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mark type usages as interesting for template parameters

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This commit is contained in:
Jacob Dufault 2017-02-20 13:48:46 -08:00
parent e78945a80f
commit 04412f056f
5 changed files with 346 additions and 52 deletions
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214
main.cpp
View File

@ -18,8 +18,6 @@
//#include <clang-c\Index.h>
// TODO: Maybe we should use clang_indexSourceFile?
// While indexing, we should refer to symbols by USR. When joining into the db, we can have optimized access.
struct TypeDef;
@ -1282,18 +1280,6 @@ bool HasUsage(const std::vector<clang::SourceLocation>& usages, const clang::Sou
return false;
}
// TODO: Let's switch over to the indexer api. It can index
// the int x = get_value() bit...
// - problem: prototype ParmDecl are not parsed - we can parse this info though using FuncDecl and checking if it prototype
// - make sure type hierarchy is possible - CXIdxCXXClassDeclInfo
// - make sure namespace is possible - look at container/lexicalContainer
// - make sure method overload is possible - should be doable using existing approach
//
// - make sure template logic is possible
// * it doesn't seem like we get any template specialization logic
// * we get two decls to the same template... resolved by checking parent? maybe this will break. not sure.
bool IsTypeDefinition(const CXIdxContainerInfo* container) {
if (!container)
return false;
@ -1307,22 +1293,43 @@ bool IsTypeDefinition(const CXIdxContainerInfo* container) {
}
}
std::optional<TypeId> ResolveToType(ParsingDatabase* db, clang::Type type) {
clang::Type var_type = type.strip_qualifiers();
std::string usr = var_type.get_usr();
#if false
struct TypeResolution {
std::optional<TypeId> resolved_type;
// If |check_template_arguments| is true, |original_type| may have template
// parameters with interesting usage information.
std::vector<clang::Type> template_arguments;
};
TypeResolution ResolveToType(ParsingDatabase* db, clang::Type type) {
TypeResolution result;
type = type.strip_qualifiers();
std::string usr = type.get_usr();
if (usr == "")
return std::nullopt;
return result;
// TODO: Add a check and don't resolve template specializations that exist in source code.
// Resolve template specialization so that we always point to the non-specialized type.
clang::Cursor decl = clang_getTypeDeclaration(var_type.cx_type);
clang::Cursor unresolved_decl = clang_getSpecializedCursorTemplate(decl.cx_cursor);
std::string template_usr = clang::Cursor(unresolved_decl).get_usr();
if (template_usr != "")
usr = template_usr;
result.template_arguments = type.get_template_arguments();
if (result.template_arguments.size() > 0) {
clang::Cursor decl = clang_getTypeDeclaration(type.cx_type);
clang::Cursor unresolved_decl = clang_getSpecializedCursorTemplate(decl.cx_cursor);
usr = clang::Cursor(unresolved_decl).get_usr();
/*
std::string template_usr = clang::Cursor(unresolved_decl).get_usr();
if (template_usr != "") {
result.check_template_arguments = true;
result.original_type = type;
usr = template_usr;
}
*/
}
return db->ToTypeId(usr);
result.resolved_type = db->ToTypeId(usr);
return result;
}
clang::SourceLocation FindLocationOfTypeSpecifier(clang::Cursor cursor) {
@ -1334,13 +1341,126 @@ clang::SourceLocation FindLocationOfTypeSpecifier(clang::Cursor cursor) {
return child.value().get_source_location();
}
void AddInterestingUsageToType(ParsingDatabase* db, TypeId type_id, clang::SourceLocation location) {
TypeDef* type_def = db->Resolve(type_id);
void AddInterestingUsageToType(ParsingDatabase* db, TypeResolution resolved_type, clang::SourceLocation location) {
// TODO: pass cursor in. Implement custom visitor just for this. Cursor resolves type as needed. Can we use visitor types as the actual types?
