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DataTree.cc
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Sébastien Villemot authoredSébastien Villemot authored
DataTree.cc 15.71 KiB
/*
* Copyright (C) 2003-2014 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 <http://www.gnu.org/licenses/>.
*/
#include <cstdlib>
#include <cassert>
#include <iostream>
#include "DataTree.hh"
DataTree::DataTree(SymbolTable &symbol_table_arg,
NumericalConstants &num_constants_arg,
ExternalFunctionsTable &external_functions_table_arg) :
symbol_table(symbol_table_arg),
num_constants(num_constants_arg),
external_functions_table(external_functions_table_arg),
node_counter(0)
{
Zero = AddNonNegativeConstant("0");
One = AddNonNegativeConstant("1");
Two = AddNonNegativeConstant("2");
MinusOne = AddUMinus(One);
NaN = AddNonNegativeConstant("NaN");
Infinity = AddNonNegativeConstant("Inf");
MinusInfinity = AddUMinus(Infinity);
Pi = AddNonNegativeConstant("3.141592653589793");
}
DataTree::~DataTree()
{
for (node_list_t::iterator it = node_list.begin(); it != node_list.end(); it++)
delete *it;
}
expr_t
DataTree::AddNonNegativeConstant(const string &value)
{
int id = num_constants.AddNonNegativeConstant(value);
num_const_node_map_t::iterator it = num_const_node_map.find(id);
if (it != num_const_node_map.end())
return it->second;
else
return new NumConstNode(*this, id);
}
VariableNode *
DataTree::AddVariableInternal(int symb_id, int lag)
{
variable_node_map_t::iterator it = variable_node_map.find(make_pair(symb_id, lag));
if (it != variable_node_map.end())
return it->second; else
return new VariableNode(*this, symb_id, lag);
}
VariableNode *
DataTree::AddVariable(int symb_id, int lag)
{
assert(lag == 0);
return AddVariableInternal(symb_id, lag);
}
expr_t
DataTree::AddPlus(expr_t iArg1, expr_t iArg2)
{
if (iArg1 != Zero && iArg2 != Zero)
{
// Simplify x+(-y) in x-y
UnaryOpNode *uarg2 = dynamic_cast<UnaryOpNode *>(iArg2);
if (uarg2 != NULL && uarg2->get_op_code() == oUminus)
return AddMinus(iArg1, uarg2->get_arg());
// To treat commutativity of "+"
// Nodes iArg1 and iArg2 are sorted by index
if (iArg1->idx > iArg2->idx)
{
expr_t tmp = iArg1;
iArg1 = iArg2;
iArg2 = tmp;
}
return AddBinaryOp(iArg1, oPlus, iArg2);
}
else if (iArg1 != Zero)
return iArg1;
else if (iArg2 != Zero)
return iArg2;
else
return Zero;
}
expr_t
DataTree::AddMinus(expr_t iArg1, expr_t iArg2)
{
if (iArg2 == Zero)
return iArg1;
if (iArg1 == Zero)
return AddUMinus(iArg2);
if (iArg1 == iArg2)
return Zero;
return AddBinaryOp(iArg1, oMinus, iArg2);
}
expr_t
DataTree::AddUMinus(expr_t iArg1)
{
if (iArg1 != Zero)
{
// Simplify -(-x) in x
UnaryOpNode *uarg = dynamic_cast<UnaryOpNode *>(iArg1);
if (uarg != NULL && uarg->get_op_code() == oUminus)
return uarg->get_arg();
return AddUnaryOp(oUminus, iArg1);
}
else
return Zero;
}
expr_t
DataTree::AddTimes(expr_t iArg1, expr_t iArg2)
{
if (iArg1 == MinusOne)
return AddUMinus(iArg2);
else if (iArg2 == MinusOne)
return AddUMinus(iArg1);
else if (iArg1 != Zero && iArg1 != One && iArg2 != Zero && iArg2 != One)
{
// To treat commutativity of "*"
// Nodes iArg1 and iArg2 are sorted by index
if (iArg1->idx > iArg2->idx)
{
expr_t tmp = iArg1;
iArg1 = iArg2;
iArg2 = tmp;
}
return AddBinaryOp(iArg1, oTimes, iArg2);
}
else if (iArg1 != Zero && iArg1 != One && iArg2 == One)
return iArg1;
else if (iArg2 != Zero && iArg2 != One && iArg1 == One)
return iArg2;
else if (iArg2 == One && iArg1 == One)
return One;
else
return Zero;
}
expr_t
DataTree::AddDivide(expr_t iArg1, expr_t iArg2)
{
