ccls/main.cpp
Jacob Dufault a8cdadc201 wip
2017-02-18 15:58:40 -08:00

973 lines
25 KiB
C++

#include <algorithm>
#include <optional>
#include <iostream>
#include <cstdint>
#include <cassert>
#include <fstream>
#include <unordered_map>
#include "libclangmm/clangmm.h"
#include "libclangmm/Utility.h"
#include "utils.h"
#include <rapidjson/writer.h>
#include <rapidjson/prettywriter.h>
#include <rapidjson/stringbuffer.h>
#include <rapidjson/document.h>
//#include <clang-c\Index.h>
// While indexing, we should refer to symbols by USR. When joining into the db, we can have optimized access.
struct TypeDef;
struct FuncDef;
struct VarDef;
/*
template<typename T>
struct Id {
uint64_t file_id;
uint64_t local_id;
Id() : file_id(0), local_id(0) {} // Needed for containers. Do not use directly.
Id(uint64_t file_id, uint64_t local_id)
: file_id(file_id), local_id(local_id) {}
};
*/
template<typename T>
struct LocalId {
uint64_t local_id;
LocalId() : local_id(0) {} // Needed for containers. Do not use directly.
explicit LocalId(uint64_t local_id) : local_id(local_id) {}
};
using TypeId = LocalId<TypeDef>;
using FuncId = LocalId<FuncDef>;
using VarId = LocalId<VarDef>;
template<typename T>
struct Ref {
LocalId<T> id;
clang::SourceLocation loc;
Ref(LocalId<T> id, clang::SourceLocation loc) : id(id), loc(loc) {}
};
using TypeRef = Ref<TypeDef>;
using FuncRef = Ref<FuncDef>;
using VarRef = Ref<VarDef>;
// NOTE: declaration is empty if there is no forward declaration!
struct TypeDef {
// General metadata.
TypeId id;
std::string usr;
std::string short_name;
std::string qualified_name;
std::optional<clang::SourceLocation> declaration; // Forward decl.
std::optional<clang::SourceLocation> definition;
// Immediate parent and immediate derived types.
std::vector<TypeId> parents;
std::vector<TypeId> derived;
// Types, functions, and variables defined in this type.
std::vector<TypeId> types;
std::vector<FuncId> funcs;
std::vector<VarId> vars;
// Usages.
std::vector<clang::SourceLocation> uses;
TypeDef(TypeId id, const std::string& usr) : id(id), usr(usr) {}
};
struct FuncDef {
// General metadata.
FuncId id;
std::string usr;
std::string short_name;
std::string qualified_name;
std::optional<clang::SourceLocation> declaration;
std::optional<clang::SourceLocation> definition;
// Type which declares this one (ie, it is a method)
std::optional<TypeId> declaring_type;
// Method this method overrides.
std::optional<FuncId> base;
// Methods which directly override this one.
std::vector<FuncId> derived;
// Local variables defined in this function.
std::vector<VarId> locals;
// Functions which call this one.
std::vector<FuncRef> callers;
// Functions that this function calls.
std::vector<FuncRef> callees;
// Usages.
std::vector<clang::SourceLocation> uses;
FuncDef(FuncId id, const std::string& usr) : id(id), usr(usr) {}
};
struct VarDef {
// General metadata.
VarId id;
std::string usr;
std::string short_name;
std::string qualified_name;
std::optional<clang::SourceLocation> declaration;
std::vector<clang::SourceLocation> initializations;
// Type of the variable.
std::optional<TypeId> variable_type;
// Type which declares this one (ie, it is a method)
std::optional<TypeId> declaring_type;
// Usages.
std::vector<clang::SourceLocation> uses;
VarDef(VarId id, const std::string& usr) : id(id), usr(usr) {}
};
struct ParsingDatabase {
// NOTE: Every Id is resolved to a file_id of 0. The correct file_id needs
// to get fixed up when inserting into the real db.
