/* SPDX-License-Identifier: BSD-2-Clause */
/**
* @file
*
* @ingroup RTEMSTestCaseRtemsSignalReqCatch
*/
/*
* Copyright (C) 2021 embedded brains GmbH (http://www.embedded-brains.de)
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* This file is part of the RTEMS quality process and was automatically
* generated. If you find something that needs to be fixed or
* worded better please post a report or patch to an RTEMS mailing list
* or raise a bug report:
*
* https://www.rtems.org/bugs.html
*
* For information on updating and regenerating please refer to the How-To
* section in the Software Requirements Engineering chapter of the
* RTEMS Software Engineering manual. The manual is provided as a part of
* a release. For development sources please refer to the online
* documentation at:
*
* https://docs.rtems.org
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <rtems.h>
#include <string.h>
#include <rtems/score/smpbarrier.h>
#include "tx-support.h"
#include <rtems/test.h>
/**
* @defgroup RTEMSTestCaseRtemsSignalReqCatch spec:/rtems/signal/req/catch
*
* @ingroup RTEMSTestSuiteTestsuitesValidation0
* @ingroup RTEMSTestSuiteTestsuitesValidation1
*
* @{
*/
typedef enum {
RtemsSignalReqCatch_Pre_Pending_Yes,
RtemsSignalReqCatch_Pre_Pending_No,
RtemsSignalReqCatch_Pre_Pending_NA
} RtemsSignalReqCatch_Pre_Pending;
typedef enum {
RtemsSignalReqCatch_Pre_Handler_Invalid,
RtemsSignalReqCatch_Pre_Handler_Valid,
RtemsSignalReqCatch_Pre_Handler_NA
} RtemsSignalReqCatch_Pre_Handler;
typedef enum {
RtemsSignalReqCatch_Pre_Preempt_Yes,
RtemsSignalReqCatch_Pre_Preempt_No,
RtemsSignalReqCatch_Pre_Preempt_NA
} RtemsSignalReqCatch_Pre_Preempt;
typedef enum {
RtemsSignalReqCatch_Pre_Timeslice_Yes,
RtemsSignalReqCatch_Pre_Timeslice_No,
RtemsSignalReqCatch_Pre_Timeslice_NA
} RtemsSignalReqCatch_Pre_Timeslice;
typedef enum {
RtemsSignalReqCatch_Pre_ASR_Yes,
RtemsSignalReqCatch_Pre_ASR_No,
RtemsSignalReqCatch_Pre_ASR_NA
} RtemsSignalReqCatch_Pre_ASR;
typedef enum {
RtemsSignalReqCatch_Pre_IntLvl_Zero,
RtemsSignalReqCatch_Pre_IntLvl_Positive,
RtemsSignalReqCatch_Pre_IntLvl_NA
} RtemsSignalReqCatch_Pre_IntLvl;
typedef enum {
RtemsSignalReqCatch_Post_Status_Ok,
RtemsSignalReqCatch_Post_Status_NotImplIntLvl,
RtemsSignalReqCatch_Post_Status_NotImplIntLvlSMP,
RtemsSignalReqCatch_Post_Status_NotImplNoPreempt,
RtemsSignalReqCatch_Post_Status_NA
} RtemsSignalReqCatch_Post_Status;
typedef enum {
RtemsSignalReqCatch_Post_ASRInfo_NopIntLvl,
RtemsSignalReqCatch_Post_ASRInfo_NopIntLvlSMP,
RtemsSignalReqCatch_Post_ASRInfo_NopNoPreempt,
RtemsSignalReqCatch_Post_ASRInfo_New,
RtemsSignalReqCatch_Post_ASRInfo_Inactive,
RtemsSignalReqCatch_Post_ASRInfo_NA
} RtemsSignalReqCatch_Post_ASRInfo;
/**
* @brief Test context for spec:/rtems/signal/req/catch test case.
*/
typedef struct {
/**
* @brief This member contains the object identifier of the runner task.
*/
rtems_id runner_id;
/**
* @brief This member contains the object identifier of the worker task.
*/
rtems_id worker_id;
/**
* @brief null If this member is non-zero, then rtems_signal_catch() is
* called with pending signals, otherwise it is called with no pending
* signals.
*/
uint32_t pending_signals;
/**
* @brief This member provides a barrier to synchronize the runner and worker
* tasks.
*/
SMP_barrier_Control barrier;
/**
* @brief This member is used for barrier operations done by the runner task.
