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preprocessor/src/ParsingDriver.cc

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/*
* Copyright © 2003-2021 Dynare Team
*
* This file is part of Dynare.
*
* Dynare is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Dynare is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Dynare. If not, see <https://www.gnu.org/licenses/>.
*/
#include <fstream>
#include <iostream>
#include <cassert>
#include <sstream>
#include <cmath>
#include "ParsingDriver.hh"
#include "Statement.hh"
#include "ExprNode.hh"
#include "WarningConsolidation.hh"
bool
ParsingDriver::symbol_exists_and_is_not_modfile_local_or_external_function(const string &s)
{
if (!mod_file->symbol_table.exists(s))
return false;
SymbolType type = mod_file->symbol_table.getType(s);
return type != SymbolType::modFileLocalVariable && type != SymbolType::externalFunction;
}
void
ParsingDriver::check_symbol_existence_in_model_block(const string &name)
{
if (!mod_file->symbol_table.exists(name)
|| undeclared_model_vars.find(name) != undeclared_model_vars.end())
undeclared_model_variable_error("Unknown symbol: " + name, name);
}
void
ParsingDriver::check_symbol_existence(const string &name)
{
if (!mod_file->symbol_table.exists(name))
error("Unknown symbol: " + name + ".\nIf referenced from the 'initval', 'endval', 'histval', or 'shocks' block, you can pass the 'nostrict' option to dynare to have this line ignored.");
}
void
ParsingDriver::check_symbol_is_parameter(const string &name)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
if (mod_file->symbol_table.getType(symb_id) != SymbolType::parameter)
error(name + " is not a parameter");
}
void
ParsingDriver::set_current_data_tree(DataTree *data_tree_arg)
{
data_tree = data_tree_arg;
model_tree = dynamic_cast<ModelTree *>(data_tree_arg);
dynamic_model = dynamic_cast<DynamicModel *>(data_tree_arg);
}
void
ParsingDriver::reset_data_tree()
{
set_current_data_tree(&mod_file->expressions_tree);
}
void
ParsingDriver::reset_current_external_function_options()
{
current_external_function_options.nargs = ExternalFunctionsTable::defaultNargs;
current_external_function_options.firstDerivSymbID = ExternalFunctionsTable::IDNotSet;
current_external_function_options.secondDerivSymbID = ExternalFunctionsTable::IDNotSet;
current_external_function_id = ExternalFunctionsTable::IDNotSet;
}
unique_ptr<ModFile>
ParsingDriver::parse(istream &in, bool debug)
{
mod_file = make_unique<ModFile>(warnings);
symbol_list.setSymbolTable(mod_file->symbol_table);
reset_data_tree();
estim_params.init(*data_tree);
osr_params.init(*data_tree);
reset_current_external_function_options();
lexer = make_unique<DynareFlex>(&in);
lexer->set_debug(debug);
Dynare::parser parser(*this);
parser.set_debug_level(debug);
parser.parse();
return move(mod_file);
}
void
ParsingDriver::error(const Dynare::parser::location_type &l, const string &m)
{
create_error_string(l, m, cerr);
exit(EXIT_FAILURE);
}
void
ParsingDriver::error(const string &m)
{
error(location, m);
}
void
ParsingDriver::create_error_string(const Dynare::parser::location_type &l, const string &m, ostream &stream)
{
stream << "ERROR: " << *l.begin.filename << ": line " << l.begin.line;
if (l.begin.line == l.end.line)
if (l.begin.column == l.end.column - 1)
stream << ", col " << l.begin.column;
else
stream << ", cols " << l.begin.column << "-" << l.end.column - 1;
else
stream << ", col " << l.begin.column << " -"
<< " line " << l.end.line << ", col " << l.end.column - 1;
stream << ": " << m << endl;
}
void
ParsingDriver::create_error_string(const Dynare::parser::location_type &l, const string &m, const string &var)
{
ostringstream stream;
create_error_string(l, m, stream);
model_errors.emplace_back(var, stream.str());
}
void
ParsingDriver::model_error(const string &m, const string &var)
{
create_error_string(location, m, var);
}
void
ParsingDriver::undeclared_model_variable_error(const string &m, const string &var)
{
ostringstream stream;
if (!nostrict)
{
stream << "ERROR: " << *location.begin.filename << ": line " << location.begin.line;
if (location.begin.line == location.end.line)
if (location.begin.column == location.end.column - 1)
stream << ", col " << location.begin.column;
else
stream << ", cols " << location.begin.column << "-" << location.end.column - 1;
else
stream << ", col " << location.begin.column << " -"
<< " line " << location.end.line << ", col " << location.end.column - 1;
stream << ": ";
}
stream << m;
if (nostrict)
stream << " automatically declared exogenous.";
undeclared_model_variable_errors.emplace_back(var, stream.str());
}
void
ParsingDriver::warning(const string &m)
{
warnings << "WARNING: " << location << ": " << m << endl;
}
void
ParsingDriver::declare_symbol(const string &name, SymbolType type, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
try
{
mod_file->symbol_table.addSymbol(name, type, tex_name, partition_value);
}
catch (SymbolTable::AlreadyDeclaredException &e)
{
if (e.same_type)
warning("Symbol " + name + " declared twice.");
else
error("Symbol " + name + " declared twice with different types!");
}
}
void
ParsingDriver::declare_endogenous(const string &name, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
declare_symbol(name, SymbolType::endogenous, tex_name, partition_value);
}
void
ParsingDriver::declare_var_endogenous(const string &name)
{
if (mod_file->symbol_table.exists(name))
{
SymbolType type = mod_file->symbol_table.getType(name);
if (type != SymbolType::endogenous && type != SymbolType::exogenous && type != SymbolType::exogenousDet)
error("Symbol " + name + " used in a VAR must be either endogenous or "
+"exogenous if it is also used elsewhere in the .mod file");
add_in_symbol_list(name);
return;
}
declare_symbol(name, SymbolType::endogenousVAR, "", {});
add_in_symbol_list(name);
}
void
ParsingDriver::declare_exogenous(const string &name, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
declare_symbol(name, SymbolType::exogenous, tex_name, partition_value);
}
void
ParsingDriver::declare_exogenous_det(const string &name, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
declare_symbol(name, SymbolType::exogenousDet, tex_name, partition_value);
}
void
ParsingDriver::declare_parameter(const string &name, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
declare_symbol(name, SymbolType::parameter, tex_name, partition_value);
}
void
ParsingDriver::declare_statement_local_variable(const string &name)
{
if (mod_file->symbol_table.exists(name))
error("Symbol " + name + " cannot be assigned within a statement "
+"while being assigned elsewhere in the modfile");
declare_symbol(name, SymbolType::statementDeclaredVariable, "", {});
}
void
ParsingDriver::set_planner_discount(expr_t value)
{
planner_discount = value;
}
void
ParsingDriver::set_planner_discount_latex_name(string tex_name)
{
planner_discount_latex_name = move(tex_name);
}
void
ParsingDriver::begin_trend()
{
set_current_data_tree(&mod_file->dynamic_model);
}
void
ParsingDriver::declare_trend_var(bool log_trend, const string &name, const string &tex_name)
{
declare_symbol(name, log_trend ? SymbolType::logTrend : SymbolType::trend, tex_name, {});
declared_trend_vars.push_back(mod_file->symbol_table.getID(name));
}
void
ParsingDriver::end_trend_var(expr_t growth_factor)
{
try
{
dynamic_model->addTrendVariables(declared_trend_vars, growth_factor);
}
catch (DataTree::TrendException &e)
{
error("Trend variable " + e.name + " was declared twice.");
}
declared_trend_vars.clear();
reset_data_tree();
}
void
ParsingDriver::add_predetermined_variable(const string &name)
{
check_symbol_is_endogenous(name);
int symb_id = mod_file->symbol_table.getID(name);
mod_file->symbol_table.markPredetermined(symb_id);
}
void
ParsingDriver::add_equation_tags(string key, string value)
{
eq_tags[key] = value;
transform(key.begin(), key.end(), key.begin(), ::tolower);
if (key.compare("endogenous") == 0)
declare_or_change_type(SymbolType::endogenous, value);
}
expr_t
ParsingDriver::add_non_negative_constant(const string &constant)
{
return data_tree->AddNonNegativeConstant(constant);
}
expr_t
ParsingDriver::add_nan_constant()
{
return data_tree->NaN;
}
expr_t
ParsingDriver::add_inf_constant()
{
return data_tree->Infinity;
}
expr_t
ParsingDriver::add_model_variable(const string &name)
{
if (name.find(".") != string::npos)
error(name + " treated as a variable, but it contains a '.'");
check_symbol_existence_in_model_block(name);
int symb_id;
try
{
symb_id = mod_file->symbol_table.getID(name);
}
catch (SymbolTable::UnknownSymbolNameException &e)
{
// Declare variable as exogenous to continue parsing
// processing will end at end of model block if nostrict option was not passed
declare_exogenous(name);
undeclared_model_vars.insert(name);
symb_id = mod_file->symbol_table.getID(name);
}
return add_model_variable(symb_id, 0);
}
expr_t
ParsingDriver::declare_or_change_type(SymbolType new_type, const string &name)
{
int symb_id;
try
{
symb_id = mod_file->symbol_table.getID(name);
mod_file->symbol_table.changeType(symb_id, new_type);
// remove error messages
undeclared_model_vars.erase(name);
for (auto it = undeclared_model_variable_errors.begin();
it != undeclared_model_variable_errors.end();)
if (it->first == name)
it = undeclared_model_variable_errors.erase(it);
else
++it;
}
catch (SymbolTable::UnknownSymbolNameException &e)
{
switch (new_type)
{
case SymbolType::endogenous:
declare_endogenous(name);
break;
case SymbolType::exogenous:
declare_exogenous(name);
break;
case SymbolType::parameter:
declare_parameter(name);
break;
default:
error("Type not yet supported");
}
symb_id = mod_file->symbol_table.getID(name);
}
return add_model_variable(symb_id, 0);
}
expr_t
ParsingDriver::add_model_variable(int symb_id, int lag)
{
assert(symb_id >= 0);
SymbolType type = mod_file->symbol_table.getType(symb_id);
if (type == SymbolType::modFileLocalVariable)
error("Variable " + mod_file->symbol_table.getName(symb_id)
+" not allowed inside model declaration. Its scope is only outside model.");
if (type == SymbolType::externalFunction)
error("Symbol " + mod_file->symbol_table.getName(symb_id)
+" is a function name external to Dynare. It cannot be used like a variable without input argument inside model.");
// See dynare#1765
if (type == SymbolType::exogenousDet && lag != 0)
error("Exogenous deterministic variable " + mod_file->symbol_table.getName(symb_id) + " cannot be given a lead or a lag.");
if (type == SymbolType::modelLocalVariable && lag != 0)
error("Model local variable " + mod_file->symbol_table.getName(symb_id) + " cannot be given a lead or a lag.");
if (dynamic_cast<StaticModel *>(model_tree) && lag != 0)
error("Leads and lags on variables are forbidden in 'planner_objective'.");
if (dynamic_cast<StaticModel *>(model_tree) && type == SymbolType::modelLocalVariable)
error("Model local variable " + mod_file->symbol_table.getName(symb_id) + " cannot be used in 'planner_objective'.");
// It makes sense to allow a lead/lag on parameters: during steady state calibration, endogenous and parameters can be swapped
return model_tree->AddVariable(symb_id, lag);
}
expr_t
ParsingDriver::add_expression_variable(const string &name)
{
if (name.find(".") != string::npos)
error(name + " treated as a variable, but it contains a '.'");
if (parsing_epilogue && !mod_file->symbol_table.exists(name))
error("Variable " + name + " used in the epilogue block but was not declared.");
// If symbol doesn't exist, then declare it as a mod file local variable
if (!mod_file->symbol_table.exists(name))
mod_file->symbol_table.addSymbol(name, SymbolType::modFileLocalVariable);
// This check must come after the previous one!