if (iArg2 == One)
return iArg1;
// This test should be before the next two, otherwise 0/0 won't be rejected
if (iArg2 == Zero)
{
cerr << "ERROR: Division by zero!" << endl;
exit(EXIT_FAILURE);
}
if (iArg1 == Zero)
return Zero;
if (iArg1 == iArg2)
return One;
return AddBinaryOp(iArg1, oDivide, iArg2);
}
expr_t
DataTree::AddLess(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oLess, iArg2);
}
expr_t
DataTree::AddGreater(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oGreater, iArg2);
}
expr_t
DataTree::AddLessEqual(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oLessEqual, iArg2);
}
expr_tDataTree::AddGreaterEqual(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oGreaterEqual, iArg2);
}
expr_t
DataTree::AddEqualEqual(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oEqualEqual, iArg2);
}
expr_t
DataTree::AddDifferent(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oDifferent, iArg2);
}
expr_t
DataTree::AddPower(expr_t iArg1, expr_t iArg2)
{
if (iArg1 != Zero && iArg2 != Zero && iArg1 != One && iArg2 != One)
return AddBinaryOp(iArg1, oPower, iArg2);
else if (iArg1 == One)
return One;
else if (iArg2 == One)
return iArg1;
else if (iArg2 == Zero)
return One;
else
return Zero;
}
expr_t
DataTree::AddPowerDeriv(expr_t iArg1, expr_t iArg2, int powerDerivOrder)
{
assert(powerDerivOrder > 0);
return AddBinaryOp(iArg1, oPowerDeriv, iArg2, powerDerivOrder);
}
expr_t
DataTree::AddExp(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oExp, iArg1);
else
return One;
}
expr_t
DataTree::AddLog(expr_t iArg1)
{
if (iArg1 != Zero && iArg1 != One)
return AddUnaryOp(oLog, iArg1);
else if (iArg1 == One)
return Zero;
else
{
cerr << "ERROR: log(0) not defined!" << endl;
exit(EXIT_FAILURE);
}
}
expr_t
DataTree::AddLog10(expr_t iArg1)
{
if (iArg1 != Zero && iArg1 != One)
return AddUnaryOp(oLog10, iArg1);
else if (iArg1 == One)
return Zero;
else {
cerr << "ERROR: log10(0) not defined!" << endl;
exit(EXIT_FAILURE);
}
}
expr_t
DataTree::AddCos(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oCos, iArg1);
else
return One;
}
expr_t
DataTree::AddSin(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oSin, iArg1);
else
return Zero;
}
expr_t
DataTree::AddTan(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oTan, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAcos(expr_t iArg1)
{
if (iArg1 != One)
return AddUnaryOp(oAcos, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAsin(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oAsin, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAtan(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oAtan, iArg1);
else
return Zero;
}
expr_t
DataTree::AddCosh(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oCosh, iArg1);
else
return One;
}
expr_tDataTree::AddSinh(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oSinh, iArg1);
else
return Zero;
}
expr_t
DataTree::AddTanh(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oTanh, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAcosh(expr_t iArg1)
{
if (iArg1 != One)
return AddUnaryOp(oAcosh, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAsinh(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oAsinh, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAtanh(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oAtanh, iArg1);
else
return Zero;
}
expr_t
DataTree::AddSqrt(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oSqrt, iArg1);
else
return Zero;
}
expr_t
DataTree::AddAbs(expr_t iArg1)
{
if (iArg1 == Zero)
return Zero;
if (iArg1 == One)
