int, Pen> penCache = new Dictionary<int, Pen>();
private readonly Font labelFont = new Font("Segoe UI", 7f);
private readonly SolidBrush labelBrush = new SolidBrush(Color.FromArgb(220, 255, 255, 200));
private readonly SolidBrush labelBackBrush = new SolidBrush(Color.FromArgb(33, 40, 48));
private readonly SolidBrush textBrush = new SolidBrush(Color.FromArgb(180, 200, 200, 200));
public event EventHandler<Line> LinePicked;
public event EventHandler PickCancelled;
public event EventHandler<CadText> TextConvertRequested;
private bool isPickingBendLine;
public bool IsPickingBendLine
@@ -74,6 +77,13 @@ namespace OpenNest.Controls
if (line != null)
LinePicked?.Invoke(this, line);
}
if (e.Button == MouseButtons.Right)
{
var text = HitTestText(e.Location);
if (text != null)
ShowTextContextMenu(text, e.Location);
}
}
protected override void OnPaint(PaintEventArgs e)
@@ -116,6 +126,8 @@ namespace OpenNest.Controls
DrawEntity(e.Graphics, entity, pen);
}
DrawTexts(e.Graphics);
if (ShowEntityLabels)
DrawEntityLabels(e.Graphics);
@@ -324,6 +336,41 @@ namespace OpenNest.Controls
return bestLine;
}
private CadText HitTestText(Point controlPoint)
{
if (Texts == null || Texts.Count == 0)
return null;
var worldPoint = PointControlToWorld(controlPoint);
var tolerance = LengthGuiToWorld(8);
foreach (var text in Texts)
{
if (string.IsNullOrEmpty(text.Value))
continue;
var estimatedWidth = text.Height * text.Value.Length * 0.6;
var minX = text.Position.X - tolerance;
var maxX = text.Position.X + estimatedWidth + tolerance;
var minY = text.Position.Y - tolerance;
var maxY = text.Position.Y + text.Height + tolerance;
if (worldPoint.X >= minX && worldPoint.X <= maxX &&
worldPoint.Y >= minY && worldPoint.Y <= maxY)
return text;
}
return null;
}
private void ShowTextContextMenu(CadText text, Point location)
{
var menu = new ContextMenuStrip();
var item = menu.Items.Add($"Convert \"{text.Value}\" to Geometry");
item.Click += (s, e) => TextConvertRequested?.Invoke(this, text);
menu.Show(this, location);
}
private void DrawEntityLabels(Graphics g)
{
for (var i = 0; i < Entities.Count; i++)
@@ -408,6 +455,7 @@ namespace OpenNest.Controls
labelFont.Dispose();
labelBrush.Dispose();
labelBackBrush.Dispose();
textBrush.Dispose();
}
base.Dispose(disposing);
}
@@ -474,6 +522,34 @@ namespace OpenNest.Controls
diameter);
}
private void DrawTexts(Graphics g)
{
if (Texts == null || Texts.Count == 0)
return;
using var sf = new StringFormat();
foreach (var text in Texts)
{
var pos = PointWorldToGraph(text.Position);
var fontSize = LengthWorldToGui(text.Height);
if (fontSize < 2f) continue;
var state = g.Save();
g.TranslateTransform(pos.X, pos.Y);
if (text.Rotation != 0)
g.RotateTransform((float)OpenNest.Math.Angle.ToDegrees(text.Rotation));
sf.Alignment = text.HAlign;
sf.LineAlignment = text.VAlign;
using var font = new Font("Segoe UI", fontSize, GraphicsUnit.Pixel);
g.DrawString(text.Value, font, textBrush, 0, 0, sf);
g.Restore(state);
}
}
private void DrawPoint(Graphics g, Vector pt, Pen pen)
{
var pt1 = PointWorldToGraph(pt);
OpenNest/Controls/FileListControl.cs
+1
View File
@@ -22,6 +22,7 @@ namespace OpenNest.Controls
public HashSet<Guid> SuppressedEntityIds { get; set; }
public Box Bounds { get; set; }
public int EntityCount { get; set; }
public List<CadText> Texts { get; set; } = new();
}
public class FileListControl : Control
OpenNest/Forms/BestFitViewerForm.cs
+4 -2
View File
@@ -45,6 +45,7 @@ namespace OpenNest.Forms
public BestFitResult SelectedResult { get; private set; }
