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//=========================================================================== // // testintr.c // // uITRON "C" test program for ixxx_yyy interrupt safe operators // //=========================================================================== //####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): hmt // Contributors:hmt // Date: 1998-08-20 // Purpose: uITRON API testing // Description: // //####DESCRIPTIONEND#### // //=========================================================================== #include <pkgconf/system.h> #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 ) && \ \ /* the end of the large #if statement */ \ 1 // ============================ END ============================ #include <cyg/hal/hal_arch.h> #include <cyg/hal/hal_intr.h> #include <cyg/infra/diag.h> #include <cyg/compat/uitron/uit_func.h> // uITRON #include <cyg/compat/uitron/uit_ifnc.h> // uITRON interrupt funcs void set_interrupt_number( void ); unsigned int clock_interrupt = 0; externC void cyg_package_start( void ) { CYG_TEST_INIT(); CYG_TEST_INFO( "Calling cyg_uitron_start()" ); set_interrupt_number(); cyg_uitron_start(); } extern "C" { void task1( unsigned int arg ); void task2( unsigned int arg ); void task3( unsigned int arg ); void task4( unsigned int arg ); } volatile int intercom = 0; INT scratch = 0; // Plan: replace (by direct intervention) the ISR and DSR of the regular // timer interrupt; be sure to ack the clock intr using the appropriate hal // macros. // // The new ISR(s) will simply use the interrupt-safe signalling functions // to control a 2nd task. Main task will check on the state thereof. // // We must test the ixxx_yyy() funcs with the scheduler already locked // also, by direct sched calls on the KAPI. This must verify that the // signal only happens when the scheduler unlocks. // // The 4 producer ops are: // iwup_tsk ( ID tskid ); // isig_sem ( ID semid ); // iset_flg ( ID flgid, UINT setptn ); // isnd_msg ( ID mbxid, T_MSG *pk_msg ); // // and return macros are: // ret_wup( ID tskid ); // ret_int(); // // These ISRs perform the producer ops on all available objects in turn. // Tasks 2-4 // Semas 1-4 // Flags 1-4 with marching bit data; they'll all be set to 0x1ff eventually // Mboxes 1-4 with an arbitrary pointer enum { NOTHING = 0, SLP, SEM, FLG, MBX, EXIT }; #define ACK_CLOCK() CYG_MACRO_START \ HAL_CLOCK_RESET( CYGNUM_HAL_INTERRUPT_RTC, \ CYGNUM_KERNEL_COUNTERS_RTC_PERIOD ); \ HAL_INTERRUPT_ACKNOWLEDGE( CYGNUM_HAL_INTERRUPT_RTC ); \ CYG_MACRO_END #define CHECK_TID() CYG_MACRO_START \ int my_tid; \ ER ercd; \ ercd = get_tid( &my_tid ); \ CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); \ CYG_TEST_CHECK( 0 == my_tid, "tid not 0 in ISR" ); \ CYG_MACRO_END unsigned int isr_wup_tsk( unsigned int vector, unsigned int data ) { // Hit TASKS in range 2..4 static int wtid = 2; ACK_CLOCK(); CHECK_TID(); iwup_tsk( wtid ); wtid++; if ( 5 == wtid ) wtid = 2; ret_int(); } unsigned int isr_ret_wup( unsigned int vector, unsigned int data ) { // Hit TASKS in range 2..4 static int rwid = 2; ACK_CLOCK(); CHECK_TID(); rwid++; if ( 6 == rwid ) rwid = 3; ret_wup( rwid - 1 ); } unsigned int isr_sig_sem( unsigned int vector, unsigned int data ) { // Hit SEMAS in range 1..3 static int ssid = 1; ACK_CLOCK(); CHECK_TID(); isig_sem( ssid ); ssid++; if ( ssid == 4 ) ssid = 1; ret_int(); } unsigned int isr_set_flg( unsigned int vector, unsigned int data ) { // Hit FLAGS in range 1..4 static int sfid = 1; static int sfdata = 0xff; ACK_CLOCK(); CHECK_TID(); iset_flg( sfid, sfdata ); sfid++; if ( sfid == 5 ) sfid = 1; // sfdata <<= 1; // if ( sfdata == 0x20 ) sfdata = 1; // so that eventually all 0x1f set