return One;
else
return AddUnaryOp(oAbs, iArg1);
}
expr_t
DataTree::AddSign(expr_t iArg1)
{
if (iArg1 == Zero)
return Zero;
if (iArg1 == One) return One;
else
return AddUnaryOp(oSign, iArg1);
}
expr_t
DataTree::AddErf(expr_t iArg1)
{
if (iArg1 != Zero)
return AddUnaryOp(oErf, iArg1);
else
return Zero;
}
expr_t
DataTree::AddMax(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oMax, iArg2);
}
expr_t
DataTree::AddMin(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oMin, iArg2);
}
expr_t
DataTree::AddNormcdf(expr_t iArg1, expr_t iArg2, expr_t iArg3)
{
return AddTrinaryOp(iArg1, oNormcdf, iArg2, iArg3);
}
expr_t
DataTree::AddNormpdf(expr_t iArg1, expr_t iArg2, expr_t iArg3)
{
return AddTrinaryOp(iArg1, oNormpdf, iArg2, iArg3);
}
expr_t
DataTree::AddSteadyState(expr_t iArg1)
{
return AddUnaryOp(oSteadyState, iArg1);
}
expr_t
DataTree::AddSteadyStateParamDeriv(expr_t iArg1, int param_symb_id)
{
return AddUnaryOp(oSteadyStateParamDeriv, iArg1, 0, param_symb_id);
}
expr_t
DataTree::AddSteadyStateParam2ndDeriv(expr_t iArg1, int param1_symb_id, int param2_symb_id)
{
return AddUnaryOp(oSteadyStateParam2ndDeriv, iArg1, 0, param1_symb_id, param2_symb_id);
}
expr_t
DataTree::AddExpectation(int iArg1, expr_t iArg2)
{
return AddUnaryOp(oExpectation, iArg2, iArg1);
}
expr_t
DataTree::AddEqual(expr_t iArg1, expr_t iArg2)
{
return AddBinaryOp(iArg1, oEqual, iArg2);
}
void
DataTree::AddLocalVariable(int symb_id, expr_t value) throw (LocalVariableException){
assert(symbol_table.getType(symb_id) == eModelLocalVariable);
// Throw an exception if symbol already declared
map<int, expr_t>::iterator it = local_variables_table.find(symb_id);
if (it != local_variables_table.end())
throw LocalVariableException(symbol_table.getName(symb_id));
local_variables_table[symb_id] = value;
}
expr_t
DataTree::AddExternalFunction(int symb_id, const vector<expr_t> &arguments)
{
assert(symbol_table.getType(symb_id) == eExternalFunction);
external_function_node_map_t::iterator it = external_function_node_map.find(make_pair(arguments, symb_id));
if (it != external_function_node_map.end())
return it->second;
return new ExternalFunctionNode(*this, symb_id, arguments);
}
expr_t
DataTree::AddFirstDerivExternalFunction(int top_level_symb_id, const vector<expr_t> &arguments, int input_index)
{
assert(symbol_table.getType(top_level_symb_id) == eExternalFunction);
first_deriv_external_function_node_map_t::iterator it
= first_deriv_external_function_node_map.find(make_pair(make_pair(arguments, input_index),
top_level_symb_id));
if (it != first_deriv_external_function_node_map.end())
return it->second;
return new FirstDerivExternalFunctionNode(*this, top_level_symb_id, arguments, input_index);
}
expr_t
DataTree::AddSecondDerivExternalFunction(int top_level_symb_id, const vector<expr_t> &arguments, int input_index1, int input_index2)
{
assert(symbol_table.getType(top_level_symb_id) == eExternalFunction);
second_deriv_external_function_node_map_t::iterator it
= second_deriv_external_function_node_map.find(make_pair(make_pair(arguments,
make_pair(input_index1, input_index2)),
top_level_symb_id));
if (it != second_deriv_external_function_node_map.end())
return it->second;
return new SecondDerivExternalFunctionNode(*this, top_level_symb_id, arguments, input_index1, input_index2);
}
bool
DataTree::isSymbolUsed(int symb_id) const
{
for (variable_node_map_t::const_iterator it = variable_node_map.begin();
it != variable_node_map.end(); it++)
if (it->first.first == symb_id)
return true;
