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docs(bmad): Add Hierarchical Subsystems (FR48) to PRD, Arch, Epics and Sprint

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_bmad-output/implementation-artifacts/3-6-hierarchical-macro-components.md Normal file
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# Story 3.6: Hierarchical Subsystems (MacroComponents)
Status: ready-for-dev
## Story
As a system designer,
I want to encapsulate a complete system (e.g., a Chiller with compressor, condenser, valve, evaporator) into a single reusable block,
so that I can compose larger models (like buildings or parallel chiller plants) using these blocks, just like in Modelica.
## Acceptance Criteria
1. **MacroComponent Trait Implementation** (AC: #1)
- Given a fully defined `System` with internal components and connections
- When I wrap it in a `MacroComponent`
- Then this `MacroComponent` implements the `Component` trait
- And the global solver treats it exactly like a basic Component
2. **External Port Mapping** (AC: #2)
- Given a `MacroComponent` wrapping an internal `System`
- When I want to expose specific internal ports (e.g., Evaporator Water In/Out, Condenser Water In/Out)
- Then I can map these to the `MacroComponent`'s external ports
- And external connections to these mapped ports correctly route fluid states to the internal components
3. **Residual and Jacobian Delegation** (AC: #3)
- Given a system solver calling `compute_residuals` or `jacobian_entries` on a `MacroComponent`
- When the `MacroComponent` executes these methods
- Then it delegates or flattens the computation down to the nested internal `System`
- And all equations are solved simultaneously globally, avoiding nested numerical solver delays
4. **Serialization and Persistence** (AC: #4)
- Given a `System` that contains `MacroComponent`s
- When serializing the system to JSON
- Then the internal topology of the `MacroComponent` is preserved and can be deserialized perfectly
## Tasks / Subtasks
- [ ] Define `MacroComponent` struct in `crates/components/src/macro_component.rs` (AC: #1)
- [ ] Store internal `System`
- [ ] Store `port_mapping` dictionary
- [ ] Implement `Component` trait for `MacroComponent` (AC: #1, #3)
- [ ] Implement `get_ports` returning mapped external ports
- [ ] Implement `compute_residuals` by delegating to internal components
- [ ] Implement `jacobian_entries` by offsetting indices and delegating to internal components
- [ ] Implement `n_equations` returning the sum of internal equations
- [ ] Implement external port bounding/mapping logic (AC: #2)
- [ ] Create API for `expose_port(internal_node_id, external_port_name)`
- [ ] Integration Tests (AC: #1-#3)
- [ ] Test encapsulating a 4-component cycle into a single `MacroComponent`
- [ ] Test connecting two identical `MacroComponent` chillers in parallel inside a higher-level `System`
- [ ] Assert global convergence works simultaneously.
## Dev Notes
### Epic Context
**Epic 3: System Topology (Graph)** — Enable component assembly via Ports and manage multi-circuits with thermal coupling.
This story adds the capability to wrap topologies into sub-blocks.
**FRs covered:** FR48 (Hierarchical Subsystems).
### Architecture Context
**Technical Stack:**
- Rust, `entropyk-components`, `entropyk-solver`
- Need to ensure that `SystemState` indices stay aligned when a `MacroComponent` is placed into a larger `System`.
**Relevant Architecture Decisions:**
- **Wrapper Pattern:** `MacroComponent` implements `Component`.
- **SystemState Flattening:** The global solver dictates state vector indices. The `MacroComponent` must know how its internal node IDs map to the global `SystemState` indices, or it must reconstruct an internal `SystemState` slice.
- **Zero-allocation:** Port mapping and index offsetting must be pre-calculated during the topology finalization phase.
### Code Structure
- Create `crates/components/src/macro_component.rs`.
- May require slight structural adjustments to `crates/solver/src/system.rs` if `System` doesn't currently support being completely embedded.
### Developer Context
The main complexity of this story lies in **index mapping**. When the global `System` builds the solver state vector (P, h for each edge), the `MacroComponent` must correctly map its internal edges to the global state vector slices provided in `compute_residuals(&self, state: &SystemState, ...)`.
Consider building an initialization step where `MacroComponent` is informed of its global state offsets before solving begins.

