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gerrit.mcp.mirantis.com / packaging / sources / thrift / 4f6138b7a2762f1937b49389f72b348736973e22 / . / compiler / cpp / src / main.cc
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/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing,
* software distributed under the License is distributed on an
* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
/**
* thrift - a lightweight cross-language rpc/serialization tool
*
* This file contains the main compiler engine for Thrift, which invokes the
* scanner/parser to build the thrift object tree. The interface generation
* code for each language lives in a file by the language name under the
* generate/ folder, and all parse structures live in parse/
*
*/
#include <cassert>
#include <stdlib.h>
#include <stdio.h>
#include <stdarg.h>
#include <time.h>
#include <string>
#include <algorithm>
#include <sys/types.h>
#include <sys/stat.h>
#include <errno.h>
#include <limits.h>
#ifdef _WIN32
#include <windows.h> /* for GetFullPathName */
#endif
// Careful: must include globals first for extern definitions
#include "globals.h"
#include "platform.h"
#include "main.h"
#include "parse/t_program.h"
#include "parse/t_scope.h"
#include "generate/t_generator.h"
#include "audit/t_audit.h"
#include "version.h"
using namespace std;
/**
* Global program tree
*/
t_program* g_program;
/**
* Global types
*/
t_type* g_type_void;
t_type* g_type_string;
t_type* g_type_binary;
t_type* g_type_slist;
t_type* g_type_bool;
t_type* g_type_i8;
t_type* g_type_i16;
t_type* g_type_i32;
t_type* g_type_i64;
t_type* g_type_double;
/**
* Global scope
*/
t_scope* g_scope;
/**
* Parent scope to also parse types
*/
t_scope* g_parent_scope;
/**
* Prefix for putting types in parent scope
*/
string g_parent_prefix;
/**
* Parsing pass
*/
PARSE_MODE g_parse_mode;
/**
* Current directory of file being parsed
*/
string g_curdir;
/**
* Current file being parsed
*/
string g_curpath;
/**
* Search path for inclusions
*/
vector<string> g_incl_searchpath;
/**
* Global debug state
*/
int g_debug = 0;
/**
* Strictness level
*/
int g_strict = 127;
/**
* Warning level
*/
int g_warn = 1;
/**
* Verbose output
*/
int g_verbose = 0;
/**
* Global time string
*/
char* g_time_str;
/**
* The last parsed doctext comment.
*/
char* g_doctext;
/**
* The location of the last parsed doctext comment.
*/
int g_doctext_lineno;
/**
* The First doctext comment
*/
char* g_program_doctext_candidate;
int g_program_doctext_lineno = 0;
PROGDOCTEXT_STATUS g_program_doctext_status = INVALID;
/**
* Whether or not negative field keys are accepted.
*/
int g_allow_neg_field_keys;
/**
* Whether or not 64-bit constants will generate a warning.
*/
int g_allow_64bit_consts = 0;
/**
* Flags to control code generation
*/
bool gen_recurse = false;
/**
* Flags to control thrift audit
*/
bool g_audit = false;
/**
* Flag to control return status
*/
bool g_return_failure = false;
bool g_audit_fatal = true;
/**
* Win32 doesn't have realpath, so use fallback implementation in that case,
* otherwise this just calls through to realpath
*/
char* saferealpath(const char* path, char* resolved_path) {
#ifdef _WIN32
char buf[MAX_PATH];
char* basename;
DWORD len = GetFullPathName(path, MAX_PATH, buf, &basename);
if (len == 0 || len > MAX_PATH - 1) {
strcpy(resolved_path, path);
} else {
strcpy(resolved_path, buf);
}
// Replace backslashes with forward slashes so the
// rest of the code behaves correctly.
size_t resolved_len = strlen(resolved_path);
for (size_t i = 0; i < resolved_len; i++) {
if (resolved_path[i] == '\\') {
resolved_path[i] = '/';
}
}
return resolved_path;
#else
return realpath(path, resolved_path);
#endif
}
bool check_is_directory(const char* dir_name) {
#ifdef _WIN32
DWORD attributes = ::GetFileAttributesA(dir_name);
if (attributes == INVALID_FILE_ATTRIBUTES) {
fprintf(stderr,
"Output directory %s is unusable: GetLastError() = %ld\n",
dir_name,
GetLastError());
return false;
}
if ((attributes & FILE_ATTRIBUTE_DIRECTORY) != FILE_ATTRIBUTE_DIRECTORY) {
fprintf(stderr, "Output directory %s exists but is not a directory\n", dir_name);
return false;
}
return true;
#else
struct stat sb;
if (stat(dir_name, &sb) < 0) {
fprintf(stderr, "Output directory %s is unusable: %s\n", dir_name, strerror(errno));
return false;
}
if (!S_ISDIR(sb.st_mode)) {
fprintf(stderr, "Output directory %s exists but is not a directory\n", dir_name);
return false;
}
return true;
#endif
}
/**
* Report an error to the user. This is called yyerror for historical
* reasons (lex and yacc expect the error reporting routine to be called
* this). Call this function to report any errors to the user.
