ReactionSystems/src/rsprocess/presets.rs

//! Module that holds useful presets for interacting with other modules.

use lalrpop_util::ParseError;
use petgraph::Graph;
use std::collections::HashMap;
use std::env;
use std::fmt::Display;
use std::fs;
use std::io;
use std::io::prelude::*;
use std::rc::Rc;

use super::graph::MapEdges;
use super::set::Set;
use super::system::ExtensionsSystem;
use super::translator::Translator;
use super::*;

use super::super::grammar;

// -----------------------------------------------------------------------------
//                                 Structures
// -----------------------------------------------------------------------------

/// Describes how the result of some computation has to be saved.
pub struct SaveOptions {
    pub print: bool,
    pub save: Option<Vec<String>>,
}

impl SaveOptions {
    pub fn combine(&mut self, other: &mut Self) {
        self.print = self.print || other.print;
        match (self.save.is_some(), other.save.is_some()) {
            (false, false) | (true, false) => {}
            (false, true) => {
                self.save = other.save.to_owned();
            }
            (true, true) => {
                self.save
                    .as_mut()
                    .unwrap()
                    .append(other.save.as_mut().unwrap());
            }
        }
    }
    pub fn new() -> Self {
        SaveOptions {
            print: false,
            save: None,
        }
    }
}

impl Default for SaveOptions {
    fn default() -> Self {
        SaveOptions::new()
    }
}

// Describes output options for a graph.
pub enum GraphSaveOptions {
    Dot {
        node_display: graph::NodeDisplay,
        edge_display: graph::EdgeDisplay,
        node_color: graph::NodeColor,
        edge_color: graph::EdgeColor,
        so: SaveOptions,
    },
    GraphML {
        node_display: graph::NodeDisplay,
        edge_display: graph::EdgeDisplay,
        so: SaveOptions,
    },
    Serialize {
        path: String,
    },
}

/// Describes the computation to apply to the input system or graph.
pub enum Instruction {
    Stats {
        so: SaveOptions,
    },
    Target {
        so: SaveOptions,
    },
    Run {
        so: SaveOptions,
    },
    Loop {
        symbol: String,
        so: SaveOptions,
    },
    Frequency {
        so: SaveOptions,
    },
    LimitFrequency {
        experiment: String,
        so: SaveOptions,
    },
    FastFrequency {
        experiment: String,
        so: SaveOptions,
    },
    Digraph {
        group: Option<Box<assert::grouping::Assert>>,
        gso: Vec<GraphSaveOptions>,
    },
    Bisimilarity {
        system_b: String,
        edge_relabeler: Box<assert::relabel::Assert>,
        so: SaveOptions,
    },
}

/// Describes a system or a graph.
#[derive(Clone)]
pub enum System {
    Deserialize { path: String },
    System { sys: system::System },
}

impl System {
    /// Deserialize the graph if applicable.
    pub fn compute(
        &self,
        translator: Translator,
    ) -> Result<EvaluatedSystem, String> {
        match self {
            Self::System { sys } => Ok(EvaluatedSystem::System {
                sys: sys.to_owned(),
                translator,
            }),
            Self::Deserialize { path } => {
                let (graph, translator) = deserialize(path.into())?;
                Ok(EvaluatedSystem::Graph { graph, translator })
            }
        }
    }
}

#[derive(Clone)]
pub enum EvaluatedSystem {
    Graph {
        graph: graph::SystemGraph,
        translator: Translator,
    },
    System {
        sys: system::System,
        translator: Translator,
    },
}

impl EvaluatedSystem {
    pub fn get_translator(&mut self) -> &mut Translator {
        match self {
            EvaluatedSystem::Graph {
                graph: _,
                translator,
            } => translator,
            EvaluatedSystem::System { sys: _, translator } => translator,
        }
    }
}

/// Holds all the computations to be done on the system
pub struct Instructions {
    pub system: System,
    pub instructions: Vec<Instruction>,
}

// -----------------------------------------------------------------------------
//                            IO Helper Functions
// -----------------------------------------------------------------------------

fn read_file<T, F>(
    translator: &mut Translator,
    path_string: String,
    parser: F,
) -> Result<T, String>
where
    F: Fn(&mut Translator, String) -> Result<T, String>,
{
    // relative path
    let mut path = match env::current_dir() {
        Ok(p) => p,
        Err(e) => return Err(format!("Error getting current directory: {e}")),
    };
    path = path.join(path_string);

