/* * Copyright (c) 2001-2025 Stephen Williams (steve@icarus.com) * * This source code is free software; you can redistribute it * and/or modify it in source code form under the terms of the GNU * General Public License as published by the Free Software * Foundation; either version 2 of the License, or (at your option) * any later version. * * This program 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 this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ # include "compile.h" # include "vpi_priv.h" # include "symbols.h" # include "statistics.h" # include "config.h" #ifdef CHECK_WITH_VALGRIND # include "vvp_cleanup.h" #endif # include # include # include # include # include "ivl_alloc.h" using namespace std; static vector vpip_root_table; static vpiHandle make_subset_iterator_(int type_code, vector&table); vpiHandle vpip_make_root_iterator(int type_code) { return make_subset_iterator_(type_code, vpip_root_table); } void vpip_make_root_iterator(__vpiHandle**&table, unsigned&ntable) { table = &vpip_root_table[0]; ntable = vpip_root_table.size(); } #ifdef CHECK_WITH_VALGRIND void port_delete(__vpiHandle*handle); void port_bit_delete(__vpiHandle*handle); /* Class definitions need to be cleaned up at the end. */ static class_type **class_list = 0; static unsigned class_list_count = 0; static void delete_sub_scopes(__vpiScope *scope) { for (unsigned idx = 0; idx < scope->intern.size(); idx += 1) { vpiHandle item = (scope->intern)[idx]; __vpiScope*lscope = static_cast<__vpiScope*>(item); switch(item->get_type_code()) { case vpiFunction: case vpiTask: contexts_delete(lscope); // fallthrough case vpiModule: case vpiGenScope: case vpiNamedBegin: case vpiNamedFork: case vpiClassTypespec: delete_sub_scopes(lscope); vthreads_delete(lscope); delete item; break; case vpiMemory: case vpiNetArray: memory_delete(item); break; case vpiModPath: /* The destination ModPath is cleaned up later. */ delete item; break; case vpiInterModPath: delete item; break; case vpiNamedEvent: named_event_delete(item); break; case vpiNet: case vpiReg: case vpiIntegerVar: case vpiLongIntVar: case vpiShortIntVar: case vpiIntVar: case vpiByteVar: case vpiBitVar: signal_delete(item); break; case vpiParameter: parameter_delete(item); break; case vpiRealVar: real_delete(item); break; case vpiEnumTypespec: enum_delete(item); break; case vpiPort: port_delete(item); break; case vpiPortBit: port_bit_delete(item); break; case vpiStringVar: string_delete(item); break; case vpiClassVar: class_delete(item); break; case vpiArrayVar: switch(item->vpi_get(vpiArrayType)) { case vpiQueueArray: queue_delete(item); break; case vpiDynamicArray: darray_delete(item); break; default: fprintf(stderr, "Need support for array type: %d\n", item->vpi_get(vpiArrayType)); assert(0); break; } break; default: fprintf(stderr, "Need support for type: %d\n", item->get_type_code()); assert(0); break; } } scope->intern.clear(); /* Save any class definitions to clean up later. */ map::iterator citer; for (citer = scope->classes.begin(); citer != scope->classes.end(); ++ citer ) { class_list_count += 1; class_list = static_cast (realloc(class_list, class_list_count*sizeof(class_type **))); class_list[class_list_count-1] = citer->second; } } void root_table_delete(void) { for (unsigned idx = 0; idx < vpip_root_table.size(); idx += 1) { __vpiScope *scope = static_cast<__vpiScope *> (vpip_root_table[idx]); vthreads_delete(scope); delete_sub_scopes(scope); delete scope; } vpip_root_table.clear(); /* Clean up all the class definitions. */ for (unsigned idx = 0; idx < class_list_count; idx += 1) { class_def_delete(class_list[idx]); } free(class_list); class_list = 0; class_list_count = 0; } #endif static void