if (mod_file->symbol_table.getType(name) == SymbolType::modelLocalVariable)
error("Variable " + name + " not allowed outside model declaration. Its scope is only inside model.");
if (mod_file->symbol_table.getType(name) == SymbolType::trend
|| mod_file->symbol_table.getType(name) == SymbolType::logTrend)
error("Variable " + name + " not allowed outside model declaration, because it is a trend variable.");
if (mod_file->symbol_table.getType(name) == SymbolType::externalFunction)
error("Symbol '" + name + "' is the name of a MATLAB/Octave function, and cannot be used as a variable.");
int symb_id = mod_file->symbol_table.getID(name);
return data_tree->AddVariable(symb_id);
}
void
ParsingDriver::declare_nonstationary_var(const string &name, const string &tex_name, const vector<pair<string, string>> &partition_value)
{
declare_endogenous(name, tex_name, partition_value);
declared_nonstationary_vars.push_back(mod_file->symbol_table.getID(name));
mod_file->nonstationary_variables = true;
}
void
ParsingDriver::end_nonstationary_var(bool log_deflator, expr_t deflator)
{
try
{
dynamic_model->addNonstationaryVariables(declared_nonstationary_vars, log_deflator, deflator);
}
catch (DataTree::TrendException &e)
{
error("Variable " + e.name + " was listed more than once as following a trend.");
}
set<int> r;
deflator->collectVariables(SymbolType::endogenous, r);
for (int it : r)
if (dynamic_model->isNonstationary(it))
error("The deflator contains a non-stationary endogenous variable. This is not allowed. Please use only stationary endogenous and/or {log_}trend_vars.");
declared_nonstationary_vars.clear();
reset_data_tree();
}
void
ParsingDriver::periods(const string &periods)
{
warning("periods: this command is now deprecated and may be removed in a future version of Dynare. Please use the ''periods'' option of the ''simul'' command instead.");
int periods_val = stoi(periods);
mod_file->addStatement(make_unique<PeriodsStatement>(periods_val));
}
void
ParsingDriver::dsample(const string &arg1)
{
int arg1_val = stoi(arg1);
mod_file->addStatement(make_unique<DsampleStatement>(arg1_val));
}
void
ParsingDriver::dsample(const string &arg1, const string &arg2)
{
int arg1_val = stoi(arg1);
int arg2_val = stoi(arg2);
mod_file->addStatement(make_unique<DsampleStatement>(arg1_val, arg2_val));
}
void
ParsingDriver::init_param(const string &name, expr_t rhs)
{
check_symbol_is_parameter(name);
int symb_id = mod_file->symbol_table.getID(name);
mod_file->addStatement(make_unique<InitParamStatement>(symb_id, rhs, mod_file->symbol_table));
}
void
ParsingDriver::init_val(const string &name, expr_t rhs)
{
if (nostrict)
if (!mod_file->symbol_table.exists(name))
{
warning("discarding '" + name + "' as it was not recognized in the initval or endval statement");
return;
}
check_symbol_is_endogenous_or_exogenous(name);
int symb_id = mod_file->symbol_table.getID(name);
init_values.emplace_back(symb_id, rhs);
}
void
ParsingDriver::initval_file()
{
mod_file->addStatement(make_unique<InitvalFileStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::hist_val(const string &name, const string &lag, expr_t rhs)
{
if (nostrict)
if (!mod_file->symbol_table.exists(name))
{
warning("discarding '" + name + "' as it was not recognized in the histval block");
return;
}
check_symbol_is_endogenous_or_exogenous(name);
int symb_id = mod_file->symbol_table.getID(name);
int ilag = stoi(lag);
if (ilag > 0)
error("histval: the lag on " + name + " should be less than or equal to 0");
pair<int, int> key(symb_id, ilag);
if (hist_values.find(key) != hist_values.end())
error("hist_val: (" + name + ", " + lag + ") declared twice");
hist_values[key] = rhs;
}
void
ParsingDriver::homotopy_val(const string &name, expr_t val1, expr_t val2)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
SymbolType type = mod_file->symbol_table.getType(symb_id);
if (type != SymbolType::parameter
&& type != SymbolType::exogenous
&& type != SymbolType::exogenousDet)
error("homotopy_val: " + name + " should be a parameter or exogenous variable");
homotopy_values.emplace_back(symb_id, val1, val2);
}
void
ParsingDriver::end_generate_irfs()
{
mod_file->addStatement(make_unique<GenerateIRFsStatement>(options_list, generate_irf_names, generate_irf_elements));
generate_irf_elements.clear();
generate_irf_names.clear();
options_list.clear();
}
void
ParsingDriver::add_generate_irfs_element(string name)
{
for (const auto &it : generate_irf_names)
if (it == name)
error("Names in the generate_irfs block must be unique but you entered '"
+ name + "' more than once.");
generate_irf_names.push_back(move(name));
generate_irf_elements.push_back(generate_irf_exos);
generate_irf_exos.clear();
}
void
ParsingDriver::add_generate_irfs_exog_element(string exo, const string &value)
{
check_symbol_is_exogenous(exo);
if (generate_irf_exos.find(exo) != generate_irf_exos.end())
error("You have set the exogenous variable " + exo + " twice.");
generate_irf_exos[move(exo)] = stod(value);
}
void
ParsingDriver::forecast()
{
mod_file->addStatement(make_unique<ForecastStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::use_dll()
{
mod_file->use_dll = true;
}
void
ParsingDriver::block()
{
mod_file->block = true;
}
void
ParsingDriver::no_static()
{
mod_file->no_static = true;
}
void
ParsingDriver::bytecode()
{
mod_file->bytecode = true;
}
void
ParsingDriver::occbin()
{
mod_file->occbin = true;
}
void
ParsingDriver::differentiate_forward_vars_all()
{
mod_file->differentiate_forward_vars = true;
}
void
ParsingDriver::differentiate_forward_vars_some()
{
mod_file->differentiate_forward_vars = true;
mod_file->differentiate_forward_vars_subset = symbol_list.get_symbols();
for (auto &it : mod_file->differentiate_forward_vars_subset)
check_symbol_is_endogenous(it);
symbol_list.clear();
}
void
ParsingDriver::cutoff(const string &value)
{
double val = stod(value);
mod_file->dynamic_model.cutoff = val;
mod_file->static_model.cutoff = val;
}
void
ParsingDriver::mfs(const string &value)
{
int val = stoi(value);
mod_file->dynamic_model.mfs = val;
mod_file->static_model.mfs = val;
}
void
ParsingDriver::compilation_setup_substitute_flags(const string &flags)
{
mod_file->dynamic_model.user_set_subst_flags = flags;
}
void
ParsingDriver::compilation_setup_add_flags(const string &flags)
{
mod_file->dynamic_model.user_set_add_flags = flags;
}
void
ParsingDriver::compilation_setup_substitute_libs(const string &libs)
{
mod_file->dynamic_model.user_set_subst_libs = libs;
}
void
ParsingDriver::compilation_setup_add_libs(const string &libs)
{
mod_file->dynamic_model.user_set_add_libs = libs;
}
void
ParsingDriver::compilation_setup_compiler(const string &compiler)
{
mod_file->dynamic_model.user_set_compiler = compiler;
}
void
ParsingDriver::balanced_growth_test_tol(const string &value)
{
mod_file->dynamic_model.balanced_growth_test_tol = stod(value);
}
void
ParsingDriver::end_initval(bool all_values_required)
{
mod_file->addStatement(make_unique<InitValStatement>(init_values, mod_file->symbol_table, all_values_required));
init_values.clear();
}
void
ParsingDriver::end_endval(bool all_values_required)
{
mod_file->addStatement(make_unique<EndValStatement>(init_values, mod_file->symbol_table, all_values_required));
init_values.clear();
}
void
ParsingDriver::end_histval(bool all_values_required)
{
mod_file->addStatement(make_unique<HistValStatement>(hist_values, mod_file->symbol_table, all_values_required));
hist_values.clear();
}
void
ParsingDriver::end_homotopy()
{
mod_file->addStatement(make_unique<HomotopyStatement>(homotopy_values, mod_file->symbol_table));
homotopy_values.clear();
}
void
ParsingDriver::begin_epilogue()
{
parsing_epilogue = true;
set_current_data_tree(&mod_file->epilogue);
}
void
ParsingDriver::end_epilogue()
{
parsing_epilogue = false;
reset_data_tree();
}
void
ParsingDriver::add_epilogue_variable(const string &name)
{
declare_symbol(name, SymbolType::epilogue, "", {});
}
void
ParsingDriver::add_epilogue_equal(const string &name, expr_t expr)
{
mod_file->epilogue.addDefinition(mod_file->symbol_table.getID(name), expr);
}
void
ParsingDriver::begin_model()
{
set_current_data_tree(&mod_file->dynamic_model);
}
void
ParsingDriver::end_model()
{
bool exit_after_write = false;
if (model_errors.size() > 0)
for (auto &it : model_errors)
{
if (it.first.empty())
exit_after_write = true;
cerr << it.second;
}
if (undeclared_model_variable_errors.size() > 0)
for (auto &it : undeclared_model_variable_errors)
if (nostrict)
warning(it.second);
else
{
exit_after_write = true;
cerr << it.second << endl;
}
if (exit_after_write)
exit(EXIT_FAILURE);
reset_data_tree();
}
void
ParsingDriver::end_shocks(bool overwrite)
{
mod_file->addStatement(make_unique<ShocksStatement>(overwrite, det_shocks, var_shocks, std_shocks,
covar_shocks, corr_shocks, mod_file->symbol_table));
det_shocks.clear();
var_shocks.clear();
std_shocks.clear();
covar_shocks.clear();
corr_shocks.clear();
}
void
ParsingDriver::end_mshocks(bool overwrite)
{
mod_file->addStatement(make_unique<MShocksStatement>(overwrite, det_shocks, mod_file->symbol_table));
det_shocks.clear();
}
void
ParsingDriver::end_heteroskedastic_shocks(bool overwrite)
{
mod_file->addStatement(make_unique<HeteroskedasticShocksStatement>(overwrite, heteroskedastic_shocks_values,
heteroskedastic_shocks_scales, mod_file->symbol_table));
heteroskedastic_shocks_values.clear();
heteroskedastic_shocks_scales.clear();
}
void
ParsingDriver::add_det_shock(const string &var, const vector<pair<int, int>> &periods, const vector<expr_t> &values, bool conditional_forecast)
{
if (conditional_forecast)
check_symbol_is_endogenous(var);
else
check_symbol_is_exogenous(var);
int symb_id = mod_file->symbol_table.getID(var);
if (det_shocks.find(symb_id) != det_shocks.end())
error("shocks/conditional_forecast_paths: variable " + var + " declared twice");
if (periods.size() != values.size())
error("shocks/conditional_forecast_paths: variable " + var + ": number of periods is different from number of shock values");
vector<ShocksStatement::DetShockElement> v;
for (size_t i = 0; i < periods.size(); i++)
{
ShocksStatement::DetShockElement dse;
dse.period1 = periods[i].first;
dse.period2 = periods[i].second;
dse.value = values[i];
v.push_back(dse);
}
det_shocks[symb_id] = v;
}
void
ParsingDriver::add_heteroskedastic_shock(const string &var, const vector<pair<int, int>> &periods, const vector<expr_t> &values, bool scales)
{
check_symbol_is_exogenous(var);
int symb_id = mod_file->symbol_table.getID(var);
if ((!scales && heteroskedastic_shocks_values.find(symb_id) != heteroskedastic_shocks_values.end())
|| (scales && heteroskedastic_shocks_scales.find(symb_id) != heteroskedastic_shocks_scales.end()))
error("heteroskedastic_shocks: variable " + var + " declared twice");
if (periods.size() != values.size())
error("heteroskedastic_shocks: variable " + var + ": number of periods is different from number of shock values");
vector<tuple<int, int, expr_t>> v;
for (size_t i = 0; i < periods.size(); i++)
v.push_back({ periods[i].first, periods[i].second, values[i] });
if (scales)
heteroskedastic_shocks_scales[symb_id] = v;
else
heteroskedastic_shocks_values[symb_id] = v;
}
void
ParsingDriver::add_stderr_shock(const string &var, expr_t value)
{
if (nostrict)
if (!mod_file->symbol_table.exists(var))
{
warning("discarding shocks block declaration of the standard error of '" + var + "' as it was not declared");
return;
}
check_symbol_existence(var);
int symb_id = mod_file->symbol_table.getID(var);
if (var_shocks.find(symb_id) != var_shocks.end()
|| std_shocks.find(symb_id) != std_shocks.end())
error("shocks: variance or stderr of shock on " + var + " declared twice");
