static void print_graphs(MSTicker *s, MSList *execution_list, bool_t force_schedule){
MSList *it;
MSList *unschedulable=NULL;
for(it=execution_list;it!=NULL;it=it->next){
print_graph((MSFilter*)it->data,s,&unschedulable,force_schedule);
}
/* filters that are part of a loop haven't been called in process() because one of their input refers to a filter that could not be scheduled (because they could not be scheduled themselves)... Do you understand ?*/
/* we resolve this by simply assuming that they must be called anyway
for the loop to run correctly*/
/* we just recall run_graphs on them, as if they were source filters */
if (unschedulable!=NULL) {
print_graphs(s,unschedulable,TRUE);
ms_list_free(unschedulable);
}
}
void ms_ticker_print_graphs(MSTicker *ticker){
print_graphs(ticker,ticker->execution_list,FALSE);
}
static int compile(struct OPTIONS *options)
{
MODULE *module;
PARSER parser;
char buffer[MAX_LINE] = "";
if (options->filename)
{
parser.filename = options->filename;
parser.file = fopen(options->filename, "rt");
}
else
{
parser.filename = "<stdin>";
parser.file = stdin;
}
/*
* 1. Read and parse source code from standard input.
*/
module = CAST_TO_MODULE(tree_create_node(DEF_MODULE));
module->filename = parser.filename;
module->table = create_hash(10, key_type_copyable);
module->strings = create_hash(10, key_type_copyable);
module->max_registers = 6;
parser.buffer = parser.p = buffer;
parser.input = get_line;
parser.module = module;
parser.scope = module->table;
parser.args = NULL;
if (yyparse(&parser) == 1)
return 0;
/*
* 2. Optimise!
*/
//TODO: Think of some possible optimisations!
// - Constant folding.
// - Common subexpression elimination.
// - Dead code removal.
// - Function inlining.
process_functions(module, analyse_tail_recursion);
process_functions(module, analyse_symbols);
process_functions(module, process_closures);
process_functions(module, flatten);
process_functions(module, optimise_constant_folding);
process_functions(module, reduce);
process_functions(module, definite_assignment_analysis);
process_functions(module, analyse_inlining);
process_functions(module, optimise_constant_tests);
process_functions(module, remove_dead_code);
/*
* 3. Output assembly code.
*/
process_functions(module, i386ify);
process_functions(module, register_allocation);
process_functions(module, analyse_function_size);
if (options->graphs)
print_graphs(module);
else
generate_as(module);
/*
* 4. Clean up.
*/
//TODO: May not be necessary as things are generally freed on termination.
tree_destroy_node(CAST_TO_NODE(module));
if (parser.file != stdin)
fclose(parser.file);
return 1;
}
