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apache / thrift / 0.7.x / . / compiler / cpp / src / generate / t_hs_generator.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.
*/
#include <string>
#include <fstream>
#include <iostream>
#include <vector>
#include <stdlib.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sstream>
#include "t_oop_generator.h"
#include "platform.h"
#include "version.h"
using namespace std;
/**
* Haskell code generator.
*
*/
class t_hs_generator : public t_oop_generator {
public:
t_hs_generator(t_program* program,
const map<string, string>& parsed_options,
const string& option_string)
: t_oop_generator(program)
{
(void) parsed_options;
(void) option_string;
out_dir_base_ = "gen-hs";
}
/**
* Init and close methods
*/
void init_generator();
void close_generator();
/**
* Program-level generation functions
*/
void generate_typedef (t_typedef* ttypedef);
void generate_enum (t_enum* tenum);
void generate_const (t_const* tconst);
void generate_struct (t_struct* tstruct);
void generate_xception (t_struct* txception);
void generate_service (t_service* tservice);
string render_const_value(t_type* type, t_const_value* value);
/**
* Struct generation code
*/
void generate_hs_struct (t_struct* tstruct,
bool is_exception);
void generate_hs_struct_definition (ofstream &out,
t_struct* tstruct,
bool is_xception = false,
bool helper = false);
void generate_hs_struct_reader (ofstream& out,
t_struct* tstruct);
void generate_hs_struct_writer (ofstream& out,
t_struct* tstruct);
void generate_hs_function_helpers (t_function* tfunction);
/**
* Service-level generation functions
*/
void generate_service_helpers (t_service* tservice);
void generate_service_interface (t_service* tservice);
void generate_service_client (t_service* tservice);
void generate_service_server (t_service* tservice);
void generate_process_function (t_service* tservice,
t_function* tfunction);
/**
* Serialization constructs
*/
void generate_deserialize_field (ofstream &out,
t_field* tfield,
string prefix);
void generate_deserialize_struct (ofstream &out,
t_struct* tstruct);
void generate_deserialize_container (ofstream &out,
t_type* ttype);
void generate_deserialize_set_element (ofstream &out,
t_set* tset);
void generate_deserialize_list_element (ofstream &out,
t_list* tlist,
string prefix = "");
void generate_deserialize_type (ofstream &out,
t_type* type);
void generate_serialize_field (ofstream &out,
t_field* tfield,
string name = "");
void generate_serialize_struct (ofstream &out,
t_struct* tstruct,
string prefix = "");
void generate_serialize_container (ofstream &out,
t_type* ttype,
string prefix = "");
void generate_serialize_map_element (ofstream &out,
t_map* tmap,
string kiter,
string viter);
void generate_serialize_set_element (ofstream &out,
t_set* tmap,
string iter);
void generate_serialize_list_element (ofstream &out,
t_list* tlist,
string iter);
/**
* Helper rendering functions
*/
string hs_autogen_comment();
string hs_language_pragma();
string hs_imports();
string type_name(t_type* ttype,
string function_prefix = "");
string function_type(t_function* tfunc,
bool options = false,
bool io = false,
bool method = false);
string type_to_enum(t_type* ttype);
string render_hs_type(t_type* type,
bool needs_parens = true);
private:
ofstream f_types_;
ofstream f_consts_;
ofstream f_service_;
ofstream f_iface_;
ofstream f_client_;
};
/**
* Prepares for file generation by opening up the necessary file output
* streams.
*
* @param tprogram The program to generate
*/
void t_hs_generator::init_generator() {
// Make output directory
MKDIR(get_out_dir().c_str());
// Make output file
string pname = capitalize(program_name_);
string f_types_name = get_out_dir() + pname + "_Types.hs";
f_types_.open(f_types_name.c_str());
string f_consts_name = get_out_dir() + pname + "_Consts.hs";
f_consts_.open(f_consts_name.c_str());
// Print header
f_types_ << hs_language_pragma() << endl;
f_types_ << hs_autogen_comment() << endl;
f_types_ << "module " << pname << "_Types where" << endl;
f_types_ << hs_imports() << endl;
f_consts_ << hs_language_pragma() << endl;
f_consts_ << hs_autogen_comment() << endl;
f_consts_ << "module " << pname << "_Consts where" << endl;
f_consts_ << hs_imports() << endl;
f_consts_ << "import " << pname << "_Types" << endl;
}
string t_hs_generator::hs_language_pragma() {
return string("{-# LANGUAGE DeriveDataTypeable #-}\n"
"{-# OPTIONS_GHC -fno-warn-missing-fields #-}\n"
"{-# OPTIONS_GHC -fno-warn-missing-signatures #-}\n"
"{-# OPTIONS_GHC -fno-warn-name-shadowing #-}\n"
"{-# OPTIONS_GHC -fno-warn-unused-imports #-}\n"
"{-# OPTIONS_GHC -fno-warn-unused-matches #-}\n");
}
/**
* Autogen'd comment
*/
string t_hs_generator::hs_autogen_comment() {
return string("-----------------------------------------------------------------\n") +
"-- Autogenerated by Thrift Compiler (" + THRIFT_VERSION + ") --\n" +
"-- --\n" +
"-- DO NOT EDIT UNLESS YOU ARE SURE YOU KNOW WHAT YOU ARE DOING --\n" +
"-----------------------------------------------------------------\n";
}
/**
* Prints standard thrift imports
*/
string t_hs_generator::hs_imports() {
const vector<t_program*>& includes = program_->get_includes();
string result = string(
"import Prelude ( Bool(..), Enum, Double, String, Maybe(..),\n"
" Eq, Show, Ord,\n"
" return, length, IO, fromIntegral, fromEnum, toEnum,\n"
" (&&), (||), (==), (++), ($), (-) )\n"
"\n"
"import Control.Exception\n"
"import Data.ByteString.Lazy\n"
"import Data.Int\n"
"import Data.Typeable ( Typeable )\n"
"import qualified Data.Map as Map\n"
"import qualified Data.Set as Set\n"
"\n"
"import Thrift\n"
"\n");
for (size_t i = 0; i < includes.size(); ++i)
result += "import qualified " + capitalize(includes[i]->get_name()) + "_Types\n";
if (includes.size() > 0)
result += "\n";
return result;
}
/**
* Closes the type files
*/
void t_hs_generator::close_generator() {
// Close types file
f_types_.close();
f_consts_.close();
}
/**
* Generates a typedef. Ez.