* yyerror takes printf style arguments.
*
* @param fmt C format string followed by additional arguments
*/
void yyerror(const char* fmt, ...) {
va_list args;
fprintf(stderr, "[ERROR:%s:%d] (last token was '%s')\n", g_curpath.c_str(), yylineno, yytext);
va_start(args, fmt);
vfprintf(stderr, fmt, args);
va_end(args);
fprintf(stderr, "\n");
}
/**
* Prints a debug message from the parser.
*
* @param fmt C format string followed by additional arguments
*/
void pdebug(const char* fmt, ...) {
if (g_debug == 0) {
return;
}
va_list args;
printf("[PARSE:%d] ", yylineno);
va_start(args, fmt);
vprintf(fmt, args);
va_end(args);
printf("\n");
}
/**
* Prints a verbose output mode message
*
* @param fmt C format string followed by additional arguments
*/
void pverbose(const char* fmt, ...) {
if (g_verbose == 0) {
return;
}
va_list args;
va_start(args, fmt);
vprintf(fmt, args);
va_end(args);
}
/**
* Prints a warning message
*
* @param fmt C format string followed by additional arguments
*/
void pwarning(int level, const char* fmt, ...) {
if (g_warn < level) {
return;
}
va_list args;
printf("[WARNING:%s:%d] ", g_curpath.c_str(), yylineno);
va_start(args, fmt);
vprintf(fmt, args);
va_end(args);
printf("\n");
}
/**
* Prints a failure message and exits
*
* @param fmt C format string followed by additional arguments
*/
void failure(const char* fmt, ...) {
va_list args;
fprintf(stderr, "[FAILURE:%s:%d] ", g_curpath.c_str(), yylineno);
va_start(args, fmt);
vfprintf(stderr, fmt, args);
va_end(args);
printf("\n");
exit(1);
}
/**
* Converts a string filename into a thrift program name
*/
string program_name(string filename) {
string::size_type slash = filename.rfind("/");
if (slash != string::npos) {
filename = filename.substr(slash + 1);
}
string::size_type dot = filename.rfind(".");
if (dot != string::npos) {
filename = filename.substr(0, dot);
}
return filename;
}
/**
* Gets the directory path of a filename
*/
string directory_name(string filename) {
string::size_type slash = filename.rfind("/");
// No slash, just use the current directory
if (slash == string::npos) {
return ".";
}
return filename.substr(0, slash);
}
/**
* Finds the appropriate file path for the given filename
*/
string include_file(string filename) {
// Absolute path? Just try that
if (filename[0] == '/') {
// Realpath!
char rp[THRIFT_PATH_MAX];
if (saferealpath(filename.c_str(), rp) == NULL) {
pwarning(0, "Cannot open include file %s\n", filename.c_str());
return std::string();
}
// Stat this file
struct stat finfo;
if (stat(rp, &finfo) == 0) {
return rp;
}
} else { // relative path, start searching
// new search path with current dir global
vector<string> sp = g_incl_searchpath;
sp.insert(sp.begin(), g_curdir);
// iterate through paths
vector<string>::iterator it;
for (it = sp.begin(); it != sp.end(); it++) {
string sfilename = *(it) + "/" + filename;
// Realpath!
char rp[THRIFT_PATH_MAX];
if (saferealpath(sfilename.c_str(), rp) == NULL) {
continue;
}
// Stat this files
struct stat finfo;
if (stat(rp, &finfo) == 0) {
return rp;
}
}
}
// Uh oh
pwarning(0, "Could not find include file %s\n", filename.c_str());
return std::string();
}
/**
* Clears any previously stored doctext string.
* Also prints a warning if we are discarding information.
*/
void clear_doctext() {
if (g_doctext != NULL) {
pwarning(2, "Uncaptured doctext at on line %d.", g_doctext_lineno);
}
free(g_doctext);
g_doctext = NULL;
}
/**
* Reset program doctext information after processing a file
*/
void reset_program_doctext_info() {
if (g_program_doctext_candidate != NULL) {
free(g_program_doctext_candidate);
g_program_doctext_candidate = NULL;
}
g_program_doctext_lineno = 0;
g_program_doctext_status = INVALID;
pdebug("%s", "program doctext set to INVALID");
}
/**
* We are sure the program doctext candidate is really the program doctext.
