#include "nixexpr.hh" #include "derivations.hh" #include "eval.hh" #include "symbol-table.hh" #include "print.hh" #include "escape-string.hh" #include #include namespace nix { ExprBlackHole eBlackHole; Expr *eBlackHoleAddr = &eBlackHole; // FIXME: remove, because *symbols* are abstract and do not have a single // textual representation; see printIdentifier() std::ostream & operator <<(std::ostream & str, const SymbolStr & symbol) { std::string_view s = symbol; return printIdentifier(str, s); } AttrName::AttrName(Symbol s) : symbol(s) { } AttrName::AttrName(std::unique_ptr e) : expr(std::move(e)) { } void Expr::show(const SymbolTable & symbols, std::ostream & str) const { abort(); } void ExprInt::show(const SymbolTable & symbols, std::ostream & str) const { str << n; } void ExprFloat::show(const SymbolTable & symbols, std::ostream & str) const { str << nf; } void ExprString::show(const SymbolTable & symbols, std::ostream & str) const { escapeString(str, s); } void ExprPath::show(const SymbolTable & symbols, std::ostream & str) const { str << s; } void ExprVar::show(const SymbolTable & symbols, std::ostream & str) const { str << symbols[name]; } void ExprInheritFrom::show(SymbolTable const & symbols, std::ostream & str) const { str << "(/* expanded inherit (expr) */ "; fromExpr->show(symbols, str); str << ")"; } void ExprSelect::show(const SymbolTable & symbols, std::ostream & str) const { str << "("; e->show(symbols, str); str << ")." << showAttrPath(symbols, attrPath); if (def) { str << " or ("; def->show(symbols, str); str << ")"; } } void ExprOpHasAttr::show(const SymbolTable & symbols, std::ostream & str) const { str << "(("; e->show(symbols, str); str << ") ? " << showAttrPath(symbols, attrPath) << ")"; } void ExprAttrs::showBindings(const SymbolTable & symbols, std::ostream & str) const { typedef const decltype(attrs)::value_type * Attr; std::vector sorted; for (auto & i : attrs) sorted.push_back(&i); std::sort(sorted.begin(), sorted.end(), [&](Attr a, Attr b) { std::string_view sa = symbols[a->first], sb = symbols[b->first]; return sa < sb; }); std::vector inherits; std::map> inheritsFrom; for (auto & i : sorted) { switch (i->second.kind) { case AttrDef::Kind::Plain: break; case AttrDef::Kind::Inherited: inherits.push_back(i->first); break; case AttrDef::Kind::InheritedFrom: { auto & select = dynamic_cast(*i->second.e); auto & from = dynamic_cast(*select.e); inheritsFrom[from.displ].push_back(i->first); break; } } } if (!inherits.empty()) { str << "inherit"; for (auto sym : inherits) str << " " << symbols[sym]; str << "; "; } for (const auto & [from, syms] : inheritsFrom) { str << "inherit ("; (*inheritFromExprs)[from]->show(symbols, str); str << ")"; for (auto sym : syms) str << " " << symbols[sym]; str << "; "; } for (auto & i : sorted) { if (i->second.kind == AttrDef::Kind::Plain) { str << symbols[i->first] << " = "; i->second.e->show(symbols, str); str << "; "; } } for (auto & i : dynamicAttrs) { str << "\"${"; i.nameExpr->show(symbols, str); str << "}\" = "; i.valueExpr->show(symbols, str); str << "; "; } } void ExprAttrs::show(const SymbolTable & symbols, std::ostream & str) const { if (recursive) str << "rec "; str << "{ "; showBindings(symbols, str); str << "}"; } void ExprList::show(const SymbolTable & symbols, std::ostream & str) const { str << "[ "; for (auto & i : elems) { str << "("; i->show(symbols, str); str << ") "; } str << "]"; } void ExprLambda::show(const SymbolTable & symbols, std::ostream & str) const { str << "("; if (hasFormals()) { str << "{ "; bool first = true; // the natural Symbol ordering is by creation time, which can lead to the // same expression being printed in two different ways depending on its // context. always use lexicographic ordering to avoid this. for (const Formal & i : formals->lexicographicOrder(symbols)) { if (first) first = false; else str << ", "; str << symbols[i.name]; if (i.def) { str << " ? "; i.def->show(symbols, str); } } if (formals->ellipsis) { if (!first) str << ", "; str << "..."; } str << " }"; if (arg) str << " @ "; } if (arg) str << symbols[arg]; str << ": "; body->show(symbols, str); str << ")"; } void ExprCall::show(const SymbolTable & symbols, std::ostream & str) const { str << '('; fun->show(symbols, str); for (auto & e : args) { str << ' '; e->show(symbols, str); } str << ')'; } void ExprLet::show(const SymbolTable & symbols, std::ostream & str) const { str << "(let "; attrs->showBindings(symbols, str); str << "in "; body->show(symbols, str); str << ")"; } void ExprWith::show(const SymbolTable & symbols, std::ostream & str) const { str << "(with "; attrs->show(symbols, str); str << "; "; body->show(symbols, str); str << ")"; } void ExprIf::show(const SymbolTable & symbols, std::ostream & str) const { str << "(if "; cond->show(symbols, str); str << " then "; then->show(symbols, str); str << " else "; else_->show(symbols, str); str << ")"; } void ExprAssert::show(const SymbolTable & symbols, std::ostream & str) const { str << "assert "; cond->show(symbols, str); str << "; "; body->show(symbols, str); } void ExprOpNot::show(const SymbolTable & symbols, std::ostream & str) const { str << "(! "; e->show(symbols, str); str << ")"; } void ExprConcatStrings::show(const SymbolTable & symbols, std::ostream & str) const { bool first = true; str << "("; for (auto & [_pos, part] : es) { if (first) first = false; else str << " + "; if (forceString && !dynamic_cast(part.get())) { /* Print as a string with an interpolation, to preserve the * semantics of the value having to be a string. * Interpolations are weird and someone should eventually * move them out into their own AST node please. */ str << "\"${"; part->show(symbols, str); str << "}\""; } else { part->show(symbols, str); } } str << ")"; } void ExprPos::show(const SymbolTable & symbols, std::ostream & str) const { str << "__curPos"; } std::string showAttrPath(const SymbolTable & symbols, const AttrPath & attrPath) { std::ostringstream out; bool first = true; for (auto & i : attrPath) { if (!first) out << '.'; else first = false; if (i.symbol) out << symbols[i.symbol]; else { out << "\"${"; i.expr->show(symbols, out); out << "}\""; } } return out.str(); } /* Computing levels/displacements for variables. */ void Expr::bindVars(EvalState & es, const std::shared_ptr & env) { abort(); } void ExprInt::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } void ExprFloat::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } void ExprString::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } void ExprPath::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } void ExprVar::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); fromWith = nullptr; /* Check whether the variable appears in the environment. If so, set its level and displacement. */ const StaticEnv * curEnv; Level level; int withLevel = -1; for (curEnv = env.get(), level = 0; curEnv; curEnv = curEnv->up, level++) { if (curEnv->isWith) { if (withLevel == -1) withLevel = level; } else { auto i = curEnv->find(name); if (i != curEnv->vars.end()) { this->level = level; displ = i->second; return; } } } /* Otherwise, the variable must be obtained from the nearest enclosing `with'. If there is no `with', then we can issue an "undefined variable" error now. */ if (withLevel == -1) es.error( "undefined variable '%1%'", es.symbols[name] ).atPos(pos).debugThrow(); for (auto * e = env.get(); e && !fromWith; e = e->up) fromWith = e->isWith; this->level = withLevel; } void ExprInheritFrom::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } void ExprSelect::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); e->bindVars(es, env); if (def) def->bindVars(es, env); for (auto & i : attrPath) if (!i.symbol) i.expr->bindVars(es, env); } void ExprOpHasAttr::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); e->bindVars(es, env); for (auto & i : attrPath) if (!i.symbol) i.expr->bindVars(es, env); } std::shared_ptr ExprAttrs::bindInheritSources( EvalState & es, const std::shared_ptr & env) { if (!inheritFromExprs) return nullptr; // the inherit (from) source values are inserted into an env of its own, which // does not introduce any variable names. // analysis must see an empty env, or an env that contains only entries with // otherwise unused names to not interfere with regular names. the parser // has already filled all exprs that access this env with appropriate level // and displacement, and nothing else is allowed to access it. ideally we'd // not even *have* an expr that grabs anything from this env since it's fully // invisible, but the evaluator does not allow for this yet. auto inner = std::make_shared(nullptr, env.get(), 0); for (auto & from : *inheritFromExprs) from->bindVars(es, env); return inner; } void ExprAttrs::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); if (recursive) { auto newEnv = [&] () -> std::shared_ptr { auto newEnv = std::make_shared(nullptr, env.get(), attrs.size()); Displacement displ = 0; for (auto & i : attrs) newEnv->vars.emplace_back(i.first, i.second.displ = displ++); return newEnv; }(); // No need to sort newEnv since attrs