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gridfire::MultiscalePartitioningEngineView Class Referencefinal
An engine view that partitions the reaction network into multiple groups based on timescales. More...
#include <engine_multiscale.h>
Inheritance diagram for gridfire::MultiscalePartitioningEngineView:
Collaboration diagram for gridfire::MultiscalePartitioningEngineView:
Classes | |
| struct | CacheStats |
| Struct for tracking cache statistics. More... | |
| struct | EigenFunctor |
| Functor for solving QSE abundances using Eigen's nonlinear optimization. More... | |
| struct | QSEGroup |
| Struct representing a QSE group. More... | |
Public Member Functions | |
| MultiscalePartitioningEngineView (DynamicEngine &baseEngine) | |
| Constructs a MultiscalePartitioningEngineView. | |
| const std::vector< fourdst::atomic::Species > & | getNetworkSpecies () const override |
| Gets the list of species in the network. | |
| std::expected< StepDerivatives< double >, expectations::StaleEngineError > | calculateRHSAndEnergy (const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Calculates the right-hand side (dY/dt) and energy generation. | |
| EnergyDerivatives | calculateEpsDerivatives (const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Calculate the derivatives of the energy generation rate with respect to T and rho. | |
| void | generateJacobianMatrix (const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Generates the Jacobian matrix for the current state. | |
| void | generateJacobianMatrix (const fourdst::composition::Composition &comp, double T9, double rho, const std::vector< fourdst::atomic::Species > &activeSpecies) const override |
| Generates the Jacobian matrix for a subset of active species. | |
| void | generateJacobianMatrix (const fourdst::composition::Composition &comp, double T9, double rho, const SparsityPattern &sparsityPattern) const override |
| Generates the Jacobian matrix using a sparsity pattern. | |
| double | getJacobianMatrixEntry (const fourdst::atomic::Species &rowSpecies, const fourdst::atomic::Species &colSpecies) const override |
| Gets an entry from the previously generated Jacobian matrix. | |
| void | generateStoichiometryMatrix () override |
| Generates the stoichiometry matrix for the network. | |
| int | getStoichiometryMatrixEntry (const fourdst::atomic::Species &species, const reaction::Reaction &reaction) const override |
| Gets an entry from the stoichiometry matrix. | |
| double | calculateMolarReactionFlow (const reaction::Reaction &reaction, const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Calculates the molar reaction flow for a given reaction. | |
| const reaction::ReactionSet & | getNetworkReactions () const override |
| Gets the set of logical reactions in the network. | |
| void | setNetworkReactions (const reaction::ReactionSet &reactions) override |
| Sets the set of logical reactions in the network. | |
| std::expected< std::unordered_map< fourdst::atomic::Species, double >, expectations::StaleEngineError > | getSpeciesTimescales (const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Computes timescales for all species in the network. | |
| std::expected< std::unordered_map< fourdst::atomic::Species, double >, expectations::StaleEngineError > | getSpeciesDestructionTimescales (const fourdst::composition::Composition &comp, double T9, double rho) const override |
| Computes destruction timescales for all species in the network. | |
| fourdst::composition::Composition | update (const NetIn &netIn) override |
| Updates the internal state of the engine, performing partitioning and QSE equilibration. | |
| bool | isStale (const NetIn &netIn) override |
| Checks if the engine's internal state is stale relative to the provided conditions. | |
| void | setScreeningModel (screening::ScreeningType model) override |
| Sets the electron screening model. | |
| screening::ScreeningType | getScreeningModel () const override |
| Gets the current electron screening model. | |
| const DynamicEngine & | getBaseEngine () const override |
| Gets the base engine. | |
| std::vector< std::vector< fourdst::atomic::Species > > | analyzeTimescalePoolConnectivity (const std::vector< std::vector< fourdst::atomic::Species > > ×cale_pools, const fourdst::composition::Composition &comp, double T9, double rho) const |
| Analyzes the connectivity of timescale pools. | |
| void | partitionNetwork (const fourdst::composition::Composition &comp, double T9, double rho) |
| Partitions the network into dynamic and algebraic (QSE) groups based on timescales. | |
| void | partitionNetwork (const NetIn &netIn) |
Partitions the network based on timescales from a NetIn struct. | |
| void | exportToDot (const std::string &filename, const fourdst::composition::Composition &comp, double T9, double rho) const |
| Exports the network to a DOT file for visualization. | |
| size_t | getSpeciesIndex (const fourdst::atomic::Species &species) const override |
| Gets the index of a species in the full network. | |
