Preprocessor: various refactorings of block decomposition

Adapt bytecode MEX accordingly.
parent ac8bc512
Pipeline #3394 passed with stages
in 95 minutes and 58 seconds
/* /*
* Copyright © 2007-2017 Dynare Team * Copyright © 2007-2020 Dynare Team
* *
* This file is part of Dynare. * This file is part of Dynare.
* *
...@@ -87,9 +87,9 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -87,9 +87,9 @@ Interpreter::evaluate_a_block(bool initialization)
{ {
it_code_type begining; it_code_type begining;
switch (type) switch (static_cast<BlockSimulationType>(type))
{ {
case EVALUATE_FORWARD: case BlockSimulationType::evaluateForward:
if (steady_state) if (steady_state)
{ {
compute_block_time(0, true, /*block_num, size, steady_state, */ false); compute_block_time(0, true, /*block_num, size, steady_state, */ false);
...@@ -117,7 +117,7 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -117,7 +117,7 @@ Interpreter::evaluate_a_block(bool initialization)
} }
} }
break; break;
case SOLVE_FORWARD_SIMPLE: case BlockSimulationType::solveForwardSimple:
g1 = static_cast<double *>(mxMalloc(size*size*sizeof(double))); g1 = static_cast<double *>(mxMalloc(size*size*sizeof(double)));
test_mxMalloc(g1, __LINE__, __FILE__, __func__, size*size*sizeof(double)); test_mxMalloc(g1, __LINE__, __FILE__, __func__, size*size*sizeof(double));
r = static_cast<double *>(mxMalloc(size*sizeof(double))); r = static_cast<double *>(mxMalloc(size*sizeof(double)));
...@@ -151,14 +151,14 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -151,14 +151,14 @@ Interpreter::evaluate_a_block(bool initialization)
mxFree(g1); mxFree(g1);
mxFree(r); mxFree(r);
break; break;
case SOLVE_FORWARD_COMPLETE: case BlockSimulationType::solveForwardComplete:
if (initialization) if (initialization)
{ {
fixe_u(&u, u_count_int, u_count_int); fixe_u(&u, u_count_int, u_count_int);
Read_SparseMatrix(bin_base_name, size, 1, 0, 0, false, stack_solve_algo, solve_algo); Read_SparseMatrix(bin_base_name, size, 1, 0, 0, false, stack_solve_algo, solve_algo);
} }
#ifdef DEBUG #ifdef DEBUG
mexPrintf("in SOLVE_FORWARD_COMPLETE r = mxMalloc(%d*sizeof(double))\n", size); mexPrintf("in SOLVE FORWARD COMPLETE r = mxMalloc(%d*sizeof(double))\n", size);
#endif #endif
r = static_cast<double *>(mxMalloc(size*sizeof(double))); r = static_cast<double *>(mxMalloc(size*sizeof(double)));
test_mxMalloc(r, __LINE__, __FILE__, __func__, size*sizeof(double)); test_mxMalloc(r, __LINE__, __FILE__, __func__, size*sizeof(double));
...@@ -190,7 +190,7 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -190,7 +190,7 @@ Interpreter::evaluate_a_block(bool initialization)
} }
mxFree(r); mxFree(r);
break; break;
case EVALUATE_BACKWARD: case BlockSimulationType::evaluateBackward:
if (steady_state) if (steady_state)
{ {
compute_block_time(0, true, /*block_num, size, steady_state,*/ false); compute_block_time(0, true, /*block_num, size, steady_state,*/ false);
...@@ -218,7 +218,7 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -218,7 +218,7 @@ Interpreter::evaluate_a_block(bool initialization)
} }
} }
break; break;
case SOLVE_BACKWARD_SIMPLE: case BlockSimulationType::solveBackwardSimple:
g1 = static_cast<double *>(mxMalloc(size*size*sizeof(double))); g1 = static_cast<double *>(mxMalloc(size*size*sizeof(double)));
test_mxMalloc(g1, __LINE__, __FILE__, __func__, size*size*sizeof(double)); test_mxMalloc(g1, __LINE__, __FILE__, __func__, size*size*sizeof(double));
r = static_cast<double *>(mxMalloc(size*sizeof(double))); r = static_cast<double *>(mxMalloc(size*sizeof(double)));