TypeDef* type_def = db->Resolve(resolved_type.resolved_type.value());
type_def->interesting_uses.push_back(location);
//if (resolved_type.check_template_arguments) {
//}
}
#endif
struct VisitDeclForTypeUsageParam {
ParsingDatabase* db;
bool is_interesting;
int has_processed_any = false;
std::optional<clang::Cursor> previous_cursor;
std::optional<TypeId> initial_type;
VisitDeclForTypeUsageParam(ParsingDatabase* db, bool is_interesting)
: db(db), is_interesting(is_interesting) {}
};
void VisitDeclForTypeUsageVisitorHandler(clang::Cursor cursor, VisitDeclForTypeUsageParam* param) {
param->has_processed_any = true;
ParsingDatabase* db = param->db;
TypeId ref_type_id = db->ToTypeId(cursor.get_referenced().get_usr());
if (!param->initial_type)
param->initial_type = ref_type_id;
if (param->is_interesting) {
TypeDef* ref_type_def = db->Resolve(ref_type_id);
ref_type_def->interesting_uses.push_back(cursor.get_source_location());
}
}
clang::VisiterResult VisitDeclForTypeUsageVisitor(clang::Cursor cursor, clang::Cursor parent, VisitDeclForTypeUsageParam* param) {
switch (cursor.get_kind()) {
case CXCursor_TemplateRef:
case CXCursor_TypeRef:
if (param->previous_cursor) {
VisitDeclForTypeUsageVisitorHandler(param->previous_cursor.value(), param);
// This if is inside the above if because if there are multiple TypeRefs,
// we always want to process the first one. If we did not always process
// the first one, we cannot tell if there are more TypeRefs after it and
// logic for fetching the return type breaks. This happens in ParmDecl
// instances which only have one TypeRef child but are not interesting
// usages.
if (!param->is_interesting)
return clang::VisiterResult::Break;
}
param->previous_cursor = cursor;
}
return clang::VisiterResult::Continue;
}
std::optional<TypeId> ResolveDeclToType(ParsingDatabase* db, clang::Cursor decl_cursor, const CXIdxContainerInfo* semantic_container, const CXIdxContainerInfo* lexical_container, bool is_interesting) {
//
// The general AST format for definitions follows this pattern:
//
// template<typename A, typename B>
// struct Container;
//
// struct S1;
// struct S2;
//
// Container<Container<S1, S2>, S2> foo;
//
// =>
//
// VarDecl
// TemplateRef Container
// TemplateRef Container
// TypeRef struct S1
// TypeRef struct S2
// TypeRef struct S2
//
// We skip the last type reference for methods/variables which are defined
// out-of-line w.r.t. the parent type.
//
// S1* Foo::foo() {}
//
// The above example looks like this in the AST:
//
// CXXMethod foo
// TypeRef struct S1
// TypeRef class Foo
// CompoundStmt
// ...
//
// The second TypeRef is an uninteresting usage.
bool process_last_type_ref = true;
if (IsTypeDefinition(semantic_container) && !IsTypeDefinition(lexical_container)) {
assert(decl_cursor.is_definition());
process_last_type_ref = false;
}
VisitDeclForTypeUsageParam param(db, is_interesting);
decl_cursor.VisitChildren(&VisitDeclForTypeUsageVisitor, &param);
// VisitDeclForTypeUsageVisitor guarantees that if there are multiple TypeRef
// children, the first one will always be visited.
if (param.previous_cursor && process_last_type_ref) {
VisitDeclForTypeUsageVisitorHandler(param.previous_cursor.value(), &param);
} else {
// If we are not processing the last type ref, it *must* be a TypeRef (ie,
// and not a TemplateRef).