std_shocks[symb_id] = value;
}
void
ParsingDriver::add_var_shock(const string &var, expr_t value)
{
if (nostrict)
if (!mod_file->symbol_table.exists(var))
{
warning("discarding shocks block declaration of the variance of '" + var + "' as it was not declared");
return;
}
check_symbol_existence(var);
int symb_id = mod_file->symbol_table.getID(var);
if (var_shocks.find(symb_id) != var_shocks.end()
|| std_shocks.find(symb_id) != std_shocks.end())
error("shocks: variance or stderr of shock on " + var + " declared twice");
var_shocks[symb_id] = value;
}
void
ParsingDriver::add_covar_shock(const string &var1, const string &var2, expr_t value)
{
if (nostrict)
if (!mod_file->symbol_table.exists(var1) || !mod_file->symbol_table.exists(var2))
{
warning("discarding shocks block declaration of the covariance of '" + var1 + "' and '" + var2 + "' as at least one was not declared");
return;
}
check_symbol_existence(var1);
check_symbol_existence(var2);
int symb_id1 = mod_file->symbol_table.getID(var1);
int symb_id2 = mod_file->symbol_table.getID(var2);
pair<int, int> key(symb_id1, symb_id2), key_inv(symb_id2, symb_id1);
if (covar_shocks.find(key) != covar_shocks.end()
|| covar_shocks.find(key_inv) != covar_shocks.end()
|| corr_shocks.find(key) != corr_shocks.end()
|| corr_shocks.find(key_inv) != corr_shocks.end())
error("shocks: covariance or correlation shock on variable pair (" + var1 + ", "
+ var2 + ") declared twice");
covar_shocks[key] = value;
}
void
ParsingDriver::add_correl_shock(const string &var1, const string &var2, expr_t value)
{
if (nostrict)
if (!mod_file->symbol_table.exists(var1) || !mod_file->symbol_table.exists(var2))
{
warning("discarding shocks block declaration of the correlation of '" + var1 + "' and '" + var2 + "' as at least one was not declared");
return;
}
check_symbol_existence(var1);
check_symbol_existence(var2);
int symb_id1 = mod_file->symbol_table.getID(var1);
int symb_id2 = mod_file->symbol_table.getID(var2);
pair<int, int> key(symb_id1, symb_id2), key_inv(symb_id2, symb_id1);
if (covar_shocks.find(key) != covar_shocks.end()
|| covar_shocks.find(key_inv) != covar_shocks.end()
|| corr_shocks.find(key) != corr_shocks.end()
|| corr_shocks.find(key_inv) != corr_shocks.end())
error("shocks: covariance or correlation shock on variable pair (" + var1 + ", "
+ var2 + ") declared twice");
corr_shocks[key] = value;
}
void
ParsingDriver::begin_svar_identification()
{
svar_upper_cholesky = false;
svar_lower_cholesky = false;
svar_constants_exclusion = false;
}
void
ParsingDriver::end_svar_identification()
{
mod_file->addStatement(make_unique<SvarIdentificationStatement>(svar_ident_restrictions,
svar_upper_cholesky,
svar_lower_cholesky,
svar_constants_exclusion,
mod_file->symbol_table));
svar_restriction_symbols.clear();
svar_equation_restrictions.clear();
svar_ident_restrictions.clear();
svar_Qi_restriction_nbr.clear();
svar_Ri_restriction_nbr.clear();
}
void
ParsingDriver::combine_lag_and_restriction(const string &lag)
{
int current_lag = stoi(lag);
for (const auto &it : svar_ident_restrictions)
if (it.lag == current_lag)
error("lag " + lag + " used more than once.");
for (const auto &it : svar_equation_restrictions)
for (auto it1 : it.second)
{
SvarIdentificationStatement::svar_identification_restriction new_restriction;
new_restriction.equation = it.first;
if (current_lag > 0)
new_restriction.restriction_nbr = ++svar_Ri_restriction_nbr[it.first];
else
new_restriction.restriction_nbr = ++svar_Qi_restriction_nbr[it.first];
new_restriction.lag = current_lag;
new_restriction.variable = it1;
new_restriction.value = data_tree->One;
svar_ident_restrictions.push_back(new_restriction);
}
svar_upper_cholesky = false;
svar_lower_cholesky = false;
svar_equation_restrictions.clear();
}
void
ParsingDriver::add_restriction_in_equation(const string &equation)
{
int eqn = stoi(equation);
if (eqn < 1)
error("equation numbers must be greater than or equal to 1.");
if (svar_equation_restrictions.count(eqn) > 0)
error("equation number " + equation + " referenced more than once under a single lag.");
svar_equation_restrictions[eqn] = svar_restriction_symbols;
svar_restriction_symbols.clear();
}
void
ParsingDriver::add_in_svar_restriction_symbols(const string &tmp_var)
{
check_symbol_existence(tmp_var);
int symb_id = mod_file->symbol_table.getID(tmp_var);
for (const auto &viit : svar_restriction_symbols)
if (symb_id == viit)
error(tmp_var + " restriction added twice.");
svar_restriction_symbols.push_back(symb_id);
}
void
ParsingDriver::add_restriction_equation_nbr(const string &eq_nbr)
{
svar_equation_nbr = stoi(eq_nbr);
svar_left_handside = true;
// reinitialize restriction type that must be set from the first restriction element
svar_restriction_type = SvarRestrictionType::NOT_SET;
}
void
ParsingDriver::add_restriction_equal()
{
if (svar_left_handside)
svar_left_handside = false;
else
error("svar_identification: there are more than one EQUAL sign in a restriction equation");
}
void
ParsingDriver::add_positive_restriction_element(expr_t value, const string &variable, const string &lag)
{
// if the expression is not on the left handside, change its sign
if (!svar_left_handside)
value = add_uminus(value);
add_restriction_element(value, variable, lag);
}
void
ParsingDriver::add_positive_restriction_element(const string &variable, const string &lag)
{
expr_t value(data_tree->One);
// if the expression is not on the left handside, change its sign
if (!svar_left_handside)
value = add_uminus(value);
add_restriction_element(value, variable, lag);
}
void
ParsingDriver::add_negative_restriction_element(expr_t value, const string &variable, const string &lag)
{
// if the expression is on the left handside, change its sign
if (svar_left_handside)
value = add_uminus(value);
add_restriction_element(value, variable, lag);
}
void
ParsingDriver::add_negative_restriction_element(const string &variable, const string &lag)
{
expr_t value(data_tree->One);
// if the expression is on the left handside, change its sign
if (svar_left_handside)
value = add_uminus(value);
add_restriction_element(value, variable, lag);
}
void
ParsingDriver::add_restriction_element(expr_t value, const string &variable, const string &lag)
{
check_symbol_existence(variable);
int symb_id = mod_file->symbol_table.getID(variable);
int current_lag = stoi(lag);
if (svar_restriction_type == SvarRestrictionType::NOT_SET)
{
if (current_lag == 0)
{
svar_restriction_type = SvarRestrictionType::Qi_TYPE;
++svar_Qi_restriction_nbr[svar_equation_nbr];
}
else
{
svar_restriction_type = SvarRestrictionType::Ri_TYPE;
++svar_Ri_restriction_nbr[svar_equation_nbr];
}
}
else
{
if ((svar_restriction_type == SvarRestrictionType::Qi_TYPE && current_lag > 0)
|| (svar_restriction_type == SvarRestrictionType::Ri_TYPE && current_lag == 0))
error("SVAR_IDENTIFICATION: a single restrictions must affect either Qi or Ri, but not both");
}
SvarIdentificationStatement::svar_identification_restriction new_restriction;
new_restriction.equation = svar_equation_nbr;
if (current_lag > 0)
new_restriction.restriction_nbr = svar_Ri_restriction_nbr[svar_equation_nbr];
else
new_restriction.restriction_nbr = svar_Qi_restriction_nbr[svar_equation_nbr];
new_restriction.lag = current_lag;
new_restriction.variable = symb_id;
new_restriction.value = value;
svar_ident_restrictions.push_back(new_restriction);
}
void
ParsingDriver::check_restriction_expression_constant(expr_t value)
{
if (value->eval({}) != 0)
error("SVAR_INDENTIFICATION restrictions must be homogenous");
}
void
ParsingDriver::add_upper_cholesky()
{
svar_upper_cholesky = true;
}
void
ParsingDriver::add_lower_cholesky()
{
svar_lower_cholesky = true;
}
void
ParsingDriver::add_constants_exclusion()
{
svar_constants_exclusion = true;
}
void
ParsingDriver::add_svar_global_identification_check()
{
mod_file->addStatement(make_unique<SvarGlobalIdentificationCheckStatement>());
}
void
ParsingDriver::do_sigma_e()
{
warning("Sigma_e: this command is now deprecated and may be removed in a future version of Dynare. Please use the ''shocks'' command instead.");
try
{
mod_file->addStatement(make_unique<SigmaeStatement>(sigmae_matrix));
}
catch (SigmaeStatement::MatrixFormException &e)
{
error("Sigma_e: matrix is neither upper triangular nor lower triangular");
}
sigmae_matrix.clear();
}
void
ParsingDriver::end_of_row()
{
sigmae_matrix.push_back(sigmae_row);
sigmae_row.clear();
}
void
ParsingDriver::add_to_row_const(const string &v)
{
expr_t id;
if (v.at(0) == '-')
id = data_tree->AddUMinus(data_tree->AddNonNegativeConstant(v.substr(1, string::npos)));
else
id = data_tree->AddNonNegativeConstant(v);
sigmae_row.push_back(id);
}
void
ParsingDriver::add_to_row(expr_t v)
{
sigmae_row.push_back(v);
}
void
ParsingDriver::steady()
{
mod_file->addStatement(make_unique<SteadyStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::option_num(string name_option, string opt1, string opt2)
{
if (options_list.paired_num_options.find(name_option)
!= options_list.paired_num_options.end())
error("option " + name_option + " declared twice");
options_list.paired_num_options[move(name_option)] = { move(opt1), move(opt2) };
}
void
ParsingDriver::option_num(string name_option, string opt)
{
if (options_list.num_options.find(name_option) != options_list.num_options.end())
error("option " + name_option + " declared twice");
options_list.num_options[move(name_option)] = move(opt);
}
void
ParsingDriver::option_str(string name_option, string opt)
{
if (options_list.string_options.find(name_option)
!= options_list.string_options.end())
error("option " + name_option + " declared twice");
options_list.string_options[move(name_option)] = move(opt);
}
void
ParsingDriver::option_date(string name_option, string opt)
{
if (options_list.date_options.find(name_option)
!= options_list.date_options.end())
error("option " + name_option + " declared twice");
options_list.date_options[move(name_option)] = move(opt);
}
void
ParsingDriver::option_symbol_list(string name_option)
{
if (options_list.symbol_list_options.find(name_option)
!= options_list.symbol_list_options.end())
error("option " + name_option + " declared twice");
if (name_option.compare("irf_shocks") == 0)
{
vector<string> shocks = symbol_list.get_symbols();
for (auto &shock : shocks)
{
if (!mod_file->symbol_table.exists(shock))
error("Unknown symbol: " + shock);
if (mod_file->symbol_table.getType(shock) != SymbolType::exogenous)
error("Variables passed to irf_shocks must be exogenous. Caused by: " + shock);
}
}
if (name_option.compare("ms.parameters") == 0)
{
vector<string> parameters = symbol_list.get_symbols();
for (auto &it : parameters)
if (mod_file->symbol_table.getType(it) != SymbolType::parameter)
error("Variables passed to the parameters option of the markov_switching statement must be parameters. Caused by: " + it);
}
options_list.symbol_list_options[move(name_option)] = symbol_list;
symbol_list.clear();
}
void
ParsingDriver::option_vec_int(string name_option, vector<int> opt)
{
if (options_list.vector_int_options.find(name_option)
!= options_list.vector_int_options.end())
error("option " + name_option + " declared twice");
if (opt.empty())
error("option " + name_option + " was passed an empty vector.");
options_list.vector_int_options[move(name_option)] = move(opt);
}
void
ParsingDriver::option_vec_str(string name_option, vector<string> opt)
{
if (options_list.vector_str_options.find(name_option)
!= options_list.vector_str_options.end())
error("option " + name_option + " declared twice");
if (opt.empty())
error("option " + name_option + " was passed an empty vector.");
