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|
// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) 2013-2017 ARM Limited, All Rights Reserved.
* Author: Marc Zyngier <marc.zyngier@arm.com>
*/
#include <linux/acpi.h>
#include <linux/acpi_iort.h>
#include <linux/bitfield.h>
#include <linux/bitmap.h>
#include <linux/cpu.h>
#include <linux/crash_dump.h>
#include <linux/delay.h>
#include <linux/efi.h>
#include <linux/interrupt.h>
#include <linux/iommu.h>
#include <linux/iopoll.h>
#include <linux/irqdomain.h>
#include <linux/list.h>
#include <linux/log2.h>
#include <linux/memblock.h>
#include <linux/mm.h>
#include <linux/msi.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/of_irq.h>
#include <linux/of_pci.h>
#include <linux/of_platform.h>
#include <linux/percpu.h>
#include <linux/slab.h>
#include <linux/syscore_ops.h>
#include <linux/irqchip.h>
#include <linux/irqchip/arm-gic-v3.h>
#include <linux/irqchip/arm-gic-v4.h>
#include <asm/cputype.h>
#include <asm/exception.h>
#include "irq-gic-common.h"
#define ITS_FLAGS_CMDQ_NEEDS_FLUSHING (1ULL << 0)
#define ITS_FLAGS_WORKAROUND_CAVIUM_22375 (1ULL << 1)
#define ITS_FLAGS_WORKAROUND_CAVIUM_23144 (1ULL << 2)
#define ITS_FLAGS_FORCE_NON_SHAREABLE (1ULL << 3)
#define RD_LOCAL_LPI_ENABLED BIT(0)
#define RD_LOCAL_PENDTABLE_PREALLOCATED BIT(1)
#define RD_LOCAL_MEMRESERVE_DONE BIT(2)
static u32 lpi_id_bits;
/*
* We allocate memory for PROPBASE to cover 2 ^ lpi_id_bits LPIs to
* deal with (one configuration byte per interrupt). PENDBASE has to
* be 64kB aligned (one bit per LPI, plus 8192 bits for SPI/PPI/SGI).
*/
#define LPI_NRBITS lpi_id_bits
#define LPI_PROPBASE_SZ ALIGN(BIT(LPI_NRBITS), SZ_64K)
#define LPI_PENDBASE_SZ ALIGN(BIT(LPI_NRBITS) / 8, SZ_64K)
#define LPI_PROP_DEFAULT_PRIO GICD_INT_DEF_PRI
/*
* Collection structure - just an ID, and a redistributor address to
* ping. We use one per CPU as a bag of interrupts assigned to this
* CPU.
*/
struct its_collection {
u64 target_address;
u16 col_id;
};
/*
* The ITS_BASER structure - contains memory information, cached
* value of BASER register configuration and ITS page size.
*/
struct its_baser {
void *base;
u64 val;
u32 order;
u32 psz;
};
struct its_device;
/*
* The ITS structure - contains most of the infrastructure, with the
* top-level MSI domain, the command queue, the collections, and the
* list of devices writing to it.
*
* dev_alloc_lock has to be taken for device allocations, while the
* spinlock must be taken to parse data structures such as the device
* list.
*/
struct its_node {
raw_spinlock_t lock;
struct mutex dev_alloc_lock;
struct list_head entry;
void __iomem *base;
void __iomem *sgir_base;
phys_addr_t phys_base;
struct its_cmd_block *cmd_base;
struct its_cmd_block *cmd_write;
struct its_baser tables[GITS_BASER_NR_REGS];
struct its_collection *collections;
struct fwnode_handle *fwnode_handle;
u64 (*get_msi_base)(struct its_device *its_dev);
u64 typer;
u64 cbaser_save;
u32 ctlr_save;
u32 mpidr;
struct list_head its_device_list;
u64 flags;
unsigned long list_nr;
int numa_node;
unsigned int msi_domain_flags;
u32 pre_its_base; /* for Socionext Synquacer */
int vlpi_redist_offset;
};
#define is_v4(its) (!!((its)->typer & GITS_TYPER_VLPIS))
#define is_v4_1(its) (!!((its)->typer & GITS_TYPER_VMAPP))
#define device_ids(its) (FIELD_GET(GITS_TYPER_DEVBITS, (its)->typer) + 1)
#define ITS_ITT_ALIGN SZ_256
/* The maximum number of VPEID bits supported by VLPI commands */
#define ITS_MAX_VPEID_BITS \
({ \
int nvpeid = 16; \
if (gic_rdists->has_rvpeid && \
gic_rdists->gicd_typer2 & GICD_TYPER2_VIL) \
nvpeid = 1 + (gic_rdists->gicd_typer2 & \
GICD_TYPER2_VID); \
\
nvpeid; \
})
#define ITS_MAX_VPEID (1 << (ITS_MAX_VPEID_BITS))
/* Convert page order to size in bytes */
#define PAGE_ORDER_TO_SIZE(o) (PAGE_SIZE << (o))
struct event_lpi_map {
unsigned long *lpi_map;
u16 *col_map;
irq_hw_number_t lpi_base;
int nr_lpis;
raw_spinlock_t vlpi_lock;
struct its_vm *vm;
struct its_vlpi_map *vlpi_maps;
int nr_vlpis;
};
/*
* The ITS view of a device - belongs to an ITS, owns an interrupt
* translation table, and a list of interrupts. If it some of its
* LPIs are injected into a guest (GICv4), the event_map.vm field
* indicates which one.
*/
struct its_device {
struct list_head entry;
struct its_node *its;
struct event_lpi_map event_map;
void *itt;
u32 nr_ites;
u32 device_id;
bool shared;
};
static struct {
raw_spinlock_t lock;
struct its_device *dev;
struct its_vpe **vpes;
int next_victim;
} vpe_proxy;
struct cpu_lpi_count {
atomic_t managed;
atomic_t unmanaged;
};
static DEFINE_PER_CPU(struct cpu_lpi_count, cpu_lpi_count);
static LIST_HEAD(its_nodes);
static DEFINE_RAW_SPINLOCK(its_lock);
static struct rdists *gic_rdists;
static struct irq_domain *its_parent;
static unsigned long its_list_map;
static u16 vmovp_seq_num;
static DEFINE_RAW_SPINLOCK(vmovp_lock);
static DEFINE_IDA(its_vpeid_ida);
#define gic_data_rdist() (raw_cpu_ptr(gic_rdists->rdist))
#define gic_data_rdist_cpu(cpu) (per_cpu_ptr(gic_rdists->rdist, cpu))
#define gic_data_rdist_rd_base() (gic_data_rdist()->rd_base)
#define gic_data_rdist_vlpi_base() (gic_data_rdist_rd_base() + SZ_128K)
/*
* Skip ITSs that have no vLPIs mapped, unless we're on GICv4.1, as we
* always have vSGIs mapped.