ret_int(); } unsigned int isr_snd_msg( unsigned int vector, unsigned int data ) { // Hit MBOXES in range 1..4 static int smid = 1; ACK_CLOCK(); CHECK_TID(); isnd_msg( smid, (T_MSG *)&smid ); smid++; if ( smid == 5 ) smid = 1; ret_int(); } void attach_isr( unsigned int (*isr)(unsigned int, unsigned int) ); void detach_isr( unsigned int (*isr)(unsigned int, unsigned int) ); void lock_sched( void ); void unlock_sched( void ); volatile int count = -1; /* #define BIGDELAY 50000000 #define SMALLDELAY (BIGDELAY/SMALLLOOPS) #define SMALLLOOPS 3 #define xxxLONGDELAY() \ do { \ int i; \ for ( i = 0; i < BIGDELAY; i++ ) \ if ( wakeups[ 4 ] > prewups[ 4 ] + 99 ) break; \ } while ( 0 ) #define xxxDELAYLOCKSCHED() \ do { \ int i,j; \ for ( j = 0; j < SMALLLOOPS; j++ ) { \ lock_sched(); \ for ( i = 0; i < SMALLDELAY; i++ ) \ if ( wakeups[ 4 ] > prewups[ 4 ] + 99 ) break; \ unlock_sched(); \ if ( wakeups[ 4 ] > prewups[ 4 ] + 99 ) break; \ } \ } while ( 0 ) */ #define SMALLDELAYHW (5000000) #define EVENTSHW ( 20) #define SMALLDELAYSIM ( 100000) #define EVENTSSIM ( 4) #define SMALLDELAY (smalldelay) #define EVENTS (events) static int smalldelay = SMALLDELAYHW; static int events = EVENTSHW; #define LONGDELAY() do { \ count = 0; \ do count++; while ( wakeups[ 4 ] < prewups[ 4 ] + EVENTS ); \ } while ( 0 ) #define DELAYLOCKSCHED() \ do { \ count = 0; \ int i; \ do { \ lock_sched(); \ for ( i = 0; i < SMALLDELAY; i++ ) { \ count++; \ if ( wakeups[ 4 ] >= prewups[ 4 ] + EVENTS ) \ break; \ } \ unlock_sched(); \ CYG_TEST_INFO(" [Still iterating, please wait....] "); \ } while ( wakeups[ 4 ] < prewups[ 4 ] + EVENTS ); \ } while ( 0 ) #define DELAY() \ if ( 1 & loops ) \ DELAYLOCKSCHED(); \ else \ LONGDELAY(); volatile int wakeups[ 5 ] = { 0,0,0,0,0 }; volatile int prewups[ 5 ] = { 0,0,0,0,0 }; void task1( unsigned int arg ) { ER ercd; int loops; CYG_TEST_INFO( "Task 1 running" ); if ( cyg_test_is_simulator ) { // take less time events = EVENTSSIM; } // First test that dis_int() and ena_int() work for the clock interrupt #ifdef CYGSEM_UITRON_BAD_PARAMS_RETURN_ERRORS ercd = ena_int( 123456789 ); // Hope this is large enough to error CYG_TEST_CHECK( E_PAR == ercd, "ena_int bad ercd !E_PAR" ); ercd = dis_int( 123456789 ); CYG_TEST_CHECK( E_PAR == ercd, "dis_int bad ercd !E_PAR" ); #endif // This may take too long on a sim... // On the synthetic target this test cannot run reliably - the // loop counting assumes exclusive access to the processor. #ifndef CYGPKG_HAL_SYNTH if ( ! cyg_test_is_simulator ) { SYSTIME t1, t2; CYG_TEST_INFO( "Testing masking of clock interrupt" ); ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); // Wait for a tick. This loop acts as a synchronizer for the loop // below, ensuring that it starts just after a tick. for ( loops = 0; loops < 10000000; loops++ ) { ercd = get_tim( &t2 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } // Wait for next tick. Reset loops counter so we get the // approximate loop count of one clock tick. for ( loops = 0; loops < 10000000; loops++ ) { ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } // save how many loops could be executed in one tick. Multiply // with 3 : we run loops in pairs below and add the time of // one extra to avoid small variations to trigger failures. intercom = loops * 3; ercd = ena_int( clock_interrupt ); // was initialized already CYG_TEST_CHECK( E_OK == ercd, "ena_int bad ercd" ); ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); // Wait for a tick for ( loops = intercom; loops > 0; loops-- ) { ercd = get_tim( &t2 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } CYG_TEST_CHECK( 0 < loops, "No first tick" ); // and a second one for ( ; loops > 0; loops-- ) { ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } CYG_TEST_CHECK( 0 < loops, "No second tick" ); // The PowerPC cannot disable the timer interrupt (separately). #ifndef CYGPKG_HAL_POWERPC ercd = dis_int( clock_interrupt ); // was initialized already CYG_TEST_CHECK( E_OK == ercd, "dis_int bad ercd" ); ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); // Wait for a tick (should not happen) for ( loops = intercom; loops > 0; loops-- ) { ercd = get_tim( &t2 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } CYG_TEST_CHECK( 0 == loops, "A tick occured - should be masked" ); CYG_TEST_CHECK( t1 == t2, "Times are different" ); // Now enable it again and ensure all is well: ercd = ena_int( clock_interrupt ); CYG_TEST_CHECK( E_OK == ercd, "ena_int bad ercd" ); #endif ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); // Wait for a tick for ( loops = intercom; loops > 0; loops-- ) { ercd = get_tim( &t2 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } CYG_TEST_CHECK( 0 < loops, "No first tick" ); // and a second one for ( ; loops > 0; loops-- ) { ercd = get_tim( &t1 ); CYG_TEST_CHECK( E_OK == ercd, "get_tim bad ercd" ); if ( t2 != t1 ) break; } CYG_TEST_CHECK( 0 < loops, "No second tick" ); CYG_TEST_PASS( "dis_int(), ena_int() OK" ); } #endif intercom = 0; ercd = get_tid( &scratch ); CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); CYG_TEST_CHECK( 1 == scratch, "tid not 1" ); // start all other tasks (our prio is 1 by default) ercd = sta_tsk( 2, 222 ); CYG_TEST_CHECK( E_OK == ercd, "sta_tsk 2 bad ercd" ); ercd = sta_tsk( 3, 333 ); CYG_TEST_CHECK( E_OK == ercd, "sta_tsk 3 bad ercd" ); ercd = sta_tsk( 4, 444 ); CYG_TEST_CHECK( E_OK == ercd, "sta_tsk 4 bad ercd" ); // drop pri of other tasks all to 5 ercd = chg_pri( 2, 5 ); CYG_TEST_CHECK( E_OK == ercd, "chg_pri 2 bad ercd" ); ercd = chg_pri( 3, 5 ); CYG_TEST_CHECK( E_OK == ercd, "chg_pri 3 bad ercd" ); ercd = chg_pri( 4, 5 ); CYG_TEST_CHECK( E_OK == ercd, "chg_pri 4 bad ercd" ); // Test sleep/wakeup intercom = SLP; // Drop our prio to lower; they will run in turn until asleep ercd = chg_pri( 1, 6 ); CYG_TEST_CHECK( E_OK == ercd, "chg_pri 1 (self) bad ercd" ); loops = 4; do { if ( 1 & loops ) CYG_TEST_INFO( " (toggling scheduler lock) " ); else CYG_TEST_INFO( " (unlocked scheduler) " ); CYG_TEST_CHECK( 0 == wakeups[0], "init: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "init: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] == wakeups[2], "init: Wakeups[2] hit" ); CYG_TEST_CHECK( prewups[3] == wakeups[3], "init: Wakeups[3] hit" ); CYG_TEST_CHECK( prewups[4] == wakeups[4], "init: Wakeups[4] hit" ); // -------- TIMERS AND TIMESLICING DISABLED --------- // install an isr that will wake them all up in turn attach_isr( isr_wup_tsk ); DELAY(); detach_isr( isr_wup_tsk ); // -------- timers and timeslicing ENABLED --------- CYG_TEST_CHECK( 0 == wakeups[0], "iwup_tsk: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "iwup_tsk: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] < wakeups[2], "iwup_tsk: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] < wakeups[3], "iwup_tsk: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] < wakeups[4], "iwup_tsk: Wakeups[4] not hit" ); diag_printf( "INFO:<(fg loops %10d) thread wakeups : %2d %2d %2d >\n", count, wakeups[2] - prewups[2], wakeups[3] - prewups[3], wakeups[4] - prewups[4] ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // -------- TIMERS AND TIMESLICING DISABLED --------- // install an isr that will wake them all up in turn attach_isr( isr_ret_wup ); DELAY(); detach_isr( isr_ret_wup ); // -------- timers and timeslicing ENABLED --------- CYG_TEST_CHECK( 0 == wakeups[0], "ret_wup: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "ret_wup: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] < wakeups[2], "ret_wup: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] < wakeups[3], "ret_wup: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] < wakeups[4], "ret_wup: Wakeups[4] not hit" ); diag_printf( "INFO:<(fg loops %10d) thread ret_wups: %2d %2d %2d >\n", count, wakeups[2] - prewups[2], wakeups[3] - prewups[3], wakeups[4] - prewups[4] ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // move them on to waiting for a semaphore intercom = SEM; ercd = wup_tsk( 2 ); CYG_TEST_CHECK( E_OK == ercd, "wup_tsk(2) bad ercd" ); ercd = wup_tsk( 3 ); CYG_TEST_CHECK( E_OK == ercd, "wup_tsk(3) bad ercd" ); ercd = wup_tsk( 4 ); CYG_TEST_CHECK( E_OK == ercd, "wup_tsk(4) bad ercd" ); CYG_TEST_CHECK( 0 == wakeups[0], "wup_tsk: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "wup_tsk: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] + 1 == wakeups[2], "wup_tsk: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] + 1 == wakeups[3], "wup_tsk: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] + 1 == wakeups[4], "wup_tsk: Wakeups[4] not hit" ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // -------- TIMERS AND TIMESLICING DISABLED --------- // install an isr that will wake them all up in turn attach_isr( isr_sig_sem ); DELAY(); detach_isr( isr_sig_sem ); // -------- timers and timeslicing ENABLED --------- CYG_TEST_CHECK( 0 == wakeups[0], "isig_sem: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "isig_sem: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] < wakeups[2], "isig_sem: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] < wakeups[3], "isig_sem: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] < wakeups[4], "isig_sem: Wakeups[4] not hit" ); diag_printf( "INFO:<(fg loops %10d) semaphore waits: %2d %2d %2d >\n", count, wakeups[2] - prewups[2], wakeups[3] - prewups[3], wakeups[4] - prewups[4] ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // move them on to waiting for a flag intercom = FLG; ercd = sig_sem( 1 ); CYG_TEST_CHECK( E_OK == ercd, "sig_sem(1) bad ercd" ); ercd = sig_sem( 2 ); CYG_TEST_CHECK( E_OK == ercd, "sig_sem(2) bad ercd" ); ercd = sig_sem( 3 ); CYG_TEST_CHECK( E_OK == ercd, "sig_sem(3) bad ercd" ); CYG_TEST_CHECK( 0 == wakeups[0], "sig_sem: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "sig_sem: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] + 1 == wakeups[2], "sig_sem: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] + 1 == wakeups[3], "sig_sem: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] + 1 == wakeups[4], "sig_sem: Wakeups[4] not hit" ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // -------- TIMERS AND TIMESLICING DISABLED --------- // install an isr that will wake them all up in turn attach_isr( isr_set_flg ); DELAY(); detach_isr( isr_set_flg ); // -------- timers and timeslicing ENABLED --------- CYG_TEST_CHECK( 0 == wakeups[0], "iset_flg: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "iset_flg: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] < wakeups[2], "iset_flg: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] < wakeups[3], "iset_flg: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] < wakeups[4], "iset_flg: Wakeups[4] not hit" ); diag_printf( "INFO:<(fg loops %10d) flag waits/sets: %2d %2d %2d >\n", count, wakeups[2] - prewups[2], wakeups[3] - prewups[3], wakeups[4] - prewups[4] ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // move them on to waiting for a message box intercom = MBX; ercd = set_flg( 2, 0xfff ); CYG_TEST_CHECK( E_OK == ercd, "set_flg(2) bad ercd" ); ercd = set_flg( 3, 0xfff ); CYG_TEST_CHECK( E_OK == ercd, "set_flg(3) bad ercd" ); ercd = set_flg( 4, 0xfff ); CYG_TEST_CHECK( E_OK == ercd, "set_flg(4) bad ercd" ); CYG_TEST_CHECK( 0 == wakeups[0], "set_flg: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "set_flg: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] + 1 == wakeups[2], "set_flg: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] + 1 == wakeups[3], "set_flg: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] + 1 == wakeups[4], "set_flg: Wakeups[4] not hit" ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // -------- TIMERS AND TIMESLICING DISABLED --------- // install an isr that will wake them all up in turn attach_isr( isr_snd_msg ); DELAY(); detach_isr( isr_snd_msg ); // -------- timers and timeslicing ENABLED --------- CYG_TEST_CHECK( 0 == wakeups[0], "isnd_msg: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "isnd_msg: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] < wakeups[2], "isnd_msg: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] < wakeups[3], "isnd_msg: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] < wakeups[4], "isnd_msg: Wakeups[4] not hit" ); diag_printf( "INFO:<(fg loops %10d) message rec'pts: %2d %2d %2d >\n", count, wakeups[2] - prewups[2], wakeups[3] - prewups[3], wakeups[4] - prewups[4] ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; // move them on to exiting, all done if ( 1 == loops ) // then we are about to exit intercom = EXIT; else intercom = SLP; ercd = snd_msg( 2, (T_MSG *)&intercom ); CYG_TEST_CHECK( E_OK == ercd, "snd_msg(2) bad ercd" ); ercd = snd_msg( 3, (T_MSG *)&intercom ); CYG_TEST_CHECK( E_OK == ercd, "snd_msg(3) bad ercd" ); ercd = snd_msg( 4, (T_MSG *)&intercom ); CYG_TEST_CHECK( E_OK == ercd, "snd_msg(4) bad ercd" ); CYG_TEST_CHECK( 0 == wakeups[0], "snd_msg: Wakeups[0] hit" ); CYG_TEST_CHECK( 0 == wakeups[1], "snd_msg: Wakeups[1] hit" ); CYG_TEST_CHECK( prewups[2] + 1 == wakeups[2], "snd_msg: Wakeups[2] not hit" ); CYG_TEST_CHECK( prewups[3] + 1 == wakeups[3], "snd_msg: Wakeups[3] not hit" ); CYG_TEST_CHECK( prewups[4] + 1 == wakeups[4], "snd_msg: Wakeups[4] not hit" ); prewups[2] = wakeups[2]; prewups[3] = wakeups[3]; prewups[4] = wakeups[4]; CYG_TEST_PASS( "Tested ISR invoked uITRON functions" ); } while ( 0 < --loops ); CYG_TEST_EXIT( "All done" ); ext_tsk(); } void body( int n ) { unsigned int z; ER ercd; T_MSG *pk_msg; do { switch ( intercom ) { case NOTHING: ercd = slp_tsk(); CYG_TEST_CHECK( E_OK == ercd, "slp_tsk (doing nothing)" ); continue; case SLP: ercd = slp_tsk(); CYG_TEST_CHECK( E_OK == ercd, "slp_tsk bad ercd" ); wakeups[ n ]++; break; case SEM: ercd = wai_sem( n-1 ); // 1..3 for semas CYG_TEST_CHECK( E_OK == ercd, "wai_sem bad ercd" ); wakeups[ n ]++; break; case FLG: ercd = wai_flg( &z, n, (1<<n), TWF_CLR | TWF_ANDW ); CYG_TEST_CHECK( E_OK == ercd, "wai_flg bad ercd" ); CYG_TEST_CHECK( z & (1<<n), "Flag bit not set" ); wakeups[ n ]++; break; case MBX: ercd = rcv_msg( &pk_msg, n ); CYG_TEST_CHECK( E_OK == ercd, "rcv_msg bad ercd" ); CYG_TEST_CHECK( pk_msg, "rcv_msg NULL msg" ); wakeups[ n ]++; break; case EXIT: return; } } while ( 1 ); } void task2( unsigned int arg ) { ER ercd; CYG_TEST_INFO( "Task 2 running" ); ercd = get_tid( &scratch ); CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); CYG_TEST_CHECK( 2 == scratch, "tid not 2" ); if ( 222 != arg ) CYG_TEST_FAIL( "Task 2 arg not 222" ); body(2); CYG_TEST_INFO( "Task 2 exiting" ); ext_tsk(); CYG_TEST_FAIL( "Task 2 failed to exit" ); } void task3( unsigned int arg ) { ER ercd; CYG_TEST_INFO("Task 3 running"); ercd = get_tid( &scratch ); CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); CYG_TEST_CHECK( 3 == scratch, "tid not 3" ); if ( 333 != arg ) CYG_TEST_FAIL( "Task 3 arg not 333" ); body(3); CYG_TEST_INFO( "Task 