Start work on algorithms in compiler post 10
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code/compiler/10/graph.hpp
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code/compiler/10/graph.hpp
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#pragma once
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#include <algorithm>
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#include <cstddef>
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#include <queue>
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#include <set>
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#include <string>
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#include <map>
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#include <memory>
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#include <vector>
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#include <iostream>
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using function = std::string;
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struct group {
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std::set<function> members;
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};
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using group_ptr = std::unique_ptr<group>;
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class function_graph {
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using group_id = size_t;
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struct group_data {
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std::set<function> functions;
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std::set<group_id> adjacency_list;
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size_t indegree;
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};
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using edge = std::pair<function, function>;
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using data_ptr = std::shared_ptr<group_data>;
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using group_edge = std::pair<group_id, group_id>;
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std::map<function, std::set<function>> adjacency_lists;
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std::set<edge> edges;
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std::set<edge> compute_transitive_edges();
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void create_groups(
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const std::set<edge>&,
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std::map<function, group_id>&,
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std::map<group_id, data_ptr>&);
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void create_edges(
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std::map<function, group_id>&,
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std::map<group_id, data_ptr>&);
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std::vector<group_ptr> generate_order(
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std::map<function, group_id>&,
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std::map<group_id, data_ptr>&);
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public:
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void add_edge(const function& from, const function& to);
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std::vector<group_ptr> compute_order();
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};
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std::set<function_graph::edge> function_graph::compute_transitive_edges() {
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std::set<edge> transitive_edges;
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transitive_edges.insert(edges.begin(), edges.end());
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for(auto& connector : adjacency_lists) {
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for(auto& from : adjacency_lists) {
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edge to_connector { from.first, connector.first };
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for(auto& to : adjacency_lists) {
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edge full_jump { from.first, to.first };
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if(transitive_edges.find(full_jump) != transitive_edges.end()) continue;
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edge from_connector { connector.first, to.first };
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if(transitive_edges.find(to_connector) != transitive_edges.end() &&
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transitive_edges.find(from_connector) != transitive_edges.end())
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transitive_edges.insert(std::move(full_jump));
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}
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}
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}
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return transitive_edges;
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}
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void function_graph::create_groups(
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const std::set<edge>& transitive_edges,
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std::map<function, group_id>& group_ids,
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std::map<group_id, data_ptr>& group_data_map) {
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group_id id_counter = 0;
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for(auto& vertex : adjacency_lists) {
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if(group_ids.find(vertex.first) != group_ids.end())
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continue;
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data_ptr new_group(new group_data);
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new_group->functions.insert(vertex.first);
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group_data_map[id_counter] = new_group;
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group_ids[vertex.first] = id_counter;
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for(auto& other_vertex : adjacency_lists) {
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if(transitive_edges.find({vertex.first, other_vertex.first}) != transitive_edges.end() &&
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transitive_edges.find({other_vertex.first, vertex.first}) != transitive_edges.end()) {
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group_ids[other_vertex.first] = id_counter;
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new_group->functions.insert(other_vertex.first);
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}
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}
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id_counter++;
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}
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}
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void function_graph::create_edges(
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std::map<function, group_id>& group_ids,
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std::map<group_id, data_ptr>& group_data_map) {
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std::set<std::pair<group_id, group_id>> group_edges;
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for(auto& vertex : adjacency_lists) {
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auto vertex_id = group_ids[vertex.first];
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auto& vertex_data = group_data_map[vertex_id];
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for(auto& other_vertex : vertex.second) {
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auto other_id = group_ids[other_vertex];
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if(vertex_id == other_id) continue;
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if(group_edges.find({vertex_id, other_id}) != group_edges.end())
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continue;
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group_edges.insert({vertex_id, other_id});
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vertex_data->adjacency_list.insert(other_id);
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group_data_map[other_id]->indegree++;
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}
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}
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}
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std::vector<group_ptr> function_graph::generate_order(
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std::map<function, group_id>& group_ids,
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std::map<group_id, data_ptr>& group_data_map) {
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std::queue<group_id> id_queue;
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std::vector<group_ptr> output;
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for(auto& group : group_data_map) {
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if(group.second->indegree == 0) id_queue.push(group.first);
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}
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while(!id_queue.empty()) {
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auto new_id = id_queue.front();
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auto& group_data = group_data_map[new_id];
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group_ptr output_group(new group);
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output_group->members = std::move(group_data->functions);
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id_queue.pop();
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for(auto& adjacent_group : group_data->adjacency_list) {
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if(--group_data_map[adjacent_group]->indegree == 0)
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id_queue.push(adjacent_group);
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}
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output.push_back(std::move(output_group));
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}
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return output;
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}
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void function_graph::add_edge(const function& from, const function& to) {
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auto adjacency_list_it = adjacency_lists.find(from);
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if(adjacency_list_it != adjacency_lists.end()) {
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adjacency_list_it->second.insert(to);
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} else {
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adjacency_lists[from] = { to };
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}
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edges.insert({ from, to });
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}
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std::vector<group_ptr> function_graph::compute_order() {
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std::set<edge> transitive_edges = compute_transitive_edges();
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std::map<function, group_id> group_ids;
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std::map<group_id, data_ptr> group_data_map;
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create_groups(transitive_edges, group_ids, group_data_map);
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create_edges(group_ids, group_data_map);
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return generate_order(group_ids, group_data_map);
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}
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@ -261,3 +261,85 @@ within a group does not matter.
