/* SPDX-License-Identifier: BSD-2-Clause */
/**
* @file
*
* @ingroup RTEMSTestCaseCReqClockNanosleep
*/
/*
* 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 <errno.h>
#include <limits.h>
#include <rtems.h>
#include <time.h>
#include <rtems/test-scheduler.h>
#include <rtems/score/timecounter.h>
#include "tx-support.h"
#include <rtems/test.h>
/**
* @defgroup RTEMSTestCaseCReqClockNanosleep spec:/c/req/clock-nanosleep
*
* @ingroup RTEMSTestSuiteTestsuitesValidationNoClock0
*
* @{
*/
typedef enum {
CReqClockNanosleep_Pre_ClockId_Monotonic,
CReqClockNanosleep_Pre_ClockId_Realtime,
CReqClockNanosleep_Pre_ClockId_Invalid,
CReqClockNanosleep_Pre_ClockId_NA
} CReqClockNanosleep_Pre_ClockId;
typedef enum {
CReqClockNanosleep_Pre_Abstime_Yes,
CReqClockNanosleep_Pre_Abstime_No,
CReqClockNanosleep_Pre_Abstime_NA
} CReqClockNanosleep_Pre_Abstime;
typedef enum {
CReqClockNanosleep_Pre_RQTp_Valid,
CReqClockNanosleep_Pre_RQTp_Null,
CReqClockNanosleep_Pre_RQTp_NA
} CReqClockNanosleep_Pre_RQTp;
typedef enum {
CReqClockNanosleep_Pre_RQTpNSec_Valid,
CReqClockNanosleep_Pre_RQTpNSec_Invalid,
CReqClockNanosleep_Pre_RQTpNSec_NA
} CReqClockNanosleep_Pre_RQTpNSec;
typedef enum {
CReqClockNanosleep_Pre_RQTpSec_Negative,
CReqClockNanosleep_Pre_RQTpSec_FarFuture,
CReqClockNanosleep_Pre_RQTpSec_Future,
CReqClockNanosleep_Pre_RQTpSec_PastOrNow,
CReqClockNanosleep_Pre_RQTpSec_NA
} CReqClockNanosleep_Pre_RQTpSec;
typedef enum {
CReqClockNanosleep_Pre_RMTp_Valid,
CReqClockNanosleep_Pre_RMTp_Null,
CReqClockNanosleep_Pre_RMTp_NA
} CReqClockNanosleep_Pre_RMTp;
typedef enum {
CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Status_ENOTSUP,
CReqClockNanosleep_Post_Status_EINVAL,
CReqClockNanosleep_Post_Status_NA
} CReqClockNanosleep_Post_Status;
typedef enum {
CReqClockNanosleep_Post_Timer_Inactive,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Timer_NA
} CReqClockNanosleep_Post_Timer;
typedef enum {
CReqClockNanosleep_Post_Expire_Last,
CReqClockNanosleep_Post_Expire_Absolute,
CReqClockNanosleep_Post_Expire_Relative,
CReqClockNanosleep_Post_Expire_NA
} CReqClockNanosleep_Post_Expire;
typedef enum {
CReqClockNanosleep_Post_Scheduler_Block,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_Scheduler_Nop,
CReqClockNanosleep_Post_Scheduler_NA
} CReqClockNanosleep_Post_Scheduler;
typedef enum {
CReqClockNanosleep_Post_RMTp_Zero,
CReqClockNanosleep_Post_RMTp_Nop,
CReqClockNanosleep_Post_RMTp_NA
} CReqClockNanosleep_Post_RMTp;
typedef struct {
uint32_t Skip : 1;
uint32_t Pre_ClockId_NA : 1;
uint32_t Pre_Abstime_NA : 1;
uint32_t Pre_RQTp_NA : 1;
uint32_t Pre_RQTpNSec_NA : 1;
uint32_t Pre_RQTpSec_NA : 1;
uint32_t Pre_RMTp_NA : 1;
uint32_t Post_Status : 2;
uint32_t Post_Timer : 2;
uint32_t Post_Expire : 2;
uint32_t Post_Scheduler : 2;
uint32_t Post_RMTp : 2;
} CReqClockNanosleep_Entry;
/**
* @brief Test context for spec:/c/req/clock-nanosleep test case.
