// IBM_PROLOG_BEGIN_TAG // This is an automatically generated prolog. // // $Source: src/usr/fsi/test/fsiprestest.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 __FSIPRESTEST_H #define __FSIPRESTEST_H /** * @file fsiprestest.H * @brief Test cases for the FSI presence detect. */ #include #include #include #include using namespace TARGETING; using namespace DeviceFW; extern trace_desc_t* g_trac_fsi; class FSIPresTest : public CxxTest::TestSuite { public: /** @brief Verify presence state matches the apparent FSI bus states. * * Performs a presence detect on every processor and memory, followed * by an FSI access to the device. Ensures we get an error on every * non-present device and we do not get an error for any present * device. */ void testPresence() { Target* l_masterChip = NULL; targetService().masterProcChipTargetHandle(l_masterChip); // Filter for just processor and mem-buffers. PredicateCTM l_proc(CLASS_NA,TYPE_PROC); PredicateCTM l_membuf(CLASS_NA,TYPE_MEMBUF); PredicatePostfixExpr l_expr; l_expr.push(&l_proc).push(&l_membuf).Or(); TargetRangeFilter target(targetService().begin(), targetService().end(), &l_expr); // Iterate through all processors and mem-buffers. while(target) { TS_TRACE("FSI-PRES: Testing target %x", TARGETING::get_huid(*target)); // Read presence detect. errlHndl_t l_errl = NULL; bool present = false; size_t l_size = 1; l_errl = deviceRead(*target, &present, l_size, DEVICE_PRESENT_ADDRESS()); if (l_errl) { TS_FAIL("FSI-PRES: Cannot perform presence detect. %x", TARGETING::get_huid(*target)); TRACFCOMP(g_trac_fsi, "Failed presence detect. %x", TARGETING::get_huid(*target)); } else if ((*target == l_masterChip) && (!present)) { TS_FAIL("FSI-PRES: Claiming master chip is not present!"); } else // Attempt FSI read. { // Determine a valid FSI address to read. uint64_t fsi_address = 0x1028; // CHIPID address if (*target == l_masterChip) { fsi_address = 0x3474; //MFSI MVER address } // Perform FSI read. uint32_t fsi_data = 0; size_t op_size = sizeof(fsi_data); l_errl = deviceRead(*target, &fsi_data, op_size, DEVICE_FSI_ADDRESS(fsi_address)); // Verify we get an FSI error if device is not present or // we do not get an FSI error if device is present. if (present && l_errl) { TS_FAIL("FSI-PRES: " "Error performing read to present device. %x", TARGETING::get_huid(*target)); TRACFCOMP(g_trac_fsi, "FSI-PRES: FSI-read failed with %d on %x", l_errl->reasonCode(), TARGETING::get_huid(*target)); // commit this log for debug l_errl->collectTrace("UNIT_TEST",512); errlCommit(l_errl,FSI_COMP_ID); } else if (!present && !l_errl) { TS_FAIL("FSI-PRES: No error performing " "read to non-present device. %x", TARGETING::get_huid(*target)); TRACFCOMP(g_trac_fsi, "FSI-PRES: FSI-read did not fail. %x", TARGETING::get_huid(*target)); } else { TS_TRACE("FSI-PRES: Read chip-id %x on %x", fsi_data, TARGETING::get_huid(*target)); } // Delete any logs that got produced if( l_errl ) { delete l_errl; } } ++target; } } }; #endif