src/lib/engine/procedures/construction.cpp

#include "gridfire/engine/procedures/construction.h"

#include <ranges>
#include <stdexcept>

#include "gridfire/reaction/reaction.h"
#include "gridfire/reaction/reaclib.h"

#include "fourdst/composition/composition.h"

#include "fourdst/logging/logging.h"

#include "quill/Logger.h"
#include "quill/LogMacros.h"

namespace gridfire {
    using reaction::LogicalReactionSet;
    using reaction::ReactionSet;
    using reaction::Reaction;
    using fourdst::composition::Composition;
    using fourdst::atomic::Species;


    LogicalReactionSet build_reaclib_nuclear_network(
        const Composition &composition,
        BuildDepthType maxLayers,
        bool reverse
    ) {
        int depth;
        if (std::holds_alternative<NetworkBuildDepth>(maxLayers)) {
            depth = static_cast<int>(std::get<NetworkBuildDepth>(maxLayers));
        } else {
            depth = std::get<int>(maxLayers);
        }
        auto logger = fourdst::logging::LogManager::getInstance().getLogger("log");
        if (depth == 0) {
            LOG_ERROR(logger, "Network build depth is set to 0. No reactions will be collected.");
            throw std::logic_error("Network build depth is set to 0. No reactions will be collected.");
        }

        const auto allReactions = reaclib::get_all_reactions();
        std::vector<Reaction> remainingReactions;
        for (const auto& reaction : allReactions) {
            if (reaction.is_reverse() == reverse) {
                remainingReactions.push_back(reaction);
            }
        }

        if (depth == static_cast<int>(NetworkBuildDepth::Full)) {
            LOG_INFO(logger, "Building full nuclear network with a total of {} reactions.", allReactions.size());
            const ReactionSet reactionSet(remainingReactions);
            return reaction::packReactionSetToLogicalReactionSet(reactionSet);
        }

        std::unordered_set<Species> availableSpecies;
        for (const auto &entry: composition | std::views::values) {
            if (entry.mass_fraction() > 0.0) {
                availableSpecies.insert(entry.isotope());
            }
        }


        std::vector<Reaction> collectedReactions;

        LOG_INFO(logger, "Starting network construction with {} available species.", availableSpecies.size());
        for (int layer = 0; layer < depth && !remainingReactions.empty(); ++layer) {
            LOG_TRACE_L1(logger, "Collecting reactions for layer {} with {} remaining reactions. Currently there are {} available species", layer, remainingReactions.size(), availableSpecies.size());
            std::vector<Reaction> reactionsForNextPass;
            std::unordered_set<Species> newProductsThisLayer;
            bool newReactionsAdded = false;

            reactionsForNextPass.reserve(remainingReactions.size());

            for (const auto &reaction : remainingReactions) {
                bool allReactantsAvailable = true;
                for (const auto& reactant : reaction.reactants()) {
                    if (!availableSpecies.contains(reactant)) {
                        allReactantsAvailable = false;
                        break;
                    }
                }

                if (allReactantsAvailable) {
                    collectedReactions.push_back(reaction);
                    newReactionsAdded = true;

                    for (const auto& product : reaction.products()) {
                        newProductsThisLayer.insert(product);
                    }
                } else {
                    reactionsForNextPass.push_back(reaction);
                }
            }

            if (!newReactionsAdded) {
                LOG_INFO(logger, "No new reactions added in layer {}. Stopping network construction with {} reactions collected.", layer, collectedReactions.size());
                break;
            }

            LOG_TRACE_L1(logger, "Layer {}: Collected {} reactions. New products this layer: {}", layer, collectedReactions.size(), newProductsThisLayer.size());
            availableSpecies.insert(newProductsThisLayer.begin(), newProductsThisLayer.end());

            remainingReactions = std::move(reactionsForNextPass);
        }

        LOG_INFO(logger, "Network construction completed with {} reactions collected.", collectedReactions.size());
        const ReactionSet reactionSet(collectedReactions);
        return reaction::packReactionSetToLogicalReactionSet(reactionSet);
    }


}
feat(GridFire): Much more robust starting network GraphEngine now can initialize with a much more robust set of reactions (including the entire reaction set). The jacobian can still be efficiently evaluated using CppAD's sparse jacobian feature. Further, the primeing network has been signifiganty enhanced to handle much hotter termperatures 2025-07-14 14:50:49 -04:00			`#include "gridfire/engine/procedures/construction.h"`