*/
static bool require_its_list_vmovp(struct its_vm *vm, struct its_node *its)
{
return (gic_rdists->has_rvpeid || vm->vlpi_count[its->list_nr]);
}
static bool rdists_support_shareable(void)
{
return !(gic_rdists->flags & RDIST_FLAGS_FORCE_NON_SHAREABLE);
}
static u16 get_its_list(struct its_vm *vm)
{
struct its_node *its;
unsigned long its_list = 0;
list_for_each_entry(its, &its_nodes, entry) {
if (!is_v4(its))
continue;
if (require_its_list_vmovp(vm, its))
__set_bit(its->list_nr, &its_list);
}
return (u16)its_list;
}
static inline u32 its_get_event_id(struct irq_data *d)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
return d->hwirq - its_dev->event_map.lpi_base;
}
static struct its_collection *dev_event_to_col(struct its_device *its_dev,
u32 event)
{
struct its_node *its = its_dev->its;
return its->collections + its_dev->event_map.col_map[event];
}
static struct its_vlpi_map *dev_event_to_vlpi_map(struct its_device *its_dev,
u32 event)
{
if (WARN_ON_ONCE(event >= its_dev->event_map.nr_lpis))
return NULL;
return &its_dev->event_map.vlpi_maps[event];
}
static struct its_vlpi_map *get_vlpi_map(struct irq_data *d)
{
if (irqd_is_forwarded_to_vcpu(d)) {
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
return dev_event_to_vlpi_map(its_dev, event);
}
return NULL;
}
static int vpe_to_cpuid_lock(struct its_vpe *vpe, unsigned long *flags)
{
raw_spin_lock_irqsave(&vpe->vpe_lock, *flags);
return vpe->col_idx;
}
static void vpe_to_cpuid_unlock(struct its_vpe *vpe, unsigned long flags)
{
raw_spin_unlock_irqrestore(&vpe->vpe_lock, flags);
}
static struct irq_chip its_vpe_irq_chip;
static int irq_to_cpuid_lock(struct irq_data *d, unsigned long *flags)
{
struct its_vpe *vpe = NULL;
int cpu;
if (d->chip == &its_vpe_irq_chip) {
vpe = irq_data_get_irq_chip_data(d);
} else {
struct its_vlpi_map *map = get_vlpi_map(d);
if (map)
vpe = map->vpe;
}
if (vpe) {
cpu = vpe_to_cpuid_lock(vpe, flags);
} else {
/* Physical LPIs are already locked via the irq_desc lock */
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
cpu = its_dev->event_map.col_map[its_get_event_id(d)];
/* Keep GCC quiet... */
*flags = 0;
}
return cpu;
}
static void irq_to_cpuid_unlock(struct irq_data *d, unsigned long flags)
{
struct its_vpe *vpe = NULL;
if (d->chip == &its_vpe_irq_chip) {
vpe = irq_data_get_irq_chip_data(d);
} else {
struct its_vlpi_map *map = get_vlpi_map(d);
if (map)
vpe = map->vpe;
}
if (vpe)
vpe_to_cpuid_unlock(vpe, flags);
}
static struct its_collection *valid_col(struct its_collection *col)
{
if (WARN_ON_ONCE(col->target_address & GENMASK_ULL(15, 0)))
return NULL;
return col;
}
static struct its_vpe *valid_vpe(struct its_node *its, struct its_vpe *vpe)
{
if (valid_col(its->collections + vpe->col_idx))
return vpe;
return NULL;
}
/*
* ITS command descriptors - parameters to be encoded in a command
* block.
*/
struct its_cmd_desc {
union {
struct {
struct its_device *dev;
u32 event_id;
} its_inv_cmd;
struct {
struct its_device *dev;
u32 event_id;
} its_clear_cmd;
struct {
struct its_device *dev;
u32 event_id;
} its_int_cmd;
struct {
struct its_device *dev;
int valid;
} its_mapd_cmd;
struct {
struct its_collection *col;
int valid;
} its_mapc_cmd;
struct {
struct its_device *dev;
u32 phys_id;
u32 event_id;
} its_mapti_cmd;
struct {
struct its_device *dev;
struct its_collection *col;
u32 event_id;
} its_movi_cmd;
struct {
struct its_device *dev;
u32 event_id;
} its_discard_cmd;
struct {
struct its_collection *col;
} its_invall_cmd;
struct {
struct its_vpe *vpe;
} its_vinvall_cmd;
struct {
struct its_vpe *vpe;
struct its_collection *col;
bool valid;
} its_vmapp_cmd;
struct {
struct its_vpe *vpe;
struct its_device *dev;
u32 virt_id;
u32 event_id;
bool db_enabled;
} its_vmapti_cmd;
struct {
struct its_vpe *vpe;
struct its_device *dev;
u32 event_id;
bool db_enabled;
} its_vmovi_cmd;
struct {
struct its_vpe *vpe;
struct its_collection *col;
u16 seq_num;
u16 its_list;
} its_vmovp_cmd;
struct {
struct its_vpe *vpe;
} its_invdb_cmd;
struct {
struct its_vpe *vpe;
u8 sgi;
u8 priority;
bool enable;
bool group;
bool clear;
} its_vsgi_cmd;
};
};
/*
* The ITS command block, which is what the ITS actually parses.
