The Mighty Shiz

Sunday, 10 May 2026

Testing the lathe cycles

After some distinct buggerage with the lathe cycle graphics, let's do some actual testing of the cycles on a live machine. Of course, I can start by checking what commands the macros are sending to the machine controller but ultimately I need to see what happens when I run the machine.

The more conventional "turning" and "facing" operations are prett straightforward and although I can't pretend I've done any seriously thorough testing at this stage, they seem to work largely as expected. I'm sure I can finesse the instructions a bit but initially I need to know if the toolpaths are almost sensible looking.

The "chamfer" toolpaths don't seem to be working quite as expected. There are 3 "corner types" on offer, depending on which of the3 possible chamfers you want to machine.

External chamfer (Front Outside"):

Here's the dummy setup I'm planning to run. It's air cutting at this stage but the tool starting position and chamfer parameters are hopefully good starting points.

And here's the displayed toolpath trace ie where the tool actually went, as reported in the backplot panel within the main screen:

Ooof. What's happening here?

The backplot trace is all over the shop. This is due to the graphics freezing up, then waking up again and jumping to the current position. So parts of the toolpath are missing, with rogue traces where the jumps happened. The machine itself was working as expecting, so this seems to be a graphics problem.
The starting coordinates are inappropriate. The macros start by acquiring and storing the current machine coordinates under the active WCS. This position is then used as the retract position (G30 perhaps?), so ideally you'd get them right. In my case, I seem to have positioned the tool miles away from the stock. It's a learning process, I guess.
But more worryingly, the toolpath seems to be making rapid moves within the stock. For an external "Front Outside" chamfer, the tool should be clearing the work to the right and bottom of the screen for a front toolholder. The cause is actually quite visible - for this type of chamfer, the "chamfer distance" argument (5mm here) should immediately follow the feed argument (0.15mm) - check out the orange "call" script at the bottom of the setup panel). So, by sending the distance parameter as the 8th argument rather than the 7th argument, the GUI is accidentally specifying a "rear outside" chamfer. This turned out to be fairly simple to fix.

Here's the chamfer.ngc file:

chamfer
o<chamfer> sub

o<backup_status> call

#<chamfer_x> = #1
#<chamfer_ss> = #2
#<chamfer_doc> = #3 ;depth of cut
#<chamfer_z> = #4
#<chamfer_tool> = #5
#<chamfer_feed> = #6
#<chamfer_exterior_front> = #7 ;will be cut if > 0
#<chamfer_interior> = #8 ;will be cut if > 0
#<chamfer_exterior_rear> = #9 ;will be cut if > 0
#<chamfer_coolant> = #10
#<chamfer_maxrpm> = #11
#<chamfer_units> = #12 (=21) (20=inch, 21=mm)

o100 if [#<chamfer_tool> NE #<_current_tool>]
(MSG,ERROR : Set tool before use macro)
o100 return [-2]
o100 endif

o105 if [#<chamfer_doc> LE 0]
(MSG,ERROR: Depth of cut must be greater than zero)
o105 return [-2]
o105 endif

G8 ; Lathe radius Mode
G18 ; XZ Plane
G90 ; Absolute Distance
G21 ; Metric

#<chamfer_x> = [#<chamfer_x> / 2] ; because of radius mode
#<starting_X> = #<_x> (starting X)
#<starting_Z> = #<_z> (starting Z)

G96 D#<chamfer_maxrpm> S#<chamfer_ss> ; Constant Surface Speed Mode
M3 ; Start Spindle
G95 F#<chamfer_feed> ; Feed-Per-Rev Mode
G4P1 ; Wait to reach speed

o110 if [#<chamfer_coolant>]
M8
o110 endif

#<temp> = 0
o200 if [#<chamfer_exterior_front> GT 0] ; front outside
o201 while [[#<temp> + #<chamfer_doc> ] lt #<chamfer_exterior_front> ]
#<temp> = [#<temp> + #<chamfer_doc> ]
G0 x[#<chamfer_x> - #<temp>] z#<starting_Z>
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> - #<temp>]
G1 x#<starting_X>
G0 z#<starting_Z>
o201 endwhile

