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|
// SPDX-License-Identifier: GPL-2.0-or-later
/*
* The file intends to implement PE based on the information from
* platforms. Basically, there have 3 types of PEs: PHB/Bus/Device.
* All the PEs should be organized as hierarchy tree. The first level
* of the tree will be associated to existing PHBs since the particular
* PE is only meaningful in one PHB domain.
*
* Copyright Benjamin Herrenschmidt & Gavin Shan, IBM Corporation 2012.
*/
#include <linux/delay.h>
#include <linux/export.h>
#include <linux/gfp.h>
#include <linux/kernel.h>
#include <linux/pci.h>
#include <linux/string.h>
#include <asm/pci-bridge.h>
#include <asm/ppc-pci.h>
static int eeh_pe_aux_size = 0;
static LIST_HEAD(eeh_phb_pe);
/**
* eeh_set_pe_aux_size - Set PE auxillary data size
* @size: PE auxillary data size
*
* Set PE auxillary data size
*/
void eeh_set_pe_aux_size(int size)
{
if (size < 0)
return;
eeh_pe_aux_size = size;
}
/**
* eeh_pe_alloc - Allocate PE
* @phb: PCI controller
* @type: PE type
*
* Allocate PE instance dynamically.
*/
static struct eeh_pe *eeh_pe_alloc(struct pci_controller *phb, int type)
{
struct eeh_pe *pe;
size_t alloc_size;
alloc_size = sizeof(struct eeh_pe);
if (eeh_pe_aux_size) {
alloc_size = ALIGN(alloc_size, cache_line_size());
alloc_size += eeh_pe_aux_size;
}
/* Allocate PHB PE */
pe = kzalloc(alloc_size, GFP_KERNEL);
if (!pe) return NULL;
/* Initialize PHB PE */
pe->type = type;
pe->phb = phb;
INIT_LIST_HEAD(&pe->child_list);
INIT_LIST_HEAD(&pe->edevs);
pe->data = (void *)pe + ALIGN(sizeof(struct eeh_pe),
cache_line_size());
return pe;
}
/**
* eeh_phb_pe_create - Create PHB PE
* @phb: PCI controller
*
* The function should be called while the PHB is detected during
* system boot or PCI hotplug in order to create PHB PE.
*/
int eeh_phb_pe_create(struct pci_controller *phb)
{
struct eeh_pe *pe;
/* Allocate PHB PE */
pe = eeh_pe_alloc(phb, EEH_PE_PHB);
if (!pe) {
pr_err("%s: out of memory!\n", __func__);
return -ENOMEM;
}
/* Put it into the list */
list_add_tail(&pe->child, &eeh_phb_pe);
pr_debug("EEH: Add PE for PHB#%x\n", phb->global_number);
return 0;
}
/**
* eeh_wait_state - Wait for PE state
* @pe: EEH PE
* @max_wait: maximal period in millisecond
*
* Wait for the state of associated PE. It might take some time
* to retrieve the PE's state.
*/
int eeh_wait_state(struct eeh_pe *pe, int max_wait)
{
int ret;
int mwait;
/*
* According to PAPR, the state of PE might be temporarily
* unavailable. Under the circumstance, we have to wait
* for indicated time determined by firmware. The maximal
* wait time is 5 minutes, which is acquired from the original
* EEH implementation. Also, the original implementation
* also defined the minimal wait time as 1 second.
*/
#define EEH_STATE_MIN_WAIT_TIME (1000)
#define EEH_STATE_MAX_WAIT_TIME (300 * 1000)
while (1) {
ret = eeh_ops->get_state(pe, &mwait);
if (ret != EEH_STATE_UNAVAILABLE)
return ret;
if (max_wait <= 0) {
pr_warn("%s: Timeout when getting PE's state (%d)\n",
__func__, max_wait);
return EEH_STATE_NOT_SUPPORT;
}
if (mwait < EEH_STATE_MIN_WAIT_TIME) {
pr_warn("%s: Firmware returned bad wait value %d\n",
__func__, mwait);
mwait = EEH_STATE_MIN_WAIT_TIME;
} else if (mwait > EEH_STATE_MAX_WAIT_TIME) {
pr_warn("%s: Firmware returned too long wait value %d\n",
__func__, mwait);
mwait = EEH_STATE_MAX_WAIT_TIME;
}
msleep(min(mwait, max_wait));
max_wait -= mwait;
}
}
/**
* eeh_phb_pe_get - Retrieve PHB PE based on the given PHB
* @phb: PCI controller
*
* The overall PEs form hierarchy tree. The first layer of the
* hierarchy tree is composed of PHB PEs. The function is used
* to retrieve the corresponding PHB PE according to the given PHB.
