Integration from Module Schemas to Full Model: Difference between revisions

From Open Source Ecology
Jump to navigation Jump to search
 
(9 intermediate revisions by the same user not shown)
Line 1: Line 1:
=About=
=About=


This must be done not by gurus—by clerks following specs.
To automate full CAD of Seed Eco-Homes, we must translate the implicit knowledge of the Seed Eco-Home build system. This must be done not by gurus—bbut by clerks following specs.


Why? Because of this - [https://chatgpt.com/share/69745a2f-5cfc-8010-9b29-09fe48aa4c1a]. In short: The real risk is not skill level—it’s unconscious substitution. The danger is not incompetence. The danger is: “I know a better way to do this.”
Why? Because of this - [https://chatgpt.com/share/69745a2f-5cfc-8010-9b29-09fe48aa4c1a]. In short: The real risk is not skill level of [[EAC]] programmers —it’s unconscious substitution. The danger is not incompetence. The danger is: “I know a better way to do this.”
 
=Howto=
The core simplification: '''Assembly is not geometry. Assembly is topology.''' Geometry already exists at the module level. Assembly is simply how modules are connected.
 
If you accept that, everything downstream becomes tractable.


= Induction-Grade House Compiler Process (Modules → Assembly → Post-Compilers) =
= Induction-Grade House Compiler Process (Modules → Assembly → Post-Compilers) =
Line 24: Line 19:
#Assemblies describe relationships
#Assemblies describe relationships
#Compilers produce geometry
#Compilers produce geometry
= Assembly Canon: Topology, Not Geometry =
== Canonical Statement ==
'''Assembly is not geometry. Assembly is topology.'''
Assembly declares '''relationships'''.
Geometry is a '''derived consequence'''.
If geometry is specified at the assembly level, automation fails.
If topology is specified, geometry becomes compilable.
== Definitions ==
=== Module ===
A module is a self-contained, parametric unit with:
* Local coordinate system (CSYS)
* Known dimensions
* Named connection ports (left, right, top, bottom, etc.)
* Published metadata (stud map, faces, no-go zones)
Modules contain geometry.
Assemblies do not.
=== Assembly ===
An assembly is a '''connection graph''' consisting only of:
* Module instances
* Connections between module ports
An assembly answers:
* What exists?
* What connects to what?
* Through which ports?
Nothing else.
== What Assembly Explicitly Does NOT Contain ==
Assembly definitions must never include:
* Coordinates (X, Y, Z)
* Absolute positions
* Offsets or dimensions
* Angles or rotations (except implicit via port orientation)
* Solids or sketches
* Boolean operations
* Manual placement decisions
Any of the above indicates a broken abstraction.
== Topology Is Sufficient ==
Given:
* Modules with known geometry and ports
* A graph of connections between ports
The assembly compiler can:
# Place a root module at origin
# Traverse the adjacency graph
# Align ports and propagate transforms
# Generate full building geometry deterministically
No additional information is required.
== Assembly Schema (Minimum Viable) ==
An assembly schema contains only:
* '''modules[]'''
  * module_id
  * module_type
  * parameters
  * orientation (discrete or implicit)
  * level (optional)
* '''connections[]'''
  * module_A.port_X → module_B.port_Y
  * (optional) connection type: L / T / splice
This schema is human-readable and human-authored.
== Why Assembly Must Be Topological ==
Topology is:
* Stable under change
* Regenerable
* Deterministic
* Auditable
* Suitable for rule-based automation
Geometry is:
* Fragile
* Context-dependent
* Hard to regenerate
* Prone to manual drift
Assemblies must survive change.
Geometry does not.
== Consequences for Automation ==
When topology is explicit:
* Corners are known (L-connections)
* T-walls are known (mid-span connections)
* Splices are known (collinear connections)
Therefore:
* Blocking rules trigger from connection types
* Electrical boxes place along wall sequences
* Plumbing and wiring become graph routing problems
* Feature injection becomes deterministic
No geometric inference hacks are required.
== Assembly vs Post-Compilers ==
Assembly compiler responsibilities:
* Place modules
* Record adjacency
* Emit connection events
Assembly compiler must:
* Make no design decisions
* Inject no features
* Modify no modules
All construction logic occurs in '''post-compilers'''.
== Invariants (Non-Negotiable) ==
* Assemblies are declarative, not procedural
* Assemblies contain no geometry
* Geometry is always regenerated
* Manual edits are forbidden
* Every downstream artifact must trace back to topology
Violating any invariant breaks induction.
== Canonical Takeaway ==
'''Assembly defines relationships.'''
'''Compilers derive geometry.'''
'''Rules inject features.'''
This separation is what makes houses, machines, and infrastructure compilable.
