Test Point Testing in C/C++: Difference between revisions

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== Introduction ==
__NOTOC__
Test Points provide an easy-to-use framework for solving a class of common yet difficult unit testing problems:  
Test code to validate the [[Expectations]] of the Test Points often follows this basic pattern:


''How can I observe and verify activity that occurs in another thread?''
# Specify an expectation set consisting of expected (i.e. the test points that are expected to be hit) and optionally unexpected (i.e. the test points that are not expected to be hit) test points
 
# Register the expectation set with the Stride runtime
A couple of common scenarios that become a lot more testable via test points include:
# Invoke the software under test (causing instrumentation points to be hit). This may not be necessary if the instrumented software under test is constantly running).
* Verification of State machine operation
* Verification of asynchronous callbacks
* Verification of communication drivers
 
== Instrumenting Source Code ==
Target threads are instrumented simply by placing lines of the following form into the source code:
<source lang='c'>
...
/* a test point with no payload */
srTEST_POINT("first test point");
 
srTEST_POINT_DATA("second test point", myData, sizeofMyData);
 
srTEST_POINT_STR1("third test point", "payload with format string %d", myVar);
</source>
 
When this code is executed it broadcasts a message via the STRIDE runtime which is detected by the test (IM) thread if it is currently looking for test points (i.e. in a srTEST_POINT_WAIT()). We refer to this as a ''test point hit''.
 
== Instrumenting Test Code ==
The test code is instrumented using these steps:
 
# Specify an expectation set (i.e. the test points that are expected to be hit)
# Optionally, specify an unexpected set (i.e. the test points that are not expected to be hit)
# Register the expectated and unexpected sets with the STRIDE runtime
# If the activity we will be obvserving/verifying needs to be started (e.g. a state machine gets kicked off) this should be done after here
# Wait for the expectation set to be satisfied or a timeout to occur
# Wait for the expectation set to be satisfied or a timeout to occur


Line 39: Line 14:
void tf_testpoint_wait(void)
void tf_testpoint_wait(void)
{
{
   /* specify expectation set */
   /* specify expected set */
   srTestPointExpect_t expected[]= {
   srTestPointExpect_t expected[]= {
         {"START"},  
         {"START"},  
Line 47: Line 22:
         {0}};
         {0}};


   /* specify unexpectation set */
   /* specify unexpected set */
   srTestPointUnexpect_t unexpected[]= {
   srTestPointUnexpect_t unexpected[]= {
         {"INVALID"},  
         {"INVALID"},  
         {0}};
         {0}};


   /* register the expectation set with the STRIDE */
   /* register the expectation set*/
   srWORD handle;
   srWORD handle;
   srTestPointExpect(expected, unexpected, srTEST_POINT_EXPECT_UNORDERED, &handle);
   srTestPointSetup(expected, unexpected, srTEST_POINT_EXPECT_UNORDERED, srTEST_CASE_DEFAULT, &handle);


   /* start your asynchronous operation */
   /* start your asynchronous operation */
Line 60: Line 35:


   /* wait for expectation set to be satisfied or a timeout to occur */
   /* wait for expectation set to be satisfied or a timeout to occur */
   srTEST_POINT_WAIT(handle, 1000);
   srTestPointWait(handle, 1000);
}
}


Line 67: Line 42:
#endif
#endif
</source>
</source>


== Reference ==
== Reference ==


=== Test Point ===
=== Expectation Set ===
To specify a test point you should use one of the following macros:
An expectation set is specified with an [[Expectations#Expected_List|expected]] array of '''srTestPointExpect_t''' structures and a second optional [[Expectations#Unexpected_List|unexpected]] array of '''srTestPointUnexpect_t''' structures.