*/
typedef struct {
/**
* @brief This member provides the scheduler operation records.
*/
T_scheduler_log_4 scheduler_log;;
/**
* @brief This member contains the CLOCK_REALTIME value before the
* clock_nanosleep() call.
*/
struct timespec now_realtime;;
/**
* @brief This member contains the CLOCK_MONOTONIC value before the
* clock_nanosleep() call.
*/
struct timespec now_monotonic;;
/**
* @brief This member contains the worker task identifier.
*/
rtems_id worker_id;;
/**
* @brief This member contains the timer information of the worker task.
*/
TaskTimerInfo timer_info;;
/**
* @brief This member provides the object referenced by the ``rqtp``
* parameter.
*/
struct timespec rqtp_obj;
/**
* @brief This member provides the object referenced by the ``rmtp``
* parameter.
*/
struct timespec rmtp_obj;
/**
* @brief This member contains the return value of the clock_nanosleep()
* call.
*/
int status;
/**
* @brief This member specifies the ``clock_id`` parameter value.
*/
clockid_t clock_id;
/**
* @brief This member specifies the ``flags`` parameter value.
*/
int flags;
/**
* @brief This member specifies the ``rqtp`` parameter value.
*/
const struct timespec *rqtp;
/**
* @brief This member specifies the ``rmtp`` parameter value.
*/
struct timespec *rmtp;
struct {
/**
* @brief This member defines the pre-condition indices for the next
* action.
*/
size_t pci[ 6 ];
/**
* @brief This member defines the pre-condition states for the next action.
*/
size_t pcs[ 6 ];
/**
* @brief If this member is true, then the test action loop is executed.
*/
bool in_action_loop;
/**
* @brief This member contains the next transition map index.
*/
size_t index;
/**
* @brief This member contains the current transition map entry.
*/
CReqClockNanosleep_Entry entry;
/**
* @brief If this member is true, then the current transition variant
* should be skipped.
*/
bool skip;
} Map;
} CReqClockNanosleep_Context;
static CReqClockNanosleep_Context
CReqClockNanosleep_Instance;
static const char * const CReqClockNanosleep_PreDesc_ClockId[] = {
"Monotonic",
"Realtime",
"Invalid",
"NA"
};
static const char * const CReqClockNanosleep_PreDesc_Abstime[] = {
"Yes",
"No",
"NA"
};
static const char * const CReqClockNanosleep_PreDesc_RQTp[] = {
"Valid",
"Null",
"NA"
};
static const char * const CReqClockNanosleep_PreDesc_RQTpNSec[] = {
"Valid",
"Invalid",
"NA"
};
static const char * const CReqClockNanosleep_PreDesc_RQTpSec[] = {
"Negative",
"FarFuture",
"Future",
"PastOrNow",
"NA"
};
static const char * const CReqClockNanosleep_PreDesc_RMTp[] = {
"Valid",
"Null",
"NA"
};
static const char * const * const CReqClockNanosleep_PreDesc[] = {
CReqClockNanosleep_PreDesc_ClockId,
CReqClockNanosleep_PreDesc_Abstime,
CReqClockNanosleep_PreDesc_RQTp,
CReqClockNanosleep_PreDesc_RQTpNSec,
CReqClockNanosleep_PreDesc_RQTpSec,
CReqClockNanosleep_PreDesc_RMTp,
NULL
};
typedef CReqClockNanosleep_Context Context;
static void Worker( rtems_task_argument arg )
{
Context *ctx;
ctx = (Context *) arg;
while ( true ) {
T_scheduler_log *log;
SuspendSelf();
log = T_scheduler_record_4( &ctx->scheduler_log );
T_null( log );
_Timecounter_Getnanotime( &ctx->now_realtime );
_Timecounter_Getnanouptime( &ctx->now_monotonic );
ctx->status = clock_nanosleep(
ctx->clock_id,
ctx->flags,
ctx->rqtp,
ctx->rmtp
);
(void) T_scheduler_record( NULL );
}
}
static void CReqClockNanosleep_Pre_ClockId_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_ClockId state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_ClockId_Monotonic: {
/*
* While the ``clock_id`` parameter is equal to CLOCK_MONOTONIC.