Lock this canon before writing code.
=Example: Minimum Viable Schemas: Module → Assembly → Post-Process =
This page defines the smallest complete, induction-grade pipeline for compiling a house from modules.
The goal is clarity, determinism, and zero interpretation.
The rule:
Modules define geometry.
Assembly defines topology.
Post-process passes inject features.
== 0) File Set (Minimum) ==
wall_module.yaml
assembly.yaml
postprocess.yaml
artifacts/ (compiler outputs: CAD, BOM, features)
== 1) Wall Module Schema (Minimum) ==
The wall module schema defines one wall module instance with local geometry and interfaces.
It contains no building-level logic.
wall_module.yaml
<syntaxhighlight lang="yaml">
module_type: wall_v1
module_id: W1
params:
  length_in: 48
  height_in: 120
  thickness_in: 5.5
  stud_spacing_in: 24
  end_stud: true
  plates:
    top: 2
    bottom: 1
ports:
  left_end:  {plane: "x=0"}
  right_end: {plane: "x=length"}
  interior_face: {plane: "y=0"}
  exterior_face: {plane: "y=thickness"}
metadata:
  stud_map:
    origin: left_end
    axis: x
    studs_at_in: [0, 24, 48]
  lanes:
    blocking_lane:
      y_range_in: [1.0, 4.5]
      z_range_in: [0, 120]
</syntaxhighlight>
Notes:
Ports are symbolic references.
Stud locations may be explicitly listed or generated by the compiler.
Lanes define where post-process features are allowed to exist.
== 2) Wall Module Compiler (Responsibilities) ==
The wall module compiler:
Reads wall_module.yaml
Generates framing solids (studs and plates)
Creates a local coordinate system
Defines named port planes
Tags studs and plates
Exports stud IDs and centerlines
Exports lanes and no-go zones
Outputs:
Module CAD file
module_metadata.json
bom.csv
The wall compiler does not know anything about the house.
== 3) Assembly Schema (Topology Only) ==
The assembly schema declares what connects to what.
It contains no geometry.
assembly.yaml
<syntaxhighlight lang="yaml">
assembly_id: house_demo_01
units: inches
modules:
  - module_id: W1
    module_type: wall_v1
    params_ref: wall_module_W1.yaml
    orientation:
      rotation_deg: 0
      level: 0
  - module_id: W2
    module_type: wall_v1
    params_ref: wall_module_W2.yaml
    orientation:
      rotation_deg: 90
      level: 0
connections:
  - a: {module_id: W1, port: right_end}
    b: {module_id: W2, port: left_end}
    connection_type: L_CORNER
</syntaxhighlight>
wall_module_W2.yaml is identical to W1 except for module_id.
== 4) Assembly Compiler (Responsibilities) ==
The assembly compiler:
Loads module metadata
Places the first module at world origin
Traverses the connection graph
Aligns ports and propagates transforms
Places all modules deterministically
The assembly compiler emits:
Placed transforms per module
An assembly graph with connection events
A complete assembled CAD model
Each connection event records:
Connection type (L_CORNER, T, SPLICE)
Participating module IDs and ports
World-space joint reference
The assembly compiler makes no design decisions and injects no features.
== 5) Post-Process Schema (Minimum) ==
The post-process schema defines ordered feature injection passes.
Each pass is deterministic and idempotent.
postprocess.yaml
<syntaxhighlight lang="yaml">
postprocess_id: pp_demo_01
passes:
  - pass_id: corner_blocking_v1
    type: feature_injection
    triggers:
      - connection_type: L_CORNER
    feature: ladder_blocking
    params:
      block_member:
        size: "2x4"
      vertical_spacing_in: 16
      z_start_in: 16
      z_end_in: 96
    host_selection:
      apply_to: [a, b]
      lane: blocking_lane
</syntaxhighlight>
== 6) Post-Process Compiler (Responsibilities) ==
The post-process compiler:
Loads assembly graph and transforms
Finds trigger events
Computes local placement references per host module
Selects studs or bays using stud_map
Creates feature objects
Materializes features into CAD geometry
Each feature object includes:
Host module ID
Feature type
Local placement reference
Source connection ID
Idempotence rule:
Feature IDs are derived from (pass_id + connection_id + host_module_id + z_index).
Re-running the pass must not duplicate geometry.
Outputs:
Updated CAD assembly
features.json (audit trail)
bom_delta.csv
== 7) Concrete Example: Right-Angle Corner with Blocking ==
Inputs:
Wall W1 oriented along +X
Wall W2 oriented along +Y
Connection type L_CORNER
Post-process rule corner_blocking_v1
Result:
The post-process compiler injects ladder blocking into W1 and W2 at the corner.
Blocking is placed only inside the declared blocking_lane.
Blocking members are attached near the corner end studs.
The BOM is updated with blocking lumber.
The feature audit log records every injected block.
This completes a full minimum viable compile:
Module → Assembly → Post-Process
All geometry is derived.
All logic is explicit.
All outputs are regenerable.