options_list.vector_str_options[move(name_option)] = move(opt);
}
void
ParsingDriver::option_vec_cellstr(string name_option, vector<string> opt)
{
if (options_list.vector_cellstr_options.find(name_option)
!= options_list.vector_cellstr_options.end())
error("option " + name_option + " declared twice");
if (opt.empty())
error("option " + name_option + " was passed an empty vector.");
options_list.vector_cellstr_options[move(name_option)] = move(opt);
}
void
ParsingDriver::linear()
{
mod_file->linear = true;
}
void
ParsingDriver::add_in_symbol_list(const string &tmp_var)
{
symbol_list.addSymbol(tmp_var);
}
void
ParsingDriver::rplot()
{
mod_file->addStatement(make_unique<RplotStatement>(symbol_list));
symbol_list.clear();
}
void
ParsingDriver::stoch_simul()
{
//make sure default order is known to preprocessor, see #49
if (options_list.num_options.find("order") == options_list.num_options.end())
options_list.num_options["order"] = "2";
mod_file->addStatement(make_unique<StochSimulStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::trend_component_model()
{
auto its = options_list.string_options.find("trend_component.name");
if (its == options_list.string_options.end())
error("You must pass the model_name option to the trend_component_model statement.");
auto name = its->second;
auto itvs = options_list.vector_str_options.find("trend_component.eqtags");
if (itvs == options_list.vector_str_options.end())
error("You must pass the eqtags option to the trend_component_model statement.");
auto eqtags = itvs->second;
auto itvs1 = options_list.vector_str_options.find("trend_component.targets");
if (itvs1 == options_list.vector_str_options.end())
error("You must pass the targets option to the trend_component_model statement.");
auto targets = itvs1->second;
mod_file->trend_component_model_table.addTrendComponentModel(name, eqtags, targets);
options_list.clear();
}
void
ParsingDriver::var_model()
{
auto its = options_list.string_options.find("var.model_name");
if (its == options_list.string_options.end())
error("You must pass the model_name option to the var_model statement.");
auto name = its->second;
int order = 0;
auto itn = options_list.num_options.find("var.order");
if (itn != options_list.num_options.end())
order = stoi(itn->second);
else
if (!symbol_list.empty())
error("You must pass the order option when passing a symbol list to the var_model statement");
vector<string> eqtags;
auto itvs = options_list.vector_str_options.find("var.eqtags");
if (itvs != options_list.vector_str_options.end())
{
eqtags = itvs->second;
if (!symbol_list.empty())
error("You cannot pass a symbol list when passing equation tags to the var_model statement");
else if (itn != options_list.num_options.end())
error("You cannot pass the order option when passing equation tags to the var_model statement");
}
mod_file->var_model_table.addVarModel(name, eqtags, {symbol_list, order});
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::simul()
{
warning("The 'simul' statement is deprecated. Please use 'perfect_foresight_setup' and 'perfect_foresight_solver' instead.");
mod_file->addStatement(make_unique<SimulStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::model_info()
{
mod_file->addStatement(make_unique<ModelInfoStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::check()
{
mod_file->addStatement(make_unique<CheckStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::add_estimated_params_element()
{
if (estim_params.name != "dsge_prior_weight")
{
check_symbol_existence(estim_params.name);
SymbolType type = mod_file->symbol_table.getType(estim_params.name);
switch (estim_params.type)
{
case 1:
if (type != SymbolType::endogenous && type != SymbolType::exogenous)
error(estim_params.name + " must be an endogenous or an exogenous variable");
break;
case 2:
check_symbol_is_parameter(estim_params.name);
break;
case 3:
check_symbol_existence(estim_params.name2);
SymbolType type2 = mod_file->symbol_table.getType(estim_params.name2);
if ((type != SymbolType::endogenous && type != SymbolType::exogenous) || type != type2)
error(estim_params.name + " and " + estim_params.name2 + " must either be both endogenous variables or both exogenous");
break;
}
}
estim_params_list.push_back(estim_params);
estim_params.init(*data_tree);
}
void
ParsingDriver::estimated_params()
{
mod_file->addStatement(make_unique<EstimatedParamsStatement>(estim_params_list, mod_file->symbol_table));
estim_params_list.clear();
}
void
ParsingDriver::estimated_params_init(bool use_calibration)
{
mod_file->addStatement(make_unique<EstimatedParamsInitStatement>(estim_params_list, mod_file->symbol_table, use_calibration));
estim_params_list.clear();
}
void
ParsingDriver::estimated_params_bounds()
{
mod_file->addStatement(make_unique<EstimatedParamsBoundsStatement>(estim_params_list, mod_file->symbol_table));
estim_params_list.clear();
}
void
ParsingDriver::add_osr_params_element()
{
check_symbol_existence(osr_params.name);
SymbolType type = mod_file->symbol_table.getType(osr_params.name);
if (type != SymbolType::parameter)
error(osr_params.name + " must be a parameter to be used in the osr_bounds block");
osr_params_list.push_back(osr_params);
osr_params.init(*data_tree);
}
void
ParsingDriver::osr_params_bounds()
{
mod_file->addStatement(make_unique<OsrParamsBoundsStatement>(osr_params_list));
osr_params_list.clear();
}
void
ParsingDriver::set_unit_root_vars()
{
mod_file->addStatement(make_unique<UnitRootVarsStatement>());
warning("''unit_root_vars'' is now obsolete; use the ''diffuse_filter'' option of ''estimation'' instead");
symbol_list.clear();
}
void
ParsingDriver::set_time(const string &arg)
{
option_date("initial_period", arg);
mod_file->addStatement(make_unique<SetTimeStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::estimation_data()
{
mod_file->addStatement(make_unique<EstimationDataStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::set_subsamples(string name1, string name2)
{
check_symbol_existence(name1);
if (!name2.empty())
check_symbol_existence(name2);
mod_file->addStatement(make_unique<SubsamplesStatement>(name1, name2, subsample_declaration_map,
mod_file->symbol_table));
subsample_declarations[{ move(name1), move(name2) }] = subsample_declaration_map;
subsample_declaration_map.clear();
}
void
ParsingDriver::copy_subsamples(string to_name1, string to_name2, string from_name1, string from_name2)
{
check_symbol_existence(to_name1);
check_symbol_existence(from_name1);
if (!to_name2.empty())
check_symbol_existence(to_name2);
if (!from_name2.empty())
check_symbol_existence(from_name2);
if (subsample_declarations.find({ from_name1, from_name2 }) == subsample_declarations.end())
{
string err{from_name1};
if (!from_name2.empty())
err.append(",").append(from_name2);
error(err + " does not have an associated subsample statement.");
}
mod_file->addStatement(make_unique<SubsamplesEqualStatement>(to_name1, to_name2, from_name1, from_name2,
mod_file->symbol_table));
subsample_declarations[{ move(to_name1), move(to_name2) }]
= subsample_declarations[{ move(from_name1), move(from_name2) }];
}
void
ParsingDriver::check_symbol_is_statement_variable(const string &name)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
if (mod_file->symbol_table.getType(symb_id) != SymbolType::statementDeclaredVariable)
error(name + " is not a variable assigned in a statement");
}
void
ParsingDriver::set_subsample_name_equal_to_date_range(string name, string date1, string date2)
{
if (subsample_declaration_map.find(name) != subsample_declaration_map.end())
error("Symbol " + name + " may only be assigned once in a SUBSAMPLE statement");
subsample_declaration_map[move(name)] = { move(date1), move(date2) };
}
void
ParsingDriver::check_subsample_declaration_exists(const string &name1, const string &subsample_name)
{
if (subsample_name.empty())
return;
check_subsample_declaration_exists(name1, "", subsample_name);
}
void
ParsingDriver::check_subsample_declaration_exists(const string &name1, const string &name2, const string &subsample_name)
{
if (subsample_name.empty())
return;
check_symbol_existence(name1);
if (!name2.empty())
check_symbol_existence(name2);
auto it = subsample_declarations.find({ name1, name2 });
if (it == subsample_declarations.end())
{
it = subsample_declarations.find({ name2, name1 });
if (it == subsample_declarations.end())
{
string err{name1};
if (!name2.empty())
err.append(",").append(name2);
error("A subsample statement has not been issued for " + err);
}
}
auto tmp_map = it->second;
if (tmp_map.find(subsample_name) == tmp_map.end())
error("The subsample name " + subsample_name + " was not previously declared in a subsample statement.");
}
void
ParsingDriver::set_prior(const string &name, const string &subsample_name)
{
check_symbol_is_parameter(name);
check_subsample_declaration_exists(name, subsample_name);
mod_file->addStatement(make_unique<PriorStatement>(name, subsample_name, prior_shape, prior_variance, options_list));
options_list.clear();
set_prior_variance();
prior_shape = PriorDistributions::noShape;
}
void
ParsingDriver::set_joint_prior(const vector<string> &symbol_vec)
{
for (auto &it : symbol_vec)
add_joint_parameter(it);
mod_file->addStatement(make_unique<JointPriorStatement>(joint_parameters, prior_shape, options_list));
joint_parameters.clear();
options_list.clear();
prior_shape = PriorDistributions::noShape;
}
void
ParsingDriver::add_joint_parameter(string name)
{
check_symbol_is_parameter(name);
joint_parameters.push_back(move(name));
}
void
ParsingDriver::set_prior_variance(expr_t variance)
{
prior_variance = variance;
}
void
ParsingDriver::copy_prior(const string &to_declaration_type, const string &to_name1,
const string &to_name2, const string &to_subsample_name,
const string &from_declaration_type, const string &from_name1,
const string &from_name2, const string &from_subsample_name)
{
if (to_declaration_type == "par")
check_symbol_is_parameter(to_name1);
else
{
check_symbol_is_endogenous_or_exogenous(to_name1);
if (!to_name2.empty())
check_symbol_is_endogenous_or_exogenous(to_name2);
}
if (from_declaration_type == "par")
check_symbol_is_parameter(from_name1);
else
{
check_symbol_is_endogenous_or_exogenous(from_name1);
if (!from_name2.empty())
check_symbol_is_endogenous_or_exogenous(from_name2);
}
mod_file->addStatement(make_unique<PriorEqualStatement>(to_declaration_type, to_name1,
to_name2, to_subsample_name,
from_declaration_type, from_name1,
from_name2, from_subsample_name,
mod_file->symbol_table));
}
void
ParsingDriver::set_options(const string &name, const string &subsample_name)
{
check_symbol_is_parameter(name);
check_subsample_declaration_exists(name, subsample_name);
mod_file->addStatement(make_unique<OptionsStatement>(name, subsample_name, options_list));
options_list.clear();
}
void
ParsingDriver::copy_options(const string &to_declaration_type, const string &to_name1,
const string &to_name2, const string &to_subsample_name,
const string &from_declaration_type, const string &from_name1,
const string &from_name2, const string &from_subsample_name)
{
if (to_declaration_type == "par")
check_symbol_is_parameter(to_name1);
else
{
check_symbol_is_endogenous_or_exogenous(to_name1);
if (!to_name2.empty())
check_symbol_is_endogenous_or_exogenous(to_name2);
}
if (from_declaration_type == "par")
check_symbol_is_parameter(from_name1);
else
{
check_symbol_is_endogenous_or_exogenous(from_name1);
if (!from_name2.empty())
check_symbol_is_endogenous_or_exogenous(from_name2);
}
mod_file->addStatement(make_unique<OptionsEqualStatement>(to_declaration_type, to_name1,
to_name2, to_subsample_name,
from_declaration_type, from_name1,