| std::vector< double > | mapNetInToMolarAbundanceVector (const NetIn &netIn) const override |
Maps a NetIn struct to a molar abundance vector for the full network. | |
| PrimingReport | primeEngine (const NetIn &netIn) override |
| Primes the engine with a specific species. | |
| std::vector< fourdst::atomic::Species > | getFastSpecies () const |
| Gets the fast species in the network. | |
| const std::vector< fourdst::atomic::Species > & | getDynamicSpecies () const |
| Gets the dynamic species in the network. | |
| fourdst::composition::Composition | equilibrateNetwork (const fourdst::composition::Composition &comp, double T9, double rho) |
| Equilibrates the network by partitioning and solving for QSE abundances. | |
| fourdst::composition::Composition | equilibrateNetwork (const NetIn &netIn) |
Equilibrates the network using QSE from a NetIn struct. | |
| bool | involvesSpecies (const fourdst::atomic::Species &species) const |
| bool | involvesSpeciesInQSE (const fourdst::atomic::Species &species) const |
| bool | involvesSpeciesInDynamic (const fourdst::atomic::Species &species) const |
| fourdst::composition::Composition | collectComposition (fourdst::composition::Composition &comp) const override |
| Collect the composition from this and sub engines. | |
 Public Member Functions inherited from gridfire::DynamicEngine | |
| virtual BuildDepthType | getDepth () const |
| Get the depth of the network. | |
| virtual void | rebuild (const fourdst::composition::Composition &comp, BuildDepthType depth) |
| Rebuild the network with a specified depth. | |
| Public Member Functions inherited from gridfire::Engine | |
| virtual | ~Engine ()=default |
| Virtual destructor. | |
| Public Member Functions inherited from gridfire::EngineView< DynamicEngine > | |
| virtual | ~EngineView ()=default |
| Virtual destructor. | |
Private Types | |
| typedef std::tuple< std::vector< fourdst::atomic::Species >, std::vector< size_t >, std::vector< fourdst::atomic::Species >, std::vector< size_t > > | QSEPartition |
| Type alias for a QSE partition. | |
Private Member Functions | |
| std::vector< std::vector< fourdst::atomic::Species > > | partitionByTimescale (const fourdst::composition::Composition &comp, double T9, double rho) const |
| Partitions the network by timescale. | |
| std::pair< std::vector< MultiscalePartitioningEngineView::QSEGroup >, std::vector< MultiscalePartitioningEngineView ::QSEGroup > > | validateGroupsWithFluxAnalysis (const std::vector< QSEGroup > &candidate_groups, const fourdst::composition::Composition &comp, double T9, double rho) const |
| Validates candidate QSE groups using flux analysis. | |
| fourdst::composition::Composition | solveQSEAbundances (const fourdst::composition::Composition &comp, double T9, double rho) |
| Solves for the QSE abundances of the algebraic species in a given state. | |
| size_t | identifyMeanSlowestPool (const std::vector< std::vector< fourdst::atomic::Species > > &pools, const fourdst::composition::Composition &comp, double T9, double rho) const |
| Identifies the pool with the slowest mean timescale. | |
| std::unordered_map< fourdst::atomic::Species, std::vector< fourdst::atomic::Species > > | buildConnectivityGraph (const std::vector< fourdst::atomic::Species > &species_pool) const |
| Builds a connectivity graph from a species pool. | |
| std::vector< QSEGroup > | constructCandidateGroups (const std::vector< std::vector< fourdst::atomic::Species > > &candidate_pools, const fourdst::composition::Composition &comp, double T9, double rho) const |
| Constructs candidate QSE groups from connected timescale pools. | |
Private Attributes | |
| quill::Logger * | m_logger = LogManager::getInstance().getLogger("log") |
| Logger instance for logging messages. | |
| DynamicEngine & | m_baseEngine |
| The base engine to which this view delegates calculations. | |
| std::vector< QSEGroup > | m_qse_groups |
| The list of identified equilibrium groups. | |
| std::vector< fourdst::atomic::Species > | m_dynamic_species |
| The simplified set of species presented to the solver (the "slow" species). | |
| std::vector< fourdst::atomic::Species > | m_algebraic_species |
| Species that are treated as algebraic (in QSE) in the QSE groups. | |
| std::unordered_map< fourdst::atomic::Species, double > | m_algebraic_abundances |
| Map from species to their calculated abundances in the QSE state. | |
| std::vector< size_t > | m_activeSpeciesIndices |
| Indices of all species considered active in the current partition (dynamic + algebraic). | |
| std::vector< size_t > | m_activeReactionIndices |
| Indices of all reactions involving only active species. | |
| std::unordered_map< QSECacheKey, std::vector< double > > | m_qse_abundance_cache |
| Cache for QSE abundances based on T9, rho, and Y. | |
| CacheStats | m_cacheStats |
| Statistics for the QSE abundance cache. | |
Detailed Description
An engine view that partitions the reaction network into multiple groups based on timescales.