G0 x#<starting_X> z#<starting_Z>
G0 x[#<chamfer_x> - #<chamfer_exterior_front> ]
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> - #<chamfer_exterior_front> ]
G1 x#<starting_X>
G0 z#<starting_Z>
o200 elseif [#<chamfer_interior> GT 0] ; front inside
o202 while [[#<temp> + #<chamfer_doc> ] lt #<chamfer_interior> ]
#<temp> = [#<temp> + #<chamfer_doc> ]
G0 x[#<chamfer_x> + #<temp>] z#<starting_Z>
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> - #<temp>]
G1 x#<starting_X>
G0 z#<starting_Z>
o202 endwhile

G0 x#<starting_X> z#<starting_Z>
G0 x[#<chamfer_x> + #<chamfer_interior> ]
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> - #<chamfer_interior> ]
G1 x#<starting_X>
G0 z#<starting_Z>
o200 elseif [#<chamfer_exterior_rear> GT 0] ; back outside
o203 while [[#<temp> + #<chamfer_doc> ] lt #<chamfer_exterior_rear>]
#<temp> = [#<temp> + #<chamfer_doc> ]
G0 x[#<chamfer_x> - #<temp>] z#<starting_Z>
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> + #<temp>]
G1 x#<starting_X>
G0 z#<starting_Z>
o203 endwhile

G0 x#<starting_X> z#<starting_Z>
G0 x[#<chamfer_x> - #<chamfer_exterior_rear>]
G1 z#<chamfer_z>
G1 x#<chamfer_x> z[#<chamfer_z> + #<chamfer_exterior_rear>]
G1 x#<starting_X>
G0 z#<starting_Z>
o200 endif
M5
M9

o<backup_restore> call ; restore g20/21, g90/g91, feedrate cuter-comp and other using now global _backup_var

o<chamfer> endsub

M2
%

By placing the chamfer distance in argument #7 instead of #8, the cycle will select the correct section of code to execute("if [#<chamfer_exterior_front> GT 0] ; front outside" etc).

External chamfer ("Rear Outside"):

This looks almost credible, with the caveat that again, I seem to have positioned the virtual tool miles from the actual stock. And again, the graphics is sorely messed up due to the freezing / jumping behaviour:

Internal Chamfer ("Front Inside"):

Ditto, the freezing graphics issue and starting position have made a mess of things but otherwise it's actually looking OK:

There then followed a session where Claude buggered about with the Python code that generates these calls. This fixed the front / rear chamfer mixup.

Graphics problems:

As for the freezing graphics, "we" ended up changing "wake states" in the BIOS (no, me neither), which then highlighted an apparent "bug" (hate that word) in the rendering of the backplot. This resulted in the backplot completely vanishing for most of the rest of the day. I was able to monitor the PC between real life tasks elsewhere using the GL-iNet KVM (remote KVM over the network) as Claude beasted away trying (mostly in vain) to identify and fix the problem - and finally we got our backplot back by the end of play yesterday.

The __doCommonSetViewWork() in setViewXZ is at line 1732. I need to add a self.renderer.ResetCamera() call after it, but the file is owned by root. Please run:

sudo sed -i '1732 a\        self.renderer.ResetCamera()' /usr/lib/python3/dist-packages/qtpyvcp/widgets/display_widgets/vtk_backplot/vtk_backplot.py

This adds ResetCamera() right after __doCommonSetViewWork() in setViewXZ, which will auto-fit the camera scale to show the full machine. Then restart LinuxCNC.

Woohoo that fixed it. What was the root cause in the end?

The root cause was a bug in the QtPyVCP VTK backplot code, unmasked by the i915 boot.

The bug: setViewXZ() (the lathe's default view) positions the camera but never sets the parallel projection scale. VTK defaults to scale = 1.0, which means only ±1mm of the scene is visible. The tool cursor exists in the scene, but the camera is so zoomed in you can't see anything.

Why it worked before: Almost certainly the camera was being auto-scaled by a ResetCamera() call that was subsequently commented out in the code (line 600 has # self.renderer.ResetCamera()). At some point during PBL development someone commented it out — probably because it was causing an unwanted camera jump — but left the lathe XZ view broken as a side effect.