assert(!param.previous_cursor.has_value() ||
param.previous_cursor.value().get_kind() == CXCursor_TypeRef);
}
return param.initial_type;
}
void indexDeclaration(CXClientData client_data, const CXIdxDeclInfo* decl) {
@ -1378,16 +1498,21 @@ void indexDeclaration(CXClientData client_data, const CXIdxDeclInfo* decl) {
var_def->all_uses.push_back(decl->loc);
std::optional<TypeId> var_type = ResolveDeclToType(db, decl_cursor, decl->semanticContainer, decl->lexicalContainer, decl_cursor.get_kind() != CXCursor_ParmDecl);
if (var_type.has_value())
var_def->variable_type = var_type.value();
// Declaring variable type information.
std::optional<TypeId> var_type_id = ResolveToType(db, decl_cursor.get_type());
if (var_type_id) {
var_def->variable_type = var_type_id.value();
/*
TypeResolution var_type = ResolveToType(db, decl_cursor.get_type());
if (var_type.resolved_type) {
var_def->variable_type = var_type.resolved_type.value();
// Insert an interesting type usage for variable declarations. Parameters
// are handled when a function is declared because clang doesn't provide
// parameter declarations for unnamed parameters.
if (decl_cursor.get_kind() != CXCursor_ParmDecl)
AddInterestingUsageToType(db, var_type_id.value(), FindLocationOfTypeSpecifier(decl_cursor));
AddInterestingUsageToType(db, var_type, FindLocationOfTypeSpecifier(decl_cursor));
}
*/
if (decl->isDefinition && IsTypeDefinition(decl->semanticContainer)) {
@ -1440,9 +1565,13 @@ void indexDeclaration(CXClientData client_data, const CXIdxDeclInfo* decl) {
declaring_type_def->funcs.push_back(func_id);
}
std::optional<TypeId> ret_type_id = ResolveToType(db, decl_cursor.get_type().get_return_type());
if (ret_type_id)
AddInterestingUsageToType(db, ret_type_id.value(), FindLocationOfTypeSpecifier(decl_cursor));
// We don't actually need to know the return type, but we need to mark it
// as an interesting usage.
ResolveDeclToType(db, decl_cursor, decl->semanticContainer, decl->lexicalContainer, true /*is_interesting*/);
//TypeResolution ret_type = ResolveToType(db, decl_cursor.get_type().get_return_type());
//if (ret_type.resolved_type)
// AddInterestingUsageToType(db, ret_type, FindLocationOfTypeSpecifier(decl_cursor));
if (decl->isDefinition || is_pure_virtual) {
// Mark type usage for parameters as interesting. We handle this here
@ -1458,9 +1587,13 @@ void indexDeclaration(CXClientData client_data, const CXIdxDeclInfo* decl) {
for (clang::Cursor arg : cursor.get_arguments()) {
switch (arg.get_kind()) {
case CXCursor_ParmDecl:
std::optional<TypeId> arg_type_id = ResolveToType(db, arg.get_type());
if (arg_type_id)
AddInterestingUsageToType(db, arg_type_id.value(), FindLocationOfTypeSpecifier(arg));
// We don't need to know the arg type, but we do want to mark it as
// an interesting usage.
ResolveDeclToType(db, arg, decl->semanticContainer, decl->lexicalContainer, true /*is_interesting*/);
//TypeResolution arg_type = ResolveToType(db, arg.get_type());
//if (arg_type.resolved_type)
// AddInterestingUsageToType(db, arg_type, FindLocationOfTypeSpecifier(arg));
break;
}
}
@ -1672,7 +1805,6 @@ void indexEntityReference(CXClientData client_data, const CXIdxEntityRefInfo* re
//if (param->last_type_usage_location == loc) break;
//param->last_type_usage_location = loc;
// TODO: initializer list can many type refs...