if (local_variables_table.find(symb_id) != local_variables_table.end())
return true;
return false;
}
int
DataTree::getDerivID(int symb_id, int lag) const throw (UnknownDerivIDException)
{
throw UnknownDerivIDException();}
SymbolType
DataTree::getTypeByDerivID(int deriv_id) const throw (UnknownDerivIDException)
{
throw UnknownDerivIDException();
}
int
DataTree::getLagByDerivID(int deriv_id) const throw (UnknownDerivIDException)
{
throw UnknownDerivIDException();
}
int
DataTree::getSymbIDByDerivID(int deriv_id) const throw (UnknownDerivIDException)
{
throw UnknownDerivIDException();
}
void
DataTree::addAllParamDerivId(set<int> &deriv_id_set)
{
}
int
DataTree::getDynJacobianCol(int deriv_id) const throw (UnknownDerivIDException)
{
throw UnknownDerivIDException();
}
bool
DataTree::isUnaryOpUsed(UnaryOpcode opcode) const
{
for (unary_op_node_map_t::const_iterator it = unary_op_node_map.begin();
it != unary_op_node_map.end(); it++)
if (it->first.first.second == opcode)
return true;
return false;
}
bool
DataTree::isBinaryOpUsed(BinaryOpcode opcode) const
{
for (binary_op_node_map_t::const_iterator it = binary_op_node_map.begin();
it != binary_op_node_map.end(); it++)
if (it->first.second == opcode)
return true;
return false;
}
bool
DataTree::isTrinaryOpUsed(TrinaryOpcode opcode) const
{
for (trinary_op_node_map_t::const_iterator it = trinary_op_node_map.begin();
it != trinary_op_node_map.end(); it++)
if (it->first.second == opcode)
return true;
return false;
}
bool
DataTree::isExternalFunctionUsed(int symb_id) const
{
for (external_function_node_map_t::const_iterator it = external_function_node_map.begin();
it != external_function_node_map.end(); it++)
if (it->first.second == symb_id) return true;
return false;
}
bool
DataTree::isFirstDerivExternalFunctionUsed(int symb_id) const
{
for (first_deriv_external_function_node_map_t::const_iterator it = first_deriv_external_function_node_map.begin();
it != first_deriv_external_function_node_map.end(); it++)
if (it->first.second == symb_id)
return true;
return false;
}
bool
DataTree::isSecondDerivExternalFunctionUsed(int symb_id) const
{
for (second_deriv_external_function_node_map_t::const_iterator it = second_deriv_external_function_node_map.begin();
it != second_deriv_external_function_node_map.end(); it++)
if (it->first.second == symb_id)
return true;
return false;
}
int
DataTree::minLagForSymbol(int symb_id) const
{
int r = 0;
for (variable_node_map_t::const_iterator it = variable_node_map.begin();
it != variable_node_map.end(); ++it)
if (it->first.first == symb_id && it->first.second < r)
r = it->first.second;
return r;
}
void
DataTree::writePowerDerivCHeader(ostream &output) const
{
if (isBinaryOpUsed(oPowerDeriv))
output << "double getPowerDeriv(double, double, int);" << endl;
}
void
DataTree::writePowerDeriv(ostream &output, bool use_dll) const
{
if (use_dll && isBinaryOpUsed(oPowerDeriv))
output << "/*" << endl
<< " * The k-th derivative of x^p" << endl
<< " */" << endl
<< "double getPowerDeriv(double x, double p, int k)" << endl
<< "{" << endl
<< "#ifdef _MSC_VER" << endl
<< "# define nearbyint(x) (fabs((x)-floor(x)) < fabs((x)-ceil(x)) ? floor(x) : ceil(x))" << endl
<< "#endif" << endl
<< " if ( fabs(x) < " << NEAR_ZERO << " && p > 0 && k > p && fabs(p-nearbyint(p)) < " << NEAR_ZERO << " )" << endl
<< " return 0.0;" << endl
<< " else" << endl
<< " {" << endl
<< " int i = 0;" << endl
<< " double dxp = pow(x, p-k);" << endl
<< " for (; i<k; i++)" << endl
<< " dxp *= p--;" << endl
<< " return dxp;" << endl
<< " }" << endl
<< "}" << endl;
}