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#pragma once
///@file
#include "eval.hh"
#include "logging.hh"
namespace nix::parser {
struct IndStringLine {
// String containing only the leading whitespace of the line. May be empty.
std::string_view indentation;
// Position of the line start (before the indentation)
PosIdx pos;
// Whether the line contains anything besides indentation and line break
bool hasContent = false;
std::vector<
std::pair<
PosIdx,
std::variant<std::unique_ptr<Expr>, std::string_view>
>
> parts = {};
};
struct State
{
SymbolTable & symbols;
PosTable & positions;
SourcePath basePath;
PosTable::Origin origin;
const Expr::AstSymbols & s;
const FeatureSettings & featureSettings;
void dupAttr(const AttrPath & attrPath, const PosIdx pos, const PosIdx prevPos);
void dupAttr(Symbol attr, const PosIdx pos, const PosIdx prevPos);
void overridesFound(const PosIdx pos);
void addAttr(ExprAttrs * attrs, AttrPath && attrPath, std::unique_ptr<Expr> e, const PosIdx pos);
std::unique_ptr<Formals> validateFormals(std::unique_ptr<Formals> formals, PosIdx pos = noPos, Symbol arg = {});
std::unique_ptr<Expr> stripIndentation(const PosIdx pos, std::vector<IndStringLine> && line);
// lazy positioning means we don't get byte offsets directly, in.position() would work
// but also requires line and column (which is expensive)
PosIdx at(const auto & in)
{
return positions.add(origin, in.begin() - in.input().begin());
}
PosIdx atEnd(const auto & in)
{
return positions.add(origin, in.end() - in.input().begin());
}
};
inline void State::dupAttr(const AttrPath & attrPath, const PosIdx pos, const PosIdx prevPos)
{
throw ParseError({
.msg = HintFmt("attribute '%1%' already defined at %2%",
showAttrPath(symbols, attrPath), positions[prevPos]),
.pos = positions[pos]
});
}
inline void State::dupAttr(Symbol attr, const PosIdx pos, const PosIdx prevPos)
{
throw ParseError({
.msg = HintFmt("attribute '%1%' already defined at %2%", symbols[attr], positions[prevPos]),
.pos = positions[pos]
});
}
inline void State::overridesFound(const PosIdx pos) {
// Added 2024-09-18. Turn into an error at some point in the future.
// See the documentation on deprecated features for more details.
warn(
"%s found at %s. This feature is deprecated and will be removed in the future. Use %s to silence this warning.",
"__overrides",
positions[pos],
"--extra-deprecated-features rec-set-overrides"
);
}
inline void State::addAttr(ExprAttrs * attrs, AttrPath && attrPath, std::unique_ptr<Expr> e, const PosIdx pos)
{
AttrPath::iterator i;
// All attrpaths have at least one attr
assert(!attrPath.empty());
// Checking attrPath validity.
// ===========================
for (i = attrPath.begin(); i + 1 < attrPath.end(); i++) {
if (i->symbol) {
ExprAttrs::AttrDefs::iterator j = attrs->attrs.find(i->symbol);
if (j != attrs->attrs.end()) {
if (j->second.kind != ExprAttrs::AttrDef::Kind::Inherited) {
ExprAttrs * attrs2 = dynamic_cast<ExprAttrs *>(j->second.e.get());
if (!attrs2) {
attrPath.erase(i + 1, attrPath.end());
dupAttr(attrPath, pos, j->second.pos);
}
attrs = attrs2;
} else {
attrPath.erase(i + 1, attrPath.end());
dupAttr(attrPath, pos, j->second.pos);
}
} else {
auto next = attrs->attrs.emplace(std::piecewise_construct,
std::tuple(i->symbol),
std::tuple(std::make_unique<ExprAttrs>(), pos));
attrs = static_cast<ExprAttrs *>(next.first->second.e.get());
}
} else {
auto & next = attrs->dynamicAttrs.emplace_back(std::move(i->expr), std::make_unique<ExprAttrs>(), pos);
attrs = static_cast<ExprAttrs *>(next.valueExpr.get());
}
}
// Expr insertion.
// ==========================
if (i->symbol) {
ExprAttrs::AttrDefs::iterator j = attrs->attrs.find(i->symbol);
if (j != attrs->attrs.end()) {
// This attr path is already defined. However, if both
// e and the expr pointed by the attr path are two attribute sets,
// we want to merge them.