std::unordered_map<std::string, TypeId> usr_to_type_id;
std::unordered_map<std::string, FuncId> usr_to_func_id;
std::unordered_map<std::string, VarId> usr_to_var_id;
std::vector<TypeDef> types;
std::vector<FuncDef> funcs;
std::vector<VarDef> vars;
TypeId ToTypeId(const std::string& usr);
FuncId ToFuncId(const std::string& usr);
VarId ToVarId(const std::string& usr);
TypeDef* Resolve(TypeId id);
FuncDef* Resolve(FuncId id);
VarDef* Resolve(VarId id);
std::string ToString();
};
TypeId ParsingDatabase::ToTypeId(const std::string& usr) {
auto it = usr_to_type_id.find(usr);
if (it != usr_to_type_id.end())
return it->second;
TypeId id(types.size());
types.push_back(TypeDef(id, usr));
usr_to_type_id[usr] = id;
return id;
}
FuncId ParsingDatabase::ToFuncId(const std::string& usr) {
auto it = usr_to_func_id.find(usr);
if (it != usr_to_func_id.end())
return it->second;
FuncId id(funcs.size());
funcs.push_back(FuncDef(id, usr));
usr_to_func_id[usr] = id;
return id;
}
VarId ParsingDatabase::ToVarId(const std::string& usr) {
auto it = usr_to_var_id.find(usr);
if (it != usr_to_var_id.end())
return it->second;
VarId id(vars.size());
vars.push_back(VarDef(id, usr));
usr_to_var_id[usr] = id;
return id;
}
TypeDef* ParsingDatabase::Resolve(TypeId id) {
return &types[id.local_id];
}
FuncDef* ParsingDatabase::Resolve(FuncId id) {
return &funcs[id.local_id];
}
VarDef* ParsingDatabase::Resolve(VarId id) {
return &vars[id.local_id];
}
using Writer = rapidjson::PrettyWriter<rapidjson::StringBuffer>;
void Write(Writer& writer, const char* key, clang::SourceLocation location) {
if (key) writer.Key(key);
std::string s = location.ToString();
writer.String(s.c_str());
}
void Write(Writer& writer, const char* key, std::optional<clang::SourceLocation> location) {
if (location) {
Write(writer, key, location.value());
}
//else {
// if (key) writer.Key(key);
// writer.Null();
//}
}
void Write(Writer& writer, const char* key, const std::vector<clang::SourceLocation>& locs) {
if (locs.size() == 0)
return;
if (key) writer.Key(key);
writer.StartArray();
for (const clang::SourceLocation& loc : locs)
Write(writer, nullptr, loc);
writer.EndArray();
}
template<typename T>
void Write(Writer& writer, const char* key, LocalId<T> id) {
if (key) writer.Key(key);
writer.Uint64(id.local_id);
}
template<typename T>
void Write(Writer& writer, const char* key, std::optional<LocalId<T>> id) {
if (id) {
Write(writer, key, id.value());
}
//else {
// if (key) writer.Key(key);
// writer.Null();
//}
}
template<typename T>
void Write(Writer& writer, const char* key, const std::vector<LocalId<T>>& ids) {
if (ids.size() == 0)
return;
if (key) writer.Key(key);
writer.StartArray();
for (LocalId<T> id : ids)
Write(writer, nullptr, id);
writer.EndArray();
}
template<typename T>
void Write(Writer& writer, const char* key, Ref<T> ref) {
if (key) writer.Key(key);
std::string s = std::to_string(ref.id.local_id) + "@" + ref.loc.ToString();
writer.String(s.c_str());
}
template<typename T>
void Write(Writer& writer, const char* key, const std::vector<Ref<T>>& refs) {
if (refs.size() == 0)
return;
if (key) writer.Key(key);
writer.StartArray();
for (Ref<T> ref : refs)
Write(writer, nullptr, ref);
writer.EndArray();
}
void Write(Writer& writer, const char* key, const std::string& value) {
if (value.size() == 0)
return;
if (key) writer.Key(key);
writer.String(value.c_str());
}
void Write(Writer& writer, const char* key, uint64_t value) {
if (key) writer.Key(key);
writer.Uint64(value);
}
std::string ParsingDatabase::ToString() {
#define WRITE(name) Write(writer, #name, def.name)
rapidjson::StringBuffer output;
rapidjson::PrettyWriter<rapidjson::StringBuffer> writer(output);
writer.SetFormatOptions(
rapidjson::PrettyFormatOptions::kFormatSingleLineArray);
