//------------------------------------------------------------------------------
// function: proc_tod_save_single_reg
//
// parameters: i_target FAPI target
// i_addr SCOM address to read
// o_data Buffer to save register read
//
// returns: FAPI_RC_SUCCESS if the given register was read and saved into buffer
// else FAPI or ECMD error is sent through
//------------------------------------------------------------------------------
fapi::ReturnCode proc_tod_save_single_reg(const fapi::Target& i_target,
const uint64_t i_addr,
ecmdDataBufferBase& o_data)
{
fapi::ReturnCode rc;
uint32_t rc_ecmd = 0;
FAPI_DBG("proc_tod_save_single_reg: Start");
do
{
rc_ecmd |= o_data.setBitLength(64);
if (rc_ecmd)
{
FAPI_ERR("proc_tod_save_single_reg: Error 0x%08X in ecmdDataBuffer setup for 0x%016llX SCOM.", rc_ecmd, i_addr);
rc.setEcmdError(rc_ecmd);
break;
}
rc=fapiGetScom(i_target,i_addr,o_data);
if (!rc.ok())
{
FAPI_ERR("proc_tod_save_single_reg: Error from fapiGetScom when retrieving 0x%016llX...", i_addr);
break;
}
FAPI_DBG("proc_tod_save_single_reg: %016llX = %016llX",i_addr, o_data.getDoubleWord(0));
} while(0);
FAPI_DBG("proc_tod_save_single_reg: End");
return rc;
}
//------------------------------------------------------------------------------
// Subroutine definitions
//------------------------------------------------------------------------------
//------------------------------------------------------------------------------
// subroutine:
// Get the SBE location from SBE VITAL
//
// parameters: i_target => slave chip target
// o_halt_code => halt code (only valid if SBE stopped)
// o_istep_num => current istep number (0xMmm)
// o_substep_num => current substep within istep
//
// returns: FAPI_RC_SUCCESS if o_istep_num and o_substep_num are valid,
// else error
//------------------------------------------------------------------------------
fapi::ReturnCode proc_check_slave_sbe_seeprom_complete_get_location(
const fapi::Target & i_target,
uint8_t & o_halt_code,
uint16_t & o_istep_num,
uint8_t & o_substep_num
)
{
// data buffer to hold register values
ecmdDataBufferBase data(64);
// return codes
uint32_t rc_ecmd = 0;
fapi::ReturnCode rc;
do
{
//Check SBE VITAL
FAPI_DBG("Checking SBE VITAL reg");
rc = fapiGetScom(i_target, MBOX_SBEVITAL_0x0005001C, data);
if(rc)
{
FAPI_ERR("Error reading SBE VITAL reg\n");
break;
}
o_halt_code = 0;
o_istep_num = 0;
o_substep_num = 0;
rc_ecmd |= data.extractToRight(&o_halt_code,
HALT_CODE_BIT_POSITION,
HALT_CODE_BIT_LENGTH);
rc_ecmd |= data.extractToRight(&o_istep_num,
ISTEP_NUM_BIT_POSITION,
ISTEP_NUM_BIT_LENGTH);
rc_ecmd |= data.extractToRight(&o_substep_num,
SUBSTEP_NUM_BIT_POSITION,
SUBSTEP_NUM_BIT_LENGTH);
if(rc_ecmd)
{
FAPI_ERR("Error (0x%x) extracting data from ecmdDataBufferBase",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
} while(0);
return rc;
}
// parameters:
// 'i_target' is chip target
//
// returns:
// FAPI_RC_SUCCESS (success, EX chiplets entered fast winkle)
//
// getscom/putscom/getattribute fapi errors
// fapi error assigned from eCMD function failure
//
//------------------------------------------------------------------------------
fapi::ReturnCode proc_mpipl_ex_cleanup(const fapi::Target & i_target) {
const char *procedureName = "proc_mpipl_ex_cleanup";
fapi::ReturnCode rc; //fapi return code
uint32_t rc_ecmd = 0; //ecmd return code value
ecmdDataBufferBase fsi_data(64); //64-bit data buffer
uint8_t attr_chip_unit_pos; //EX chiplet's unit offset within chip with respect to similar EX units
const uint64_t EX_OFFSET_MULT = 0x01000000; //Multiplier used to calculate offset for respective EX chiplet
uint64_t address; // Varible for computed addresses
uint64_t offset;
char reg_name[32]; // Character array for register names
// Relevant PMGP0 bits
// const uint32_t PM_DISABLE = 0;
const uint32_t BLOCK_REG_WKUP_SOURCE = 53;
// Relevant PMGP1 bits
const uint32_t WINKLE_POWER_OFF_SEL = 5;
std::vector<fapi::Target> v_ex_chiplets; //Vector of EX chiplets
do
{
//Entering fapi function
FAPI_INF("Entering %s", procedureName);
//Get vector of EX chiplets
rc = fapiGetChildChiplets( i_target,
fapi::TARGET_TYPE_EX_CHIPLET,
v_ex_chiplets,
fapi::TARGET_STATE_FUNCTIONAL);
if (rc)
{
FAPI_ERR("%s: fapiGetChildChiplets error", procedureName);
break;
}
FAPI_INF("Processing target %s", i_target.toEcmdString());
//Parse thru EX chiplets and prepare fast-winkled cores for deep operations
//Loop thru EX chiplets in vector
for (uint32_t counter = 0; counter < v_ex_chiplets.size(); counter++)
{
// Get EX chiplet number
rc = FAPI_ATTR_GET( ATTR_CHIP_UNIT_POS,
&(v_ex_chiplets[counter]),
attr_chip_unit_pos);
if (rc)
{
FAPI_ERR("%s: fapiGetAttribute error (ATTR_CHIP_UNIT_POS)", procedureName);
break;
}
FAPI_INF("EX chiplet pos = 0x%02X", attr_chip_unit_pos);
// Calculate the address offset based on chiplet number
offset = EX_OFFSET_MULT * attr_chip_unit_pos;
// -----------------------------------------------------------------
FAPI_DBG("\tOriginal register contents");
address = EX_GP3_0x100F0012 + offset;
strcpy(reg_name, "GP3");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
address = EX_PMGP0_0x100F0100 + offset;
strcpy(reg_name, "PMGP0");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
address = EX_PMGP1_0x100F0103 + offset;
strcpy(reg_name, "PMGP1");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
// -----------------------------------------------------------------
// Clean up configuration remnants of the fast-winkle configuration
// that was used to flush the chiplets after checkstop. EX chiplets
// will have been through SBE EX Init with certain step skippled due
// to MPIPL.