public Drawing SelectedDrawing => activeDrawing;
public List<Part> SelectedParts { get; private set; }
public BestFitViewerForm(DrawingCollection drawings, Plate plate, Units units = Units.Inches)
{
@@ -318,12 +319,12 @@ namespace OpenNest.Forms
var cell = new BestFitCell(colorScheme);
cell.PartColor = partColor;
cell.Dock = DockStyle.Fill;
var parts = result.BuildCanonicalParts();
cell.Plate.Size = new Geometry.Size(
result.BoundingHeight,
result.BoundingWidth);
var parts = result.BuildParts(drawing);
foreach (var part in parts)
cell.Plate.Parts.Add(part);
@@ -332,6 +333,7 @@ namespace OpenNest.Forms
cell.DoubleClick += (sender, e) =>
{
SelectedResult = result;
SelectedParts = result.BuildSourceParts(drawing);
DialogResult = DialogResult.OK;
Close();
};
OpenNest/Forms/BomImportForm.cs
+2 -1
View File
@@ -165,7 +165,8 @@ namespace OpenNest.Forms
else
{
var lookupName = item.FileName;
if (lookupName.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase))
if (lookupName.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase)
|| lookupName.EndsWith(".dwg", StringComparison.OrdinalIgnoreCase))
lookupName = Path.GetFileNameWithoutExtension(lookupName);
if (matchedPaths.TryGetValue(lookupName, out var dxfPath))
OpenNest/Forms/CadConverterForm.cs
+219 -2
View File
@@ -45,6 +45,7 @@ namespace OpenNest.Forms
filterPanel.AddBendLineClicked += OnAddBendLineClicked;
entityView1.LinePicked += OnLinePicked;
entityView1.PickCancelled += OnPickCancelled;
entityView1.TextConvertRequested += OnTextConvertRequested;
btnSplit.Click += OnSplitClicked;
numQuantity.ValueChanged += OnQuantityChanged;
txtCustomer.TextChanged += OnCustomerChanged;
@@ -92,7 +93,8 @@ namespace OpenNest.Forms
Customer = string.Empty,
Bends = result.Bends,
Bounds = result.Bounds,
EntityCount = result.Entities.Count
EntityCount = result.Entities.Count,
Texts = ExtractTexts(result.Document),
};
if (InvokeRequired)
@@ -152,6 +154,7 @@ namespace OpenNest.Forms
entityView1.Entities.Clear();
entityView1.Entities.AddRange(item.Entities);
entityView1.Bends = item.Bends ?? new List<Bend>();
entityView1.Texts = item.Texts ?? new List<CadText>();
item.Entities.ForEach(e => e.IsVisible = true);
if (item.Entities.Any(e => e.Layer != null))
@@ -461,6 +464,115 @@ namespace OpenNest.Forms
filterPanel.SetPickMode(false);
}
private void OnTextConvertRequested(object sender, Controls.CadText text)
{
var item = CurrentItem;
if (item == null) return;
var font = LoadChrFont();
if (font == null) return;
var layer = new Geometry.Layer("ENGRAVE")
{
Color = System.Drawing.Color.Cyan,
IsVisible = true,
};
var entities = font.RenderText(text.Value, text.Height, Geometry.Vector.Zero, layer);
if (entities.Count > 0)
{
var box = entities.GetBoundingBox();
var shiftX = text.HAlign switch
{
System.Drawing.StringAlignment.Center => text.Position.X - (box.Left + box.Right) / 2,
System.Drawing.StringAlignment.Far => text.Position.X - box.Right,
_ => text.Position.X - box.Left,
};
var shiftY = text.VAlign switch
{
System.Drawing.StringAlignment.Center => text.Position.Y - (box.Top + box.Bottom) / 2,
System.Drawing.StringAlignment.Near => text.Position.Y - box.Top,
_ => text.Position.Y - box.Bottom,
};
var shift = new Geometry.Vector(shiftX, shiftY);
foreach (var e in entities)
e.Offset(shift);
}
if (entities.Count == 0)
{
MessageBox.Show($"No geometry produced for \"{text.Value}\".", "Convert Text",
MessageBoxButtons.OK, MessageBoxIcon.Information);
return;
}
item.Entities.AddRange(entities);
item.Texts.Remove(text);