writer.SetIndent(' ', 2);
writer.StartObject();
// Types
writer.Key("types");
writer.StartArray();
for (TypeDef& def : types) {
writer.StartObject();
WRITE(id);
WRITE(usr);
WRITE(short_name);
WRITE(qualified_name);
WRITE(declaration);
WRITE(definition);
WRITE(parents);
WRITE(derived);
WRITE(types);
WRITE(funcs);
WRITE(vars);
WRITE(uses);
writer.EndObject();
}
writer.EndArray();
// Functions
writer.Key("functions");
writer.StartArray();
for (FuncDef& def : funcs) {
writer.StartObject();
WRITE(id);
WRITE(usr);
WRITE(short_name);
WRITE(qualified_name);
WRITE(declaration);
WRITE(definition);
WRITE(declaring_type);
WRITE(base);
WRITE(derived);
WRITE(locals);
WRITE(callers);
WRITE(callees);
WRITE(uses);
writer.EndObject();
}
writer.EndArray();
// Variables
writer.Key("variables");
writer.StartArray();
for (VarDef& def : vars) {
writer.StartObject();
WRITE(id);
WRITE(usr);
WRITE(short_name);
WRITE(qualified_name);
WRITE(declaration);
WRITE(initializations);
WRITE(variable_type);
WRITE(declaring_type);
WRITE(uses);
writer.EndObject();
}
writer.EndArray();
writer.EndObject();
return output.GetString();
#undef WRITE
}
struct FileDef {
uint64_t id;
std::string path;
std::vector<TypeDef> types;
std::vector<FuncDef> funcs;
std::vector<VarDef> vars;
};
/*
struct Database {
std::unordered_map<std::string, TypeId> usr_to_type_id;
std::unordered_map<std::string, FuncId> usr_to_func_id;
std::unordered_map<std::string, VarId> usr_to_var_id;
std::vector<FileDef> files;
TypeId ToTypeId(const std::string& usr);
FuncId ToFuncId(const std::string& usr);
VarId ToVarId(const std::string& usr);
};
TypeId Database::ToTypeId(const std::string& usr) {
auto it = usr_to_type_id.find(usr);
assert(it != usr_to_type_id.end() && "Usr is not registered");
return it->second;
}
FuncId Database::ToFuncId(const std::string& usr) {
auto it = usr_to_func_id.find(usr);
assert(it != usr_to_func_id.end() && "Usr is not registered");
return it->second;
}
VarId Database::ToVarId(const std::string& usr) {
auto it = usr_to_var_id.find(usr);
assert(it != usr_to_var_id.end() && "Usr is not registered");
return it->second;
}
TypeDef* Resolve(FileDef* file, TypeId id) {
assert(file->id == id.file_id);
return &file->types[id.local_id];
}
FuncDef* Resolve(FileDef* file, FuncId id) {
assert(file->id == id.file_id);
return &file->funcs[id.local_id];
}
VarDef* Resolve(FileDef* file, VarId id) {
assert(file->id == id.file_id);
return &file->vars[id.local_id];
}
TypeDef* Resolve(Database* db, TypeId id) {
return Resolve(&db->files[id.file_id], id);
}
FuncDef* Resolve(Database* db, FuncId id) {
return Resolve(&db->files[id.file_id], id);
}
VarDef* Resolve(Database* db, VarId id) {
return Resolve(&db->files[id.file_id], id);
}
*/
struct NamespaceStack {
std::vector<std::string> stack;
void Push(const std::string& ns);
void Pop();
std::string ComputeQualifiedName(
ParsingDatabase* db, std::optional<TypeId> declaring_type, std::string short_name);
static NamespaceStack kEmpty;
};
NamespaceStack NamespaceStack::kEmpty;
void NamespaceStack::Push(const std::string& ns) {
stack.push_back(ns);
}
void NamespaceStack::Pop() {
stack.pop_back();
}
std::string NamespaceStack::ComputeQualifiedName(
ParsingDatabase* db, std::optional<TypeId> declaring_type, std::string short_name) {
if (declaring_type) {
TypeDef* def = db->Resolve(declaring_type.value());
return def->qualified_name + "::" + short_name;
}
std::string result;
for (const std::string& ns : stack)
result += ns + "::";
result += short_name;
return result;
}
std::optional<TypeId> ResolveDeclaringType(CXCursorKind kind, ParsingDatabase* db, const clang::Cursor& cursor, std::optional<TypeId> declaring_type) {
// Resolve the declaring type for out-of-line method definitions.