*/
void declare_valid_program_doctext() {
if ((g_program_doctext_candidate != NULL) && (g_program_doctext_status == STILL_CANDIDATE)) {
g_program_doctext_status = ABSOLUTELY_SURE;
pdebug("%s", "program doctext set to ABSOLUTELY_SURE");
} else {
g_program_doctext_status = NO_PROGRAM_DOCTEXT;
pdebug("%s", "program doctext set to NO_PROGRAM_DOCTEXT");
}
}
/**
* Cleans up text commonly found in doxygen-like comments
*
* Warning: if you mix tabs and spaces in a non-uniform way,
* you will get what you deserve.
*/
char* clean_up_doctext(char* doctext) {
// Convert to C++ string, and remove Windows's carriage returns.
string docstring = doctext;
docstring.erase(remove(docstring.begin(), docstring.end(), '\r'), docstring.end());
// Separate into lines.
vector<string> lines;
string::size_type pos = string::npos;
string::size_type last;
while (true) {
last = (pos == string::npos) ? 0 : pos + 1;
pos = docstring.find('\n', last);
if (pos == string::npos) {
// First bit of cleaning. If the last line is only whitespace, drop it.
string::size_type nonwhite = docstring.find_first_not_of(" \t", last);
if (nonwhite != string::npos) {
lines.push_back(docstring.substr(last));
}
break;
}
lines.push_back(docstring.substr(last, pos - last));
}
// A very profound docstring.
if (lines.empty()) {
return NULL;
}
// Clear leading whitespace from the first line.
pos = lines.front().find_first_not_of(" \t");
lines.front().erase(0, pos);
// If every nonblank line after the first has the same number of spaces/tabs,
// then a star, remove them.
bool have_prefix = true;
bool found_prefix = false;
string::size_type prefix_len = 0;
vector<string>::iterator l_iter;
for (l_iter = lines.begin() + 1; l_iter != lines.end(); ++l_iter) {
if (l_iter->empty()) {
continue;
}
pos = l_iter->find_first_not_of(" \t");
if (!found_prefix) {
if (pos != string::npos) {
if (l_iter->at(pos) == '*') {
found_prefix = true;
prefix_len = pos;
} else {
have_prefix = false;
break;
}
} else {
// Whitespace-only line. Truncate it.
l_iter->clear();
}
} else if (l_iter->size() > pos && l_iter->at(pos) == '*' && pos == prefix_len) {
// Business as usual.
} else if (pos == string::npos) {
// Whitespace-only line. Let's truncate it for them.
l_iter->clear();
} else {
// The pattern has been broken.
have_prefix = false;
break;
}
}
// If our prefix survived, delete it from every line.
if (have_prefix) {
// Get the star too.
prefix_len++;
for (l_iter = lines.begin() + 1; l_iter != lines.end(); ++l_iter) {
l_iter->erase(0, prefix_len);
}
}
// Now delete the minimum amount of leading whitespace from each line.
prefix_len = string::npos;
for (l_iter = lines.begin() + 1; l_iter != lines.end(); ++l_iter) {
if (l_iter->empty()) {
continue;
}
pos = l_iter->find_first_not_of(" \t");
if (pos != string::npos && (prefix_len == string::npos || pos < prefix_len)) {
prefix_len = pos;
}
}
// If our prefix survived, delete it from every line.
if (prefix_len != string::npos) {
for (l_iter = lines.begin() + 1; l_iter != lines.end(); ++l_iter) {
l_iter->erase(0, prefix_len);
}
}
// Remove trailing whitespace from every line.
for (l_iter = lines.begin(); l_iter != lines.end(); ++l_iter) {
pos = l_iter->find_last_not_of(" \t");
if (pos != string::npos && pos != l_iter->length() - 1) {
l_iter->erase(pos + 1);
}
}
// If the first line is empty, remove it.
// Don't do this earlier because a lot of steps skip the first line.
if (lines.front().empty()) {
lines.erase(lines.begin());
}
// Now rejoin the lines and copy them back into doctext.
docstring.clear();
for (l_iter = lines.begin(); l_iter != lines.end(); ++l_iter) {
docstring += *l_iter;
docstring += '\n';
}
// assert(docstring.length() <= strlen(doctext)); may happen, see THRIFT-1755
if (docstring.length() <= strlen(doctext)) {
strcpy(doctext, docstring.c_str());
} else {
free(doctext); // too short
doctext = strdup(docstring.c_str());
}
return doctext;
}
/** Set to true to debug docstring parsing */
static bool dump_docs = false;
/**
* Dumps docstrings to stdout
* Only works for top-level definitions and the whole program doc
* (i.e., not enum constants, struct fields, or functions.