*/
ctx->clock_id = CLOCK_MONOTONIC;
break;
}
case CReqClockNanosleep_Pre_ClockId_Realtime: {
/*
* While the ``clock_id`` parameter is equal to CLOCK_REALTIME.
*/
ctx->clock_id = CLOCK_REALTIME;
break;
}
case CReqClockNanosleep_Pre_ClockId_Invalid: {
/*
* While the ``clock_id`` parameter is an invalid clock identifier.
*/
ctx->clock_id = INT_MAX;
break;
}
case CReqClockNanosleep_Pre_ClockId_NA:
break;
}
}
static void CReqClockNanosleep_Pre_Abstime_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_Abstime state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_Abstime_Yes: {
/*
* While the ``flags`` parameter indicates an absolute time.
*/
ctx->flags |= TIMER_ABSTIME;
break;
}
case CReqClockNanosleep_Pre_Abstime_No: {
/*
* While the ``flags`` parameter does not indicate an absolute time.
*/
/* This is the default */
break;
}
case CReqClockNanosleep_Pre_Abstime_NA:
break;
}
}
static void CReqClockNanosleep_Pre_RQTp_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_RQTp state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_RQTp_Valid: {
/*
* While the ``rqtp`` parameter references an object of type struct
* timespec.
*/
ctx->rqtp = &ctx->rqtp_obj;
break;
}
case CReqClockNanosleep_Pre_RQTp_Null: {
/*
* While the ``rqtp parameter is equal to NULL.
*/
ctx->rqtp = NULL;
break;
}
case CReqClockNanosleep_Pre_RQTp_NA:
break;
}
}
static void CReqClockNanosleep_Pre_RQTpNSec_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_RQTpNSec state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_RQTpNSec_Valid: {
/*
* While the ``tv_nsec`` member of the object referenced by the ``rqtp``
* parameter is a valid nanoseconds value.
*/
ctx->rqtp_obj.tv_nsec = 999999999;
break;
}
case CReqClockNanosleep_Pre_RQTpNSec_Invalid: {
/*
* While the ``tv_nsec`` member of the object referenced by the ``rqtp``
* parameter is an invalid nanoseconds value.
*/
ctx->rqtp_obj.tv_nsec = -1;
break;
}
case CReqClockNanosleep_Pre_RQTpNSec_NA:
break;
}
}
static void CReqClockNanosleep_Pre_RQTpSec_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_RQTpSec state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_RQTpSec_Negative: {
/*
* While the ``tv_sec`` member of the object referenced by the ``rqtp``
* parameter is negative.
*/
ctx->rqtp_obj.tv_sec = -238479;
break;
}
case CReqClockNanosleep_Pre_RQTpSec_FarFuture: {
/*
* While the ``tv_sec`` member of the object referenced by the ``rqtp``
* parameter specifies a time point which is past the implementation
* limit.
*/
ctx->rqtp_obj.tv_sec = INT64_MAX;
break;
}
case CReqClockNanosleep_Pre_RQTpSec_Future: {
/*
* While the ``tv_sec`` member of the object referenced by the ``rqtp``
* parameter specifies a time point which is after the current time of
* the clock specified by the ``clock_id`` parameter and is within the
* implementation limits.
*/
ctx->rqtp_obj.tv_sec = 1621322302;
break;
}
case CReqClockNanosleep_Pre_RQTpSec_PastOrNow: {
/*
* While the ``tv_sec`` member of the object referenced by the ``rqtp``
* parameter is non-negative and specifies a time point which is before
* or at the current time of the clock specified by the ``clock_id``
* parameter.
*/
ctx->rqtp_obj.tv_sec = 0;
if ( ctx->rqtp_obj.tv_nsec == 999999999 ) {
ctx->rqtp_obj.tv_nsec = 0;
}
break;
}
case CReqClockNanosleep_Pre_RQTpSec_NA:
break;
}
}
static void CReqClockNanosleep_Pre_RMTp_Prepare(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Pre_RMTp state
)
{
switch ( state ) {
case CReqClockNanosleep_Pre_RMTp_Valid: {
/*
* While the ``rmtp`` parameter references an object of type struct
* timespec.
