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#include "grammer.h"
#include "debug.h"
#include <algorithm>
#include <limits>
using namespace Gram;
void Compiler::clear()
{
symbol_variants.clear();
nodes.clear();
}
std::string Compiler::GetTypeOfNode(index_t node_id) const
{
if (node_id >= nodes.size())
throw std::runtime_error("GetTypeOfNode(): node_id="s + std::to_string(node_id) + ", nodes.size()="s + std::to_string(nodes.size()));
return nodes[node_id].type;
}
bool Gram::ChildIdIsEmpty(int32_t child_id)
{
return child_id == 0;
}
bool Gram::ChildIdIsToken(int32_t child_id)
{
return child_id < 0;
}
bool Gram::ChildIdIsNode(int32_t child_id)
{
return child_id > 0;
}
index_t Gram::TokenIdFromChildId(int32_t child_id)
{
return index_t(-child_id) - 1;
}
int32_t Gram::ChildIdFromTokenId(index_t token_id)
{
return -1 - int32_t(token_id);
}
void Compiler::DumpTree()
{
Debug("= Dump =======================================");
Debug("nodes.size()="s + std::to_string(nodes.size()));
if (nodes.size() > 0) {
if (0) {
Debug("--- Nodes ------------------------------------");
for (const auto& node : nodes) {
std::string line{"("s + std::to_string(node.node_id) + "):"s};
for (const auto& child : node.child_ids) {
line += " "s;
if (ChildIdIsToken(child))
line += "t"s + std::to_string(TokenIdFromChildId(child));
else
line += std::to_string(child);
}
Debug(line);
}
}
Debug("--- Tree -------------------------------------");
std::deque<std::pair<int32_t, size_t>> todo{std::pair<int32_t, size_t>{static_cast<int32_t>(0), 0}}; // id, indent
while (!todo.empty()) {
auto [current_index, indent] {todo.front()};
todo.pop_front();
std::string line(indent, ' ');
if (ChildIdIsToken(current_index)) {
index_t token_id {TokenIdFromChildId(current_index)};
line += "Token("s + std::to_string(token_id) + "): "s + tokens[token_id].type;
if (tokens[token_id].value != tokens[token_id].type)
line += "("s + tokens[token_id].value + ")"s;
} else {
auto& node {nodes[current_index]};
line += "Node("s + std::to_string(current_index) + "): "s + node.type + "/" + std::to_string(node.variant);
auto child_ids{node.child_ids};
for (int i = 0; i < child_ids.size(); i++) {
todo.insert(todo.begin() + i, std::pair<int32_t, size_t>{child_ids[i], indent + 1});
}
}
Debug(line);
}
}
Debug("==============================================");
}
index_t Compiler::AddNode(const std::string& type, index_t variant, NodePosition pos)
{
auto& list { m_bnf[type][variant]};
index_t node_id{nodes.size()};
if (nodes.size() > 0)
nodes[pos.node_id].child_ids[pos.child_pos] = node_id;
nodes.emplace_back(TreeNode{pos, node_id, type, variant, std::vector<int32_t>(size_t(list.size()), 0)});
return node_id;
}
Compiler::AddNodeGuard::AddNodeGuard(Compiler& compiler, index_t variant): m_compiler(compiler)
{
m_compiler.symbol_variants.push_back(variant);
}
Compiler::AddNodeGuard::~AddNodeGuard()
{
m_compiler.symbol_variants.pop_back();
}
void Compiler::IncNodePosition(NodePosition& pos)
{
if (nodes.size() == 0) // special case: empty tree
return;
if (pos.node_id >= nodes.size())
throw std::runtime_error("ICE: NodePosition with node_id "s + std::to_string(pos.node_id) + " doesn't exist."s);
if (pos.child_pos >= nodes[pos.node_id].child_ids.size())
throw std::runtime_error("ICE: NodePosition with child_pos "s + std::to_string(pos.child_pos) + " in node_id "s + std::to_string(pos.node_id) + " doesn't exist."s);
int32_t child_id{nodes[pos.node_id].child_ids[pos.child_pos]};
if (ChildIdIsEmpty(child_id))
throw std::runtime_error("ICE: NodePosition is empty");
// Actually, advance
if (ChildIdIsToken(child_id)) {
pos.child_pos++;
} else {
pos.node_id = child_id;
pos.child_pos = 0;
}
// Go to parent if child ids completely traversed