FAPI_INF("Re-establish Deep Winkle mode default");
address = EX_PMGP1_OR_0x100F0105 + offset;
strcpy(reg_name, "PMGP1 OR");
rc_ecmd |= fsi_data.flushTo0();
rc_ecmd |= fsi_data.setBit(WINKLE_POWER_OFF_SEL);
if(rc_ecmd)
{
FAPI_ERR("ecmdDatatBuffer error preparing %s reg (addr: 0x%08llX) with rc %x", reg_name, address, rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target, address, fsi_data);
if (rc)
{
FAPI_ERR("fapiPutScom error (addr: 0x%08llX)", address);
break;
}
FAPI_INF("Clear block wakeup sources to PM logic. PM is NOT re-enabled");
// (eg clear Block Interrrupt Sources)
address = EX_PMGP0_AND_0x100F0101 + offset;
strcpy(reg_name, "PMGP0 AND");
rc_ecmd |= fsi_data.flushTo1();
// rc_ecmd |= fsi_data.clearBit(PM_DISABLE);
rc_ecmd |= fsi_data.clearBit(BLOCK_REG_WKUP_SOURCE);
if(rc_ecmd)
{
FAPI_ERR("ecmdDatatBuffer error preparing %s reg (addr: 0x%08llX)", reg_name, address);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target, address, fsi_data);
if (rc)
{
FAPI_ERR("fapiPutScom error (addr: 0x%08llX)", address);
break;
}
// -----------------------------------------------------------------
FAPI_DBG("\tUpdated register contents");
address = EX_GP3_0x100F0012 + offset;
strcpy(reg_name, "GP3");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
address = EX_PMGP0_0x100F0100 + offset;
strcpy(reg_name, "PMGP0");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
address = EX_PMGP1_0x100F0103 + offset;
strcpy(reg_name, "PMGP1");
rc = fapiGetScom( i_target, address, fsi_data );
if (rc)
{
FAPI_ERR("fapiGetScom error (addr: 0x%08llX)", address);
break;
}
FAPI_DBG("\t%s (addr: 0x%08llX), val=0x%016llX", reg_name, address, fsi_data.getDoubleWord(0));
// -----------------------------------------------------------------
} // chiplet loop
// Error exit from above loop
// Not really needed as outer while(0) is next but here for consistent structure
if (!rc.ok())
{
break;
}
} while (0);
//Exiting fapi function
FAPI_INF("Exiting %s", procedureName);
return rc;
}
// HWP entry point
fapi::ReturnCode proc_getecid(
const fapi::Target& i_target,
ecmdDataBufferBase& io_fuseString)
{
// return code
fapi::ReturnCode rc;
uint32_t rc_ecmd = 0;
uint64_t attr_data[2];
// mark HWP entry
FAPI_DBG("proc_getecid: Start");
io_fuseString.setBitLength(112); // sets size and zeros out buffer
ecmdDataBufferBase otprom_mode_data(64);
ecmdDataBufferBase ecid_data(64);
do
{
//
// clear ECC enable before reading ECID data (read-modify-write OTPROM Mode register)
//
rc = fapiGetScom(i_target, OTPC_M_MODE_REGISTER_0x00010008, otprom_mode_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: fapiGetScom error (OTPC_M_MODE_REGISTER_0x00010008) for %s",
i_target.toEcmdString());
break;
}
rc_ecmd |= otprom_mode_data.clearBit(OTPC_M_MODE_REGISTER_ECC_ENABLE_BIT);
if (rc_ecmd)
{
FAPI_ERR("proc_getecid: Error 0x%X setting up OTPROM Mode register data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target, OTPC_M_MODE_REGISTER_0x00010008, otprom_mode_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: fapiPutScom error (OTPC_M_MODE_REGISTER_0x00010008) for %s",
i_target.toEcmdString());
break;
}
//
// extract and manipulate ECID data
//
rc = fapiGetScom(i_target, ECID_PART_0_0x00018000, ecid_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: fapiGetScom error (ECID_PART_0_0x00018000) for %s",
i_target.toEcmdString());
break;
}
// 0:63 become 63:0
rc_ecmd |= ecid_data.reverse();
// copy bits 0:63 from the scom into 0:63 of the fuseString/attribute data
rc_ecmd |= io_fuseString.insert(ecid_data, 0, 64);
attr_data[0] = ecid_data.getDoubleWord(0);
if (rc_ecmd)
{
FAPI_ERR("proc_getecid: Error 0x%X processing ECID (part 0) data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiGetScom(i_target, ECID_PART_1_0x00018001, ecid_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: fapiGetScom error (ECID_PART_1_0x00018001) for %s",
i_target.toEcmdString());
break;
}
// 0:63 become 63:0
rc_ecmd |= ecid_data.reverse();
// copy bits 0:47 from the scom into 64:111 of the fuseString
// all bits into attribute data
rc_ecmd |= io_fuseString.insert(ecid_data, 64, 48);
attr_data[1] = ecid_data.getDoubleWord(0);
if (rc_ecmd)
{
FAPI_ERR("proc_getecid: Error 0x%X processing ECID (part 1) data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
// push fuse string into attribute
rc = FAPI_ATTR_SET(ATTR_ECID,
&i_target,
attr_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: Error from FAPI_ATTR_SET (ATTR_ECID) for %s (attr_data[0] = %016llX, attr_data[1] = %016llX",
i_target.toEcmdString(), attr_data[0], attr_data[1]);
break;
}
//
// restore ECC enable setting
//
rc_ecmd |= otprom_mode_data.setBit(OTPC_M_MODE_REGISTER_ECC_ENABLE_BIT);
if (rc_ecmd)
{
FAPI_ERR("proc_getecid: Error 0x%X setting up OTPROM Mode register data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target, OTPC_M_MODE_REGISTER_0x00010008, otprom_mode_data);
if (!rc.ok())
{
FAPI_ERR("proc_getecid: fapiPutScom error (OTPC_M_MODE_REGISTER_0x00010008) for %s",
i_target.toEcmdString());
break;
}
} while(0);
// mark HWP exit
FAPI_DBG("proc_getecid: End");
return rc;
}
// HWP entry point, comments in header
fapi::ReturnCode proc_chiplet_scominit(const fapi::Target & i_target)
{
fapi::ReturnCode rc;
uint32_t rc_ecmd = 0;
fapi::TargetType target_type;
std::vector<fapi::Target> initfile_targets;
std::vector<fapi::Target> ex_targets;