*/
struct eeh_pe *eeh_phb_pe_get(struct pci_controller *phb)
{
struct eeh_pe *pe;
list_for_each_entry(pe, &eeh_phb_pe, child) {
/*
* Actually, we needn't check the type since
* the PE for PHB has been determined when that
* was created.
*/
if ((pe->type & EEH_PE_PHB) && pe->phb == phb)
return pe;
}
return NULL;
}
/**
* eeh_pe_next - Retrieve the next PE in the tree
* @pe: current PE
* @root: root PE
*
* The function is used to retrieve the next PE in the
* hierarchy PE tree.
*/
struct eeh_pe *eeh_pe_next(struct eeh_pe *pe, struct eeh_pe *root)
{
struct list_head *next = pe->child_list.next;
if (next == &pe->child_list) {
while (1) {
if (pe == root)
return NULL;
next = pe->child.next;
if (next != &pe->parent->child_list)
break;
pe = pe->parent;
}
}
return list_entry(next, struct eeh_pe, child);
}
/**
* eeh_pe_traverse - Traverse PEs in the specified PHB
* @root: root PE
* @fn: callback
* @flag: extra parameter to callback
*
* The function is used to traverse the specified PE and its
* child PEs. The traversing is to be terminated once the
* callback returns something other than NULL, or no more PEs
* to be traversed.
*/
void *eeh_pe_traverse(struct eeh_pe *root,
eeh_pe_traverse_func fn, void *flag)
{
struct eeh_pe *pe;
void *ret;
eeh_for_each_pe(root, pe) {
ret = fn(pe, flag);
if (ret) return ret;
}
return NULL;
}
/**
* eeh_pe_dev_traverse - Traverse the devices from the PE
* @root: EEH PE
* @fn: function callback
* @flag: extra parameter to callback
*
* The function is used to traverse the devices of the specified
* PE and its child PEs.
*/
void eeh_pe_dev_traverse(struct eeh_pe *root,
eeh_edev_traverse_func fn, void *flag)
{
struct eeh_pe *pe;
struct eeh_dev *edev, *tmp;
if (!root) {
pr_warn("%s: Invalid PE %p\n",
__func__, root);
return;
}
/* Traverse root PE */
eeh_for_each_pe(root, pe)
eeh_pe_for_each_dev(pe, edev, tmp)
fn(edev, flag);
}
/**
* __eeh_pe_get - Check the PE address
* @data: EEH PE
* @flag: EEH device
*
* For one particular PE, it can be identified by PE address
* or tranditional BDF address. BDF address is composed of
* Bus/Device/Function number. The extra data referred by flag
* indicates which type of address should be used.
*/
struct eeh_pe_get_flag {
int pe_no;
int config_addr;
};
static void *__eeh_pe_get(struct eeh_pe *pe, void *flag)
{
struct eeh_pe_get_flag *tmp = (struct eeh_pe_get_flag *) flag;
/* Unexpected PHB PE */
if (pe->type & EEH_PE_PHB)
return NULL;
/*
* We prefer PE address. For most cases, we should
* have non-zero PE address
*/
if (eeh_has_flag(EEH_VALID_PE_ZERO)) {
if (tmp->pe_no == pe->addr)
return pe;
} else {
if (tmp->pe_no &&
(tmp->pe_no == pe->addr))
return pe;
}
/* Try BDF address */
if (tmp->config_addr &&
(tmp->config_addr == pe->config_addr))
return pe;
return NULL;
}
/**
* eeh_pe_get - Search PE based on the given address
* @phb: PCI controller
* @pe_no: PE number
* @config_addr: Config address
*
* Search the corresponding PE based on the specified address which
* is included in the eeh device. The function is used to check if
* the associated PE has been created against the PE address. It's
* notable that the PE address has 2 format: traditional PE address
* which is composed of PCI bus/device/function number, or unified
* PE address.
