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357d3b8c6d
This promotes "and" and "or" from a type of statement to "job decorators," as a possible prefix on a job. The point is to rationalize how they interact with && and ||. In the new world 'and' and 'or' apply to a entire job conjunction, i.e. they have "lower precedence." Example: if [ $age -ge 0 ] && [ $age -le 18 ] or [ $age -ge 75 ] && [ $age -le 100 ] echo "Child or senior" end
280 lines
12 KiB
C++
280 lines
12 KiB
C++
// Type-safe access to fish parse trees.
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#ifndef FISH_TNODE_H
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#define FISH_TNODE_H
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#include "parse_grammar.h"
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#include "parse_tree.h"
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struct source_range_t {
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uint32_t start;
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uint32_t length;
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};
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// Check if a child type is possible for a parent type at a given index.
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template <typename Parent, typename Child, size_t Index>
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constexpr bool child_type_possible_at_index() {
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return Parent::template type_possible<Child, Index>();
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}
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// Check if a child type is possible for a parent type at any index.
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// The number of cases here should match MAX_PRODUCTION_LENGTH.
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template <typename Parent, typename Child>
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constexpr bool child_type_possible() {
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return child_type_possible_at_index<Parent, Child, 0>() ||
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child_type_possible_at_index<Parent, Child, 1>() ||
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child_type_possible_at_index<Parent, Child, 2>() ||
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child_type_possible_at_index<Parent, Child, 3>() ||
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child_type_possible_at_index<Parent, Child, 4>() ||
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child_type_possible_at_index<Parent, Child, 5>();
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}
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/// tnode_t ("typed node") is type-safe access to a parse_tree. A tnode_t holds both a pointer to a
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/// parse_node_tree_t and a pointer to a parse_node_t. (Note that the parse_node_tree_t is unowned;
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/// the caller must ensure that the tnode does not outlive the tree.
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///
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/// tnode_t is a lightweight value-type class. It ought to be passed by value. A tnode_t may also be
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/// "missing", associated with a null parse_node_t pointer. operator bool() may be used to check if
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/// a tnode_t is misisng.
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///
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/// A tnode_t is parametrized by a grammar element, and uses the fish grammar to statically
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/// type-check accesses to children and parents. Any particular tnode either corresponds to a
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/// sequence (a single child) or an alternation (multiple possible children). A sequence may have
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/// its children accessed directly via child(), which is templated on the index (and returns a
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/// tnode of the proper type). Alternations may be disambiguated via try_get_child(), which returns
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/// an empty child if the child has the wrong type, or require_get_child() which aborts if the child
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/// has the wrong type.
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template <typename Type>
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class tnode_t {
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/// The tree containing our node.
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const parse_node_tree_t *tree = nullptr;
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/// The node in the tree
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const parse_node_t *nodeptr = nullptr;
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// Helper to get a child type at a given index.
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template <class Element, uint32_t Index>
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using child_at = typename std::tuple_element<Index, typename Element::type_tuple>::type;
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public:
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tnode_t() = default;
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tnode_t(const parse_node_tree_t *t, const parse_node_t *n) : tree(t), nodeptr(n) {
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assert(t && "tree cannot be null in this constructor");
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assert((!n || n->type == Type::token) && "node has wrong type");
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}
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// Try to create a tnode from the given tree and parse node.
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// Returns an empty node if the parse node is null, or has the wrong type.
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static tnode_t try_create(const parse_node_tree_t *tree, const parse_node_t *node) {
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assert(tree && "tree cannot be null");
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return tnode_t(tree, node && node->type == Type::token ? node : nullptr);
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}
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/// Temporary conversion to parse_node_t to assist in migration.
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/* implicit */ operator const parse_node_t &() const {
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assert(nodeptr && "Empty tnode_t");
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return *nodeptr;
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}
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/* implicit */ operator const parse_node_t *() const { return nodeptr; }
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/// \return the underlying (type-erased) node.
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const parse_node_t *node() const { return nodeptr; }
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/// Check whether we're populated.