{| class="prettytable"
==== Expected Array ====
| colspan="2" | '''Test Point'''
srTestPointExpect_t is typedef'd as follows:
|-
| srTEST_POINT(''label'')
| ''label'' is a pointer to a null-terminated string
|-
| srTEST_POINT_DATA(''label'', ''data'', ''size'')
| ''label'' is a pointer to a null-terminated string<br/>
''data'' is a pointer to a byte sequence<br/>
''size'' is the size of the ''data'' in bytes
|-
| srTEST_POINT_STR(''label'', ''message'')
| ''label'' is a pointer to a null-terminated string<br/>
''message'' is a pointer to a null-terminated string
|-
| srTEST_POINT_STR[1..4](''label'', ''message'', ...)
| ''label'' is a pointer to a null-terminated string<br/>
''message'' is a pointer to a null-terminated format string<br/>
''...'' variable list (up to 4) matching the format string
|}
 
=== Expectation Set ===
An expectation set is an array of '''srTestPointExpect_t''' structures. srTestPointExpect_t is typedef'd as follows:


<source lang='c'>
<source lang='c'>
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     /* optional, count specifies the number of times the test point is expected to be hit */  
     /* optional, count specifies the number of times the test point is expected to be hit */  
     srDWORD                count;
     srDWORD                count;
     /* optional, predicate to use for payload validation against user data */  
     /* optional, predicate function to use for payload validation against user data */  
     srTestPointPredicate_t  predicate;
     srTestPointPredicate_t  predicate;
     /* optional, user data to validate the payload against */
     /* optional, user data to validate the payload against */
Line 115: Line 70:
* The ''count'', ''predicate'' and ''user'' members may be omitted in the array declaration (they will be automatically set to 0 by the compiler)
* The ''count'', ''predicate'' and ''user'' members may be omitted in the array declaration (they will be automatically set to 0 by the compiler)
* A ''count'' value of either 0 or 1 is interpreted as 1  
* A ''count'' value of either 0 or 1 is interpreted as 1  
* The ''count'' could be set as "0 or more" by using the special srTEST_POINT_ANY_COUNT symbolic constant   
* The ''count'' could be set as "0 or more" by using the [[Expectations#Special_Processing|special]] srTEST_POINT_ANY_COUNT symbolic constant   
* A ''predicate'' value 0 indicates that any associated with a test point payload will be ignored.
* A ''predicate'' value 0 indicates that any associated data with a test point payload will be ignored.
* A ''user'' value 0 indicates that there is no user data associated with this test point
* A ''user'' value 0 indicates that there is no user data associated with this test point
* The ''label'' could be specified to ''everything else'' by using the special symbolic constant srTEST_POINT_EVERYTHING_ELSE. It is required to be the one end only (non zero) entry in the array.
* The ''label'' could be specified to ''any test point'' within the current expected set of test points by using the [[Expectations#Special_Processing|special]] srTEST_POINT_ANY_IN_SET or srTEST_POINT_ANY_AT_ALL symbolic constants.
 
==== Unexpected Array ====
srTestPointUnexpect_t is typedef'd as follows:
 
<source lang='c'>
typedef struct
{
    /* the label value is considered the test point's identity */
    const srCHAR *          label;
} srTestPointUnexpect_t;
</source>


=== srTestPointExpect ===
'''NOTES:'''
The srTestPointExpect() routine is used to register an expectation set.
* The end of the array has to be marked by a srTestPointUnexpect_t set to all zero values
* The ''label'' could be specified to ''everything else'' relative to the '''expected''' array by using the [[Expectations#Special_Processing|special]] srTEST_POINT_EVERYTHING_ELSE symbolic constant.
 
==== srTestPointPredicate_t ====
When defining the expectation set per entry a [[Expectations#State_Data_Validation|payload validation]] predicate function could be specified. The signature of it should match the following type:


<source lang="c">
<source lang="c">
srBOOL srTestPointExpect(srTestPointExpect_t* ptExpected,  
extern "C" typedef srBYTE (*srTestPointPredicate_t)(const srTestPoint_t* ptTP, void* pvUser);
                        srTestPointExpectOrder_e eOrder,  
</source>
                        srTestPointExpectMembership_e eMembership,  
 
                        srWORD* pwHandle);
{| border="1" cellspacing="0" cellpadding="10" style="align:left;" 
| '''Parameters'''
| '''Type'''
| '''Description'''
|-
| ptTP
| Input
| Pointer to the currently processed Test Point.
|-
| pvUser
| Input
| Pointer to opaque user data associated with an entry in the expectation set.
|}
<br>
{| border="1" cellspacing="0" cellpadding="10" style="align:left;"
| '''Return Value'''
| ''' Description'''
|-
| srBYTE
| srTRUE for valid, srFALSE for invalid, srIGNORE otherwise.
|}
 
'''NOTE:'''
* As part of the standard Stride distribution there are three predefined function predicate helpers:
** srTestPointMemCmp - byte comparison
** srTestPointStrCmp - string case sensitive comparison
** srTestPointStrCaseCmp - string case insensitive comparison
 
==== srTestPointSetup ====
The srTestPointSetup() routine is used to register an expectation set.
 