std::vector<fapi::Target> mcs_targets;
uint8_t nx_enabled;
uint8_t mcs_pos;
uint8_t ex_pos;
uint8_t num_ex_targets;
uint8_t master_mcs_pos = 0xFF;
fapi::Target master_mcs;
uint8_t enable_xbus_resonant_clocking = 0x0;
uint8_t i2c_slave_address = 0x0;
uint8_t dual_capp_present = 0x0;
ecmdDataBufferBase data(64);
ecmdDataBufferBase cfam_data(32);
ecmdDataBufferBase mask(64);
bool is_master = false;
// mark HWP entry
FAPI_INF("proc_chiplet_scominit: Start");
do
{
rc = proc_check_master_sbe_seeprom(i_target, is_master);
if (!rc.ok())
{
FAPI_ERR("proc_cen_ref_clk_enable: Error from proc_check_master_sbe_seeprom");
break;
}
// obtain target type to determine which initfile(s) to execute
target_type = i_target.getType();
// chip level target
if (target_type == fapi::TARGET_TYPE_PROC_CHIP)
{
// execute FBC SCOM initfile
initfile_targets.push_back(i_target);
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_FBC_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_FBC_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_FBC_IF,
i_target.toEcmdString());
break;
}
// execute PSI SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_PSI_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_PSI_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_PSI_IF,
i_target.toEcmdString());
break;
}
// execute TP bridge SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_TPBRIDGE_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_TPBRIDGE_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_TPBRIDGE_IF,
i_target.toEcmdString());
break;
}
// query NX partial good attribute
rc = FAPI_ATTR_GET(ATTR_PROC_NX_ENABLE,
&i_target,
nx_enabled);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error querying ATTR_PROC_NX_ENABLE");
break;
}
// apply NX/AS SCOM initfiles only if partial good attribute is set
if (nx_enabled == fapi::ENUM_ATTR_PROC_NX_ENABLE_ENABLE)
{
// execute NX SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_NX_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_NX_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_NX_IF,
i_target.toEcmdString());
break;
}
// execute CXA SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_CXA_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_CXA_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_CXA_IF,
i_target.toEcmdString());
break;
}
// configure CXA APC master LCO settings
rc = fapiGetChildChiplets(i_target,
fapi::TARGET_TYPE_EX_CHIPLET,
ex_targets,
fapi::TARGET_STATE_FUNCTIONAL);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiGetChildChiplets (EX) on %s",
i_target.toEcmdString());
break;
}
// form valid LCO target list
for (std::vector<fapi::Target>::iterator i = ex_targets.begin();
i != ex_targets.end();
i++)
{
// determine EX chiplet number
rc = FAPI_ATTR_GET(ATTR_CHIP_UNIT_POS, &(*i), ex_pos);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from FAPI_ATTR_GET (ATTR_CHIP_UNIT_POS) on %s",
i->toEcmdString());
break;
}
rc_ecmd |= data.setBit(ex_pos-((ex_pos < 8)?(1):(3)));
}
if (!rc.ok())
{
break;
}
num_ex_targets = ex_targets.size();
rc_ecmd |= data.insertFromRight(
num_ex_targets,
CAPP_APC_MASTER_LCO_TARGET_MIN_START_BIT,
(CAPP_APC_MASTER_LCO_TARGET_MIN_END_BIT-
CAPP_APC_MASTER_LCO_TARGET_MIN_START_BIT+1));
if (rc_ecmd)
{
FAPI_ERR("proc_chiplet_scominit: Error 0x%x setting APC Master LCO Target register data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target,
CAPP_APC_MASTER_LCO_TARGET_0x02013021,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (CAPP_APC_MASTER_LCO_TARGET_0x02013021) on %s",
i_target.toEcmdString());
break;
}
// get dual CAPP presence attribute
FAPI_DBG("proc_chiplet_scominit: Querying dual CAPP feature attribute");
rc = FAPI_ATTR_GET(ATTR_CHIP_EC_FEATURE_DUAL_CAPP_PRESENT,
&i_target,
dual_capp_present);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error querying ATTR_CHIP_EC_FEATURE_DUAL_CAPP_PRESENT");
break;
}
if (dual_capp_present != 0)
{
rc = fapiPutScom(i_target,
CAPP1_APC_MASTER_LCO_TARGET_0x020131A1,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (CAPP1_APC_MASTER_LCO_TARGET_0x020131A1) on %s",
i_target.toEcmdString());
break;
}
}
// execute AS SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_AS_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_AS_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_AS_IF,
i_target.toEcmdString());
break;
}
}
else
{
FAPI_DBG("proc_chiplet_scominit: Skipping execution of %s/%s/%s (partial good)",
PROC_CHIPLET_SCOMINIT_NX_IF, PROC_CHIPLET_SCOMINIT_CXA_IF, PROC_CHIPLET_SCOMINIT_AS_IF);
}
// conditionally enable I2C Slave
rc = FAPI_ATTR_GET(ATTR_I2C_SLAVE_ADDRESS,
&i_target,
i2c_slave_address);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error querying ATTR_I2C_SLAVE_ADDRESS on %s",
i_target.toEcmdString());
break;
}
rc = fapiGetScom(i_target,
I2C_SLAVE_CONFIG_REG_0x000D0000,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiGetScom error (I2C_SLAVE_CONFIG_REG_0x000D0000) on %s",
i_target.toEcmdString());
break;
}
if (i2c_slave_address)
{
FAPI_DBG("proc_chiplet_scominit: I2C Slave enabled (%s) address = %d",
i_target.toEcmdString(),i2c_slave_address);
//set I2C address
rc_ecmd |= data.insert(i2c_slave_address,0,7);
// disable error state. when this is enabled and there
// is an error from I2CS it locks up the I2CS and no
// more operations are allowed unless cleared
// through FSI. Not good for a FSPless system.