...@@ -252,7 +252,7 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -252,7 +252,7 @@ Interpreter::evaluate_a_block(bool initialization)
mxFree(g1); mxFree(g1);
mxFree(r); mxFree(r);
break; break;
case SOLVE_BACKWARD_COMPLETE: case BlockSimulationType::solveBackwardComplete:
if (initialization) if (initialization)
{ {
fixe_u(&u, u_count_int, u_count_int); fixe_u(&u, u_count_int, u_count_int);
...@@ -288,8 +288,8 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -288,8 +288,8 @@ Interpreter::evaluate_a_block(bool initialization)
} }
mxFree(r); mxFree(r);
break; break;
case SOLVE_TWO_BOUNDARIES_SIMPLE: case BlockSimulationType::solveTwoBoundariesSimple:
case SOLVE_TWO_BOUNDARIES_COMPLETE: case BlockSimulationType::solveTwoBoundariesComplete:
if (initialization) if (initialization)
{ {
fixe_u(&u, u_count_int, u_count_int); fixe_u(&u, u_count_int, u_count_int);
...@@ -314,6 +314,8 @@ Interpreter::evaluate_a_block(bool initialization) ...@@ -314,6 +314,8 @@ Interpreter::evaluate_a_block(bool initialization)
} }
mxFree(r); mxFree(r);
break; break;
case BlockSimulationType::unknown:
throw FatalExceptionHandling("UNKNOWN block simulation type: impossible case");
} }
} }
...@@ -329,39 +331,39 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c ...@@ -329,39 +331,39 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c
mexPrintf("simulate_a_block type = %d, periods=%d, y_kmin=%d, y_kmax=%d\n", type, periods, y_kmin, y_kmax); mexPrintf("simulate_a_block type = %d, periods=%d, y_kmin=%d, y_kmax=%d\n", type, periods, y_kmin, y_kmax);
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
switch (type) switch (static_cast<BlockSimulationType>(type))
{ {
case EVALUATE_FORWARD: case BlockSimulationType::evaluateForward:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("EVALUATE_FORWARD\n"); mexPrintf("EVALUATE FORWARD\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
evaluate_over_periods(true); evaluate_over_periods(true);
break; break;
case EVALUATE_BACKWARD: case BlockSimulationType::evaluateBackward:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("EVALUATE_BACKWARD\n"); mexPrintf("EVALUATE BACKWARD\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
evaluate_over_periods(false); evaluate_over_periods(false);
break; break;
case SOLVE_FORWARD_SIMPLE: case BlockSimulationType::solveForwardSimple:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("SOLVE_FORWARD_SIMPLE size=%d\n", size); mexPrintf("SOLVE FORWARD SIMPLE size=%d\n", size);
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
solve_simple_over_periods(true); solve_simple_over_periods(true);
break; break;
case SOLVE_BACKWARD_SIMPLE: case BlockSimulationType::solveBackwardSimple:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("SOLVE_BACKWARD_SIMPLE\n"); mexPrintf("SOLVE BACKWARD SIMPLE\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
solve_simple_over_periods(false); solve_simple_over_periods(false);
break; break;
case SOLVE_FORWARD_COMPLETE: case BlockSimulationType::solveForwardComplete:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("SOLVE_FORWARD_COMPLETE\n"); mexPrintf("SOLVE FORWARD COMPLETE\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
if (vector_table_conditional_local.size()) if (vector_table_conditional_local.size())
...@@ -386,9 +388,9 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c ...@@ -386,9 +388,9 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c
