Test Double: Difference between revisions

From STRIDE Wiki
Jump to navigation Jump to search
(Created page with "__NOTOC__ The ''Test Double'' feature provides a means for intercepting C/C++ language '''global functions''' on the target, and directing the call to a substitute function wi...")
 
No edit summary
 
Line 21: Line 21:
   
   
<source lang="c">
<source lang="c">
// test.h
// fut.h
int test(int x, int y);
int fut(int x, int y);
</source>
</source>
   
   


<source lang="c">
<source lang="c">
// test.c
// fut.c
#include "test.h"
#include "fut.h"
#include "depend.h"
#include "depend.h"
   
   
int test(int x, int y)
int fut(int x, int y)
{
{
     return depend(x) * y;
     return depend(x) * y;
Line 38: Line 38:




In the above sample, ''test()'' is the function under test and ''depend()'' is a dependency candidate for doubling.
In the above sample, ''fut()'' is the function under test and ''depend()'' is a dependency candidate for doubling.


The steps required to achieve doubling of a dependency function are as follows:
The steps required to achieve doubling of a dependency function are as follows:
Line 108: Line 108:
<source lang="cpp">
<source lang="cpp">
#include <srtest.h>
#include <srtest.h>
#include "fut.h"
#include "depend.h"
#include "depend.h"


Line 126: Line 127:
     }
     }


     int test1(void) { return test(1, 2); }
     void test1(void) { srASSERT_EQ(fut(1, 2), 2); }
     int test2(void) { return test(5, 6); }
     void test2(void) { srASSERT_EQ(fut(5, 6), 150); }
};
};
   
   

Latest revision as of 22:33, 8 July 2020

The Test Double feature provides a means for intercepting C/C++ language global functions on the target, and directing the call to a substitute function with identical parameters and return value. The use case is a unit test where the function under test uses a function during its execution, and this dependency is simulated by a substitute or double function during testing. The unit test is able to control the substitution of the dependency during run time, and thereby verify the behavior of the function under test. The following sample illustrates the relationship of the function under test and a dependency:

// depend.h
int depend(int x);


// depend.c
#include "depend.h"
 
int depend(int x)
{
    return x + x;
}


// fut.h
int fut(int x, int y);


// fut.c
#include "fut.h"
#include "depend.h"
 
int fut(int x, int y)
{
    return depend(x) * y;
}


In the above sample, fut() is the function under test and depend() is a dependency candidate for doubling.

The steps required to achieve doubling of a dependency function are as follows:

  1. Configuring the Double Using Function Pragma
  2. Create Double Intercepts in the IM
  3. Switch Double Function During Runtime


Configuring the Double Using Function Pragma

The syntax of the function pragma supports a set of optional attributes that allow the specification of function interception parameters. When captured for the purpose of interception (intercept-able) the optional arguments are required.

#pragma scl_function(function-name [,context, name-mangling, group-id])


Refer to the actual function pragma definition for an explanation of

  • context - set to DEFINITION or REFERENCE
  • name-mangling - set to EXPLICIT or IMPLICIT. Note if set to explicit requires usage of the srTEST_INTERCEPT macro
  • group-id - user defined to enable or disable interception


In the above sample, depend() needs to be captured via the pragma and enabled for interception in the following manner.

// depend_scl.h
#include "depend.h"

#pragma scl_function(depend, "DEFINITION", "IMPLICIT", "TEST_GROUP")


Creating Double Intercepts in the IM

If a function has been configured as a double candidate using the function pragma as outlined in the above step, the Stride Build Tools will automatically create the Intercept Module, aka IM, that contains the intercept for the double function. This all happens automatically during the build process.

But to enable the interception the source file containing the depend() implementation must be altered to mangle the function's name by defining the Group ID and including the generated Intercept Module header file (xxxIM.h):

// depend.c
#include "depend.h"
/* define the Group ID before including the IM header */
#define TEST_GROUP
#include "strideIM.h"

int depend(int x)
{
    return x + x;
}

Switching the Double Function During Runtime

In the context of the test unit code the following STRIDE runtime macros, defined in the STRIDE runtime header file srtest.h, could be used for substituting a stub function for a double candidate.

srDOUBLE_SET(fn, fnDbl)
srDOUBLE_RESET(fn)

srDOUBLE_GET(fn, pfnDbl) // used for more advanced scenarios

Where:

  • fn is the function qualified by scl_function or scl_func as a dependency candidate, as above.
  • pfnDbl is a pointer to a object of type srFunctionDouble_t, declared to hold the current value of the active double function.
  • fnDbl is a function that is to be the current active double. The function passed in should always match the signature of the dependency candidate specified by fn.

Note: the initial value of the current active double is always the dependency candidate function.

Example 1

The following example shows how to double a routine for the lifetime of a C++ Test Unit:

#include <srtest.h>
#include "fut.h"
#include "depend.h"

extern "C" int depend_dbl(int a) { return a * a; }

class Test: public stride::srTest
{ 
public:

    Test()
    {
        srDOUBLE_SET(depend, depend_dbl);
    }

    ~Test()
    {
        srDOUBLE_RESET(depend);
    }

    void test1(void) { srASSERT_EQ(fut(1, 2), 2); }
    void test2(void) { srASSERT_EQ(fut(5, 6), 150); }
};
 
#ifdef _SCL
#pragma scl_test_class(Test)
#pragma scl_function(depend, "DEFINITION", "IMPLICIT", "TEST_GROUP")
#endif

Example 2

The following example shows how to make a call to the original routine in the context of a double by safely handling any nested doubling:

#include <srtest.h>
#include "depend.h"

extern "C" int depend_dbl(int a) 
{
    int ret;

    srFunctionDouble_t fn;
    srDOUBLE_GET(depend, &fn);
    srDOUBLE_RESET(depend);
    ret = depend(a);
    srDOUBLE_SET(depend, fn);
    
    return ret; 
}