/*
* Copyright (C) 2003-2017 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 .
*/
#ifndef _STATIC_MODEL_HH
#define _STATIC_MODEL_HH
using namespace std;
#include
#include "ModelTree.hh"
//! Stores a static model, as derived from the "model" block when leads and lags have been removed
class StaticModel : public ModelTree
{
private:
//! global temporary terms for block decomposed models
vector > v_temporary_terms;
//! local temporary terms for block decomposed models
vector > v_temporary_terms_local;
vector v_temporary_terms_inuse;
typedef map< pair< int, pair< int, int> >, expr_t> first_chain_rule_derivatives_t;
first_chain_rule_derivatives_t first_chain_rule_derivatives;
//! Writes static model file (standard Matlab version)
void writeStaticMFile(const string &static_basename) const;
//! Writes static model file (C version)
void writeStaticCFile(const string &func_name) const;
//! Writes static model file (Julia version)
void writeStaticJuliaFile(const string &basename) const;
//! Writes the static model equations and its derivatives
void writeStaticModel(ostream &StaticOutput, bool use_dll, bool julia) const;
//! Writes the static function calling the block to solve (Matlab version)
void writeStaticBlockMFSFile(const string &basename) const;
//! Writes the Block reordred structure of the model in M output
void writeModelEquationsOrdered_M(const string &dynamic_basename) const;
//! Writes the code of the Block reordred structure of the model in virtual machine bytecode
void writeModelEquationsCode_Block(const string file_name, const string bin_basename, map_idx_t map_idx, vector map_idx2) const;
//! Writes the code of the model in virtual machine bytecode
void writeModelEquationsCode(const string file_name, const string bin_basename, map_idx_t map_idx) const;
//! Computes jacobian and prepares for equation normalization
/*! Using values from initval/endval blocks and parameter initializations:
- computes the jacobian for the model w.r. to contemporaneous variables
- removes edges of the incidence matrix when derivative w.r. to the corresponding variable is too close to zero (below the cutoff)
*/
void evaluateJacobian(const eval_context_t &eval_context, jacob_map_t *j_m, bool dynamic);
map_idx_t map_idx;
vector map_idx2;
//! sorts the temporary terms in the blocks order
void computeTemporaryTermsOrdered();
//! creates a mapping from the index of temporary terms to a natural index
void computeTemporaryTermsMapping(temporary_terms_t &temporary_terms, map_idx_t &map_idx);
//! Write derivative code of an equation w.r. to a variable
void compileDerivative(ofstream &code_file, unsigned int &instruction_number, int eq, int symb_id, map_idx_t &map_idx, temporary_terms_t temporary_terms) const;
//! Write chain rule derivative code of an equation w.r. to a variable
void compileChainRuleDerivative(ofstream &code_file, unsigned int &instruction_number, int eq, int var, int lag, map_idx_t &map_idx, temporary_terms_t temporary_terms) const;
//! Get the type corresponding to a derivation ID
virtual SymbolType getTypeByDerivID(int deriv_id) const throw (UnknownDerivIDException);
//! Get the lag corresponding to a derivation ID
virtual int getLagByDerivID(int deriv_id) const throw (UnknownDerivIDException);
//! Get the symbol ID corresponding to a derivation ID
virtual int getSymbIDByDerivID(int deriv_id) const throw (UnknownDerivIDException);
//! Compute the column indices of the static Jacobian
void computeStatJacobianCols();
//! return a map on the block jacobian
map >, pair >, int> get_Derivatives(int block);
//! Computes chain rule derivatives of the Jacobian w.r. to endogenous variables
void computeChainRuleJacobian(blocks_derivatives_t &blocks_derivatives);
//! Collect only the first derivatives
map >, expr_t> collect_first_order_derivatives_endogenous();
//! Write chain rule derivative of a recursive equation w.r. to a variable
void writeChainRuleDerivative(ostream &output, int eq, int var, int lag, ExprNodeOutputType output_type, const temporary_terms_t &temporary_terms) const;
//! Collecte the derivatives w.r. to endogenous of the block, to endogenous of previouys blocks and to exogenous
void collect_block_first_order_derivatives();
protected:
//! Indicate if the temporary terms are computed for the overall model (true) or not (false). Default value true
bool global_temporary_terms;
//! Vector describing equations: BlockSimulationType, if BlockSimulationType == EVALUATE_s then a expr_t on the new normalized equation