- Purpose
- This class is designed to accelerate the integration of stiff nuclear reaction networks. It identifies species that react on very short timescales ("fast" species) and treats them as being in Quasi-Steady-State Equilibrium (QSE). Their abundances are solved for algebraically, removing their stiff differential equations from the system. The remaining "slow" or "dynamic" species are integrated normally. This significantly improves the stability and performance of the solver.
- How
- The core logic resides in the
partitionNetwork()andequilibrateNetwork()methods. The partitioning process involves:- Timescale Analysis: Using
getSpeciesDestructionTimescalesfrom the base engine, all species are sorted by their characteristic timescales. - Gap Detection: The sorted list of timescales is scanned for large gaps (e.g., several orders of magnitude) to create distinct "timescale pools".
- Connectivity Analysis: Each pool is analyzed for internal reaction connectivity to form cohesive groups.
- Flux Validation: Candidate QSE groups are validated by comparing the total reaction flux within the group to the flux leaving the group. A high internal-to-external flux ratio indicates a valid QSE group.
- QSE Solve: For valid QSE groups,
solveQSEAbundancesuses a Levenberg-Marquardt nonlinear solver (Eigen::LevenbergMarquardt) to find the equilibrium abundances of the "algebraic" species, holding the "seed" species constant.
- Timescale Analysis: Using
All calculations are cached using QSECacheKey to avoid re-partitioning and re-solving for similar thermodynamic conditions.
- Usage Example:
- // 1. Create a base engine (e.g., GraphEngine)gridfire::GraphEngine baseEngine(composition);// 2. Wrap it with the MultiscalePartitioningEngineViewgridfire::MultiscalePartitioningEngineView multiscaleEngine(baseEngine);// 3. Before integration, update the view to partition the network// and find the initial equilibrium state.NetIn initialConditions = { .composition = composition, .temperature = 1e8, .density = 1e3 };fourdst::composition::Composition equilibratedComp = multiscaleEngine.update(initialConditions);// 4. Use the multiscaleEngine for integration. It will use the cached QSE solution.// The integrator will call calculateRHSAndEnergy, etc. on the multiscaleEngine.auto Y_initial = multiscaleEngine.mapNetInToMolarAbundanceVector({equilibratedComp, ...});auto derivatives = multiscaleEngine.calculateRHSAndEnergy(Y_initial, T9, rho);A reaction network engine that uses a graph-based representation.Definition engine_graph.h:99An engine view that partitions the reaction network into multiple groups based on timescales.Definition engine_multiscale.h:180Definition network.h:51
<DynamicEngine>
Member Typedef Documentation
◆ QSEPartition
|
private |
Type alias for a QSE partition.
A QSE partition is a tuple containing the fast species, their indices, the slow species, and their indices.
Constructor & Destructor Documentation
◆ MultiscalePartitioningEngineView()
|
explicit |
Constructs a MultiscalePartitioningEngineView.
- Parameters
-
baseEngine The underlying GraphEngine to which this view delegates calculations. It must be a GraphEngineand not a more generalDynamicEnginebecause this view relies on its specific implementation details.
Member Function Documentation
◆ analyzeTimescalePoolConnectivity()
| std::vector< std::vector< Species > > gridfire::MultiscalePartitioningEngineView::analyzeTimescalePoolConnectivity | ( | const std::vector< std::vector< fourdst::atomic::Species > > & | timescale_pools, |
| const fourdst::composition::Composition & | comp, | ||
| double | T9, | ||
| double | rho ) const |
Analyzes the connectivity of timescale pools.
- Parameters
-
timescale_pools A vector of vectors of species indices, where each inner vector represents a timescale pool. comp Vector of current molar abundances for the full network. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A vector of vectors of species indices, where each inner vector represents a single connected component.
- Purpose
- To merge timescale pools that are strongly connected by reactions, forming cohesive groups for QSE analysis.
- How
- For each pool, it builds a reaction connectivity graph using
buildConnectivityGraph. It then finds the connected components within that graph using a Breadth-First Search (BFS). The resulting components from all pools are collected and returned.
◆ buildConnectivityGraph()
|
private |
Builds a connectivity graph from a species pool.