*/
struct eeh_pe *eeh_pe_get(struct pci_controller *phb,
int pe_no, int config_addr)
{
struct eeh_pe *root = eeh_phb_pe_get(phb);
struct eeh_pe_get_flag tmp = { pe_no, config_addr };
struct eeh_pe *pe;
pe = eeh_pe_traverse(root, __eeh_pe_get, &tmp);
return pe;
}
/**
* eeh_pe_get_parent - Retrieve the parent PE
* @edev: EEH device
*
* The whole PEs existing in the system are organized as hierarchy
* tree. The function is used to retrieve the parent PE according
* to the parent EEH device.
*/
static struct eeh_pe *eeh_pe_get_parent(struct eeh_dev *edev)
{
struct eeh_dev *parent;
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
/*
* It might have the case for the indirect parent
* EEH device already having associated PE, but
* the direct parent EEH device doesn't have yet.
*/
if (edev->physfn)
pdn = pci_get_pdn(edev->physfn);
else
pdn = pdn ? pdn->parent : NULL;
while (pdn) {
/* We're poking out of PCI territory */
parent = pdn_to_eeh_dev(pdn);
if (!parent)
return NULL;
if (parent->pe)
return parent->pe;
pdn = pdn->parent;
}
return NULL;
}
/**
* eeh_add_to_parent_pe - Add EEH device to parent PE
* @edev: EEH device
*
* Add EEH device to the parent PE. If the parent PE already
* exists, the PE type will be changed to EEH_PE_BUS. Otherwise,
* we have to create new PE to hold the EEH device and the new
* PE will be linked to its parent PE as well.
*/
int eeh_add_to_parent_pe(struct eeh_dev *edev)
{
struct eeh_pe *pe, *parent;
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
int config_addr = (pdn->busno << 8) | (pdn->devfn);
/* Check if the PE number is valid */
if (!eeh_has_flag(EEH_VALID_PE_ZERO) && !edev->pe_config_addr) {
eeh_edev_err(edev, "PE#0 is invalid for this PHB!\n");
return -EINVAL;
}
/*
* Search the PE has been existing or not according
* to the PE address. If that has been existing, the
* PE should be composed of PCI bus and its subordinate
* components.
*/
pe = eeh_pe_get(pdn->phb, edev->pe_config_addr, config_addr);
if (pe) {
if (pe->type & EEH_PE_INVALID) {
list_add_tail(&edev->entry, &pe->edevs);
edev->pe = pe;
/*
* We're running to here because of PCI hotplug caused by
* EEH recovery. We need clear EEH_PE_INVALID until the top.
*/
parent = pe;
while (parent) {
if (!(parent->type & EEH_PE_INVALID))
break;
parent->type &= ~EEH_PE_INVALID;
parent = parent->parent;
}
eeh_edev_dbg(edev,
"Added to device PE (parent: PE#%x)\n",
pe->parent->addr);
} else {
/* Mark the PE as type of PCI bus */
pe->type = EEH_PE_BUS;
edev->pe = pe;
/* Put the edev to PE */
list_add_tail(&edev->entry, &pe->edevs);
eeh_edev_dbg(edev, "Added to bus PE\n");
}
return 0;
}
/* Create a new EEH PE */
if (edev->physfn)
pe = eeh_pe_alloc(pdn->phb, EEH_PE_VF);
else
pe = eeh_pe_alloc(pdn->phb, EEH_PE_DEVICE);
if (!pe) {
pr_err("%s: out of memory!\n", __func__);
return -ENOMEM;
}
pe->addr = edev->pe_config_addr;
pe->config_addr = config_addr;
/*
* Put the new EEH PE into hierarchy tree. If the parent
* can't be found, the newly created PE will be attached
* to PHB directly. Otherwise, we have to associate the
* PE with its parent.