Latest revision as of 06:45, 24 January 2026

About

To automate full CAD of Seed Eco-Homes, we must translate the implicit knowledge of the Seed Eco-Home build system. This must be done not by gurus—bbut by clerks following specs.

Why? Because of this - [1]. In short: The real risk is not skill level of EAC programmers —it’s unconscious substitution. The danger is not incompetence. The danger is: “I know a better way to do this.”

Induction-Grade House Compiler Process (Modules → Assembly → Post-Compilers)

Canonical Principle

All downstream artifacts are generated from:

  1. Module Schemas (single-module truth)
  2. Assembly Schema (topology truth: what connects to what)
  3. Post-Compiler Passes (feature injection + routing + schedules)

No manual CAD edits. Every output must be regenerable from schemas.

Canonical Principle 2

  1. Schemas describe intent
  2. Assemblies describe relationships
  3. Compilers produce geometry

Assembly Canon: Topology, Not Geometry

Canonical Statement

Assembly is not geometry. Assembly is topology.

Assembly declares relationships. Geometry is a derived consequence.

If geometry is specified at the assembly level, automation fails. If topology is specified, geometry becomes compilable.

Definitions

Module

A module is a self-contained, parametric unit with:

  • Local coordinate system (CSYS)
  • Known dimensions
  • Named connection ports (left, right, top, bottom, etc.)
  • Published metadata (stud map, faces, no-go zones)

Modules contain geometry. Assemblies do not.

Assembly

An assembly is a connection graph consisting only of:

  • Module instances
  • Connections between module ports

An assembly answers:

  • What exists?
  • What connects to what?
  • Through which ports?

Nothing else.

What Assembly Explicitly Does NOT Contain

Assembly definitions must never include:

  • Coordinates (X, Y, Z)
  • Absolute positions
  • Offsets or dimensions
  • Angles or rotations (except implicit via port orientation)
  • Solids or sketches
  • Boolean operations
  • Manual placement decisions

Any of the above indicates a broken abstraction.

Topology Is Sufficient

Given:

  • Modules with known geometry and ports
  • A graph of connections between ports

The assembly compiler can:

  1. Place a root module at origin
  2. Traverse the adjacency graph
  3. Align ports and propagate transforms
  4. Generate full building geometry deterministically

No additional information is required.

Assembly Schema (Minimum Viable)

An assembly schema contains only:

  • modules[]
 * module_id
 * module_type
 * parameters
 * orientation (discrete or implicit)
 * level (optional)
  • connections[]
 * module_A.port_X → module_B.port_Y
 * (optional) connection type: L / T / splice

This schema is human-readable and human-authored.

Why Assembly Must Be Topological

Topology is:

  • Stable under change
  • Regenerable
  • Deterministic
  • Auditable
  • Suitable for rule-based automation

Geometry is:

  • Fragile
  • Context-dependent
  • Hard to regenerate
  • Prone to manual drift

Assemblies must survive change. Geometry does not.

Consequences for Automation

When topology is explicit:

  • Corners are known (L-connections)
  • T-walls are known (mid-span connections)
  • Splices are known (collinear connections)

Therefore:

  • Blocking rules trigger from connection types
  • Electrical boxes place along wall sequences
  • Plumbing and wiring become graph routing problems
  • Feature injection becomes deterministic

No geometric inference hacks are required.

Assembly vs Post-Compilers

Assembly compiler responsibilities:

  • Place modules
  • Record adjacency
  • Emit connection events

Assembly compiler must:

  • Make no design decisions
  • Inject no features
  • Modify no modules

All construction logic occurs in post-compilers.

Invariants (Non-Negotiable)

  • Assemblies are declarative, not procedural
  • Assemblies contain no geometry
  • Geometry is always regenerated
  • Manual edits are forbidden
  • Every downstream artifact must trace back to topology

Violating any invariant breaks induction.

Canonical Takeaway

Assembly defines relationships. Compilers derive geometry. Rules inject features.

This separation is what makes houses, machines, and infrastructure compilable.

Lock this canon before writing code.

Example: Minimum Viable Schemas: Module → Assembly → Post-Process

This page defines the smallest complete, induction-grade pipeline for compiling a house from modules. The goal is clarity, determinism, and zero interpretation.