<source lang="c">
srBOOL srTestPointSetup(srTestPointExpect_t* ptExpected,  
                        srTestPointUnexpect_t* ptUnexpected,
                        srBYTE yMode,  
                        srTestCaseHandle_t tTestCase,  
                        srWORD* pwHandle);
</source>
</source>


Line 137: Line 143:
| ptExpected
| ptExpected
| Input
| Input
| Pointer to an expectation set.
| Pointer to an expectated array.
|-
| ptUnexpected
| Input
| Pointer to an unexpectated array. This is optional and could be set srNULL.
|-
|-
| eOrder
| yMode
| Input  
| Input  
| Expectation order. Possible values are: <br/>  
| Bitmask that specifies whether the expectated test points occur in [[Expectations#Sequencing_Properties|order and/or strict]]. Possible values are: <br/>  
srTEST_POINT_EXPECT_ORDERED - the test points are expected to be hit exactly in the defined order <br/>
srTEST_POINT_EXPECT_ORDERED - the test points are expected to be hit exactly in the defined order <br/>
srTEST_POINT_EXPECT_UNORDERED - the test points could to be hit in any order
srTEST_POINT_EXPECT_UNORDERED - the test points could to be hit in any order <br/>
srTEST_POINT_EXPECT_STRICT - the test points are expected to be hit exactly as specified (no consecutive duplicate hits)<br/>
srTEST_POINT_EXPECT_NONSTRICT - other test points from the universe could to be hit in between <br/>
srTEST_POINT_EXPECT_CONTINUE - on successful expectation satisfaction continue processing until the wait timeout expires
|-
|-
| eMembership
| tTestCase 
| Input  
| Input  
| Expectation membership. Possible values are: <br/>
| Handle to a test case. srTEST_CASE_DEFAULT can be used for the default test case.
srTEST_POINT_EXPECT_EXCLUSIVE - any non expected test point hit will be treated as an error <br/>
srTEST_POINT_EXPECT_NONEXCLUSIVE - non expected test points hit are ignored
|-
|-
| pwHandle  
| pwHandle  
Line 164: Line 175:
|}
|}


=== srTestPointWait ===
==== srTestPointWait ====
The srTestPointWait() routine is used to wait for the expectation to be satisfied.  
The srTestPointWait() routine is used to wait for the expectation to be satisfied.  


<source lang="c">
<source lang="c">
srBOOL srTestPointWait(srWORD wHandle,  
srBOOL srTestPointWait(srWORD wHandle,  
                      srTestCaseHandle_t tTestCase,
                       srDWORD dwTimeout);
                       srDWORD dwTimeout);
</source>
</source>
Line 181: Line 191:
| Input
| Input
| Handle to a registered expectation set.
| Handle to a registered expectation set.
|-
| tTestCase
| Input
| Handle to a test case where the results would be reported. srTEST_CASE_DEFAULT can be used for the default test case.
|-
|-
| dwTimeout  
| dwTimeout  
Line 199: Line 205:
|}
|}


For convinience the following macros are provided:
'''NOTES:'''
<source lang="c">
* The test thread blocks until either the expectation set is satisfied, unless srTEST_POINT_EXPECT_CONTINUE is specified on setup, or the timeout elapses.
#define srTEST_POINT_WAIT(handle, timeout) srTestPointWait(handle, srTEST_CASE_DEFAULT, timeout)
#define srTEST_POINT_CHECK(handle) srTestPointWait(handle, srTEST_CASE_DEFAULT, 0)
</source>
 
NOTES:
* The test thread blocks until either the expectation set is satisfied or the timeout elapses.
* All test points hit during the wait (both expected and unexpected) are added to the test report as testcase comments
* All test points hit during the wait (both expected and unexpected) are added to the test report as testcase comments
* If an unexpected test point is encountered (either out of order or not in the expectation set), or the timeout period elapses before the expectation set is satisfied the current test immediately fails
* Once the wait is over (whether the expectation set has been satisfied or there has been a test failure), the current expectation set is automatically unregistered from the Stride runtime and the handle is released
* Once the wait is over (whether the expectation set has been satisfied or there has been a test failure), the current expectation set is automatically unregistered from the STRIDE runtime and the handle is released
* If you want to return immediately from a test case if expectation fails then make the check/wait call an argument to the ''srASSERT_TRUE()'' macro.
 
