static int e1000_intr_test(struct e1000_adapter *adapter, u64 *data)
{
struct net_device *netdev = adapter->netdev;
struct e1000_hw *hw = &adapter->hw;
u32 mask;
u32 shared_int = 1;
u32 irq = adapter->pdev->irq;
int i;
int ret_val = 0;
int int_mode = E1000E_INT_MODE_LEGACY;
*data = 0;
/* NOTE: we don't test MSI/MSI-X interrupts here, yet */
if (adapter->int_mode == E1000E_INT_MODE_MSIX) {
int_mode = adapter->int_mode;
e1000e_reset_interrupt_capability(adapter);
adapter->int_mode = E1000E_INT_MODE_LEGACY;
e1000e_set_interrupt_capability(adapter);
}
/* Hook up test interrupt handler just for this test */
if (!request_irq(irq, e1000_test_intr, IRQF_PROBE_SHARED, netdev->name,
netdev)) {
shared_int = 0;
} else if (request_irq(irq, e1000_test_intr, IRQF_SHARED,
netdev->name, netdev)) {
*data = 1;
ret_val = -1;
goto out;
}
e_info("testing %s interrupt\n", (shared_int ? "shared" : "unshared"));
/* Disable all the interrupts */
ew32(IMC, 0xFFFFFFFF);
e1e_flush();
usleep_range(10000, 20000);
/* Test each interrupt */
for (i = 0; i < 10; i++) {
/* Interrupt to test */
mask = 1 << i;
if (adapter->flags & FLAG_IS_ICH) {
switch (mask) {
case E1000_ICR_RXSEQ:
continue;
case 0x00000100:
if (adapter->hw.mac.type == e1000_ich8lan ||
adapter->hw.mac.type == e1000_ich9lan)
continue;
break;
default:
break;
}
}
if (!shared_int) {
/*
* Disable the interrupt to be reported in
* the cause register and then force the same
* interrupt and see if one gets posted. If
* an interrupt was posted to the bus, the
* test failed.
*/
adapter->test_icr = 0;
ew32(IMC, mask);
ew32(ICS, mask);
e1e_flush();
usleep_range(10000, 20000);
if (adapter->test_icr & mask) {
*data = 3;
break;
}
}
/*
* Enable the interrupt to be reported in
* the cause register and then force the same
* interrupt and see if one gets posted. If
* an interrupt was not posted to the bus, the
* test failed.
*/
adapter->test_icr = 0;
ew32(IMS, mask);
ew32(ICS, mask);
e1e_flush();
usleep_range(10000, 20000);
if (!(adapter->test_icr & mask)) {
*data = 4;
break;
}
if (!shared_int) {
/*
* Disable the other interrupts to be reported in
* the cause register and then force the other
* interrupts and see if any get posted. If
* an interrupt was posted to the bus, the
* test failed.