*/
void dump_docstrings(t_program* program) {
string progdoc = program->get_doc();
if (!progdoc.empty()) {
printf("Whole program doc:\n%s\n", progdoc.c_str());
}
const vector<t_typedef*>& typedefs = program->get_typedefs();
vector<t_typedef*>::const_iterator t_iter;
for (t_iter = typedefs.begin(); t_iter != typedefs.end(); ++t_iter) {
t_typedef* td = *t_iter;
if (td->has_doc()) {
printf("typedef %s:\n%s\n", td->get_name().c_str(), td->get_doc().c_str());
}
}
const vector<t_enum*>& enums = program->get_enums();
vector<t_enum*>::const_iterator e_iter;
for (e_iter = enums.begin(); e_iter != enums.end(); ++e_iter) {
t_enum* en = *e_iter;
if (en->has_doc()) {
printf("enum %s:\n%s\n", en->get_name().c_str(), en->get_doc().c_str());
}
}
const vector<t_const*>& consts = program->get_consts();
vector<t_const*>::const_iterator c_iter;
for (c_iter = consts.begin(); c_iter != consts.end(); ++c_iter) {
t_const* co = *c_iter;
if (co->has_doc()) {
printf("const %s:\n%s\n", co->get_name().c_str(), co->get_doc().c_str());
}
}
const vector<t_struct*>& structs = program->get_structs();
vector<t_struct*>::const_iterator s_iter;
for (s_iter = structs.begin(); s_iter != structs.end(); ++s_iter) {
t_struct* st = *s_iter;
if (st->has_doc()) {
printf("struct %s:\n%s\n", st->get_name().c_str(), st->get_doc().c_str());
}
}
const vector<t_struct*>& xceptions = program->get_xceptions();
vector<t_struct*>::const_iterator x_iter;
for (x_iter = xceptions.begin(); x_iter != xceptions.end(); ++x_iter) {
t_struct* xn = *x_iter;
if (xn->has_doc()) {
printf("xception %s:\n%s\n", xn->get_name().c_str(), xn->get_doc().c_str());
}
}
const vector<t_service*>& services = program->get_services();
vector<t_service*>::const_iterator v_iter;
for (v_iter = services.begin(); v_iter != services.end(); ++v_iter) {
t_service* sv = *v_iter;
if (sv->has_doc()) {
printf("service %s:\n%s\n", sv->get_name().c_str(), sv->get_doc().c_str());
}
}
}
/**
* Emits a warning on list<byte>, binary type is typically a much better choice.
*/
void check_for_list_of_bytes(t_type* list_elem_type) {
if ((g_parse_mode == PROGRAM) && (list_elem_type != NULL) && list_elem_type->is_base_type()) {
t_base_type* tbase = (t_base_type*)list_elem_type;
if (tbase->get_base() == t_base_type::TYPE_I8) {
pwarning(1, "Consider using the more efficient \"binary\" type instead of \"list<byte>\".");
}
}
}
static bool g_byte_warning_emitted = false;
/**
* Emits a one-time warning on byte type, promoting the new i8 type instead
*/
void emit_byte_type_warning() {
if (!g_byte_warning_emitted) {
pwarning(1,
"The \"byte\" type is a compatibility alias for \"i8\". Use \"i8\" to emphasize the "
"signedness of this type.\n");
g_byte_warning_emitted = true;
}
}
/**
* Prints deprecation notice for old NS declarations that are no longer supported
* If new_form is NULL, old_form is assumed to be a language identifier, such as "cpp"
* If new_form is not NULL, both arguments are used exactly as given
*/
void error_unsupported_namespace_decl(char* old_form, char* new_form) {
char* remainder = "";
if( new_form == NULL) {
new_form = old_form;
remainder = "_namespace";
}
failure("Unsupported declaration '%s%s'. Use 'namespace %s' instead.", old_form, remainder, new_form);
}
/**
* Prints the version number
*/
void version() {
printf("Thrift version %s\n", THRIFT_VERSION);
}
/**
* Display the usage message and then exit with an error code.
*/
void usage() {
fprintf(stderr, "Usage: thrift [options] file\n\n");
fprintf(stderr, "Use thrift -help for a list of options\n");
exit(1);
}
/**
* Diplays the help message and then exits with an error code.