if (!declaring_type) {
clang::Cursor parent = cursor.get_semantic_parent();
switch (parent.get_kind()) {
case CXCursor_ClassDecl:
case CXCursor_StructDecl:
declaring_type = db->ToTypeId(parent.get_usr());
break;
}
}
// FieldDecl, etc must have a declaring type.
assert(cursor.get_kind() != kind || declaring_type);
return declaring_type;
}
clang::VisiterResult DumpVisitor(clang::Cursor cursor, clang::Cursor parent, int* level) {
for (int i = 0; i < *level; ++i)
std::cout << " ";
std::cout << clang::ToString(cursor.get_kind()) << " " << cursor.get_spelling() << std::endl;
*level += 1;
cursor.VisitChildren(&DumpVisitor, level);
*level -= 1;
return clang::VisiterResult::Continue;
}
void Dump(clang::Cursor cursor) {
int level = 0;
cursor.VisitChildren(&DumpVisitor, &level);
}
void HandleVarDecl(ParsingDatabase* db, NamespaceStack* ns, clang::Cursor var, std::optional<TypeId> declaring_type) {
//Dump(var);
VarId var_id = db->ToVarId(var.get_usr());
declaring_type = ResolveDeclaringType(CXCursor_FieldDecl, db, var, declaring_type);
// TODO: We could use RAII to verify we don't modify db while have a *Def
// instance alive.
VarDef* var_def = db->Resolve(var_id);
var_def->short_name = var.get_spelling();
var_def->qualified_name =
ns->ComputeQualifiedName(db, declaring_type, var_def->short_name);
if (declaring_type && !var_def->declaration) {
db->Resolve(declaring_type.value())->vars.push_back(var_id);
var_def->declaring_type = declaring_type;
}
// We don't do any additional processing for non-definitions.
if (!var.is_definition()) {
var_def->declaration = var.get_source_location();
return;
}
// If we're a definition and there hasn't been a forward decl, just assign
// declaration location to definition location.
else if (!var_def->declaration) {
var_def->declaration = var.get_source_location();
}
// TODO: Figure out how to scan initializations properly. We probably need
// to scan for assignment statement, or definition+ctor.
var_def->initializations.push_back(var.get_source_location());
var_def->variable_type = db->ToTypeId(var.get_type().get_usr());
}
// |func_id| is the function definition that is currently being processed.