*/
adapter->test_icr = 0;
ew32(IMC, ~mask & 0x00007FFF);
ew32(ICS, ~mask & 0x00007FFF);
e1e_flush();
usleep_range(10000, 20000);
if (adapter->test_icr) {
*data = 5;
break;
}
}
}
/* Disable all the interrupts */
ew32(IMC, 0xFFFFFFFF);
e1e_flush();
usleep_range(10000, 20000);
/* Unhook test interrupt handler */
free_irq(irq, netdev);
out:
if (int_mode == E1000E_INT_MODE_MSIX) {
e1000e_reset_interrupt_capability(adapter);
adapter->int_mode = int_mode;
e1000e_set_interrupt_capability(adapter);
}
return ret_val;
}
unlock(&flash_lock);
}
static void dec_in_flight_param(void)
{
lock(&flash_lock);
assert(in_flight_params > 0);
in_flight_params--;
unlock(&flash_lock);
}
static void got_code_update_policy(uint32_t param_id __unused, int err_len,
void *data __unused)
{
if (err_len != 4) {
log_simple_error(&e_info(OPAL_RC_CU_INIT), "CUPD: Error "
"retrieving code update policy: %d\n", err_len);
} else
prlog(PR_NOTICE, "CUPD: Code update policy from FSP: %d\n",
update_policy);
dec_in_flight_param();
}
static void get_code_update_policy(void)
{
int rc;
inc_in_flight_param();
rc = fsp_get_sys_param(SYS_PARAM_FLASH_POLICY, &update_policy, 4,
got_code_update_policy, NULL);
switch(sz) {
case 1:
*data = rdata >> 24;
break;
case 2:
*data = rdata >> 16;
break;
default:
*data = rdata;
break;
}
return 0;
}
time_wait_nopoll(100);
}
log_simple_error(&e_info(OPAL_RC_LPC_READ), "LPC: Read timeout !\n");
return OPAL_HARDWARE;
}
static int64_t lpc_set_fw_idsel(struct proc_chip *chip, uint8_t idsel)
{
uint32_t val;
int64_t rc;
if (idsel == chip->lpc_fw_idsel)
return OPAL_SUCCESS;
if (idsel > 0xf)
return OPAL_PARAMETER;
rc = opb_read(chip, lpc_reg_opb_base + LPC_HC_FW_SEG_IDSEL,
&val, 4);
static int64_t xscom_handle_error(uint64_t hmer, uint32_t gcid, uint32_t pcb_addr,
bool is_write, int64_t retries,
int64_t *xscom_clear_retries)
{
unsigned int stat = GETFIELD(SPR_HMER_XSCOM_STATUS, hmer);
int64_t rc = OPAL_HARDWARE;
/* XXX Figure out error codes from doc and error
* recovery procedures
*/
switch(stat) {
case 1:
/*
* XSCOM engine is blocked, need to retry. Reset XSCOM
* engine after crossing retry threshold before
* retrying again.
*/
if (retries && !(retries % XSCOM_BUSY_RESET_THRESHOLD)) {
prlog(PR_NOTICE, "XSCOM: Busy even after %d retries, "
"resetting XSCOM now. Total retries = %lld\n",
XSCOM_BUSY_RESET_THRESHOLD, retries);
xscom_reset(gcid, true);
}
/* Log error if we have retried enough and its still busy */
if (retries == XSCOM_BUSY_MAX_RETRIES)
log_simple_error(&e_info(OPAL_RC_XSCOM_BUSY),
"XSCOM: %s-busy error gcid=0x%x pcb_addr=0x%x "
"stat=0x%x\n", is_write ? "write" : "read",
gcid, pcb_addr, stat);
return OPAL_XSCOM_BUSY;
case 2: /* CPU is asleep, reset XSCOM engine and return */
xscom_reset(gcid, false);
return OPAL_XSCOM_CHIPLET_OFF;
case 3: /* Partial good */
rc = OPAL_XSCOM_PARTIAL_GOOD;
break;
case 4: /* Invalid address / address error */
rc = OPAL_XSCOM_ADDR_ERROR;
if (xscom_clear_error(gcid, pcb_addr)) {
/* return busy if retries still pending. */
if ((*xscom_clear_retries)--)
return OPAL_XSCOM_BUSY;
prlog(PR_DEBUG, "XSCOM: error recovery failed for "
"gcid=0x%x pcb_addr=0x%x\n", gcid, pcb_addr);
}
break;
case 5: /* Clock error */
rc = OPAL_XSCOM_CLOCK_ERROR;
break;
case 6: /* Parity error */
rc = OPAL_XSCOM_PARITY_ERROR;
break;
case 7: /* Time out */
rc = OPAL_XSCOM_TIMEOUT;
break;
}
/* XXX: Create error log entry ? */
log_simple_error(&e_info(OPAL_RC_XSCOM_RW),
"XSCOM: %s error gcid=0x%x pcb_addr=0x%x stat=0x%x\n",
is_write ? "write" : "read", gcid, pcb_addr, stat);
/* We need to reset the XSCOM or we'll hang on the next access */
xscom_reset(gcid, false);
/* Non recovered ... just fail */
return rc;
}
/**
* e1000e_check_options - Range Checking for Command Line Parameters
* @adapter: board private structure
*
* This routine checks all command line parameters for valid user
* input. If an invalid value is given, or if no user specified
* value exists, a default value is used. The final value is stored
* in a variable in the adapter structure.