item.EntityCount = item.Entities.Count;
item.Bounds = item.Entities.GetBoundingBox();
entityView1.Entities.Clear();
entityView1.Entities.AddRange(item.Entities);
entityView1.Texts = item.Texts;
filterPanel.LoadItem(item.Entities, item.Bends);
entityView1.Invalidate();
staleProgram = true;
lblEntityCount.Text = $"{item.EntityCount} entities";
}
private ChrFont cachedChrFont;
private string cachedChrFontPath;
private ChrFont LoadChrFont()
{
if (cachedChrFont != null)
return cachedChrFont;
// Look for .CHR files next to the app, then prompt
var appDir = System.IO.Path.GetDirectoryName(Application.ExecutablePath);
var candidates = Directory.GetFiles(appDir, "*.CHR", SearchOption.TopDirectoryOnly);
string fontPath;
if (candidates.Length == 1)
{
fontPath = candidates[0];
}
else if (candidates.Length > 1)
{
fontPath = PromptForChrFile(appDir);
}
else
{
fontPath = PromptForChrFile(null);
}
if (fontPath == null)
return null;
try
{
cachedChrFont = ChrFont.Read(fontPath);
cachedChrFontPath = fontPath;
return cachedChrFont;
}
catch (Exception ex)
{
MessageBox.Show($"Error loading font: {ex.Message}", "Font Error",
MessageBoxButtons.OK, MessageBoxIcon.Error);
return null;
}
}
private static string PromptForChrFile(string initialDir)
{
using var dlg = new OpenFileDialog
{
Title = "Select Engraving Font (.CHR)",
Filter = "Gravograph Font (*.CHR)|*.CHR",
InitialDirectory = initialDir ?? "",
};
return dlg.ShowDialog() == DialogResult.OK ? dlg.FileName : null;
}
private void OnDragEnter(object sender, DragEventArgs e)
{
if (e.Data.GetDataPresent(DataFormats.FileDrop))
@@ -473,7 +585,8 @@ namespace OpenNest.Forms
{
var files = (string[])e.Data.GetData(DataFormats.FileDrop);
var dxfFiles = files.Where(f =>
f.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase)).ToArray();
f.EndsWith(".dxf", StringComparison.OrdinalIgnoreCase) ||
f.EndsWith(".dwg", StringComparison.OrdinalIgnoreCase)).ToArray();
if (dxfFiles.Length > 0)
AddFiles(dxfFiles);
}
@@ -803,6 +916,110 @@ namespace OpenNest.Forms
#endregion
private static List<CadText> ExtractTexts(ACadSharp.CadDocument doc)
{
var texts = new List<CadText>();
if (doc == null) return texts;
foreach (var entity in doc.Entities)
{
switch (entity)
{
case ACadSharp.Entities.MText mtext:
var (mh, mv) = MapAttachmentPoint(mtext.AttachmentPoint);
texts.Add(new CadText
{
Position = new Vector(mtext.InsertPoint.X, mtext.InsertPoint.Y),
Value = ReplaceControlCodes(StripMTextFormatting(mtext.Value)),
Height = mtext.Height,
Rotation = mtext.Rotation,
LayerName = mtext.Layer?.Name,
HAlign = mh,
VAlign = mv,
});
break;
case ACadSharp.Entities.TextEntity text:
var useAlignment = text.HorizontalAlignment != 0
|| text.VerticalAlignment != 0;
var pt = useAlignment ? text.AlignmentPoint : text.InsertPoint;
var ha = text.HorizontalAlignment switch
{
ACadSharp.Entities.TextHorizontalAlignment.Center => System.Drawing.StringAlignment.Center,
ACadSharp.Entities.TextHorizontalAlignment.Right => System.Drawing.StringAlignment.Far,
_ => System.Drawing.StringAlignment.Near,
};
var va = text.VerticalAlignment switch
{
ACadSharp.Entities.TextVerticalAlignmentType.Middle => System.Drawing.StringAlignment.Center,
ACadSharp.Entities.TextVerticalAlignmentType.Top => System.Drawing.StringAlignment.Near,
ACadSharp.Entities.TextVerticalAlignmentType.Bottom => System.Drawing.StringAlignment.Far,
_ => System.Drawing.StringAlignment.Far,
};
texts.Add(new CadText
{
Position = new Vector(pt.X, pt.Y),
Value = ReplaceControlCodes(text.Value),
Height = text.Height,
Rotation = text.Rotation,