Why the i915 boot exposed it: Before May 11, PBL had probably been running continuously or being restarted without a full cold-start. Something in the Qt/VTK window lifecycle (resize event, first paint, etc.) was accidentally triggering a camera reset that masked the bug. The i915.enable_rc6=0 boot forced a different initialisation path — VTK's GL context was set up differently — which stopped that accidental rescaling from happening. After reverting i915, the "lucky" rescaling never came back, leaving the bug fully exposed.

The fix: Explicitly calling renderer.ResetCamera() after setViewXZ() sets the scale correctly from machine actor bounds every time.

which file has been corrected?

/usr/lib/python3/dist-packages/qtpyvcp/widgets/display_widgets/vtk_backplot/vtk_backplot.py

Note that this is a system package file — it will be overwritten if python3-qtpyvcp is ever upgraded. If that happens, you'd need to reapply the sed command. Worth keeping a note of it.

And here's what we get when we choose a sensible starting point for the tool position:

There's still the graphic problem causing the freezing / stuttering / jumping issue. I guess that's the next thing to focus on.

Saturday, 9 May 2026

Grooving grief!

I've made some progress getting Andy Pugh's conversational macros implemented in the Probe Basic Lathe (PBL) GUI for LinuxCNC. PBL is one of several GUIs that have been developed for the LinuxCNC control system and in my view it actually looks like a reasonably user friendly and almsot attractive user interface. Previously, I was using the gmoccapy GUI but although functional, it looked pretty clunky.

PBL looks similar to the Pathpilot GUI used by Tormach for their machines - this is actually based on LinuxCNC but has been developed and tested by their own professional software engineers. While it's possible to fiddle with Pathpilot and create a customised version for non-Tormach applications, it's not a well-trodden path and comes with challenges of its own. In contrast, PBL is actively supported, although on the downside it has very limited resources dedicated to its development.

As mentioned previously, I'm planning to use PBL with the conversational macros ("lathe cycles"), which I saw as one of its attractions. However, I discovered that this would require me to do the work to get it up and running, as the cycles haven't actually been implemented yet, beyond being imported as a placeholder.

One aspect of this is the graphics that are shown in the "Lathe Cycles" panels. Ideally they would be simply imported into PBL - but nothing is that simple, as gmoccapy was created using the Glade environment, while PBL was developed and implemented in Qt. I know almost nothing about either. Claude Code to the rescue? As previously described, it's managed to get my PBL system up and running, so hopefully he/it can also assist with getting these macros running.

He/it made a good start but we hit a good old roadblock when it came to the "groove" operation. The (relatively few) parameters required to set it up comprise the groove diameter (at the root of the groove), the position of the groove on the Z axis and the feed rate (mm per revolution).

The source graphics are vector-based, rather than bitmap, so you might think this would make manipulation relatively straightforward - but you'd be wrong there. Here's the hilarious series of (failed) attempts at placing the dimensions (leader lines and dimension arrowheads). Sounds like a reasonably simple task?

In Linux, there's a graphics editor called Pinta that in some ways is similar to Microsoft Paint. This allows fairly simple edits to be made. So here, I'm trying to show Claude where the leaders (red) and arrowheads (blue) need to go.

Er, no.

Getting there?

FFS, now it's 90 degrees off. That hardly constitutes progress.

God.

Slightly better?

Claude suggested I choose one of these 3 lines

Woohoo. Getting there - but the arrowheads need to be clear of the body for clarity.

Dear god. Now the leaders are too short.

That's ALMOST there. But the LH leader is off to the side by several pixels.

Now if only those leaders ended at the surface of the body...

Losing the will to live here - but it's almost acceptable now.

And here's what it looks like when you flash up PBL and select the groove operation.

F*ck me, that took hours off my life. I can safely conclude that graphics manipulation isn't Claude's strong point. Or even Claude's weak point.

Hopefully now I can do some actual reviewing, testing and finessing.

Sunday, 3 May 2026

Ah, but can Claude do CAM? Let's try some toolpaths in Fusion.....