**/
void __devinit e1000e_check_options(struct e1000_adapter *adapter)
{
struct e1000_hw *hw = &adapter->hw;
int bd = adapter->bd_number;
if (bd >= E1000_MAX_NIC) {
e_notice("Warning: no configuration for board #%i\n", bd);
e_notice("Using defaults for all values\n");
}
{ /* Transmit Interrupt Delay */
const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TIDV),
.def = DEFAULT_TIDV,
.arg = { .r = { .min = MIN_TXDELAY,
.max = MAX_TXDELAY } }
};
if (num_TxIntDelay > bd) {
adapter->tx_int_delay = TxIntDelay[bd];
e1000_validate_option(&adapter->tx_int_delay, &opt,
adapter);
} else {
adapter->tx_int_delay = opt.def;
}
}
{ /* Transmit Absolute Interrupt Delay */
const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TADV),
.def = DEFAULT_TADV,
.arg = { .r = { .min = MIN_TXABSDELAY,
.max = MAX_TXABSDELAY } }
};
if (num_TxAbsIntDelay > bd) {
adapter->tx_abs_int_delay = TxAbsIntDelay[bd];
e1000_validate_option(&adapter->tx_abs_int_delay, &opt,
adapter);
} else {
adapter->tx_abs_int_delay = opt.def;
}
}
{ /* Receive Interrupt Delay */
struct e1000_option opt = {
.type = range_option,
.name = "Receive Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RDTR),
.def = DEFAULT_RDTR,
.arg = { .r = { .min = MIN_RXDELAY,
.max = MAX_RXDELAY } }
};
if (num_RxIntDelay > bd) {
adapter->rx_int_delay = RxIntDelay[bd];
e1000_validate_option(&adapter->rx_int_delay, &opt,
adapter);
} else {
adapter->rx_int_delay = opt.def;
}
}
{ /* Receive Absolute Interrupt Delay */
const struct e1000_option opt = {
.type = range_option,
.name = "Receive Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RADV),
.def = DEFAULT_RADV,
.arg = { .r = { .min = MIN_RXABSDELAY,
.max = MAX_RXABSDELAY } }
};
if (num_RxAbsIntDelay > bd) {
adapter->rx_abs_int_delay = RxAbsIntDelay[bd];
e1000_validate_option(&adapter->rx_abs_int_delay, &opt,
adapter);
} else {
adapter->rx_abs_int_delay = opt.def;
}
}
{ /* Interrupt Throttling Rate */
const struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Throttling Rate (ints/sec)",
.err = "using default of "
__MODULE_STRING(DEFAULT_ITR),
.def = DEFAULT_ITR,
.arg = { .r = { .min = MIN_ITR,
.max = MAX_ITR } }
};
if (num_InterruptThrottleRate > bd) {
adapter->itr = InterruptThrottleRate[bd];
switch (adapter->itr) {
case 0:
e_info("%s turned off\n", opt.name);
break;
case 1:
e_info("%s set to dynamic mode\n", opt.name);
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
break;
case 3:
e_info("%s set to dynamic conservative mode\n",
opt.name);
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
break;
case 4:
e_info("%s set to simplified (2000-8000 ints) "
"mode\n", opt.name);
adapter->itr_setting = 4;
break;
default:
/*
* Save the setting, because the dynamic bits
* change itr.
*/
if (e1000_validate_option(&adapter->itr, &opt,
adapter) &&
(adapter->itr == 3)) {
/*
* In case of invalid user value,
* default to conservative mode.
*/
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
} else {
/*
* Clear the lower two bits because
* they are used as control.