equation_type_and_normalized_equation_t equation_type_and_normalized_equation;
//! for each block contains pair< Simulation_Type, pair < Block_Size, Recursive_part_Size > >
block_type_firstequation_size_mfs_t block_type_firstequation_size_mfs;
//! for all blocks derivatives description
blocks_derivatives_t blocks_derivatives;
//! The jacobian without the elements below the cutoff
dynamic_jacob_map_t dynamic_jacobian;
//! Vector indicating if the block is linear in endogenous variable (true) or not (false)
vector blocks_linear;
//! Map the derivatives for a block pair
typedef map >, expr_t> derivative_t;
//! Vector of derivative for each blocks
vector derivative_endo, derivative_other_endo, derivative_exo, derivative_exo_det;
//!List for each block and for each lag-leag all the other endogenous variables and exogenous variables
typedef set var_t;
typedef map lag_var_t;
vector other_endo_block, exo_block, exo_det_block;
//! for each block described the number of static, forward, backward and mixed variables in the block
/*! pair< pair, pair > */
vector, pair > > block_col_type;
//! List for each variable its block number and its maximum lag and lead inside the block
vector > > variable_block_lead_lag;
//! List for each equation its block number
vector equation_block;
//!Maximum lead and lag for each block on endogenous of the block, endogenous of the previous blocks, exogenous and deterministic exogenous
vector > endo_max_leadlag_block, other_endo_max_leadlag_block, exo_max_leadlag_block, exo_det_max_leadlag_block, max_leadlag_block;
public:
StaticModel(SymbolTable &symbol_table_arg, NumericalConstants &num_constants, ExternalFunctionsTable &external_functions_table_arg);
//! Writes information on block decomposition when relevant
void writeOutput(ostream &output, bool block) const;
//! Execute computations (variable sorting + derivation)
/*!
\param eval_context evaluation context for normalization
\param no_tmp_terms if true, no temporary terms will be computed in the static files
\param hessian whether 2nd derivatives w.r. to exo, exo_det and endo should be computed
\param paramsDerivsOrder order of derivatives w.r. to a pair (endo/exo/exo_det, parameter) to be computed
*/
void computingPass(const eval_context_t &eval_context, bool no_tmp_terms, bool hessian, bool thirdDerivatices, int paramsDerivsOrder, bool block, bool bytecode);
//! Adds informations for simulation in a binary file for a block decomposed model
void Write_Inf_To_Bin_File_Block(const string &static_basename, const string &bin_basename, const int &num,
int &u_count_int, bool &file_open) const;
//! Writes static model file
void writeStaticFile(const string &basename, bool block, bool bytecode, bool use_dll, bool julia) const;
//! Write JSON Output (used by PlannerObjectiveStatement)
void writeJsonOutput(ostream &output) const;
//! Write JSON representation of static model
void writeJsonComputingPassOutput(ostream &output, bool writeDetails) const;
//! Writes file containing static parameters derivatives
void writeJsonParamsDerivativesFile(ostream &output, bool writeDetails) const;
//! Writes file containing static parameters derivatives
void writeParamsDerivativesFile(const string &basename, bool julia) const;
//! Writes LaTeX file with the equations of the static model
void writeLatexFile(const string &basename) const;
//! Writes initializations in oo_.steady_state or steady state file for the auxiliary variables
void writeAuxVarInitval(ostream &output, ExprNodeOutputType output_type) const;
//! Writes definition of the auxiliary variables in a .m or .jl file
void writeSetAuxiliaryVariables(const string &basename, const bool julia) const;
void writeAuxVarRecursiveDefinitions(ostream &output, ExprNodeOutputType output_type) const;
//! To ensure that no exogenous is present in the planner objective
//! See #1264
bool exoPresentInEqs() const;
virtual int getDerivID(int symb_id, int lag) const throw (UnknownDerivIDException);
virtual void addAllParamDerivId(set &deriv_id_set);
//! Return the number of blocks
virtual unsigned int
getNbBlocks() const
{
return (block_type_firstequation_size_mfs.size());
};
//! Determine the simulation type of each block
virtual BlockSimulationType
getBlockSimulationType(int block_number) const
{
return (block_type_firstequation_size_mfs[block_number].first.first);
};
//! Return the first equation number of a block
virtual unsigned int