from_name2, from_subsample_name,
mod_file->symbol_table));
}
void
ParsingDriver::check_symbol_is_endogenous_or_exogenous(const string &name)
{
check_symbol_existence(name);
switch (mod_file->symbol_table.getType(name))
{
case SymbolType::endogenous:
case SymbolType::exogenous:
case SymbolType::exogenousDet:
break;
default:
error(name + " is neither endogenous or exogenous.");
}
}
void
ParsingDriver::check_symbol_is_endogenous(const string &name)
{
check_symbol_existence(name);
if (mod_file->symbol_table.getType(name) != SymbolType::endogenous)
error(name + " is not endogenous.");
}
void
ParsingDriver::check_symbol_is_exogenous(const string &name)
{
check_symbol_existence(name);
switch (mod_file->symbol_table.getType(name))
{
case SymbolType::exogenous:
case SymbolType::exogenousDet:
break;
default:
error(name + " is not exogenous.");
}
}
void
ParsingDriver::set_std_prior(const string &name, const string &subsample_name)
{
check_symbol_is_endogenous_or_exogenous(name);
check_subsample_declaration_exists(name, subsample_name);
mod_file->addStatement(make_unique<StdPriorStatement>(name, subsample_name, prior_shape, prior_variance,
options_list, mod_file->symbol_table));
options_list.clear();
set_prior_variance();
prior_shape = PriorDistributions::noShape;
}
void
ParsingDriver::set_std_options(const string &name, const string &subsample_name)
{
check_symbol_is_endogenous_or_exogenous(name);
check_subsample_declaration_exists(name, subsample_name);
mod_file->addStatement(make_unique<StdOptionsStatement>(name, subsample_name, options_list, mod_file->symbol_table));
options_list.clear();
}
void
ParsingDriver::set_corr_prior(const string &name1, const string &name2, const string &subsample_name)
{
check_symbol_is_endogenous_or_exogenous(name1);
check_symbol_is_endogenous_or_exogenous(name2);
check_subsample_declaration_exists(name1, name2, subsample_name);
mod_file->addStatement(make_unique<CorrPriorStatement>(name1, name2, subsample_name, prior_shape, prior_variance,
options_list, mod_file->symbol_table));
options_list.clear();
set_prior_variance();
prior_shape = PriorDistributions::noShape;
}
void
ParsingDriver::set_corr_options(const string &name1, const string &name2, const string &subsample_name)
{
check_symbol_is_endogenous_or_exogenous(name1);
check_symbol_is_endogenous_or_exogenous(name2);
check_subsample_declaration_exists(name1, name2, subsample_name);
mod_file->addStatement(make_unique<CorrOptionsStatement>(name1, name2, subsample_name, options_list, mod_file->symbol_table));
options_list.clear();
}
void
ParsingDriver::run_estimation()
{
mod_file->addStatement(make_unique<EstimationStatement>(mod_file->symbol_table, symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::dynare_sensitivity()
{
mod_file->addStatement(make_unique<DynareSensitivityStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::check_varobs()
{
if (mod_file->symbol_table.observedVariablesNbr() > 0)
error("varobs: you cannot have several 'varobs' statements in the same MOD file");
}
void
ParsingDriver::add_varobs(const string &name)
{
check_symbol_is_endogenous(name);
int symb_id = mod_file->symbol_table.getID(name);
mod_file->symbol_table.addObservedVariable(symb_id);
}
void
ParsingDriver::check_varexobs()
{
if (mod_file->symbol_table.observedExogenousVariablesNbr() > 0)
error("varexobs: you cannot have several 'varexobs' statements in the same MOD file");
}
void
ParsingDriver::add_varexobs(const string &name)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
if (mod_file->symbol_table.getType(symb_id) != SymbolType::exogenous)
error("varexobs: " + name + " is not an exogenous variable");
mod_file->symbol_table.addObservedExogenousVariable(symb_id);
}
void
ParsingDriver::set_trends()
{
mod_file->addStatement(make_unique<ObservationTrendsStatement>(trend_elements, mod_file->symbol_table));
trend_elements.clear();
}
void
ParsingDriver::set_deterministic_trends()
{
mod_file->addStatement(make_unique<DeterministicTrendsStatement>(trend_elements, mod_file->symbol_table));
trend_elements.clear();
}
void
ParsingDriver::set_trend_element(string arg1, expr_t arg2)
{
check_symbol_existence(arg1);
if (trend_elements.find(arg1) != trend_elements.end())
error("observation_trends: " + arg1 + " declared twice");
trend_elements[move(arg1)] = arg2;
}
void
ParsingDriver::set_filter_initial_state()
{
mod_file->addStatement(make_unique<FilterInitialStateStatement>(filter_initial_state_elements, mod_file->symbol_table));
filter_initial_state_elements.clear();
}
void
ParsingDriver::set_filter_initial_state_element(const string &name, const string &lag, expr_t rhs)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
SymbolType type = mod_file->symbol_table.getType(symb_id);
int ilag = stoi(lag);
if (type != SymbolType::endogenous
&& type != SymbolType::exogenous
&& type != SymbolType::exogenousDet)
error("filter_initial_state: " + name + " should be an endogenous or exogenous variable");
if ((type == SymbolType::exogenous || type == SymbolType::exogenousDet) && ilag == 0)
error("filter_initial_state: exogenous variable " + name + " must be provided with a lag");
if (filter_initial_state_elements.find({ symb_id, ilag }) != filter_initial_state_elements.end())
error("filter_initial_state: (" + name + ", " + lag + ") declared twice");
if (mod_file->dynamic_model.minLagForSymbol(symb_id) > ilag - 1)
error("filter_initial_state: variable " + name + " does not appear in the model with the lag " + to_string(ilag-1) + " (see the reference manual for the timing convention in 'filter_initial_state')");
filter_initial_state_elements[{ symb_id, ilag }] = rhs;
}
void
ParsingDriver::set_optim_weights(string name, expr_t value)
{
check_symbol_is_endogenous(name);
if (var_weights.find(name) != var_weights.end())
error("optim_weights: " + name + " declared twice");
var_weights[move(name)] = move(value);
}
void
ParsingDriver::set_optim_weights(const string &name1, const string &name2, expr_t value)
{
check_symbol_is_endogenous(name1);
check_symbol_is_endogenous(name2);
pair<string, string> covar_key{name1, name2};
if (covar_weights.find(covar_key) != covar_weights.end())
error("optim_weights: pair of variables (" + name1 + ", " + name2
+ ") declared twice");
covar_weights[covar_key] = value;
}
void
ParsingDriver::optim_weights()
{
mod_file->addStatement(make_unique<OptimWeightsStatement>(var_weights, covar_weights, mod_file->symbol_table));
var_weights.clear();
covar_weights.clear();
}
void
ParsingDriver::set_osr_params()
{
mod_file->addStatement(make_unique<OsrParamsStatement>(symbol_list, mod_file->symbol_table));
symbol_list.clear();
}
void
ParsingDriver::run_osr()
{
mod_file->addStatement(make_unique<OsrStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::run_dynatype(const string &filename)
{
mod_file->addStatement(make_unique<DynaTypeStatement>(symbol_list, filename));
symbol_list.clear();
}
void
ParsingDriver::run_dynasave(const string &filename)
{
mod_file->addStatement(make_unique<DynaSaveStatement>(symbol_list, filename));
symbol_list.clear();
}
void
ParsingDriver::run_load_params_and_steady_state(const string &filename)
{
mod_file->addStatement(make_unique<LoadParamsAndSteadyStateStatement>(filename, mod_file->symbol_table, warnings));
}
void
ParsingDriver::run_save_params_and_steady_state(const string &filename)
{
mod_file->addStatement(make_unique<SaveParamsAndSteadyStateStatement>(filename));
}
void
ParsingDriver::run_identification()
{
mod_file->addStatement(make_unique<IdentificationStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::add_mc_filename(string filename, string prior)
{
for (auto &it : filename_list)
if (it.first == filename)
error("model_comparison: filename " + filename + " declared twice");
filename_list.emplace_back(move(filename), move(prior));
}
void
ParsingDriver::run_model_comparison()
{
mod_file->addStatement(make_unique<ModelComparisonStatement>(filename_list, options_list));
filename_list.clear();
options_list.clear();
}
void
ParsingDriver::begin_planner_objective()
{
planner_objective = make_unique<StaticModel>(mod_file->symbol_table,
mod_file->num_constants,
mod_file->external_functions_table);
set_current_data_tree(planner_objective.get());
}
void
ParsingDriver::end_planner_objective(expr_t expr)
{
// Add equation corresponding to expression
expr_t eq = model_tree->AddEqual(expr, model_tree->Zero);
model_tree->addEquation(eq, location.begin.line);
mod_file->addStatement(make_unique<PlannerObjectiveStatement>(*planner_objective));
reset_data_tree();
}
void
ParsingDriver::ramsey_model()
{
if (!mod_file->symbol_table.exists("optimal_policy_discount_factor"))
{
if (!planner_discount)
planner_discount = data_tree->One;
declare_parameter("optimal_policy_discount_factor", planner_discount_latex_name);
init_param("optimal_policy_discount_factor", planner_discount);
}
else if (planner_discount)
error("ramsey_model: the 'planner_discount' option cannot be used when the 'optimal_policy_discount_factor' parameter is explicitly declared.");
mod_file->addStatement(make_unique<RamseyModelStatement>(options_list));
options_list.clear();
planner_discount = nullptr;
planner_discount_latex_name.clear();
}
void
ParsingDriver::ramsey_policy()
{
warning("The 'ramsey_policy' statement is deprecated. Please use 'ramsey_model', 'stoch_simul', and 'evaluate_planner_objective' instead.");
if (!mod_file->symbol_table.exists("optimal_policy_discount_factor"))
{
if (!planner_discount)
planner_discount = data_tree->One;
declare_parameter("optimal_policy_discount_factor");
init_param("optimal_policy_discount_factor", planner_discount);
}
else if (planner_discount)
error("ramsey_policy: the 'planner_discount' option cannot be used when the 'optimal_policy_discount_factor' parameter is explicitly declared.");
mod_file->addStatement(make_unique<RamseyPolicyStatement>(mod_file->symbol_table,
symbol_list, options_list));
options_list.clear();
symbol_list.clear();
planner_discount = nullptr;
}
void
ParsingDriver::evaluate_planner_objective()
{
mod_file->addStatement(make_unique<EvaluatePlannerObjective>());
}
void
ParsingDriver::discretionary_policy()
{
/* The logic here is different from “ramsey_policy” and “ramsey_model”,
because we want to allow several instances of “discretionary_policy” in
the same .mod file. */
if (!mod_file->symbol_table.exists("optimal_policy_discount_factor"))
declare_parameter("optimal_policy_discount_factor");
if (!planner_discount)
planner_discount = data_tree->One;
init_param("optimal_policy_discount_factor", planner_discount);
mod_file->addStatement(make_unique<DiscretionaryPolicyStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
planner_discount = nullptr;
}
void
ParsingDriver::write_latex_dynamic_model(bool write_equation_tags)
{
mod_file->addStatement(make_unique<WriteLatexDynamicModelStatement>(mod_file->dynamic_model, write_equation_tags));
}
void
ParsingDriver::write_latex_static_model(bool write_equation_tags)
{
mod_file->addStatement(make_unique<WriteLatexStaticModelStatement>(mod_file->static_model, write_equation_tags));
}
void
ParsingDriver::write_latex_original_model(bool write_equation_tags)
{
mod_file->addStatement(make_unique<WriteLatexOriginalModelStatement>(mod_file->original_model, write_equation_tags));
}
void
ParsingDriver::write_latex_steady_state_model()
{
mod_file->addStatement(make_unique<WriteLatexSteadyStateModelStatement>(mod_file->steady_state_model));
}
void
ParsingDriver::bvar_density(const string &maxnlags)
{
mod_file->addStatement(make_unique<BVARDensityStatement>(stoi(maxnlags), options_list));
options_list.clear();
}
void
ParsingDriver::bvar_forecast(const string &nlags)