construct_scope_fullname(__vpiScope*ref, char*buf) { if (ref->scope) { construct_scope_fullname(ref->scope, buf); // Add a "." separator, unless this is for a package if (ref->scope->get_type_code() != vpiPackage) { strcat(buf, "."); } } strcat(buf, ref->scope_name()); // For a package, add a "::" to the end if (ref->get_type_code() == vpiPackage) strcat(buf, "::"); } static const char* scope_get_type(int code) { switch (code) { case vpiModule: return "vpiModule"; case vpiGenScope: return "vpiGenScope"; case vpiFunction: return "vpiFunction"; case vpiTask: return "vpiTask"; case vpiNamedBegin: return "vpiNamedBegin"; case vpiNamedFork: return "vpiNamedFork"; default: fprintf(stderr, "VPI error: invalid scope type code %d.\n", code); return NULL; } } static char* scope_get_str(int code, vpiHandle obj) { __vpiScope*ref = dynamic_cast<__vpiScope*>(obj); assert(ref); char buf[4096]; // XXX is a fixed buffer size really reliable? const char *p=0; switch (code) { case vpiDefFile: p = file_names[ref->def_file_idx]; break; case vpiFile: p = file_names[ref->file_idx]; break; case vpiFullName: buf[0] = 0; construct_scope_fullname(ref, buf); p = buf; break; case vpiName: p = ref->scope_name(); break; case vpiDefName: p = ref->scope_def_name(); break; case vpiType: p = scope_get_type(code); break; default: fprintf(stderr, "VPI error: invalid scope string code %d.\n", code); return NULL; } return simple_set_rbuf_str(p); } static vpiHandle scope_get_handle(int code, vpiHandle obj) { __vpiScope*rfp = dynamic_cast<__vpiScope*>(obj); assert(rfp); switch (code) { case vpiScope: return rfp->scope; case vpiModule: return rfp->scope; } return 0; } /* compares vpiType's considering object classes */ static int compare_types(int code, int type) { /* NOTE: The Verilog VPI does not for any object support vpiScope as an iterator parameter, so it is used here as a means to scan everything in the *current* scope. */ if (code == vpiScope) return 1; if (code == type) return 1; if ( code == vpiInternalScope && (type == vpiModule || type == vpiGenScope || type == vpiFunction || type == vpiTask || type == vpiNamedBegin || type == vpiNamedFork) ) return 1; if ( code == vpiInstance && (type == vpiModule || type == vpiProgram || type == vpiInterface || type == vpiPackage) ) return 1; if ( code == vpiVariables && (type == vpiIntegerVar || type == vpiBitVar || type == vpiByteVar || type == vpiShortIntVar || type == vpiIntVar || type == vpiLongIntVar || type == vpiTimeVar || type == vpiRealVar)) return 1; return 0; } static vpiHandle make_subset_iterator_(int type_code, vector&table) { unsigned mcnt = 0, ncnt = 0; vpiHandle*args; for (unsigned idx = 0; idx < table.size(); idx += 1) if (compare_types(type_code, table[idx]->get_type_code())) mcnt += 1; if (mcnt == 0) return 0; args = static_cast(calloc(mcnt, sizeof(vpiHandle))); for (unsigned idx = 0; idx < table.size(); idx += 1) if (compare_types(type_code, table[idx]->get_type_code())) args[ncnt++] = table[idx]; assert(ncnt == mcnt); return vpip_make_iterator(mcnt, args, true); } /* * This function implements the vpi_iterate method for vpiModule and * similar objects. The vpi_iterate allows the user to iterate over * things that are contained in the scope object, by generating an * iterator for the requested set of items. */ static vpiHandle module_iter(int code, vpiHandle obj) { __vpiScope*ref = dynamic_cast<__vpiScope*>(obj); assert(ref); return make_subset_iterator_(code, ref->intern); } __vpiScope::__vpiScope(const char*nam, const char*tnam, bool auto_flag) : is_automatic_(auto_flag) { name_ = vpip_name_string(nam); tname_ = vpip_name_string(tnam? tnam : ""); } int __vpiScope::vpi_get(int code) { switch (code) { case vpiCellInstance: return is_cell? 1 : 0; case vpiDefLineNo: return def_lineno; case vpiLineNo: return lineno; case vpiTimeUnit: return time_units; case vpiTimePrecision: return time_precision; case vpiTopModule: return 0x0 == scope; case vpiAutomatic: return is_automatic_? 