*/
parent = eeh_pe_get_parent(edev);
if (!parent) {
parent = eeh_phb_pe_get(pdn->phb);
if (!parent) {
pr_err("%s: No PHB PE is found (PHB Domain=%d)\n",
__func__, pdn->phb->global_number);
edev->pe = NULL;
kfree(pe);
return -EEXIST;
}
}
pe->parent = parent;
/*
* Put the newly created PE into the child list and
* link the EEH device accordingly.
*/
list_add_tail(&pe->child, &parent->child_list);
list_add_tail(&edev->entry, &pe->edevs);
edev->pe = pe;
eeh_edev_dbg(edev, "Added to device PE (parent: PE#%x)\n",
pe->parent->addr);
return 0;
}
/**
* eeh_rmv_from_parent_pe - Remove one EEH device from the associated PE
* @edev: EEH device
*
* The PE hierarchy tree might be changed when doing PCI hotplug.
* Also, the PCI devices or buses could be removed from the system
* during EEH recovery. So we have to call the function remove the
* corresponding PE accordingly if necessary.
*/
int eeh_rmv_from_parent_pe(struct eeh_dev *edev)
{
struct eeh_pe *pe, *parent, *child;
bool keep, recover;
int cnt;
pe = eeh_dev_to_pe(edev);
if (!pe) {
eeh_edev_dbg(edev, "No PE found for device.\n");
return -EEXIST;
}
/* Remove the EEH device */
edev->pe = NULL;
list_del(&edev->entry);
/*
* Check if the parent PE includes any EEH devices.
* If not, we should delete that. Also, we should
* delete the parent PE if it doesn't have associated
* child PEs and EEH devices.
*/
while (1) {
parent = pe->parent;
/* PHB PEs should never be removed */
if (pe->type & EEH_PE_PHB)
break;
/*
* XXX: KEEP is set while resetting a PE. I don't think it's
* ever set without RECOVERING also being set. I could
* be wrong though so catch that with a WARN.
*/
keep = !!(pe->state & EEH_PE_KEEP);
recover = !!(pe->state & EEH_PE_RECOVERING);
WARN_ON(keep && !recover);
if (!keep && !recover) {
if (list_empty(&pe->edevs) &&
list_empty(&pe->child_list)) {
list_del(&pe->child);
kfree(pe);
} else {
break;
}
} else {
/*
* Mark the PE as invalid. At the end of the recovery
* process any invalid PEs will be garbage collected.
*
* We need to delay the free()ing of them since we can
* remove edev's while traversing the PE tree which
* might trigger the removal of a PE and we can't
* deal with that (yet).
*/
if (list_empty(&pe->edevs)) {
cnt = 0;
list_for_each_entry(child, &pe->child_list, child) {
if (!(child->type & EEH_PE_INVALID)) {
cnt++;
break;
}
}
if (!cnt)
pe->type |= EEH_PE_INVALID;
else
break;
}
}
pe = parent;
}
return 0;
}
/**
* eeh_pe_update_time_stamp - Update PE's frozen time stamp
* @pe: EEH PE
*
* We have time stamp for each PE to trace its time of getting
* frozen in last hour. The function should be called to update
* the time stamp on first error of the specific PE. On the other
* handle, we needn't account for errors happened in last hour.
*/
void eeh_pe_update_time_stamp(struct eeh_pe *pe)
{
time64_t tstamp;
if (!pe) return;
if (pe->freeze_count <= 0) {
pe->freeze_count = 0;
pe->tstamp = ktime_get_seconds();
} else {
tstamp = ktime_get_seconds();
if (tstamp - pe->tstamp > 3600) {
pe->tstamp = tstamp;
pe->freeze_count = 0;
}
}
}
/**
* eeh_pe_state_mark - Mark specified state for PE and its associated device
* @pe: EEH PE
*
* EEH error affects the current PE and its child PEs. The function
* is used to mark appropriate state for the affected PEs and the
* associated devices.