The rule: Modules define geometry. Assembly defines topology. Post-process passes inject features.

0) File Set (Minimum)

wall_module.yaml assembly.yaml postprocess.yaml artifacts/ (compiler outputs: CAD, BOM, features)

1) Wall Module Schema (Minimum)

The wall module schema defines one wall module instance with local geometry and interfaces. It contains no building-level logic.

wall_module.yaml

<syntaxhighlight lang="yaml"> module_type: wall_v1 module_id: W1

params: 

 length_in: 48
 height_in: 120
 thickness_in: 5.5
 stud_spacing_in: 24
 end_stud: true
 plates:
   top: 2
   bottom: 1

ports: 

 left_end:  {plane: "x=0"}
 right_end: {plane: "x=length"}
 interior_face: {plane: "y=0"}
 exterior_face: {plane: "y=thickness"}

metadata: 

 stud_map:
   origin: left_end
   axis: x
   studs_at_in: [0, 24, 48]

 lanes:
   blocking_lane:
     y_range_in: [1.0, 4.5]
     z_range_in: [0, 120]

</syntaxhighlight>

Notes: Ports are symbolic references. Stud locations may be explicitly listed or generated by the compiler. Lanes define where post-process features are allowed to exist.

2) Wall Module Compiler (Responsibilities)

The wall module compiler: Reads wall_module.yaml Generates framing solids (studs and plates) Creates a local coordinate system Defines named port planes Tags studs and plates Exports stud IDs and centerlines Exports lanes and no-go zones

Outputs: Module CAD file module_metadata.json bom.csv

The wall compiler does not know anything about the house.

3) Assembly Schema (Topology Only)

The assembly schema declares what connects to what. It contains no geometry.

assembly.yaml

<syntaxhighlight lang="yaml"> assembly_id: house_demo_01 units: inches

modules: 

 - module_id: W1
   module_type: wall_v1
   params_ref: wall_module_W1.yaml
   orientation:
     rotation_deg: 0
     level: 0

 - module_id: W2
   module_type: wall_v1
   params_ref: wall_module_W2.yaml
   orientation:
     rotation_deg: 90
     level: 0

connections: 

 - a: {module_id: W1, port: right_end}
   b: {module_id: W2, port: left_end}
   connection_type: L_CORNER

</syntaxhighlight>

wall_module_W2.yaml is identical to W1 except for module_id.

4) Assembly Compiler (Responsibilities)

The assembly compiler: Loads module metadata Places the first module at world origin Traverses the connection graph Aligns ports and propagates transforms Places all modules deterministically

The assembly compiler emits: Placed transforms per module An assembly graph with connection events A complete assembled CAD model

Each connection event records: Connection type (L_CORNER, T, SPLICE) Participating module IDs and ports World-space joint reference

The assembly compiler makes no design decisions and injects no features.

5) Post-Process Schema (Minimum)

The post-process schema defines ordered feature injection passes. Each pass is deterministic and idempotent.

postprocess.yaml

<syntaxhighlight lang="yaml"> postprocess_id: pp_demo_01

passes: 

 - pass_id: corner_blocking_v1
   type: feature_injection

   triggers:
     - connection_type: L_CORNER

   feature: ladder_blocking

   params:
     block_member:
       size: "2x4"
     vertical_spacing_in: 16
     z_start_in: 16
     z_end_in: 96

   host_selection:
     apply_to: [a, b]
     lane: blocking_lane

</syntaxhighlight>

6) Post-Process Compiler (Responsibilities)

The post-process compiler: Loads assembly graph and transforms Finds trigger events Computes local placement references per host module Selects studs or bays using stud_map Creates feature objects Materializes features into CAD geometry

Each feature object includes: Host module ID Feature type Local placement reference Source connection ID

Idempotence rule: Feature IDs are derived from (pass_id + connection_id + host_module_id + z_index). Re-running the pass must not duplicate geometry.

Outputs: Updated CAD assembly features.json (audit trail) bom_delta.csv

7) Concrete Example: Right-Angle Corner with Blocking

Inputs: Wall W1 oriented along +X Wall W2 oriented along +Y Connection type L_CORNER Post-process rule corner_blocking_v1

Result: The post-process compiler injects ladder blocking into W1 and W2 at the corner. Blocking is placed only inside the declared blocking_lane. Blocking members are attached near the corner end studs. The BOM is updated with blocking lumber. The feature audit log records every injected block.

This completes a full minimum viable compile: Module → Assembly → Post-Process

All geometry is derived. All logic is explicit. All outputs are regenerable.

Retrieved from "https://wiki.opensourceecology.org/index.php?title=Integration_from_Module_Schemas_to_Full_Model&oldid=319022"