rc_ecmd |= data.clearBit(23);
// enable I2C interface
rc_ecmd |= data.setBit(21);
}
else
{
FAPI_DBG("proc_chiplet_scominit: I2C Slave disabled (%s)",
i_target.toEcmdString());
// disable I2C interface when attribute = 0x0
rc_ecmd |= data.clearBit(21);
}
if (rc_ecmd)
{
FAPI_ERR("proc_chiplet_scominit: Error 0x%x setting I2C Slave register data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target,
I2C_SLAVE_CONFIG_REG_0x000D0000,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (I2C_SLAVE_CONFIG_REG_0x000D0000) on %s",
i_target.toEcmdString());
break;
}
// conditionally enable resonant clocking for XBUS
rc = FAPI_ATTR_GET(ATTR_CHIP_EC_FEATURE_XBUS_RESONANT_CLK_VALID,
&i_target,
enable_xbus_resonant_clocking);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error querying ATTR_CHIP_EC_FEATURE_XBUS_RESONANT_CLK_VALID on %s",
i_target.toEcmdString());
break;
}
if (enable_xbus_resonant_clocking)
{
FAPI_DBG("proc_chiplet_scominit: Enabling XBUS resonant clocking");
rc = fapiGetScom(i_target,
MBOX_FSIGP6_0x00050015,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiGetScom error (MBOX_FSIGP6_0x00050015) on %s",
i_target.toEcmdString());
break;
}
rc_ecmd |= data.insertFromRight(
XBUS_RESONANT_CLOCK_CONFIG,
MBOX_FSIGP6_XBUS_RESONANT_CLOCK_CONFIG_START_BIT,
(MBOX_FSIGP6_XBUS_RESONANT_CLOCK_CONFIG_END_BIT-
MBOX_FSIGP6_XBUS_RESONANT_CLOCK_CONFIG_START_BIT+1));
if (rc_ecmd)
{
FAPI_ERR("proc_chiplet_scominit: Error 0x%x setting FSI GP6 register data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
if (is_master)
{
rc = fapiPutScom(i_target,
MBOX_FSIGP6_0x00050015,
data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (MBOX_FSIGP6_0x00050015) on %s",
i_target.toEcmdString());
break;
}
}
else
{
cfam_data.insert(data, 0, 32, 0);
rc = fapiPutCfamRegister(i_target, CFAM_FSI_GP6_0x00002815, cfam_data);
if (rc)
{
FAPI_ERR("proc_cen_ref_clk_enable: fapiPutCfamRegister error (CFAM_FSI_GP8_0x00001017)");
break;
}
}
}
// execute A/X/PCI/DMI FIR init SCOM initfile
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_A_X_PCI_DMI_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_A_X_PCI_DMI_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_A_X_PCI_DMI_IF,
i_target.toEcmdString());
break;
}
// execute NV scominit file
uint8_t exist_NV = 0x00;
rc = FAPI_ATTR_GET(ATTR_CHIP_EC_FEATURE_NV_PRESENT, &i_target, exist_NV);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error getting attribute value ATTR_CHIP_EC_FEATURE_NV_PRESENT");
break;
}
if (exist_NV)
{
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_NPU_IF, i_target.toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_NPU_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_NPU_IF,
i_target.toEcmdString());
break;
}
// cleanup FIR bit (NPU FIR bit 27) caused by NDL/NTL parity error
rc_ecmd = data.flushTo1();
rc_ecmd = data.clearBit(NPU_FIR_NTL_DL2TL_PARITY_ERR_BIT);
if (rc_ecmd)
{
FAPI_ERR("proc_chiplet_scominit: Error 0x%Xforming NPU FIR cleanup data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(i_target, NPU_FIR_AND_0x08013D81, data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (NPU_FIR_AND_0x08013D81) on %s",
i_target.toEcmdString());
break;
}
rc = fapiPutScom(i_target, NPU_FIR_MASK_AND_0x08013D84, data);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScom error (NPU_FIR_MASK_AND_0x08013D84) on %s",
i_target.toEcmdString());
break;
}
}
else
{
FAPI_INF("proc_chiplet_scominit: NV link logic not present, scom initfile processing skipped");
}
// determine set of functional MCS chiplets
rc = fapiGetChildChiplets(i_target,
fapi::TARGET_TYPE_MCS_CHIPLET,
mcs_targets,
fapi::TARGET_STATE_FUNCTIONAL);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiGetChildChiplets (MCS) on %s",
i_target.toEcmdString());
break;
}
// apply MCS SCOM initfile only for functional chiplets
for (std::vector<fapi::Target>::iterator i = mcs_targets.begin();
(i != mcs_targets.end()) && rc.ok();
i++)
{
// execute MCS SCOM initfile
initfile_targets.clear();
initfile_targets.push_back(*i);
initfile_targets.push_back(i_target);
FAPI_INF("proc_chiplet_scominit: Executing %s on %s",
PROC_CHIPLET_SCOMINIT_MCS_IF, i->toEcmdString());
FAPI_EXEC_HWP(
rc,
fapiHwpExecInitFile,
initfile_targets,
PROC_CHIPLET_SCOMINIT_MCS_IF);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from fapiHwpExecInitfile executing %s on %s",
PROC_CHIPLET_SCOMINIT_MCS_IF,
i->toEcmdString());
break;
}
// determine MCS position
rc = FAPI_ATTR_GET(ATTR_CHIP_UNIT_POS, &(*i), mcs_pos);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: Error from FAPI_ATTR_GET (ATTR_CHIP_UNIT_POS) on %s",
i->toEcmdString());
break;
}
if (mcs_pos < master_mcs_pos)
{
fapi::Target cen_target_unused;
rc = fapiGetOtherSideOfMemChannel(*i,
cen_target_unused,
fapi::TARGET_STATE_FUNCTIONAL);
// use return code only to indicate presence of connected Centaur,
// do not propogate/emit error if not connected
if (rc.ok())
{
FAPI_DBG("Updating master_mcs_pos to %d", mcs_pos);