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explicit operator bool() const { return nodeptr != nullptr; }
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bool operator==(const tnode_t &rhs) const { return tree == rhs.tree && nodeptr == rhs.nodeptr; }
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bool operator!=(const tnode_t &rhs) const { return !(*this == rhs); }
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// Helper to return whether the given tree is the same as ours.
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bool matches_node_tree(const parse_node_tree_t &t) const { return &t == tree; }
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const parse_node_tree_t *get_tree() const { return tree; }
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bool has_source() const { return nodeptr && nodeptr->has_source(); }
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// return the tag, or 0 if missing.
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parse_node_tag_t tag() const { return nodeptr ? nodeptr->tag : 0; }
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// return the number of children, or 0 if missing.
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uint8_t child_count() const { return nodeptr ? nodeptr->child_count : 0; }
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maybe_t<source_range_t> source_range() const {
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if (nodeptr->source_start == NODE_OFFSET_INVALID) return none();
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return source_range_t{nodeptr->source_start, nodeptr->source_length};
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}
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wcstring get_source(const wcstring &str) const {
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return nodeptr->get_source(str);
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}
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bool location_in_or_at_end_of_source_range(size_t loc) const {
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return nodeptr && nodeptr->location_in_or_at_end_of_source_range(loc);
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}
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static tnode_t find_node_matching_source_location(const parse_node_tree_t *tree,
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size_t source_loc,
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const parse_node_t *parent) {
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assert(tree && "null tree");
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return tnode_t{tree,
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tree->find_node_matching_source_location(Type::token, source_loc, parent)};
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}
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/// Type-safe access to a child at the given index.
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template <node_offset_t Index>
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tnode_t<child_at<Type, Index>> child() const {
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using child_type = child_at<Type, Index>;
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const parse_node_t *child = nullptr;
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if (nodeptr) child = tree->get_child(*nodeptr, Index, child_type::token);
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return tnode_t<child_type>{tree, child};
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}
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/// Return a parse_node_t for a child.
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/// This is used to disambiguate alts.
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template <node_offset_t Index>
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const parse_node_t &get_child_node() const {
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assert(nodeptr && "receiver is missing in get_child_node");
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return *tree->get_child(*nodeptr, Index);
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}
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/// If the child at the given index has the given type, return it; otherwise return an empty
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/// child. Note this will refuse to compile if the child type is not possible.
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/// This is used for e.g. alternations.
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template <class ChildType, node_offset_t Index>
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tnode_t<ChildType> try_get_child() const {
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static_assert(child_type_possible_at_index<Type, ChildType, Index>(),
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"Cannot contain a child of this type");
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const parse_node_t *child = nullptr;
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if (nodeptr) child = tree->get_child(*nodeptr, Index);
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if (child && child->type == ChildType::token) return {tree, child};
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return {tree, nullptr};
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}
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/// assert that this is not empty and that the child at index Index has the given type, then
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/// return that child. Note this will refuse to compile if the child type is not possible.
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template <class ChildType, node_offset_t Index>
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tnode_t<ChildType> require_get_child() const {
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assert(nodeptr && "receiver is missing in require_get_child()");
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auto result = try_get_child<ChildType, Index>();
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assert(result && "require_get_child(): wrong child type");
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return result;
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}
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/// Find the first direct child of the given node of the given type. asserts on failure.
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template <class ChildType>
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tnode_t<ChildType> find_child() const {
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static_assert(child_type_possible<Type, ChildType>(), "Cannot have that type as a child");
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assert(nodeptr && "receiver is missing in find_child()");
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tnode_t<ChildType> result{tree, &tree->find_child(*nodeptr, ChildType::token)};
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assert(result && "cannot find child");
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return result;
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}
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/// Type-safe access to a node's parent.
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/// If the parent exists and has type ParentType, return it.
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/// Otherwise return a missing tnode.
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template <class ParentType>
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tnode_t<ParentType> try_get_parent() const {
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static_assert(child_type_possible<ParentType, Type>(), "Parent cannot have us as a child");
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if (!nodeptr) return {};
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return {tree, tree->get_parent(*nodeptr, ParentType::token)};
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}
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/// Finds all descendants (up to max_count) under this node of the given type.
