FESADev/docs/ARCHITECTURE.md

# FESA Solver Architecture

## 목표
FESA는 C++17/MSVC 기반 유한요소 구조해석 솔버다. 초기 구현은 MITC4 4절점 shell element의 선형정적 해석이며, 이후 비선형 정적해석, 비선형 동적해석, 열전달 및 thermal-stress coupling, 1D/3D 요소로 확장한다.

초기 구현은 정확도와 테스트 가능성을 우선한다. 단, 대규모 모델을 목표로 하므로 자유도 관리, 희소 행렬 조립, 선형 솔버, 병렬 실행 계층은 초기부터 성능 확장이 가능하도록 분리한다.

## 개발 프로세스 구조
```text
Feature request
-> requirements
-> research evidence
-> FEM formulation
-> I/O contract
-> reference model and artifact contract
-> TDD implementation plan
-> C++ implementation
-> build/test validation
-> HDF5 reference comparison
-> physics/release review
```

## 설계 원칙
- `Domain`은 입력 모델의 의미를 보존하고 파싱 이후 가능한 한 불변에 가깝게 유지한다.
- 해석 중 변하는 물리량과 반복 상태는 `AnalysisState`에 명시적으로 분리한다.
- 현재 step에서 활성화되는 실행 view는 `AnalysisModel`이 담당하며, `Domain`을 복사하지 않는다.
- 요소, 재료, 하중, 경계조건, 해석 알고리즘은 런타임 다형성 기반으로 확장한다.
- 결과는 step/frame/field/history 개념으로 저장하여 정적, 비선형, 동적, 열전달 해석을 같은 결과 모델로 다룬다.
- 외부 라이브러리인 MKL, TBB, HDF5는 adapter 계층 뒤에 둔다.
- Abaqus input 호환성은 parser와 factory/registry 계층에서 관리한다.
- shell node는 6자유도이고, 결과 자유도 순서는 `U1, U2, U3, UR1, UR2, UR3`이다.
- 단위계는 강제하지 않는다. 입력과 reference artifact metadata에 기록된 일관 단위계를 그대로 사용한다.
- 결과 부호와 shell output component naming은 Abaqus 규약을 따른다.
- 경계조건은 constrained DOF 제거 방식으로 적용하고, reaction은 full vector 기준 `K_full * U_full - F_full`로 계산한다.
- 기본 실수 precision은 `double`이다.
- 대규모 모델을 위해 id, index, equation numbering은 int64 기반으로 설계한다.
- Mesh quality 진단은 1차 범위에서 제외한다. 대신 singular system 진단은 필수로 제공한다.

## Directory Structure
```text
include/fesa/
  analysis/        # Static, nonlinear static, dynamic, heat transfer analysis interfaces
  assembly/        # Global matrix/vector assembly and sparse pattern creation
  boundary/        # Fix, RBE2, RBE3 and future constraint objects
  core/            # Domain, AnalysisModel, AnalysisState, DofManager
  element/         # Node, Element, MITC4 and future elements
  io/              # Abaqus input parser and HDF5 result writer
  load/            # NodalLoad, PressureLoad, BodyForce
  math/            # Vector, Matrix, SparseMatrix, MKL adapter
  material/        # LinearElastic and future material models
  property/        # ShellProperty and 1D/2D/3D properties
  results/         # ResultStep, ResultFrame, FieldOutput, HistoryOutput
  util/            # Diagnostics, logging, validation helpers
  verification/    # HDF5 reference comparison utilities

src/
  analysis/
  assembly/
  boundary/
  core/
  element/
  io/
  load/
  math/
  material/
  property/
  results/
  util/
  verification/

tests/
  parser/
  element/
  assembly/
  solver/
  hdf5/
  reference/
```

The current repository may not yet contain all directories. They are intended ownership boundaries for implementation planning.