*/
SMP_barrier_State runner_barrier_state;
/**
* @brief When the default handler is called, this member is incremented.
*/
uint32_t default_handler_calls;
/**
* @brief When the handler is called, this member is incremented.
*/
uint32_t handler_calls;
/**
* @brief This member contains the mode observed in the last handler call.
*/
rtems_mode handler_mode;
/**
* @brief This member specifies the normal task mode for the action.
*/
rtems_mode normal_mode;
/**
* @brief This member specifies the handler for the action.
*/
rtems_asr_entry handler;
/**
* @brief This member specifies the task mode for the action.
*/
rtems_mode mode;
/**
* @brief This member contains the return status of the rtems_signal_catch()
* call of the action.
*/
rtems_status_code catch_status;
/**
* @brief This member contains the return status of the rtems_signal_send()
* call of the action.
*/
rtems_status_code send_status;
/**
* @brief This member defines the pre-condition states for the next action.
*/
size_t pcs[ 6 ];
/**
* @brief This member indicates if the test action loop is currently
* executed.
*/
bool in_action_loop;
} RtemsSignalReqCatch_Context;
static RtemsSignalReqCatch_Context
RtemsSignalReqCatch_Instance;
static const char * const RtemsSignalReqCatch_PreDesc_Pending[] = {
"Yes",
"No",
"NA"
};
static const char * const RtemsSignalReqCatch_PreDesc_Handler[] = {
"Invalid",
"Valid",
"NA"
};
static const char * const RtemsSignalReqCatch_PreDesc_Preempt[] = {
"Yes",
"No",
"NA"
};
static const char * const RtemsSignalReqCatch_PreDesc_Timeslice[] = {
"Yes",
"No",
"NA"
};
static const char * const RtemsSignalReqCatch_PreDesc_ASR[] = {
"Yes",
"No",
"NA"
};
static const char * const RtemsSignalReqCatch_PreDesc_IntLvl[] = {
"Zero",
"Positive",
"NA"
};
static const char * const * const RtemsSignalReqCatch_PreDesc[] = {
RtemsSignalReqCatch_PreDesc_Pending,
RtemsSignalReqCatch_PreDesc_Handler,
RtemsSignalReqCatch_PreDesc_Preempt,
RtemsSignalReqCatch_PreDesc_Timeslice,
RtemsSignalReqCatch_PreDesc_ASR,
RtemsSignalReqCatch_PreDesc_IntLvl,
NULL
};
typedef RtemsSignalReqCatch_Context Context;
static void DefaultHandler( rtems_signal_set signal_set )
{
Context *ctx;
ctx = T_fixture_context();
++ctx->default_handler_calls;
if ( ctx->pending_signals != 0 && ctx->default_handler_calls == 1 ) {
T_eq_u32( signal_set, 0x600df00d );
} else {
T_eq_u32( signal_set, 0xdeadbeef );
}
}
static void SignalHandler( rtems_signal_set signal_set )
{
Context *ctx;
rtems_status_code sc;
ctx = T_fixture_context();
++ctx->handler_calls;
sc = rtems_task_mode(
RTEMS_DEFAULT_MODES,
RTEMS_CURRENT_MODE,
&ctx->handler_mode
);
T_rsc_success( sc );
if ( ctx->pending_signals != 0 && ctx->handler_calls == 1 ) {
T_eq_u32( signal_set, 0x600df00d );
} else {
T_eq_u32( signal_set, 0xdeadbeef );
}
}
static void CheckNoASRChange( Context *ctx )
{
T_rsc_success( ctx->send_status );
T_eq_u32( ctx->default_handler_calls, 1 + ctx->pending_signals );
T_eq_u32( ctx->handler_calls, 0 );
T_eq_u32( ctx->handler_mode, 0xffffffff );
}
static void CheckNewASRSettings( Context *ctx )
{
T_rsc_success( ctx->send_status );
T_eq_u32( ctx->default_handler_calls, 0 );
T_eq_u32( ctx->handler_calls, 1 + ctx->pending_signals );
T_eq_u32( ctx->handler_mode, ctx->mode );
}
static void Worker( rtems_task_argument arg )
{
Context *ctx;
SMP_barrier_State barrier_state;
ctx = (Context *) arg;
_SMP_barrier_State_initialize( &barrier_state );
while ( true ) {
rtems_status_code sc;
_SMP_barrier_Wait( &ctx->barrier, &barrier_state, 2 );
sc = rtems_signal_send( ctx->runner_id, 0x600df00d );
T_rsc_success( sc );
_SMP_barrier_Wait( &ctx->barrier, &barrier_state, 2 );
}
}
static void RtemsSignalReqCatch_Pre_Pending_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_Pending state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_Pending_Yes: {
/*
* Where the system has more than one processor, while the calling task
* has pending signals.