*
* @param ttypedef The type definition
*/
void t_hs_generator::generate_typedef(t_typedef* ttypedef) {
string tname = capitalize(ttypedef->get_symbolic());
string tdef = render_hs_type(ttypedef->get_type(), false);
indent(f_types_) << "type " << tname << " = " << tdef << endl;
f_types_ << endl;
}
/**
* Generates code for an enumerated type.
* the values.
*
* @param tenum The enumeration
*/
void t_hs_generator::generate_enum(t_enum* tenum) {
indent(f_types_) << "data " << capitalize(tenum->get_name()) << " = ";
indent_up();
vector<t_enum_value*> constants = tenum->get_constants();
vector<t_enum_value*>::iterator c_iter;
bool first = true;
for (c_iter = constants.begin(); c_iter != constants.end(); ++c_iter) {
string name = capitalize((*c_iter)->get_name());
f_types_ << (first ? "" : "|");
f_types_ << name;
first = false;
}
indent(f_types_) << "deriving (Show,Eq, Typeable, Ord)" << endl;
indent_down();
string ename = capitalize(tenum->get_name());
indent(f_types_) << "instance Enum " << ename << " where" << endl;
indent_up();
indent(f_types_) << "fromEnum t = case t of" << endl;
indent_up();
for (c_iter = constants.begin(); c_iter != constants.end(); ++c_iter) {
int value = (*c_iter)->get_value();
string name = capitalize((*c_iter)->get_name());
indent(f_types_) << name << " -> " << value << endl;
}
indent_down();
indent(f_types_) << "toEnum t = case t of" << endl;
indent_up();
for(c_iter = constants.begin(); c_iter != constants.end(); ++c_iter) {
int value = (*c_iter)->get_value();
string name = capitalize((*c_iter)->get_name());
indent(f_types_) << value << " -> " << name << endl;
}
indent(f_types_) << "_ -> throw ThriftException" << endl;
indent_down();
indent_down();
}
/**
* Generate a constant value
*/
void t_hs_generator::generate_const(t_const* tconst) {
t_type* type = tconst->get_type();
string name = decapitalize(tconst->get_name());
t_const_value* value = tconst->get_value();
indent(f_consts_) << name << " :: " << render_hs_type(type, false) << endl;
indent(f_consts_) << name << " = " << render_const_value(type, value) << endl;
f_consts_ << endl;
}
/**
* Prints the value of a constant with the given type. Note that type checking
* is NOT performed in this function as it is always run beforehand using the
* validate_types method in main.cc
*/
string t_hs_generator::render_const_value(t_type* type, t_const_value* value) {
type = get_true_type(type);
ostringstream out;
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:
out << '"' << get_escaped_string(value) << '"';
break;
case t_base_type::TYPE_BOOL:
out << (value->get_integer() > 0 ? "True" : "False");
break;
case t_base_type::TYPE_BYTE:
out << "(" << value->get_integer() << " :: Int8)";
break;
case t_base_type::TYPE_I16:
out << "(" << value->get_integer() << " :: Int16)";
break;
case t_base_type::TYPE_I32:
out << "(" << value->get_integer() << " :: Int32)";
break;
case t_base_type::TYPE_I64:
out << "(" << value->get_integer() << " :: Int64)";
break;
case t_base_type::TYPE_DOUBLE:
if (value->get_type() == t_const_value::CV_INTEGER) {
out << value->get_integer();
} else {
out << value->get_double();
}
break;
default:
throw "compiler error: no const of base type " + t_base_type::t_base_name(tbase);
}
} else if (type->is_enum()) {
t_enum* tenum = (t_enum*)type;
vector<t_enum_value*> constants = tenum->get_constants();
vector<t_enum_value*>::iterator c_iter;
for (c_iter = constants.begin(); c_iter != constants.end(); ++c_iter) {
int val = (*c_iter)->get_value();
if (val == value->get_integer()) {
indent(out) << capitalize((*c_iter)->get_name());
break;
}
}
} else if (type->is_struct() || type->is_xception()) {
string cname = type_name(type);
indent(out) << cname << "{";
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;
bool first = true;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
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();
string fname = v_iter->first->get_string();
string const_value = render_const_value(field_type, v_iter->second);
out << (first ? "" : ",");
out << "f_" << cname << "_" << fname << " = Just (" << const_value << ")";
first = false;
}
indent(out) << "}";
} else if (type->is_map()) {
t_type* ktype = ((t_map*)type)->get_key_type();
t_type* vtype = ((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;
out << "(Map.fromList [";
bool first = true;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
string key = render_const_value(ktype, v_iter->first);
string val = render_const_value(vtype, v_iter->second);
out << (first ? "" : ",");
out << "(" << key << "," << val << ")";
first = false;
}
out << "])";
} else if (type->is_list() || type->is_set()) {
t_type* etype = type->is_list()
? ((t_list*) type)->get_elem_type()
: ((t_set*) type)->get_elem_type();
const vector<t_const_value*>& val = value->get_list();
vector<t_const_value*>::const_iterator v_iter;
if (type->is_set())
out << "(Set.fromList ";
out << "[";
bool first = true;
for (v_iter = val.begin(); v_iter != val.end(); ++v_iter) {
out << (first ? "" : ",");
out << render_const_value(etype, *v_iter);
first = false;
}
out << "]";
if (type->is_set())
out << ")";
} else {
throw "CANNOT GENERATE CONSTANT FOR TYPE: " + type->get_name();
}
return out.str();
}
/**
* Generates a "struct"
*/
void t_hs_generator::generate_struct(t_struct* tstruct) {
generate_hs_struct(tstruct, false);
}
/**
* Generates a struct definition for a thrift exception. Basically the same
* as a struct, but also has an exception declaration.