## Core Runtime Objects
- `Domain`: owns model definitions from input: nodes, elements, materials, properties, sets, boundary conditions, loads, and step definitions.
- `AnalysisModel`: step-local execution view over active elements, loads, boundary conditions, properties, materials, and equation system view.
- `AnalysisState`: owns changing physical quantities and iteration/time state such as displacement, velocity, acceleration, temperature, forces, residual, current time, increment, and element/integration-point state.
- `Node`: stores node id, coordinates, and six DOF values in order `U1, U2, U3, UR1, UR2, UR3`.
- `Element`: computes local stiffness, internal force/resultants, stress recovery, and connectivity.
- `ShellMITC4Element`: 4 nodes, 24 DOF, 2x2 Gauss integration, MITC transverse shear interpolation.
- `Material`: base contract for material behavior.
- `Property`: element property and section data, including shell thickness.
- `LinearElasticShellSection`: isotropic elastic shell section with thickness and shear correction.
- `DofManager`: active DOF definitions, constrained/free DOF mapping, equation numbering, sparse pattern ownership, and full/reduced vector reconstruction.
- `Assembler`: gathers element contributions into deterministic global sparse data.
- `SparseMatrix`: internal sparse matrix abstraction backed by MKL-compatible CSR for v0.
- `LinearSolver`: solver interface implemented initially by `MklPardisoSolver`.
- `Analysis`: strategy interface for `LinearStaticAnalysis` and future nonlinear/dynamic/thermal analyses.
- `Hdf5ResultWriter`: writes mesh, metadata, nodal results, element resultants, stresses, field output, and history output.
- `ReferenceComparator`: compares FESA HDF5 output with stored reference HDF5 artifacts using tolerance `1e-5`.

## State Ownership

### Domain
`Domain` represents parsed model definition and should not store equation ids, solver vectors, current displacement, or iteration state.

Included:
- nodes and elements
- materials and properties
- node sets and element sets
- loads and boundary conditions
- analysis step definitions

### AnalysisModel
`AnalysisModel` is built per active step. It references `Domain` objects by id or stable reference and defines what participates in the current solve.

Included:
- active elements
- active loads
- active boundary conditions
- active property/material references
- current equation system view

### DofManager
`DofManager` centralizes all equation numbering. Node or Element objects must not independently own equation ids.

Responsibilities:
- define active node DOFs
- map constrained and free DOFs
- assign equation numbers
- provide connectivity for sparse matrix pattern generation
- reconstruct full vectors from reduced solution vectors

### AnalysisState
`AnalysisState` stores mutable quantities and future nonlinear/time history extension points.

Included:
- displacement, velocity, acceleration
- temperature
- external force, internal force, residual
- current time, increment, Newton iteration
- element state and integration point state

Phase 1 uses displacement-centered state only, but the structure must not block geometric nonlinear and thermal-stress extensions.

### Results State
Results use:
- `ResultStep`: analysis step result group
- `ResultFrame`: static load increment or dynamic time frame
- `FieldOutput`: node/element field results
- `HistoryOutput`: selected node, element, set, reaction, or energy histories

## Data Flow
```text
Abaqus input file
-> InputParser
-> Factory/Registry object creation
-> Domain
-> StepDefinition loop
-> AnalysisModel
-> DofManager
-> sparse pattern creation
-> TBB parallel element stiffness computation
-> deterministic CSR assembly
-> constrained DOF elimination
-> MKL PARDISO solve
-> full displacement vector reconstruction
-> reaction recovery by K_full * U_full - F_full
-> TBB parallel element result recovery
-> HDF5 step/frame/field/history output
-> HDF5 reference comparison
```

## Patterns

### Strategy
Used for swappable analysis and numerical algorithms:
- `Analysis`: `LinearStaticAnalysis`, `NonlinearStaticAnalysis`, `DynamicAnalysis`, `HeatTransferAnalysis`
- `LinearSolver`: `MklPardisoSolver`, future iterative solver
- `TimeIntegrator`: future Newmark/HHT
- `ConvergenceCriteria`: future residual, displacement, and energy norms

### Template Method
`Analysis::run()` owns the high-level execution order:
```text
initialize
buildAnalysisModel
buildDofMap
buildSparsePattern
assemble
applyBoundaryConditions
solve
updateState
writeResults
```

Nonlinear static analysis will reuse this sequence inside Newton-Raphson loops. Dynamic analysis will reuse it inside time step/frame loops.