- Parameters
-
species_pool A vector of species indices representing a species pool.
- Returns
- An unordered map representing the adjacency list of the connectivity graph.
- Purpose
- To find reaction connections within a specific group of species.
- How
- It iterates through all reactions in the base engine. If a reaction involves at least two distinct species from the input
species_pool(one as a reactant and one as a product), it adds edges between all reactants and products from that reaction that are also in the pool.
◆ calculateEpsDerivatives()
|
nodiscardoverridevirtual |
Calculate the derivatives of the energy generation rate with respect to T and rho.
- Parameters
-
comp Composition object containing current abundances. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- EnergyDerivatives containing dEps/dT and dEps/dRho.
This method computes the partial derivatives of the specific nuclear energy generation rate with respect to temperature and density for the current state.
Implements gridfire::DynamicEngine.
◆ calculateMolarReactionFlow()
|
nodiscardoverridevirtual |
Calculates the molar reaction flow for a given reaction.
- Parameters
-
reaction The reaction for which to calculate the flow. comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- Molar flow rate for the reaction (e.g., mol/g/s).
- Purpose
- To compute the net rate of a single reaction.
- How
- It first checks the QSE cache. On a hit, it retrieves the cached equilibrium abundances for the algebraic species. It creates a mutable copy of
Y_full, overwrites the algebraic species abundances with the cached equilibrium values, and then calls the base engine'scalculateMolarReactionFlowwith this modified abundance vector.
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Exceptions
-
StaleEngineError If the QSE cache misses.
Implements gridfire::DynamicEngine.
◆ calculateRHSAndEnergy()
|
nodiscardoverridevirtual |
Calculates the right-hand side (dY/dt) and energy generation.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A
std::expectedcontainingStepDerivatives<double>on success, or aStaleEngineErrorif the engine's QSE cache does not contain a solution for the given state.
- Purpose
- To compute the time derivatives for the ODE solver. This implementation modifies the derivatives from the base engine to enforce the QSE condition.
- How
- It first performs a lookup in the QSE abundance cache (
m_qse_abundance_cache). If a cache hit occurs, it calls the base engine'scalculateRHSAndEnergy. It then manually sets the time derivatives (dydt) of all identified algebraic species to zero, effectively removing their differential equations from the system being solved.
- Precondition
- The engine must have been updated via
update()orequilibrateNetwork()for the current thermodynamic conditions, so that a valid entry exists in the QSE cache.
- Postcondition
- The returned derivatives will have
dydt=0for all algebraic species.
- Exceptions
-
StaleEngineError If the QSE cache does not contain an entry for the given (T9, rho, Y_full). This indicates update()was not called recently enough.
Implements gridfire::Engine.
◆ collectComposition()
|
overridevirtual |
Collect the composition from this and sub engines.
This method operates by injecting the current equilibrium abundances for algebraic species into the composition object so that they can be bubbled up to the caller.
- Parameters
-
comp Input Composition
- Returns
- New composition which is comp + any edits from lower levels + the equilibrium abundances of all algebraic species.
- Exceptions
-
BadCollectionError if there is a species in the algebraic species set which does not show up in the reported composition from the base engine.:w
Implements gridfire::DynamicEngine.
◆ constructCandidateGroups()
|
private |
Constructs candidate QSE groups from connected timescale pools.
- Parameters
-
candidate_pools A vector of vectors of species indices, where each inner vector represents a connected pool of species with similar fast timescales. comp Vector of current molar abundances. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A vector of
QSEGroupstructs, ready for flux validation.
- How
- For each input pool, it identifies "bridge" reactions that connect the pool to species outside the pool. The reactants of these bridge reactions that are not in the pool are identified as "seed" species. The original pool members are the "algebraic" species. It then bundles the seed and algebraic species into a
QSEGroupstruct.
- Precondition
- The
candidate_poolsshould be connected components fromanalyzeTimescalePoolConnectivity.
- Postcondition
- A list of candidate
QSEGroupobjects is returned.
◆ equilibrateNetwork() [1/2]
| fourdst::composition::Composition gridfire::MultiscalePartitioningEngineView::equilibrateNetwork | ( | const fourdst::composition::Composition & | comp, |
| double | T9, | ||
| double | rho ) |
Equilibrates the network by partitioning and solving for QSE abundances.
- Parameters
-
comp Vector of current molar abundances for the full network. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A new composition object with the equilibrated abundances.
- Purpose
- A convenience method to run the full QSE analysis and get an equilibrated composition object as a result.