*/
adapter->itr_setting =
adapter->itr & ~3;
}
break;
}
} else {
adapter->itr_setting = opt.def;
adapter->itr = 20000;
}
}
{ /* Interrupt Mode */
struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Mode",
.err = "defaulting to 2 (MSI-X)",
.def = E1000E_INT_MODE_MSIX,
.arg = { .r = { .min = MIN_INTMODE,
.max = MAX_INTMODE } }
};
if (num_IntMode > bd) {
unsigned int int_mode = IntMode[bd];
e1000_validate_option(&int_mode, &opt, adapter);
adapter->int_mode = int_mode;
} else {
adapter->int_mode = opt.def;
}
}
{ /* Smart Power Down */
const struct e1000_option opt = {
.type = enable_option,
.name = "PHY Smart Power Down",
.err = "defaulting to Disabled",
.def = OPTION_DISABLED
};
if (num_SmartPowerDownEnable > bd) {
unsigned int spd = SmartPowerDownEnable[bd];
e1000_validate_option(&spd, &opt, adapter);
if ((adapter->flags & FLAG_HAS_SMART_POWER_DOWN)
&& spd)
adapter->flags |= FLAG_SMART_POWER_DOWN;
}
}
{ /* CRC Stripping */
const struct e1000_option opt = {
.type = enable_option,
.name = "CRC Stripping",
.err = "defaulting to enabled",
.def = OPTION_ENABLED
};
if (num_CrcStripping > bd) {
unsigned int crc_stripping = CrcStripping[bd];
e1000_validate_option(&crc_stripping, &opt, adapter);
if (crc_stripping == OPTION_ENABLED)
adapter->flags2 |= FLAG2_CRC_STRIPPING;
} else {
adapter->flags2 |= FLAG2_CRC_STRIPPING;
}
}
{ /* Kumeran Lock Loss Workaround */
const struct e1000_option opt = {
.type = enable_option,
.name = "Kumeran Lock Loss Workaround",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (num_KumeranLockLoss > bd) {
unsigned int kmrn_lock_loss = KumeranLockLoss[bd];
e1000_validate_option(&kmrn_lock_loss, &opt, adapter);
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
kmrn_lock_loss);
} else {
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
opt.def);
}
}
{ /* Write-protect NVM */
const struct e1000_option opt = {
.type = enable_option,
.name = "Write-protect NVM",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (adapter->flags & FLAG_IS_ICH) {
if (num_WriteProtectNVM > bd) {
unsigned int write_protect_nvm = WriteProtectNVM[bd];
e1000_validate_option(&write_protect_nvm, &opt,
adapter);
if (write_protect_nvm)
adapter->flags |= FLAG_READ_ONLY_NVM;
} else {
if (opt.def)
adapter->flags |= FLAG_READ_ONLY_NVM;
}
}
}
}
/**
* e1000e_check_options - Range Checking for Command Line Parameters
* @adapter: board private structure
*
* This routine checks all command line parameters for valid user
* input. If an invalid value is given, or if no user specified
* value exists, a default value is used. The final value is stored
* in a variable in the adapter structure.