*
* @param txception The struct definition
*/
void t_hs_generator::generate_xception(t_struct* txception) {
generate_hs_struct(txception, true);
}
/**
* Generates a Haskell struct
*/
void t_hs_generator::generate_hs_struct(t_struct* tstruct,
bool is_exception) {
generate_hs_struct_definition(f_types_,tstruct, is_exception,false);
}
/**
* Generates a struct definition for a thrift data type.
*
* @param tstruct The struct definition
*/
void t_hs_generator::generate_hs_struct_definition(ofstream& out,
t_struct* tstruct,
bool is_exception,
bool helper) {
(void) helper;
string tname = type_name(tstruct);
string name = tstruct->get_name();
const vector<t_field*>& members = tstruct->get_members();
vector<t_field*>::const_iterator m_iter;
indent(out) << "data " << tname << " = " << tname;
if (members.size() > 0) {
out << "{";
bool first = true;
for (m_iter = members.begin(); m_iter != members.end(); ++m_iter) {
string mname = (*m_iter)->get_name();
out << (first ? "" : ",");
out << "f_" << tname << "_" << mname << " :: Maybe " << render_hs_type((*m_iter)->get_type());
first = false;
}
out << "}";
}
out << " deriving (Show,Eq,Ord,Typeable)" << endl;
if (is_exception)
out << "instance Exception " << tname << endl;
generate_hs_struct_writer(out, tstruct);
generate_hs_struct_reader(out, tstruct);
}
/**
* Generates the read method for a struct
*/
void t_hs_generator::generate_hs_struct_reader(ofstream& out, t_struct* tstruct) {
const vector<t_field*>& fields = tstruct->get_members();
vector<t_field*>::const_iterator f_iter;
string sname = type_name(tstruct);
string str = tmp("_str");
string t = tmp("_t");
string id = tmp("_id");
indent(out) << "read_" << sname << "_fields iprot record = do" << endl;
indent_up();
// Read beginning field marker
indent(out) << "(_," << t << "," << id << ") <- readFieldBegin iprot" << endl;
// Check for field STOP marker and break
indent(out) << "if " << t << " == T_STOP then return record else" << endl;
indent_up();
indent(out) << "case " << id << " of " << endl;
indent_up();
// Generate deserialization code for known cases
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter) {
int32_t key = (*f_iter)->get_key();
string etype = type_to_enum((*f_iter)->get_type());
indent(out) << key << " -> " << "if " << t << " == " << etype << " then do" << endl;
indent_up();
indent(out) << "s <- ";
generate_deserialize_field(out, *f_iter,str);
out << endl;
string fname = decapitalize((*f_iter)->get_name());
indent(out) << "read_" << sname << "_fields iprot record{f_" << sname << "_" << fname << "=Just s}" << endl;
indent(out) << "else do" << endl;
indent_up();
indent(out) << "skip iprot " << t << endl;
indent(out) << "read_" << sname << "_fields iprot record" << endl;
indent_down();
indent_down();
}
// In the default case we skip the field
indent(out) << "_ -> do" << endl;
indent_up();
indent(out) << "skip iprot " << t << endl;
indent(out) << "readFieldEnd iprot" << endl;
indent(out) << "read_" << sname << "_fields iprot record" << endl;
indent_down();
indent_down();
indent_down();
indent_down();
// read
indent(out) << "read_" << sname << " iprot = do" << endl;
indent_up();
indent(out) << "_ <- readStructBegin iprot" << endl;
indent(out) << "record <- read_" << sname << "_fields iprot (" << sname << "{";
bool first = true;
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter) {
out << (first ? "" : ",");
out << "f_" << sname << "_" << decapitalize((*f_iter)->get_name()) << "=Nothing";
first = false;
}
out << "})" << endl;
indent(out) << "readStructEnd iprot" << endl;
indent(out) << "return record" << endl;
indent_down();
}
void t_hs_generator::generate_hs_struct_writer(ofstream& out,
t_struct* tstruct) {
string name = type_name(tstruct);
const vector<t_field*>& fields = tstruct->get_sorted_members();
vector<t_field*>::const_iterator f_iter;
string str = tmp("_str");
string f = tmp("_f");
indent(out) << "write_" << name << " oprot record = do" << endl;
indent_up();
indent(out) << "writeStructBegin oprot \"" << name << "\"" << endl;
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter) {
// Write field header
string mname = (*f_iter)->get_name();
indent(out) << "case f_" << name << "_" << mname << " record of {Nothing -> return (); Just _v -> do" << endl;
indent_up();
indent(out) << "writeFieldBegin oprot (\"" << (*f_iter)->get_name() << "\","
<< type_to_enum((*f_iter)->get_type()) << ","
<< (*f_iter)->get_key() << ")" << endl;
// Write field contents
indent(out);
generate_serialize_field(out, *f_iter, "_v");
out << endl;
// Write field closer
indent(out) << "writeFieldEnd oprot}" << endl;
indent_down();
}
// Write the struct map
indent(out) << "writeFieldStop oprot" << endl;
indent(out) << "writeStructEnd oprot" << endl;
indent_down();
}
/**
* Generates a thrift service.