while (pos.node_id > 0 && pos.child_pos >= nodes[pos.node_id].child_ids.size()) {
pos = nodes[pos.node_id].pos;
pos.child_pos++;
}
// Advancing at root node for last child is allowed: Finished
if (pos.child_pos >= nodes[pos.node_id].child_ids.size())
return;
if (ChildIdIsNode(nodes[pos.node_id].child_ids[pos.child_pos]))
throw std::runtime_error("ICE: No node expected at "s + std::to_string(pos.node_id) + "/"s + std::to_string(pos.child_pos));
}
size_t Compiler::minimumSymbolsNeeded(const std::string& symbol)
{
if (isTerminal(m_bnf, symbol)) {
return 1;
} else {
auto it_min{m_min.find(symbol)};
if (it_min != m_min.end())
return it_min->second;
m_min[symbol] = std::numeric_limits<size_t>::max();
auto it{m_bnf.find(symbol)};
if (it != m_bnf.end()) {
size_t minimum{std::numeric_limits<size_t>::max()};
for (const auto& list: it->second) {
minimum = std::min(minimum, minimumSymbolsNeeded(list));
}
m_min[symbol] = minimum;
return minimum;
} else
throw std::runtime_error("ICE: Symbol "s + symbol + " expected in BNF"s);
}
}
size_t Compiler::minimumSymbolsNeeded(const std::vector<std::string>& symbol_list)
{
size_t result{0};
for (const auto& symbol: symbol_list) {
size_t min { minimumSymbolsNeeded(symbol) };
if (min == std::numeric_limits<size_t>::max())
return min;
result += min;
}
return result;
}
/// begin, end: indexes in tokens list
bool Compiler::match(std::vector<std::string> symbol_list, size_t begin, size_t end)
{
// match terminal symbols at start
while (begin < end && symbol_list.size() > 0 && symbol_list.front() == tokens[begin].type) {
begin++;
symbol_list.erase(symbol_list.begin());
}
// matching of empty list in non-terminals
if (symbol_list.size() == 0) {
if (begin == end) { // only match real empty list
// this is the point of the final match
constructTree();
return true;
}
return false;
}
// matching of empty list in terminals
if (begin == end) {
const auto& symbol{symbol_list.front()};
auto it{m_empty_lut.find(symbol)};
if (it == m_empty_lut.end()) // can't match empty tokens list with this nt-symbol
return false;
AddNodeGuard guard(*this, it->second);
std::vector<std::string> list {m_bnf[symbol][it->second]};
list.insert(list.end(), symbol_list.begin() + 1, symbol_list.end());
return match(list, begin, end);
}
// now, symbol_list has size > 0 and contains non-terminal symbols at start and end
// resolve first symbol
auto it = m_match_lut.find({symbol_list.front(), tokens[begin].type});
if (it != m_match_lut.end()) {
for (size_t i: it->second) {
AddNodeGuard guard(*this, i);
std::vector<std::string> list {m_bnf[symbol_list.front()][i]};
list.insert(list.end(), symbol_list.begin() + 1, symbol_list.end());
if (minimumSymbolsNeeded(list) > end - begin) // stop recursion
continue;
if (match(list, begin, end))
return true;
}
} else
return false; // terminal symbol not found in bnf, non-matching
return false; // no match found
}
bool Compiler::match(std::string symbol, size_t begin, size_t end)
{
std::vector<std::string> symbol_list{symbol};
return match(symbol_list, begin, end);
}
void Compiler::fillStartCache()
{
std::unordered_set<std::string> terminals {getTerminals(m_bnf)};
{ // follow terminal symbols
for (const std::string& terminal: terminals) {
std::unordered_set<std::string> current_set{terminal};
std::unordered_set<std::string> done_set;
std::unordered_set<std::string> next_set;
do {
for (const auto& current_symbol: current_set) {
auto it {reversedPosFirst.find(current_symbol)};
if (it != reversedPosFirst.end()) {
std::unordered_set<std::pair<std::string, index_t>, PairHash>& positions{it->second};
for (const auto& position: positions) {
auto it_lut {m_match_lut.find({position.first, terminal})};