    // we read the file with a buffer
    let f = match fs::File::open(path) {
        Ok(f) => f,
        Err(e) => return Err(format!("Error opening file: {e}.")),
    };
    let mut buf_reader = io::BufReader::new(f);
    let mut contents = String::new();
    match buf_reader.read_to_string(&mut contents) {
        Ok(_) => {}
        Err(e) => return Err(format!("Error reading file: {e}")),
    }

    // parse
    let result = parser(translator, contents)?;

    Ok(result)
}

fn reformat_error<T, S>(
    e: ParseError<usize, T, &'static str>,
    input_str: &str,
) -> Result<S, String>
where
    T: Display,
{
    match e {
        ParseError::ExtraToken { token: (l, t, r) } => Err(format!(
            "Unexpected token \"{t}\" \
         between positions {l} and {r}."
        )),
        ParseError::UnrecognizedEof {
            location: _,
            expected: _,
        } => Err("End of file encountered while parsing.".into()),
        ParseError::InvalidToken { location } => {
            Err(format!("Invalid token at position {location}."))
        }
        ParseError::UnrecognizedToken {
            token: (l, t, r),
            expected,
        } => {
            use colored::Colorize;

            let mut err = format!(
                "Unrecognized token {}{}{} \
                 between positions {l} and {r}.",
                "\"".red(),
                t.to_string().red(),
                "\"".red(),
            );

            // Temporary debug.
            err.push_str("Expected: ");
            let mut it = expected.iter().peekable();
            while let Some(s) = it.next() {
                err.push('(');
                err.push_str(&format!("{}", s.green()));
                err.push(')');
                if it.peek().is_some() {
                    err.push(',');
                    err.push(' ');
                }
            }
            let right_new_line = input_str[l..]
                .find("\n")
                .map(|pos| pos + l)
                .unwrap_or(input_str.len());
            let left_new_line = input_str[..r]
                .rfind("\n")
                .map(|pos| pos + 1)
                .unwrap_or_default();

            let line_number = input_str[..l].match_indices('\n').count() + 1;
            let pre_no_color = format!("{line_number} |");
            let pre = format!("{}", pre_no_color.blue());

            let line_pos_l = l - left_new_line;
            let line_pos_r = r - left_new_line;

            err.push_str(&format!(
                "\nLine {} position {} to {}:\n{}{}{}{}",
                line_number,
                line_pos_l,
                line_pos_r,
                &pre,
                &input_str[left_new_line..l].green(),
                &input_str[l..r].red(),
                &input_str[r..right_new_line],
            ));
            err.push('\n');
            err.push_str(&" ".repeat(pre_no_color.len() - 1));
            err.push_str(&format!("{}", "|".blue()));
            err.push_str(&" ".repeat(l - left_new_line));
            err.push_str(&format!("{}", &"↑".red()));
            if r - l > 2 {
                err.push_str(&" ".repeat(r - l - 2));
                err.push_str(&format!("{}", &"↑".red()));
            }

            Err(err)
        }
        ParseError::User { error } => Err(error.to_string()),
    }
}

fn parser_experiment(
    translator: &mut Translator,
    contents: String,
) -> Result<(Vec<u32>, Vec<Set>), String> {
    match grammar::ExperimentParser::new().parse(translator, &contents) {
        Ok(sys) => Ok(sys),
        Err(e) => reformat_error(e, &contents),
    }
}

fn parser_instructions(
    translator: &mut Translator,
    contents: String,
) -> Result<Instructions, String> {
    match grammar::RunParser::new().parse(translator, &contents) {
        Ok(sys) => Ok(sys),
        Err(e) => reformat_error(e, &contents),
    }
}

fn save_file(contents: &String, path_string: String) -> Result<(), String> {
    // relative path
    let mut path = match env::current_dir() {
        Ok(p) => p,
        Err(_) => return Err("Error getting current directory.".into()),
    };
    path = path.join(path_string);

    let mut f = match fs::File::create(&path) {
        Ok(f) => f,
        Err(_) => {
            return Err(format!(
                "Error creating file {}.",
                path.to_str().unwrap()
            ));
        }
    };
    match write!(f, "{contents}") {
        Ok(_) => {}
        Err(_) => return Err("Error writing to file.".into()),
    }
    Ok(())
}