1 : 0; } return vpiUndefined; } char*__vpiScope::vpi_get_str(int code) { return scope_get_str(code, this); } vpiHandle __vpiScope::vpi_handle(int code) { return scope_get_handle(code, this); } vpiHandle __vpiScope::vpi_iterate(int code) { return module_iter(code, this); } class vpiScopeModule : public __vpiScope { public: inline vpiScopeModule(const char*nam, const char*tnam) : __vpiScope(nam,tnam,false) { } int get_type_code(void) const override { return vpiModule; } }; struct vpiScopePackage : public __vpiScope { inline vpiScopePackage(const char*nam, const char*tnam) : __vpiScope(nam,tnam) { } int get_type_code(void) const override { return vpiPackage; } }; struct vpiScopeTask : public __vpiScope { inline vpiScopeTask(const char*nam, const char*tnam) : __vpiScope(nam,tnam) { } int get_type_code(void) const override { return vpiTask; } }; struct vpiScopeTaskAuto : public __vpiScope { inline vpiScopeTaskAuto(const char*nam, const char*tnam) : __vpiScope(nam,tnam,true) { } int get_type_code(void) const override { return vpiTask; } }; struct vpiScopeBegin : public __vpiScope { inline vpiScopeBegin(const char*nam, const char*tnam) : __vpiScope(nam,tnam,false) { } int get_type_code(void) const override { return vpiNamedBegin; } }; class vpiScopeBeginAuto : public __vpiScope { public: inline vpiScopeBeginAuto(const char*nam, const char*tnam) : __vpiScope(nam,tnam,true) { } int get_type_code(void) const override { return vpiNamedBegin; } }; struct vpiScopeGenerate : public __vpiScope { inline vpiScopeGenerate(const char*nam, const char*tnam) : __vpiScope(nam,tnam) { } int get_type_code(void) const override { return vpiGenScope; } }; struct vpiScopeFork : public __vpiScope { inline vpiScopeFork(const char*nam, const char*tnam) : __vpiScope(nam,tnam,false) { } int get_type_code(void) const override { return vpiNamedFork; } }; class vpiScopeForkAuto : public __vpiScope { public: inline vpiScopeForkAuto(const char*nam, const char*tnam) : __vpiScope(nam,tnam,true) { } int get_type_code(void) const override { return vpiNamedFork; } }; struct vpiScopeClass : public __vpiScope { inline vpiScopeClass(const char*nam, const char*tnam) : __vpiScope(nam,tnam) { } int get_type_code(void) const override { return vpiClassTypespec; } }; /* * The current_scope is a compile time concept. As the vvp source is * compiled, items that have scope are placed in the current * scope. The ".scope" directives select the scope that is current. */ static __vpiScope*current_scope = 0; void vpip_attach_to_scope(__vpiScope*scope, vpiHandle obj) { assert(scope); scope->intern.push_back(obj); } /* * When the compiler encounters a scope declaration, this function * creates and initializes a __vpiScope object with the requested name * and within the addressed parent. The label is used as a key in the * symbol table and the name is used to construct the actual object. */ void compile_scope_decl(char*label, char*type, char*name, char*tname, char*parent, long file_idx, long lineno, long def_file_idx, long def_lineno, long is_cell) { count_vpi_scopes += 1; char vec_type; char sign_flag; unsigned wid; __vpiScope*scope; if (strcmp(type,"module") == 0) { scope = new vpiScopeModule(name, tname); } else if ( sscanf(type, "function.vec%c.%c%u", &vec_type, &sign_flag, &wid) == 3 ) { int type_code; if (sign_flag=='s') { type_code = vpiSizedSignedFunc; } else if (sign_flag=='u') { type_code = vpiSizedFunc; } else if (sign_flag=='i') { type_code = vpiIntFunc; } else { assert(0); type_code = vpiSizedFunc; } vvp_bit4_t init_val = vec_type == '4' ? BIT4_X : BIT4_0; scope = new vpiScopeFunction(name, tname, false, type_code, wid, init_val); } else if ( sscanf(type, "autofunction.vec%c.