*/
void eeh_pe_state_mark(struct eeh_pe *root, int state)
{
struct eeh_pe *pe;
eeh_for_each_pe(root, pe)
if (!(pe->state & EEH_PE_REMOVED))
pe->state |= state;
}
EXPORT_SYMBOL_GPL(eeh_pe_state_mark);
/**
* eeh_pe_mark_isolated
* @pe: EEH PE
*
* Record that a PE has been isolated by marking the PE and it's children as
* EEH_PE_ISOLATED (and EEH_PE_CFG_BLOCKED, if required) and their PCI devices
* as pci_channel_io_frozen.
*/
void eeh_pe_mark_isolated(struct eeh_pe *root)
{
struct eeh_pe *pe;
struct eeh_dev *edev;
struct pci_dev *pdev;
eeh_pe_state_mark(root, EEH_PE_ISOLATED);
eeh_for_each_pe(root, pe) {
list_for_each_entry(edev, &pe->edevs, entry) {
pdev = eeh_dev_to_pci_dev(edev);
if (pdev)
pdev->error_state = pci_channel_io_frozen;
}
/* Block PCI config access if required */
if (pe->state & EEH_PE_CFG_RESTRICTED)
pe->state |= EEH_PE_CFG_BLOCKED;
}
}
EXPORT_SYMBOL_GPL(eeh_pe_mark_isolated);
static void __eeh_pe_dev_mode_mark(struct eeh_dev *edev, void *flag)
{
int mode = *((int *)flag);
edev->mode |= mode;
}
/**
* eeh_pe_dev_state_mark - Mark state for all device under the PE
* @pe: EEH PE
*
* Mark specific state for all child devices of the PE.
*/
void eeh_pe_dev_mode_mark(struct eeh_pe *pe, int mode)
{
eeh_pe_dev_traverse(pe, __eeh_pe_dev_mode_mark, &mode);
}
/**
* eeh_pe_state_clear - Clear state for the PE
* @data: EEH PE
* @state: state
* @include_passed: include passed-through devices?
*
* The function is used to clear the indicated state from the
* given PE. Besides, we also clear the check count of the PE
* as well.
*/
void eeh_pe_state_clear(struct eeh_pe *root, int state, bool include_passed)
{
struct eeh_pe *pe;
struct eeh_dev *edev, *tmp;
struct pci_dev *pdev;
eeh_for_each_pe(root, pe) {
/* Keep the state of permanently removed PE intact */
if (pe->state & EEH_PE_REMOVED)
continue;
if (!include_passed && eeh_pe_passed(pe))
continue;
pe->state &= ~state;
/*
* Special treatment on clearing isolated state. Clear
* check count since last isolation and put all affected
* devices to normal state.
*/
if (!(state & EEH_PE_ISOLATED))
continue;
pe->check_count = 0;
eeh_pe_for_each_dev(pe, edev, tmp) {
pdev = eeh_dev_to_pci_dev(edev);
if (!pdev)
continue;
pdev->error_state = pci_channel_io_normal;
}
/* Unblock PCI config access if required */
if (pe->state & EEH_PE_CFG_RESTRICTED)
pe->state &= ~EEH_PE_CFG_BLOCKED;
}
}
/*
* Some PCI bridges (e.g. PLX bridges) have primary/secondary
* buses assigned explicitly by firmware, and we probably have
* lost that after reset. So we have to delay the check until
* the PCI-CFG registers have been restored for the parent
* bridge.
*
* Don't use normal PCI-CFG accessors, which probably has been
* blocked on normal path during the stage. So we need utilize
* eeh operations, which is always permitted.