*/
void help() {
fprintf(stderr, "Usage: thrift [options] file\n");
fprintf(stderr, "Options:\n");
fprintf(stderr, " -version Print the compiler version\n");
fprintf(stderr, " -o dir Set the output directory for gen-* packages\n");
fprintf(stderr, " (default: current directory)\n");
fprintf(stderr, " -out dir Set the ouput location for generated files.\n");
fprintf(stderr, " (no gen-* folder will be created)\n");
fprintf(stderr, " -I dir Add a directory to the list of directories\n");
fprintf(stderr, " searched for include directives\n");
fprintf(stderr, " -nowarn Suppress all compiler warnings (BAD!)\n");
fprintf(stderr, " -strict Strict compiler warnings on\n");
fprintf(stderr, " -v[erbose] Verbose mode\n");
fprintf(stderr, " -r[ecurse] Also generate included files\n");
fprintf(stderr, " -debug Parse debug trace to stdout\n");
fprintf(stderr,
" --allow-neg-keys Allow negative field keys (Used to "
"preserve protocol\n");
fprintf(stderr, " compatibility with older .thrift files)\n");
fprintf(stderr, " --allow-64bit-consts Do not print warnings about using 64-bit constants\n");
fprintf(stderr, " --gen STR Generate code with a dynamically-registered generator.\n");
fprintf(stderr, " STR has the form language[:key1=val1[,key2[,key3=val3]]].\n");
fprintf(stderr, " Keys and values are options passed to the generator.\n");
fprintf(stderr, " Many options will not require values.\n");
fprintf(stderr, "\n");
fprintf(stderr, "Options related to audit operation\n");
fprintf(stderr, " --audit OldFile Old Thrift file to be audited with 'file'\n");
fprintf(stderr, " -Iold dir Add a directory to the list of directories\n");
fprintf(stderr, " searched for include directives for old thrift file\n");
fprintf(stderr, " -Inew dir Add a directory to the list of directories\n");
fprintf(stderr, " searched for include directives for new thrift file\n");
fprintf(stderr, "\n");
fprintf(stderr, "Available generators (and options):\n");
t_generator_registry::gen_map_t gen_map = t_generator_registry::get_generator_map();
t_generator_registry::gen_map_t::iterator iter;
for (iter = gen_map.begin(); iter != gen_map.end(); ++iter) {
fprintf(stderr,
" %s (%s):\n",
iter->second->get_short_name().c_str(),
iter->second->get_long_name().c_str());
fprintf(stderr, "%s", iter->second->get_documentation().c_str());
}
exit(1);
}
/**
* You know, when I started working on Thrift I really thought it wasn't going
* to become a programming language because it was just a generator and it
* wouldn't need runtime type information and all that jazz. But then we
* decided to add constants, and all of a sudden that means runtime type
* validation and inference, except the "runtime" is the code generator
* runtime.
*/
void validate_const_rec(std::string name, t_type* type, t_const_value* value) {
if (type->is_void()) {
throw "type error: cannot declare a void const: " + name;
}
if (type->is_base_type()) {
t_base_type::t_base tbase = ((t_base_type*)type)->get_base();
switch (tbase) {
case t_base_type::TYPE_STRING:
if (value->get_type() != t_const_value::CV_STRING) {
throw "type error: const \"" + name + "\" was declared as string";
}
break;
case t_base_type::TYPE_BOOL:
if (value->get_type() != t_const_value::CV_INTEGER) {
throw "type error: const \"" + name + "\" was declared as bool";
}
break;
case t_base_type::TYPE_I8:
if (value->get_type() != t_const_value::CV_INTEGER) {
throw "type error: const \"" + name + "\" was declared as byte";
}
break;
case t_base_type::TYPE_I16:
if (value->get_type() != t_const_value::CV_INTEGER) {
throw "type error: const \"" + name + "\" was declared as i16";
}
break;
case t_base_type::TYPE_I32:
if (value->get_type() != t_const_value::CV_INTEGER) {
throw "type error: const \"" + name + "\" was declared as i32";
}
break;
case t_base_type::TYPE_I64:
if (value->get_type() != t_const_value::CV_INTEGER) {
throw "type error: const \"" + name + "\" was declared as i64";
}
break;
case t_base_type::TYPE_DOUBLE:
if (value->get_type() != t_const_value::CV_INTEGER
&& value->get_type() != t_const_value::CV_DOUBLE) {
throw "type error: const \"" + name + "\" was declared as double";
}
break;
default:
throw "compiler error: no const of base type " + t_base_type::t_base_name(tbase) + name;
}
} else if (type->is_enum()) {
if (value->get_type() != t_const_value::CV_IDENTIFIER) {
throw "type error: const \"" + name + "\" was declared as enum";
}
// see if there's a dot in the identifier
std::string name_portion = value->get_identifier_name();
const vector<t_enum_value*>& enum_values = ((t_enum*)type)->get_constants();
vector<t_enum_value*>::const_iterator c_iter;
bool found = false;
for (c_iter = enum_values.begin(); c_iter != enum_values.end(); ++c_iter) {
if ((*c_iter)->get_name() == name_portion) {
found = true;
break;
}
}
if (!found) {
throw "type error: const " + name + " was declared as type " + type->get_name()
+ " which is an enum, but " + value->get_identifier()
+ " is not a valid value for that enum";
}
} else if (type->is_struct() || type->is_xception()) {
if (value->get_type() != t_const_value::CV_MAP) {
throw "type error: const \"" + name + "\" was declared as struct/xception";
}
const vector<t_field*>& fields = ((t_struct*)type)->get_members();
vector<t_field*>::const_iterator f_iter;
const map<t_const_value*, t_const_value*>& val = value->get_map();
map<t_const_value*, t_const_value*>::const_iterator v_iter;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
if (v_iter->first->get_type() != t_const_value::CV_STRING) {
throw "type error: " + name + " struct key must be string";
}
t_type* field_type = NULL;
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter) {
if ((*f_iter)->get_name() == v_iter->first->get_string()) {
field_type = (*f_iter)->get_type();
}
}
if (field_type == NULL) {
throw "type error: " + type->get_name() + " has no field " + v_iter->first->get_string();
}
validate_const_rec(name + "." + v_iter->first->get_string(), field_type, v_iter->second);
}
} else if (type->is_map()) {
t_type* k_type = ((t_map*)type)->get_key_type();
t_type* v_type = ((t_map*)type)->get_val_type();
const map<t_const_value*, t_const_value*>& val = value->get_map();
map<t_const_value*, t_const_value*>::const_iterator v_iter;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
validate_const_rec(name + "<key>", k_type, v_iter->first);
validate_const_rec(name + "<val>", v_type, v_iter->second);
}
} else if (type->is_list() || type->is_set()) {
t_type* e_type;
if (type->is_list()) {
e_type = ((t_list*)type)->get_elem_type();
} else {
e_type = ((t_set*)type)->get_elem_type();
}
const vector<t_const_value*>& val = value->get_list();
vector<t_const_value*>::const_iterator v_iter;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
validate_const_rec(name + "<elem>", e_type, *v_iter);
}
}
}
/**
* Check simple identifier names
* It's easier to do it this way instead of rewriting the whole grammar etc.
