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[/] [or1k/] [trunk/] [ecos-2.0/] [packages/] [compat/] [uitron/] [v2_0/] [tests/] [testcx4.cxx] - Rev 1254
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//=========================================================================== // // testcx4.cxx // // uITRON "C++" test program four // //=========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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 2 or (at your option) any later version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //=========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): dsm // Contributors: dsm // Date: 1998-06-12 // Purpose: uITRON API testing // Description: // //####DESCRIPTIONEND#### // //=========================================================================== #include <pkgconf/uitron.h> // uITRON setup CYGNUM_UITRON_SEMAS // CYGPKG_UITRON et al #include <cyg/infra/testcase.h> // testing infrastructure #ifdef CYGPKG_UITRON // we DO want the uITRON package #ifdef CYGSEM_KERNEL_SCHED_MLQUEUE // we DO want prioritized threads #ifdef CYGFUN_KERNEL_THREADS_TIMER // we DO want timout-able calls #ifdef CYGVAR_KERNEL_COUNTERS_CLOCK // we DO want the realtime clock // we're OK if it's C++ or neither of those two is defined: #if defined( __cplusplus ) || \ (!defined( CYGIMP_UITRON_INLINE_FUNCS ) && \ !defined( CYGIMP_UITRON_CPP_OUTLINE_FUNCS) ) // =================== TEST CONFIGURATION =================== #if \ /* test configuration for enough tasks */ \ (CYGNUM_UITRON_TASKS >= 4) && \ (CYGNUM_UITRON_TASKS < 90) && \ (CYGNUM_UITRON_START_TASKS == 1) && \ ( !defined(CYGPKG_UITRON_TASKS_CREATE_DELETE) || \ CYGNUM_UITRON_TASKS_INITIALLY >= 4 ) && \ \ /* test configuration for enough cyclic handlers */ \ defined( CYGPKG_UITRON_CYCLICS ) && \ (CYGNUM_UITRON_CYCLICS >= 3) && \ (CYGNUM_UITRON_CYCLICS < 90) && \ \ /* test configuration for enough alarm handlers */ \ defined( CYGPKG_UITRON_ALARMS ) && \ (CYGNUM_UITRON_ALARMS >= 3) && \ (CYGNUM_UITRON_ALARMS < 90) && \ \ /* the end of the large #if statement */ \ 1 // ============================ END ============================ #include <cyg/compat/uitron/uit_func.h> // uITRON externC void cyg_package_start( void ) { CYG_TEST_INIT(); CYG_TEST_INFO( "Calling cyg_uitron_start()" ); cyg_uitron_start(); } volatile int intercount = 0; INT scratch; void hand1(void) { CYG_TEST_INFO("Handler 1 called"); intercount++; } void hand2(void) { CYG_TEST_CHECK( 2 == intercount, "handler out of sync" ); CYG_TEST_INFO("Handler 2 called"); intercount++; } extern "C" { void task1( unsigned int arg ); void task2( unsigned int arg ); void task3( unsigned int arg ); void task4( unsigned int arg ); } void task1( unsigned int arg ) { ER ercd; T_DCYC dcyc; T_DALM dalm; T_RCYC rcyc; T_RALM ralm; unsigned int tm; static char foo[] = "Test message"; VP info = (VP)foo; // Increase times when running on HW since overhead of GDB packet // acknowledgements may cause tests of timing to fail. if (cyg_test_is_simulator) tm = 1; else tm = 4; CYG_TEST_INFO( "Task 1 running" ); ercd = get_tid( &scratch ); CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); CYG_TEST_CHECK( 1 == scratch, "tid not 1" ); dcyc.exinf = (VP)info; dcyc.cycatr = TA_HLNG; dcyc.cychdr = (FP)&hand1; dcyc.cycact = TCY_INI; // bad dcyc.cyctim = 2; #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = def_cyc(3, &dcyc); CYG_TEST_CHECK( E_PAR == ercd, "def_cyc bad ercd !E_PAR" ); #endif // we can test bad param error returns dcyc.cycact = TCY_OFF; // make good dcyc.cyctim = 0; // bad #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = def_cyc(3, &dcyc); CYG_TEST_CHECK( E_PAR == ercd, "def_cyc bad ercd !E_PAR" ); #endif // we can test bad param