*
* Where the system has exactly one processor, while the calling task has
* no pending signals.
*/
if ( rtems_scheduler_get_processor_maximum() > 1 ) {
ctx->pending_signals = 1;
} else {
ctx->pending_signals = 0;
}
break;
}
case RtemsSignalReqCatch_Pre_Pending_No: {
/*
* While the calling task has no pending signals.
*/
ctx->pending_signals = 0;
break;
}
case RtemsSignalReqCatch_Pre_Pending_NA:
break;
}
}
static void RtemsSignalReqCatch_Pre_Handler_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_Handler state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_Handler_Invalid: {
/*
* While the ``asr_handler`` parameter is NULL.
*/
ctx->handler = NULL;
break;
}
case RtemsSignalReqCatch_Pre_Handler_Valid: {
/*
* While the ``asr_handler`` parameter is a valid ASR handler.
*/
ctx->handler = SignalHandler;
break;
}
case RtemsSignalReqCatch_Pre_Handler_NA:
break;
}
}
static void RtemsSignalReqCatch_Pre_Preempt_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_Preempt state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_Preempt_Yes: {
/*
* While the ``mode_set`` parameter specifies that preemption is enabled.
*/
if ( rtems_configuration_get_maximum_processors() == 1 ) {
ctx->normal_mode |= RTEMS_NO_PREEMPT;
}
break;
}
case RtemsSignalReqCatch_Pre_Preempt_No: {
/*
* While the ``mode_set`` parameter specifies that preemption is
* disabled.
*/
ctx->mode |= RTEMS_NO_PREEMPT;
break;
}
case RtemsSignalReqCatch_Pre_Preempt_NA:
break;
}
}
static void RtemsSignalReqCatch_Pre_Timeslice_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_Timeslice state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_Timeslice_Yes: {
/*
* While the ``mode_set`` parameter specifies that timeslicing is
* enabled.
*/
ctx->mode |= RTEMS_TIMESLICE;
break;
}
case RtemsSignalReqCatch_Pre_Timeslice_No: {
/*
* While the ``mode_set`` parameter specifies that timeslicing is
* disabled.
*/
ctx->normal_mode |= RTEMS_TIMESLICE;
break;
}
case RtemsSignalReqCatch_Pre_Timeslice_NA:
break;
}
}
static void RtemsSignalReqCatch_Pre_ASR_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_ASR state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_ASR_Yes: {
/*
* While the ``mode_set`` parameter specifies that ASR processing is
* enabled.
*/
/*
* We cannot disable ASR processing at normal task level for this state.
*/
break;
}
case RtemsSignalReqCatch_Pre_ASR_No: {
/*
* While the ``mode_set`` parameter specifies that ASR processing is
* disabled.
*/
ctx->mode |= RTEMS_NO_ASR;
break;
}
case RtemsSignalReqCatch_Pre_ASR_NA:
break;
}
}
static void RtemsSignalReqCatch_Pre_IntLvl_Prepare(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Pre_IntLvl state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Pre_IntLvl_Zero: {
/*
* While the ``mode_set`` parameter specifies an interrupt level of zero.
*/
#if CPU_ENABLE_ROBUST_THREAD_DISPATCH == FALSE && !defined(RTEMS_SMP)
ctx->normal_mode |= RTEMS_INTERRUPT_LEVEL( 1 );
#endif
break;
}
case RtemsSignalReqCatch_Pre_IntLvl_Positive: {
/*
* While the ``mode_set`` parameter specifies an interrupt level greater
* than or equal to one and less than or equal to
* CPU_MODES_INTERRUPT_MASK.
*/
ctx->mode |= RTEMS_INTERRUPT_LEVEL( 1 );
break;
}
case RtemsSignalReqCatch_Pre_IntLvl_NA:
break;
}
}
static void RtemsSignalReqCatch_Post_Status_Check(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Post_Status state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Post_Status_Ok: {
/*
* The return status of rtems_signal_catch() shall be RTEMS_SUCCESSFUL.
*/
T_rsc_success( ctx->catch_status );
break;
}
case RtemsSignalReqCatch_Post_Status_NotImplIntLvl: {
/*
* The return status of rtems_signal_catch() shall be
* RTEMS_NOT_IMPLEMENTED.
