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// IBM_PROLOG_BEGIN_TAG
// This is an automatically generated prolog.
//
// $Source: src/usr/i2c/test/eepromddtest.H $
//
// IBM CONFIDENTIAL
//
// COPYRIGHT International Business Machines Corp. 2011
//
// p1
//
// Object Code Only (OCO) source materials
// Licensed Internal Code Source Materials
// IBM HostBoot Licensed Internal Code
//
// The source code for this program is not published or other-
// wise divested of its trade secrets, irrespective of what has
// been deposited with the U.S. Copyright Office.
//
// Origin: 30
//
// IBM_PROLOG_END
#ifndef __EEPROMTEST_H
#define __EEPROMTEST_H
/**
* @file eepromtest.H
*
* @brief Test cases for the eeprom dd code
*/
#include <sys/time.h>
#include <cxxtest/TestSuite.H>
#include <errl/errlmanager.H>
#include <errl/errlentry.H>
#include <errl/errltypes.H>
#include <devicefw/driverif.H>
#include <i2c/eepromddreasoncodes.H>
#include <targeting/predicates/predicatectm.H>
#include <targeting/predicates/predicatepostfixexpr.H>
extern trace_desc_t* g_trac_eeprom;
using namespace TARGETING;
class EEPROMTest: public CxxTest::TestSuite
{
public:
/**
* @brief EEPROM Read/Write Test
* This test will test a variety of reads/writes and lengths
* across slave devices.
*/
void testEEPROMReadWrite ( void )
{
errlHndl_t err = NULL;
int fails = 0;
int num_ops = 0;
TRACFCOMP( g_trac_eeprom,
"testEEPROMReadWrite - Start" );
struct
{
uint64_t addr; // Slave Device Address to access
uint64_t chip; // Which EEPROM chip hung off of the target to access
uint64_t data; // Data to write or compare to
size_t size; // Number of bytes to read/write
bool rnw; // Read (true), Write (false)
} testData[] =
{
{ 0x1111, 0x0, 0xfedcba9876543210, 8, false }, // Write data
{ 0x1111, 0x0, 0xfedcba9876543210, 8, true }, // Read data
{ 0x2222, 0x0, 0xaabb000000000000, 2, false },
{ 0x2222, 0x0, 0xaabb000000000000, 2, true },
{ 0x1122, 0x0, 0x1122334400000000, 4, false },
{ 0x1122, 0x0, 0x1122334400000000, 4, true },
};
const uint32_t NUM_CMDS = sizeof(testData)/sizeof(testData[0]);
//@TODO
//@VBU workaround - Disable I2C test case on fake target
//Test case use fake targets, which will fail when running
//on VBU. Need to fix this.
TARGETING::EntityPath syspath(TARGETING::EntityPath::PATH_PHYSICAL);
syspath.addLast(TARGETING::TYPE_SYS,0);
TARGETING::Target* sys = TARGETING::targetService().toTarget(syspath);
uint8_t vpo_mode = 0;
if( sys
&& sys->tryGetAttr<TARGETING::ATTR_IS_SIMULATION>(vpo_mode)
&& (vpo_mode == 1) )
{
return;
}
do
{
// Get a processor Target
TARGETING::TargetService& l_targetService = TARGETING::targetService();
TARGETING::Target* testTarget = NULL;
l_targetService.masterProcChipTargetHandle( testTarget );
assert(testTarget != NULL);
TargetHandleList fullList;
fullList.push_back( testTarget );
// TODO - The following is what I want to use... BUT, since we
// can't target DIMMs yet, and only Proc 0 has a slave device
// hung off of it, we can't do that yet. Uncomment the following
// when it is supported.
// TARGETING::TargetService& tS = TARGETING::targetService();
// TARGETING::Target * sysTarget = NULL;
// TargetHandleList fullList;
// // Get top level system target
// tS.getTopLevelTarget( sysTarget );
// assert( sysTarget != NULL );
// // Predicate for the Procs
// TARGETING::PredicateCTM predProc( TARGETING::CLASS_CHIP,
// TARGETING::TYPE_PROC );
// // Predicate for the DIMMs
// TARGETING::PredicateCTM predDimm( TARGETING::CLASS_CARD,
// TARGETING::TYPE_DIMM );
// // Expression to get both Procs and DIMMs.