LayerName = text.Layer?.Name,
HAlign = ha,
VAlign = va,
});
break;
}
}
return texts;
}
private static (System.Drawing.StringAlignment h, System.Drawing.StringAlignment v) MapAttachmentPoint(
ACadSharp.Entities.AttachmentPointType apt)
{
var h = apt switch
{
ACadSharp.Entities.AttachmentPointType.TopCenter
or ACadSharp.Entities.AttachmentPointType.MiddleCenter
or ACadSharp.Entities.AttachmentPointType.BottomCenter => System.Drawing.StringAlignment.Center,
ACadSharp.Entities.AttachmentPointType.TopRight
or ACadSharp.Entities.AttachmentPointType.MiddleRight
or ACadSharp.Entities.AttachmentPointType.BottomRight => System.Drawing.StringAlignment.Far,
_ => System.Drawing.StringAlignment.Near,
};
var v = apt switch
{
ACadSharp.Entities.AttachmentPointType.MiddleLeft
or ACadSharp.Entities.AttachmentPointType.MiddleCenter
or ACadSharp.Entities.AttachmentPointType.MiddleRight => System.Drawing.StringAlignment.Center,
ACadSharp.Entities.AttachmentPointType.BottomLeft
or ACadSharp.Entities.AttachmentPointType.BottomCenter
or ACadSharp.Entities.AttachmentPointType.BottomRight => System.Drawing.StringAlignment.Far,
_ => System.Drawing.StringAlignment.Near,
};
return (h, v);
}
private static string StripMTextFormatting(string text)
{
if (string.IsNullOrEmpty(text)) return text;
var result = System.Text.RegularExpressions.Regex.Replace(text, @"\\[A-Za-z][^;]*;", "");
result = result.Replace("{", "").Replace("}", "");
return result.Trim();
}
private static string ReplaceControlCodes(string text)
{
if (string.IsNullOrEmpty(text)) return text;
return text
.Replace("%%p", "±")
.Replace("%%P", "±")
.Replace("%%d", "°")
.Replace("%%D", "°")
.Replace("%%c", "⌀")
.Replace("%%C", "⌀")
.Replace("%%%", "%");
}
private void filterPanel_Paint(object sender, PaintEventArgs e)
{
OpenNest/Forms/EditNestForm.cs
+1 -2
View File
@@ -329,7 +329,7 @@ namespace OpenNest.Forms
{
var dlg = new OpenFileDialog();
dlg.Multiselect = true;
dlg.Filter = "DXF Files (*.dxf) | *.dxf";
dlg.Filter = "CAD Files (*.dxf;*.dwg)|*.dxf;*.dwg|DXF Files (*.dxf)|*.dxf|DWG Files (*.dwg)|*.dwg";
if (dlg.ShowDialog() != DialogResult.OK)
return;
@@ -346,7 +346,6 @@ namespace OpenNest.Forms
drawings.ForEach(d => Nest.Drawings.Add(d));
UpdateDrawingList();
tabControl1.SelectedIndex = 1;
}
public bool Export()
OpenNest/Forms/MainForm.cs
+2 -1
View File
@@ -686,7 +686,8 @@ namespace OpenNest.Forms
{
if (form.ShowDialog(this) == DialogResult.OK && form.SelectedResult != null)
{
var parts = form.SelectedResult.BuildParts(form.SelectedDrawing);
var parts = form.SelectedParts
?? form.SelectedResult.BuildSourceParts(form.SelectedDrawing);
activeForm.PlateView.SetAction(typeof(ActionClone), parts);
}
}
OpenNest/GraphicsHelper.cs
+25 -5
View File
@@ -138,9 +138,20 @@ namespace OpenNest
break;
case CodeType.RapidMove:
cutPath.StartFigure();
leadPath.StartFigure();
AddLine(cutPath, (RapidMove)code, mode, ref curpos);
{
var rapid = (RapidMove)code;
var endpt = rapid.EndPoint;
if (mode == Mode.Incremental)
endpt += curpos;
var dx = endpt.X - curpos.X;
var dy = endpt.Y - curpos.Y;
if (dx * dx + dy * dy > 0.001 * 0.001)
{
cutPath.StartFigure();
leadPath.StartFigure();
}
curpos = endpt;
}
break;
case CodeType.SubProgramCall:
@@ -300,8 +311,17 @@ namespace OpenNest
break;
case CodeType.RapidMove:
Flush();
AddLine(path, (RapidMove)code, mode, ref curpos);
{
var rapid = (RapidMove)code;
var endpt = rapid.EndPoint;
if (mode == Mode.Incremental)
endpt += curpos;
var dx = endpt.X - curpos.X;
var dy = endpt.Y - curpos.Y;