getBlockFirstEquation(int block_number) const
{
return (block_type_firstequation_size_mfs[block_number].first.second);
};
//! Return the size of the block block_number
virtual unsigned int
getBlockSize(int block_number) const
{
return (block_type_firstequation_size_mfs[block_number].second.first);
};
//! Return the number of exogenous variable in the block block_number
virtual unsigned int
getBlockExoSize(int block_number) const
{
return 0;
};
//! Return the number of colums in the jacobian matrix for exogenous variable in the block block_number
virtual unsigned int
getBlockExoColSize(int block_number) const
{
return 0;
}
//! Return the number of feedback variable of the block block_number
virtual unsigned int
getBlockMfs(int block_number) const
{
return (block_type_firstequation_size_mfs[block_number].second.second);
};
//! Return the maximum lag in a block
virtual unsigned int
getBlockMaxLag(int block_number) const
{
return (block_lag_lead[block_number].first);
};
//! Return the maximum lead in a block
virtual unsigned int
getBlockMaxLead(int block_number) const
{
return (block_lag_lead[block_number].second);
};
//! Return the type of equation (equation_number) belonging to the block block_number
virtual EquationType
getBlockEquationType(int block_number, int equation_number) const
{
return (equation_type_and_normalized_equation[equation_reordered[block_type_firstequation_size_mfs[block_number].first.second+equation_number]].first);
};
//! Return true if the equation has been normalized
virtual bool
isBlockEquationRenormalized(int block_number, int equation_number) const
{
return (equation_type_and_normalized_equation[equation_reordered[block_type_firstequation_size_mfs[block_number].first.second+equation_number]].first == E_EVALUATE_S);
};
//! Return the expr_t of the equation equation_number belonging to the block block_number
virtual expr_t
getBlockEquationExpr(int block_number, int equation_number) const
{
return (equations[equation_reordered[block_type_firstequation_size_mfs[block_number].first.second+equation_number]]);
};
//! Return the expr_t of the renormalized equation equation_number belonging to the block block_number
virtual expr_t
getBlockEquationRenormalizedExpr(int block_number, int equation_number) const
{
return (equation_type_and_normalized_equation[equation_reordered[block_type_firstequation_size_mfs[block_number].first.second+equation_number]].second);
};
//! Return the original number of equation equation_number belonging to the block block_number
virtual int
getBlockEquationID(int block_number, int equation_number) const
{
return (equation_reordered[block_type_firstequation_size_mfs[block_number].first.second+equation_number]);
};
//! Return the original number of variable variable_number belonging to the block block_number
virtual int
getBlockVariableID(int block_number, int variable_number) const
{
return (variable_reordered[block_type_firstequation_size_mfs[block_number].first.second+variable_number]);
};
//! Return the original number of the exogenous variable varexo_number belonging to the block block_number
virtual int
getBlockVariableExoID(int block_number, int variable_number) const
{
return 0;
};
//! Return the position of equation_number in the block number belonging to the block block_number
virtual int
getBlockInitialEquationID(int block_number, int equation_number) const
{
return ((int) inv_equation_reordered[equation_number] - (int) block_type_firstequation_size_mfs[block_number].first.second);
};
//! Return the position of variable_number in the block number belonging to the block block_number
virtual int
getBlockInitialVariableID(int block_number, int variable_number) const
{
return ((int) inv_variable_reordered[variable_number] - (int) block_type_firstequation_size_mfs[block_number].first.second);
};
//! Return the position of variable_number in the block number belonging to the block block_number
virtual int
getBlockInitialExogenousID(int block_number, int variable_number) const
{
return -1;
};
//! Return the position of the deterministic exogenous variable_number in the block number belonging to the block block_number
virtual int
getBlockInitialDetExogenousID(int block_number, int variable_number) const
{
return -1;
};
//! Return the position of the other endogenous variable_number in the block number belonging to the block block_number
virtual int
getBlockInitialOtherEndogenousID(int block_number, int variable_number) const
{
return -1;
};
};
#endif