// PredicatePostfixExpr query;
// query.push( &predProc ).push( &predDimm ).Or();
// tS.getAssociated( fullList,
// sysTarget,
// TARGETING::TargetService::CHILD,
// TARGETING::TargetService::ALL,
// &query );
// assert( 0 != fullList.size() );
// Number of total operations
num_ops = fullList.size() * NUM_CMDS;
for( uint32_t j = 0; j < fullList.size(); j++ )
{
for( uint32_t i = 0; i < NUM_CMDS; i++ )
{
uint64_t data;
// if a read, initialize data, else, set data to write
if( testData[i].rnw )
{
data = 0x0ull;
}
else
{
data = testData[i].data;
}
// do the operation
err = deviceOp( (testData[i].rnw ? DeviceFW::READ : DeviceFW::WRITE),
fullList[j],
&data,
testData[i].size,
DEVICE_EEPROM_ADDRESS( testData[i].addr,
testData[i].chip ) );
if( err )
{
TS_FAIL( "testEEPROMReadWrite - fail on cmd %d out of %d",
i, NUM_CMDS );
errlCommit( err,
EEPROM_COMP_ID );
delete err;
fails++;
continue;
}
// compare data for the read
if( testData[i].rnw )
{
if( data != testData[i].data )
{
TRACFCOMP( g_trac_eeprom,
"testEEPROMReadWrite - cmd: %d/%d, Data read: %016llx, "
"expected: %016llx",
i, NUM_CMDS, data, testData[i].data );
TS_FAIL( "testEEPROMReadWrite - Failure comparing read data!" );
fails++;
continue;
}
}
}
}
} while( 0 );
TRACFCOMP( g_trac_eeprom,
"testEEPROMReadWrite - %d/%d fails",
fails, num_ops );
}
/**
* @brief EEPROM Invalid Operation Test
* This test will pass in an invalid Operation type. It
* is expected that an error log is to be returned.
*/
void testEEPROMInvalidOperation ( void )
{
errlHndl_t err = NULL;
int64_t fails = 0, num_ops = 0;
uint64_t data = 0x0ull;
size_t dataSize = 8;
do
{
// Get a processor Target
TARGETING::TargetService& tS = TARGETING::targetService();
TARGETING::Target* testTarget = NULL;
tS.masterProcChipTargetHandle( testTarget );
assert(testTarget != NULL);
num_ops++;
err = deviceOp( DeviceFW::LAST_OP_TYPE,
testTarget,
&data,
dataSize,
DEVICE_EEPROM_ADDRESS( 0x0,
0x0 ) );
if( NULL == err )
{
fails++;
TS_FAIL( "Error should've resulted in Operation type of LAST_OP_TYPE!" );
}
else
{
delete err;
err = NULL;
}
} while( 0 );
TRACFCOMP( g_trac_eeprom,
"testEEPROMInvalidOperation - %d/%d fails",
fails, num_ops );
}
/**
* @brief EEPROM Invalid Chip Test
* This test will pass in an invalid chip identifier which should
* result in an error being returned back from
*/
void testEEPROMInvalidChip ( void )
{
errlHndl_t err = NULL;
int64_t fails = 0, num_ops = 0;
uint64_t data = 0x0ull;
size_t dataSize = 8;
const int64_t CHIP_NUM = 20;
do
{
// Get a processor Target
TARGETING::TargetService& tS = TARGETING::targetService();
TARGETING::Target* testTarget = NULL;
tS.masterProcChipTargetHandle( testTarget );
assert(testTarget != NULL);
num_ops++;
err = deviceOp( DeviceFW::WRITE,
testTarget,
&data,
dataSize,
DEVICE_EEPROM_ADDRESS( 0x0,
CHIP_NUM ) );
if( NULL == err )
{
fails++;
TS_FAIL( "Error should've resulted in using EEPROM chip %d!",
CHIP_NUM );
}
else
{
delete err;
err = NULL;
}
} while( 0 );
TRACFCOMP( g_trac_eeprom,
"testEEPROMInvalidChip - %d/%d fails",
fails, num_ops );
}
};
#endif
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