if (it_lut == m_match_lut.end()) { // add new list
m_match_lut[std::pair<std::string, std::string>{position.first, terminal}] = std::vector<size_t>{position.second};
} else { // extend list
it_lut->second.emplace_back(position.second);
}
if (done_set.find(position.first) == done_set.end()) {
next_set.insert(position.first);
done_set.insert(position.first);
}
}
}
}
current_set = next_set;
next_set.clear();
} while (!current_set.empty());
}
}
{ // follow empty non-terminal symbols, and combine all found non-terminals with all terminals
std::unordered_set<std::pair<std::string, size_t>, PairHash> current_set {getEmptyPositions(m_bnf)};
std::unordered_set<std::pair<std::string, size_t>, PairHash> done_set;
std::unordered_set<std::pair<std::string, size_t>, PairHash> next_set;
do {
for (const auto& current_pos: current_set) {
m_empty_lut[current_pos.first] = current_pos.second;
for (const std::string& terminal: terminals) {
auto it_lut {m_match_lut.find({current_pos.first, terminal})};
if (it_lut == m_match_lut.end()) { // add new list
m_match_lut[std::pair<std::string, std::string>{current_pos.first, terminal}] = std::vector<size_t>{current_pos.second};
} else { // extend list
it_lut->second.emplace_back(current_pos.second);
}
}
auto it {reversedPosFirst.find(current_pos.first)};
if (it != reversedPosFirst.end()) {
std::unordered_set<std::pair<std::string, index_t>, PairHash>& positions{it->second};
for (const auto& position: positions) {
if (done_set.find(position) == done_set.end()) {
next_set.insert(position);
done_set.insert(position);
}
}
}
}
current_set = next_set;
next_set.clear();
} while (!current_set.empty());
}
for (auto& x: m_match_lut) {
std::sort(x.second.begin(), x.second.end());
}
}
void Compiler::constructTree()
{
symbol_variants_it = symbol_variants.begin();
std::vector<std::string> symbol_list{m_top};
index_t symbol_list_pos{0};
NodePosition tree_pos;
while (symbol_list_pos < symbol_list.size()) {
std::string symbol{symbol_list[symbol_list_pos]};
if (isTerminal(m_bnf, symbol)) {
// Advance terminal symbol
nodes[tree_pos.node_id].child_ids[tree_pos.child_pos] = ChildIdFromTokenId(symbol_list_pos);
IncNodePosition(tree_pos);
symbol_list_pos++;
} else {
// Replace non-terminal symbol
symbol_list.erase(symbol_list.begin() + symbol_list_pos);
std::vector<std::string> list {m_bnf[symbol][*symbol_variants_it]};
symbol_list.insert(symbol_list.begin() + symbol_list_pos, list.begin(), list.end());
index_t node_id {AddNode(symbol, *symbol_variants_it, tree_pos)};
if (node_id > 0) {
nodes[tree_pos.node_id].child_ids[tree_pos.child_pos] = node_id;
IncNodePosition(tree_pos);
}
symbol_variants_it++;
}
}
}
Compiler::Compiler(BNF& bnf, const std::string& top)
: m_bnf {removeHeadRecursion(bnf)}
, m_top(top)
, reversedPosFirst{reversePosFirst(m_bnf)}
{
//
// prepare helper cache (TODO: remove this ugly workaround for remaining bad marker elements)
//
(void) minimumSymbolsNeeded("translation-unit");
// remove bad marker elements
auto it{m_min.begin()};
while (it != m_min.end()) {
if (it->second == std::numeric_limits<size_t>::max()) {
it = m_min.erase(it);
} else {
++it;
}
}
(void) minimumSymbolsNeeded("translation-unit");
// fill other cache
fillStartCache();
}
std::vector<TreeNode> Compiler::compile(std::vector<Token> p_tokens)
{
clear();
tokens = p_tokens;
if (tokens.size() == 0)
throw std::runtime_error("No tokens");
//
// top-down algorithm:
//
// 1. Match linear tokens list to bnf, building up list of used variants (symbol_variants)
// 2. Construct Node Tree from symbol_variants
//
if (!match(m_top, 0, tokens.size()))
throw std::runtime_error("Compile error");
DumpTree();
return nodes;
}
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