%c%u", &vec_type, &sign_flag, &wid) == 3 ) { int type_code; switch (sign_flag) { case 's': type_code = vpiSizedSignedFunc; break; case 'u': type_code = vpiSizedFunc; break; default: assert(0); type_code = vpiSizedFunc; break; } vvp_bit4_t init_val = vec_type == '4' ? BIT4_X : BIT4_0; scope = new vpiScopeFunction(name, tname, true, type_code, wid, init_val); } else if (strcmp(type,"function.obj") == 0) { scope = new vpiScopeFunction(name, tname, false, vpiSizedFunc, 0, BIT4_0); } else if (strcmp(type,"autofunction.obj") == 0) { scope = new vpiScopeFunction(name, tname, true, vpiSizedFunc, 0, BIT4_0); } else if (strcmp(type,"function.real") == 0) { scope = new vpiScopeFunction(name, tname, false, vpiRealFunc, 0, BIT4_0); } else if (strcmp(type,"autofunction.real") == 0) { scope = new vpiScopeFunction(name, tname, true, vpiRealFunc, 0, BIT4_0); } else if (strcmp(type,"function.str") == 0) { scope = new vpiScopeFunction(name, tname, false, vpiOtherFunc, 0, BIT4_0); } else if (strcmp(type,"autofunction.str") == 0) { scope = new vpiScopeFunction(name, tname, true, vpiOtherFunc, 0, BIT4_0); } else if (strcmp(type,"function.void") == 0) { scope = new vpiScopeFunction(name, tname, false, vpiOtherFunc, 0, BIT4_0); } else if (strcmp(type,"autofunction.void") == 0) { scope = new vpiScopeFunction(name, tname, true, vpiOtherFunc, 0, BIT4_0); } else if (strcmp(type,"task") == 0) { scope = new vpiScopeTask(name, tname); } else if (strcmp(type,"autotask") == 0) { scope = new vpiScopeTaskAuto(name, tname); } else if (strcmp(type,"fork") == 0) { scope = new vpiScopeFork(name, tname); } else if (strcmp(type,"autofork") == 0) { scope = new vpiScopeForkAuto(name, tname); } else if (strcmp(type,"begin") == 0) { scope = new vpiScopeBegin(name, tname); } else if (strcmp(type,"autobegin") == 0) { scope = new vpiScopeBeginAuto(name, tname); } else if (strcmp(type,"generate") == 0) { scope = new vpiScopeGenerate(name, tname); } else if (strcmp(type,"package") == 0) { scope = new vpiScopePackage(name, tname); } else if (strcmp(type,"class") == 0) { scope = new vpiScopeClass(name, tname); } else { scope = new vpiScopeModule(name, tname); assert(0); } scope->file_idx = (unsigned) file_idx; scope->lineno = (unsigned) lineno; scope->def_file_idx = (unsigned) def_file_idx; scope->def_lineno = (unsigned) def_lineno; scope->item = 0; scope->nitem = 0; scope->live_contexts = 0; scope->free_contexts = 0; if (is_cell) scope->is_cell = true; else scope->is_cell = false; current_scope = scope; compile_vpi_symbol(label, scope); free(label); free(type); delete[] name; delete[] tname; if (parent) { static vpiHandle obj; compile_vpi_lookup(&obj, parent); assert(obj); __vpiScope*sp = dynamic_cast<__vpiScope*>(obj); vpip_attach_to_scope(sp, scope); scope->scope = dynamic_cast<__vpiScope*>(obj); /* Inherit time units and precision from the parent scope. */ scope->time_units = sp->time_units; scope->time_precision = sp->time_precision; } else { scope->scope = 0x0; vpip_root_table.push_back(scope); /* Root scopes inherit time_units and precision from the system precision. */ scope->time_units = vpip_get_time_precision(); scope->time_precision = vpip_get_time_precision(); } } void compile_scope_recall(char*symbol) { /* A __vpiScope starts with a __vpiHandle structure so this is a safe cast. We need the (void*) to avoid a dereferenced type punned pointer warning from some gcc compilers. */ compile_vpi_lookup((vpiHandle*)(void*)¤t_scope, symbol); assert(current_scope); } /* * This