3 exiting" ); ext_tsk(); CYG_TEST_FAIL( "Task 3 failed to exit" ); } void task4( unsigned int arg ) { ER ercd; CYG_TEST_INFO("Task 4 running"); ercd = get_tid( &scratch ); CYG_TEST_CHECK( E_OK == ercd, "get_tid bad ercd" ); CYG_TEST_CHECK( 4 == scratch, "tid not 4" ); if ( 444 != arg ) CYG_TEST_FAIL( "Task 4 arg not 444" ); body(4); CYG_TEST_INFO( "Task 4 exiting" ); ext_tsk(); CYG_TEST_FAIL( "Task 4 failed to exit" ); } // ------------------------------------------------------------------------ // Start of C++ aware portion, so to speak. // #include <cyg/hal/hal_intr.h> #include <cyg/kernel/intr.hxx> #include <cyg/kernel/clock.hxx> #include <cyg/kernel/sched.hxx> #include <cyg/kernel/sched.inl> void set_interrupt_number( void ) { clock_interrupt = CYGNUM_HAL_INTERRUPT_RTC; } // This snippet stolen from kernel/.../clock.cxx to be able to detach // the RTC from its interrupt source. class Cyg_RealTimeClock : public Cyg_Clock { public: Cyg_Interrupt interrupt; static cyg_uint32 isr(cyg_vector vector, CYG_ADDRWORD data); static void dsr(cyg_vector vector, cyg_ucount32 count, CYG_ADDRWORD data); Cyg_RealTimeClock(); }; static Cyg_Interrupt uit_intr( (unsigned)CYGNUM_HAL_INTERRUPT_RTC, // Vector to attach to 0, // Queue priority (unsigned)0, // Data pointer &isr_wup_tsk, // Interrupt Service Routine &cyg_uitron_dsr // Deferred Service Routine ); void attach_isr( unsigned int (*isr)(unsigned int, unsigned int) ) { int inuse; int old_ints; Cyg_RealTimeClock *prtc = (Cyg_RealTimeClock *)Cyg_Clock::real_time_clock; HAL_DISABLE_INTERRUPTS(old_ints); HAL_INTERRUPT_MASK( CYGNUM_HAL_INTERRUPT_RTC ); prtc->interrupt.detach(); #ifndef CYGIMP_KERNEL_INTERRUPTS_CHAIN // Only check that the vector was cleared when there's a specific // vector for the RTC. In chain mode, other interrupt handlers // may prevent the shared vector from being cleared when detaching // the RTC ISR, and this assertion fails. HAL_INTERRUPT_IN_USE( CYGNUM_HAL_INTERRUPT_RTC, inuse ); CYG_TEST_CHECK( !inuse, "Failed to detach clock ISR" ); #endif uit_intr = Cyg_Interrupt( CYGNUM_HAL_INTERRUPT_RTC, // Vector to attach to 1, // Queue priority 0, // Data pointer isr, // Interrupt Service Routine cyg_uitron_dsr // Deferred Service Routine ); uit_intr.attach(); HAL_INTERRUPT_IN_USE( CYGNUM_HAL_INTERRUPT_RTC, inuse ); CYG_TEST_CHECK( inuse, "Failed to attach new ISR" ); ACK_CLOCK(); HAL_INTERRUPT_UNMASK( CYGNUM_HAL_INTERRUPT_RTC ); HAL_RESTORE_INTERRUPTS(old_ints); } void detach_isr( unsigned int (*isr)(unsigned int, unsigned int) ) { int inuse; int old_ints; Cyg_RealTimeClock *prtc = (Cyg_RealTimeClock *)Cyg_Clock::real_time_clock; HAL_DISABLE_INTERRUPTS(old_ints); HAL_INTERRUPT_MASK( CYGNUM_HAL_INTERRUPT_RTC ); uit_intr.detach(); #ifndef CYGIMP_KERNEL_INTERRUPTS_CHAIN // See comment above in attach_isr. HAL_INTERRUPT_IN_USE( CYGNUM_HAL_INTERRUPT_RTC, inuse ); CYG_TEST_CHECK( !inuse, "Failed to detach my ISR" ); #endif prtc->interrupt.attach(); HAL_INTERRUPT_IN_USE( CYGNUM_HAL_INTERRUPT_RTC, inuse ); CYG_TEST_CHECK( inuse, "Failed to attach clock ISR" ); ACK_CLOCK(); HAL_INTERRUPT_UNMASK( CYGNUM_HAL_INTERRUPT_RTC ); HAL_RESTORE_INTERRUPTS(old_ints); } void lock_sched( void ) { cyg_uint32 l; Cyg_Scheduler::lock(); l = Cyg_Scheduler::get_sched_lock(); CYG_TEST_CHECK( 0 < l, "lock: Sched not locked" ); CYG_TEST_CHECK( 2 > l, "lock: Sched already locked" ); } void unlock_sched( void ) { cyg_uint32 l; l = Cyg_Scheduler::get_sched_lock(); CYG_TEST_CHECK( 0 < l, "unlock: Sched not locked" ); CYG_TEST_CHECK( 2 > l, "unlock: Sched already locked" ); Cyg_Scheduler::unlock(); } #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 testintr.c
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