FAPI_DBG(" Target: %s", cen_target_unused.toEcmdString());
master_mcs = *i;
master_mcs_pos = mcs_pos;
}
else
{
rc = fapi::FAPI_RC_SUCCESS;
}
}
}
if (!rc.ok())
{
break;
}
if (master_mcs.getType() == fapi::TARGET_TYPE_MCS_CHIPLET)
{
// set MCMODE0Q_ENABLE_CENTAUR_SYNC on first target only
// (this bit is required to be set on at most one MCS/chip)
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(MCSMODE0_EN_CENTAUR_SYNC_BIT);
rc_ecmd |= mask.setBit(MCSMODE0_EN_CENTAUR_SYNC_BIT);
// check buffer manipulation return codes
if (rc_ecmd)
{
FAPI_ERR("proc_chiplet_scominit: Error 0x%X setting up MCSMODE0 data buffer",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
// write register with updated content
rc = fapiPutScomUnderMask(master_mcs,
MCS_MCSMODE0_0x02011807,
data,
mask);
if (!rc.ok())
{
FAPI_ERR("proc_chiplet_scominit: fapiPutScomUnderMask error (MCS_MCSMODE0_0x02011807) on %s",
master_mcs.toEcmdString());
break;
}
}
}
// unsupported target type
else
{
FAPI_ERR("proc_chiplet_scominit: Unsupported target type");
const fapi::Target & TARGET = i_target;
FAPI_SET_HWP_ERROR(rc, RC_PROC_CHIPLET_SCOMINIT_INVALID_TARGET);
break;
}
} while(0);
// mark HWP exit
FAPI_INF("proc_chiplet_scominit: End");
return rc;
}
//------------------------------------------------------------------------------
// function: init_tod_node
//
// parameters: i_tod_node Reference to TOD topology (FAPI targets included within)
//
// returns: FAPI_RC_SUCCESS if TOD topology is successfully initialized
// else FAPI or ECMD error is sent through
//------------------------------------------------------------------------------
fapi::ReturnCode init_tod_node(const tod_topology_node* i_tod_node)
{
fapi::ReturnCode rc;
ecmdDataBufferBase data(64);
uint32_t rc_ecmd = 0;
uint32_t tod_init_pending_count = 0; // Timeout counter for bits that are cleared by hardware
fapi::Target* target = i_tod_node->i_target;
FAPI_INF("configure_tod_node: Start: Configuring %s", target->toEcmdString());
do
{
const bool is_mdmt = (i_tod_node->i_tod_master && i_tod_node->i_drawer_master);
if (is_mdmt)
{
FAPI_INF("init_tod_node: Master: Chip TOD step checkers enable");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(0);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Error 0x%08X in ecmdDataBuffer setup for TOD_TX_TTYPE_2_REG_00040013 SCOM.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_TX_TTYPE_2_REG_00040013, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Could not write TOD_TX_TTYPE_2_REG_00040013.");
break;
}
FAPI_INF("init_tod_node: Master: switch local Chip TOD to 'Not Set' state");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(TOD_LOAD_TOD_MOD_REG_FSM_LOAD_TOD_MOD_TRIG);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Master: Error 0x%08X in ecmdDataBuffer setup for TOD_LOAD_TOD_MOD_REG_00040018 SCOM.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_LOAD_TOD_MOD_REG_00040018, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Master: Could not write TOD_LOAD_TOD_MOD_REG_00040018");
break;
}
FAPI_INF("init_tod_node: Master: switch all Chip TOD in the system to 'Not Set' state");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(0);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Master: Error 0x%08X in ecmdDataBuffer setup for TOD_TX_TTYPE_5_REG_00040016 SCOM.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_TX_TTYPE_5_REG_00040016, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Master: Could not write TOD_TX_TTYPE_5_REG_00040016");
break;
}
FAPI_INF("init_tod_node: Master: Chip TOD load value (move TB to TOD)");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setWord(0,0x00000000);
rc_ecmd |= data.setWord(1,0x00003FF0); // bits 51:59 must be 1s
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Master: Error 0x%08X in ecmdDataBuffer setup for TOD_LOAD_TOD_REG_00040021 SCOM.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_LOAD_TOD_REG_00040021, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Master: Could not write TOD_LOAD_TOD_REG_00040021");
break;
}
FAPI_INF("init_tod_node: Master: Chip TOD start_tod (switch local Chip TOD to 'Running' state)");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(TOD_START_TOD_REG_FSM_START_TOD_TRIGGER);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Master: Error 0x%08X in ecmdDataBuffer setup for TOD_START_TOD_REG_00040022 SCOM.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_START_TOD_REG_00040022, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Master: Could not write TOD_START_TOD_REG_00040022");
break;
}
FAPI_INF("init_tod_node: Master: Send local Chip TOD value to all Chip TODs");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(0);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Master: Error 0x%08X in ecmdDataBuffer setup for TOD_TX_TTYPE_4_REG_00040015", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_TX_TTYPE_4_REG_00040015, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Master: Could not write TOD_TX_TTYPE_4_REG_00040015");