- How
- It first calls
partitionNetwork()with the given state to define the QSE groups. Then, it callssolveQSEAbundances()to compute the new equilibrium abundances for the algebraic species. Finally, it packs the resulting full abundance vector into a newfourdst::composition::Compositionobject and returns it.
- Precondition
- The input state (Y, T9, rho) must be a valid physical state.
- Postcondition
- The engine's internal partition is updated. A new composition object is returned.
◆ equilibrateNetwork() [2/2]
| fourdst::composition::Composition gridfire::MultiscalePartitioningEngineView::equilibrateNetwork | ( | const NetIn & | netIn | ) |
Equilibrates the network using QSE from a NetIn struct.
- Parameters
-
netIn A struct containing the current network input.
- Returns
- The equilibrated composition.
- Purpose
- A convenience overload for
equilibrateNetwork.
- How
- It unpacks the
netInstruct intoY,T9, andrhoand then calls the primaryequilibrateNetworkmethod.
◆ exportToDot()
| void gridfire::MultiscalePartitioningEngineView::exportToDot | ( | const std::string & | filename, |
| const fourdst::composition::Composition & | comp, | ||
| double | T9, | ||
| double | rho ) const |
Exports the network to a DOT file for visualization.
- Parameters
-
filename The name of the DOT file to create. comp Composition object T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Purpose
- To visualize the partitioned network graph.
- How
- This method delegates the DOT file export to the base engine. It does not currently add any partitioning information to the output graph.
◆ generateJacobianMatrix() [1/3]
|
overridevirtual |
Generates the Jacobian matrix for the current state.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Purpose
- To compute the Jacobian matrix required by implicit ODE solvers.
- How
- It first performs a QSE cache lookup. On a hit, it delegates the full Jacobian calculation to the base engine. While this view could theoretically return a modified, sparser Jacobian reflecting the QSE constraints, the current implementation returns the full Jacobian from the base engine. The solver is expected to handle the algebraic constraints (e.g., via
dydt=0fromcalculateRHSAndEnergy).
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Postcondition
- The base engine's internal Jacobian is updated.
- Exceptions
-
exceptions::StaleEngineError If the QSE cache misses, as it cannot proceed without a valid partition.
Implements gridfire::DynamicEngine.
◆ generateJacobianMatrix() [2/3]
|
overridevirtual |
Generates the Jacobian matrix using a sparsity pattern.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3. sparsityPattern The sparsity pattern to use for the Jacobian.
- Purpose
- To compute the Jacobian matrix while leveraging a known sparsity pattern for efficiency. This is effectively a lower level version of the active species method.
- How
- It first checks the QSE cache. On a hit, it delegates to the base engine's
generateJacobianMatrixmethod with the provided sparsity pattern.
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Postcondition
- The base engine's internal Jacobian is updated according to the sparsity pattern.
- Exceptions
-
exceptions::StaleEngineError If the QSE cache misses.
Implements gridfire::DynamicEngine.
◆ generateJacobianMatrix() [3/3]
|
overridevirtual |
Generates the Jacobian matrix for a subset of active species.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3. activeSpecies The subset of species to include in the Jacobian.
- Purpose
- To compute a reduced Jacobian matrix for implicit solvers that only consider a subset of species.
- How
- Similar to the full Jacobian generation, it first checks the QSE cache. On a hit, it calls the base engine's
generateJacobianMatrixwith the specified active species. The returned Jacobian still reflects the full network, but only for the active species subset.
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Postcondition
- The base engine's internal Jacobian is updated for the active species.
- Exceptions
-
exceptions::StaleEngineError If the QSE cache misses.
Implements gridfire::DynamicEngine.
◆ generateStoichiometryMatrix()
|
overridevirtual |
Generates the stoichiometry matrix for the network.
- Purpose
- To prepare the stoichiometry matrix for later queries.
- How
- This method delegates directly to the base engine's
generateStoichiometryMatrix(). The stoichiometry is based on the full, unpartitioned network.
Implements gridfire::DynamicEngine.
◆ getBaseEngine()
|
overridevirtual |
Gets the base engine.
- Returns
- A const reference to the base engine.
Implements gridfire::EngineView< DynamicEngine >.
◆ getDynamicSpecies()
|
nodiscard |
Gets the dynamic species in the network.
- Returns
- A const reference to the vector of species identified as "dynamic" or "slow".
- Purpose
- To allow external queries of the partitioning results.
- How
- It returns a const reference to the
m_dynamic_speciesmember vector.
- Precondition
partitionNetwork()must have been called.
◆ getFastSpecies()
|
nodiscard |
Gets the fast species in the network.