*/
struct its_cmd_block {
union {
u64 raw_cmd[4];
__le64 raw_cmd_le[4];
};
};
#define ITS_CMD_QUEUE_SZ SZ_64K
#define ITS_CMD_QUEUE_NR_ENTRIES (ITS_CMD_QUEUE_SZ / sizeof(struct its_cmd_block))
typedef struct its_collection *(*its_cmd_builder_t)(struct its_node *,
struct its_cmd_block *,
struct its_cmd_desc *);
typedef struct its_vpe *(*its_cmd_vbuilder_t)(struct its_node *,
struct its_cmd_block *,
struct its_cmd_desc *);
static void its_mask_encode(u64 *raw_cmd, u64 val, int h, int l)
{
u64 mask = GENMASK_ULL(h, l);
*raw_cmd &= ~mask;
*raw_cmd |= (val << l) & mask;
}
static void its_encode_cmd(struct its_cmd_block *cmd, u8 cmd_nr)
{
its_mask_encode(&cmd->raw_cmd[0], cmd_nr, 7, 0);
}
static void its_encode_devid(struct its_cmd_block *cmd, u32 devid)
{
its_mask_encode(&cmd->raw_cmd[0], devid, 63, 32);
}
static void its_encode_event_id(struct its_cmd_block *cmd, u32 id)
{
its_mask_encode(&cmd->raw_cmd[1], id, 31, 0);
}
static void its_encode_phys_id(struct its_cmd_block *cmd, u32 phys_id)
{
its_mask_encode(&cmd->raw_cmd[1], phys_id, 63, 32);
}
static void its_encode_size(struct its_cmd_block *cmd, u8 size)
{
its_mask_encode(&cmd->raw_cmd[1], size, 4, 0);
}
static void its_encode_itt(struct its_cmd_block *cmd, u64 itt_addr)
{
its_mask_encode(&cmd->raw_cmd[2], itt_addr >> 8, 51, 8);
}
static void its_encode_valid(struct its_cmd_block *cmd, int valid)
{
its_mask_encode(&cmd->raw_cmd[2], !!valid, 63, 63);
}
static void its_encode_target(struct its_cmd_block *cmd, u64 target_addr)
{
its_mask_encode(&cmd->raw_cmd[2], target_addr >> 16, 51, 16);
}
static void its_encode_collection(struct its_cmd_block *cmd, u16 col)
{
its_mask_encode(&cmd->raw_cmd[2], col, 15, 0);
}
static void its_encode_vpeid(struct its_cmd_block *cmd, u16 vpeid)
{
its_mask_encode(&cmd->raw_cmd[1], vpeid, 47, 32);
}
static void its_encode_virt_id(struct its_cmd_block *cmd, u32 virt_id)
{
its_mask_encode(&cmd->raw_cmd[2], virt_id, 31, 0);
}
static void its_encode_db_phys_id(struct its_cmd_block *cmd, u32 db_phys_id)
{
its_mask_encode(&cmd->raw_cmd[2], db_phys_id, 63, 32);
}
static void its_encode_db_valid(struct its_cmd_block *cmd, bool db_valid)
{
its_mask_encode(&cmd->raw_cmd[2], db_valid, 0, 0);
}
static void its_encode_seq_num(struct its_cmd_block *cmd, u16 seq_num)
{
its_mask_encode(&cmd->raw_cmd[0], seq_num, 47, 32);
}
static void its_encode_its_list(struct its_cmd_block *cmd, u16 its_list)
{
its_mask_encode(&cmd->raw_cmd[1], its_list, 15, 0);
}
static void its_encode_vpt_addr(struct its_cmd_block *cmd, u64 vpt_pa)
{
its_mask_encode(&cmd->raw_cmd[3], vpt_pa >> 16, 51, 16);
}
static void its_encode_vpt_size(struct its_cmd_block *cmd, u8 vpt_size)
{
its_mask_encode(&cmd->raw_cmd[3], vpt_size, 4, 0);
}
static void its_encode_vconf_addr(struct its_cmd_block *cmd, u64 vconf_pa)
{
its_mask_encode(&cmd->raw_cmd[0], vconf_pa >> 16, 51, 16);
}
static void its_encode_alloc(struct its_cmd_block *cmd, bool alloc)
{
its_mask_encode(&cmd->raw_cmd[0], alloc, 8, 8);
}
static void its_encode_ptz(struct its_cmd_block *cmd, bool ptz)
{
its_mask_encode(&cmd->raw_cmd[0], ptz, 9, 9);
}
static void its_encode_vmapp_default_db(struct its_cmd_block *cmd,
u32 vpe_db_lpi)
{
its_mask_encode(&cmd->raw_cmd[1], vpe_db_lpi, 31, 0);
}
static void its_encode_vmovp_default_db(struct its_cmd_block *cmd,
u32 vpe_db_lpi)
{
its_mask_encode(&cmd->raw_cmd[3], vpe_db_lpi, 31, 0);
}
static void its_encode_db(struct its_cmd_block *cmd, bool db)
{
its_mask_encode(&cmd->raw_cmd[2], db, 63, 63);
}
static void its_encode_sgi_intid(struct its_cmd_block *cmd, u8 sgi)
{
its_mask_encode(&cmd->raw_cmd[0], sgi, 35, 32);
}
static void its_encode_sgi_priority(struct its_cmd_block *cmd, u8 prio)
{
its_mask_encode(&cmd->raw_cmd[0], prio >> 4, 23, 20);
}
static void its_encode_sgi_group(struct its_cmd_block *cmd, bool grp)
{
its_mask_encode(&cmd->raw_cmd[0], grp, 10, 10);
}
static void its_encode_sgi_clear(struct its_cmd_block *cmd, bool clr)
{
its_mask_encode(&cmd->raw_cmd[0], clr, 9, 9);
}
static void its_encode_sgi_enable(struct its_cmd_block *cmd, bool en)
{
its_mask_encode(&cmd->raw_cmd[0], en, 8, 8);
}
static inline void its_fixup_cmd(struct its_cmd_block *cmd)
{
/* Let's fixup BE commands */
cmd->raw_cmd_le[0] = cpu_to_le64(cmd->raw_cmd[0]);
cmd->raw_cmd_le[1] = cpu_to_le64(cmd->raw_cmd[1]);
cmd->raw_cmd_le[2] = cpu_to_le64(cmd->raw_cmd[2]);
cmd->raw_cmd_le[3] = cpu_to_le64(cmd->raw_cmd[3]);
}
static struct its_collection *its_build_mapd_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
unsigned long itt_addr;
u8 size = ilog2(desc->its_mapd_cmd.dev->nr_ites);
itt_addr = virt_to_phys(desc->its_mapd_cmd.dev->itt);
itt_addr = ALIGN(itt_addr, ITS_ITT_ALIGN);
its_encode_cmd(cmd, GITS_CMD_MAPD);
its_encode_devid(cmd, desc->its_mapd_cmd.dev->device_id);
its_encode_size(cmd, size - 1);
its_encode_itt(cmd, itt_addr);
its_encode_valid(cmd, desc->its_mapd_cmd.valid);
its_fixup_cmd(cmd);
return NULL;
}
static struct its_collection *its_build_mapc_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
its_encode_cmd(cmd, GITS_CMD_MAPC);
its_encode_collection(cmd, desc->its_mapc_cmd.col->col_id);
its_encode_target(cmd, desc->its_mapc_cmd.col->target_address);
its_encode_valid(cmd, desc->its_mapc_cmd.valid);
its_fixup_cmd(cmd);
return desc->its_mapc_cmd.col;
}
static struct its_collection *its_build_mapti_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_mapti_cmd.dev,
desc->its_mapti_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_MAPTI);
its_encode_devid(cmd, desc->its_mapti_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_mapti_cmd.event_id);