**/
void __devinit e1000e_check_options(struct e1000_adapter *adapter)
{
struct e1000_hw *hw = &adapter->hw;
int bd = adapter->bd_number;
if (bd >= E1000_MAX_NIC) {
e_notice("Warning: no configuration for board #%i\n", bd);
e_notice("Using defaults for all values\n");
}
{ /* Transmit Interrupt Delay */
static const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TIDV),
.def = DEFAULT_TIDV,
.arg = { .r = { .min = MIN_TXDELAY,
.max = MAX_TXDELAY } }
};
if (num_TxIntDelay > bd) {
adapter->tx_int_delay = TxIntDelay[bd];
e1000_validate_option(&adapter->tx_int_delay, &opt,
adapter);
} else {
adapter->tx_int_delay = opt.def;
}
}
{ /* Transmit Absolute Interrupt Delay */
static const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TADV),
.def = DEFAULT_TADV,
.arg = { .r = { .min = MIN_TXABSDELAY,
.max = MAX_TXABSDELAY } }
};
if (num_TxAbsIntDelay > bd) {
adapter->tx_abs_int_delay = TxAbsIntDelay[bd];
e1000_validate_option(&adapter->tx_abs_int_delay, &opt,
adapter);
} else {
adapter->tx_abs_int_delay = opt.def;
}
}
{ /* Receive Interrupt Delay */
static struct e1000_option opt = {
.type = range_option,
.name = "Receive Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RDTR),
.def = DEFAULT_RDTR,
.arg = { .r = { .min = MIN_RXDELAY,
.max = MAX_RXDELAY } }
};
if (num_RxIntDelay > bd) {
adapter->rx_int_delay = RxIntDelay[bd];
e1000_validate_option(&adapter->rx_int_delay, &opt,
adapter);
} else {
adapter->rx_int_delay = opt.def;
}
}
{ /* Receive Absolute Interrupt Delay */
static const struct e1000_option opt = {
.type = range_option,
.name = "Receive Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RADV),
.def = DEFAULT_RADV,
.arg = { .r = { .min = MIN_RXABSDELAY,
.max = MAX_RXABSDELAY } }
};
if (num_RxAbsIntDelay > bd) {
adapter->rx_abs_int_delay = RxAbsIntDelay[bd];
e1000_validate_option(&adapter->rx_abs_int_delay, &opt,
adapter);
} else {
adapter->rx_abs_int_delay = opt.def;
}
}
{ /* Interrupt Throttling Rate */
static const struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Throttling Rate (ints/sec)",
.err = "using default of "
__MODULE_STRING(DEFAULT_ITR),
.def = DEFAULT_ITR,
.arg = { .r = { .min = MIN_ITR,
.max = MAX_ITR } }
};
if (num_InterruptThrottleRate > bd) {
adapter->itr = InterruptThrottleRate[bd];
switch (adapter->itr) {
case 0:
e_info("%s turned off\n", opt.name);
break;
case 1:
e_info("%s set to dynamic mode\n", opt.name);
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
break;
case 3:
e_info("%s set to dynamic conservative mode\n",
opt.name);
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
break;
case 4:
e_info("%s set to simplified (2000-8000 ints) "
"mode\n", opt.name);
adapter->itr_setting = 4;
break;
default:
/*
* Save the setting, because the dynamic bits
* change itr.
*/
if (e1000_validate_option(&adapter->itr, &opt,
adapter) &&
(adapter->itr == 3)) {
/*
* In case of invalid user value,
* default to conservative mode.
*/
adapter->itr_setting = adapter->itr;
adapter->itr = 20000;
} else {
/*
* Clear the lower two bits because
* they are used as control.
*/
adapter->itr_setting =
adapter->itr & ~3;
}
break;
}
} else {
adapter->itr_setting = opt.def;
adapter->itr = 20000;
}
}
#ifdef CONFIG_E1000E_MSIX
{ /* Interrupt Mode */
static struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Mode",
.err = "defaulting to 2 (MSI-X)",