== Use Cases ==


=== 0 or More Expectations ===
==== srTestPointCheck ====
In some cases the expected test point pattern is something like:
The srTestPointCheck() routine is used to check for the expectation post routine completion. This is useful for verifying a set of expectations events that should have already transpired (thus are waiting to be processed).
* START
* PROGRESS
...
* END
where any number (0 or more) of PROGRESS are expected but doesn't matter how many.


To specify that use the special <tt>srTEST_POINT_ANY_COUNT</tt> constant:
<source lang="c">
<source lang="c">
#include <srtest.h>
srBOOL srTestPointCheck(srWORD wHandle);
void tf_testpoint_any(void)
{
  /* specify expectation set */
  srTestPointExpect_t expected[]= {
        {"START"},
        {"PROGRESS", srTEST_POINT_ANY_COUNT},
        {"END"},
        {0}};
...
}
</source>
</source>


=== Negative Expectations ===  
{| border="1" cellspacing="0" cellpadding="10" style="align:left;" 
'''Case 1.''' Need to run a scenario and verify that NONE of the test points are hit.
| '''Parameters'''
| '''Type'''
| '''Description'''
|-
| wHandle
| Input
| Handle to a registered expectation set.
|}
<br>
{| border="1" cellspacing="0" cellpadding="10" style="align:left;"
| '''Return Value'''
| ''' Description'''
|-
| srBOOL
| srTRUE on success, srFALSE otherwise.
|}


Dedicate a special test point, lets call it “NEGATIVE_FINAL”, and add it at the end of your test sequence then by setting the expectation “exclusively” to just that test point would allow testing that none of your other test points were hit:
'''NOTES:'''
* All test points hit before the check (both expected and unexpected) are added to the test report as testcase comments
* Once the check is done (whether the expectation set has been satisfied or there has been a test failure), the current expectation set is automatically unregistered from the Stride runtime and the handle is released
* If you want to return immediately from a test case if expectation fails then make the check/wait call an argument to the ''srASSERT_TRUE()'' macro.


<source lang="c">
=== C++ Facade Class ===
#include <srtest.h>
The ''srtest.h'' file provides a simple [http://en.wikipedia.org/wiki/Facade_pattern facade] class that wraps the test point APIs described above in a simple C++ class called '''srTestPointsHandler'''. If you are writing your unit tests in C++ (using Stride test classes), then this class is available for your use. The class implements the following methods, which correspond exactly to the C API equivalents:
void tf_testpoint_none(void)
{
  srTestPointExpect_t expected[]= {
        {"NEGATIVE_FINAL"},
        {0}};
 
  srWORD handle;
  srTestPointExpect(expected, srTEST_POINT_EXPECT_UNORDERED, srTEST_POINT_EXPECT_EXCLUSIVE, &handle);
...
}
</source>
 
 
'''Case 2.''' Need to verify that a subset of test points are not hit.
 
By expecting that all other (not in the negative subset) test points could be hit any number of times combined with the the technique described in case 1 would allow testing that a subset was to hit.
 
<source lang="c">
#include <srtest.h>
void tf_testpoint_none(void)
{
  srTestPointExpect_t expected[]= {
        {"TP_1", srTEST_POINT_ANY_COUNT},
        {"TP_2", srTEST_POINT_ANY_COUNT},
        ...
        {"TP_N", srTEST_POINT_ANY_COUNT},
        {"NEGATIVE_FINAL"},
        {0}};
 
  srWORD handle;
  srTestPointExpect(expected, srTEST_POINT_EXPECT_UNORDERED, srTEST_POINT_EXPECT_EXCLUSIVE, &handle);
...
}
</source>
 
 
'''Case 3.''' Want to return immediately from a test case if expectation fails.
 