its_encode_phys_id(cmd, desc->its_mapti_cmd.phys_id);
its_encode_collection(cmd, col->col_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_movi_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_movi_cmd.dev,
desc->its_movi_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_MOVI);
its_encode_devid(cmd, desc->its_movi_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_movi_cmd.event_id);
its_encode_collection(cmd, desc->its_movi_cmd.col->col_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_discard_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_discard_cmd.dev,
desc->its_discard_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_DISCARD);
its_encode_devid(cmd, desc->its_discard_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_discard_cmd.event_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_inv_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_inv_cmd.dev,
desc->its_inv_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_INV);
its_encode_devid(cmd, desc->its_inv_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_inv_cmd.event_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_int_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_int_cmd.dev,
desc->its_int_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_INT);
its_encode_devid(cmd, desc->its_int_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_int_cmd.event_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_clear_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_collection *col;
col = dev_event_to_col(desc->its_clear_cmd.dev,
desc->its_clear_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_CLEAR);
its_encode_devid(cmd, desc->its_clear_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_clear_cmd.event_id);
its_fixup_cmd(cmd);
return valid_col(col);
}
static struct its_collection *its_build_invall_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
its_encode_cmd(cmd, GITS_CMD_INVALL);
its_encode_collection(cmd, desc->its_invall_cmd.col->col_id);
its_fixup_cmd(cmd);
return desc->its_invall_cmd.col;
}
static struct its_vpe *its_build_vinvall_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
its_encode_cmd(cmd, GITS_CMD_VINVALL);
its_encode_vpeid(cmd, desc->its_vinvall_cmd.vpe->vpe_id);
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vinvall_cmd.vpe);
}
static struct its_vpe *its_build_vmapp_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
unsigned long vpt_addr, vconf_addr;
u64 target;
bool alloc;
its_encode_cmd(cmd, GITS_CMD_VMAPP);
its_encode_vpeid(cmd, desc->its_vmapp_cmd.vpe->vpe_id);
its_encode_valid(cmd, desc->its_vmapp_cmd.valid);
if (!desc->its_vmapp_cmd.valid) {
if (is_v4_1(its)) {
alloc = !atomic_dec_return(&desc->its_vmapp_cmd.vpe->vmapp_count);
its_encode_alloc(cmd, alloc);
}
goto out;
}
vpt_addr = virt_to_phys(page_address(desc->its_vmapp_cmd.vpe->vpt_page));
target = desc->its_vmapp_cmd.col->target_address + its->vlpi_redist_offset;
its_encode_target(cmd, target);
its_encode_vpt_addr(cmd, vpt_addr);
its_encode_vpt_size(cmd, LPI_NRBITS - 1);
if (!is_v4_1(its))
goto out;
vconf_addr = virt_to_phys(page_address(desc->its_vmapp_cmd.vpe->its_vm->vprop_page));
alloc = !atomic_fetch_inc(&desc->its_vmapp_cmd.vpe->vmapp_count);
its_encode_alloc(cmd, alloc);
/*
* GICv4.1 provides a way to get the VLPI state, which needs the vPE
* to be unmapped first, and in this case, we may remap the vPE
* back while the VPT is not empty. So we can't assume that the
* VPT is empty on map. This is why we never advertise PTZ.
*/
its_encode_ptz(cmd, false);
its_encode_vconf_addr(cmd, vconf_addr);
its_encode_vmapp_default_db(cmd, desc->its_vmapp_cmd.vpe->vpe_db_lpi);
out:
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vmapp_cmd.vpe);
}
static struct its_vpe *its_build_vmapti_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
u32 db;
if (!is_v4_1(its) && desc->its_vmapti_cmd.db_enabled)
db = desc->its_vmapti_cmd.vpe->vpe_db_lpi;
else
db = 1023;
its_encode_cmd(cmd, GITS_CMD_VMAPTI);
its_encode_devid(cmd, desc->its_vmapti_cmd.dev->device_id);
its_encode_vpeid(cmd, desc->its_vmapti_cmd.vpe->vpe_id);
its_encode_event_id(cmd, desc->its_vmapti_cmd.event_id);
its_encode_db_phys_id(cmd, db);
its_encode_virt_id(cmd, desc->its_vmapti_cmd.virt_id);
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vmapti_cmd.vpe);
}
static struct its_vpe *its_build_vmovi_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
u32 db;
if (!is_v4_1(its) && desc->its_vmovi_cmd.db_enabled)
db = desc->its_vmovi_cmd.vpe->vpe_db_lpi;
else
db = 1023;
its_encode_cmd(cmd, GITS_CMD_VMOVI);
its_encode_devid(cmd, desc->its_vmovi_cmd.dev->device_id);
its_encode_vpeid(cmd, desc->its_vmovi_cmd.vpe->vpe_id);
its_encode_event_id(cmd, desc->its_vmovi_cmd.event_id);
its_encode_db_phys_id(cmd, db);
its_encode_db_valid(cmd, true);
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vmovi_cmd.vpe);
}
static struct its_vpe *its_build_vmovp_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
u64 target;
target = desc->its_vmovp_cmd.col->target_address + its->vlpi_redist_offset;
its_encode_cmd(cmd, GITS_CMD_VMOVP);
its_encode_seq_num(cmd, desc->its_vmovp_cmd.seq_num);
its_encode_its_list(cmd, desc->its_vmovp_cmd.its_list);
its_encode_vpeid(cmd, desc->its_vmovp_cmd.vpe->vpe_id);
its_encode_target(cmd, target);
if (is_v4_1(its)) {
its_encode_db(cmd, true);
its_encode_vmovp_default_db(cmd, desc->its_vmovp_cmd.vpe->vpe_db_lpi);
}
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vmovp_cmd.vpe);
}
static struct its_vpe *its_build_vinv_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_vlpi_map *map;