*/
ctx->rmtp = &ctx->rmtp_obj;
break;
}
case CReqClockNanosleep_Pre_RMTp_Null: {
/*
* While the ``rmtp parameter is equal to NULL.
*/
ctx->rmtp = NULL;
break;
}
case CReqClockNanosleep_Pre_RMTp_NA:
break;
}
}
static void CReqClockNanosleep_Post_Status_Check(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Post_Status state
)
{
switch ( state ) {
case CReqClockNanosleep_Post_Status_Zero: {
/*
* The return value of clock_nanosleep() shall be equal to zero.
*/
T_eq_int( ctx->status, 0 );
break;
}
case CReqClockNanosleep_Post_Status_ENOTSUP: {
/*
* The return value of clock_nanosleep() shall be equal to ENOTSUP.
*/
T_eq_int( ctx->status, ENOTSUP );
break;
}
case CReqClockNanosleep_Post_Status_EINVAL: {
/*
* The return value of clock_nanosleep() shall be equal to EINVAL.
*/
T_eq_int( ctx->status, EINVAL );
break;
}
case CReqClockNanosleep_Post_Status_NA:
break;
}
}
static void CReqClockNanosleep_Post_Timer_Check(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Post_Timer state
)
{
switch ( state ) {
case CReqClockNanosleep_Post_Timer_Inactive: {
/*
* The timer of the calling task shall be inactive.
*/
T_eq_int( ctx->timer_info.state, TASK_TIMER_INACTIVE );
break;
}
case CReqClockNanosleep_Post_Timer_Monotonic: {
/*
* The timer of the calling task shall be active using the
* CLOCK_MONOTONIC.
*/
T_eq_int( ctx->timer_info.state, TASK_TIMER_MONOTONIC );
break;
}
case CReqClockNanosleep_Post_Timer_Realtime: {
/*
* The timer of the calling task shall be active using the
* CLOCK_REALTIME.
*/
T_eq_int( ctx->timer_info.state, TASK_TIMER_REALTIME );
break;
}
case CReqClockNanosleep_Post_Timer_NA:
break;
}
}
static void CReqClockNanosleep_Post_Expire_Check(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Post_Expire state
)
{
struct timespec expire;
switch ( state ) {
case CReqClockNanosleep_Post_Expire_Last: {
/*
* The timer of the calling task shall expire at the last valid time
* point of the clock specified by the ``clock_id`` parameter.
*/
T_eq_u64( ctx->timer_info.expire_ticks, 0xffffffffffffffff );
break;
}
case CReqClockNanosleep_Post_Expire_Absolute: {
/*
* The timer of the calling task shall expire at the time point specified
* by the ``rqtp`` parameter.
*/
T_eq_i64( ctx->timer_info.expire_timespec.tv_sec, ctx->rqtp_obj.tv_sec );
T_eq_long(
ctx->timer_info.expire_timespec.tv_nsec,
ctx->rqtp_obj.tv_nsec
);
break;
}
case CReqClockNanosleep_Post_Expire_Relative: {
/*
* The timer of the calling task shall expire at the time point specified
* by the sum of the current time of the clock specified by the
* ``clock_id`` parameter and the interval specified by the ``rqtp``
* parameter.
*/
if ( ctx->clock_id == CLOCK_REALTIME ) {
expire = ctx->now_realtime;
} else {
expire = ctx->now_monotonic;
}
expire.tv_sec += ctx->rqtp_obj.tv_sec;
expire.tv_nsec += ctx->rqtp_obj.tv_nsec;
if ( expire.tv_nsec >= 1000000000 ) {
++expire.tv_sec;
expire.tv_nsec -= 1000000000;
}
T_eq_i64( ctx->timer_info.expire_timespec.tv_sec, expire.tv_sec );
T_eq_long( ctx->timer_info.expire_timespec.tv_nsec, expire.tv_nsec );
break;
}
case CReqClockNanosleep_Post_Expire_NA:
break;
}
}
static void CReqClockNanosleep_Post_Scheduler_Check(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Post_Scheduler state
)
{
switch ( state ) {
case CReqClockNanosleep_Post_Scheduler_Block: {
/*
* The calling task shall be blocked by the scheduler exactly once by the
* clock_nanosleep() call.