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_bmad-output/implementation-artifacts/sprint-status.yaml
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@ -73,6 +73,7 @@ development_status:
3-3-multi-circuit-machine-definition: done
3-4-thermal-coupling-between-circuits: done
3-5-zero-flow-branch-handling: done
3-6-hierarchical-macro-components: ready-for-dev
epic-3-retrospective: optional
# Epic 4: Intelligent Solver Engine

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_bmad-output/planning-artifacts/architecture.md
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@ -283,6 +283,32 @@ impl Compressor<Disconnected> {
- Extensible pour composants custom (e.g., Ejecteur de Robert)
- AHRI 540 coefficients intégrés dans struct Compressor
### Hierarchical Subsystems (MacroComponents)
**Decision:** Wrapper Pattern matching the `Component` trait
**Core Pattern:**
```rust
struct MacroComponent {
internal_system: System,
port_mapping: HashMap<PortId, InternalLocation>, /* e.g., Exposes 'Condenser Water In' */
}
impl Component for MacroComponent {
fn compute_residuals(&self, state: &SystemState, residuals: &mut ResidualVector) {
// Delegates or flattens computation to internal_system
self.internal_system.compute_residuals(state, residuals);
}
// ... maps external ports to internal boundary ports ...
}
```
**Rationale:**
- Allows users to build reusable blocks (like a full Chiller, Air Handling Unit)
- Mimics Modelica/Simulink ecosystem composability
- The global solver treats `MacroComponent` exactly like a basic Component, preserving zero-cost abstractions
- `SystemState` flattening ensures equations are solved simultaneously globally, avoiding nested numerical solver delays.
### Fluid Properties Backend
**Decision:** Trait abstraction with multiple backends
@ -794,7 +820,7 @@ pub trait Solver {
| Feature | FRs | Location |
|---------|-----|----------|
| Component Modeling | FR1-FR8 | `crates/components/src/` |
| System Topology | FR9-FR13 | `crates/solver/src/system.rs` |
| System Topology | FR9-FR13, FR48 | `crates/solver/src/system.rs` & `macro_component.rs` |
| Solver Engine | FR14-FR21 | `crates/solver/src/strategies/` |
| Inverse Control | FR22-FR24 | `crates/solver/src/inverse/` |
| Fluid Properties | FR25-FR29 | `crates/fluids/src/` |

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_bmad-output/planning-artifacts/epics.md
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@ -251,6 +251,7 @@ This document provides the complete epic and story breakdown for Entropyk, decom
| FR45 | Epic 7 | Inverse calibration (parameter estimation) |
| FR46 | Epic 1 | Air Coils (EvaporatorCoil, CondenserCoil) |
| FR47 | Epic 2 | Rich Thermodynamic State Abstraction |
| FR48 | Epic 3 | Hierarchical Subsystems (MacroComponents) |
## Epic List
@ -273,11 +274,11 @@ This document provides the complete epic and story breakdown for Entropyk, decom
---
### Epic 3: System Topology (Graph)
**Goal:** Enable component assembly via Ports and manage multi-circuits with thermal coupling.
**Goal:** Enable component assembly via Ports and manage multi-circuits with thermal coupling, and support hierarchical subsystems.
**Innovation:** Multi-fluid directed graph in a single model.
**Innovation:** Multi-fluid directed graph in a single model, with natively supported hierarchical sub-blocks.
**FRs covered:** FR9, FR10, FR11, FR12, FR13
**FRs covered:** FR9, FR10, FR11, FR12, FR13, FR48
---
@ -664,6 +665,23 @@ This document provides the complete epic and story breakdown for Entropyk, decom
---
### Story 3.6: Hierarchical Subsystems (MacroComponents)
**As a** system designer,
**I want** to encapsulate a complete system (e.g., a Chiller with compressor, condenser, valve, evaporator) into a single reusable block,
**So that** I can compose larger models (like buildings or parallel chiller plants) using these blocks, just like in Modelica.
**Acceptance Criteria:**
**Given** a fully defined `System` with internal components and connections
**When** I wrap it in a `MacroComponent`
**Then** I can expose specific internal ports (e.g., Evaporator Water In/Out, Condenser Water In/Out) as the `MacroComponent`'s external ports
**And** this `MacroComponent` implements the `Component` trait
**And** I can add it to a higher-level `System` just like any regular component
**And** the global solver correctly flattens or delegates the residual and jacobian computations down to the nested components.
---
## Epic 4: Intelligent Solver Engine
### Story 4.1: Solver Trait Abstraction

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_bmad-output/planning-artifacts/prd.md
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@ -460,6 +460,7 @@ Le produit est utile uniquement si tous les éléments critiques fonctionnent en
- **FR11** : Le système supporte les connexions entre circuits (couplage thermique)
- **FR12** : Le système peut résoudre les N circuits simultanément ou séquentiellement
- **FR13** : Le système gère mathématiquement les branches à débit nul sans division par zéro
- **FR48** : Le système permet de définir des sous-systèmes hiérarchiques (MacroComponents/Blocks) comme dans Modelica, encapsulant une topologie interne et exposant uniquement des ports (ex: raccorder deux Chillers en parallèle).
### 3. Résolution du Système (Solver)
@ -552,7 +553,7 @@ Le produit est utile uniquement si tous les éléments critiques fonctionnent en
**Workflow :** BMAD Create PRD
**Steps Completed :** 12/12
**Total FRs :** 47
**Total FRs :** 48
**Total NFRs :** 17
**Personas :** 5
**Innovations :** 5