map = dev_event_to_vlpi_map(desc->its_inv_cmd.dev,
desc->its_inv_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_INV);
its_encode_devid(cmd, desc->its_inv_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_inv_cmd.event_id);
its_fixup_cmd(cmd);
return valid_vpe(its, map->vpe);
}
static struct its_vpe *its_build_vint_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_vlpi_map *map;
map = dev_event_to_vlpi_map(desc->its_int_cmd.dev,
desc->its_int_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_INT);
its_encode_devid(cmd, desc->its_int_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_int_cmd.event_id);
its_fixup_cmd(cmd);
return valid_vpe(its, map->vpe);
}
static struct its_vpe *its_build_vclear_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
struct its_vlpi_map *map;
map = dev_event_to_vlpi_map(desc->its_clear_cmd.dev,
desc->its_clear_cmd.event_id);
its_encode_cmd(cmd, GITS_CMD_CLEAR);
its_encode_devid(cmd, desc->its_clear_cmd.dev->device_id);
its_encode_event_id(cmd, desc->its_clear_cmd.event_id);
its_fixup_cmd(cmd);
return valid_vpe(its, map->vpe);
}
static struct its_vpe *its_build_invdb_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
if (WARN_ON(!is_v4_1(its)))
return NULL;
its_encode_cmd(cmd, GITS_CMD_INVDB);
its_encode_vpeid(cmd, desc->its_invdb_cmd.vpe->vpe_id);
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_invdb_cmd.vpe);
}
static struct its_vpe *its_build_vsgi_cmd(struct its_node *its,
struct its_cmd_block *cmd,
struct its_cmd_desc *desc)
{
if (WARN_ON(!is_v4_1(its)))
return NULL;
its_encode_cmd(cmd, GITS_CMD_VSGI);
its_encode_vpeid(cmd, desc->its_vsgi_cmd.vpe->vpe_id);
its_encode_sgi_intid(cmd, desc->its_vsgi_cmd.sgi);
its_encode_sgi_priority(cmd, desc->its_vsgi_cmd.priority);
its_encode_sgi_group(cmd, desc->its_vsgi_cmd.group);
its_encode_sgi_clear(cmd, desc->its_vsgi_cmd.clear);
its_encode_sgi_enable(cmd, desc->its_vsgi_cmd.enable);
its_fixup_cmd(cmd);
return valid_vpe(its, desc->its_vsgi_cmd.vpe);
}
static u64 its_cmd_ptr_to_offset(struct its_node *its,
struct its_cmd_block *ptr)
{
return (ptr - its->cmd_base) * sizeof(*ptr);
}
static int its_queue_full(struct its_node *its)
{
int widx;
int ridx;
widx = its->cmd_write - its->cmd_base;
ridx = readl_relaxed(its->base + GITS_CREADR) / sizeof(struct its_cmd_block);
/* This is incredibly unlikely to happen, unless the ITS locks up. */
if (((widx + 1) % ITS_CMD_QUEUE_NR_ENTRIES) == ridx)
return 1;
return 0;
}
static struct its_cmd_block *its_allocate_entry(struct its_node *its)
{
struct its_cmd_block *cmd;
u32 count = 1000000; /* 1s! */
while (its_queue_full(its)) {
count--;
if (!count) {
pr_err_ratelimited("ITS queue not draining\n");
return NULL;
}
cpu_relax();
udelay(1);
}
cmd = its->cmd_write++;
/* Handle queue wrapping */
if (its->cmd_write == (its->cmd_base + ITS_CMD_QUEUE_NR_ENTRIES))
its->cmd_write = its->cmd_base;
/* Clear command */
cmd->raw_cmd[0] = 0;
cmd->raw_cmd[1] = 0;
cmd->raw_cmd[2] = 0;
cmd->raw_cmd[3] = 0;
return cmd;
}
static struct its_cmd_block *its_post_commands(struct its_node *its)
{
u64 wr = its_cmd_ptr_to_offset(its, its->cmd_write);
writel_relaxed(wr, its->base + GITS_CWRITER);
return its->cmd_write;
}
static void its_flush_cmd(struct its_node *its, struct its_cmd_block *cmd)
{
/*
* Make sure the commands written to memory are observable by
* the ITS.
*/
if (its->flags & ITS_FLAGS_CMDQ_NEEDS_FLUSHING)
gic_flush_dcache_to_poc(cmd, sizeof(*cmd));
else
dsb(ishst);
}
static int its_wait_for_range_completion(struct its_node *its,
u64 prev_idx,
struct its_cmd_block *to)
{
u64 rd_idx, to_idx, linear_idx;
u32 count = 1000000; /* 1s! */
/* Linearize to_idx if the command set has wrapped around */
to_idx = its_cmd_ptr_to_offset(its, to);
if (to_idx < prev_idx)
to_idx += ITS_CMD_QUEUE_SZ;
linear_idx = prev_idx;
while (1) {
s64 delta;
rd_idx = readl_relaxed(its->base + GITS_CREADR);
/*
* Compute the read pointer progress, taking the
* potential wrap-around into account.
*/
delta = rd_idx - prev_idx;
if (rd_idx < prev_idx)
delta += ITS_CMD_QUEUE_SZ;
linear_idx += delta;
if (linear_idx >= to_idx)
break;
count--;
if (!count) {
pr_err_ratelimited("ITS queue timeout (%llu %llu)\n",
to_idx, linear_idx);
return -1;
}
prev_idx = rd_idx;
cpu_relax();
udelay(1);
}
return 0;
}
/* Warning, macro hell follows */
#define BUILD_SINGLE_CMD_FUNC(name, buildtype, synctype, buildfn) \
void name(struct its_node *its, \
buildtype builder, \
struct its_cmd_desc *desc) \
{ \
struct its_cmd_block *cmd, *sync_cmd, *next_cmd; \
synctype *sync_obj; \
unsigned long flags; \
u64 rd_idx; \
\
raw_spin_lock_irqsave(&its->lock, flags); \
\
cmd = its_allocate_entry(its); \
if (!cmd) { /* We're soooooo screewed... */ \
raw_spin_unlock_irqrestore(&its->lock, flags); \
return; \
} \
sync_obj = builder(its, cmd, desc); \
its_flush_cmd(its, cmd); \
\
if (sync_obj) { \
sync_cmd = its_allocate_entry(its); \
if (!sync_cmd) \
goto post; \
\
buildfn(its, sync_cmd, sync_obj); \
its_flush_cmd(its, sync_cmd); \
} \
\
post: \
rd_idx = readl_relaxed(its->base + GITS_CREADR); \
next_cmd = its_post_commands(its); \
raw_spin_unlock_irqrestore(&its->lock, flags); \
\
if (its_wait_for_range_completion(its, rd_idx, next_cmd)) \
pr_err_ratelimited("ITS cmd %ps failed\n", builder); \
}
static void its_build_sync_cmd(struct its_node *its,
struct its_cmd_block *sync_cmd,
struct its_collection *sync_col)
{
its_encode_cmd(sync_cmd, GITS_CMD_SYNC);
its_encode_target(sync_cmd, sync_col->target_address);
its_fixup_cmd(sync_cmd);
}
static BUILD_SINGLE_CMD_FUNC(its_send_single_command, its_cmd_builder_t,