is in sorted order. auto inheritFromEnv = bindInheritSources(es, newEnv); for (auto & i : attrs) i.second.e->bindVars(es, i.second.chooseByKind(newEnv, env, inheritFromEnv)); for (auto & i : dynamicAttrs) { i.nameExpr->bindVars(es, newEnv); i.valueExpr->bindVars(es, newEnv); } } else { auto inheritFromEnv = bindInheritSources(es, env); for (auto & i : attrs) i.second.e->bindVars(es, i.second.chooseByKind(env, env, inheritFromEnv)); for (auto & i : dynamicAttrs) { i.nameExpr->bindVars(es, env); i.valueExpr->bindVars(es, env); } } } void ExprList::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); for (auto & i : elems) i->bindVars(es, env); } void ExprLambda::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); auto newEnv = std::make_shared( nullptr, env.get(), (hasFormals() ? formals->formals.size() : 0) + (!arg ? 0 : 1)); Displacement displ = 0; if (arg) newEnv->vars.emplace_back(arg, displ++); if (hasFormals()) { for (auto & i : formals->formals) newEnv->vars.emplace_back(i.name, displ++); newEnv->sort(); for (auto & i : formals->formals) if (i.def) i.def->bindVars(es, newEnv); } body->bindVars(es, newEnv); } void ExprCall::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); fun->bindVars(es, env); for (auto & e : args) e->bindVars(es, env); } void ExprLet::bindVars(EvalState & es, const std::shared_ptr & env) { auto newEnv = [&] () -> std::shared_ptr { auto newEnv = std::make_shared(nullptr, env.get(), attrs->attrs.size()); Displacement displ = 0; for (auto & i : attrs->attrs) newEnv->vars.emplace_back(i.first, i.second.displ = displ++); return newEnv; }(); // No need to sort newEnv since attrs->attrs is in sorted order. auto inheritFromEnv = attrs->bindInheritSources(es, newEnv); for (auto & i : attrs->attrs) i.second.e->bindVars(es, i.second.chooseByKind(newEnv, env, inheritFromEnv)); if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); body->bindVars(es, newEnv); } void ExprWith::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); parentWith = nullptr; for (auto * e = env.get(); e && !parentWith; e = e->up) parentWith = e->isWith; /* Does this `with' have an enclosing `with'? If so, record its level so that `lookupVar' can look up variables in the previous `with' if this one doesn't contain the desired attribute. */ const StaticEnv * curEnv; Level level; prevWith = 0; for (curEnv = env.get(), level = 1; curEnv; curEnv = curEnv->up, level++) if (curEnv->isWith) { prevWith = level; break; } attrs->bindVars(es, env); auto newEnv = std::make_shared(this, env.get()); body->bindVars(es, newEnv); } void ExprIf::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); cond->bindVars(es, env); then->bindVars(es, env); else_->bindVars(es, env); } void ExprAssert::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); cond->bindVars(es, env); body->bindVars(es, env); } void ExprOpNot::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); e->bindVars(es, env); } void ExprConcatStrings::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); for (auto & i : this->es) i.second->bindVars(es, env); } void ExprPos::bindVars(EvalState & es, const std::shared_ptr & env) { if (es.debugRepl) es.exprEnvs.insert(std::make_pair(this, env)); } /* Storing function names. */ void Expr::setName(Symbol name) { } void ExprLambda::setName(Symbol name) { this->name = name; body->setName(name); } std::string ExprLambda::showNamePos(const EvalState & state) const { std::string id(name ? concatStrings("'", state.symbols[name], "'") : "anonymous function"); return fmt("%1% at %2%", id, state.positions[pos]); } /* Position table. */ Pos PosTable::operator[](PosIdx p) const { auto origin = resolve(p); if (!origin) return {}; const auto offset = origin->offsetOf(p); Pos result{0, 0, origin->origin}; auto lines = this->lines.lock(); auto & linesForInput = (*lines)[origin->offset]; if (linesForInput.empty()) { auto source = result.getSource().value_or(""); const char * begin = source.data(); for (Pos::LinesIterator it(source), end; it != end; it++) linesForInput.push_back(it->data() - begin); if (linesForInput.empty()) linesForInput.push_back(0); } // as above: the first line starts at byte 0 and is always present auto lineStartOffset = std::prev( std::upper_bound(linesForInput.begin(), linesForInput.end(), offset)); result.line = 1 + (lineStartOffset - linesForInput.begin()); result.column = 1 + (offset - *lineStartOffset); return result; } /* Symbol table. */ size_t SymbolTable::totalSize() const { size_t n = 0; dump([&] (const std::string & s) { n += s.size(); }); return n; } }