*
* @param tservice The service definition
*/
void t_hs_generator::generate_service(t_service* tservice) {
string f_service_name = get_out_dir() + capitalize(service_name_) + ".hs";
f_service_.open(f_service_name.c_str());
f_service_ << hs_language_pragma() << endl;
f_service_ << hs_autogen_comment() << endl;
f_service_ << "module " << capitalize(service_name_) << " where" << endl;
f_service_ << hs_imports() << endl;
if (tservice->get_extends()) {
f_service_ << "import qualified " << capitalize(tservice->get_extends()->get_name()) << endl;
}
f_service_ << "import " << capitalize(program_name_) << "_Types" << endl;
f_service_ << "import qualified " << capitalize(service_name_) << "_Iface as Iface" << endl;
// Generate the three main parts of the service
generate_service_helpers(tservice);
generate_service_interface(tservice);
generate_service_client(tservice);
generate_service_server(tservice);
// Close service file
f_service_.close();
}
/**
* Generates helper functions for a service.
*
* @param tservice The service to generate a header definition for
*/
void t_hs_generator::generate_service_helpers(t_service* tservice) {
vector<t_function*> functions = tservice->get_functions();
vector<t_function*>::iterator f_iter;
indent(f_service_) << "-- HELPER FUNCTIONS AND STRUCTURES --" << endl;
indent(f_service_) << endl;
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter) {
t_struct* ts = (*f_iter)->get_arglist();
generate_hs_struct_definition(f_service_,ts, false);
generate_hs_function_helpers(*f_iter);
}
}
/**
* Generates a struct and helpers for a function.
*
* @param tfunction The function
*/
void t_hs_generator::generate_hs_function_helpers(t_function* tfunction) {
t_struct result(program_, decapitalize(tfunction->get_name()) + "_result");
t_field success(tfunction->get_returntype(), "success", 0);
if (!tfunction->get_returntype()->is_void())
result.append(&success);
t_struct* xs = tfunction->get_xceptions();
const vector<t_field*>& fields = xs->get_members();
vector<t_field*>::const_iterator f_iter;
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter)
result.append(*f_iter);
generate_hs_struct_definition(f_service_,&result, false);
}
/**
* Generates a service interface definition.
*
* @param tservice The service to generate a header definition for
*/
void t_hs_generator::generate_service_interface(t_service* tservice) {
string f_iface_name = get_out_dir() + capitalize(service_name_) + "_Iface.hs";
f_iface_.open(f_iface_name.c_str());
f_iface_ << hs_language_pragma() << endl;
f_iface_ << hs_autogen_comment() << endl;
f_iface_ << "module " << capitalize(service_name_) << "_Iface where" << endl;
f_iface_ << hs_imports() << endl;
f_iface_ << "import " << capitalize(program_name_) << "_Types" << endl;
f_iface_ << endl;
string sname = capitalize(service_name_);
if (tservice->get_extends() != NULL) {
string extends = type_name(tservice->get_extends());
indent(f_iface_) << "import " << extends << "_Iface" << endl;
indent(f_iface_) << "class " << extends << "_Iface a => " << sname << "_Iface a where" << endl;
} else {
indent(f_iface_) << "class " << sname << "_Iface a where" << endl;
}
indent_up();
vector<t_function*> functions = tservice->get_functions();
vector<t_function*>::iterator f_iter;
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter) {
string ft = function_type(*f_iter, true, true, true);
indent(f_iface_) << decapitalize((*f_iter)->get_name()) << " :: a -> " << ft << endl;
}
indent_down();
f_iface_.close();
}
/**
* Generates a service client definition. Note that in Haskell, the client doesn't implement iface. This is because
* The client does not (and should not have to) deal with arguments being Nothing.
*
* @param tservice The service to generate a server for.