- Returns
- A vector of species identified as "fast" or "algebraic" by the partitioning.
- Purpose
- To allow external queries of the partitioning results.
- How
- It returns a copy of the
m_algebraic_speciesmember vector.
- Precondition
partitionNetwork()must have been called.
◆ getJacobianMatrixEntry()
|
nodiscardoverridevirtual |
Gets an entry from the previously generated Jacobian matrix.
- Parameters
-
rowSpecies Species corresponding to the row index (i_full). colSpecies Species corresponding to the column index (j_full).
- Returns
- Value of the Jacobian matrix at (i_full, j_full).
- Purpose
- To provide Jacobian entries to an implicit solver.
- How
- This method directly delegates to the base engine's
getJacobianMatrixEntry. It does not currently modify the Jacobian to reflect the QSE algebraic constraints, as these are handled by settingdY/dt = 0incalculateRHSAndEnergy.
- Precondition
generateJacobianMatrix()must have been called for the current state.
Implements gridfire::DynamicEngine.
◆ getNetworkReactions()
|
nodiscardoverridevirtual |
Gets the set of logical reactions in the network.
- Returns
- A const reference to the
LogicalReactionSetfrom the base engine, containing all reactions in the full network.
Implements gridfire::DynamicEngine.
◆ getNetworkSpecies()
|
nodiscardoverridevirtual |
Gets the list of species in the network.
- Returns
- A const reference to the vector of
Speciesobjects representing all species in the underlying base engine. This view does not alter the species list itself, only how their abundances are evolved.
Implements gridfire::Engine.
◆ getScreeningModel()
|
nodiscardoverridevirtual |
Gets the current electron screening model.
- Returns
- The currently active screening model type.
- How
- This method delegates directly to the base engine's
getScreeningModel().
Implements gridfire::DynamicEngine.
◆ getSpeciesDestructionTimescales()
|
nodiscardoverridevirtual |
Computes destruction timescales for all species in the network.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A
std::expectedcontaining a map fromSpeciesto their characteristic destruction timescales (s) on success, or aStaleEngineErroron failure.
- Purpose
- To get the timescale for species destruction, which is used as the primary metric for network partitioning.
- How
- It delegates the calculation to the base engine. For any species identified as algebraic (in QSE), it manually sets their timescale to 0.0.
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Exceptions
-
StaleEngineError If the QSE cache misses.
Implements gridfire::DynamicEngine.
◆ getSpeciesIndex()
|
nodiscardoverridevirtual |
Gets the index of a species in the full network.
- Parameters
-
species The species to get the index of.
- Returns
- The index of the species in the base engine's network.
- How
- This method delegates directly to the base engine's
getSpeciesIndex().
Implements gridfire::DynamicEngine.
◆ getSpeciesTimescales()
|
nodiscardoverridevirtual |
Computes timescales for all species in the network.
- Parameters
-
comp The current composition. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A
std::expectedcontaining a map fromSpeciesto their characteristic timescales (s) on success, or aStaleEngineErroron failure.
- Purpose
- To get the characteristic timescale
Y / (dY/dt)for each species.
- How
- It delegates the calculation to the base engine. For any species identified as algebraic (in QSE), it manually sets their timescale to 0.0 to signify that they equilibrate instantaneously on the timescale of the solver.
- Precondition
- The engine must have a valid QSE cache entry for the given state.
- Exceptions
-
StaleEngineError If the QSE cache misses.
Implements gridfire::DynamicEngine.
◆ getStoichiometryMatrixEntry()
|
nodiscardoverridevirtual |
Gets an entry from the stoichiometry matrix.
- Parameters
-
species Species to look up stoichiometry for. reaction Reaction to find.
- Returns
- Stoichiometric coefficient for the species in the reaction.
- Purpose
- To query the stoichiometric relationship between a species and a reaction.
- How
- This method delegates directly to the base engine's
getStoichiometryMatrixEntry().
- Precondition
generateStoichiometryMatrix()must have been called.
Implements gridfire::DynamicEngine.
◆ identifyMeanSlowestPool()
|
private |
Identifies the pool with the slowest mean timescale.
- Parameters
-
pools A vector of vectors of species indices, where each inner vector represents a timescale pool. comp Vector of current molar abundances for the full network. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- The index of the pool with the largest (slowest) mean destruction timescale.
- Purpose
- To identify the core set of dynamic species that will not be part of any QSE group.
- How
- It calculates the geometric mean of the destruction timescales for all species in each pool and returns the index of the pool with the maximum mean timescale.