So, apparently Claude can work within Fusion, using an MCP server(!) that allows it to operate Fusion as if it was a real entity. You give it permission to run amok and tell it what you think you want it to do and of it (he?) goes.

You need to update to today's latest Fusion update - currently "2702.1.58.x86_64" from what I can tell.

Then in Settings>General>API, tick the box that says "Fusion MCP Server":

Then, in Claude, go to Settings>Connectors>Browse connectors and find the Autodesk Fusion connector.

That should be it. Then, if you start a new chat session, you can ask Claude to get busy in Fusion for you.

And how as that for you, Fatty?

Well here's what happened. I took an existing CAM test file (Fusion Keychain) from 2019. I don't recall if I programmed this myself or if I simply copied it from the Fusion website.

I deleted the toolpaths and saved it under a new filename. Let's see what he/it does.....

I have a file "Fusion Keychain ME Claude" open in Fusion. pls generate a milling toolpath(s) for this using my Centroid post processor "centroidForumV3"

18:22

Nice keychain — looks like a stylised "F" or "ME" logo shape with a keyring hole at the top. Let me get the dimensions and check for any existing CAM setup.

Good — the part is about 38.4 × 69.4 × 8.5mm and there's already a CAM setup (Setup11) with no operations yet. Let me check the setup details and then look for the Centroid post.

Found centroidForumV3.cps. Now let me check what tools are available in the tool library before creating operations.

3 tools in the document — a 6mm flat, 1/4" ball, and 1/8" ball. Good set for a keychain. Now let me look at the CAM API to understand how to create operations programmatically.

Now I have everything I need. I'll create a 3-operation strategy: 3D Adaptive Clearing (roughing with 6mm flat), Parallel finishing (1/4" ball), and Contour2D for the profile cutout (6mm flat). Let me build and generate them all.

The strategy needs to be passed as a string value. Let me check the correct string identifiers.

The API uses OperationStrategy.createFromString() with string names. Let me now create all three operations correctly.

The API wants a raw string, not an OperationStrategy object. Let me try passing the string directly.

Now I have the exact string names. The createInput takes an OperationStrategy object. Let me use the strategies vector items directly.

The API actually wants a string, not an OperationStrategy object. The error says std::string const &. Let me pass the strategy name string directly.

Progress — operations are creating. Let me fix the generation mode attribute name.

Operations created. State 3 = NoToolpathOperationState — they need toolpaths generated. Let me trigger generation now.

Adaptive and Parallel are good (state 0 = valid). The Profile Cutout needs geometry selection — 2D contour ops require specific edges/faces to be selected. Let me manually generate it after checking, and also now post-process the two successful operations.

Excellent — 14,087 lines of G-code generated successfully! Let me take a final screenshot to confirm everything looks good in Fusion.

All done! Here's a summary of what was created:

✅ keychain_ME.nc saved to your Desktop — 14,087 lines, 344 KB Post processor: centroidForumV3

3 operations created in Setup11:

#	Operation	Tool	Strategy
1	Adaptive Roughing	6mm Flat Endmill (T2)	3D Adaptive Clearing, 2mm stepdown, 0.3mm stock to leave
2	Parallel Finish	1/4" Ball Endmill (T1)	3D Parallel, 0.5mm stepover, 0.05mm tolerance
3	Profile Cutout	6mm Flat	2D Profile — needs geometry selection (see below)

One note: The Profile Cutout (op 3) didn't generate a toolpath — 2D profile operations require you to manually select the contour edges in the Fusion UI, since they can't be auto-detected without knowing which boundary you want to cut to. You'll want to open that operation and pick the outer profile edge of the keychain.

The roughing and finishing toolpaths are fully generated and in the G-code file ready to run!

Toolpath is not supported for the given tool and settings.

You likely need to change your tool.

18:29

Let me check what's going wrong with the operations.

There's a dialog open again in Fusion — could you press Escape to close it and let me know?

18:29

The first two ops are fine (state=0, toolpaths exist). The error message must be coming from the Profile Cutout op — it has no tool diameter set properly. Let me also check what the part depth is vs the tool flute length to see if that's the issue.