break;
}
}
FAPI_INF("init_tod_node: Check TOD is Running");
tod_init_pending_count = 0;
while (tod_init_pending_count < PROC_TOD_UTIL_TIMEOUT_COUNT)
{
FAPI_DBG("init_tod_node: Waiting for TOD to assert TOD_FSM_REG_TOD_IS_RUNNING...");
rc = fapiDelay(PROC_TOD_UTILS_HW_NS_DELAY,
PROC_TOD_UTILS_SIM_CYCLE_DELAY);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: fapiDelay error");
break;
}
rc = fapiGetScom(*target, TOD_FSM_REG_00040024, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Could not retrieve TOD_FSM_REG_00040024");
break;
}
if (data.isBitSet(TOD_FSM_REG_TOD_IS_RUNNING))
{
FAPI_INF("init_tod_node: TOD is running!");
break;
}
++tod_init_pending_count;
}
if (!rc.ok())
{
break; // error in above while loop
}
if (tod_init_pending_count>=PROC_TOD_UTIL_TIMEOUT_COUNT)
{
FAPI_ERR("init_tod_node: TOD is not running! (It should be)");
const fapi::Target & CHIP_TARGET = *target;
FAPI_SET_HWP_ERROR(rc, RC_PROC_TOD_INIT_NOT_RUNNING);
break;
}
FAPI_INF("init_tod_node: clear TTYPE#2 and TTYPE#4 status");
rc_ecmd |= data.flushTo0();
rc_ecmd |= data.setBit(TOD_ERROR_REG_RX_TTYPE_2);
rc_ecmd |= data.setBit(TOD_ERROR_REG_RX_TTYPE_4);
if (rc_ecmd)
{
FAPI_ERR("init_tod_node: Error 0x%08X in ecmdDataBuffer setup for TOD_ERROR_REG_00040030.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
rc = fapiPutScom(*target, TOD_ERROR_REG_00040030, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Could not write TOD_ERROR_REG_00040030.");
break;
}
FAPI_INF("init_tod_node: checking for TOD errors");
rc = fapiGetScom(*target, TOD_ERROR_REG_00040030, data);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Could not read TOD_ERROR_REG_00040030.");
break;
}
if (data.getDoubleWord(0) != 0)
{
FAPI_ERR("init_tod_node: FIR bit active! (TOD_ERROR_REG = 0x%016llX)",data.getDoubleWord(0));
const fapi::Target & CHIP_TARGET = *target;
const uint64_t TOD_ERROR_REG = data.getDoubleWord(0);
FAPI_SET_HWP_ERROR(rc, RC_PROC_TOD_INIT_ERROR);
break;
}
// Finish configuring downstream nodes
for (std::list<tod_topology_node*>::const_iterator child = (i_tod_node->i_children).begin();
child != (i_tod_node->i_children).end();
++child)
{
tod_topology_node* tod_node = *child;
rc = init_tod_node(tod_node);
if (!rc.ok())
{
FAPI_ERR("init_tod_node: Failure configuring downstream node!");
break;
}
}
if (!rc.ok())
{
break; // error in above for loop
}
} while(0);
FAPI_INF("init_tod_node: End");
return rc;
}
//------------------------------------------------------------------------------
// subroutine:
// Check if the SBE is still running
//
// parameters: i_target => slave chip target
// o_still_running => true if still running, false otherwise
//
// returns: FAPI_RC_SUCCESS if o_still_running is valid, else error
//------------------------------------------------------------------------------
fapi::ReturnCode proc_check_slave_sbe_seeprom_complete_check_running(
const fapi::Target & i_target,
bool & o_still_running )
{
// data buffer to hold register values
ecmdDataBufferBase data(64);
// return codes
uint32_t rc_ecmd = 0;
fapi::ReturnCode rc;
do
{
FAPI_DBG("Checking SBE control reg");
rc = fapiGetScom(i_target, PORE_SBE_CONTROL_0x000E0001, data);
if(rc)
{
FAPI_ERR("Error reading SBE control reg\n");
break;
}
// Bit 0 : 1 = stopped, 0 = running (or stopped at breakpoint)
if( data.isBitClear(0) )
{
o_still_running = true;
//If running, check for stopped at breakpoint
FAPI_DBG("Checking SBE status reg");
rc = fapiGetScom(i_target, PORE_SBE_STATUS_0x000E0000, data);
if(rc)
{
FAPI_ERR("Error reading SBE status reg\n");
break;
}
uint8_t state = 0;
uint64_t address = data.getDoubleWord(0) &
0x0000FFFFFFFFFFFFull;
rc_ecmd |= data.extractToRight( &state, 3, 4 );
if(rc_ecmd)
{
FAPI_ERR("Error (0x%x) extracting SBE status",
rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
if( state == SBE_STOPPED_AT_BREAKPOINT_0xB )
{
FAPI_ERR("SBE stopped at breakpoint (address 0x%012llX)",
address);
const fapi::Target & CHIP_IN_ERROR = i_target;
FAPI_SET_HWP_ERROR(rc,
RC_PROC_CHECK_SLAVE_SBE_SEEPROM_COMPLETE_STOPPED_AT_BREAKPOINT);
break;
}
}
else
{
o_still_running = false;
}
} while(0);
return rc;
}
//------------------------------------------------------------------------------
// name: proc_mpipl_chip_cleanup
//------------------------------------------------------------------------------
// purpose:
// To enable MCD recovery
//
// Note: PHBs are left in ETU reset state after executing proc_mpipl_nest_cleanup, which runs before this procedure. PHYP releases PHBs from ETU reset post HostBoot IPL.
//
// SCOM regs
//
// 1) MCD even recovery control register
// 0000000002013410 (SCOM)
// bit 0 (MCD_REC_EVEN_ENABLE): 0 to 1 transition needed to start, reset to 0 at end of request.
// bit 5 (MCD_REC_EVEN_REQ_PEND)
//
//
// 2) MCD odd recovery control register
// 0000000002013411 (SCOM)
// bit 0 (MCD_REC_ODD_ENABLE): 0 to 1 transition needed to start, reset to 0 at end of request.