*/
void validate_simple_identifier(const char* identifier) {
string name(identifier);
if (name.find(".") != string::npos) {
yyerror("Identifier %s can't have a dot.", identifier);
exit(1);
}
}
/**
* Check the type of the parsed const information against its declared type
*/
void validate_const_type(t_const* c) {
validate_const_rec(c->get_name(), c->get_type(), c->get_value());
}
/**
* Check the type of a default value assigned to a field.
*/
void validate_field_value(t_field* field, t_const_value* cv) {
validate_const_rec(field->get_name(), field->get_type(), cv);
}
/**
* Check that all the elements of a throws block are actually exceptions.
*/
bool validate_throws(t_struct* throws) {
const vector<t_field*>& members = throws->get_members();
vector<t_field*>::const_iterator m_iter;
for (m_iter = members.begin(); m_iter != members.end(); ++m_iter) {
if (!t_generator::get_true_type((*m_iter)->get_type())->is_xception()) {
return false;
}
}
return true;
}
/**
* Skips UTF-8 BOM if there is one
*/
bool skip_utf8_bom(FILE* f) {
// pretty straightforward, but works
if (fgetc(f) == 0xEF) {
if (fgetc(f) == 0xBB) {
if (fgetc(f) == 0xBF) {
return true;
}
}
}
rewind(f);
return false;
}
/**
* Parses a program
*/
void parse(t_program* program, t_program* parent_program) {
// Get scope file path
string path = program->get_path();
// Set current dir global, which is used in the include_file function
g_curdir = directory_name(path);
g_curpath = path;
// Open the file
// skip UTF-8 BOM if there is one
yyin = fopen(path.c_str(), "r");
if (yyin == 0) {
failure("Could not open input file: \"%s\"", path.c_str());
}
if (skip_utf8_bom(yyin))
pverbose("Skipped UTF-8 BOM at %s\n", path.c_str());
// Create new scope and scan for includes
pverbose("Scanning %s for includes\n", path.c_str());
g_parse_mode = INCLUDES;
g_program = program;
g_scope = program->scope();
try {
yylineno = 1;
if (yyparse() != 0) {
failure("Parser error during include pass.");
}
} catch (string x) {
failure(x.c_str());
}
fclose(yyin);
// Recursively parse all the include programs
vector<t_program*>& includes = program->get_includes();
vector<t_program*>::iterator iter;
for (iter = includes.begin(); iter != includes.end(); ++iter) {
parse(*iter, program);
}
// reset program doctext status before parsing a new file
reset_program_doctext_info();
// Parse the program file
g_parse_mode = PROGRAM;
g_program = program;
g_scope = program->scope();
g_parent_scope = (parent_program != NULL) ? parent_program->scope() : NULL;
g_parent_prefix = program->get_name() + ".";
g_curpath = path;
// Open the file
// skip UTF-8 BOM if there is one
yyin = fopen(path.c_str(), "r");
if (yyin == 0) {
failure("Could not open input file: \"%s\"", path.c_str());
}
if (skip_utf8_bom(yyin))
pverbose("Skipped UTF-8 BOM at %s\n", path.c_str());
pverbose("Parsing %s for types\n", path.c_str());
yylineno = 1;
try {
if (yyparse() != 0) {
failure("Parser error during types pass.");
}
} catch (string x) {
failure(x.c_str());
}
fclose(yyin);
}
/**
* Generate code
*/
void generate(t_program* program, const vector<string>& generator_strings) {
// Oooohh, recursive code generation, hot!!