// -----------------------------------------------------------------------------
//                                  main_do
// -----------------------------------------------------------------------------

/// Prints statistics of the system.
/// Equivalent main_do(stat) or main_do(stat, MissingE)
pub fn stats(system: &EvaluatedSystem) -> Result<String, String> {
    match system {
        EvaluatedSystem::System { sys, translator } => {
            Ok(sys.statistics(translator))
        }
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            Ok(sys.statistics(translator))
        }
    }
}

/// Prints a final set of entities in a terminating Reaction System.
/// The system needs to terminate to return.
/// Equivalent to main_do(target, E)
pub fn target(system: &EvaluatedSystem) -> Result<String, String> {
    let (res, translator) = match system {
        EvaluatedSystem::System { sys, translator } => {
            (sys.target()?, translator)
        }
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            (sys.target()?, translator)
        }
    };
    Ok(format!(
        "After {} steps we arrive at state:\n{}",
        res.0,
        translator::Formatter::from(translator, &res.1)
    ))
}

/// Finds the list of traversed states in a (deterministic) terminating
/// reaction.
/// The system needs to terminate to return.
/// equivalent to main_do(run,Es)
pub fn traversed(system: &EvaluatedSystem) -> Result<String, String> {
    let (res, translator) = match system {
        EvaluatedSystem::System { sys, translator } => {
            (sys.run_separated()?, translator)
        }
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            (sys.run_separated()?, translator)
        }
    };

    let mut output = String::new();

    output.push_str("The trace is composed by the set of entities: ");
    for (e, _c, _t) in res {
        output.push_str(&format!(
            "{}",
            translator::Formatter::from(translator, &e)
        ));
    }
    Ok(output)
}

/// Finds the looping list of states in a reaction system with a perpetual
/// context. IMPORTANT: for loops, we assume Delta defines the process constant
/// x = Q.x and the context process is x .
/// equivalent to main_do(loop,Es)
pub fn hoop(
    system: &EvaluatedSystem,
    symbol: String,
) -> Result<String, String> {
    use system::LoopSystem;

    let (res, translator) = match system {
        EvaluatedSystem::System { sys, translator } => (sys, translator),
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            (sys, translator)
        }
    };
    // we retrieve the id for "x" and use it to find the corresponding loop
    let Some(id) = translator.encode_not_mut(&symbol) else {
        return Err(format!("Symbol {symbol} not found."));
    };
    let res = match res.lollipops_only_loop_named(id) {
        Some(o) => o,
        None => {
            return Err("No loop found.".into());
        }
    };

    let mut output = String::new();

    output.push_str("The loop is composed by the sets: ");
    for e in res {
        output.push_str(&format!(
            "{}",
            translator::Formatter::from(translator, &e)
        ));
    }

    Ok(output)
}

/// Finds the frequency of each entity in the traversed states for a
/// (deterministic) terminating Reaction System.
/// equivalent to main_do(freq, PairList)
pub fn freq(system: &EvaluatedSystem) -> Result<String, String> {
    use frequency::BasicFrequency;

    let (sys, translator) = match system {
        EvaluatedSystem::System { sys, translator } => (sys, translator),
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            (sys, translator)
        }
    };

    let res = frequency::Frequency::naive_frequency(sys)?;

    Ok(format!(
        "Frequency of encountered symbols:\n{}",
        translator::Formatter::from(translator, &res)
    ))
}

/// Finds the frequency of each entity in the limit loop of a nonterminating
/// Reaction System whose context has the form Q1 ... Q1.Q2 ... Q2 ... Qn ...
/// equivalent to main_do(limitfreq, PairList)
pub fn limit_freq(
    system: &mut EvaluatedSystem,
    experiment: String,
) -> Result<String, String> {
    use frequency::BasicFrequency;

    let (sys, translator): (&system::System, &mut Translator) = match system {
        EvaluatedSystem::System { sys, translator } => (sys, translator),
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph.".into());
            };
            (sys, translator)
        }
    };

    let (_, sets) = read_file(translator, experiment, parser_experiment)?;

    let res = match frequency::Frequency::limit_frequency(
        &sets,
        &sys.reaction_rules,
        &sys.available_entities,
    ) {
        Some(e) => e,
        None => {
            return Err("Error calculating frequency.".into());
        }
    };