error returns dcyc.cyctim = 1; // make good ercd = def_cyc(3, &dcyc); CYG_TEST_CHECK( E_OK == ercd, "def_cyc bad ercd" ); #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = def_cyc(-6, &dcyc); CYG_TEST_CHECK( E_PAR == ercd, "def_cyc bad ercd !E_PAR" ); ercd = def_cyc(99, &dcyc); CYG_TEST_CHECK( E_PAR == ercd, "def_cyc bad ercd !E_PAR" ); ercd = act_cyc(-6, TCY_OFF); CYG_TEST_CHECK( E_PAR == ercd, "act_cyc bad ercd !E_PAR" ); ercd = act_cyc(99, TCY_OFF); CYG_TEST_CHECK( E_PAR == ercd, "act_cyc bad ercd !E_PAR" ); ercd = act_cyc( 3, ~0); CYG_TEST_CHECK( E_PAR == ercd, "act_cyc bad ercd !E_PAR" ); ercd = ref_cyc(&rcyc, -6); CYG_TEST_CHECK( E_PAR == ercd, "ref_cyc bad ercd !E_PAR" ); ercd = ref_cyc(&rcyc, 99); CYG_TEST_CHECK( E_PAR == ercd, "ref_cyc bad ercd !E_PAR" ); #ifndef CYGSEM_UITRON_PARAMS_NULL_IS_GOOD_PTR ercd = ref_cyc(NULL, 3); CYG_TEST_CHECK( E_PAR == ercd, "ref_cyc bad ercd !E_PAR" ); #endif #endif // we can test bad param error returns ercd = def_cyc(3, (T_DCYC *)NADR); CYG_TEST_CHECK( E_OK == ercd, "def_cyc bad ercd" ); #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_NOEXS == ercd, "ref_cyc bad ercd !E_NOEXS" ); #endif // we can test bad param error returns CYG_TEST_PASS( "bad calls: def_cyc, act_cyc, ref_cyc" ); dalm.exinf = (VP)info; dalm.almatr = TA_HLNG; dalm.almhdr = (FP)&hand2; dalm.tmmode = ~0; // bad dalm.almtim = 20; #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = def_alm(3, &dalm); CYG_TEST_CHECK( E_PAR == ercd, "def_alm bad ercd !E_PAR" ); #endif // we can test bad param error returns dalm.tmmode = TTM_REL; // make good dalm.almtim = 0; // bad #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = def_alm(3, &dalm); CYG_TEST_CHECK( E_PAR == ercd, "def_alm bad ercd !E_PAR" ); #endif // we can test bad param error returns dalm.almtim = 1000; // make good ercd = def_alm(3, &dalm); CYG_TEST_CHECK( E_OK == ercd, "def_alm bad ercd" ); #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = ref_alm(&ralm, -6); CYG_TEST_CHECK( E_PAR == ercd, "ref_alm bad ercd !E_PAR" ); ercd = ref_alm(&ralm, 99); CYG_TEST_CHECK( E_PAR == ercd, "ref_alm bad ercd !E_PAR" ); #ifndef CYGSEM_UITRON_PARAMS_NULL_IS_GOOD_PTR ercd = ref_alm(NULL, 3); CYG_TEST_CHECK( E_PAR == ercd, "ref_alm bad ercd !E_PAR" ); #endif #endif // we can test bad param error returns ercd = def_alm(3, (T_DALM *)NADR); CYG_TEST_CHECK( E_OK == ercd, "def_cyc bad ercd" ); #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = ref_alm(&ralm, 3); CYG_TEST_CHECK( E_NOEXS == ercd, "ref_cyc bad ercd !E_NOEXS" ); #endif // we can test bad param error returns CYG_TEST_PASS( "bad calls: def_alm, act_alm, ref_alm" ); dcyc.exinf = (VP)info; dcyc.cycatr = TA_HLNG; dcyc.cychdr = (FP)&hand1; dcyc.cycact = TCY_ON; dcyc.cyctim = 50*tm; ercd = def_cyc(3, &dcyc); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 45*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 50*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_ON == rcyc.cycact, "rcyc.cycact should be TCY_ON" ); ercd = act_cyc(3, TCY_OFF); CYG_TEST_CHECK( E_OK == ercd, "act_cyc bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 45*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 50*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_OFF == rcyc.cycact, "rcyc.cycact should be TCY_OFF" ); ercd = act_cyc(3, TCY_ON); CYG_TEST_CHECK( E_OK == ercd, "act_cyc bad ercd" ); CYG_TEST_PASS("good calls: def_cyc, act_cyc, ref_cyc"); dalm.exinf = (VP)info; dalm.almatr = TA_HLNG; dalm.almhdr = (FP)&hand2; dalm.tmmode = TTM_REL; dalm.almtim = 120*tm; ercd = def_alm(3, &dalm); CYG_TEST_CHECK( E_OK == ercd, "def_alm bad ercd" ); ercd = ref_alm(&ralm, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_alm bad ercd" ); CYG_TEST_CHECK( info == ralm.exinf, "ralm.exinf should be info" ); CYG_TEST_CHECK( 115*tm < ralm.lfttim, "ralm.lfttim too small" ); CYG_TEST_CHECK( ralm.lfttim <= 120*tm, "ralm.lfttim too big" ); // Expect handlers to be called at approximate times // time intercount // tm*50 hand1 0 // tm*100 hand1 1 // tm*120 hand2 2 // tm*150 hand1 3 ercd = dly_tsk(160*tm); CYG_TEST_CHECK( E_OK == ercd, "dly_tsk bad ercd" ); CYG_TEST_CHECK( 4 == intercount, "handlers not both called" ); ercd = act_cyc(3, TCY_OFF); CYG_TEST_CHECK( E_OK == ercd, "act_cyc(off) bad ercd" ); ercd = dly_tsk(60*tm); // enough for at least one tick CYG_TEST_CHECK( E_OK == ercd, "dly_tsk bad ercd" ); CYG_TEST_CHECK( 4 == intercount, "cyclic not disabled" ); // approx time now 220, so we expect a cycle in about 30 ticks ercd = act_cyc(3, TCY_ON); CYG_TEST_CHECK( E_OK == ercd, "act_cyc(on) bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 25*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 35*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_ON == rcyc.cycact, "rcyc.cycact should be TCY_ON" ); // now resynchronize with right now: ercd = act_cyc(3, TCY_ON|TCY_INI); CYG_TEST_CHECK( E_OK == ercd, "act_cyc(on) bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 45*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 50*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_ON == rcyc.cycact, "rcyc.cycact should be TCY_ON" ); // wait a bit and check that time marches on, or even down ercd = dly_tsk(10*tm); CYG_TEST_CHECK( E_OK == ercd, "dly_tsk bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 35*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 45*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_ON == rcyc.cycact, "rcyc.cycact should be TCY_ON" ); // now turn it off and re-synch with right now: ercd = act_cyc(3, TCY_OFF|TCY_INI); CYG_TEST_CHECK( E_OK == ercd, "act_cyc(on) bad ercd" ); ercd = ref_cyc(&rcyc, 3); CYG_TEST_CHECK( E_OK == ercd, "ref_cyc bad ercd" ); CYG_TEST_CHECK( info == rcyc.exinf, "rcyc.exinf should be info" ); CYG_TEST_CHECK( 45*tm < rcyc.lfttim, "rcyc.lfttim too small" ); CYG_TEST_CHECK( rcyc.lfttim <= 50*tm, "rcyc.lfttim too big" ); CYG_TEST_CHECK( TCY_OFF == rcyc.cycact, "rcyc.cycact should be TCY_OFF" ); ercd = act_cyc(3, TCY_OFF); CYG_TEST_CHECK( E_OK == ercd, "act_cyc(on) bad ercd" ); CYG_TEST_PASS("good calls: def_cyc, act_cyc, ref_cyc, def_alm, ref_alm"); // all done CYG_TEST_EXIT( "All done" ); ext_tsk(); } void task2( unsigned int arg ) { } void task3( unsigned int arg ) { } void task4( unsigned int arg ) { } #else // not enough (or too many) uITRON objects configured in #define N_A_MSG "not enough uITRON objects to run test" #endif // not enough (or too many) uITRON objects configured in #else // not C++ and some C++ specific options enabled #define N_A_MSG "C++ specific options selected but this is C" #endif // not C++ and some C++ specific options enabled #else // ! CYGVAR_KERNEL_COUNTERS_CLOCK - can't test without it #define N_A_MSG "no CYGVAR_KERNEL_COUNTERS_CLOCK" #endif // ! CYGVAR_KERNEL_COUNTERS_CLOCK - can't test without it #else // ! CYGFUN_KERNEL_THREADS_TIMER - can't test without it #define N_A_MSG "no CYGFUN_KERNEL_THREADS_TIMER" #endif // ! CYGFUN_KERNEL_THREADS_TIMER - can't test without it #else // ! CYGIMP_THREAD_PRIORITY - can't test without it #define N_A_MSG "no CYGSEM_KERNEL_SCHED_MLQUEUE" #endif // ! CYGSEM_KERNEL_SCHED_MLQUEUE - can't test without it #else // ! CYGPKG_UITRON #define N_A_MSG "uITRON Compatibility layer disabled" #endif // CYGPKG_UITRON #ifdef N_A_MSG externC void cyg_start( void ) { CYG_TEST_INIT(); CYG_TEST_NA( N_A_MSG ); } #endif // N_A_MSG defined ie. we are N/A. // EOF testcx4.cxx
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