// Otherwise, throw an error.
auto * ae = dynamic_cast<ExprAttrs *>(e.get());
auto * jAttrs = dynamic_cast<ExprAttrs *>(j->second.e.get());
if (jAttrs && ae) {
if (ae->inheritFromExprs && !jAttrs->inheritFromExprs)
jAttrs->inheritFromExprs = std::make_unique<std::vector<ref<Expr>>>();
for (auto & ad : ae->attrs) {
auto j2 = jAttrs->attrs.find(ad.first);
if (j2 != jAttrs->attrs.end()) // Attr already defined in iAttrs, error.
return dupAttr(ad.first, j2->second.pos, ad.second.pos);
if (ad.second.kind == ExprAttrs::AttrDef::Kind::InheritedFrom) {
auto & sel = dynamic_cast<ExprSelect &>(*ad.second.e);
auto & from = dynamic_cast<ExprInheritFrom &>(*sel.e);
from.displ += jAttrs->inheritFromExprs->size();
}
jAttrs->attrs.emplace(ad.first, std::move(ad.second));
}
std::ranges::move(ae->dynamicAttrs, std::back_inserter(jAttrs->dynamicAttrs));
if (ae->inheritFromExprs)
std::ranges::move(*ae->inheritFromExprs, std::back_inserter(*jAttrs->inheritFromExprs));
} else {
dupAttr(attrPath, pos, j->second.pos);
}
} else {
// Before inserting new attrs, check for __override and throw an error
// (the error will initially be a warning to ease migration)
if (attrs->recursive && !featureSettings.isEnabled(Dep::RecSetOverrides) && i->symbol == s.overrides) {
overridesFound(pos);
}
// This attr path is not defined. Let's create it.
e->setName(i->symbol);
attrs->attrs.emplace(std::piecewise_construct,
std::tuple(i->symbol),
std::tuple(std::move(e), pos));
}
} else {
attrs->dynamicAttrs.emplace_back(std::move(i->expr), std::move(e), pos);
}
}
inline std::unique_ptr<Formals> State::validateFormals(std::unique_ptr<Formals> formals, PosIdx pos, Symbol arg)
{
std::sort(formals->formals.begin(), formals->formals.end(),
[] (const auto & a, const auto & b) {
return std::tie(a.name, a.pos) < std::tie(b.name, b.pos);
});
std::optional<std::pair<Symbol, PosIdx>> duplicate;
for (size_t i = 0; i + 1 < formals->formals.size(); i++) {
if (formals->formals[i].name != formals->formals[i + 1].name)
continue;
std::pair thisDup{formals->formals[i].name, formals->formals[i + 1].pos};
duplicate = std::min(thisDup, duplicate.value_or(thisDup));
}
if (duplicate)
throw ParseError({
.msg = HintFmt("duplicate formal function argument '%1%'", symbols[duplicate->first]),
.pos = positions[duplicate->second]
});
if (arg && formals->has(arg))
throw ParseError({
.msg = HintFmt("duplicate formal function argument '%1%'", symbols[arg]),
.pos = positions[pos]
});
return formals;
}
inline std::unique_ptr<Expr> State::stripIndentation(
const PosIdx pos,
std::vector<IndStringLine> && lines)
{
/* If the only line is whitespace-only, directly return empty string.
* The rest of the code relies on the final string not being empty.
*/
if (lines.size() == 1 && lines.front().parts.empty()) {
return std::make_unique<ExprString>("");
}
/* If the last line only contains whitespace, trim it to not cause excessive whitespace.
* (Other whitespace-only lines get stripped only of the common indentation, and excess
* whitespace becomes part of the string.)
*/
if (lines.back().parts.empty()) {
lines.back().indentation = {};
}
/* Figure out the minimum indentation. Note that by design
whitespace-only lines are not taken into account. */
size_t minIndent = 1000000;
for (auto & line : lines) {
if (line.hasContent) {
minIndent = std::min(minIndent, line.indentation.size());
}
}
/* Strip spaces from each line. */
for (auto & line : lines) {
line.indentation.remove_prefix(std::min(minIndent, line.indentation.size()));
}
/* Concat the parts together again */
std::vector<std::pair<PosIdx, std::unique_ptr<Expr>>> parts;
/* Accumulator for merging intermediates */
PosIdx merged_pos;
std::string merged = "";
auto push_merged = [&] (PosIdx i_pos, std::string_view str) {
if (merged.empty()) {
merged_pos = i_pos;
}
merged += str;
};
auto flush_merged = [&] () {
if (!merged.empty()) {
parts.emplace_back(merged_pos, std::make_unique<ExprString>(std::string(merged)));
merged.clear();
}
};
for (auto && [li, line] : enumerate(lines)) {
push_merged(line.pos, line.indentation);
for (auto & val : line.parts) {
auto &[i_pos, item] = val;
std::visit(overloaded{
[&](std::string_view str) {
push_merged(i_pos, str);
},
[&](std::unique_ptr<Expr> expr) {
flush_merged();
parts.emplace_back(i_pos, std::move(expr));
},
}, std::move(item));
}
}
flush_merged();
/* If this is a single string, then don't do a concatenation.
* (If it's a single expression, still do the ConcatStrings to properly force it being a string.)
*/
if (parts.size() == 1 && dynamic_cast<ExprString *>(parts[0].second.get())) {
return std::move(parts[0].second);
}
return std::make_unique<ExprConcatStrings>(pos, true, std::move(parts));
}
}
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