    Ok(format!(
        "Frequency of encountered symbols:\n{}",
        translator::Formatter::from(translator, &res)
    ))
}

/// Finds the frequency of each entity in the traversed loops of a terminating
/// reaction system whose context has the form
/// Q1 ... Q1.Q2 ... Q2 ... Qn ... Qn.nil and each Qi is repeated Wi times
/// read from a corresponding file.
/// equivalent to main_do(fastfreq, PairList)
pub fn fast_freq(
    system: &mut EvaluatedSystem,
    experiment: String,
) -> Result<String, String> {
    use frequency::BasicFrequency;

    let (sys, translator): (&system::System, &mut Translator) = match system {
        EvaluatedSystem::System { sys, translator } => (sys, translator),
        EvaluatedSystem::Graph { graph, translator } => {
            let Some(sys) = graph.node_weights().next() else {
                return Err("No node found in graph".into());
            };
            (sys, translator)
        }
    };

    let (weights, sets) = read_file(translator, experiment, parser_experiment)?;

    let res = match frequency::Frequency::fast_frequency(
        &sets,
        &sys.reaction_rules,
        &sys.available_entities,
        &weights,
    ) {
        Some(e) => e,
        None => {
            return Err("Error calculating frequency.".into());
        }
    };

    Ok(format!(
        "Frequency of encountered symbols:\n{}",
        translator::Formatter::from(translator, &res)
    ))
}

/// Computes the LTS.
/// equivalent to main_do(digraph, Arcs) or to main_do(advdigraph, Arcs)
pub fn digraph(system: &mut EvaluatedSystem) -> Result<(), String> {
    if let EvaluatedSystem::System { sys, translator } = system {
        *system = EvaluatedSystem::Graph {
            graph: sys.digraph()?,
            translator: translator.to_owned(),
        };
    }
    Ok(())
}

pub fn grouping(
    system: &mut EvaluatedSystem,
    group: &assert::grouping::Assert,
) -> Result<(), String> {
    let mut buckets = HashMap::new();
    let mut leader: HashMap<petgraph::prelude::NodeIndex, _> = HashMap::new();

    if let EvaluatedSystem::Graph { graph, translator } = system {
        for node in graph.node_indices() {
            let val = group.execute(graph, &node, translator)?;
            buckets.entry(val.clone()).or_insert(vec![]).push(node);
            let l = buckets.get(&val).unwrap().first().unwrap();
            leader.insert(node, (*l, val));
        }

        for node in graph.node_indices().rev() {
            let (origin, val) = leader.get(&node).unwrap();
            if *origin == node {
                continue;
            }
            if buckets.get(val).unwrap().len() <= 1 {
                continue;
            }

            let mut edges =
                graph.neighbors_directed(node, petgraph::Outgoing).detach();
            while let Some(edge) = edges.next_edge(graph) {
                graph.add_edge(
                    *origin,
                    graph.edge_endpoints(edge).unwrap().1,
                    graph.edge_weight(edge).unwrap().clone(),
                );
            }
            let mut edges =
                graph.neighbors_directed(node, petgraph::Incoming).detach();
            while let Some(edge) = edges.next_edge(graph) {
                graph.add_edge(
                    graph.edge_endpoints(edge).unwrap().0,
                    *origin,
                    graph.edge_weight(edge).unwrap().clone(),
                );
            }
            graph
                .remove_node(node)
                .ok_or(format!("Could not remove node {node:?}"))?;
        }

        Ok(())
    } else {
        Err("Grouping can be done only on graphs.".into())
    }
}