struct its_collection, its_build_sync_cmd)
static void its_build_vsync_cmd(struct its_node *its,
struct its_cmd_block *sync_cmd,
struct its_vpe *sync_vpe)
{
its_encode_cmd(sync_cmd, GITS_CMD_VSYNC);
its_encode_vpeid(sync_cmd, sync_vpe->vpe_id);
its_fixup_cmd(sync_cmd);
}
static BUILD_SINGLE_CMD_FUNC(its_send_single_vcommand, its_cmd_vbuilder_t,
struct its_vpe, its_build_vsync_cmd)
static void its_send_int(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
desc.its_int_cmd.dev = dev;
desc.its_int_cmd.event_id = event_id;
its_send_single_command(dev->its, its_build_int_cmd, &desc);
}
static void its_send_clear(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
desc.its_clear_cmd.dev = dev;
desc.its_clear_cmd.event_id = event_id;
its_send_single_command(dev->its, its_build_clear_cmd, &desc);
}
static void its_send_inv(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
desc.its_inv_cmd.dev = dev;
desc.its_inv_cmd.event_id = event_id;
its_send_single_command(dev->its, its_build_inv_cmd, &desc);
}
static void its_send_mapd(struct its_device *dev, int valid)
{
struct its_cmd_desc desc;
desc.its_mapd_cmd.dev = dev;
desc.its_mapd_cmd.valid = !!valid;
its_send_single_command(dev->its, its_build_mapd_cmd, &desc);
}
static void its_send_mapc(struct its_node *its, struct its_collection *col,
int valid)
{
struct its_cmd_desc desc;
desc.its_mapc_cmd.col = col;
desc.its_mapc_cmd.valid = !!valid;
its_send_single_command(its, its_build_mapc_cmd, &desc);
}
static void its_send_mapti(struct its_device *dev, u32 irq_id, u32 id)
{
struct its_cmd_desc desc;
desc.its_mapti_cmd.dev = dev;
desc.its_mapti_cmd.phys_id = irq_id;
desc.its_mapti_cmd.event_id = id;
its_send_single_command(dev->its, its_build_mapti_cmd, &desc);
}
static void its_send_movi(struct its_device *dev,
struct its_collection *col, u32 id)
{
struct its_cmd_desc desc;
desc.its_movi_cmd.dev = dev;
desc.its_movi_cmd.col = col;
desc.its_movi_cmd.event_id = id;
its_send_single_command(dev->its, its_build_movi_cmd, &desc);
}
static void its_send_discard(struct its_device *dev, u32 id)
{
struct its_cmd_desc desc;
desc.its_discard_cmd.dev = dev;
desc.its_discard_cmd.event_id = id;
its_send_single_command(dev->its, its_build_discard_cmd, &desc);
}
static void its_send_invall(struct its_node *its, struct its_collection *col)
{
struct its_cmd_desc desc;
desc.its_invall_cmd.col = col;
its_send_single_command(its, its_build_invall_cmd, &desc);
}
static void its_send_vmapti(struct its_device *dev, u32 id)
{
struct its_vlpi_map *map = dev_event_to_vlpi_map(dev, id);
struct its_cmd_desc desc;
desc.its_vmapti_cmd.vpe = map->vpe;
desc.its_vmapti_cmd.dev = dev;
desc.its_vmapti_cmd.virt_id = map->vintid;
desc.its_vmapti_cmd.event_id = id;
desc.its_vmapti_cmd.db_enabled = map->db_enabled;
its_send_single_vcommand(dev->its, its_build_vmapti_cmd, &desc);
}
static void its_send_vmovi(struct its_device *dev, u32 id)
{
struct its_vlpi_map *map = dev_event_to_vlpi_map(dev, id);
struct its_cmd_desc desc;
desc.its_vmovi_cmd.vpe = map->vpe;
desc.its_vmovi_cmd.dev = dev;
desc.its_vmovi_cmd.event_id = id;
desc.its_vmovi_cmd.db_enabled = map->db_enabled;
its_send_single_vcommand(dev->its, its_build_vmovi_cmd, &desc);
}
static void its_send_vmapp(struct its_node *its,
struct its_vpe *vpe, bool valid)
{
struct its_cmd_desc desc;
desc.its_vmapp_cmd.vpe = vpe;
desc.its_vmapp_cmd.valid = valid;
desc.its_vmapp_cmd.col = &its->collections[vpe->col_idx];
its_send_single_vcommand(its, its_build_vmapp_cmd, &desc);
}
static void its_send_vmovp(struct its_vpe *vpe)
{
struct its_cmd_desc desc = {};
struct its_node *its;
unsigned long flags;
int col_id = vpe->col_idx;
desc.its_vmovp_cmd.vpe = vpe;
if (!its_list_map) {
its = list_first_entry(&its_nodes, struct its_node, entry);
desc.its_vmovp_cmd.col = &its->collections[col_id];
its_send_single_vcommand(its, its_build_vmovp_cmd, &desc);
return;
}
/*
* Yet another marvel of the architecture. If using the
* its_list "feature", we need to make sure that all ITSs
* receive all VMOVP commands in the same order. The only way
* to guarantee this is to make vmovp a serialization point.
*
* Wall <-- Head.
*/
raw_spin_lock_irqsave(&vmovp_lock, flags);
desc.its_vmovp_cmd.seq_num = vmovp_seq_num++;
desc.its_vmovp_cmd.its_list = get_its_list(vpe->its_vm);
/* Emit VMOVPs */
list_for_each_entry(its, &its_nodes, entry) {
if (!is_v4(its))
continue;
if (!require_its_list_vmovp(vpe->its_vm, its))
continue;
desc.its_vmovp_cmd.col = &its->collections[col_id];
its_send_single_vcommand(its, its_build_vmovp_cmd, &desc);
}
raw_spin_unlock_irqrestore(&vmovp_lock, flags);
}
static void its_send_vinvall(struct its_node *its, struct its_vpe *vpe)
{
struct its_cmd_desc desc;
desc.its_vinvall_cmd.vpe = vpe;
its_send_single_vcommand(its, its_build_vinvall_cmd, &desc);
}
static void its_send_vinv(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
/*
* There is no real VINV command. This is just a normal INV,
* with a VSYNC instead of a SYNC.
*/
desc.its_inv_cmd.dev = dev;
desc.its_inv_cmd.event_id = event_id;
its_send_single_vcommand(dev->its, its_build_vinv_cmd, &desc);
}
static void its_send_vint(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
/*
* There is no real VINT command. This is just a normal INT,
* with a VSYNC instead of a SYNC.
*/
desc.its_int_cmd.dev = dev;
desc.its_int_cmd.event_id = event_id;
its_send_single_vcommand(dev->its, its_build_vint_cmd, &desc);
}
static void its_send_vclear(struct its_device *dev, u32 event_id)
{
struct its_cmd_desc desc;
/*
* There is no real VCLEAR command. This is just a normal CLEAR,
* with a VSYNC instead of a SYNC.