◆ involvesSpecies()
| bool gridfire::MultiscalePartitioningEngineView::involvesSpecies | ( | const fourdst::atomic::Species & | species | ) | const |
◆ involvesSpeciesInDynamic()
| bool gridfire::MultiscalePartitioningEngineView::involvesSpeciesInDynamic | ( | const fourdst::atomic::Species & | species | ) | const |
◆ involvesSpeciesInQSE()
| bool gridfire::MultiscalePartitioningEngineView::involvesSpeciesInQSE | ( | const fourdst::atomic::Species & | species | ) | const |
◆ isStale()
|
overridevirtual |
Checks if the engine's internal state is stale relative to the provided conditions.
- Parameters
-
netIn A struct containing the current network input.
- Returns
trueif the engine is stale,falseotherwise.
- Purpose
- To determine if
update()needs to be called.
- How
- It creates a
QSECacheKeyfrom thenetIndata and checks for its existence in them_qse_abundance_cache. A cache miss indicates the engine is stale because it does not have a valid QSE partition for the current conditions. It also queries the base engine'sisStale()method.
Implements gridfire::DynamicEngine.
◆ mapNetInToMolarAbundanceVector()
|
nodiscardoverridevirtual |
Maps a NetIn struct to a molar abundance vector for the full network.
- Parameters
-
netIn A struct containing the current network input.
- Returns
- A vector of molar abundances corresponding to the species order in the base engine.
- How
- This method delegates directly to the base engine's
mapNetInToMolarAbundanceVector().
Implements gridfire::DynamicEngine.
◆ partitionByTimescale()
|
private |
Partitions the network by timescale.
- Parameters
-
comp Vector of current molar abundances for all species. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A vector of vectors of species indices, where each inner vector represents a timescale pool.
- Purpose
- To group species into "pools" based on their destruction timescales.
- How
- It retrieves all species destruction timescales from the base engine, sorts them, and then iterates through the sorted list, creating a new pool whenever it detects a gap between consecutive timescales that is larger than a predefined threshold (e.g., a factor of 100).
◆ partitionNetwork() [1/2]
| void gridfire::MultiscalePartitioningEngineView::partitionNetwork | ( | const fourdst::composition::Composition & | comp, |
| double | T9, | ||
| double | rho ) |
Partitions the network into dynamic and algebraic (QSE) groups based on timescales.
- Parameters
-
comp Vector of current molar abundances for the full network. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Purpose
- To perform the core partitioning logic that identifies which species are "fast" (and can be treated algebraically) and which are "slow" (and must be integrated dynamically).
@how
partitionByTimescale: Gets species destruction timescales from the base engine, sorts them, and looks for large gaps to create timescale "pools".identifyMeanSlowestPool: The pool with the slowest average timescale is designated as the core set of dynamic species.analyzeTimescalePoolConnectivity: The other (faster) pools are analyzed for reaction connectivity to form cohesive groups.constructCandidateGroups: These connected groups are processed to identify "seed" species (dynamic species that feed the group) and "algebraic" species (the rest).validateGroupsWithFluxAnalysis: The groups are validated by ensuring their internal reaction flux is much larger than the flux connecting them to the outside network.
- Precondition
- The input state (Y, T9, rho) must be a valid physical state.
- Postcondition
- The internal member variables
m_qse_groups,m_dynamic_species, andm_algebraic_species(and their index maps) are populated with the results of the partitioning.
◆ partitionNetwork() [2/2]
| void gridfire::MultiscalePartitioningEngineView::partitionNetwork | ( | const NetIn & | netIn | ) |
Partitions the network based on timescales from a NetIn struct.
- Parameters
-
netIn A struct containing the current network input.
- Purpose
- A convenience overload for
partitionNetwork.
- How
- It unpacks the
netInstruct intoY,T9, andrhoand then calls the primarypartitionNetworkmethod.
◆ primeEngine()
|
nodiscardoverridevirtual |
Primes the engine with a specific species.
- Parameters
-
netIn A struct containing the current network input.
- Returns
- A
PrimingReportstruct containing information about the priming process.
- Purpose
- To prepare the network for ignition or specific pathway studies.
- How
- This method delegates directly to the base engine's
primeEngine(). The multiscale view does not currently interact with the priming process.
Implements gridfire::DynamicEngine.
◆ setNetworkReactions()
|
overridevirtual |
Sets the set of logical reactions in the network.
- Parameters
-
reactions The set of logical reactions to use.
- Purpose
- To modify the reaction network.
- How
- This operation is not supported by the
MultiscalePartitioningEngineViewas it would invalidate the partitioning logic. It logs a critical error and throws an exception. Network modifications should be done on the base engine before it is wrapped by this view.
