ccls/src/clang_cursor.cc

199 lines
5.5 KiB
C++

#include "clang_cursor.h"
#include "clang_utils.h"
#include <algorithm>
#include <cassert>
ClangType::ClangType() : cx_type() {}
ClangType::ClangType(const CXType& other) : cx_type(other) {}
bool ClangType::operator==(const ClangType& rhs) const {
return clang_equalTypes(cx_type, rhs.cx_type);
}
bool ClangType::is_fundamental() const {
// NOTE: This will return false for pointed types. Should we call
// strip_qualifiers for the user?
return cx_type.kind >= CXType_FirstBuiltin &&
cx_type.kind <= CXType_LastBuiltin;
}
CXCursor ClangType::get_declaration() const {
return clang_getTypeDeclaration(cx_type);
}
std::string ClangType::get_usr() const {
return ClangCursor(clang_getTypeDeclaration(cx_type)).get_usr();
}
ClangType ClangType::get_canonical() const {
return clang_getCanonicalType(cx_type);
}
ClangType ClangType::strip_qualifiers() const {
// CXRefQualifierKind qualifiers = clang_Type_getCXXRefQualifier(cx_type)
switch (cx_type.kind) {
case CXType_LValueReference:
case CXType_Pointer:
return clang_getPointeeType(cx_type);
default:
break;
}
return cx_type;
}
std::string ClangType::get_spelling() const {
return ToString(clang_getTypeSpelling(cx_type));
}
ClangType ClangType::get_return_type() const {
return ClangType(clang_getResultType(cx_type));
}
std::vector<ClangType> ClangType::get_arguments() const {
int size = clang_getNumArgTypes(cx_type);
assert(size >= 0);
if (size < 0)
return std::vector<ClangType>();
std::vector<ClangType> types(size);
for (int i = 0; i < size; ++i)
types.emplace_back(clang_getArgType(cx_type, i));
return types;
}
std::vector<ClangType> ClangType::get_template_arguments() const {
int size = clang_Type_getNumTemplateArguments(cx_type);
assert(size >= 0);
if (size < 0)
return std::vector<ClangType>();
std::vector<ClangType> types(size);
for (int i = 0; i < size; ++i)
types.emplace_back(clang_Type_getTemplateArgumentAsType(cx_type, i));
return types;
}
static_assert(sizeof(ClangCursor) == sizeof(CXCursor),
"Cursor must be the same size as CXCursor");
ClangCursor::ClangCursor() : cx_cursor(clang_getNullCursor()) {}
ClangCursor::ClangCursor(const CXCursor& other) : cx_cursor(other) {}
ClangCursor::operator bool() const {
return !clang_Cursor_isNull(cx_cursor);
}
bool ClangCursor::operator==(const ClangCursor& rhs) const {
return clang_equalCursors(cx_cursor, rhs.cx_cursor);
}
bool ClangCursor::operator!=(const ClangCursor& rhs) const {
return !(*this == rhs);
}
CXCursorKind ClangCursor::get_kind() const {
return cx_cursor.kind;
}
ClangCursor ClangCursor::get_declaration() const {
ClangType type = get_type();
// auto x = new Foo() will not be deduced to |Foo| if we do not use the
// canonical type. However, a canonical type will look past typedefs so we
// will not accurately report variables on typedefs if we always do this.
if (type.cx_type.kind == CXType_Auto)
type = type.get_canonical();
return type.strip_qualifiers().get_declaration();
}
ClangType ClangCursor::get_type() const {
return ClangType(clang_getCursorType(cx_cursor));
}
std::string ClangCursor::get_spelling() const {
return ::ToString(clang_getCursorSpelling(cx_cursor));
}
std::string ClangCursor::get_display_name() const {
return ::ToString(clang_getCursorDisplayName(cx_cursor));
}
std::string ClangCursor::get_usr() const {
return ::ToString(clang_getCursorUSR(cx_cursor));
}
bool ClangCursor::is_definition() const {
return clang_isCursorDefinition(cx_cursor);
}
ClangCursor ClangCursor::template_specialization_to_template_definition()
const {
CXCursor definition = clang_getSpecializedCursorTemplate(cx_cursor);
if (definition.kind == CXCursor_FirstInvalid)
return cx_cursor;
return definition;
}
ClangCursor ClangCursor::get_referenced() const {
return ClangCursor(clang_getCursorReferenced(cx_cursor));
}
ClangCursor ClangCursor::get_canonical() const {
return ClangCursor(clang_getCanonicalCursor(cx_cursor));
}
ClangCursor ClangCursor::get_definition() const {
return ClangCursor(clang_getCursorDefinition(cx_cursor));
}
ClangCursor ClangCursor::get_semantic_parent() const {
return ClangCursor(clang_getCursorSemanticParent(cx_cursor));
}
std::vector<ClangCursor> ClangCursor::get_arguments() const {
int size = clang_Cursor_getNumArguments(cx_cursor);
if (size < 0)
return std::vector<ClangCursor>();
std::vector<ClangCursor> cursors(size);
for (int i = 0; i < size; ++i)
cursors.emplace_back(clang_Cursor_getArgument(cx_cursor, i));
return cursors;
}
bool ClangCursor::is_valid_kind() const {
CXCursor referenced = clang_getCursorReferenced(cx_cursor);
if (clang_Cursor_isNull(referenced))
return false;
CXCursorKind kind = get_kind();
return kind > CXCursor_UnexposedDecl &&
(kind < CXCursor_FirstInvalid || kind > CXCursor_LastInvalid);
}
std::string ClangCursor::get_type_description() const {
auto type = clang_getCursorType(cx_cursor);
return ::ToString(clang_getTypeSpelling(type));
}
optional<std::string> ClangCursor::get_comments() const {
return nullopt;
// TODO
ClangCursor referenced = get_referenced();
if (referenced)
// Get unformatted comments. Returns multiple paragraphs.
return ::ToString(clang_Cursor_getRawCommentText(referenced.cx_cursor));
// Get formatted comments. Returns only the first paragraph.
return ::ToString(clang_Cursor_getBriefCommentText(referenced.cx_cursor));
}
std::string ClangCursor::ToString() const {
return ::ToString(get_kind()) + " " + get_spelling();
}