/// Computes bisimularity of two provided systems
pub fn bisimilar(
    system_a: &mut EvaluatedSystem,
    edge_relabeler: &assert::relabel::Assert,
    system_b: String,
) -> Result<String, String> {
    use assert::relabel::AssertReturnValue;

    let system_b = read_file(
        system_a.get_translator(),
        system_b.to_string(),
        parser_instructions,
    )?;
    let mut system_b = match system_b
        .system
        .compute(system_a.get_translator().clone())?
    {
        EvaluatedSystem::System { sys, translator } => {
            EvaluatedSystem::System { sys, translator }
        }
        EvaluatedSystem::Graph { graph, translator } => {
            if translator != *system_a.get_translator() {
                return Err("Bisimilarity not implemented for systems with \
                different encodings. Serialize the systems \
                with the same translator."
                    .into());
            }
            EvaluatedSystem::Graph { graph, translator }
        }
    };

    digraph(system_a)?;
    digraph(&mut system_b)?;

    // since we ran digraph on both they have to be graphs
    match (system_a, &mut system_b) {
        (
            EvaluatedSystem::Graph {
                graph: a,
                translator: _,
            },
            EvaluatedSystem::Graph {
                graph: b,
                translator: translator_b,
            },
        ) => {
            let a: Graph<system::System, AssertReturnValue> =
                a.map_edges(edge_relabeler, translator_b)?;
            let b: Graph<system::System, AssertReturnValue> =
                b.map_edges(edge_relabeler, translator_b)?;
            Ok(format!(
                "{}",
                // bisimilarity::bisimilarity_kanellakis_smolka::bisimilarity(&&a, &&b)
                // bisimilarity::bisimilarity_paige_tarjan::bisimilarity_ignore_labels(&&a, &&b)
                bisimilarity::bisimilarity_paige_tarkan::bisimilarity(&&a, &&b)
            ))
        }
        _ => {
            unreachable!()
        }
    }
}

// -----------------------------------------------------------------------------
//                              Output Functions
// -----------------------------------------------------------------------------

/// Writes the specified graph to a file in .dot format.
pub fn dot(
    system: &EvaluatedSystem,
    node_display: graph::NodeDisplay,
    edge_display: graph::EdgeDisplay,
    node_color: graph::NodeColor,
    edge_color: graph::EdgeColor,
) -> Result<String, String> {
    match system {
        EvaluatedSystem::System {
            sys: _,
            translator: _,
        } => Err("Supplied system is not a graph".into()),
        EvaluatedSystem::Graph { graph, translator } => {
            let rc_translator = Rc::new(translator.clone());
            let modified_graph = graph.map(
                node_display.generate(Rc::clone(&rc_translator), graph),
                edge_display.generate(Rc::clone(&rc_translator), graph),
            );

            let graph = Rc::new(graph.to_owned());

            let node_formatter = node_color
                .generate(Rc::clone(&graph), translator.encode_not_mut("*"));
            let edge_formatter = edge_color.generate(Rc::clone(&graph));

            let dot = dot::Dot::with_attr_getters(
                &modified_graph,
                &[],
                &edge_formatter,
                &node_formatter,
            );

            Ok(format!("{dot}"))
        }
    }
}

/// Writes the specified graph to a file in .graphml format.
pub fn graphml(
    system: &EvaluatedSystem,
    node_display: graph::NodeDisplay,
    edge_display: graph::EdgeDisplay,
) -> Result<String, String> {
    match system {
        EvaluatedSystem::System {
            sys: _,
            translator: _,
        } => Err("Supplied system is not a graph".into()),
        EvaluatedSystem::Graph { graph, translator } => {
            let rc_translator = Rc::new(translator.to_owned());

            // map each value to the corresponding value we want to display
            let modified_graph = graph.map(
                node_display.generate(Rc::clone(&rc_translator), graph),
                edge_display.generate(rc_translator, graph),
            );

            use petgraph_graphml::GraphMl;
            let graphml = GraphMl::new(&modified_graph)
                .pretty_print(true)
                .export_node_weights_display()
                .export_edge_weights_display();