void InsertReference(ParsingDatabase* db, FuncId func_id, clang::Cursor referencer) {
clang::SourceLocation loc = referencer.get_source_location();
clang::Cursor referenced = referencer.get_referenced();
switch (referenced.get_kind()) {
case CXCursor_CXXMethod:
case CXCursor_FunctionDecl:
{
FuncId referenced_id = db->ToFuncId(referenced.get_usr());
FuncDef* referenced_def = db->Resolve(referenced_id);
FuncDef* func_def = db->Resolve(func_id);
func_def->callees.push_back(FuncRef(referenced_id, loc));
referenced_def->callers.push_back(FuncRef(func_id, loc));
referenced_def->uses.push_back(loc);
break;
}
case CXCursor_VarDecl:
{
VarId referenced_id = db->ToVarId(referenced.get_usr());
VarDef* referenced_def = db->Resolve(referenced_id);
referenced_def->uses.push_back(loc);
break;
}
default:
std::cerr << "Unhandled reference from \"" << referencer.ToString()
<< "\" to \"" << referenced.ToString() << "\"" << std::endl;
break;
}
}
struct FuncDefinitionParam {
ParsingDatabase* db;
NamespaceStack* ns;
FuncId func_id;
FuncDefinitionParam(ParsingDatabase* db, NamespaceStack* ns, FuncId func_id)
: db(db), ns(ns), func_id(func_id) {}
};
clang::VisiterResult VisitFuncDefinition(clang::Cursor cursor, clang::Cursor parent, FuncDefinitionParam* param) {
//std::cout << "VistFuncDefinition got " << cursor.ToString() << std::endl;
switch (cursor.get_kind()) {
// TODO: Maybe we should default to recurse?
/*
case CXCursor_CompoundStmt:
case CXCursor_DeclStmt:
case CXCursor_CallExpr:
case CXCursor_UnexposedExpr:
case CXCursor_UnaryExpr:
return clang::VisiterResult::Recurse;
*/
case CXCursor_CallExpr:
// The called element is handled by DeclRefExpr below.
//InsertReference(param->db, param->func_id, cursor);
return clang::VisiterResult::Recurse;
case CXCursor_MemberRefExpr:
case CXCursor_DeclRefExpr:
InsertReference(param->db, param->func_id, cursor);
return clang::VisiterResult::Continue;
case CXCursor_VarDecl:
case CXCursor_ParmDecl:
HandleVarDecl(param->db, param->ns, cursor, std::nullopt);
return clang::VisiterResult::Recurse;
case CXCursor_ReturnStmt:
return clang::VisiterResult::Recurse;
default:
//std::cerr << "Unhandled VisitFuncDefinition kind " << clang::ToString(cursor.get_kind()) << std::endl;
return clang::VisiterResult::Recurse;
}
}
void HandleFunc(ParsingDatabase* db, NamespaceStack* ns, clang::Cursor func, std::optional<TypeId> declaring_type) {
// What this method must process:
// - function declaration
// - function definition
// - method declaration
// - method inline definition
// - method definition
// Resolve id before checking for is_definition so that we insert the
// function into the db even if it is only a prototype. This is needed for
// various file-level operations like outlining.
FuncId func_id = db->ToFuncId(func.get_usr());
// TODO: Consider skipping some of this processing if we've done it already
// (ie, parsed prototype, then parse definition).
declaring_type =
ResolveDeclaringType(CXCursor_CXXMethod, db, func, declaring_type);
FuncDef* func_def = db->Resolve(func_id);
func_def->short_name = func.get_spelling();
func_def->qualified_name =
ns->ComputeQualifiedName(db, declaring_type, func_def->short_name);
if (declaring_type && !func_def->declaration) {
db->Resolve(declaring_type.value())->funcs.push_back(func_id);
func_def->declaring_type = declaring_type;
}
// We don't do any additional processing for non-definitions.