if (dx * dx + dy * dy > 0.001 * 0.001)
Flush();
curpos = endpt;
}
break;
case CodeType.SubProgramCall:
tools/StreamGravographJob/Program.cs
+266
View File
@@ -0,0 +1,266 @@
using System;
using System.ComponentModel;
using System.Diagnostics;
using System.IO;
using System.IO.Ports;
using System.Runtime.InteropServices;
using System.Threading;
using Microsoft.Win32.SafeHandles;
if (args.Length < 2)
{
Console.Error.WriteLine("Usage:");
Console.Error.WriteLine(" StreamGravographJob <file.prn> <COMx> [chunk=256] [flow=rtscts|xonxoff|none]");
Console.Error.WriteLine(" StreamGravographJob --gen <name> <outfile.prn> # name: testA | testB | miniB | miniSquare");
Console.Error.WriteLine(" StreamGravographJob --inspect-nest <file.nest>");
Console.Error.WriteLine(" StreamGravographJob --from-nest <file.nest> <outfile.prn>");
return 2;
}
// Inspect a .nest file: extract polylines via the post-processor pipeline and
// report dimensions / bounding box / pen-up travel — no bytes written.
if (args[0] == "--inspect-nest")
{
if (args.Length < 2) { Console.Error.WriteLine("--inspect-nest requires <file.nest>"); return 2; }
var nestPath = args[1];
if (!File.Exists(nestPath)) { Console.Error.WriteLine($"Not found: {nestPath}"); return 3; }
using var fs = new FileStream(nestPath, FileMode.Open, FileAccess.Read);
var reader = new OpenNest.IO.NestReader(fs);
var nest = reader.Read();
Console.WriteLine($"Nest: {nest.Name}");
Console.WriteLine($"Units: {nest.Units}");
Console.WriteLine($"Plates: {nest.Plates.Count}");
var plateIdx = 0;
foreach (var plate in nest.Plates)
{
plateIdx++;
Console.WriteLine($" Plate {plateIdx}: size={plate.Size.Length} x {plate.Size.Width}, quadrant={plate.Quadrant}, parts={plate.Parts.Count}");
}
var polylines = new OpenNest.Posts.GravographIS.NestPolylineExtractor().Extract(nest);
if (polylines.Count == 0)
{
Console.WriteLine("No polylines extracted.");
return 0;
}
double minX = double.PositiveInfinity, minY = double.PositiveInfinity;
double maxX = double.NegativeInfinity, maxY = double.NegativeInfinity;
int totalPts = 0;
foreach (var p in polylines)
{
foreach (var v in p)
{
if (v.X < minX) minX = v.X;
if (v.X > maxX) maxX = v.X;
if (v.Y < minY) minY = v.Y;
if (v.Y > maxY) maxY = v.Y;
}
totalPts += p.Count;
}
Console.WriteLine($"Polylines: {polylines.Count}, total points: {totalPts}");
Console.WriteLine($"Bounding box (inches): X ∈ [{minX:F3}, {maxX:F3}] Y ∈ [{minY:F3}, {maxY:F3}]");
Console.WriteLine($"Extents: {maxX - minX:F3}\" × {maxY - minY:F3}\"");
// After running the pre-pass (stitch + reorder from origin) — what the writer will actually consume.
var prepared = OpenNest.Posts.GravographIS.PolylinePrePass.Prepare(polylines);
Console.WriteLine($"After stitch+reorder: {prepared.Count} polylines");
Console.WriteLine();
Console.WriteLine("--- Vertex dump (prepared, upper-left origin, with segment deltas) ---");
var pi = 0;
foreach (var poly in prepared)
{
pi++;
Console.WriteLine($"Polyline {pi}: {poly.Count} points");
var cumX = 0.0; var cumY = 0.0;
for (var i = 0; i < poly.Count; i++)
{
var v = poly[i];
if (i == 0)
{
Console.WriteLine($" [{i}] ({v.X,7:F3}, {v.Y,7:F3}) first DR travel from upper-left origin=({v.X,+7:F3}, {v.Y,+7:F3})");
}
else
{
var dx = v.X - poly[i - 1].X;
var dy = v.Y - poly[i - 1].Y;
cumX += dx;
cumY += dy;
Console.WriteLine($" [{i}] ({v.X,7:F3}, {v.Y,7:F3}) Δ=({dx,+7:F3}, {dy,+7:F3}) cum from origin=({cumX,+7:F3}, {cumY,+7:F3})");
}
}
}
return 0;
}
// Convert a .nest file to a .prn job via the full post-processor pipeline.