            Ok(format!("{graphml}"))
        }
    }
}

/// Writes the specified graph, translator tuple to file.
/// N.B. graph size in memory might be much larger after serialization and
/// deserialization.
pub fn serialize(system: &EvaluatedSystem, path: String) -> Result<(), String> {
    match system {
        EvaluatedSystem::System {
            sys: _,
            translator: _,
        } => Err("Supplied system is not a graph".into()),
        EvaluatedSystem::Graph { graph, translator } => {
            // relative path
            let mut path = std::path::PathBuf::from(path);
            path.set_extension("cbor");

            let f = match fs::File::create(&path) {
                Ok(f) => f,
                Err(_) => {
                    return Err(format!(
                        "Error creating file {}.",
                        path.to_str().unwrap()
                    ));
                }
            };

            match serialize::ser(f, graph, translator) {
                Ok(_) => Ok(()),
                Err(_) => Err("Error during serialization.".into()),
            }
        }
    }
}

/// Reads the specified serialized system from a file.
/// N.B. graph size in memory might be much larger after serialization and
/// deserialization
pub fn deserialize(
    input_path: String,
) -> Result<(graph::SystemGraph, Translator), String> {
    // relative path
    let mut path = match env::current_dir() {
        Ok(p) => p,
        Err(_) => return Err("Error getting current directory.".into()),
    };
    path = path.join(input_path);
    path.set_extension("cbor");

    let f = match fs::File::open(&path) {
        Ok(f) => f,
        Err(_) => {
            return Err(format!(
                "Error opening file {}.",
                path.to_str().unwrap()
            ));
        }
    };

    match serialize::de(f) {
        Ok(a) => Ok(a),
        Err(_) => Err("Error during deserialization.".into()),
    }
}

//------------------------------------------------------------------------------
//                         Interpreting Instructions
//------------------------------------------------------------------------------

macro_rules! save_options {
    ($assignment: expr, $so: ident) => {
        let SaveOptions { print, save } = $so;
        let output = $assignment;
        if print {
            println!("{output}");
        }
        if let Some(save) = save {
            for file in save {
                save_file(&output, file)?;
            }
        }
    };
}

fn execute(
    instruction: Instruction,
    system: &mut EvaluatedSystem,
) -> Result<(), String> {
    match instruction {
        Instruction::Stats { so } => {
            save_options!(stats(system)?, so);
        }
        Instruction::Target { so } => {
            save_options!(target(system)?, so);
        }
        Instruction::Run { so } => {
            save_options!(traversed(system)?, so);
        }
        Instruction::Loop { symbol, so } => {
            save_options!(hoop(system, symbol)?, so);
        }
        Instruction::Frequency { so } => {
            save_options!(freq(system)?, so);
        }
        Instruction::LimitFrequency { experiment, so } => {
            save_options!(limit_freq(system, experiment)?, so);
        }
        Instruction::FastFrequency { experiment, so } => {
            save_options!(fast_freq(system, experiment)?, so);
        }
        Instruction::Digraph { group, gso } => {
            let mut graph = system.clone();
            digraph(&mut graph)?;
            if let Some(group) = group {
                group.typecheck()?;
                grouping(&mut graph, &group)?;
            }
            for save in gso {
                match save {
                    GraphSaveOptions::Dot {
                        node_display: nd,
                        edge_display: ed,
                        node_color: nc,
                        edge_color: ec,
                        so,
                    } => {
                        save_options!(dot(&graph, nd, ed, nc, ec)?, so);
                    }
                    GraphSaveOptions::GraphML {
                        node_display: nd,
                        edge_display: ed,
                        so,
                    } => {
                        save_options!(graphml(&graph, nd, ed)?, so);
                    }
                    GraphSaveOptions::Serialize { path } => {
                        serialize(&graph, path)?;
                    }
                }
            }
        }
        Instruction::Bisimilarity {
            system_b,
            edge_relabeler,
            so,
        } => {
            edge_relabeler.typecheck()?;
            save_options!(bisimilar(system, &edge_relabeler, system_b)?, so);
        }
    }
    Ok(())
}

/// Interprets file at supplied path, then executes the code specified as
/// instructions inside the file.
pub fn run(path: String) -> Result<(), String> {
    let mut translator = Translator::new();

    let Instructions {
        system,
        instructions,
    } = read_file(&mut translator, path, parser_instructions)?;

    let mut system = system.compute(translator)?;

    for instr in instructions {
        execute(instr, &mut system)?;
    }

    Ok(())
}