// bit 5 (MCD_REC_ODD_REQ_PEND)
//
// 3) Clear PCI Nest FIR registers
// 02012000 (SCOM)
// 02012400 (SCOM)
// 02012800 (SCOM)
//
// parameters:
// 'i_target' is reference to chip target
//
// returns:
// FAPI_RC_SUCCESS (success, MCD recovery enabled for odd and even slices)
//
// RC_MCD_RECOVERY_NOT_DISABLED_RC (MCD recovery for even or odd slice is not disabled; therefore can't re-enable MCD recovery)
// (Note: refer to file eclipz/chips/p8/working/procedures/xml/error_info/proc_mpipl_chip_cleanup_errors.xml)
//
// getscom/putscom fapi errors
// fapi error assigned from eCMD function failure
//
//------------------------------------------------------------------------------
fapi::ReturnCode proc_mpipl_chip_cleanup(const fapi::Target &i_target){
const char *procedureName = "proc_mpipl_chip_cleanup"; //Name of this procedure
fapi::ReturnCode rc; //fapi return code value
uint32_t rc_ecmd = 0; //ecmd return code value
const uint32_t data_size = 64; //Size of data buffer
const int MAX_MCD_DIRS = 2; //Max of 2 MCD Directories (even and odd)
ecmdDataBufferBase fsi_data[MAX_MCD_DIRS];
const uint64_t ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[MAX_MCD_DIRS] = {
0x0000000002013410, //MCD even recovery control register address
0x0000000002013411 //MCD odd recovery control register address
};
const uint32_t MCD_RECOVERY_CTRL_REG_BIT_POS0 = 0; //Bit 0 of MCD even and odd recovery control regs
const char *ARY_MCD_DIR_STRS[MAX_MCD_DIRS] = {
"Even", //Ptr to char string "Even" for even MCD
"Odd" //Ptr to char string "Odd" for odd MCD
};
const int MAX_PHBS = 3;
const uint64_t PCI_NEST_FIR_REG_ADDRS[MAX_PHBS] = {
0x02012000,
0x02012400,
0x02012800
};
do {
//Set bit length for 64-bit buffers
rc_ecmd = fsi_data[0].setBitLength(data_size);
rc_ecmd |= fsi_data[1].setBitLength(data_size);
if(rc_ecmd) {
rc.setEcmdError(rc_ecmd);
break;
}
//Verify MCD recovery was previously disabled for even and odd slices
//If not, this is an error condition
for (int counter = 0; counter < MAX_MCD_DIRS; counter++) {
FAPI_DBG("Verifying MCD %s Recovery is disabled, target=%s", ARY_MCD_DIR_STRS[counter], i_target.toEcmdString());
//Get data from MCD Even or Odd Recovery Ctrl reg
rc = fapiGetScom(i_target, ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter], fsi_data[counter]);
if (!rc.ok()) {
FAPI_ERR("%s: fapiGetScom error (addr: 0x%08llX), target=%s", procedureName, ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter], i_target.toEcmdString());
break;
}
//Check whether bit 0 is 0, meaning MCD recovery is disabled as expected
if( fsi_data[counter].getBit(MCD_RECOVERY_CTRL_REG_BIT_POS0) ) {
FAPI_ERR("%s: MCD %s Recovery not disabled as expected, target=%s", procedureName, ARY_MCD_DIR_STRS[counter], i_target.toEcmdString());
const fapi::Target & CHIP_TARGET = i_target;
const uint64_t & MCD_RECOV_CTRL_REG_ADDR = ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter];
ecmdDataBufferBase & MCD_RECOV_CTRL_REG_DATA = fsi_data[counter];
FAPI_SET_HWP_ERROR(rc, RC_MPIPL_MCD_RECOVERY_NOT_DISABLED_RC);
break;
}
}
if(!rc.ok()) {
break;
}
//Assert bit 0 of MCD Recovery Ctrl regs to enable MCD recovery
for (int counter = 0; counter < MAX_MCD_DIRS; counter++) {
FAPI_DBG("Enabling MCD %s Recovery, target=%s", ARY_MCD_DIR_STRS[counter], i_target.toEcmdString());
//Assert bit 0 of MCD Even or Odd Recovery Control reg to enable recovery
rc_ecmd = fsi_data[counter].setBit(MCD_RECOVERY_CTRL_REG_BIT_POS0 );
if(rc_ecmd) {
FAPI_ERR("%s: Error (%u) asserting bit pos %u in ecmdDataBufferBase that stores value of MCD %s Recovery Control reg (addr: 0x%08llX), target=%s", procedureName, rc_ecmd, MCD_RECOVERY_CTRL_REG_BIT_POS0, ARY_MCD_DIR_STRS[counter], ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter], i_target.toEcmdString());
rc.setEcmdError(rc_ecmd);
break;
}
//Write data to MCD Even or Odd Recovery Control reg
rc = fapiPutScom(i_target, ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter], fsi_data[counter]);
if (!rc.ok()) {
FAPI_ERR("%s: fapiPutScom error (addr: 0x%08llX), target=%s", procedureName, ARY_MCD_RECOVERY_CTRL_REGS_ADDRS[counter], i_target.toEcmdString());
break;
}
}
if(!rc.ok()) {
break;
}
// SW227429: clear PCI Nest FIR registers
// hostboot is blindly sending EOIs in order to ensure no interrupts are pending when PHYP starts up again
// with ETU held in reset, these get trapped in PCI and force a freeze to occur (PCI Nest FIR(14))
// clearing the FIR should remove the freeze condition
rc_ecmd = fsi_data[0].flushTo0();
if (rc_ecmd) {
FAPI_ERR("%s: Error (%u) forming PCI Nest FIR clear data buffer, target=%s", procedureName, rc_ecmd, i_target.toEcmdString());
rc.setEcmdError(rc_ecmd);
break;
}
for (int counter = 0; counter < MAX_PHBS; counter++) {
FAPI_DBG("Clearing PCI%d Nest FIR, target=%s", counter, i_target.toEcmdString());
rc = fapiPutScom(i_target, PCI_NEST_FIR_REG_ADDRS[counter], fsi_data[0]);
if (!rc.ok()) {
FAPI_ERR("%s: fapiPutScom error (addr: 0x%08llX), target=%s", procedureName, PCI_NEST_FIR_REG_ADDRS[counter], i_target.toEcmdString());
break;
}
}
} while(0);
FAPI_IMP("Exiting %s", procedureName);
return rc;
}