*/
T_rsc( ctx->catch_status, RTEMS_NOT_IMPLEMENTED );
break;
}
case RtemsSignalReqCatch_Post_Status_NotImplIntLvlSMP: {
/*
* Where the system needs inter-processor interrupts, the return status
* of rtems_signal_catch() shall be RTEMS_NOT_IMPLEMENTED.
*
* Where the system does not need inter-processor interrupts, the return
* status of rtems_signal_catch() shall be RTEMS_SUCCESSFUL.
*/
if ( rtems_configuration_get_maximum_processors() > 1 ) {
T_rsc( ctx->catch_status, RTEMS_NOT_IMPLEMENTED );
} else {
T_rsc_success( ctx->catch_status );
}
break;
}
case RtemsSignalReqCatch_Post_Status_NotImplNoPreempt: {
/*
* Where the scheduler does not support the no-preempt mode, the return
* status of rtems_signal_catch() shall be RTEMS_NOT_IMPLEMENTED.
*
* Where the scheduler does support the no-preempt mode, the return
* status of rtems_signal_catch() shall be RTEMS_SUCCESSFUL.
*/
if ( rtems_configuration_get_maximum_processors() > 1 ) {
T_rsc( ctx->catch_status, RTEMS_NOT_IMPLEMENTED );
} else {
T_rsc_success( ctx->catch_status );
}
break;
}
case RtemsSignalReqCatch_Post_Status_NA:
break;
}
}
static void RtemsSignalReqCatch_Post_ASRInfo_Check(
RtemsSignalReqCatch_Context *ctx,
RtemsSignalReqCatch_Post_ASRInfo state
)
{
switch ( state ) {
case RtemsSignalReqCatch_Post_ASRInfo_NopIntLvl: {
/*
* The ASR information of the caller of rtems_signal_catch() shall not be
* changed by the rtems_signal_catch() call.
*/
CheckNoASRChange( ctx );
break;
}
case RtemsSignalReqCatch_Post_ASRInfo_NopIntLvlSMP: {
/*
* Where the system needs inter-processor interrupts, the ASR information
* of the caller of rtems_signal_catch() shall not be changed by the
* rtems_signal_catch() call.
*
* Where the system does not need inter-processor interrupts, the ASR
* processing for the caller of rtems_signal_catch() shall be done using
* the handler specified by ``asr_handler`` in the mode specified by
* ``mode_set``.
*/
if ( rtems_configuration_get_maximum_processors() > 1 ) {
CheckNoASRChange( ctx );
} else {
CheckNewASRSettings( ctx );
}
break;
}
case RtemsSignalReqCatch_Post_ASRInfo_NopNoPreempt: {
/*
* Where the scheduler does not support the no-preempt mode, the ASR
* information of the caller of rtems_signal_catch() shall not be changed
* by the rtems_signal_catch() call.
*
* Where the scheduler does support the no-preempt mode, the ASR
* processing for the caller of rtems_signal_catch() shall be done using
* the handler specified by ``asr_handler`` in the mode specified by
* ``mode_set``.
*/
if ( rtems_configuration_get_maximum_processors() > 1 ) {
CheckNoASRChange( ctx );
} else {
CheckNewASRSettings( ctx );
}
break;
}
case RtemsSignalReqCatch_Post_ASRInfo_New: {
/*
* The ASR processing for the caller of rtems_signal_catch() shall be
* done using the handler specified by ``asr_handler`` in the mode
* specified by ``mode_set``.
*/
CheckNewASRSettings( ctx );
break;
}
case RtemsSignalReqCatch_Post_ASRInfo_Inactive: {
/*
* The ASR processing for the caller of rtems_signal_catch() shall be
* deactivated.
*
* The pending signals of the caller of rtems_signal_catch() shall be
* cleared.