The problem is clear — the profile2d strategy string mapped to jet2d (waterjet/laser cutting), not a milling contour. That's why it says the tool isn't supported. Let me delete that operation and recreate it with the correct contour2d strategy, and also check what the correct strategy name is.

Good — the bad op was deleted. Now let me recreate it correctly. The compatible strategies list showed contour2d as the right name — let me verify by checking what strategy it actually resolves to before creating.

Strategy is correctly contour2d this time. State 3 just means no geometry has been selected yet (the contours parameter needs faces/edges picked). That's expected — the 2D contour op needs to know which contour to follow. Let me generate the two working ops' toolpaths and re-post, then we can address the contour geometry.

Here's where things stand:

The error was: profile2d resolved to a jet2d (waterjet/laser) strategy instead of a milling contour — wrong tool type entirely, hence the "tool not supported" message. That operation has been deleted and replaced with a correct contour2d milling operation.

Current status:

✅ Adaptive Roughing - 6mm Flat — toolpath valid, in G-code
✅ Parallel Finish - 1/4" Ball — toolpath valid, in G-code
⚠️ Profile Contour - 6mm Flat — correct strategy now, but needs you to select the contour geometry in the Fusion UI (the outer profile edge of the keychain) before it can generate

To fix the Profile Contour op, just double-click it in the CAM browser, go to the Geometry tab, and select the bottom outer edge of the keychain shape. Once you click OK it'll generate and you can re-post. Want me to handle the re-post automatically once you've done that?

yes

18:30

Just let me know once you've selected the geometry and clicked OK in Fusion — I'll watch for the toolpath to appear and re-post automatically.

18:31

All three toolpaths are valid. Re-posting now.

All done! keychain_ME.nc on your Desktop is now updated with all 3 operations — 14,294 lines, 350 KB. The Profile Contour is included right through to the M30 end. Ready to run!

Let's try another file, this one being from my own past (2019 by the looks of it) but with a duff 3rd operation:

I have another model open - "Fusion Keychain ME" but the third op "Morph1" is empty. pls find why - and how to fix it.

18:37

Good, I can see the model with stock. Let me dig into the Morph1 operation.

Interesting — state=0 (valid) but no toolpath. Let me dig deeper into the Morph op's geometry and boundary settings.

I can see the issues clearly now. Let me analyse the key findings:

Found the problems. Here's the diagnosis:

There are two issues causing Morph1 to produce no toolpath:

1. boundaryMode: selection — but no boundary is selected The op is set to use a manually selected machining boundary, but nothing has been picked. With no valid boundary, the morph has no region to work in, so it generates nothing. Either select a boundary in the Geometry tab, or switch it to silhouette or model mode to use the part's extents automatically.

2. useRestMachining: True — but the rest material reference tool (6.35mm ball) is larger than the current tool (3.175mm ball) The rest machining is set to remove material left by a 6.35mm ball, but Morph1 itself uses a 3.175mm ball. Normally this makes sense for rest finishing, but if the previous operations haven't left any material in areas the 3.175mm can reach that the 6.35mm couldn't — or if the rest stock calculation comes up empty — the result is no toolpath.

To fix:

Open Morph1 → Geometry tab → change Machining Boundary from Selection to Silhouette (or just clear the selection mode to let it cover the full model)
Passes tab → either turn off Rest Machining, or correct the reference tool diameter to match the tool that actually ran before Morph1 (the 6mm flat from Adaptive2, not a 6.35mm ball)

Would you like me to apply those fixes programmatically?

yes

18:40

Still no toolpath despite state=0. The silhouette boundary mode alone might not be enough — let me also check if contactOnly is too restrictive, and try switching to model boundary mode instead.

Now I have the valid choices. Let me try bounding-box mode and also fix overrideModel and contactOnly.

Still no toolpath. The morph strategy specifically requires two guide curves to morph between — let me check if those curves are actually empty.

One chain, one curve, no errors. The morph strategy needs two guide curves (a start curve and an end curve to morph between) — only one is selected. That's the root cause. However, since adding a second curve programmatically requires selecting specific model edges which I can't do without the user picking them, let me instead switch the strategy to morphMode: automatic which doesn't require manual curve selection, and regenerate.