*/
T_eq_sz( ctx->scheduler_log.header.recorded, 1 );
T_eq_int(
ctx->scheduler_log.events[ 0 ].operation,
T_SCHEDULER_BLOCK
);
break;
}
case CReqClockNanosleep_Post_Scheduler_BlockUnblock: {
/*
* The calling task shall be blocked exactly once by the scheduler and
* then unblocked in the same thread dispatch critical section by the
* clock_nanosleep() call.
*/
T_eq_sz( ctx->scheduler_log.header.recorded, 2 );
T_eq_int(
ctx->scheduler_log.events[ 0 ].operation,
T_SCHEDULER_BLOCK
);
T_eq_int(
ctx->scheduler_log.events[ 1 ].operation,
T_SCHEDULER_UNBLOCK
);
break;
}
case CReqClockNanosleep_Post_Scheduler_Nop: {
/*
* The calling task shall not be altered by the scheduler by the
* clock_nanosleep() call.
*/
T_eq_sz( ctx->scheduler_log.header.recorded, 0 );
break;
}
case CReqClockNanosleep_Post_Scheduler_NA:
break;
}
}
static void CReqClockNanosleep_Post_RMTp_Check(
CReqClockNanosleep_Context *ctx,
CReqClockNanosleep_Post_RMTp state
)
{
switch ( state ) {
case CReqClockNanosleep_Post_RMTp_Zero: {
/*
* The object referenced by the ``rmtp`` parameter shall be cleared to
* zero after the return of the clock_nanosleep() call.
*/
T_eq_i64( ctx->rmtp_obj.tv_sec, 0 );
T_eq_long( ctx->rmtp_obj.tv_nsec, 0 );
break;
}
case CReqClockNanosleep_Post_RMTp_Nop: {
/*
* Objects referenced by the ``rmtp`` parameter in past calls to
* clock_nanosleep() shall not be accessed by the clock_nanosleep() call.
*/
T_eq_i64( ctx->rmtp_obj.tv_sec, -1 );
T_eq_long( ctx->rmtp_obj.tv_nsec, -1 );
break;
}
case CReqClockNanosleep_Post_RMTp_NA:
break;
}
}
static void CReqClockNanosleep_Setup( CReqClockNanosleep_Context *ctx )
{
rtems_time_of_day now = { 1988, 1, 1, 0, 0, 0, 0 };
T_rsc_success( rtems_clock_set( &now ) );
SetSelfPriority( PRIO_NORMAL );
ctx->worker_id = CreateTask( "WORK", PRIO_HIGH );
StartTask( ctx->worker_id, Worker, ctx );
}
static void CReqClockNanosleep_Setup_Wrap( void *arg )
{
CReqClockNanosleep_Context *ctx;
ctx = arg;
ctx->Map.in_action_loop = false;
CReqClockNanosleep_Setup( ctx );
}
static void CReqClockNanosleep_Teardown( CReqClockNanosleep_Context *ctx )
{
DeleteTask( ctx->worker_id );
RestoreRunnerPriority();
}
static void CReqClockNanosleep_Teardown_Wrap( void *arg )
{
CReqClockNanosleep_Context *ctx;
ctx = arg;
ctx->Map.in_action_loop = false;
CReqClockNanosleep_Teardown( ctx );
}
static void CReqClockNanosleep_Prepare( CReqClockNanosleep_Context *ctx )
{
ctx->status = -1;
ctx->flags = 0;
ctx->rmtp_obj.tv_sec = -1;
ctx->rmtp_obj.tv_nsec = -1;
}
static void CReqClockNanosleep_Action( CReqClockNanosleep_Context *ctx )
{
ResumeTask( ctx->worker_id );
(void) T_scheduler_record( NULL );
GetTaskTimerInfo( ctx->worker_id, &ctx->timer_info );
ClockTick();
FinalClockTick();
}
static const CReqClockNanosleep_Entry
CReqClockNanosleep_Entries[] = {