Note that <tt>[[#srTestPointWait|srTestPointWait()]]</tt> returns <tt>srFALSE</tt> if the expectation fails. By making the call an argument to <tt>[[Pass/Fail_Macros#Boolean_Macros|srASSERT_TRUE()]]</tt>, you can automatically return from the current test case if the expectation is not met.
 
<source lang="c">
 
...
 
/* If expectation fails, returns immediately */
srASSERT_TRUE(srTestPointWait(handle, 1000));
 
</source>


[[Category:Test Units]]
; srTestPointsHandler : constructor. Takes four arguments which match exactly the first four parameters of the [[#srTestPointSetup|srTestPointSetup]] function.
[[Category:Testing]]
; Wait : instance method that provides same functionality as [[#srTestPointWait|srTestPointWait]].
; Check : instance method that provides same functionality as [[#srTestPointCheck|srTestPointCheck]].

Latest revision as of 21:14, 8 July 2015

Test code to validate the Expectations of the Test Points often follows this basic pattern:

  1. Specify an expectation set consisting of expected (i.e. the test points that are expected to be hit) and optionally unexpected (i.e. the test points that are not expected to be hit) test points
  2. Register the expectation set with the Stride runtime
  3. Invoke the software under test (causing instrumentation points to be hit). This may not be necessary if the instrumented software under test is constantly running).
  4. Wait for the expectation set to be satisfied or a timeout to occur

Here is an example:

#include <srtest.h>

void tf_testpoint_wait(void)
{
  /* specify expected set */
  srTestPointExpect_t expected[]= {
        {"START"}, 
        {"ACTIVE"}, 
        {"IDLE"},
        {"END"}, 
        {0}};

  /* specify unexpected set */
  srTestPointUnexpect_t unexpected[]= {
        {"INVALID"}, 
        {0}};

  /* register the expectation set*/
  srWORD handle;
  srTestPointSetup(expected, unexpected, srTEST_POINT_EXPECT_UNORDERED, srTEST_CASE_DEFAULT, &handle);

  /* start your asynchronous operation */
  ...

  /* wait for expectation set to be satisfied or a timeout to occur */
  srTestPointWait(handle, 1000);
}

#ifdef _SCL
#pragma scl_test_flist(“testfunc”, tf_testpoint_wait)
#endif


Reference

Expectation Set

An expectation set is specified with an expected array of srTestPointExpect_t structures and a second optional unexpected array of srTestPointUnexpect_t structures.

Expected Array

srTestPointExpect_t is typedef'd as follows:

typedef struct
{
    /* the label value is considered the test point's identity */
    const srCHAR *          label;
    /* optional, count specifies the number of times the test point is expected to be hit */ 
    srDWORD                 count;
    /* optional, predicate function to use for payload validation against user data */ 
    srTestPointPredicate_t  predicate;
    /* optional, user data to validate the payload against */
    void *                  user;
} srTestPointExpect_t;

NOTES:

  • The end of the array has to be marked by a srTestPointExpect_t set to all zero values
  • The count, predicate and user members may be omitted in the array declaration (they will be automatically set to 0 by the compiler)
  • A count value of either 0 or 1 is interpreted as 1
  • The count could be set as "0 or more" by using the special srTEST_POINT_ANY_COUNT symbolic constant
  • A predicate value 0 indicates that any associated data with a test point payload will be ignored.
  • A user value 0 indicates that there is no user data associated with this test point
  • The label could be specified to any test point within the current expected set of test points by using the special srTEST_POINT_ANY_IN_SET or srTEST_POINT_ANY_AT_ALL symbolic constants.

Unexpected Array

srTestPointUnexpect_t is typedef'd as follows:

typedef struct
{
    /* the label value is considered the test point's identity */
    const srCHAR *          label;
} srTestPointUnexpect_t;

NOTES:

  • The end of the array has to be marked by a srTestPointUnexpect_t set to all zero values
  • The label could be specified to everything else relative to the expected array by using the special srTEST_POINT_EVERYTHING_ELSE symbolic constant.

srTestPointPredicate_t

When defining the expectation set per entry a payload validation predicate function could be specified. The signature of it should match the following type:

extern "C" typedef srBYTE (*srTestPointPredicate_t)(const srTestPoint_t* ptTP, void* pvUser);
Parameters Type Description
ptTP Input Pointer to the currently processed Test Point.
pvUser Input Pointer to opaque user data associated with an entry in the expectation set.