.def = E1000E_INT_MODE_MSIX,
.arg = { .r = { .min = MIN_INTMODE,
.max = MAX_INTMODE } }
};
if (num_IntMode > bd) {
unsigned int int_mode = IntMode[bd];
e1000_validate_option(&int_mode, &opt, adapter);
adapter->int_mode = int_mode;
} else {
adapter->int_mode = opt.def;
}
}
#endif /* CONFIG_E1000E_MSIX */
{ /* Smart Power Down */
static const struct e1000_option opt = {
.type = enable_option,
.name = "PHY Smart Power Down",
.err = "defaulting to Disabled",
.def = OPTION_DISABLED
};
if (num_SmartPowerDownEnable > bd) {
unsigned int spd = SmartPowerDownEnable[bd];
e1000_validate_option(&spd, &opt, adapter);
if ((adapter->flags & FLAG_HAS_SMART_POWER_DOWN)
&& spd)
adapter->flags |= FLAG_SMART_POWER_DOWN;
}
}
{ /* CRC Stripping */
static const struct e1000_option opt = {
.type = enable_option,
.name = "CRC Stripping",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (num_CrcStripping > bd) {
unsigned int crc_stripping = CrcStripping[bd];
e1000_validate_option(&crc_stripping, &opt, adapter);
if (crc_stripping == OPTION_ENABLED)
adapter->flags2 |= FLAG2_CRC_STRIPPING;
} else {
adapter->flags2 |= FLAG2_CRC_STRIPPING;
}
}
{ /* Kumeran Lock Loss Workaround */
static const struct e1000_option opt = {
.type = enable_option,
.name = "Kumeran Lock Loss Workaround",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (num_KumeranLockLoss > bd) {
unsigned int kmrn_lock_loss = KumeranLockLoss[bd];
e1000_validate_option(&kmrn_lock_loss, &opt, adapter);
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
kmrn_lock_loss);
} else {
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
opt.def);
}
}
{ /* EEE for parts supporting the feature */
static const struct e1000_option opt = {
.type = enable_option,
.name = "EEE Support",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (adapter->flags2 & FLAG2_HAS_EEE) {
/* Currently only supported on 82579 */
if (num_EEE > bd) {
unsigned int eee = EEE[bd];
e1000_validate_option(&eee, &opt, adapter);
hw->dev_spec.ich8lan.eee_disable = !eee;
} else {
hw->dev_spec.ich8lan.eee_disable = !opt.def;
}
}
}
{ /* configure node specific allocation */
static struct e1000_option opt = {
.type = range_option,
.name = "Node used to allocate memory",
.err = "defaulting to -1 (disabled)",
#ifdef HAVE_EARLY_VMALLOC_NODE
.def = 0,
#else
.def = -1,
#endif
.arg = { .r = { .min = 0,
.max = MAX_NUMNODES - 1 } }
};
int node = opt.def;
/* if the default was zero then we need to set the
* default value to an online node, which is not
* necessarily zero, and the constant initializer
* above can't take first_online_node */
if (node == 0)
/* must set opt.def for validate */
opt.def = node = first_online_node;
if (num_Node > bd) {
node = Node[bd];
e1000_validate_option((uint *)&node, &opt, adapter);
if (node != OPTION_UNSET)
e_info("node used for allocation: %d\n", node);
}
/* check sanity of the value */
if ((node != -1) && !node_online(node)) {
e_info("ignoring node set to invalid value %d\n", node);
node = opt.def;
}
adapter->node = node;
}
}
void __devinit e1000e_check_options(struct e1000_adapter *adapter)
{
struct e1000_hw *hw = &adapter->hw;
int bd = adapter->bd_number;
if (bd >= E1000_MAX_NIC) {
e_notice("Warning: no configuration for board #%i\n", bd);
e_notice("Using defaults for all values\n");
}
{
static const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TIDV),