{
mod_file->addStatement(make_unique<BVARForecastStatement>(stoi(nlags), options_list));
options_list.clear();
}
void
ParsingDriver::sbvar()
{
mod_file->addStatement(make_unique<SBVARStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_estimation()
{
mod_file->addStatement(make_unique<MSSBVAREstimationStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_simulation()
{
mod_file->addStatement(make_unique<MSSBVARSimulationStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_compute_mdd()
{
mod_file->addStatement(make_unique<MSSBVARComputeMDDStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_compute_probabilities()
{
mod_file->addStatement(make_unique<MSSBVARComputeProbabilitiesStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_irf()
{
mod_file->addStatement(make_unique<MSSBVARIrfStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::ms_forecast()
{
mod_file->addStatement(make_unique<MSSBVARForecastStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::ms_variance_decomposition()
{
mod_file->addStatement(make_unique<MSSBVARVarianceDecompositionStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::svar()
{
auto it0 = options_list.string_options.find("ms.coefficients"),
it1 = options_list.string_options.find("ms.variances"),
it2 = options_list.string_options.find("ms.constants");
if (it0 == options_list.string_options.end()
&& it1 == options_list.string_options.end()
&& it2 == options_list.string_options.end())
error("You must pass one of 'coefficients', 'variances', or 'constants'.");
if ((it0 != options_list.string_options.end()
&& it1 != options_list.string_options.end())
|| (it1 != options_list.string_options.end()
&& it2 != options_list.string_options.end())
|| (it0 != options_list.string_options.end()
&& it2 != options_list.string_options.end()))
error("You may only pass one of 'coefficients', 'variances', or 'constants'.");
if (auto itn = options_list.num_options.find("ms.chain");
itn == options_list.num_options.end())
error("A chain option must be passed to the svar statement.");
else if (stoi(itn->second) <= 0)
error("The value passed to the chain option must be greater than zero.");
if (auto itv = options_list.vector_int_options.find("ms.equations");
itv != options_list.vector_int_options.end())
for (int viit : itv->second)
if (viit <= 0)
error("The value(s) passed to the equation option must be greater than zero.");
mod_file->addStatement(make_unique<SvarStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::markov_switching()
{
auto it0 = options_list.num_options.find("ms.chain");
if (it0 == options_list.num_options.end())
error("A chain option must be passed to the markov_switching statement.");
else if (stoi(it0->second) <= 0)
error("The value passed to the chain option must be greater than zero.");
it0 = options_list.num_options.find("ms.number_of_regimes");
if (it0 == options_list.num_options.end())
error("A number_of_regimes option must be passed to the markov_switching statement.");
else if (stoi(it0->second) <= 0)
error("The value passed to the number_of_regimes option must be greater than zero.");
it0 = options_list.num_options.find("ms.duration");
if (it0 == options_list.num_options.end())
error("A duration option must be passed to the markov_switching statement.");
mod_file->addStatement(make_unique<MarkovSwitchingStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::shock_decomposition()
{
mod_file->addStatement(make_unique<ShockDecompositionStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::realtime_shock_decomposition()
{
mod_file->addStatement(make_unique<RealtimeShockDecompositionStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::plot_shock_decomposition()
{
mod_file->addStatement(make_unique<PlotShockDecompositionStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::initial_condition_decomposition()
{
mod_file->addStatement(make_unique<InitialConditionDecompositionStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::squeeze_shock_decomposition()
{
mod_file->addStatement(make_unique<SqueezeShockDecompositionStatement>(symbol_list));
symbol_list.clear();
}
void
ParsingDriver::conditional_forecast()
{
mod_file->addStatement(make_unique<ConditionalForecastStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::plot_conditional_forecast(const string &periods)
{
int nperiods = periods.empty() ? -1 : stoi(periods);
mod_file->addStatement(make_unique<PlotConditionalForecastStatement>(nperiods, symbol_list));
symbol_list.clear();
}
void
ParsingDriver::conditional_forecast_paths()
{
mod_file->addStatement(make_unique<ConditionalForecastPathsStatement>(det_shocks, mod_file->symbol_table));
det_shocks.clear();
}
void
ParsingDriver::calib_smoother()
{
mod_file->addStatement(make_unique<CalibSmootherStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::extended_path()
{
mod_file->addStatement(make_unique<ExtendedPathStatement>(options_list));
options_list.clear();
}
expr_t
ParsingDriver::add_model_equal(expr_t arg1, expr_t arg2)
{
expr_t id = model_tree->AddEqual(arg1, arg2);
// Detect if the equation is tagged [static]
if (eq_tags.find("static") != eq_tags.end())
{
if (!id->isInStaticForm())
error("An equation tagged [static] cannot contain leads, lags, expectations or STEADY_STATE operators");
dynamic_model->addStaticOnlyEquation(id, location.begin.line, eq_tags);
}
else
model_tree->addEquation(id, location.begin.line, eq_tags);
eq_tags.clear();
return id;
}
expr_t
ParsingDriver::add_model_equal_with_zero_rhs(expr_t arg)
{
return add_model_equal(arg, model_tree->Zero);
}
void
ParsingDriver::declare_model_local_variable(const string &name, const string &tex_name)
{
declare_symbol(name, SymbolType::modelLocalVariable, tex_name, {});
}
void
ParsingDriver::declare_and_init_model_local_variable(const string &name, expr_t rhs)
{
int symb_id;
try
{
symb_id = mod_file->symbol_table.addSymbol(name, SymbolType::modelLocalVariable);
}
catch (SymbolTable::AlreadyDeclaredException &e)
{
/* It can have already been declared in a steady_state_model block or
model_local_variable statement, check that it is indeed a
ModelLocalVariable */
symb_id = mod_file->symbol_table.getID(name);
if (mod_file->symbol_table.getType(symb_id) != SymbolType::modelLocalVariable)
error(name + " has wrong type or was already used on the right-hand side. You cannot use it on the left-hand side of a pound ('#') expression");
}
try
{
model_tree->AddLocalVariable(symb_id, rhs);
}
catch (DataTree::LocalVariableException &e)
{
error("Local model variable " + name + " declared twice.");
}
}
void
ParsingDriver::change_type(SymbolType new_type, const vector<string> &var_list)
{
for (auto &it : var_list)
{
int id;
try
{
id = mod_file->symbol_table.getID(it);
}
catch (SymbolTable::UnknownSymbolNameException &e)
{
error("Unknown variable " + it);
}
// Check if symbol already used in a VariableNode
if (mod_file->expressions_tree.isSymbolUsed(id)
|| mod_file->dynamic_model.isSymbolUsed(id))
error("You cannot modify the type of symbol " + it + " after having used it in an expression");
mod_file->symbol_table.changeType(id, new_type);
}
}
expr_t
ParsingDriver::add_plus(expr_t arg1, expr_t arg2)
{
return data_tree->AddPlus(arg1, arg2);
}
expr_t
ParsingDriver::add_minus(expr_t arg1, expr_t arg2)
{
return data_tree->AddMinus(arg1, arg2);
}
expr_t
ParsingDriver::add_uminus(expr_t arg1)
{
return data_tree->AddUMinus(arg1);
}
expr_t
ParsingDriver::add_times(expr_t arg1, expr_t arg2)
{
return data_tree->AddTimes(arg1, arg2);
}
expr_t
ParsingDriver::add_divide(expr_t arg1, expr_t arg2)
{
try
{
return data_tree->AddDivide(arg1, arg2);
}
catch (DataTree::DivisionByZeroException)
{
error("Division by zero error encountered when reading model from .mod file");
}
}
expr_t
ParsingDriver::add_less(expr_t arg1, expr_t arg2)
{
return data_tree->AddLess(arg1, arg2);
}
expr_t
ParsingDriver::add_greater(expr_t arg1, expr_t arg2)
{
return data_tree->AddGreater(arg1, arg2);
}
expr_t
ParsingDriver::add_less_equal(expr_t arg1, expr_t arg2)
{
return data_tree->AddLessEqual(arg1, arg2);
}
expr_t
ParsingDriver::add_greater_equal(expr_t arg1, expr_t arg2)
{
return data_tree->AddGreaterEqual(arg1, arg2);
}
expr_t
ParsingDriver::add_equal_equal(expr_t arg1, expr_t arg2)
{
return data_tree->AddEqualEqual(arg1, arg2);
}
expr_t
ParsingDriver::add_different(expr_t arg1, expr_t arg2)
{
return data_tree->AddDifferent(arg1, arg2);
}
expr_t
ParsingDriver::add_power(expr_t arg1, expr_t arg2)
{
return data_tree->AddPower(arg1, arg2);
}
expr_t
ParsingDriver::add_expectation(const string &arg1, expr_t arg2)
{
return data_tree->AddExpectation(stoi(arg1), arg2);
}
expr_t
ParsingDriver::add_var_expectation(const string &model_name)
{
return data_tree->AddVarExpectation(model_name);
}
expr_t
ParsingDriver::add_pac_expectation(const string &var_model_name)
{
return data_tree->AddPacExpectation(var_model_name);
}
void
ParsingDriver::begin_pac_growth()
{
set_current_data_tree(&mod_file->dynamic_model);
}
void
ParsingDriver::begin_pac_model()
{
parsing_pac_model = true;
pac_growth = nullptr;
pac_steady_state_growth_rate_number = -1;
pac_steady_state_growth_rate_symb_id = -1;
options_list.clear();
}
void
ParsingDriver::pac_model()
{
auto it = options_list.string_options.find("pac.model_name");
if (it == options_list.string_options.end())
error("You must pass the model_name option to the pac_model statement.");
auto name = it->second;
bool pac_growth_is_param = false;
if (pac_growth && dynamic_cast<VariableNode *>(pac_growth))
{
set<int> params;
pac_growth->collectVariables(SymbolType::parameter, params);
if (params.size() == 1)
pac_growth_is_param = true;
pac_growth->collectVariables(SymbolType::endogenous, params);
pac_growth->collectVariables(SymbolType::exogenous, params);
if (params.size() != 1)
pac_growth_is_param = false;
}
string aux_model_name;
it = options_list.string_options.find("pac.aux_model_name");
if (it != options_list.string_options.end())
{
aux_model_name = it->second;
if (pac_steady_state_growth_rate_number >= 0 || pac_steady_state_growth_rate_symb_id >= 0)
{
pac_steady_state_growth_rate_number = -1;
pac_steady_state_growth_rate_symb_id = -1;
warning("when aux_model_name is used in the pac_model statement, steady_state_growth is ignored");
}
}
else
if (pac_growth_is_param
&& (pac_steady_state_growth_rate_number >= 0 || pac_steady_state_growth_rate_symb_id >= 0))
warning("If growth option is constant, steady_state_growth is ignored");
else if (pac_growth && !pac_growth_is_param
&& pac_steady_state_growth_rate_number < 0
&& pac_steady_state_growth_rate_symb_id < 0)
error("The steady state growth rate of the target must be provided (steady_state_growth option) if option growth is not constant");
if (pac_steady_state_growth_rate_symb_id >= 0
&& mod_file->symbol_table.getType(pac_steady_state_growth_rate_symb_id) != SymbolType::parameter)
error("pac_model: steady_state_growth accepts either a number or a parameter");
it = options_list.string_options.find("pac.discount");
if (it == options_list.string_options.end())
error("You must pass the discount option to the pac_model statement.");
auto discount = it->second;
mod_file->addStatement(make_unique<PacModelStatement>(name, aux_model_name, discount,
pac_growth,
pac_steady_state_growth_rate_number,
pac_steady_state_growth_rate_symb_id,
mod_file->symbol_table));
parsing_pac_model = false;
}
void
ParsingDriver::set_pac_growth(expr_t pac_growth_arg)
{
pac_growth = pac_growth_arg;
reset_data_tree();
}
void
ParsingDriver::set_pac_steady_state_growth(const string &name_or_number)
{
try
{
pac_steady_state_growth_rate_number = stod(name_or_number);
}
catch (...)