if (args[0] == "--from-nest")
{
if (args.Length < 3) { Console.Error.WriteLine("--from-nest requires <file.nest> <outfile.prn>"); return 2; }
var nestPath = args[1];
var outFile = args[2];
if (!File.Exists(nestPath)) { Console.Error.WriteLine($"Not found: {nestPath}"); return 3; }
using var fs = new FileStream(nestPath, FileMode.Open, FileAccess.Read);
var nest = new OpenNest.IO.NestReader(fs).Read();
var post = new OpenNest.Posts.GravographIS.GravographISPostProcessor();
post.Post(nest, outFile);
var size = new FileInfo(outFile).Length;
Console.WriteLine($"Wrote {size} bytes → {outFile}");
return 0;
}
// Generator mode: run the live writer to produce a captured-test file on disk.
if (args[0] == "--gen")
{
if (args.Length < 3) { Console.Error.WriteLine("--gen requires <name> <outfile>"); return 2; }
var preset = args[1];
var outFile = args[2];
var polylines = preset.ToLowerInvariant() switch
{
"testa" => new System.Collections.Generic.List<System.Collections.Generic.IReadOnlyList<OpenNest.Geometry.Vector>>
{
new[] { new OpenNest.Geometry.Vector(1, 1), new OpenNest.Geometry.Vector(1, 3) },
},
"testb" => new System.Collections.Generic.List<System.Collections.Generic.IReadOnlyList<OpenNest.Geometry.Vector>>
{
new[] { new OpenNest.Geometry.Vector(1, 1), new OpenNest.Geometry.Vector(1, 3) },
new[] { new OpenNest.Geometry.Vector(4, 1), new OpenNest.Geometry.Vector(4, 3) },
new[] { new OpenNest.Geometry.Vector(4, 5), new OpenNest.Geometry.Vector(4, 7) },
new[] { new OpenNest.Geometry.Vector(1, 5), new OpenNest.Geometry.Vector(1, 7) },
},
// Same 4-polyline topology as testB (vertical lines + diagonal PU travels between them),
// shrunk to a 0.5" × 1.5" footprint so it stays right near the operator-set work origin.
"minib" => new System.Collections.Generic.List<System.Collections.Generic.IReadOnlyList<OpenNest.Geometry.Vector>>
{
new[] { new OpenNest.Geometry.Vector(0, 0), new OpenNest.Geometry.Vector(0, 0.5) },
new[] { new OpenNest.Geometry.Vector(0.5, 0), new OpenNest.Geometry.Vector(0.5, 0.5) },
new[] { new OpenNest.Geometry.Vector(0.5, 1), new OpenNest.Geometry.Vector(0.5, 1.5) },
new[] { new OpenNest.Geometry.Vector(0, 1), new OpenNest.Geometry.Vector(0, 1.5) },
},
// Closed 0.5" square as a SINGLE polyline of 5 points → 4-segment PD packet.
// Exercises multi-segment PD (one FF FD 50 44 00 00 followed by 4 records,
// no intermediate lifts) and bi-directional motion (X+, Y+, X, Y).
// Returns the head to its starting point so no manual jog needed after.