if (!func.is_definition()) {
func_def->declaration = func.get_source_location();
return;
}
func_def->definition = func.get_source_location();
//std::cout << "!! Types: ";
//for (clang::Cursor arg : func.get_arguments())
// std::cout << arg.ToString() << ", ";
//std::cout << std::endl;
//std::cout << func.get_usr() << ": Set qualified name to " << db->Resolve(id)->qualified_name;
//std::cout << " IsDefinition? " << func.is_definition() << std::endl;
//clang::Type func_type = func.get_type();
//clang::Type return_type = func_type.get_return_type();
//std::vector<clang::Type> argument_types = func_type.get_arguments();
//auto argument_types = func.get_arguments();
//clang::Type cursor_type = func.get_type();
//clang::Type return_type_1 = func.get_type().get_result();
//clang::Type return_type_2 = clang_getCursorResultType(func.cx_cursor);
//Dump(func);
FuncDefinitionParam funcDefinitionParam(db, &NamespaceStack::kEmpty, func_id);
func.VisitChildren(&VisitFuncDefinition, &funcDefinitionParam);
//CXType return_type = clang_getResultType(func.get_type());
//CXType_FunctionProto
//std::cout << "!! HandleFunc " << func.get_type_description() << std::endl;
//std::cout << " comment: " << func.get_comments() << std::endl;
//std::cout << " spelling: " << func.get_spelling() << std::endl;
//for (clang::Cursor argument : func.get_arguments())
// std::cout << " arg: " << clang::ToString(argument.get_kind()) << " " << argument.get_spelling() << std::endl;
}
struct ClassDeclParam {
ParsingDatabase* db;
NamespaceStack* ns;
TypeId active_type;
ClassDeclParam(ParsingDatabase* db, NamespaceStack* ns, TypeId active_type)
: db(db), ns(ns), active_type(active_type) {}
};
clang::VisiterResult VisitClassDecl(clang::Cursor cursor, clang::Cursor parent, ClassDeclParam* param) {
ParsingDatabase* db = param->db;
switch (cursor.get_kind()) {
case CXCursor_CXXMethod:
HandleFunc(param->db, param->ns, cursor, param->active_type);
break;
case CXCursor_FieldDecl:
case CXCursor_VarDecl:
HandleVarDecl(param->db, param->ns, cursor, param->active_type);
break;
default:
std::cerr << "Unhandled VisitClassDecl kind " << clang::ToString(cursor.get_kind()) << std::endl;
break;
}
return clang::VisiterResult::Continue;
}
void HandleClassDecl(clang::Cursor cursor, ParsingDatabase* db, NamespaceStack* ns) {
TypeId func_id = db->ToTypeId(cursor.get_usr());
TypeDef* func_def = db->Resolve(func_id);
func_def->short_name = cursor.get_spelling();
// TODO: Support nested classes (pass in declaring type insteaad of nullopt!)
func_def->qualified_name =
ns->ComputeQualifiedName(db, std::nullopt, func_def->short_name);
if (!cursor.is_definition()) {
if (!func_def->declaration)
func_def->declaration = cursor.get_source_location();
return;
}
func_def->definition = cursor.get_source_location();
ClassDeclParam classDeclParam(db, ns, func_id);
cursor.VisitChildren(&VisitClassDecl, &classDeclParam);
}
struct FileParam {
ParsingDatabase* db;
NamespaceStack* ns;
FileParam(ParsingDatabase* db, NamespaceStack* ns) : db(db), ns(ns) {}
};
clang::VisiterResult VisitFile(clang::Cursor cursor, clang::Cursor parent, FileParam* param) {
switch (cursor.get_kind()) {
case CXCursor_Namespace:
// For a namespace, visit the children of the namespace, but this time with
// a pushed namespace stack.
param->ns->Push(cursor.get_display_name());
cursor.VisitChildren(&VisitFile, param);
param->ns->Pop();
break;
case CXCursor_StructDecl:
case CXCursor_ClassDecl:
// TODO: Cleanup Handle* param order.