*/
desc.its_clear_cmd.dev = dev;
desc.its_clear_cmd.event_id = event_id;
its_send_single_vcommand(dev->its, its_build_vclear_cmd, &desc);
}
static void its_send_invdb(struct its_node *its, struct its_vpe *vpe)
{
struct its_cmd_desc desc;
desc.its_invdb_cmd.vpe = vpe;
its_send_single_vcommand(its, its_build_invdb_cmd, &desc);
}
/*
* irqchip functions - assumes MSI, mostly.
*/
static void lpi_write_config(struct irq_data *d, u8 clr, u8 set)
{
struct its_vlpi_map *map = get_vlpi_map(d);
irq_hw_number_t hwirq;
void *va;
u8 *cfg;
if (map) {
va = page_address(map->vm->vprop_page);
hwirq = map->vintid;
/* Remember the updated property */
map->properties &= ~clr;
map->properties |= set | LPI_PROP_GROUP1;
} else {
va = gic_rdists->prop_table_va;
hwirq = d->hwirq;
}
cfg = va + hwirq - 8192;
*cfg &= ~clr;
*cfg |= set | LPI_PROP_GROUP1;
/*
* Make the above write visible to the redistributors.
* And yes, we're flushing exactly: One. Single. Byte.
* Humpf...
*/
if (gic_rdists->flags & RDIST_FLAGS_PROPBASE_NEEDS_FLUSHING)
gic_flush_dcache_to_poc(cfg, sizeof(*cfg));
else
dsb(ishst);
}
static void wait_for_syncr(void __iomem *rdbase)
{
while (readl_relaxed(rdbase + GICR_SYNCR) & 1)
cpu_relax();
}
static void __direct_lpi_inv(struct irq_data *d, u64 val)
{
void __iomem *rdbase;
unsigned long flags;
int cpu;
/* Target the redistributor this LPI is currently routed to */
cpu = irq_to_cpuid_lock(d, &flags);
raw_spin_lock(&gic_data_rdist_cpu(cpu)->rd_lock);
rdbase = per_cpu_ptr(gic_rdists->rdist, cpu)->rd_base;
gic_write_lpir(val, rdbase + GICR_INVLPIR);
wait_for_syncr(rdbase);
raw_spin_unlock(&gic_data_rdist_cpu(cpu)->rd_lock);
irq_to_cpuid_unlock(d, flags);
}
static void direct_lpi_inv(struct irq_data *d)
{
struct its_vlpi_map *map = get_vlpi_map(d);
u64 val;
if (map) {
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
WARN_ON(!is_v4_1(its_dev->its));
val = GICR_INVLPIR_V;
val |= FIELD_PREP(GICR_INVLPIR_VPEID, map->vpe->vpe_id);
val |= FIELD_PREP(GICR_INVLPIR_INTID, map->vintid);
} else {
val = d->hwirq;
}
__direct_lpi_inv(d, val);
}
static void lpi_update_config(struct irq_data *d, u8 clr, u8 set)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
lpi_write_config(d, clr, set);
if (gic_rdists->has_direct_lpi &&
(is_v4_1(its_dev->its) || !irqd_is_forwarded_to_vcpu(d)))
direct_lpi_inv(d);
else if (!irqd_is_forwarded_to_vcpu(d))
its_send_inv(its_dev, its_get_event_id(d));
else
its_send_vinv(its_dev, its_get_event_id(d));
}
static void its_vlpi_set_doorbell(struct irq_data *d, bool enable)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
struct its_vlpi_map *map;
/*
* GICv4.1 does away with the per-LPI nonsense, nothing to do
* here.
*/
if (is_v4_1(its_dev->its))
return;
map = dev_event_to_vlpi_map(its_dev, event);
if (map->db_enabled == enable)
return;
map->db_enabled = enable;
/*
* More fun with the architecture:
*
* Ideally, we'd issue a VMAPTI to set the doorbell to its LPI
* value or to 1023, depending on the enable bit. But that
* would be issuing a mapping for an /existing/ DevID+EventID
* pair, which is UNPREDICTABLE. Instead, let's issue a VMOVI
* to the /same/ vPE, using this opportunity to adjust the
* doorbell. Mouahahahaha. We loves it, Precious.
*/
its_send_vmovi(its_dev, event);
}
static void its_mask_irq(struct irq_data *d)
{
if (irqd_is_forwarded_to_vcpu(d))
its_vlpi_set_doorbell(d, false);
lpi_update_config(d, LPI_PROP_ENABLED, 0);
}
static void its_unmask_irq(struct irq_data *d)
{
if (irqd_is_forwarded_to_vcpu(d))
its_vlpi_set_doorbell(d, true);
lpi_update_config(d, 0, LPI_PROP_ENABLED);
}
static __maybe_unused u32 its_read_lpi_count(struct irq_data *d, int cpu)
{
if (irqd_affinity_is_managed(d))
return atomic_read(&per_cpu_ptr(&cpu_lpi_count, cpu)->managed);
return atomic_read(&per_cpu_ptr(&cpu_lpi_count, cpu)->unmanaged);
}
static void its_inc_lpi_count(struct irq_data *d, int cpu)
{
if (irqd_affinity_is_managed(d))
atomic_inc(&per_cpu_ptr(&cpu_lpi_count, cpu)->managed);
else
atomic_inc(&per_cpu_ptr(&cpu_lpi_count, cpu)->unmanaged);
}
static void its_dec_lpi_count(struct irq_data *d, int cpu)
{
if (irqd_affinity_is_managed(d))
atomic_dec(&per_cpu_ptr(&cpu_lpi_count, cpu)->managed);
else
atomic_dec(&per_cpu_ptr(&cpu_lpi_count, cpu)->unmanaged);
}
static unsigned int cpumask_pick_least_loaded(struct irq_data *d,
const struct cpumask *cpu_mask)
{
unsigned int cpu = nr_cpu_ids, tmp;
int count = S32_MAX;
for_each_cpu(tmp, cpu_mask) {
int this_count = its_read_lpi_count(d, tmp);
if (this_count < count) {
cpu = tmp;
count = this_count;
}
}
return cpu;
}
/*
* As suggested by Thomas Gleixner in:
* https://lore.kernel.org/r/87h80q2aoc.fsf@nanos.tec.linutronix.de
*/
static int its_select_cpu(struct irq_data *d,
const struct cpumask *aff_mask)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
static DEFINE_RAW_SPINLOCK(tmpmask_lock);
static struct cpumask __tmpmask;
struct cpumask *tmpmask;
unsigned long flags;
int cpu, node;
node = its_dev->its->numa_node;
tmpmask = &__tmpmask;
raw_spin_lock_irqsave(&tmpmask_lock, flags);
if (!irqd_affinity_is_managed(d)) {
/* First try the NUMA node */
if (node != NUMA_NO_NODE) {
/*
* Try the intersection of the affinity mask and the
* node mask (and the online mask, just to be safe).