Return Value Description
srBYTE srTRUE for valid, srFALSE for invalid, srIGNORE otherwise.

NOTE:

  • As part of the standard Stride distribution there are three predefined function predicate helpers:
    • srTestPointMemCmp - byte comparison
    • srTestPointStrCmp - string case sensitive comparison
    • srTestPointStrCaseCmp - string case insensitive comparison

srTestPointSetup

The srTestPointSetup() routine is used to register an expectation set.

srBOOL srTestPointSetup(srTestPointExpect_t* ptExpected, 
                        srTestPointUnexpect_t* ptUnexpected, 
                        srBYTE yMode, 
                        srTestCaseHandle_t tTestCase, 
                        srWORD* pwHandle);
Parameters Type Description
ptExpected Input Pointer to an expectated array.
ptUnexpected Input Pointer to an unexpectated array. This is optional and could be set srNULL.
yMode Input Bitmask that specifies whether the expectated test points occur in order and/or strict. Possible values are:

srTEST_POINT_EXPECT_ORDERED - the test points are expected to be hit exactly in the defined order
srTEST_POINT_EXPECT_UNORDERED - the test points could to be hit in any order
srTEST_POINT_EXPECT_STRICT - the test points are expected to be hit exactly as specified (no consecutive duplicate hits)
srTEST_POINT_EXPECT_NONSTRICT - other test points from the universe could to be hit in between
srTEST_POINT_EXPECT_CONTINUE - on successful expectation satisfaction continue processing until the wait timeout expires

tTestCase Input Handle to a test case. srTEST_CASE_DEFAULT can be used for the default test case.
pwHandle Output Handle that represents the registered expectation set


Return Value Description
srBOOL srTRUE on success, srFALSE otherwise.

srTestPointWait

The srTestPointWait() routine is used to wait for the expectation to be satisfied.

srBOOL srTestPointWait(srWORD wHandle, 
                       srDWORD dwTimeout);
Parameters Type Description
wHandle Input Handle to a registered expectation set.
dwTimeout Input Timeout value in milliseconds; 0 means just check without waiting.


Return Value Description
srBOOL srTRUE on success, srFALSE otherwise.

NOTES:

  • The test thread blocks until either the expectation set is satisfied, unless srTEST_POINT_EXPECT_CONTINUE is specified on setup, or the timeout elapses.
  • All test points hit during the wait (both expected and unexpected) are added to the test report as testcase comments
  • Once the wait is over (whether the expectation set has been satisfied or there has been a test failure), the current expectation set is automatically unregistered from the Stride runtime and the handle is released
  • If you want to return immediately from a test case if expectation fails then make the check/wait call an argument to the srASSERT_TRUE() macro.

srTestPointCheck

The srTestPointCheck() routine is used to check for the expectation post routine completion. This is useful for verifying a set of expectations events that should have already transpired (thus are waiting to be processed).

srBOOL srTestPointCheck(srWORD wHandle);
Parameters Type Description
wHandle Input Handle to a registered expectation set.


Return Value Description
srBOOL srTRUE on success, srFALSE otherwise.

NOTES:

  • All test points hit before the check (both expected and unexpected) are added to the test report as testcase comments
  • Once the check is done (whether the expectation set has been satisfied or there has been a test failure), the current expectation set is automatically unregistered from the Stride runtime and the handle is released
  • If you want to return immediately from a test case if expectation fails then make the check/wait call an argument to the srASSERT_TRUE() macro.

C++ Facade Class

The srtest.h file provides a simple facade class that wraps the test point APIs described above in a simple C++ class called srTestPointsHandler. If you are writing your unit tests in C++ (using Stride test classes), then this class is available for your use. The class implements the following methods, which correspond exactly to the C API equivalents:

srTestPointsHandler
constructor. Takes four arguments which match exactly the first four parameters of the srTestPointSetup function.
Wait
instance method that provides same functionality as srTestPointWait.
Check
instance method that provides same functionality as srTestPointCheck.