- Exceptions
-
exceptions::UnableToSetNetworkReactionsError Always.
Implements gridfire::DynamicEngine.
◆ setScreeningModel()
|
overridevirtual |
Sets the electron screening model.
- Parameters
-
model The type of screening model to use for reaction rate calculations.
- How
- This method delegates directly to the base engine's
setScreeningModel().
Implements gridfire::DynamicEngine.
◆ solveQSEAbundances()
|
private |
Solves for the QSE abundances of the algebraic species in a given state.
- Parameters
-
comp Vector of current molar abundances for all species in the base engine. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A vector of molar abundances for the algebraic species.
- Purpose
- To find the equilibrium abundances of the algebraic species that satisfy the QSE conditions.
- How
- It uses the Levenberg-Marquardt algorithm via Eigen's
LevenbergMarquardtclass. The problem is defined by theEigenFunctorwhich computes the residuals and Jacobian for the QSE equations.
- Precondition
- The input state (Y_full, T9, rho) must be a valid physical state.
- Postcondition
- The algebraic species in the QSE cache are updated with the new equilibrium abundances.
◆ update()
|
overridevirtual |
Updates the internal state of the engine, performing partitioning and QSE equilibration.
- Parameters
-
netIn A struct containing the current network input: temperature, density, and composition.
- Returns
- The new composition after QSE species have been brought to equilibrium.
- Purpose
- This is the main entry point for preparing the multiscale engine for use. It triggers the network partitioning and solves for the initial QSE abundances, caching the result.
@how
- It first checks the QSE cache. If a valid entry already exists for the input state, it returns the input composition, as no work is needed.
- If the cache misses, it calls
equilibrateNetwork(). equilibrateNetwork()in turn callspartitionNetwork()to define the dynamic and algebraic species sets.- It then calls
solveQSEAbundances()to compute the equilibrium abundances. - The resulting equilibrium abundances for the algebraic species are stored in the
m_qse_abundance_cache. - A new
fourdst::composition::Compositionobject reflecting the equilibrated state is created and returned.
- Precondition
- The
netInstruct should contain a valid physical state.
- Postcondition
- The engine is partitioned (
m_dynamic_species,m_algebraic_species, etc. are populated). Them_qse_abundance_cacheis populated with the QSE solution for the given state. The returned composition reflects the new equilibrium.
Implements gridfire::DynamicEngine.
◆ validateGroupsWithFluxAnalysis()
|
private |
Validates candidate QSE groups using flux analysis.
- Parameters
-
candidate_groups A vector of candidate QSE groups. comp Vector of current molar abundances for the full network. T9 Temperature in units of 10^9 K. rho Density in g/cm^3.
- Returns
- A vector of validated QSE groups that meet the flux criteria.
- Purpose
- To ensure that a candidate QSE group is truly in equilibrium by checking that the reaction fluxes within the group are much larger than the fluxes leaving the group.
- How
- For each candidate group, it calculates the sum of all internal reaction fluxes and the sum of all external (bridge) reaction fluxes. If the ratio of internal to external flux exceeds a configurable threshold, the group is considered valid and is added to the returned vector.
Member Data Documentation
◆ m_activeReactionIndices
|
private |
Indices of all reactions involving only active species.
◆ m_activeSpeciesIndices
|
private |
Indices of all species considered active in the current partition (dynamic + algebraic).
◆ m_algebraic_abundances
|
private |
Map from species to their calculated abundances in the QSE state.
◆ m_algebraic_species
|
private |
Species that are treated as algebraic (in QSE) in the QSE groups.
◆ m_baseEngine
|
private |
The base engine to which this view delegates calculations.
◆ m_cacheStats
|
mutableprivate |
Statistics for the QSE abundance cache.
◆ m_dynamic_species
|
private |
The simplified set of species presented to the solver (the "slow" species).
◆ m_logger
|
private |
Logger instance for logging messages.
◆ m_qse_abundance_cache
|
mutableprivate |
Cache for QSE abundances based on T9, rho, and Y.
- Purpose
- This is the core of the caching mechanism. It stores the results of QSE solves to avoid re-computation. The key is a
QSECacheKeywhich hashes the thermodynamic state, and the value is the vector of solved molar abundances for the algebraic species.
◆ m_qse_groups
|
private |
The list of identified equilibrium groups.
The documentation for this class was generated from the following files:
- src/include/gridfire/engine/views/engine_multiscale.h
- src/lib/engine/views/engine_multiscale.cpp