memset(direction, 0, size_of_direction); memset(direction, 0, size_of_direction);
End_Solver(); End_Solver();
break; break;
case SOLVE_BACKWARD_COMPLETE: case BlockSimulationType::solveBackwardComplete:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("SOLVE_BACKWARD_COMPLETE\n"); mexPrintf("SOLVE BACKWARD COMPLETE\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
if (vector_table_conditional_local.size()) if (vector_table_conditional_local.size())
...@@ -413,15 +415,15 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c ...@@ -413,15 +415,15 @@ Interpreter::simulate_a_block(vector_table_conditional_local_type vector_table_c
mxFree(u); mxFree(u);
End_Solver(); End_Solver();
break; break;
case SOLVE_TWO_BOUNDARIES_SIMPLE: case BlockSimulationType::solveTwoBoundariesSimple:
case SOLVE_TWO_BOUNDARIES_COMPLETE: case BlockSimulationType::solveTwoBoundariesComplete:
#ifdef DEBUG #ifdef DEBUG
mexPrintf("SOLVE_TWO_BOUNDARIES\n"); mexPrintf("SOLVE TWO BOUNDARIES\n");
mexEvalString("drawnow;"); mexEvalString("drawnow;");
#endif #endif
if (steady_state) if (steady_state)
{ {
mexPrintf("SOLVE_TWO_BOUNDARIES in a steady state model: impossible case\n"); mexPrintf("SOLVE TWO BOUNDARIES in a steady state model: impossible case\n");
return ERROR_ON_EXIT; return ERROR_ON_EXIT;
} }
if (vector_table_conditional_local.size()) if (vector_table_conditional_local.size())
...@@ -612,7 +614,7 @@ Interpreter::check_for_controlled_exo_validity(FBEGINBLOCK_ *fb, vector<s_plan> ...@@ -612,7 +614,7 @@ Interpreter::check_for_controlled_exo_validity(FBEGINBLOCK_ *fb, vector<s_plan>
tmp << "\n the conditional forecast involving as constrained variable " << get_variable(SymbolType::endogenous, it->exo_num) << " and as endogenized exogenous " << get_variable(SymbolType::exogenous, it->var_num) << " that do not appear in block=" << Block_Count+1 << ")\n You should not use block in model options\n"; tmp << "\n the conditional forecast involving as constrained variable " << get_variable(SymbolType::endogenous, it->exo_num) << " and as endogenized exogenous " << get_variable(SymbolType::exogenous, it->var_num) << " that do not appear in block=" << Block_Count+1 << ")\n You should not use block in model options\n";
throw FatalExceptionHandling(tmp.str()); throw FatalExceptionHandling(tmp.str());
} }
else if ((find(endogenous.begin(), endogenous.end(), it->exo_num) != endogenous.end()) && (find(exogenous.begin(), exogenous.end(), it->var_num) != exogenous.end()) && ((fb->get_type() == EVALUATE_FORWARD) || (fb->get_type() != EVALUATE_BACKWARD))) else if ((find(endogenous.begin(), endogenous.end(), it->exo_num) != endogenous.end()) && (find(exogenous.begin(), exogenous.end(), it->var_num) != exogenous.end()) && ((fb->get_type() == static_cast<uint8_t>(BlockSimulationType::evaluateForward)) || (fb->get_type() != static_cast<uint8_t>(BlockSimulationType::evaluateBackward))))
{ {
ostringstream tmp; ostringstream tmp;
tmp << "\n the conditional forecast cannot be implemented for the block=" << Block_Count+1 << ") that has to be evaluated instead to be solved\n You should not use block in model options\n"; tmp << "\n the conditional forecast cannot be implemented for the block=" << Block_Count+1 << ") that has to be evaluated instead to be solved\n You should not use block in model options\n";
......
Subproject commit bd6eee93dfa3f07d9c0ebca7f7aa21dfbad111f7 Subproject commit 5d6e6338f43ffb563c28af490e2544dbfbe7626b
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