//------------------------------------------------------------------------------
// function:
// Stop SBE runtime scan service
//
// parameters: i_target => chip target
// returns: FAPI_RC_SUCCESS if operation was successful, else error
//------------------------------------------------------------------------------
fapi::ReturnCode proc_stop_sbe_scan_service(
const fapi::Target& i_target,
const void* i_pSEEPROM)
{
// return codes
fapi::ReturnCode rc;
uint32_t rc_ecmd = 0;
// track if procedure has cleared I2C master bus fence
bool i2cm_bus_fence_cleared = false;
// mark function entry
FAPI_DBG("Start");
do
{
// check SBE progress
bool sbe_running = true;
size_t loop_time = 0;
uint8_t halt_code = 0;
uint16_t istep_num = 0;
uint8_t substep_num = 0;
bool scan_service_loop_reached = false;
// retrieve status
rc = proc_sbe_utils_check_status(
i_target,
sbe_running,
halt_code,
istep_num,
substep_num);
if (!rc.ok())
{
FAPI_ERR("Error from proc_check_sbe_state_check_status");
break;
}
// get HB->SBE request mailbox, check that it is clear
ecmdDataBufferBase mbox_data(64);
bool sbe_ready = false;
rc = fapiGetScom(i_target, MBOX_SCRATCH_REG0_0x00050038, mbox_data);
if (!rc.ok())
{
FAPI_ERR("Scom error reading SBE MBOX0 Register");
break;
}
sbe_ready = (mbox_data.getDoubleWord(0) == 0);
scan_service_loop_reached =
sbe_running &&
sbe_ready &&
!halt_code &&
(istep_num == PROC_SBE_SCAN_SERVICE_ISTEP_NUM) &&
(substep_num == SUBSTEP_SBE_READY);
FAPI_INF("SBE is running [%d], loop time [%zd], scan service loop reached [%d]",
sbe_running, loop_time, scan_service_loop_reached);
if (!sbe_running)
{
FAPI_INF("SBE is stopped, exiting!");
break;
}
else if (scan_service_loop_reached)
{
// format stop request
rc_ecmd |= mbox_data.setBit(MBOX0_REQUEST_VALID_BIT);
rc_ecmd |= mbox_data.insertFromRight(MBOX0_HALT_PATTERN,
MBOX0_HALT_PATTERN_START_BIT,
(MBOX0_HALT_PATTERN_END_BIT-
MBOX0_HALT_PATTERN_START_BIT)+1);
if (rc_ecmd)
{
FAPI_ERR("Error 0x%x setting up SBE MBOX0 data buffer.", rc_ecmd);
rc.setEcmdError(rc_ecmd);
break;
}
// submit stop request to SBE
FAPI_DBG("Submitting stop request to SBE");
rc = fapiPutScom(i_target, MBOX_SCRATCH_REG0_0x00050038, mbox_data);
if (!rc.ok())
{
FAPI_ERR("Error writing SBE MBOX0 Register");
break;
}
// pause to allow request to be processed
uint32_t loop_num = 0;
while (sbe_running && (loop_num < SBE_HALT_POLL_MAX_LOOPS))
{
loop_num++;
rc = fapiDelay(SBE_HALT_POLL_DELAY_HW, SBE_HALT_POLL_DELAY_SIM);
if (!rc.ok())
{
FAPI_ERR("Error from fapiDelay");
break;
}
// retrieve status
rc = proc_sbe_utils_check_status(
i_target,
sbe_running,
halt_code,
istep_num,
substep_num);
if (!rc.ok())
{
FAPI_ERR("Error from proc_check_sbe_state_check_status");
break;
}
}
if (rc)
{
break;
}
if (sbe_running)
{
FAPI_ERR("SBE is STILL running!");
const fapi::Target & TARGET = i_target;
FAPI_SET_HWP_ERROR(rc, RC_PROC_STOP_SBE_SCAN_SERVICE_SBE_NOT_STOPPED);
break;
}
// before analysis proceeds, make sure that I2C master bus fence is cleared
FAPI_EXEC_HWP(rc, proc_reset_i2cm_bus_fence, i_target);
if (!rc.ok())
{
FAPI_ERR("Error from proc_reset_i2cm_bus_fence");
break;
}
// mark that fence has been cleared
i2cm_bus_fence_cleared = true;
// ensure correct halt code is captured
rc = proc_sbe_utils_check_status(
i_target,
sbe_running,
halt_code,
istep_num,
substep_num);
if (!rc.ok())
{
FAPI_ERR("Error from proc_check_sbe_state_check_status");
break;
}
// confirm that expected halt point was reached
if (halt_code != SBE_EXIT_SUCCESS_0xF)
{
FAPI_ERR("SBE halted with error 0x%X (istep 0x%03X, substep 0x%X)",
halt_code, istep_num, substep_num);
// extract & return error code from analyzing SBE state
FAPI_EXEC_HWP(rc, proc_extract_sbe_rc, i_target, NULL, i_pSEEPROM, SBE);
break;
}
if ((istep_num != PROC_SBE_SCAN_SERVICE_ISTEP_NUM) ||
(substep_num != SUBSTEP_HALT_SUCCESS))
{
FAPI_ERR("Expected SBE istep 0x%03llX, substep 0x%X but found istep 0x%03X, substep 0x%X",
PROC_SBE_SCAN_SERVICE_ISTEP_NUM, SUBSTEP_HALT_SUCCESS,
istep_num, substep_num);
const fapi::Target & TARGET = i_target;
const uint32_t & ISTEP_NUM = istep_num;
const uint32_t & SUBSTEP_NUM = substep_num;
FAPI_SET_HWP_ERROR(rc, RC_PROC_STOP_SBE_SCAN_SERVICE_SBE_BAD_HALT);
break;
}
// Reset the SBE so it can be used for MPIPL if needed
ecmdDataBufferBase sbe_reset_data(64);
rc = fapiPutScom(i_target, PORE_SBE_RESET_0x000E0002, sbe_reset_data);
if (!rc.ok())
{
FAPI_ERR("Scom error resetting SBE\n");
break;
}
}
// error
else
{
FAPI_ERR("SBE did not reach acceptable final state!");
const fapi::Target & TARGET = i_target;
const bool & SBE_RUNNING = sbe_running;
const uint8_t & HALT_CODE = halt_code;
const uint16_t & ISTEP_NUM = istep_num;
const uint8_t & SUBSTEP_NUM = substep_num;
FAPI_SET_HWP_ERROR(rc, RC_PROC_STOP_SBE_SCAN_SERVICE_UNEXPECTED_FINAL_STATE);
break;
}
} while(0);
// if an error occurred prior to the I2C master bus fence
// being cleared, attempt to clear it prior to exit
if (!rc.ok() && !i2cm_bus_fence_cleared)
{
// discard rc, return that of original fail
fapi::ReturnCode rc_unused;
FAPI_EXEC_HWP(rc_unused, proc_reset_i2cm_bus_fence, i_target);
}
// mark function entry
FAPI_DBG("End");
return rc;
}