*/
void t_hs_generator::generate_service_client(t_service* tservice) {
string f_client_name = get_out_dir() + capitalize(service_name_) + "_Client.hs";
f_client_.open(f_client_name.c_str());
f_client_ << hs_language_pragma() << endl;
f_client_ << hs_autogen_comment() << endl;
vector<t_function*> functions = tservice->get_functions();
vector<t_function*>::const_iterator f_iter;
string extends = "";
string exports = "";
bool first = true;
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter) {
exports += (first ? "" : ",");
string funname = (*f_iter)->get_name();
exports += decapitalize(funname);
first = false;
}
string sname = capitalize(service_name_);
indent(f_client_) << "module " << sname << "_Client(" << exports << ") where" << endl;
if (tservice->get_extends() != NULL) {
extends = type_name(tservice->get_extends());
indent(f_client_) << "import " << extends << "_Client" << endl;
}
indent(f_client_) << "import Data.IORef" << endl;
indent(f_client_) << hs_imports() << endl;
indent(f_client_) << "import " << capitalize(program_name_) << "_Types" << endl;
indent(f_client_) << "import " << capitalize(service_name_) << endl;
// DATS RITE A GLOBAL VAR
indent(f_client_) << "seqid = newIORef 0" << endl;
// Generate client method implementations
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter) {
t_struct* arg_struct = (*f_iter)->get_arglist();
const vector<t_field*>& fields = arg_struct->get_members();
vector<t_field*>::const_iterator fld_iter;
string funname = (*f_iter)->get_name();
string fargs = "";
for (fld_iter = fields.begin(); fld_iter != fields.end(); ++fld_iter)
fargs += " arg_" + decapitalize((*fld_iter)->get_name());
// Open function
indent(f_client_) << decapitalize(funname) << " (ip,op)" << fargs << " = do" << endl;
indent_up();
indent(f_client_) << "send_" << funname << " op" << fargs;
f_client_ << endl;
if (!(*f_iter)->is_oneway())
indent(f_client_) << "recv_" << funname << " ip" << endl;
indent_down();
indent(f_client_) << "send_" << funname << " op" << fargs << " = do" << endl;
indent_up();
indent(f_client_) << "seq <- seqid" << endl;
indent(f_client_) << "seqn <- readIORef seq" << endl;
string argsname = capitalize((*f_iter)->get_name() + "_args");
// Serialize the request header
string fname = (*f_iter)->get_name();
indent(f_client_) << "writeMessageBegin op (\"" << fname << "\", M_CALL, seqn)" << endl;
indent(f_client_) << "write_" << argsname << " op (" << argsname << "{";
bool first = true;
for (fld_iter = fields.begin(); fld_iter != fields.end(); ++fld_iter) {
string fieldname = (*fld_iter)->get_name();
f_client_ << (first ? "" : ",");
f_client_ << "f_" << argsname << "_" << fieldname << "=Just arg_" << fieldname;
first = false;
}
f_client_ << "})" << endl;
// Write to the stream
indent(f_client_) << "writeMessageEnd op" << endl;
indent(f_client_) << "tFlush (getTransport op)" << endl;
indent_down();
if (!(*f_iter)->is_oneway()) {
string resultname = capitalize((*f_iter)->get_name() + "_result");
t_struct noargs(program_);
string funname = string("recv_") + (*f_iter)->get_name();
t_function recv_function((*f_iter)->get_returntype(), funname, &noargs);
// Open function
indent(f_client_) << funname << " ip = do" << endl;
indent_up();
// TODO(mcslee): Validate message reply here, seq ids etc.
indent(f_client_) << "(fname, mtype, rseqid) <- readMessageBegin ip" << endl;
indent(f_client_) << "if mtype == M_EXCEPTION then do" << endl;
indent(f_client_) << " x <- readAppExn ip" << endl;
indent(f_client_) << " readMessageEnd ip" << endl;
indent(f_client_) << " throw x" << endl;
indent(f_client_) << " else return ()" << endl;
t_struct* xs = (*f_iter)->get_xceptions();
const vector<t_field*>& xceptions = xs->get_members();
indent(f_client_) << "res <- read_" << resultname << " ip" << endl;
indent(f_client_) << "readMessageEnd ip" << endl;
// Careful, only return _result if not a void function
if (!(*f_iter)->get_returntype()->is_void()) {
indent(f_client_) << "case f_" << resultname << "_success res of" << endl;
indent_up();
indent(f_client_) << "Just v -> return v" << endl;
indent(f_client_) << "Nothing -> do" << endl;
indent_up();
}
vector<t_field*>::const_iterator x_iter;
for (x_iter = xceptions.begin(); x_iter != xceptions.end(); ++x_iter) {
string xname = (*x_iter)->get_name();
indent(f_client_) << "case f_" << resultname << "_" << xname << " res of" << endl;
indent_up();
indent(f_client_) << "Nothing -> return ()" << endl;
indent(f_client_) << "Just _v -> throw _v" << endl;
indent_down();
}
// Careful, only return _result if not a void function
if ((*f_iter)->get_returntype()->is_void()) {
indent(f_client_) << "return ()" << endl;
} else {
string tname = (*f_iter)->get_name();
indent(f_client_) << "throw (AppExn AE_MISSING_RESULT \"" << tname << " failed: unknown result\")" << endl;
indent_down();
indent_down();
}
// Close function
indent_down();
}
}
f_client_.close();
}
/**
* Generates a service server definition.
*
* @param tservice The service to generate a server for.
*/
void t_hs_generator::generate_service_server(t_service* tservice) {
// Generate the dispatch methods
vector<t_function*> functions = tservice->get_functions();
vector<t_function*>::iterator f_iter;
// Generate the process subfunctions
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter)
generate_process_function(tservice, *f_iter);
indent(f_service_) << "proc_ handler (iprot,oprot) (name,typ,seqid) = case name of" << endl;
indent_up();
for (f_iter = functions.begin(); f_iter != functions.end(); ++f_iter) {
string fname = (*f_iter)->get_name();
indent(f_service_) << "\"" << fname << "\" -> process_" << decapitalize(fname) << " (seqid,iprot,oprot,handler)" << endl;
}
indent(f_service_) << "_ -> ";
if (tservice->get_extends() != NULL) {
f_service_ << type_name(tservice->get_extends()) << ".proc_ handler (iprot,oprot) (name,typ,seqid)" << endl;
} else {
f_service_ << "do" << endl;
indent_up();
indent(f_service_) << "skip iprot T_STRUCT" << endl;
indent(f_service_) << "readMessageEnd iprot" << endl;
indent(f_service_) << "writeMessageBegin oprot (name,M_EXCEPTION,seqid)" << endl;
indent(f_service_) << "writeAppExn oprot (AppExn AE_UNKNOWN_METHOD (\"Unknown function \" ++ name))" << endl;
indent(f_service_) << "writeMessageEnd oprot" << endl;
indent(f_service_) << "tFlush (getTransport oprot)" << endl;
indent_down();
}
indent_down();
// Generate the server implementation
indent(f_service_) << "process handler (iprot, oprot) = do" << endl;
indent_up();
indent(f_service_) << "(name, typ, seqid) <- readMessageBegin iprot" << endl;
indent(f_service_) << "proc_ handler (iprot,oprot) (name,typ,seqid)" << endl;
indent(f_service_) << "return True" << endl;
indent_down();
}
/**
* Generates a process function definition.