*/
static void eeh_bridge_check_link(struct eeh_dev *edev)
{
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
int cap;
uint32_t val;
int timeout = 0;
/*
* We only check root port and downstream ports of
* PCIe switches
*/
if (!(edev->mode & (EEH_DEV_ROOT_PORT | EEH_DEV_DS_PORT)))
return;
eeh_edev_dbg(edev, "Checking PCIe link...\n");
/* Check slot status */
cap = edev->pcie_cap;
eeh_ops->read_config(pdn, cap + PCI_EXP_SLTSTA, 2, &val);
if (!(val & PCI_EXP_SLTSTA_PDS)) {
eeh_edev_dbg(edev, "No card in the slot (0x%04x) !\n", val);
return;
}
/* Check power status if we have the capability */
eeh_ops->read_config(pdn, cap + PCI_EXP_SLTCAP, 2, &val);
if (val & PCI_EXP_SLTCAP_PCP) {
eeh_ops->read_config(pdn, cap + PCI_EXP_SLTCTL, 2, &val);
if (val & PCI_EXP_SLTCTL_PCC) {
eeh_edev_dbg(edev, "In power-off state, power it on ...\n");
val &= ~(PCI_EXP_SLTCTL_PCC | PCI_EXP_SLTCTL_PIC);
val |= (0x0100 & PCI_EXP_SLTCTL_PIC);
eeh_ops->write_config(pdn, cap + PCI_EXP_SLTCTL, 2, val);
msleep(2 * 1000);
}
}
/* Enable link */
eeh_ops->read_config(pdn, cap + PCI_EXP_LNKCTL, 2, &val);
val &= ~PCI_EXP_LNKCTL_LD;
eeh_ops->write_config(pdn, cap + PCI_EXP_LNKCTL, 2, val);
/* Check link */
eeh_ops->read_config(pdn, cap + PCI_EXP_LNKCAP, 4, &val);
if (!(val & PCI_EXP_LNKCAP_DLLLARC)) {
eeh_edev_dbg(edev, "No link reporting capability (0x%08x) \n", val);
msleep(1000);
return;
}
/* Wait the link is up until timeout (5s) */
timeout = 0;
while (timeout < 5000) {
msleep(20);
timeout += 20;
eeh_ops->read_config(pdn, cap + PCI_EXP_LNKSTA, 2, &val);
if (val & PCI_EXP_LNKSTA_DLLLA)
break;
}
if (val & PCI_EXP_LNKSTA_DLLLA)
eeh_edev_dbg(edev, "Link up (%s)\n",
(val & PCI_EXP_LNKSTA_CLS_2_5GB) ? "2.5GB" : "5GB");
else
eeh_edev_dbg(edev, "Link not ready (0x%04x)\n", val);
}
#define BYTE_SWAP(OFF) (8*((OFF)/4)+3-(OFF))
#define SAVED_BYTE(OFF) (((u8 *)(edev->config_space))[BYTE_SWAP(OFF)])
static void eeh_restore_bridge_bars(struct eeh_dev *edev)
{
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
int i;
/*
* Device BARs: 0x10 - 0x18
* Bus numbers and windows: 0x18 - 0x30
*/
for (i = 4; i < 13; i++)
eeh_ops->write_config(pdn, i*4, 4, edev->config_space[i]);
/* Rom: 0x38 */
eeh_ops->write_config(pdn, 14*4, 4, edev->config_space[14]);
/* Cache line & Latency timer: 0xC 0xD */
eeh_ops->write_config(pdn, PCI_CACHE_LINE_SIZE, 1,
SAVED_BYTE(PCI_CACHE_LINE_SIZE));
eeh_ops->write_config(pdn, PCI_LATENCY_TIMER, 1,
SAVED_BYTE(PCI_LATENCY_TIMER));
/* Max latency, min grant, interrupt ping and line: 0x3C */
eeh_ops->write_config(pdn, 15*4, 4, edev->config_space[15]);
/* PCI Command: 0x4 */
eeh_ops->write_config(pdn, PCI_COMMAND, 4, edev->config_space[1] |
PCI_COMMAND_MEMORY | PCI_COMMAND_MASTER);
/* Check the PCIe link is ready */
eeh_bridge_check_link(edev);
}
static void eeh_restore_device_bars(struct eeh_dev *edev)
{
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
int i;
u32 cmd;
for (i = 4; i < 10; i++)
eeh_ops->write_config(pdn, i*4, 4, edev->config_space[i]);
/* 12 == Expansion ROM Address */
eeh_ops->write_config(pdn, 12*4, 4, edev->config_space[12]);
eeh_ops->write_config(pdn, PCI_CACHE_LINE_SIZE, 1,
SAVED_BYTE(PCI_CACHE_LINE_SIZE));
eeh_ops->write_config(pdn, PCI_LATENCY_TIMER, 1,
SAVED_BYTE(PCI_LATENCY_TIMER));
/* max latency, min grant, interrupt pin and line */
eeh_ops->write_config(pdn, 15*4, 4, edev->config_space[15]);
/*
* Restore PERR & SERR bits, some devices require it,
* don't touch the other command bits
*/
eeh_ops->read_config(pdn, PCI_COMMAND, 4, &cmd);
if (edev->config_space[1] & PCI_COMMAND_PARITY)
cmd |= PCI_COMMAND_PARITY;
else
cmd &= ~PCI_COMMAND_PARITY;
if (edev->config_space[1] & PCI_COMMAND_SERR)
cmd |= PCI_COMMAND_SERR;
else
cmd &= ~PCI_COMMAND_SERR;
eeh_ops->write_config(pdn, PCI_COMMAND, 4, cmd);
}
/**
* eeh_restore_one_device_bars - Restore the Base Address Registers for one device
* @data: EEH device
* @flag: Unused
*
* Loads the PCI configuration space base address registers,
* the expansion ROM base address, the latency timer, and etc.