if (!HasUsage(referenced_def->all_uses, loc))
referenced_def->all_uses.push_back(loc);
@ -1862,12 +1994,14 @@ int main(int argc, char** argv) {
*/
for (std::string path : GetFilesInFolder("tests")) {
//if (path != "tests/declaration_vs_definition/method.cc") continue;
//if (path == "tests/usage/type_usage_declare_extern.cc") continue;
//if (path != "tests/declaration_vs_definition/class_member_static.cc") continue;
//if (path != "tests/usage/type_usage_declare_param.cc") continue;
//if (path == "tests/constructors/constructor.cc") continue;
//if (path == "tests/constructors/destructor.cc") continue;
//if (path == "tests/usage/func_usage_call_method.cc") continue;
if (path != "tests/usage/type_usage_as_template_parameter_simple.cc") continue;
//if (path != "tests/usage/type_usage_as_template_parameter.cc") continue;
//if (path != "tests/usage/type_usage_as_template_parameter_complex.cc") continue;
//if (path != "tests/usage/type_usage_as_template_parameter_simple.cc") continue;
//if (path != "tests/usage/type_usage_typedef_and_using.cc") continue;
//if (path != "tests/usage/type_usage_declare_local.cc") continue;
//if (path != "tests/usage/func_usage_addr_method.cc") continue;

4
tests/usage/func_usage_template_func.cc
View File

@ -1,5 +1,5 @@
template<typename T>
void accept(T) {}
void accept(T);
void foo() {
accept(1);
@ -15,7 +15,7 @@ OUTPUT:
"usr": "c:@FT@>1#Taccept#t0.0#v#",
"short_name": "accept",
"qualified_name": "accept",
"definition": "tests/usage/func_usage_template_func.cc:2:6",
"declaration": "tests/usage/func_usage_template_func.cc:2:6",
"callers": ["1@tests/usage/func_usage_template_func.cc:5:3", "1@tests/usage/func_usage_template_func.cc:6:3"],
"all_uses": ["tests/usage/func_usage_template_func.cc:2:6", "tests/usage/func_usage_template_func.cc:5:3", "tests/usage/func_usage_template_func.cc:6:3"]
}, {

3
tests/usage/type_usage_as_template_parameter.cc
View File

@ -24,7 +24,8 @@ OUTPUT:
"short_name": "S",
"qualified_name": "S",
"definition": "tests/usage/type_usage_as_template_parameter.cc:4:8",
"all_uses": ["tests/usage/type_usage_as_template_parameter.cc:4:8", "tests/usage/type_usage_as_template_parameter.cc:7:19", "tests/usage/type_usage_as_template_parameter.cc:9:12", "tests/usage/type_usage_as_template_parameter.cc:10:14"]
"all_uses": ["tests/usage/type_usage_as_template_parameter.cc:4:8", "tests/usage/type_usage_as_template_parameter.cc:7:19", "tests/usage/type_usage_as_template_parameter.cc:9:12", "tests/usage/type_usage_as_template_parameter.cc:10:14"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter.cc:7:19", "tests/usage/type_usage_as_template_parameter.cc:9:12", "tests/usage/type_usage_as_template_parameter.cc:10:14"]
}],
"functions": [{
"id": 0,

157
tests/usage/type_usage_as_template_parameter_complex.cc Normal file
View File

@ -0,0 +1,157 @@
template<typename T, typename B>
class unique_ptr;
struct S1;
struct S2;
#if false
VarDecl f
TemplateRef unique_ptr
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
TypeRef struct S2
#endif
extern unique_ptr<unique_ptr<S1, S2>, S2> f;
#if false
FunctionDecl as_return_type
TemplateRef unique_ptr
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
TypeRef struct S2
ParmDecl
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
CompoundStmt
ReturnStmt
UnexposedExpr
CXXNullPtrLiteralExpr
#endif
unique_ptr<unique_ptr<S1, S2>, S2>* as_return_type(unique_ptr<S1, S2>*) { return nullptr; }
#if false
FunctionDecl no_return_type
ParmDecl
CompoundStmt
#endif
void no_return_type(int) {}
#if false
FunctionDecl empty
CompoundStmt
DeclStmt
VarDecl local
TemplateRef unique_ptr
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