.def = DEFAULT_TIDV,
.arg = { .r = { .min = MIN_TXDELAY,
.max = MAX_TXDELAY } }
};
if (num_TxIntDelay > bd) {
adapter->tx_int_delay = TxIntDelay[bd];
e1000_validate_option(&adapter->tx_int_delay, &opt,
adapter);
} else {
adapter->tx_int_delay = opt.def;
}
}
{
static const struct e1000_option opt = {
.type = range_option,
.name = "Transmit Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_TADV),
.def = DEFAULT_TADV,
.arg = { .r = { .min = MIN_TXABSDELAY,
.max = MAX_TXABSDELAY } }
};
if (num_TxAbsIntDelay > bd) {
adapter->tx_abs_int_delay = TxAbsIntDelay[bd];
e1000_validate_option(&adapter->tx_abs_int_delay, &opt,
adapter);
} else {
adapter->tx_abs_int_delay = opt.def;
}
}
{
static struct e1000_option opt = {
.type = range_option,
.name = "Receive Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RDTR),
.def = DEFAULT_RDTR,
.arg = { .r = { .min = MIN_RXDELAY,
.max = MAX_RXDELAY } }
};
if (num_RxIntDelay > bd) {
adapter->rx_int_delay = RxIntDelay[bd];
e1000_validate_option(&adapter->rx_int_delay, &opt,
adapter);
} else {
adapter->rx_int_delay = opt.def;
}
}
{
static const struct e1000_option opt = {
.type = range_option,
.name = "Receive Absolute Interrupt Delay",
.err = "using default of "
__MODULE_STRING(DEFAULT_RADV),
.def = DEFAULT_RADV,
.arg = { .r = { .min = MIN_RXABSDELAY,
.max = MAX_RXABSDELAY } }
};
if (num_RxAbsIntDelay > bd) {
adapter->rx_abs_int_delay = RxAbsIntDelay[bd];
e1000_validate_option(&adapter->rx_abs_int_delay, &opt,
adapter);
} else {
adapter->rx_abs_int_delay = opt.def;
}
}
{
static const struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Throttling Rate (ints/sec)",
.err = "using default of "
__MODULE_STRING(DEFAULT_ITR),
.def = DEFAULT_ITR,
.arg = { .r = { .min = MIN_ITR,
.max = MAX_ITR } }
};
if (num_InterruptThrottleRate > bd) {
adapter->itr = InterruptThrottleRate[bd];
if ((adapter->itr > 4) &&
e1000_validate_option(&adapter->itr, &opt, adapter))
adapter->itr = opt.def;
} else {
adapter->itr = opt.def;
if (adapter->itr > 40)
e_info("%s set to default %d\n", opt.name,
adapter->itr);
}
adapter->itr_setting = adapter->itr;
switch (adapter->itr) {
case 0:
e_info("%s turned off\n", opt.name);
break;
case 1:
e_info("%s set to dynamic mode\n", opt.name);
adapter->itr = 20000;
break;
case 3:
e_info("%s set to dynamic conservative mode\n",
opt.name);
adapter->itr = 20000;
break;
case 4:
e_info("%s set to simplified (2000-8000 ints) mode\n",
opt.name);
break;
default:
adapter->itr_setting &= ~3;
break;
}
}
{
static struct e1000_option opt = {
.type = range_option,
.name = "Interrupt Mode",
#ifndef CONFIG_PCI_MSI
.err = "defaulting to 0 (legacy)",
.def = E1000E_INT_MODE_LEGACY,
.arg = { .r = { .min = 0,
.max = 0 } }
#endif
};
#ifdef CONFIG_PCI_MSI
if (adapter->flags & FLAG_HAS_MSIX) {
opt.err = kstrdup("defaulting to 2 (MSI-X)",
GFP_KERNEL);
opt.def = E1000E_INT_MODE_MSIX;
opt.arg.r.max = E1000E_INT_MODE_MSIX;
} else {
opt.err = kstrdup("defaulting to 1 (MSI)", GFP_KERNEL);
opt.def = E1000E_INT_MODE_MSI;
opt.arg.r.max = E1000E_INT_MODE_MSI;
}
if (!opt.err) {
dev_err(&adapter->pdev->dev,
"Failed to allocate memory\n");
return;
}
#endif
if (num_IntMode > bd) {
unsigned int int_mode = IntMode[bd];
e1000_validate_option(&int_mode, &opt, adapter);
adapter->int_mode = int_mode;
} else {
adapter->int_mode = opt.def;
}
#ifdef CONFIG_PCI_MSI