"minisquare" => new System.Collections.Generic.List<System.Collections.Generic.IReadOnlyList<OpenNest.Geometry.Vector>>
{
new[]
{
new OpenNest.Geometry.Vector(0, 0),
new OpenNest.Geometry.Vector(0.5, 0),
new OpenNest.Geometry.Vector(0.5, 0.5),
new OpenNest.Geometry.Vector(0, 0.5),
new OpenNest.Geometry.Vector(0, 0),
},
},
_ => throw new ArgumentException($"Unknown preset '{preset}' (try testA, testB, miniB, or miniSquare)."),
};
using var outFs = new FileStream(outFile, FileMode.Create, FileAccess.Write);
new OpenNest.Posts.GravographIS.GravographISWriter().Write(polylines, outFs);
Console.WriteLine($"Wrote {new FileInfo(outFile).Length} bytes via live writer → {outFile}");
return 0;
}
var file = args[0];
var portName = args[1];
var chunk = args.Length > 2 ? int.Parse(args[2]) : 256;
var flowArg = args.Length > 3 ? args[3] : "rtscts";
var handshake = flowArg.ToLowerInvariant() switch
{
"rtscts" or "rts" or "cts" => Handshake.RequestToSend,
"xonxoff" or "xon" or "xoff" => Handshake.XOnXOff,
"none" => Handshake.None,
_ => throw new ArgumentException($"Unknown flow control '{flowArg}'."),
};
if (!File.Exists(file))
{
Console.Error.WriteLine($"File not found: {file}");
return 3;
}
var bytes = File.ReadAllBytes(file);
Console.WriteLine($"File: {file}");
Console.WriteLine($"Size: {bytes.Length} bytes");
Console.WriteLine($"Header: {BitConverter.ToString(bytes, 0, Math.Min(7, bytes.Length)).Replace('-', ' ')}");
var ports = SerialPort.GetPortNames();
Array.Sort(ports);
Console.WriteLine($"Available COM ports: {string.Join(", ", ports)}");
if (Array.IndexOf(ports, portName) < 0)
{
Console.Error.WriteLine($"{portName} not in available ports.");
return 4;
}
using var port = new SerialPort(portName, 9600, Parity.None, 8, StopBits.One)
{
Handshake = handshake,
WriteTimeout = 30000,
ReadTimeout = 30000,
WriteBufferSize = 4096,
DtrEnable = true,
};
// Probe with the same CreateFile flags SerialStream uses, in this same process,
// so we can tell SerialStream-specific failures apart from process-level access denials.
{
const uint GENERIC_RW = 0x80000000u | 0x40000000u;
const uint OPEN_EXISTING = 3;
const uint FILE_FLAG_OVERLAPPED = 0x40000000u;
var devName = @"\\.\" + portName;
var handle = NativeMethods.CreateFileW(devName, GENERIC_RW, 0, IntPtr.Zero, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, IntPtr.Zero);
var err = Marshal.GetLastWin32Error();
if (handle.IsInvalid)
{
Console.WriteLine($"CreateFile(\"{devName}\", overlapped, exclusive) FAILED: win32={err} ({new Win32Exception(err).Message})");
}
else
{
Console.WriteLine($"CreateFile(\"{devName}\", overlapped, exclusive) OK — closing.");
handle.Close();
}
}
Console.WriteLine($"Opening {portName} 9600 8N1 handshake={handshake}...");
port.Open();
Console.WriteLine("Opened.");
var sw = Stopwatch.StartNew();
try
{
for (var i = 0; i < bytes.Length; i += chunk)
{
var n = Math.Min(chunk, bytes.Length - i);
port.Write(bytes, i, n);
}
try { port.BaseStream.Flush(); } catch { /* advisory */ }
Thread.Sleep(500);
}
finally
{
sw.Stop();
port.Close();
}
Console.WriteLine($"Sent {bytes.Length} bytes in {sw.ElapsedMilliseconds} ms. Port closed.");
return 0;
internal static class NativeMethods
{
[DllImport("kernel32.dll", SetLastError = true, CharSet = CharSet.Unicode, EntryPoint = "CreateFileW")]
internal static extern SafeFileHandle CreateFileW(
string lpFileName,
uint dwDesiredAccess,
uint dwShareMode,
IntPtr lpSecurityAttributes,
uint dwCreationDisposition,
uint dwFlagsAndAttributes,
IntPtr hTemplateFile);
}
tools/StreamGravographJob/StreamGravographJob.csproj
+14
View File
@@ -0,0 +1,14 @@
<Project Sdk="Microsoft.NET.Sdk">
<PropertyGroup>
<OutputType>Exe</OutputType>
<TargetFramework>net8.0-windows</TargetFramework>
<Nullable>enable</Nullable>
<ImplicitUsings>enable</ImplicitUsings>
<RootNamespace>OpenNest.Tools.StreamGravographJob</RootNamespace>
</PropertyGroup>
<ItemGroup>
<PackageReference Include="System.IO.Ports" Version="8.0.0" />
<ProjectReference Include="..\..\OpenNest.Posts.GravographIS\OpenNest.Posts.GravographIS.csproj" />
<ProjectReference Include="..\..\OpenNest.IO\OpenNest.IO.csproj" />
</ItemGroup>
</Project>