TypeRef struct S2
#endif
void empty() {
unique_ptr<unique_ptr<S1, S2>, S2>* local;
}
#if false
ClassDecl Foo
CXXMethod foo
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
#endif
class Foo {
unique_ptr<S1, S2>* foo();
};
#if false
CXXMethod foo
TemplateRef unique_ptr
TypeRef struct S1
TypeRef struct S2
TypeRef class Foo
CompoundStmt
ReturnStmt
UnexposedExpr
CXXNullPtrLiteralExpr
#endif
unique_ptr<S1, S2>* Foo::foo() { return nullptr; }
/*
OUTPUT:
{
"types": [{
"id": 0,
"usr": "c:@ST>2#T#T@unique_ptr",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:2:7", "tests/usage/type_usage_as_template_parameter_complex.cc:15:8", "tests/usage/type_usage_as_template_parameter_complex.cc:15:19", "tests/usage/type_usage_as_template_parameter_complex.cc:33:1", "tests/usage/type_usage_as_template_parameter_complex.cc:33:12", "tests/usage/type_usage_as_template_parameter_complex.cc:33:52", "tests/usage/type_usage_as_template_parameter_complex.cc:54:3", "tests/usage/type_usage_as_template_parameter_complex.cc:54:14", "tests/usage/type_usage_as_template_parameter_complex.cc:65:3", "tests/usage/type_usage_as_template_parameter_complex.cc:79:1"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:15:8", "tests/usage/type_usage_as_template_parameter_complex.cc:15:19", "tests/usage/type_usage_as_template_parameter_complex.cc:33:1", "tests/usage/type_usage_as_template_parameter_complex.cc:33:12", "tests/usage/type_usage_as_template_parameter_complex.cc:33:52", "tests/usage/type_usage_as_template_parameter_complex.cc:54:3", "tests/usage/type_usage_as_template_parameter_complex.cc:54:14", "tests/usage/type_usage_as_template_parameter_complex.cc:65:3", "tests/usage/type_usage_as_template_parameter_complex.cc:79:1"]
}, {
"id": 1,
"usr": "c:@S@S1",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:4:8", "tests/usage/type_usage_as_template_parameter_complex.cc:15:30", "tests/usage/type_usage_as_template_parameter_complex.cc:33:23", "tests/usage/type_usage_as_template_parameter_complex.cc:33:63", "tests/usage/type_usage_as_template_parameter_complex.cc:54:25", "tests/usage/type_usage_as_template_parameter_complex.cc:65:14", "tests/usage/type_usage_as_template_parameter_complex.cc:79:12"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:15:30", "tests/usage/type_usage_as_template_parameter_complex.cc:33:23", "tests/usage/type_usage_as_template_parameter_complex.cc:33:63", "tests/usage/type_usage_as_template_parameter_complex.cc:54:25", "tests/usage/type_usage_as_template_parameter_complex.cc:65:14", "tests/usage/type_usage_as_template_parameter_complex.cc:79:12"]
}, {
"id": 2,
"usr": "c:@S@S2",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:5:8", "tests/usage/type_usage_as_template_parameter_complex.cc:15:34", "tests/usage/type_usage_as_template_parameter_complex.cc:15:39", "tests/usage/type_usage_as_template_parameter_complex.cc:33:27", "tests/usage/type_usage_as_template_parameter_complex.cc:33:32", "tests/usage/type_usage_as_template_parameter_complex.cc:33:67", "tests/usage/type_usage_as_template_parameter_complex.cc:54:29", "tests/usage/type_usage_as_template_parameter_complex.cc:54:34", "tests/usage/type_usage_as_template_parameter_complex.cc:65:18", "tests/usage/type_usage_as_template_parameter_complex.cc:79:16"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:15:34", "tests/usage/type_usage_as_template_parameter_complex.cc:15:39", "tests/usage/type_usage_as_template_parameter_complex.cc:33:27", "tests/usage/type_usage_as_template_parameter_complex.cc:33:32", "tests/usage/type_usage_as_template_parameter_complex.cc:33:67", "tests/usage/type_usage_as_template_parameter_complex.cc:54:29", "tests/usage/type_usage_as_template_parameter_complex.cc:54:34", "tests/usage/type_usage_as_template_parameter_complex.cc:65:18", "tests/usage/type_usage_as_template_parameter_complex.cc:79:16"]