if (gen_recurse) {
const vector<t_program*>& includes = program->get_includes();
for (size_t i = 0; i < includes.size(); ++i) {
// Propagate output path from parent to child programs
includes[i]->set_out_path(program->get_out_path(), program->is_out_path_absolute());
generate(includes[i], generator_strings);
}
}
// Generate code!
try {
pverbose("Program: %s\n", program->get_path().c_str());
// Compute fingerprints. - not anymore, we do it on the fly now
// generate_all_fingerprints(program);
if (dump_docs) {
dump_docstrings(program);
}
vector<string>::const_iterator iter;
for (iter = generator_strings.begin(); iter != generator_strings.end(); ++iter) {
t_generator* generator = t_generator_registry::get_generator(program, *iter);
if (generator == NULL) {
pwarning(1, "Unable to get a generator for \"%s\".\n", iter->c_str());
} else {
pverbose("Generating \"%s\"\n", iter->c_str());
generator->generate_program();
delete generator;
}
}
} catch (string s) {
printf("Error: %s\n", s.c_str());
} catch (const char* exc) {
printf("Error: %s\n", exc);
}
}
void audit(t_program* new_program,
t_program* old_program,
string new_thrift_include_path,
string old_thrift_include_path) {
vector<string> temp_incl_searchpath = g_incl_searchpath;
if (!old_thrift_include_path.empty()) {
g_incl_searchpath.push_back(old_thrift_include_path);
}
parse(old_program, NULL);
g_incl_searchpath = temp_incl_searchpath;
if (!new_thrift_include_path.empty()) {
g_incl_searchpath.push_back(new_thrift_include_path);
}
parse(new_program, NULL);
compare_namespace(new_program, old_program);
compare_services(new_program->get_services(), old_program->get_services());
compare_enums(new_program->get_enums(), old_program->get_enums());
compare_structs(new_program->get_structs(), old_program->get_structs());
compare_structs(new_program->get_xceptions(), old_program->get_xceptions());
compare_consts(new_program->get_consts(), old_program->get_consts());
}
/**
* Parse it up.. then spit it back out, in pretty much every language. Alright
* not that many languages, but the cool ones that we care about.
*/
int main(int argc, char** argv) {
int i;
std::string out_path;
bool out_path_is_absolute = false;
// Setup time string
time_t now = time(NULL);
g_time_str = ctime(&now);
// Check for necessary arguments, you gotta have at least a filename and
// an output language flag
if (argc < 2) {
usage();
}
vector<string> generator_strings;
string old_thrift_include_path;
string new_thrift_include_path;
string old_input_file;
// Set the current path to a dummy value to make warning messages clearer.
g_curpath = "arguments";
// Hacky parameter handling... I didn't feel like using a library sorry!
for (i = 1; i < argc - 1; i++) {
char* arg;
arg = strtok(argv[i], " ");
while (arg != NULL) {
// Treat double dashes as single dashes
if (arg[0] == '-' && arg[1] == '-') {
++arg;
}
if (strcmp(arg, "-help") == 0) {
help();
} else if (strcmp(arg, "-version") == 0) {
version();
exit(0);
} else if (strcmp(arg, "-debug") == 0) {
g_debug = 1;
} else if (strcmp(arg, "-nowarn") == 0) {
g_warn = 0;
} else if (strcmp(arg, "-strict") == 0) {
g_strict = 255;
g_warn = 2;
} else if (strcmp(arg, "-v") == 0 || strcmp(arg, "-verbose") == 0) {
g_verbose = 1;
} else if (strcmp(arg, "-r") == 0 || strcmp(arg, "-recurse") == 0) {
gen_recurse = true;
} else if (strcmp(arg, "-allow-neg-keys") == 0) {
g_allow_neg_field_keys = true;
} else if (strcmp(arg, "-allow-64bit-consts") == 0) {
g_allow_64bit_consts = true;
} else if (strcmp(arg, "-gen") == 0) {
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "Missing generator specification\n");
usage();
}
generator_strings.push_back(arg);
} else if (strcmp(arg, "-I") == 0) {
// An argument of "-I\ asdf" is invalid and has unknown results
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "Missing Include directory\n");
usage();
}
g_incl_searchpath.push_back(arg);
} else if ((strcmp(arg, "-o") == 0) || (strcmp(arg, "-out") == 0)) {
out_path_is_absolute = (strcmp(arg, "-out") == 0) ? true : false;
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "-o: missing output directory\n");
usage();
}
out_path = arg;
#ifdef _WIN32
// strip out trailing \ on Windows
std::string::size_type last = out_path.length() - 1;
if (out_path[last] == '\\') {
out_path.erase(last);
}
#endif
if (!check_is_directory(out_path.c_str()))
return -1;
} else if (strcmp(arg, "-audit") == 0) {