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4. We typecheck the function groups, and functions within them, following the above topological order.
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4. We typecheck the function groups, and functions within them, following the above topological order.
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To find the transitive closure of a graph, we can use [Warshall's Algorithm](https://cs.winona.edu/lin/cs440/ch08-2.pdf).
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To find the transitive closure of a graph, we can use [Warshall's Algorithm](https://cs.winona.edu/lin/cs440/ch08-2.pdf).
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This algorithm, with complexity \\(O(|V|^3)\\), goes as follows:
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{{< latex >}}
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\begin{aligned}
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& A, R^{(i)} \in \mathbb{B}^{n \times n} \\
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& \\
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& R^{(0)} \leftarrow A \\
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& \textbf{for} \; k \leftarrow 1 \; \textbf{to} \; n \; \textbf{do} \\
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& \quad \textbf{for} \; i \leftarrow 1 \; \textbf{to} \; n \; \textbf{do} \\
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& \quad \quad \textbf{for} \; j \leftarrow 1 \; \textbf{to} \; n \; \textbf{do} \\
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& \quad \quad \quad R^{(k)}[i,j] \leftarrow R^{(k-1)}[i,j] \; \textbf{or} \; R^{(k-1)}[i,k] \; \textbf{and} \; R^{(k-1)}[k,j] \\
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& \textbf{return} \; R^{(n)}
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\end{aligned}
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{{< /latex >}}
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In the above notation, \\(R^{(i)}\\) is the \\(i\\)th matrix \\(R\\), and \\(A\\) is the adjacency
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matrix of the graph in question. All matrices in the algorithm are from \\(\\mathbb{B}^{n \times n}\\),
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the set of \\(n\\) by \\(n\\) boolean matrices. Once this algorithm is complete, we get as output a
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transitive closure adjacency matrix \\(R^{(n)}\\). Mutually dependent functions will be pretty easy to
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isolate from this matrix. If \\(R^{(n)}[i,j]\\) and \\(R^{(n)}[j,i]\\), then the functions represented by vertices
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\\(i\\) and \\(j\\) depend on each other.
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Once we've identified the groups, and
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{{< sidenote "right" "group-graph-note" "constructed a group graph," >}}
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This might seem like a "draw the rest of the owl" situation, but it really isn't.
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We'll follow a naive algorithm for findings groups, and for translating function dependencies
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into group dependencies. This algorithm, in C++, will be presented later on.
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{{< /sidenote >}} it is time to compute the topological order. For this, we will use
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[Kahn's Algorithm](https://en.wikipedia.org/wiki/Topological_sorting#Kahn's_algorithm).
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The algorithm goes as follows:
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{{< latex >}}
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\begin{aligned}
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& L \leftarrow \text{empty list} \\
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& S \leftarrow \text{set of all nodes with no incoming edges} \\
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& \\
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& \textbf{while} \; S \; \text{is non-empty} \; \textbf{do} \\
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& \quad \text{remove a node} \; n \; \text{from} \; S \\
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& \quad \text{add} \; n \; \text{to the end of} \; L \\
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& \quad \textbf{for each} \; \text{node} \; m \; \text{with edge} \;
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e \; \text{from} \; n \; \text{to} \; m \; \textbf{do} \\
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& \quad \quad \text{remove edge} \; e \; \text{from the graph} \\
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& \quad \quad \textbf{if} \; m \; \text{has no other incoming edges} \; \textbf{then} \\
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& \quad \quad \quad \text{insert} \; m \; \text{into} \; S \\
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& \\
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& \textbf{if} \; \text{the graph has edges} \; \textbf{then} \\
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& \quad \textbf{return} \; \text{error} \quad \textit{(graph has at least once cycle)} \\
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& \textbf{else} \\
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& \quad \textbf{return} \; L \quad \textit{(a topologically sorted order)}
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\end{aligned}
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{{< /latex >}}
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Note that since we've already isolated all mutually dependent functions into
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groups, our graph will never have cycles, and this algorithm will always succeed.
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Also note that since we start with nodes with no incoming edges, our list will
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__begin with the groups that should be checked last__. This is because a node
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with no incoming edges might (and probably does) still have outgoing edges,
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and thus depends on other functions / groups. Like in our successful example,
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we want to __typecheck functions that are depended on first__.
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### Implementation
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Let's start working on a C++ implementation of all of this now. First,
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I think that we should create a C++ class that will represent our function
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dependency graph. Let's call it `function_graph`. I propose the following
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definition:
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{{< codelines "C++" "compiler/10/graph.hpp" 12 51 >}}
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There's a lot to unpack here. First of all, we create a type alias `function` that
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represents the label of a function in our graph. It is probably most convenient
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to work with `std::string` instances, so we settle for that. Next, we define
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a struct that will represent a single group of mutually dependent functions.
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Passing this struct by value seems wrong, so we'll settle for a C++ `unique_pt`
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to help carry instances around.
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Finally, we arrive at the definition of `function_graph`. Inside this class,
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we define a helper struct, `group_data`, which holds information
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about an individual group as it is being constructed. This information
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includes the group's adjacency list and
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[indegree](https://en.wikipedia.org/wiki/Directed_graph#Indegree_and_outdegree)
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(both used for Kahn's topological sorting algorithm), as well as the set
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of functions in the group (which we will eventually return).
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