{ 0, 0, 0, 0, 1, 1, 0, CReqClockNanosleep_Post_Status_EINVAL,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 1, 1, 0, CReqClockNanosleep_Post_Status_ENOTSUP,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_Nop, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_EINVAL,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 1, 1, 0, CReqClockNanosleep_Post_Status_EINVAL,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_ENOTSUP,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_Nop, CReqClockNanosleep_Post_RMTp_Nop },
{ 1, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_NA,
CReqClockNanosleep_Post_Timer_NA, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_NA, CReqClockNanosleep_Post_RMTp_NA },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_EINVAL,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Expire_Last,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Expire_Last,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Expire_Absolute,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Inactive, CReqClockNanosleep_Post_Expire_NA,
CReqClockNanosleep_Post_Scheduler_BlockUnblock,
CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Expire_Absolute,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Expire_Last,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Expire_Relative,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Monotonic,
CReqClockNanosleep_Post_Expire_Relative,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Expire_Last,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Expire_Relative,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Zero },
{ 0, 0, 0, 0, 0, 0, 0, CReqClockNanosleep_Post_Status_Zero,
CReqClockNanosleep_Post_Timer_Realtime,
CReqClockNanosleep_Post_Expire_Relative,
CReqClockNanosleep_Post_Scheduler_Block, CReqClockNanosleep_Post_RMTp_Nop }
};
static const uint8_t
CReqClockNanosleep_Map[] = {
6, 6, 8, 8, 10, 10, 6, 6, 2, 2, 2, 2, 2, 2, 2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 7, 2, 13, 8, 14, 15, 11, 6, 7, 2, 7, 2, 7, 2, 7, 2, 3,
0, 3, 0, 3, 0, 3, 0, 3, 0, 3, 0, 3, 0, 3, 0, 6, 6, 9, 9, 12, 12, 6, 6, 2, 2,
2, 2, 2, 2, 2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 7, 2, 16,
9, 17, 18, 11, 6, 7, 2, 7, 2, 7, 2, 7, 2, 3, 0, 3, 0, 3, 0, 3, 0, 3, 0, 3, 0,
3, 0, 3, 0, 4, 4, 4, 4, 5, 5, 5, 5, 4, 4, 4, 4, 5, 5, 5, 5, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 4, 4, 4, 4, 5, 5, 5, 5, 4, 4, 4, 4, 5, 5, 5, 5,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1
};
static size_t CReqClockNanosleep_Scope( void *arg, char *buf, size_t n )
{
CReqClockNanosleep_Context *ctx;
ctx = arg;
if ( ctx->Map.in_action_loop ) {
return T_get_scope( CReqClockNanosleep_PreDesc, buf, n, ctx->Map.pcs );
}
return 0;
}
static T_fixture CReqClockNanosleep_Fixture = {
.setup = CReqClockNanosleep_Setup_Wrap,
.stop = NULL,
.teardown = CReqClockNanosleep_Teardown_Wrap,
.scope = CReqClockNanosleep_Scope,
.initial_context = &CReqClockNanosleep_Instance
};
static inline CReqClockNanosleep_Entry CReqClockNanosleep_PopEntry(