			`#include <ranges>`
			`#include <stdexcept>`

			`#include "gridfire/reaction/reaction.h"`
			`#include "gridfire/reaction/reaclib.h"`

			`#include "fourdst/composition/composition.h"`

			`#include "fourdst/logging/logging.h"`

			`#include "quill/Logger.h"`
			`#include "quill/LogMacros.h"`

			`namespace gridfire {`
			`using reaction::LogicalReactionSet;`
			`using reaction::ReactionSet;`
			`using reaction::Reaction;`
			`using fourdst::composition::Composition;`
			`using fourdst::atomic::Species;`


			`LogicalReactionSet build_reaclib_nuclear_network(`
			`const Composition &composition,`
			`BuildDepthType maxLayers,`
			`bool reverse`
			`) {`
			`int depth;`
			`if (std::holds_alternative<NetworkBuildDepth>(maxLayers)) {`
			`depth = static_cast<int>(std::get<NetworkBuildDepth>(maxLayers));`
			`} else {`
			`depth = std::get<int>(maxLayers);`
			`}`
			`auto logger = fourdst::logging::LogManager::getInstance().getLogger("log");`
			`if (depth == 0) {`
			`LOG_ERROR(logger, "Network build depth is set to 0. No reactions will be collected.");`
			`throw std::logic_error("Network build depth is set to 0. No reactions will be collected.");`
			`}`

			`const auto allReactions = reaclib::get_all_reactions();`
			`std::vector<Reaction> remainingReactions;`
			`for (const auto& reaction : allReactions) {`
			`if (reaction.is_reverse() == reverse) {`
			`remainingReactions.push_back(reaction);`
			`}`
			`}`

			`if (depth == static_cast<int>(NetworkBuildDepth::Full)) {`
			`LOG_INFO(logger, "Building full nuclear network with a total of {} reactions.", allReactions.size());`
			`const ReactionSet reactionSet(remainingReactions);`
			`return reaction::packReactionSetToLogicalReactionSet(reactionSet);`
			`}`

			`std::unordered_set<Species> availableSpecies;`
			`for (const auto &entry: composition \| std::views::values) {`
			`if (entry.mass_fraction() > 0.0) {`
			`availableSpecies.insert(entry.isotope());`
			`}`
			`}`


			`std::vector<Reaction> collectedReactions;`

			`LOG_INFO(logger, "Starting network construction with {} available species.", availableSpecies.size());`
			`for (int layer = 0; layer < depth && !remainingReactions.empty(); ++layer) {`
			`LOG_TRACE_L1(logger, "Collecting reactions for layer {} with {} remaining reactions. Currently there are {} available species", layer, remainingReactions.size(), availableSpecies.size());`
			`std::vector<Reaction> reactionsForNextPass;`
			`std::unordered_set<Species> newProductsThisLayer;`
			`bool newReactionsAdded = false;`

			`reactionsForNextPass.reserve(remainingReactions.size());`

			`for (const auto &reaction : remainingReactions) {`
			`bool allReactantsAvailable = true;`
			`for (const auto& reactant : reaction.reactants()) {`
			`if (!availableSpecies.contains(reactant)) {`
			`allReactantsAvailable = false;`
			`break;`
			`}`
			`}`

			`if (allReactantsAvailable) {`
			`collectedReactions.push_back(reaction);`
			`newReactionsAdded = true;`

			`for (const auto& product : reaction.products()) {`
			`newProductsThisLayer.insert(product);`
			`}`
			`} else {`
			`reactionsForNextPass.push_back(reaction);`
			`}`
			`}`

			`if (!newReactionsAdded) {`
			`LOG_INFO(logger, "No new reactions added in layer {}. Stopping network construction with {} reactions collected.", layer, collectedReactions.size());`
			`break;`
			`}`

			`LOG_TRACE_L1(logger, "Layer {}: Collected {} reactions. New products this layer: {}", layer, collectedReactions.size(), newProductsThisLayer.size());`
			`availableSpecies.insert(newProductsThisLayer.begin(), newProductsThisLayer.end());`

			`remainingReactions = std::move(reactionsForNextPass);`
			`}`

			`LOG_INFO(logger, "Network construction completed with {} reactions collected.", collectedReactions.size());`
			`const ReactionSet reactionSet(collectedReactions);`
			`return reaction::packReactionSetToLogicalReactionSet(reactionSet);`
			`}`



			`}`