kfree(opt.err);
#endif
}
{
static const struct e1000_option opt = {
.type = enable_option,
.name = "PHY Smart Power Down",
.err = "defaulting to Disabled",
.def = OPTION_DISABLED
};
if (num_SmartPowerDownEnable > bd) {
unsigned int spd = SmartPowerDownEnable[bd];
e1000_validate_option(&spd, &opt, adapter);
if ((adapter->flags & FLAG_HAS_SMART_POWER_DOWN)
&& spd)
adapter->flags |= FLAG_SMART_POWER_DOWN;
}
}
{
static const struct e1000_option opt = {
.type = enable_option,
.name = "CRC Stripping",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (num_CrcStripping > bd) {
unsigned int crc_stripping = CrcStripping[bd];
e1000_validate_option(&crc_stripping, &opt, adapter);
if (crc_stripping == OPTION_ENABLED) {
adapter->flags2 |= FLAG2_CRC_STRIPPING;
adapter->flags2 |= FLAG2_DFLT_CRC_STRIPPING;
}
} else {
adapter->flags2 |= FLAG2_CRC_STRIPPING;
adapter->flags2 |= FLAG2_DFLT_CRC_STRIPPING;
}
}
{
static const struct e1000_option opt = {
.type = enable_option,
.name = "Kumeran Lock Loss Workaround",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (num_KumeranLockLoss > bd) {
unsigned int kmrn_lock_loss = KumeranLockLoss[bd];
e1000_validate_option(&kmrn_lock_loss, &opt, adapter);
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
kmrn_lock_loss);
} else {
if (hw->mac.type == e1000_ich8lan)
e1000e_set_kmrn_lock_loss_workaround_ich8lan(hw,
opt.def);
}
}
{
static const struct e1000_option opt = {
.type = enable_option,
.name = "Write-protect NVM",
.err = "defaulting to Enabled",
.def = OPTION_ENABLED
};
if (adapter->flags & FLAG_IS_ICH) {
if (num_WriteProtectNVM > bd) {
unsigned int write_protect_nvm = WriteProtectNVM[bd];
e1000_validate_option(&write_protect_nvm, &opt,
adapter);
if (write_protect_nvm)
adapter->flags |= FLAG_READ_ONLY_NVM;
} else {
if (opt.def)
adapter->flags |= FLAG_READ_ONLY_NVM;
}
}
}
}
static int64_t opb_write(struct lpcm *lpc, uint32_t addr, uint32_t data,
uint32_t sz)
{
uint64_t ctl = ECCB_CTL_MAGIC, stat;
int64_t rc, tout;
uint64_t data_reg;
if (lpc->mbase)
return opb_mmio_write(lpc, addr, data, sz);
switch(sz) {
case 1:
data_reg = ((uint64_t)data) << 56;
break;
case 2:
data_reg = ((uint64_t)data) << 48;
break;
case 4:
data_reg = ((uint64_t)data) << 32;
break;
default:
prerror("Invalid data size %d\n", sz);
return OPAL_PARAMETER;
}
rc = xscom_write(lpc->chip_id, lpc->xbase + ECCB_DATA, data_reg);
if (rc) {
log_simple_error(&e_info(OPAL_RC_LPC_WRITE),
"LPC: XSCOM write to ECCB DATA error %lld\n", rc);
return rc;
}
ctl = SETFIELD(ECCB_CTL_DATASZ, ctl, sz);
ctl = SETFIELD(ECCB_CTL_ADDRLEN, ctl, ECCB_ADDRLEN_4B);
ctl = SETFIELD(ECCB_CTL_ADDR, ctl, addr);
rc = xscom_write(lpc->chip_id, lpc->xbase + ECCB_CTL, ctl);
if (rc) {
log_simple_error(&e_info(OPAL_RC_LPC_WRITE),
"LPC: XSCOM write to ECCB CTL error %lld\n", rc);
return rc;
}
for (tout = 0; tout < ECCB_TIMEOUT; tout++) {
rc = xscom_read(lpc->chip_id, lpc->xbase + ECCB_STAT,
&stat);
if (rc) {
log_simple_error(&e_info(OPAL_RC_LPC_WRITE),
"LPC: XSCOM read from ECCB STAT err %lld\n",
rc);
return rc;
}
if (stat & ECCB_STAT_OP_DONE) {
if (stat & ECCB_STAT_ERR_MASK) {
log_simple_error(&e_info(OPAL_RC_LPC_WRITE),
"LPC: Error status: 0x%llx\n", stat);
return OPAL_HARDWARE;
}
return OPAL_SUCCESS;
}
time_wait_nopoll(100);
}
log_simple_error(&e_info(OPAL_RC_LPC_WRITE), "LPC: Write timeout !\n");
return OPAL_HARDWARE;
}