{
if (!mod_file->symbol_table.exists(name_or_number))
error("Unknown symbol used in pac_steady_state_growth option: " + name_or_number + "\n");
pac_steady_state_growth_rate_symb_id = mod_file->symbol_table.getID(name_or_number);
}
}
expr_t
ParsingDriver::add_exp(expr_t arg1)
{
return data_tree->AddExp(arg1);
}
expr_t
ParsingDriver::add_diff(expr_t arg1)
{
return data_tree->AddDiff(arg1);
}
expr_t
ParsingDriver::add_adl(expr_t arg1, const string &name, const string &lag)
{
vector<int> lags;
for (int i = 1; i <= stoi(lag); i++)
lags.push_back(i);
return add_adl(arg1, name, lags);
}
expr_t
ParsingDriver::add_adl(expr_t arg1, const string &name, const vector<int> &lags)
{
expr_t id = data_tree->AddAdl(arg1, name, lags);
// Declare parameters here so that parameters can be initialized after the model block
for (auto i : lags)
declare_parameter(name + "_lag_" + to_string(i));
return id;
}
expr_t
ParsingDriver::add_log(expr_t arg1)
{
return data_tree->AddLog(arg1);
}
expr_t
ParsingDriver::add_log10(expr_t arg1)
{
return data_tree->AddLog10(arg1);
}
expr_t
ParsingDriver::add_cos(expr_t arg1)
{
return data_tree->AddCos(arg1);
}
expr_t
ParsingDriver::add_sin(expr_t arg1)
{
return data_tree->AddSin(arg1);
}
expr_t
ParsingDriver::add_tan(expr_t arg1)
{
return data_tree->AddTan(arg1);
}
expr_t
ParsingDriver::add_acos(expr_t arg1)
{
return data_tree->AddAcos(arg1);
}
expr_t
ParsingDriver::add_asin(expr_t arg1)
{
return data_tree->AddAsin(arg1);
}
expr_t
ParsingDriver::add_atan(expr_t arg1)
{
return data_tree->AddAtan(arg1);
}
expr_t
ParsingDriver::add_cosh(expr_t arg1)
{
return data_tree->AddCosh(arg1);
}
expr_t
ParsingDriver::add_sinh(expr_t arg1)
{
return data_tree->AddSinh(arg1);
}
expr_t
ParsingDriver::add_tanh(expr_t arg1)
{
return data_tree->AddTanh(arg1);
}
expr_t
ParsingDriver::add_acosh(expr_t arg1)
{
return data_tree->AddAcosh(arg1);
}
expr_t
ParsingDriver::add_asinh(expr_t arg1)
{
return data_tree->AddAsinh(arg1);
}
expr_t
ParsingDriver::add_atanh(expr_t arg1)
{
return data_tree->AddAtanh(arg1);
}
expr_t
ParsingDriver::add_sqrt(expr_t arg1)
{
return data_tree->AddSqrt(arg1);
}
expr_t
ParsingDriver::add_cbrt(expr_t arg1)
{
return data_tree->AddCbrt(arg1);
}
expr_t
ParsingDriver::add_abs(expr_t arg1)
{
return data_tree->AddAbs(arg1);
}
expr_t
ParsingDriver::add_sign(expr_t arg1)
{
return data_tree->AddSign(arg1);
}
expr_t
ParsingDriver::add_max(expr_t arg1, expr_t arg2)
{
return data_tree->AddMax(arg1, arg2);
}
expr_t
ParsingDriver::add_min(expr_t arg1, expr_t arg2)
{
return data_tree->AddMin(arg1, arg2);
}
expr_t
ParsingDriver::add_normcdf(expr_t arg1, expr_t arg2, expr_t arg3)
{
return data_tree->AddNormcdf(arg1, arg2, arg3);
}
expr_t
ParsingDriver::add_normcdf(expr_t arg)
{
return add_normcdf(arg, data_tree->Zero, data_tree->One);
}
expr_t
ParsingDriver::add_normpdf(expr_t arg1, expr_t arg2, expr_t arg3)
{
return data_tree->AddNormpdf(arg1, arg2, arg3);
}
expr_t
ParsingDriver::add_normpdf(expr_t arg)
{
return add_normpdf(arg, data_tree->Zero, data_tree->One);
}
expr_t
ParsingDriver::add_erf(expr_t arg1)
{
return data_tree->AddErf(arg1);
}
expr_t
ParsingDriver::add_steady_state(expr_t arg1)
{
// Forbid exogenous variables, see dynare#825
set<int> r;
arg1->collectVariables(SymbolType::exogenous, r);
if (r.size() > 0)
error("Exogenous variables are not allowed in the context of the STEADY_STATE() operator.");
arg1->collectVariables(SymbolType::exogenousDet, r);
if (r.size() > 0)
error("Exogenous deterministic variables are not allowed in the context of the STEADY_STATE() operator.");
return data_tree->AddSteadyState(arg1);
}
void
ParsingDriver::external_function_option(const string &name_option, const string &opt)
{
if (name_option == "name")
{
if (opt.empty())
error("An argument must be passed to the 'name' option of the external_function() statement.");
declare_symbol(opt, SymbolType::externalFunction, "", {});
current_external_function_id = mod_file->symbol_table.getID(opt);
}
else if (name_option == "first_deriv_provided")
{
if (opt.empty())
current_external_function_options.firstDerivSymbID = ExternalFunctionsTable::IDSetButNoNameProvided;
else
{
declare_symbol(opt, SymbolType::externalFunction, "", {});
current_external_function_options.firstDerivSymbID = mod_file->symbol_table.getID(opt);
}
}
else if (name_option == "second_deriv_provided")
{
if (opt.empty())
current_external_function_options.secondDerivSymbID = ExternalFunctionsTable::IDSetButNoNameProvided;
else
{
declare_symbol(opt, SymbolType::externalFunction, "", {});
current_external_function_options.secondDerivSymbID = mod_file->symbol_table.getID(opt);
}
}
else if (name_option == "nargs")
current_external_function_options.nargs = stoi(opt);
else
error("Unexpected error in ParsingDriver::external_function_option(): Please inform Dynare Team.");
}
void
ParsingDriver::external_function()
{
if (current_external_function_id == ExternalFunctionsTable::IDNotSet)
error("The 'name' option must be passed to external_function().");
if (current_external_function_options.secondDerivSymbID >= 0
&& current_external_function_options.firstDerivSymbID == ExternalFunctionsTable::IDNotSet)
error("If the second derivative is provided to the external_function command, the first derivative must also be provided.");
if (current_external_function_options.secondDerivSymbID == ExternalFunctionsTable::IDSetButNoNameProvided
&& current_external_function_options.firstDerivSymbID != ExternalFunctionsTable::IDSetButNoNameProvided)
error("If the second derivative is provided in the top-level function, the first derivative must also be provided in that function.");
mod_file->external_functions_table.addExternalFunction(current_external_function_id, current_external_function_options, true);
reset_current_external_function_options();
}
void
ParsingDriver::push_external_function_arg_vector_onto_stack()
{
vector<expr_t> emptyvec;
stack_external_function_args.push(emptyvec);
}
void
ParsingDriver::add_external_function_arg(expr_t arg)
{
stack_external_function_args.top().push_back(arg);
}
pair<bool, double>
ParsingDriver::is_there_one_integer_argument() const
{
if (stack_external_function_args.top().size() != 1)
return { false, 0 };
auto numNode = dynamic_cast<NumConstNode *>(stack_external_function_args.top().front());
auto unaryNode = dynamic_cast<UnaryOpNode *>(stack_external_function_args.top().front());
if (!numNode && !unaryNode)
return { false, 0 };
eval_context_t ectmp;
double model_var_arg;
if (!unaryNode)
{
try
{
model_var_arg = numNode->eval(ectmp);
}
catch (ExprNode::EvalException &e)
{
return { false, 0 };
}
}
else
if (unaryNode->op_code != UnaryOpcode::uminus)
return { false, 0 };
else
{
try
{
model_var_arg = unaryNode->eval(ectmp);
}
catch (ExprNode::EvalException &e)
{
return { false, 0 };
}
}
if (model_var_arg != floor(model_var_arg))
return { false, 0 };
return { true, model_var_arg };
}
expr_t
ParsingDriver::add_model_var_or_external_function(const string &function_name, bool in_model_block)
{
expr_t nid;
if (mod_file->symbol_table.exists(function_name))
if (mod_file->symbol_table.getType(function_name) != SymbolType::externalFunction)
if (!in_model_block && !parsing_epilogue && !parsing_pac_model)
{
if (stack_external_function_args.top().size() > 0)
error(string("Symbol ") + function_name + string(" cannot take arguments."));
else
return add_expression_variable(function_name);
}
else
{ // e.g. model_var(lag) => ADD MODEL VARIABLE WITH LEAD (NumConstNode)/LAG (UnaryOpNode)
if (undeclared_model_vars.find(function_name) != undeclared_model_vars.end())
undeclared_model_variable_error("Unknown symbol: " + function_name, function_name);
pair<bool, double> rv = is_there_one_integer_argument();
if (!rv.first)
model_error("Symbol " + function_name
+" is being treated as if it were a function (i.e., takes an argument that is not an integer).", "");
nid = add_model_variable(mod_file->symbol_table.getID(function_name), static_cast<int>(rv.second));
stack_external_function_args.pop();
return nid;
}
else
{ // e.g. this function has already been referenced (either ad hoc or through the external_function() statement
// => check that the information matches previously declared info
int symb_id = mod_file->symbol_table.getID(function_name);
if (!mod_file->external_functions_table.exists(symb_id))
error("Using a derivative of an external function (" + function_name + ") in the model block is currently not allowed.");
if (in_model_block || parsing_epilogue)
if (mod_file->external_functions_table.getNargs(symb_id) == ExternalFunctionsTable::IDNotSet)
error("Before using " + function_name
+"() in the model block, you must first declare it via the external_function() statement");
else if (static_cast<int>(stack_external_function_args.top().size()) != mod_file->external_functions_table.getNargs(symb_id))
error("The number of arguments passed to " + function_name
+"() does not match those of a previous call or declaration of this function.");
}
else
{ //First time encountering this external function i.e., not previously declared or encountered
if (parsing_epilogue)
error("Variable " + function_name + " used in the epilogue block but was not declared.");
if (in_model_block)
{
// Continue processing, noting that it was not declared
// Processing will end at the end of the model block if nostrict was not passed
undeclared_model_vars.insert(function_name);
undeclared_model_variable_error("Unknown symbol: " + function_name, function_name);
pair<bool, double> rv = is_there_one_integer_argument();
if (rv.first)
{
// assume it's a lead/lagged variable
declare_exogenous(function_name);
return add_model_variable(mod_file->symbol_table.getID(function_name), static_cast<int>(rv.second));
}
else
error("To use an external function (" + function_name
+") within the model block, you must first declare it via the external_function() statement.");
}
declare_symbol(function_name, SymbolType::externalFunction, "", {});
current_external_function_options.nargs = stack_external_function_args.top().size();
mod_file->external_functions_table.addExternalFunction(mod_file->symbol_table.getID(function_name),
current_external_function_options, in_model_block);
reset_current_external_function_options();
}
//By this point, we're sure that this function exists in the External Functions Table and is not a mod var
int symb_id = mod_file->symbol_table.getID(function_name);
nid = data_tree->AddExternalFunction(symb_id, stack_external_function_args.top());
stack_external_function_args.pop();
return nid;