function handles the ".timescale" directive in the vvp * source. It sets in the current scope the specified units value. */ void compile_timescale(long units, long precision) { assert(current_scope); current_scope->time_units = units; current_scope->time_precision = precision; } __vpiScope* vpip_peek_current_scope(void) { return current_scope; } void vpip_attach_to_current_scope(vpiHandle obj) { vpip_attach_to_scope(current_scope, obj); } __vpiScope* vpip_peek_context_scope(void) { __vpiScope*scope = current_scope; /* A context is allocated for each automatic task or function. Storage for nested scopes (named blocks) is allocated in the parent context. */ while (scope->scope && scope->scope->is_automatic()) scope = scope->scope; return scope; } unsigned vpip_add_item_to_context(automatic_hooks_s*item, __vpiScope*scope) { assert(scope); assert(scope->is_automatic()); unsigned idx = scope->nitem++; if (scope->item == 0) scope->item = static_cast (malloc(sizeof(automatic_hooks_s*))); else scope->item = static_cast (realloc(scope->item, sizeof(automatic_hooks_s*)*scope->nitem)); scope->item[idx] = item; /* Offset the context index by 2 to leave space for the list links. */ return 2 + idx; } vpiPortInfo::vpiPortInfo( __vpiScope *parent, unsigned index, int vpi_direction, unsigned width, const char *name, char* buffer) : parent_(parent), index_(index), direction_(vpi_direction), width_(width), name_(name) { if (buffer != nullptr) functor_ref_lookup(&ref_, buffer); else ref_ = nullptr; } vpiPortInfo::~vpiPortInfo() { delete[] name_; } #ifdef CHECK_WITH_VALGRIND void port_delete(__vpiHandle *handle) { delete dynamic_cast(handle); } #endif int vpiPortInfo::vpi_get(int code) { switch( code ) { case vpiDirection : return direction_; case vpiPortIndex : return index_; case vpiSize : return width_; default : return vpiUndefined; } } char *vpiPortInfo::vpi_get_str(int code) { switch( code ) { case vpiName : return simple_set_rbuf_str(name_); default : return NULL; } } vpiHandle vpiPortInfo::vpi_handle(int code) { switch (code) { case vpiParent: case vpiScope: case vpiModule: return parent_; default : break; } return 0; } static vpiHandle portinfo_iterate(int code, vpiHandle ref) { vpiPortInfo*rfp = dynamic_cast(ref); assert(rfp); unsigned width = rfp->get_width(); switch (code) { case vpiBit: { vpiHandle*args = static_cast(calloc(width, sizeof(vpiHandle*))); for (unsigned i = 0; iport_bits_.size(); i++) { args[i] = rfp->port_bits_[i]; } return vpip_make_iterator(width, args, true); } } return 0; } vpiHandle vpiPortInfo::vpi_iterate(int code) { return portinfo_iterate(code, this); } vpiPortBitInfo::vpiPortBitInfo(vpiPortInfo *parent, unsigned bit) : parent_(parent), bit_(bit) { } vpiPortBitInfo::~vpiPortBitInfo() { } #ifdef CHECK_WITH_VALGRIND void port_bit_delete(__vpiHandle *handle) { delete dynamic_cast(handle); } #endif vpiHandle vpiPortBitInfo::vpi_handle(int code) { switch (code) { case vpiParent: return parent_; default : break; } return 0; } int vpiPortBitInfo::vpi_get(int code) { switch( code ) { case vpiBit : return bit_; default : break; } return 0; } /* Port info is meta-data to allow vpi queries of the port signature of modules for * code-generators etc. There are no actual nets corresponding to instances of module ports * as elaboration directly connects nets connected through module ports. */ void compile_port_info( unsigned index, int vpi_direction, unsigned width, const char *name, char* buffer ) { vpiPortInfo* obj = new vpiPortInfo( vpip_peek_current_scope(), index, vpi_direction, width, name, buffer ); vpip_attach_to_current_scope(obj); // Create vpiPortBit objects for (unsigned i=0; iadd_port_bit(obj_bit); vpip_attach_to_current_scope(obj_bit); } }