*
* @param tfunction The function to write a dispatcher for
*/
void t_hs_generator::generate_process_function(t_service* tservice,
t_function* tfunction) {
(void) tservice;
// Open function
string funname = decapitalize(tfunction->get_name());
indent(f_service_) << "process_" << funname << " (seqid, iprot, oprot, handler) = do" << endl;
indent_up();
string argsname = capitalize(tfunction->get_name()) + "_args";
string resultname = capitalize(tfunction->get_name()) + "_result";
// Generate the function call
t_struct* arg_struct = tfunction->get_arglist();
const vector<t_field*>& fields = arg_struct->get_members();
vector<t_field*>::const_iterator f_iter;
indent(f_service_) << "args <- read_" << argsname << " iprot" << endl;
indent(f_service_) << "readMessageEnd iprot" << endl;
t_struct* xs = tfunction->get_xceptions();
const vector<t_field*>& xceptions = xs->get_members();
vector<t_field*>::const_iterator x_iter;
size_t n = xceptions.size();
if (!tfunction->is_oneway()) {
if (!tfunction->get_returntype()->is_void())
n++;
indent(f_service_) << "rs <- return (" << resultname;
for(size_t i = 0; i < n; i++)
f_service_ << " Nothing";
f_service_ << ")" << endl;
}
indent(f_service_) << "res <- ";
// Try block for a function with exceptions
if (xceptions.size() > 0) {
for(size_t i = 0; i < xceptions.size(); i++) {
f_service_ << "(Control.Exception.catch" << endl;
indent_up();
indent(f_service_);
}
}
f_service_ << "(do" << endl;
indent_up();
indent(f_service_);
if (!tfunction->is_oneway() && !tfunction->get_returntype()->is_void())
f_service_ << "res <- ";
f_service_ << "Iface." << decapitalize(tfunction->get_name()) << " handler";
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter)
f_service_ << " (f_" << argsname << "_" << (*f_iter)->get_name() << " args)";
if (!tfunction->is_oneway() && !tfunction->get_returntype()->is_void()) {
f_service_ << endl;
indent(f_service_) << "return rs{f_" << resultname << "_success= Just res}";
} else if (!tfunction->is_oneway()) {
f_service_ << endl;
indent(f_service_) << "return rs";
}
f_service_ << ")" << endl;
indent_down();
if (xceptions.size() > 0 && !tfunction->is_oneway()) {
for (x_iter = xceptions.begin(); x_iter != xceptions.end(); ++x_iter) {
indent(f_service_) << "(\\e -> " << endl;
indent_up();
if (!tfunction->is_oneway()) {
indent(f_service_) << "return rs{f_" << resultname << "_" << (*x_iter)->get_name() << " =Just e}";
} else {
indent(f_service_) << "return ()";
}
f_service_ << "))" << endl;
indent_down();
indent_down();
}
}
// Shortcut out here for oneway functions
if (tfunction->is_oneway()) {
indent(f_service_) << "return ()" << endl;
indent_down();
return;
}
indent(f_service_ ) << "writeMessageBegin oprot (\"" << tfunction->get_name() << "\", M_REPLY, seqid);" << endl;
indent(f_service_ ) << "write_" << resultname << " oprot res" << endl;
indent(f_service_ ) << "writeMessageEnd oprot" << endl;
indent(f_service_ ) << "tFlush (getTransport oprot)" << endl;
// Close function
indent_down();
}
/**
* Deserializes a field of any type.
*/
void t_hs_generator::generate_deserialize_field(ofstream &out,
t_field* tfield,
string prefix) {
(void) prefix;
t_type* type = tfield->get_type();
generate_deserialize_type(out,type);
}
/**
* Deserializes a field of any type.
*/
void t_hs_generator::generate_deserialize_type(ofstream &out,
t_type* type) {
type = get_true_type(type);
if (type->is_void())
throw "CANNOT GENERATE DESERIALIZE CODE FOR void TYPE";
if (type->is_struct() || type->is_xception()) {
generate_deserialize_struct(out, (t_struct*)type);
} else if (type->is_container()) {
generate_deserialize_container(out, type);
} else if (type->is_base_type()) {
t_base_type::t_base tbase = ((t_base_type*)type)->get_base();
switch (tbase) {
case t_base_type::TYPE_VOID:
throw "compiler error: cannot serialize void field in a struct";
break;
case t_base_type::TYPE_STRING:
out << (((t_base_type*)type)->is_binary() ? "readBinary" : "readString");
break;
case t_base_type::TYPE_BOOL:
out << "readBool";
break;
case t_base_type::TYPE_BYTE:
out << "readByte";
break;
case t_base_type::TYPE_I16:
out << "readI16";
break;
case t_base_type::TYPE_I32:
out << "readI32";
break;
case t_base_type::TYPE_I64:
out << "readI64";
break;
case t_base_type::TYPE_DOUBLE:
out << "readDouble";
break;
default:
throw "compiler error: no PHP name for base type " + t_base_type::t_base_name(tbase);
}
out << " iprot";
} else if (type->is_enum()) {
string ename = capitalize(type->get_name());
out << "(do {i <- readI32 iprot; return $ toEnum $ fromIntegral i})";
} else {
printf("DO NOT KNOW HOW TO DESERIALIZE TYPE '%s'\n",
type->get_name().c_str());
}
}
/**
* Generates an unserializer for a struct, calling read()
*/
void t_hs_generator::generate_deserialize_struct(ofstream &out,
t_struct* tstruct) {
string name = capitalize(tstruct->get_name());
out << "(read_" << name << " iprot)";
}
/**
* Serialize a container by writing out the header followed by
* data and then a footer.