}
void
ParsingDriver::add_native(const string &s)
{
mod_file->addStatement(make_unique<NativeStatement>(s));
}
void
ParsingDriver::add_native_remove_charset(string str, const string &token)
{
size_t found = str.find(token);
assert(found != string::npos);
str.resize(found);
add_native(str);
}
void
ParsingDriver::add_verbatim(const string &s)
{
mod_file->addStatement(make_unique<VerbatimStatement>(s));
}
void
ParsingDriver::add_verbatim_remove_charset(string str, const string &token)
{
size_t found = str.find(token);
assert(found != string::npos);
str.resize(found);
add_verbatim(str);
}
void
ParsingDriver::begin_steady_state_model()
{
set_current_data_tree(&mod_file->steady_state_model);
}
void
ParsingDriver::add_steady_state_model_equal(const string &varname, expr_t expr)
{
int id;
try
{
id = mod_file->symbol_table.getID(varname);
}
catch (SymbolTable::UnknownSymbolNameException &e)
{
// Unknown symbol, declare it as a ModFileLocalVariable
id = mod_file->symbol_table.addSymbol(varname, SymbolType::modFileLocalVariable);
}
SymbolType type = mod_file->symbol_table.getType(id);
if (type != SymbolType::endogenous && type != SymbolType::modFileLocalVariable && type != SymbolType::parameter)
error(varname + " has incorrect type");
mod_file->steady_state_model.addDefinition(id, expr);
}
void
ParsingDriver::add_steady_state_model_equal_multiple(expr_t expr)
{
const vector<string> &symbs = symbol_list.get_symbols();
vector<int> ids;
for (const auto &symb : symbs)
{
int id;
try
{
id = mod_file->symbol_table.getID(symb);
}
catch (SymbolTable::UnknownSymbolNameException &e)
{
// Unknown symbol, declare it as a ModFileLocalVariable
id = mod_file->symbol_table.addSymbol(symb, SymbolType::modFileLocalVariable);
}
SymbolType type = mod_file->symbol_table.getType(id);
if (type != SymbolType::endogenous && type != SymbolType::modFileLocalVariable && type != SymbolType::parameter)
error(symb + " has incorrect type");
ids.push_back(id);
}
mod_file->steady_state_model.addMultipleDefinitions(ids, expr);
symbol_list.clear();
}
void
ParsingDriver::add_graph_format(const string &name)
{
graph_formats.addSymbol(name);
}
void
ParsingDriver::process_graph_format_option()
{
options_list.symbol_list_options["graph_format"] = graph_formats;
graph_formats.clear();
}
void
ParsingDriver::initial_condition_decomp_process_graph_format_option()
{
options_list.symbol_list_options["initial_condition_decomp.graph_format"] = graph_formats;
graph_formats.clear();
}
void
ParsingDriver::plot_shock_decomp_process_graph_format_option()
{
options_list.symbol_list_options["plot_shock_decomp.graph_format"] = graph_formats;
graph_formats.clear();
}
void
ParsingDriver::model_diagnostics()
{
mod_file->addStatement(make_unique<ModelDiagnosticsStatement>());
}
void
ParsingDriver::add_parallel_local_file(string filename)
{
mod_file->parallel_local_files.push_back(move(filename));
}
void
ParsingDriver::add_moment_calibration_item(const string &endo1, const string &endo2, string lags, const pair<expr_t, expr_t> &range)
{
MomentCalibration::Constraint c;
check_symbol_is_endogenous(endo1);
c.endo1 = mod_file->symbol_table.getID(endo1);
check_symbol_is_endogenous(endo2);
c.endo2 = mod_file->symbol_table.getID(endo2);
c.lags = move(lags);
c.lower_bound = range.first;
c.upper_bound = range.second;
moment_calibration_constraints.push_back(c);
}
void
ParsingDriver::end_moment_calibration()
{
mod_file->addStatement(make_unique<MomentCalibration>(moment_calibration_constraints,
mod_file->symbol_table));
moment_calibration_constraints.clear();
}
void
ParsingDriver::add_irf_calibration_item(const string &endo, string periods, const string &exo, const pair<expr_t, expr_t> &range)
{
IrfCalibration::Constraint c;
check_symbol_is_endogenous(endo);
c.endo = mod_file->symbol_table.getID(endo);
c.periods = move(periods);
check_symbol_existence(exo);
c.exo = mod_file->symbol_table.getID(exo);
if (mod_file->symbol_table.getType(exo) != SymbolType::exogenous)
error("Variable " + endo + " is not an exogenous.");
c.lower_bound = range.first;
c.upper_bound = range.second;
irf_calibration_constraints.push_back(c);
}
void
ParsingDriver::end_irf_calibration()
{
mod_file->addStatement(make_unique<IrfCalibration>(irf_calibration_constraints,
mod_file->symbol_table,
options_list));
irf_calibration_constraints.clear();
}
void
ParsingDriver::smoother2histval()
{
mod_file->addStatement(make_unique<Smoother2histvalStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::histval_file()
{
mod_file->addStatement(make_unique<HistvalFileStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::perfect_foresight_setup()
{
mod_file->addStatement(make_unique<PerfectForesightSetupStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::perfect_foresight_solver()
{
mod_file->addStatement(make_unique<PerfectForesightSolverStatement>(options_list));
options_list.clear();
}
void
ParsingDriver::method_of_moments()
{
mod_file->addStatement(make_unique<MethodOfMomentsStatement>(symbol_list, options_list));
symbol_list.clear();
options_list.clear();
}
void
ParsingDriver::prior_posterior_function(bool prior_func)
{
mod_file->addStatement(make_unique<PriorPosteriorFunctionStatement>(static_cast<bool>(prior_func), options_list));
options_list.clear();
}
void
ParsingDriver::add_ramsey_constraints_statement()
{
mod_file->addStatement(make_unique<RamseyConstraintsStatement>(mod_file->symbol_table, ramsey_constraints));
ramsey_constraints.clear();
}
void
ParsingDriver::ramsey_constraint_add_less(const string &name, const expr_t rhs)
{
add_ramsey_constraint(name, BinaryOpcode::less, rhs);
}
void
ParsingDriver::ramsey_constraint_add_greater(const string &name, const expr_t rhs)
{
add_ramsey_constraint(name, BinaryOpcode::greater, rhs);
}
void
ParsingDriver::ramsey_constraint_add_less_equal(const string &name, const expr_t rhs)
{
add_ramsey_constraint(name, BinaryOpcode::lessEqual, rhs);
}
void
ParsingDriver::ramsey_constraint_add_greater_equal(const string &name, const expr_t rhs)
{
add_ramsey_constraint(name, BinaryOpcode::greaterEqual, rhs);
}
void
ParsingDriver::add_ramsey_constraint(const string &name, BinaryOpcode op_code, const expr_t rhs)
{
check_symbol_is_endogenous(name);
int symb_id = mod_file->symbol_table.getID(name);
RamseyConstraintsStatement::Constraint C;
C.endo = symb_id;
C.code = op_code;
C.expression = rhs;
ramsey_constraints.push_back(C);
}
void
ParsingDriver::add_shock_group_element(string name)
{
check_symbol_existence(name);
int symb_id = mod_file->symbol_table.getID(name);
SymbolType type = mod_file->symbol_table.getType(symb_id);
if (type != SymbolType::exogenous)
error("shock_groups: " + name + " should be an exogenous variable");
shock_group.push_back(move(name));
}
void
ParsingDriver::add_shock_group(string name)
{
ShockGroupsStatement::Group G;
G.name = move(name);
G.list = shock_group;
shock_groups.push_back(G);
shock_group.clear();
}
void
ParsingDriver::end_shock_groups(const string &name)
{
mod_file->addStatement(make_unique<ShockGroupsStatement>(shock_groups, name));
shock_groups.clear();
}
void
ParsingDriver::add_init2shocks(const string &endo_name, const string &exo_name)
{
check_symbol_existence(endo_name);
check_symbol_existence(exo_name);
int symb_id_endo = mod_file->symbol_table.getID(endo_name);
if (mod_file->symbol_table.getType(symb_id_endo) != SymbolType::endogenous)
error("init2shocks: " + endo_name + " should be an endogenous variable");
int symb_id_exo = mod_file->symbol_table.getID(exo_name);
if (mod_file->symbol_table.getType(symb_id_exo) != SymbolType::exogenous)
error("init2shocks: " + exo_name + " should be an exogenous variable");
init2shocks.emplace_back(symb_id_endo, symb_id_exo);
}
void
ParsingDriver::end_init2shocks(const string &name)
{
mod_file->addStatement(make_unique<Init2shocksStatement>(init2shocks, name, mod_file->symbol_table));
init2shocks.clear();
}
void
ParsingDriver::var_expectation_model()
{
auto it = options_list.string_options.find("variable");
if (it == options_list.string_options.end() && !var_expectation_model_expression)
error("You must pass either the 'variable' or the 'expression' option to the var_expectation_model statement.");
if (it != options_list.string_options.end())
{
if (var_expectation_model_expression)
error("You can't pass both the 'variable' or the 'expression' options to the var_expectation_model statement.");
var_expectation_model_expression = data_tree->AddVariable(mod_file->symbol_table.getID(it->second));
}
it = options_list.string_options.find("auxiliary_model_name");
if (it == options_list.string_options.end())
error("You must pass the auxiliary_model_name option to the var_expectation_model statement.");
auto var_model_name = it->second;
it = options_list.string_options.find("model_name");
if (it == options_list.string_options.end())
error("You must pass the model_name option to the var_expectation_model statement.");
auto model_name = it->second;
it = options_list.num_options.find("horizon");
if (it == options_list.num_options.end())
error("You must pass the horizon option to the var_expectation_model statement.");
auto horizon = it->second;
if (var_expectation_model_discount)
{
VariableNode *var;
if (!dynamic_cast<NumConstNode *>(var_expectation_model_discount)
&& !((var = dynamic_cast<VariableNode *>(var_expectation_model_discount))
&& var->get_type() == SymbolType::parameter))
error("The discount factor must be a constant expression or a parameter");
}
else
var_expectation_model_discount = data_tree->One;
mod_file->addStatement(make_unique<VarExpectationModelStatement>(model_name, var_expectation_model_expression,
var_model_name, horizon,
var_expectation_model_discount, mod_file->symbol_table));
options_list.clear();
var_expectation_model_discount = nullptr;
var_expectation_model_expression = nullptr;
}
void
ParsingDriver::begin_matched_moments()
{
set_current_data_tree(&mod_file->dynamic_model);
}
void
ParsingDriver::end_matched_moments(const vector<expr_t> &moments)
{
vector<tuple<vector<int>, vector<int>, vector<int>>> parsed_moments;
for (auto m : moments)
try
{
vector<int> symb_ids, lags, powers;
m->matchMatchedMoment(symb_ids, lags, powers);
parsed_moments.emplace_back(symb_ids, lags, powers);
}
catch (ExprNode::MatchFailureException &e)
{
error("Matched moment expression has incorrect format: " + e.message);
}
mod_file->addStatement(make_unique<MatchedMomentsStatement>(mod_file->symbol_table, parsed_moments));
reset_data_tree();
}
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