CReqClockNanosleep_Context *ctx
)
{
size_t index;
index = ctx->Map.index;
ctx->Map.index = index + 1;
return CReqClockNanosleep_Entries[
CReqClockNanosleep_Map[ index ]
];
}
static void CReqClockNanosleep_SetPreConditionStates(
CReqClockNanosleep_Context *ctx
)
{
ctx->Map.pcs[ 0 ] = ctx->Map.pci[ 0 ];
ctx->Map.pcs[ 1 ] = ctx->Map.pci[ 1 ];
ctx->Map.pcs[ 2 ] = ctx->Map.pci[ 2 ];
if ( ctx->Map.entry.Pre_RQTpNSec_NA ) {
ctx->Map.pcs[ 3 ] = CReqClockNanosleep_Pre_RQTpNSec_NA;
} else {
ctx->Map.pcs[ 3 ] = ctx->Map.pci[ 3 ];
}
if ( ctx->Map.entry.Pre_RQTpSec_NA ) {
ctx->Map.pcs[ 4 ] = CReqClockNanosleep_Pre_RQTpSec_NA;
} else {
ctx->Map.pcs[ 4 ] = ctx->Map.pci[ 4 ];
}
ctx->Map.pcs[ 5 ] = ctx->Map.pci[ 5 ];
}
static void CReqClockNanosleep_TestVariant( CReqClockNanosleep_Context *ctx )
{
CReqClockNanosleep_Pre_ClockId_Prepare( ctx, ctx->Map.pcs[ 0 ] );
CReqClockNanosleep_Pre_Abstime_Prepare( ctx, ctx->Map.pcs[ 1 ] );
CReqClockNanosleep_Pre_RQTp_Prepare( ctx, ctx->Map.pcs[ 2 ] );
CReqClockNanosleep_Pre_RQTpNSec_Prepare( ctx, ctx->Map.pcs[ 3 ] );
CReqClockNanosleep_Pre_RQTpSec_Prepare( ctx, ctx->Map.pcs[ 4 ] );
CReqClockNanosleep_Pre_RMTp_Prepare( ctx, ctx->Map.pcs[ 5 ] );
CReqClockNanosleep_Action( ctx );
CReqClockNanosleep_Post_Status_Check( ctx, ctx->Map.entry.Post_Status );
CReqClockNanosleep_Post_Timer_Check( ctx, ctx->Map.entry.Post_Timer );
CReqClockNanosleep_Post_Expire_Check( ctx, ctx->Map.entry.Post_Expire );
CReqClockNanosleep_Post_Scheduler_Check(
ctx,
ctx->Map.entry.Post_Scheduler
);
CReqClockNanosleep_Post_RMTp_Check( ctx, ctx->Map.entry.Post_RMTp );
}
/**
* @fn void T_case_body_CReqClockNanosleep( void )
*/
T_TEST_CASE_FIXTURE( CReqClockNanosleep, &CReqClockNanosleep_Fixture )
{
CReqClockNanosleep_Context *ctx;
ctx = T_fixture_context();
ctx->Map.in_action_loop = true;
ctx->Map.index = 0;
for (
ctx->Map.pci[ 0 ] = CReqClockNanosleep_Pre_ClockId_Monotonic;
ctx->Map.pci[ 0 ] < CReqClockNanosleep_Pre_ClockId_NA;
++ctx->Map.pci[ 0 ]
) {
for (
ctx->Map.pci[ 1 ] = CReqClockNanosleep_Pre_Abstime_Yes;
ctx->Map.pci[ 1 ] < CReqClockNanosleep_Pre_Abstime_NA;
++ctx->Map.pci[ 1 ]
) {
for (
ctx->Map.pci[ 2 ] = CReqClockNanosleep_Pre_RQTp_Valid;
ctx->Map.pci[ 2 ] < CReqClockNanosleep_Pre_RQTp_NA;
++ctx->Map.pci[ 2 ]
) {
for (
ctx->Map.pci[ 3 ] = CReqClockNanosleep_Pre_RQTpNSec_Valid;
ctx->Map.pci[ 3 ] < CReqClockNanosleep_Pre_RQTpNSec_NA;
++ctx->Map.pci[ 3 ]
) {
for (
ctx->Map.pci[ 4 ] = CReqClockNanosleep_Pre_RQTpSec_Negative;
ctx->Map.pci[ 4 ] < CReqClockNanosleep_Pre_RQTpSec_NA;
++ctx->Map.pci[ 4 ]
) {
for (
ctx->Map.pci[ 5 ] = CReqClockNanosleep_Pre_RMTp_Valid;
ctx->Map.pci[ 5 ] < CReqClockNanosleep_Pre_RMTp_NA;
++ctx->Map.pci[ 5 ]
) {
ctx->Map.entry = CReqClockNanosleep_PopEntry( ctx );
if ( ctx->Map.entry.Skip ) {
continue;
}
CReqClockNanosleep_SetPreConditionStates( ctx );
CReqClockNanosleep_Prepare( ctx );
CReqClockNanosleep_TestVariant( ctx );
}
}
}
}
}
}
}
/** @} */