/***************************************************************************** Licensed to Accellera Systems Initiative Inc. (Accellera) under one or more contributor license agreements. See the NOTICE file distributed with this work for additional information regarding copyright ownership. Accellera licenses this file to you under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. *****************************************************************************/ // sc_writer_policy.cpp -- test for // // Original Author: John Aynsley, Doulos, Inc. // // MODIFICATION LOG - modifiers, enter your name, affiliation, date and // // $Log: sc_writer_policy.cpp,v $ // Revision 1.2 2011/05/08 19:18:46 acg // Andy Goodrich: remove extraneous + prefixes from git diff. // // sc_writer_policy template argument of class sc_signal #define SC_INCLUDE_DYNAMIC_PROCESSES #include using namespace sc_core; using namespace sc_dt; using std::cout; using std::endl; using std::string; struct M: sc_module { sc_inout port; sc_time delay; sc_signal one_sig; sc_signal many_sig; bool first_run; int g0, g1, g2, g3; M(sc_module_name _name, sc_time _delay) : port("port") , delay(_delay) , first_run(true) { sc_assert( one_sig.get_writer_policy() == SC_ONE_WRITER ); sc_assert( many_sig.get_writer_policy() == SC_MANY_WRITERS ); SC_THREAD(T); SC_METHOD(method_process_1); SC_METHOD(method_process_2); one_sig.write(-1); many_sig.write(-1); g0 = g1 = g2 = g3 = 0; } void end_of_elaboration() { sc_assert( port->get_writer_policy() == SC_MANY_WRITERS ); one_sig.write(1); many_sig.write(1); g0 = 1; } void start_of_simulation() { one_sig.write(2); many_sig.write(2); g1 = 1; } void T() { wait(delay); port.write(true); g2 = 1; } void method_process_1() { one_sig.write(3); many_sig.write(3); } void method_process_2() { if (first_run) { first_run = false; next_trigger(SC_ZERO_TIME); } else { try { one_sig = 4; } catch (const std::exception& e) { g3 = 1; } many_sig.write(4); } } SC_HAS_PROCESS(M); }; struct Top: sc_module { M *m1; M *m2; sc_signal many_sig_1; sc_signal many_sig_2; sc_signal one_sig_1; sc_signal one_sig_2; sc_buffer buffy; sc_signal_resolved resolved; sc_signal_rv<2> rv; Top(sc_module_name _name) : many_sig_1("many_sig_1") , many_sig_2("many_sig_2") , one_sig_1("one_sig_1") , buffy("buffy") , resolved("resolved") , rv("rv") { m1 = new M("m1", sc_time(1, SC_PS)); m2 = new M("m2", sc_time(2, SC_PS)); m1->port.bind(many_sig_1); m2->port.bind(many_sig_1); SC_THREAD(T1); SC_THREAD(T2); sc_spawn(sc_bind(&Top::T3, this)); sc_assert( many_sig_1.get_writer_policy() == SC_MANY_WRITERS ); sc_assert( many_sig_2.get_writer_policy() == SC_MANY_WRITERS ); sc_assert( one_sig_1 .get_writer_policy() == SC_ONE_WRITER ); sc_assert( one_sig_2 .get_writer_policy() == SC_ONE_WRITER ); sc_assert( buffy .get_writer_policy() == SC_MANY_WRITERS ); sc_assert( resolved .get_writer_policy() == SC_MANY_WRITERS ); sc_assert( rv .get_writer_policy() == SC_MANY_WRITERS ); one_sig_1 = 0; buffy = SC_LOGIC_X; resolved = SC_LOGIC_Z; rv = sc_lv<2>("ZZ"); // Writes outside of a process should not count as manyple writers many_sig_1.write(true); many_sig_2.write(0); one_sig_1.write(0); one_sig_2.write(0); buffy.write(SC_LOGIC_0); f0 = f1 = f2 = f3 = f4 = f5 = 0; } int f0, f1, f2, f3, f4, f5; void T1() { resolved = SC_LOGIC_0; rv = sc_lv<2>("01"); // Attempt to write SC_ONE_WRITER signal from >1 process should fail try { one_sig_1 = 1; } catch (const std::exception& e) { f3 = 1; } try { one_sig_2 = 1; } catch (const std::exception& e) { f4 = 1; } wait(1, SC_PS); // Attempt to write SC_MANY_WRITER signal from >1 process IN SAME DELTA should fail try { many_sig_2.write(3); } catch (const std::exception& e) { f5 = 1; } wait(3, SC_PS); many_sig_2.write(6); buffy = SC_LOGIC_0; wait(many_sig_2.default_event()); f0 = 1; } void T2() { resolved = SC_LOGIC_1; rv = sc_lv<2>("10"); try { one_sig_1 = 2; } catch (const std::exception& e) { f3 = 1; } try { one_sig_2 = 2; } catch (const std::exception& e) { f4 = 1; } wait(1, SC_PS); try { many_sig_2.write(4); } catch (const std::exception& e) { f5 = 1; } wait(4, SC_PS); many_sig_2.write(7); buffy = SC_LOGIC_1; wait(many_sig_2.default_event()); f1 = 1; } void T3() { resolved = SC_LOGIC_Z; rv = sc_lv<2>("ZZ"); try { one_sig_1 = 3; } catch (const std::exception& e) { f3 = 1; } try { one_sig_2 = 3; } catch (const std::exception& e) { f4 = 1; } wait(1, SC_PS); try { many_sig_2.write(5); } catch (const std::exception& e) { f5 = 1; } wait(5, SC_PS); many_sig_2.write(8); buffy = SC_LOGIC_0; wait(many_sig_2.default_event()); f2 = 1; sc_assert( resolved.read() == SC_LOGIC_X ); sc_assert( rv.read() == sc_lv<2>("XX") ); sc_assert( many_sig_2.read() == 8 ); sc_assert( buffy.read() == SC_LOGIC_0 ); } SC_HAS_PROCESS(Top); }; int sc_main(int argc, char* argv[]) { Top top("top"); sc_start(); sc_assert( top.f0 ); sc_assert( top.f1 ); sc_assert( top.f2 ); sc_assert( top.f3 ); sc_assert( top.f4 ); sc_assert( top.f5 ); sc_assert( top.m1->g0 ); sc_assert( top.m2->g0 ); sc_assert( top.m1->g1 ); sc_assert( top.m2->g1 ); sc_assert( top.m1->g2 ); sc_assert( top.m2->g2 ); sc_assert( top.m1->g3 ); sc_assert( top.m2->g3 ); cout << endl << "Success" << endl; return 0; }