* from the saved values in the device node.
*/
static void eeh_restore_one_device_bars(struct eeh_dev *edev, void *flag)
{
struct pci_dn *pdn = eeh_dev_to_pdn(edev);
/* Do special restore for bridges */
if (edev->mode & EEH_DEV_BRIDGE)
eeh_restore_bridge_bars(edev);
else
eeh_restore_device_bars(edev);
if (eeh_ops->restore_config && pdn)
eeh_ops->restore_config(pdn);
}
/**
* eeh_pe_restore_bars - Restore the PCI config space info
* @pe: EEH PE
*
* This routine performs a recursive walk to the children
* of this device as well.
*/
void eeh_pe_restore_bars(struct eeh_pe *pe)
{
/*
* We needn't take the EEH lock since eeh_pe_dev_traverse()
* will take that.
*/
eeh_pe_dev_traverse(pe, eeh_restore_one_device_bars, NULL);
}
/**
* eeh_pe_loc_get - Retrieve location code binding to the given PE
* @pe: EEH PE
*
* Retrieve the location code of the given PE. If the primary PE bus
* is root bus, we will grab location code from PHB device tree node
* or root port. Otherwise, the upstream bridge's device tree node
* of the primary PE bus will be checked for the location code.
*/
const char *eeh_pe_loc_get(struct eeh_pe *pe)
{
struct pci_bus *bus = eeh_pe_bus_get(pe);
struct device_node *dn;
const char *loc = NULL;
while (bus) {
dn = pci_bus_to_OF_node(bus);
if (!dn) {
bus = bus->parent;
continue;
}
if (pci_is_root_bus(bus))
loc = of_get_property(dn, "ibm,io-base-loc-code", NULL);
else
loc = of_get_property(dn, "ibm,slot-location-code",
NULL);
if (loc)
return loc;
bus = bus->parent;
}
return "N/A";
}
/**
* eeh_pe_bus_get - Retrieve PCI bus according to the given PE
* @pe: EEH PE
*
* Retrieve the PCI bus according to the given PE. Basically,
* there're 3 types of PEs: PHB/Bus/Device. For PHB PE, the
* primary PCI bus will be retrieved. The parent bus will be
* returned for BUS PE. However, we don't have associated PCI
* bus for DEVICE PE.
*/
struct pci_bus *eeh_pe_bus_get(struct eeh_pe *pe)
{
struct eeh_dev *edev;
struct pci_dev *pdev;
if (pe->type & EEH_PE_PHB)
return pe->phb->bus;
/* The primary bus might be cached during probe time */
if (pe->state & EEH_PE_PRI_BUS)
return pe->bus;
/* Retrieve the parent PCI bus of first (top) PCI device */
edev = list_first_entry_or_null(&pe->edevs, struct eeh_dev, entry);
pdev = eeh_dev_to_pci_dev(edev);
if (pdev)
return pdev->bus;
return NULL;
}
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