*/
T_rsc( ctx->send_status, RTEMS_NOT_DEFINED );
T_eq_u32( ctx->default_handler_calls, 0 );
T_eq_u32( ctx->handler_calls, 0 );
T_eq_u32( ctx->handler_mode, 0xffffffff );
break;
}
case RtemsSignalReqCatch_Post_ASRInfo_NA:
break;
}
}
static void RtemsSignalReqCatch_Setup( RtemsSignalReqCatch_Context *ctx )
{
memset( ctx, 0, sizeof( *ctx ) );
ctx->runner_id = rtems_task_self();
_SMP_barrier_Control_initialize( &ctx->barrier );
_SMP_barrier_State_initialize( &ctx->runner_barrier_state );
if ( rtems_scheduler_get_processor_maximum() > 1 ) {
rtems_status_code sc;
rtems_id scheduler_id;
ctx->worker_id = CreateTask( "WORK", 1 );
sc = rtems_scheduler_ident_by_processor( 1, &scheduler_id );
T_assert_rsc_success( sc );
sc = rtems_task_set_scheduler( ctx->worker_id, scheduler_id, 1 );
T_assert_rsc_success( sc );
StartTask( ctx->worker_id, Worker, ctx );
}
}
static void RtemsSignalReqCatch_Setup_Wrap( void *arg )
{
RtemsSignalReqCatch_Context *ctx;
ctx = arg;
ctx->in_action_loop = false;
RtemsSignalReqCatch_Setup( ctx );
}
static void RtemsSignalReqCatch_Teardown( RtemsSignalReqCatch_Context *ctx )
{
DeleteTask( ctx->worker_id );
RestoreRunnerASR();
}
static void RtemsSignalReqCatch_Teardown_Wrap( void *arg )
{
RtemsSignalReqCatch_Context *ctx;
ctx = arg;
ctx->in_action_loop = false;
RtemsSignalReqCatch_Teardown( ctx );
}
static void RtemsSignalReqCatch_Prepare( RtemsSignalReqCatch_Context *ctx )
{
rtems_status_code sc;
ctx->default_handler_calls = 0;
ctx->handler_calls = 0;
ctx->handler_mode = 0xffffffff;
ctx->normal_mode = RTEMS_DEFAULT_MODES;
ctx->handler = NULL;
ctx->mode = RTEMS_DEFAULT_MODES;
sc = rtems_signal_catch( DefaultHandler, RTEMS_NO_ASR );
T_rsc_success( sc );
}
static void RtemsSignalReqCatch_Action( RtemsSignalReqCatch_Context *ctx )
{
rtems_status_code sc;
rtems_mode mode;
if ( ctx->pending_signals != 0 ) {
rtems_interrupt_level level;
rtems_interrupt_local_disable(level);
_SMP_barrier_Wait( &ctx->barrier, &ctx->runner_barrier_state, 2 );
_SMP_barrier_Wait( &ctx->barrier, &ctx->runner_barrier_state, 2 );
ctx->catch_status = rtems_signal_catch( ctx->handler, ctx->mode );
rtems_interrupt_local_enable(level);
} else {
ctx->catch_status = rtems_signal_catch( ctx->handler, ctx->mode );
}
sc = rtems_task_mode( ctx->normal_mode, RTEMS_ALL_MODE_MASKS, &mode );
T_rsc_success( sc );
ctx->send_status = rtems_signal_send( RTEMS_SELF, 0xdeadbeef );
sc = rtems_task_mode( mode, RTEMS_ALL_MODE_MASKS, &mode );
T_rsc_success( sc );
}
typedef struct {
uint16_t Skip : 1;
uint16_t Pre_Pending_NA : 1;
uint16_t Pre_Handler_NA : 1;
uint16_t Pre_Preempt_NA : 1;
uint16_t Pre_Timeslice_NA : 1;
uint16_t Pre_ASR_NA : 1;
uint16_t Pre_IntLvl_NA : 1;
uint16_t Post_Status : 3;
uint16_t Post_ASRInfo : 3;
} RtemsSignalReqCatch_Entry;
static const RtemsSignalReqCatch_Entry
RtemsSignalReqCatch_Entries[] = {
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_Ok,
RtemsSignalReqCatch_Post_ASRInfo_Inactive },
#if CPU_ENABLE_ROBUST_THREAD_DISPATCH == TRUE
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_NotImplIntLvl,
RtemsSignalReqCatch_Post_ASRInfo_NopIntLvl },
#elif defined(RTEMS_SMP)