### Factory + Registry
Abaqus input keywords map to internal object factories:
- `*ELEMENT, TYPE=S4` -> `MITC4ElementFactory`
- `*ELEMENT, TYPE=S4R` -> `MITC4ElementFactory`
- `*MATERIAL`, `*ELASTIC` -> `LinearElasticMaterialFactory`
- `*SHELL SECTION` -> `ShellPropertyFactory`
- `*BOUNDARY` -> `FixBoundaryFactory`
- `*CLOAD` -> `NodalLoadFactory`
- `*NSET`, `*ELSET` -> set registry

Adding an element, material, load, or boundary condition should not require rewriting the parser core.

### Adapter
MKL, TBB, and HDF5 APIs are not exposed directly to solver core objects.

Adapter targets:
- `SparseMatrix`, `Vector`, `Matrix`
- `LinearSolver`
- `ParallelFor`
- `ResultsWriter`

This allows test doubles and future dependency replacement without changing solver physics code.

### Runtime Polymorphism
Elements, materials, loads, and boundary conditions are handled through base interfaces. Phase 1 prioritizes clarity and testability. If large-model performance requires it later, assembly internals may add type-specific batch kernels.

## MITC4 Result Contract
Nodal displacement output:
```text
node_id, U1, U2, U3, UR1, UR2, UR3
```

Nodal reaction output:
```text
node_id, RF1, RF2, RF3, RM1, RM2, RM3
```

Element internal force/resultant output at Gauss points:
```text
element_id, gauss_id, xi, eta, N11, N22, N12, M11, M22, M12, Q13, Q23
```

Stress output:
```text
element_id, gauss_id, section_point, S11, S22, S12, S13, S23
```

## HDF5 Layout
```text
/metadata
  feature_id
  solver_version
  model_id
  units
  tolerance
  reference_solver

/mesh/nodes
/mesh/elements/mitc4/connectivity

/results/step_000/frame_000/nodal/displacement
/results/step_000/frame_000/nodal/reaction
/results/step_000/frame_000/element/forces
/results/step_000/frame_000/element/stress
/results/step_000/frame_000/history
```

## Parallelism And Sparse Assembly
TBB parallelism is allowed for element-local computations, element force recovery, assembly precompute, and independent postprocessing.

Global assembly must remain deterministic:
```text
parallel element loop
-> thread-local sparse contribution buffers
-> stable sort by (row, column)
-> deterministic sum
-> CSR arrays
```

The sparse matrix path must preserve 64-bit index boundaries so MKL `pardiso_64` can be used for large models.

The solver must avoid uncontrolled MKL/TBB oversubscription. Thread-count decisions are part of analysis metadata and validation reports.

## Validation Flow
```text
python scripts/validate_workspace.py
-> CMake configure
-> MSVC Debug build
-> CTest
-> feature-specific reference comparison tests
```

When no CMake project exists yet, validation may report the harness no-op path. Once solver code is introduced, CMake/CTest validation is mandatory.

## Reference Artifact Flow
Agents do not run Abaqus or Nastran.

```text
Human-approved Abaqus run
-> stored HDF5 reference artifact under references/<feature>/<model-id>/
-> FESA solver HDF5 output
-> ReferenceComparator
-> pass/fail using abs-or-rel 1e-5
```

For `mitc4-linear-static-shell`, Abaqus S4R is primary and S4 is diagnostic.

## Performance Extension Direction
- Sparse matrix storage is the default global system representation.
- MKL direct solver is the first supported solver, but `LinearSolver` must allow future iterative solvers.
- Element stiffness and result recovery should be designed for type-specific batch kernels later, but not optimized before correctness evidence exists.
- MITC4 formulation should remain clear and reviewable until patch and reference comparisons pass.