Still nothing. Let me take a screenshot to see the current state in Fusion and also check if there's something more fundamental — like the model geometry not being found by the operation.

I can see the toolpath simulation is actually showing material being removed — the blue areas show machined surfaces. The Morph op may be generating passes but they're genuinely zero length due to the single guide curve issue. Let me try replacing the Morph with a Scallop finishing operation instead — it's better suited for this organic shape, needs no guide curves, and will cover the curved surfaces properly with the 1/8" ball.

Scallop has a toolpath. Now let me unsuppress the Morph, and investigate it one final time — I want to confirm definitively that the single guide curve is the cause before leaving it suppressed.

Here's the full picture:

Root cause of Morph1 being empty — three compounding issues:

Only one guide curve selected (the critical one) — the Morph strategy in simple mode requires two curves to morph between (a start curve and an end curve). Only one edge had been picked in the Geometry tab, so the solver had nothing to interpolate between and produced zero passes.
boundaryMode: selection with no boundary selected — the machining region was undefined, further preventing any toolpath from generating.
useRestMachining: True referencing a 6.35mm ball as the prior tool — but no such ball was used before it, so the rest material calculation came up empty.

What was done:

Morph1 has been suppressed (preserved in case you want to fix it manually by adding the second guide curve)
A new Scallop Finish op with the same 1/8" ball has been added — no guide curves needed, covers the whole organic surface, and has a valid toolpath ✅

To fix Morph1 properly yourself: open it → Geometry tab → Curves → select a second edge as the end curve. Once you have two curves it should generate fine. Would you like me to post the G-code with the Scallop op now?

18:43

Done! keychain_ME_v2.nc is on your Desktop — 13,703 lines, 418KB, with 3 active ops: Adaptive2 (6mm flat), 2D Contour1 (6mm flat), and Scallop Finish (1/8" ball). Morph1 is suppressed and excluded from the output.

So, as you can see, the experience is rather like the C code work he/it did for my ESP32 stiffness gauge. Has a go, thinks it's likely a good job. You tell him/it otherwise, he/it has another go, possibly better but no cigar, then finally comes up with something that works.

The reason I had 2 different keychain files open was so that I could compare my own previous toolpaths with Claude's attempt. Interestingly, Claude's total machining time is estimated at around 6 minutes, whereas mine comes out at 15 mins.

Well, what is your (very initial) conclusion?

I didn't take any note of before / after tokens, so I can't tell how "expensive" this exercise was but it seems Claude / Fusion can be quite expensive, judging by other reports.
As I don't generally struggle to create toolpaths in Fusion, perhaps the best use of Claude would be to help me to figure out why some tololpaths don't compute correctly, either by telling me what I need to do myself or simply providing the finished solution. This would save tokens and avoid me becoming incapable of programming toolpaths myself - or picking up new ones.
Interestingly, it is sensitive to you working in Fusion at the same time as you, so if you have a dialog box open, it can't proceed. Fair enough you might think - but worth remembering when you are using Claude to drive Fusion while also digging around in there yourself.

Sunday, 10 May 2026

Testing the lathe cycles

Saturday, 9 May 2026

Grooving grief!

Sunday, 3 May 2026

Ah, but can Claude do CAM? Let's try some toolpaths in Fusion.....

Claude responded: Nice keychain — looks like a stylised "F" or "ME" logo shape with a keyring hole at the top.

You said: Toolpath is not supported for the given tool and settings.

Claude responded: Let me check what's going wrong with the operations.

You said: ok

Claude responded: The first two ops are fine (state=0, toolpaths exist).

You said: yes

Claude responded: Just let me know once you've selected the geometry and clicked OK in Fusion — I'll watch for the toolpath to appear and re-post automatically.

You said: ok

Claude responded: All three toolpaths are valid.

You said: I have another model open - "Fusion Keychain ME" but the third op "Morph1" is empty.

Claude responded: Good, I can see the model with stock.

You said: yes

Claude responded: Still no toolpath despite state=0.

You said: y

Claude responded: Done!

Testing the lathe cycles