HandleClassDecl(cursor, param->db, param->ns);
break;
case CXCursor_CXXMethod:
case CXCursor_FunctionDecl:
HandleFunc(param->db, param->ns, cursor, std::nullopt);
break;
case CXCursor_VarDecl:
HandleVarDecl(param->db, param->ns, cursor, std::nullopt);
break;
default:
std::cerr << "Unhandled VisitFile kind " << clang::ToString(cursor.get_kind()) << std::endl;
break;
}
return clang::VisiterResult::Continue;
}
ParsingDatabase Parse(std::string filename) {
std::vector<std::string> args;
clang::Index index(0 /*excludeDeclarationsFromPCH*/, 0 /*displayDiagnostics*/);
clang::TranslationUnit tu(index, filename, args);
std::cout << "Start document dump" << std::endl;
Dump(tu.document_cursor());
std::cout << "Done document dump" << std::endl << std::endl;
ParsingDatabase db;
NamespaceStack ns;
FileParam fileParam(&db, &ns);
tu.document_cursor().VisitChildren(&VisitFile, &fileParam);
return db;
}
template<typename T>
bool AreEqual(const std::vector<T>& a, const std::vector<T>& b) {
if (a.size() != b.size())
return false;
for (int i = 0; i < a.size(); ++i) {
if (a[i] != b[i])
return false;
}
return true;
}
void Write(const std::vector<std::string>& strs) {
for (const std::string& str : strs) {
std::cout << str << std::endl;
}
}
std::vector<std::string> split_string(const std::string& str, const std::string& delimiter) {
// http://stackoverflow.com/a/13172514
std::vector<std::string> strings;
std::string::size_type pos = 0;
std::string::size_type prev = 0;
while ((pos = str.find(delimiter, prev)) != std::string::npos) {
strings.push_back(str.substr(prev, pos - prev));
prev = pos + 1;
}
// To get the last substring (or only, if delimiter is not found)
strings.push_back(str.substr(prev));
return strings;
}
void DiffDocuments(rapidjson::Document& expected, rapidjson::Document& actual) {
std::vector<std::string> actual_output;
{
rapidjson::StringBuffer buffer;
rapidjson::PrettyWriter<rapidjson::StringBuffer> writer(buffer);
writer.SetFormatOptions(
rapidjson::PrettyFormatOptions::kFormatSingleLineArray);
writer.SetIndent(' ', 2);
buffer.Clear();
actual.Accept(writer);
actual_output = split_string(buffer.GetString(), "\n");
}
std::vector<std::string> expected_output;
{
rapidjson::StringBuffer buffer;
rapidjson::PrettyWriter<rapidjson::StringBuffer> writer(buffer);
writer.SetFormatOptions(
rapidjson::PrettyFormatOptions::kFormatSingleLineArray);
writer.SetIndent(' ', 2);
buffer.Clear();
expected.Accept(writer);
expected_output = split_string(buffer.GetString(), "\n");
}
int len = std::min(actual_output.size(), expected_output.size());
for (int i = 0; i < len; ++i) {
if (actual_output[i] != expected_output[i]) {
std::cout << "Line " << i << " differs" << std::endl;
std::cout << " expected: " << expected_output[i] << std::endl;
std::cout << " actual: " << actual_output[i] << std::endl;
}
}
if (actual_output.size() > len) {
std::cout << "Additional output in actual:" << std::endl;
for (int i = len; i < actual_output.size(); ++i)
std::cout << " " << actual_output[i] << std::endl;
}
if (expected_output.size() > len) {
std::cout << "Additional output in expected:" << std::endl;
for (int i = len; i < expected_output.size(); ++i)
std::cout << " " << expected_output[i] << std::endl;
}
}
int main(int argc, char** argv) {
for (std::string path : GetFilesInFolder("tests")) {
// TODO: Fix all existing tests.
//if (path != "tests/usage/func_usage_class_inline_var_def.cc") continue;
// Parse expected output from the test, parse it into JSON document.
std::string expected_output;
ParseTestExpectation(path, &expected_output);
rapidjson::Document expected;
expected.Parse(expected_output.c_str());
// Run test.
std::cout << "[START] " << path << std::endl;
ParsingDatabase db = Parse(path);
std::string actual_output = db.ToString();
rapidjson::Document actual;
actual.Parse(actual_output.c_str());
if (actual == expected) {
std::cout << "[PASSED] " << path << std::endl;
}
else {
std::cout << "[FAILED] " << path << std::endl;
std::cout << "Expected output for " << path << ":" << std::endl;
std::cout << expected_output;
std::cout << "Actual output for " << path << ":" << std::endl;
std::cout << actual_output;
std::cout << std::endl;
std::cout << std::endl;
DiffDocuments(expected, actual);
break;
}
}
std::cin.get();
return 0;
}
// TODO: ctor/dtor, copy ctor