g_audit = true;
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "Missing old thrift file name for audit operation\n");
usage();
}
char old_thrift_file_rp[THRIFT_PATH_MAX];
if (saferealpath(arg, old_thrift_file_rp) == NULL) {
failure("Could not open input file with realpath: %s", arg);
}
old_input_file = string(old_thrift_file_rp);
} else if (strcmp(arg, "-audit-nofatal") == 0) {
g_audit_fatal = false;
} else if (strcmp(arg, "-Iold") == 0) {
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "Missing Include directory for old thrift file\n");
usage();
}
old_thrift_include_path = string(arg);
} else if (strcmp(arg, "-Inew") == 0) {
arg = argv[++i];
if (arg == NULL) {
fprintf(stderr, "Missing Include directory for new thrift file\n");
usage();
}
new_thrift_include_path = string(arg);
} else {
fprintf(stderr, "Unrecognized option: %s\n", arg);
usage();
}
// Tokenize more
arg = strtok(NULL, " ");
}
}
// display help
if ((strcmp(argv[argc - 1], "-help") == 0) || (strcmp(argv[argc - 1], "--help") == 0)) {
help();
}
// if you're asking for version, you have a right not to pass a file
if ((strcmp(argv[argc - 1], "-version") == 0) || (strcmp(argv[argc - 1], "--version") == 0)) {
version();
exit(0);
}
// Initialize global types
g_type_void = new t_base_type("void", t_base_type::TYPE_VOID);
g_type_string = new t_base_type("string", t_base_type::TYPE_STRING);
g_type_binary = new t_base_type("string", t_base_type::TYPE_STRING);
((t_base_type*)g_type_binary)->set_binary(true);
g_type_slist = new t_base_type("string", t_base_type::TYPE_STRING);
((t_base_type*)g_type_slist)->set_string_list(true);
g_type_bool = new t_base_type("bool", t_base_type::TYPE_BOOL);
g_type_i8 = new t_base_type("i8", t_base_type::TYPE_I8);
g_type_i16 = new t_base_type("i16", t_base_type::TYPE_I16);
g_type_i32 = new t_base_type("i32", t_base_type::TYPE_I32);
g_type_i64 = new t_base_type("i64", t_base_type::TYPE_I64);
g_type_double = new t_base_type("double", t_base_type::TYPE_DOUBLE);
if (g_audit) {
// Audit operation
if (old_input_file.empty()) {
fprintf(stderr, "Missing file name of old thrift file for audit\n");
usage();
}
char new_thrift_file_rp[THRIFT_PATH_MAX];
if (argv[i] == NULL) {
fprintf(stderr, "Missing file name of new thrift file for audit\n");
usage();
}
if (saferealpath(argv[i], new_thrift_file_rp) == NULL) {
failure("Could not open input file with realpath: %s", argv[i]);
}
string new_input_file(new_thrift_file_rp);
t_program new_program(new_input_file);
t_program old_program(old_input_file);
audit(&new_program, &old_program, new_thrift_include_path, old_thrift_include_path);
} else {
// Generate options
// You gotta generate something!
if (generator_strings.empty()) {
fprintf(stderr, "No output language(s) specified\n");
usage();
}
// Real-pathify it
char rp[THRIFT_PATH_MAX];
if (argv[i] == NULL) {
fprintf(stderr, "Missing file name\n");
usage();
}
if (saferealpath(argv[i], rp) == NULL) {
failure("Could not open input file with realpath: %s", argv[i]);
}
string input_file(rp);
// Instance of the global parse tree
t_program* program = new t_program(input_file);
if (out_path.size()) {
program->set_out_path(out_path, out_path_is_absolute);
}
// Compute the cpp include prefix.
// infer this from the filename passed in
string input_filename = argv[i];
string include_prefix;
string::size_type last_slash = string::npos;
if ((last_slash = input_filename.rfind("/")) != string::npos) {
include_prefix = input_filename.substr(0, last_slash);
}
program->set_include_prefix(include_prefix);
// Parse it!
parse(program, NULL);
// The current path is not really relevant when we are doing generation.
// Reset the variable to make warning messages clearer.
g_curpath = "generation";
// Reset yylineno for the heck of it. Use 1 instead of 0 because
// That is what shows up during argument parsing.
yylineno = 1;
// Generate it!
generate(program, generator_strings);
delete program;
}
// Clean up. Who am I kidding... this program probably orphans heap memory
// all over the place, but who cares because it is about to exit and it is
// all referenced and used by this wacky parse tree up until now anyways.
delete g_type_void;
delete g_type_string;
delete g_type_bool;
delete g_type_i8;
delete g_type_i16;
delete g_type_i32;
delete g_type_i64;
delete g_type_double;
// Finished
if (g_return_failure && g_audit_fatal) {
exit(2);
}
// Finished
return 0;
}