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_NotImplIntLvlSMP,
RtemsSignalReqCatch_Post_ASRInfo_NopIntLvlSMP },
#else
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_Ok,
RtemsSignalReqCatch_Post_ASRInfo_New },
#endif
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_Ok,
RtemsSignalReqCatch_Post_ASRInfo_New },
#if defined(RTEMS_SMP)
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_NotImplNoPreempt,
RtemsSignalReqCatch_Post_ASRInfo_NopNoPreempt }
#else
{ 0, 0, 0, 0, 0, 0, 0, RtemsSignalReqCatch_Post_Status_Ok,
RtemsSignalReqCatch_Post_ASRInfo_New }
#endif
};
static const uint8_t
RtemsSignalReqCatch_Map[] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 2, 1, 2, 1, 2, 1, 3, 1,
3, 1, 3, 1, 3, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 2, 1,
2, 1, 2, 1, 3, 1, 3, 1, 3, 1, 3, 1
};
static size_t RtemsSignalReqCatch_Scope( void *arg, char *buf, size_t n )
{
RtemsSignalReqCatch_Context *ctx;
ctx = arg;
if ( ctx->in_action_loop ) {
return T_get_scope( RtemsSignalReqCatch_PreDesc, buf, n, ctx->pcs );
}
return 0;
}
static T_fixture RtemsSignalReqCatch_Fixture = {
.setup = RtemsSignalReqCatch_Setup_Wrap,
.stop = NULL,
.teardown = RtemsSignalReqCatch_Teardown_Wrap,
.scope = RtemsSignalReqCatch_Scope,
.initial_context = &RtemsSignalReqCatch_Instance
};
static inline RtemsSignalReqCatch_Entry RtemsSignalReqCatch_GetEntry(
size_t index
)
{
return RtemsSignalReqCatch_Entries[
RtemsSignalReqCatch_Map[ index ]
];
}
/**
* @fn void T_case_body_RtemsSignalReqCatch( void )
*/
T_TEST_CASE_FIXTURE( RtemsSignalReqCatch, &RtemsSignalReqCatch_Fixture )
{
RtemsSignalReqCatch_Context *ctx;
size_t index;
ctx = T_fixture_context();
ctx->in_action_loop = true;
index = 0;
for (
ctx->pcs[ 0 ] = RtemsSignalReqCatch_Pre_Pending_Yes;
ctx->pcs[ 0 ] < RtemsSignalReqCatch_Pre_Pending_NA;
++ctx->pcs[ 0 ]
) {
for (
ctx->pcs[ 1 ] = RtemsSignalReqCatch_Pre_Handler_Invalid;
ctx->pcs[ 1 ] < RtemsSignalReqCatch_Pre_Handler_NA;
++ctx->pcs[ 1 ]
) {
for (
ctx->pcs[ 2 ] = RtemsSignalReqCatch_Pre_Preempt_Yes;
ctx->pcs[ 2 ] < RtemsSignalReqCatch_Pre_Preempt_NA;
++ctx->pcs[ 2 ]
) {
for (
ctx->pcs[ 3 ] = RtemsSignalReqCatch_Pre_Timeslice_Yes;
ctx->pcs[ 3 ] < RtemsSignalReqCatch_Pre_Timeslice_NA;
++ctx->pcs[ 3 ]
) {
for (
ctx->pcs[ 4 ] = RtemsSignalReqCatch_Pre_ASR_Yes;
ctx->pcs[ 4 ] < RtemsSignalReqCatch_Pre_ASR_NA;
++ctx->pcs[ 4 ]
) {
for (
ctx->pcs[ 5 ] = RtemsSignalReqCatch_Pre_IntLvl_Zero;
ctx->pcs[ 5 ] < RtemsSignalReqCatch_Pre_IntLvl_NA;
++ctx->pcs[ 5 ]
) {
RtemsSignalReqCatch_Entry entry;
entry = RtemsSignalReqCatch_GetEntry( index );
++index;
RtemsSignalReqCatch_Prepare( ctx );
RtemsSignalReqCatch_Pre_Pending_Prepare( ctx, ctx->pcs[ 0 ] );
RtemsSignalReqCatch_Pre_Handler_Prepare( ctx, ctx->pcs[ 1 ] );
RtemsSignalReqCatch_Pre_Preempt_Prepare( ctx, ctx->pcs[ 2 ] );
RtemsSignalReqCatch_Pre_Timeslice_Prepare( ctx, ctx->pcs[ 3 ] );
RtemsSignalReqCatch_Pre_ASR_Prepare( ctx, ctx->pcs[ 4 ] );
RtemsSignalReqCatch_Pre_IntLvl_Prepare( ctx, ctx->pcs[ 5 ] );
RtemsSignalReqCatch_Action( ctx );
RtemsSignalReqCatch_Post_Status_Check( ctx, entry.Post_Status );
RtemsSignalReqCatch_Post_ASRInfo_Check(
ctx,
entry.Post_ASRInfo
);
}
}
}
}
}
}
}
/** @} */