*/
void t_hs_generator::generate_deserialize_container(ofstream &out,
t_type* ttype) {
string size = tmp("_size");
string ktype = tmp("_ktype");
string vtype = tmp("_vtype");
string etype = tmp("_etype");
string con = tmp("_con");
t_field fsize(g_type_i32, size);
t_field fktype(g_type_byte, ktype);
t_field fvtype(g_type_byte, vtype);
t_field fetype(g_type_byte, etype);
// Declare variables, read header
if (ttype->is_map()) {
out << "(let {f 0 = return []; f n = do {k <- ";
generate_deserialize_type(out,((t_map*)ttype)->get_key_type());
out << "; v <- ";
generate_deserialize_type(out,((t_map*)ttype)->get_val_type());
out << ";r <- f (n-1); return $ (k,v):r}} in do {(" << ktype << "," << vtype << "," << size << ") <- readMapBegin iprot; l <- f " << size << "; return $ Map.fromList l})";
} else if (ttype->is_set()) {
out << "(let {f 0 = return []; f n = do {v <- ";
generate_deserialize_type(out,((t_map*)ttype)->get_key_type());
out << ";r <- f (n-1); return $ v:r}} in do {(" << etype << "," << size << ") <- readSetBegin iprot; l <- f " << size << "; return $ Set.fromList l})";
} else if (ttype->is_list()) {
out << "(let {f 0 = return []; f n = do {v <- ";
generate_deserialize_type(out,((t_map*)ttype)->get_key_type());
out << ";r <- f (n-1); return $ v:r}} in do {(" << etype << "," << size << ") <- readListBegin iprot; f " << size << "})";
}
}
/**
* Serializes a field of any type.
*
* @param tfield The field to serialize
* @param prefix Name to prepend to field name
*/
void t_hs_generator::generate_serialize_field(ofstream &out,
t_field* tfield,
string name) {
t_type* type = get_true_type(tfield->get_type());
// Do nothing for void types
if (type->is_void())
throw "CANNOT GENERATE SERIALIZE CODE FOR void TYPE: " + tfield->get_name();
if (name.length() == 0)
name = decapitalize(tfield->get_name());
if (type->is_struct() || type->is_xception()) {
generate_serialize_struct(out, (t_struct*)type, name);
} else if (type->is_container()) {
generate_serialize_container(out, type, name);
} else if (type->is_base_type() || type->is_enum()) {
if (type->is_base_type()) {
t_base_type::t_base tbase = ((t_base_type*)type)->get_base();
switch (tbase) {
case t_base_type::TYPE_VOID:
throw
"compiler error: cannot serialize void field in a struct: " + name;
break;
case t_base_type::TYPE_STRING:
out << (((t_base_type*)type)->is_binary() ? "writeBinary" : "writeString") << " oprot " << name;
break;
case t_base_type::TYPE_BOOL:
out << "writeBool oprot " << name;
break;
case t_base_type::TYPE_BYTE:
out << "writeByte oprot " << name;
break;
case t_base_type::TYPE_I16:
out << "writeI16 oprot " << name;
break;
case t_base_type::TYPE_I32:
out << "writeI32 oprot " << name;
break;
case t_base_type::TYPE_I64:
out << "writeI64 oprot " << name;
break;
case t_base_type::TYPE_DOUBLE:
out << "writeDouble oprot " << name;
break;
default:
throw "compiler error: no hs name for base type " + t_base_type::t_base_name(tbase);
}
} else if (type->is_enum()) {
string ename = capitalize(type->get_name());
out << "writeI32 oprot (fromIntegral $ fromEnum " << name << ")";
}
} else {
printf("DO NOT KNOW HOW TO SERIALIZE FIELD '%s' TYPE '%s'\n",
tfield->get_name().c_str(),
type->get_name().c_str());
}
}
/**
* Serializes all the members of a struct.
*
* @param tstruct The struct to serialize
* @param prefix String prefix to attach to all fields
*/
void t_hs_generator::generate_serialize_struct(ofstream &out,
t_struct* tstruct,
string prefix) {
out << type_name(tstruct, "write_") << " oprot " << prefix;
}
void t_hs_generator::generate_serialize_container(ofstream &out,
t_type* ttype,
string prefix) {
if (ttype->is_map()) {
string k = tmp("_kiter");
string v = tmp("_viter");
out << "(let {f [] = return (); f ((" << k << "," << v << "):t) = do {";
generate_serialize_map_element(out, (t_map*)ttype, k, v);
out << ";f t}} in do {writeMapBegin oprot (" << type_to_enum(((t_map*)ttype)->get_key_type()) << "," << type_to_enum(((t_map*)ttype)->get_val_type()) << ",fromIntegral $ Map.size " << prefix << "); f (Map.toList " << prefix << ");writeMapEnd oprot})";
} else if (ttype->is_set()) {
string v = tmp("_viter");
out << "(let {f [] = return (); f (" << v << ":t) = do {";
generate_serialize_set_element(out, (t_set*)ttype, v);
out << ";f t}} in do {writeSetBegin oprot (" << type_to_enum(((t_set*)ttype)->get_elem_type()) << ",fromIntegral $ Set.size " << prefix << "); f (Set.toList " << prefix << ");writeSetEnd oprot})";
} else if (ttype->is_list()) {
string v = tmp("_viter");
out << "(let {f [] = return (); f (" << v << ":t) = do {";
generate_serialize_list_element(out, (t_list*)ttype, v);
out << ";f t}} in do {writeListBegin oprot (" << type_to_enum(((t_list*)ttype)->get_elem_type()) << ",fromIntegral $ Prelude.length " << prefix << "); f " << prefix << ";writeListEnd oprot})";
}
}
/**
* Serializes the members of a map.