}, {
"id": 3,
"usr": "c:@S@Foo",
"short_name": "Foo",
"qualified_name": "Foo",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:64:7",
"funcs": [3],
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:64:7", "tests/usage/type_usage_as_template_parameter_complex.cc:79:21"]
}],
"functions": [{
"id": 0,
"usr": "c:@F@as_return_type#*$@S@unique_ptr>#$@S@S1#$@S@S2#",
"short_name": "as_return_type",
"qualified_name": "as_return_type",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:33:37",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:33:37"]
}, {
"id": 1,
"usr": "c:@F@no_return_type#I#",
"short_name": "no_return_type",
"qualified_name": "no_return_type",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:40:6",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:40:6"]
}, {
"id": 2,
"usr": "c:@F@empty#",
"short_name": "empty",
"qualified_name": "empty",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:53:6",
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:53:6"]
}, {
"id": 3,
"usr": "c:@S@Foo@F@foo#",
"short_name": "foo",
"qualified_name": "Foo::foo",
"declaration": "tests/usage/type_usage_as_template_parameter_complex.cc:65:23",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:79:26",
"declaring_type": 3,
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:65:23", "tests/usage/type_usage_as_template_parameter_complex.cc:79:26"]
}],
"variables": [{
"id": 0,
"usr": "c:@f",
"short_name": "f",
"qualified_name": "f",
"declaration": "tests/usage/type_usage_as_template_parameter_complex.cc:15:43",
"variable_type": 0,
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:15:43"]
}, {
"id": 1,
"usr": "c:type_usage_as_template_parameter_complex.cc@1062@F@empty#@local",
"short_name": "local",
"qualified_name": "local",
"definition": "tests/usage/type_usage_as_template_parameter_complex.cc:54:39",
"variable_type": 0,
"all_uses": ["tests/usage/type_usage_as_template_parameter_complex.cc:54:39"]
}]
}
*/

20
tests/usage/type_usage_as_template_parameter_simple.cc
View File

@ -1,34 +1,36 @@
template<typename T>
class unique_ptr;
class unique_ptr {};
struct S;
extern unique_ptr<S> f;
static unique_ptr<S> foo;
/*
// TODO: There should be an interesting usage on S as well.
OUTPUT:
{
"types": [{
"id": 0,
"usr": "c:@ST>1#T@unique_ptr",
"short_name": "unique_ptr",
"qualified_name": "unique_ptr",
"definition": "tests/usage/type_usage_as_template_parameter_simple.cc:2:7",
"all_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:2:7", "tests/usage/type_usage_as_template_parameter_simple.cc:6:8"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:6:8"]
}, {
"id": 1,
"usr": "c:@S@S",
"all_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:4:8", "tests/usage/type_usage_as_template_parameter_simple.cc:6:19"]
"all_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:4:8", "tests/usage/type_usage_as_template_parameter_simple.cc:6:19"],
"interesting_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:6:19"]
}],
"functions": [],
"variables": [{
"id": 0,
"usr": "c:@f",
"short_name": "f",
"qualified_name": "f",
"declaration": "tests/usage/type_usage_as_template_parameter_simple.cc:6:22",
"usr": "c:type_usage_as_template_parameter_simple.cc@foo",
"short_name": "foo",
"qualified_name": "foo",
"definition": "tests/usage/type_usage_as_template_parameter_simple.cc:6:22",
"variable_type": 0,
"all_uses": ["tests/usage/type_usage_as_template_parameter_simple.cc:6:22"]
}]
}
*/