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template <typename DescendantType>
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std::vector<tnode_t<DescendantType>> descendants(size_t max_count = -1) const {
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if (!nodeptr) return {};
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std::vector<tnode_t<DescendantType>> result;
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std::vector<const parse_node_t *> stack{nodeptr};
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while (!stack.empty() && result.size() < max_count) {
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const parse_node_t *node = stack.back();
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if (node->type == DescendantType::token) result.emplace_back(tree, node);
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stack.pop_back();
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node_offset_t index = node->child_count;
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while (index--) {
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stack.push_back(tree->get_child(*node, index));
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}
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}
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return result;
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}
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/// Given that we are a list type, \return the next node of some Item in some node list,
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/// adjusting 'this' to be the remainder of the list.
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/// Returns an empty item on failure.
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template <class ItemType>
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tnode_t<ItemType> next_in_list() {
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// We require that we can contain ourselves, and ItemType as well.
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static_assert(child_type_possible<Type, Type>(), "Is not a list");
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static_assert(child_type_possible<Type, ItemType>(), "Is not a list of that type");
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if (!nodeptr) return {tree, nullptr};
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const parse_node_t *next =
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tree->next_node_in_node_list(*nodeptr, ItemType::token, &nodeptr);
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return {tree, next};
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}
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};
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template <typename Type>
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tnode_t<Type> parse_node_tree_t::find_child(const parse_node_t &parent) const {
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return tnode_t<Type>(this, &this->find_child(parent, Type::token));
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}
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template <typename Type>
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tnode_t<Type> parse_node_tree_t::find_last_node(const parse_node_t *parent) const {
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return tnode_t<Type>(this, this->find_last_node_of_type(Type::token, parent));
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}
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/// Given a plain statement, get the command from the child node. Returns the command string on
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/// success, none on failure.
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maybe_t<wcstring> command_for_plain_statement(tnode_t<grammar::plain_statement> stmt,
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const wcstring &src);
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/// Return the decoration for a plain statement.
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parse_statement_decoration_t get_decoration(tnode_t<grammar::plain_statement> stmt);
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/// Return the type for a boolean statement.
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enum parse_bool_statement_type_t bool_statement_type(tnode_t<grammar::job_decorator> stmt);
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enum parse_bool_statement_type_t bool_statement_type(tnode_t<grammar::job_conjunction_continuation> stmt);
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/// Given a redirection, get the redirection type (or none) and target (file path, or fd).
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maybe_t<redirection_type_t> redirection_type(tnode_t<grammar::redirection> redirection,
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const wcstring &src, int *out_fd,
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wcstring *out_target);
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/// Return the arguments under an arguments_list or arguments_or_redirection_list
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/// Do not return more than max.
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using arguments_node_list_t = std::vector<tnode_t<grammar::argument>>;
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arguments_node_list_t get_argument_nodes(tnode_t<grammar::argument_list>, size_t max = -1);
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arguments_node_list_t get_argument_nodes(tnode_t<grammar::arguments_or_redirections_list>,
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size_t max = -1);
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/// Return whether the given job is background because it has a & symbol.
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bool job_node_is_background(tnode_t<grammar::job>);
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/// If the conjunction is has a decorator (and/or), return it; otherwise return none. This only
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/// considers the leading conjunction, e.g. in `and true || false` only the 'true' conjunction will
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/// return 'and'.
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parse_bool_statement_type_t get_decorator(tnode_t<grammar::job_conjunction>);
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/// Return whether the statement is part of a pipeline.
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/// This doesn't detect e.g. pipelines involving our parent's block statements.
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enum class pipeline_position_t {
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none, // not part of a pipeline
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first, // first command in a pipeline
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subsequent // second or further command in a pipeline
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};
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pipeline_position_t get_pipeline_position(tnode_t<grammar::statement> st);
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/// Check whether an argument_list is a root list.
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inline bool argument_list_is_root(tnode_t<grammar::argument_list> list) {
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return !list.try_get_parent<grammar::argument_list>();
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}
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inline bool argument_list_is_root(tnode_t<grammar::arguments_or_redirections_list> list) {
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return !list.try_get_parent<grammar::arguments_or_redirections_list>();
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}
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#endif
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