*
*/
void t_hs_generator::generate_serialize_map_element(ofstream &out,
t_map* tmap,
string kiter,
string viter) {
t_field kfield(tmap->get_key_type(), kiter);
out << "do {";
generate_serialize_field(out, &kfield);
out << ";";
t_field vfield(tmap->get_val_type(), viter);
generate_serialize_field(out, &vfield);
out << "}";
}
/**
* Serializes the members of a set.
*/
void t_hs_generator::generate_serialize_set_element(ofstream &out,
t_set* tset,
string iter) {
t_field efield(tset->get_elem_type(), iter);
generate_serialize_field(out, &efield);
}
/**
* Serializes the members of a list.
*/
void t_hs_generator::generate_serialize_list_element(ofstream &out,
t_list* tlist,
string iter) {
t_field efield(tlist->get_elem_type(), iter);
generate_serialize_field(out, &efield);
}
string t_hs_generator::function_type(t_function* tfunc, bool options, bool io, bool method) {
string result = "";
const vector<t_field*>& fields = tfunc->get_arglist()->get_members();
vector<t_field*>::const_iterator f_iter;
for (f_iter = fields.begin(); f_iter != fields.end(); ++f_iter) {
if (options) result += "Maybe ";
result += render_hs_type((*f_iter)->get_type(), options);
result += " -> ";
}
if (fields.empty() && !method)
result += "() -> ";
if (io)
result += "IO ";
result += render_hs_type(tfunc->get_returntype(), io);
return result;
}
string t_hs_generator::type_name(t_type* ttype, string function_prefix) {
string prefix = "";
t_program* program = ttype->get_program();
if (program != NULL && program != program_)
if (!ttype->is_service())
prefix = capitalize(program->get_name()) + "_Types.";
return prefix + function_prefix + capitalize(ttype->get_name());
}
/**
* Converts the parse type to a Protocol.t_type enum
*/
string t_hs_generator::type_to_enum(t_type* type) {
type = get_true_type(type);
if (type->is_base_type()) {
t_base_type::t_base tbase = ((t_base_type*)type)->get_base();
switch (tbase) {
case t_base_type::TYPE_VOID: return "T_VOID";
case t_base_type::TYPE_STRING: return "T_STRING";
case t_base_type::TYPE_BOOL: return "T_BOOL";
case t_base_type::TYPE_BYTE: return "T_BYTE";
case t_base_type::TYPE_I16: return "T_I16";
case t_base_type::TYPE_I32: return "T_I32";
case t_base_type::TYPE_I64: return "T_I64";
case t_base_type::TYPE_DOUBLE: return "T_DOUBLE";
}
} else if (type->is_enum()) {
return "T_I32";
} else if (type->is_struct() || type->is_xception()) {
return "T_STRUCT";
} else if (type->is_map()) {
return "T_MAP";
} else if (type->is_set()) {
return "T_SET";
} else if (type->is_list()) {
return "T_LIST";
}
throw "INVALID TYPE IN type_to_enum: " + type->get_name();
}
/**
* Converts the parse type to an haskell type
*/
string t_hs_generator::render_hs_type(t_type* type, bool needs_parens) {
type = get_true_type(type);
string type_repr;
if (type->is_base_type()) {
t_base_type::t_base tbase = ((t_base_type*)type)->get_base();
switch (tbase) {
case t_base_type::TYPE_VOID: return "()";
case t_base_type::TYPE_STRING: return (((t_base_type*)type)->is_binary() ? "ByteString" : "String");
case t_base_type::TYPE_BOOL: return "Bool";
case t_base_type::TYPE_BYTE: return "Int8";
case t_base_type::TYPE_I16: return "Int16";
case t_base_type::TYPE_I32: return "Int32";
case t_base_type::TYPE_I64: return "Int64";
case t_base_type::TYPE_DOUBLE: return "Double";
}
} else if (type->is_enum()) {
return capitalize(((t_enum*)type)->get_name());
} else if (type->is_struct() || type->is_xception()) {
return type_name((t_struct*)type);
} else if (type->is_map()) {
t_type* ktype = ((t_map*)type)->get_key_type();
t_type* vtype = ((t_map*)type)->get_val_type();
type_repr = "Map.Map " + render_hs_type(ktype, true) + " " + render_hs_type(vtype, true);
} else if (type->is_set()) {
t_type* etype = ((t_set*)type)->get_elem_type();
type_repr = "Set.Set " + render_hs_type(etype, true) ;
} else if (type->is_list()) {
t_type* etype = ((t_list*)type)->get_elem_type();
return "[" + render_hs_type(etype, false) + "]";
} else {
throw "INVALID TYPE IN type_to_enum: " + type->get_name();
}
return needs_parens ? "(" + type_repr + ")" : type_repr;
}
THRIFT_REGISTER_GENERATOR(hs, "Haskell", "")