*/
cpumask_and(tmpmask, cpumask_of_node(node), aff_mask);
cpumask_and(tmpmask, tmpmask, cpu_online_mask);
/*
* Ideally, we would check if the mask is empty, and
* try again on the full node here.
*
* But it turns out that the way ACPI describes the
* affinity for ITSs only deals about memory, and
* not target CPUs, so it cannot describe a single
* ITS placed next to two NUMA nodes.
*
* Instead, just fallback on the online mask. This
* diverges from Thomas' suggestion above.
*/
cpu = cpumask_pick_least_loaded(d, tmpmask);
if (cpu < nr_cpu_ids)
goto out;
/* If we can't cross sockets, give up */
if ((its_dev->its->flags & ITS_FLAGS_WORKAROUND_CAVIUM_23144))
goto out;
/* If the above failed, expand the search */
}
/* Try the intersection of the affinity and online masks */
cpumask_and(tmpmask, aff_mask, cpu_online_mask);
/* If that doesn't fly, the online mask is the last resort */
if (cpumask_empty(tmpmask))
cpumask_copy(tmpmask, cpu_online_mask);
cpu = cpumask_pick_least_loaded(d, tmpmask);
} else {
cpumask_copy(tmpmask, aff_mask);
/* If we cannot cross sockets, limit the search to that node */
if ((its_dev->its->flags & ITS_FLAGS_WORKAROUND_CAVIUM_23144) &&
node != NUMA_NO_NODE)
cpumask_and(tmpmask, tmpmask, cpumask_of_node(node));
cpu = cpumask_pick_least_loaded(d, tmpmask);
}
out:
raw_spin_unlock_irqrestore(&tmpmask_lock, flags);
pr_debug("IRQ%d -> %*pbl CPU%d\n", d->irq, cpumask_pr_args(aff_mask), cpu);
return cpu;
}
static int its_set_affinity(struct irq_data *d, const struct cpumask *mask_val,
bool force)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
struct its_collection *target_col;
u32 id = its_get_event_id(d);
int cpu, prev_cpu;
/* A forwarded interrupt should use irq_set_vcpu_affinity */
if (irqd_is_forwarded_to_vcpu(d))
return -EINVAL;
prev_cpu = its_dev->event_map.col_map[id];
its_dec_lpi_count(d, prev_cpu);
if (!force)
cpu = its_select_cpu(d, mask_val);
else
cpu = cpumask_pick_least_loaded(d, mask_val);
if (cpu < 0 || cpu >= nr_cpu_ids)
goto err;
/* don't set the affinity when the target cpu is same as current one */
if (cpu != prev_cpu) {
target_col = &its_dev->its->collections[cpu];
its_send_movi(its_dev, target_col, id);
its_dev->event_map.col_map[id] = cpu;
irq_data_update_effective_affinity(d, cpumask_of(cpu));
}
its_inc_lpi_count(d, cpu);
return IRQ_SET_MASK_OK_DONE;
err:
its_inc_lpi_count(d, prev_cpu);
return -EINVAL;
}
static u64 its_irq_get_msi_base(struct its_device *its_dev)
{
struct its_node *its = its_dev->its;
return its->phys_base + GITS_TRANSLATER;
}
static void its_irq_compose_msi_msg(struct irq_data *d, struct msi_msg *msg)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
struct its_node *its;
u64 addr;
its = its_dev->its;
addr = its->get_msi_base(its_dev);
msg->address_lo = lower_32_bits(addr);
msg->address_hi = upper_32_bits(addr);
msg->data = its_get_event_id(d);
iommu_dma_compose_msi_msg(irq_data_get_msi_desc(d), msg);
}
static int its_irq_set_irqchip_state(struct irq_data *d,
enum irqchip_irq_state which,
bool state)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
if (which != IRQCHIP_STATE_PENDING)
return -EINVAL;
if (irqd_is_forwarded_to_vcpu(d)) {
if (state)
its_send_vint(its_dev, event);
else
its_send_vclear(its_dev, event);
} else {
if (state)
its_send_int(its_dev, event);
else
its_send_clear(its_dev, event);
}
return 0;
}
static int its_irq_retrigger(struct irq_data *d)
{
return !its_irq_set_irqchip_state(d, IRQCHIP_STATE_PENDING, true);
}
/*
* Two favourable cases:
*
* (a) Either we have a GICv4.1, and all vPEs have to be mapped at all times
* for vSGI delivery
*
* (b) Or the ITSs do not use a list map, meaning that VMOVP is cheap enough
* and we're better off mapping all VPEs always
*
* If neither (a) nor (b) is true, then we map vPEs on demand.
*
*/
static bool gic_requires_eager_mapping(void)
{
if (!its_list_map || gic_rdists->has_rvpeid)
return true;
return false;
}
static void its_map_vm(struct its_node *its, struct its_vm *vm)
{
unsigned long flags;
if (gic_requires_eager_mapping())
return;
raw_spin_lock_irqsave(&vmovp_lock, flags);
/*
* If the VM wasn't mapped yet, iterate over the vpes and get
* them mapped now.
*/
vm->vlpi_count[its->list_nr]++;
if (vm->vlpi_count[its->list_nr] == 1) {
int i;
for (i = 0; i < vm->nr_vpes; i++) {
struct its_vpe *vpe = vm->vpes[i];
struct irq_data *d = irq_get_irq_data(vpe->irq);
/* Map the VPE to the first possible CPU */
vpe->col_idx = cpumask_first(cpu_online_mask);
its_send_vmapp(its, vpe, true);
its_send_vinvall(its, vpe);
irq_data_update_effective_affinity(d, cpumask_of(vpe->col_idx));
}
}
raw_spin_unlock_irqrestore(&vmovp_lock, flags);
}
static void its_unmap_vm(struct its_node *its, struct its_vm *vm)
{
unsigned long flags;
/* Not using the ITS list? Everything is always mapped. */
if (gic_requires_eager_mapping())
return;
raw_spin_lock_irqsave(&vmovp_lock, flags);
if (!--vm->vlpi_count[its->list_nr]) {
int i;
for (i = 0; i < vm->nr_vpes; i++)
its_send_vmapp(its, vm->vpes[i], false);
}
raw_spin_unlock_irqrestore(&vmovp_lock, flags);
}
static int its_vlpi_map(struct irq_data *d, struct its_cmd_info *info)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
int ret = 0;
if (!info->map)
return -EINVAL;
raw_spin_lock(&its_dev->event_map.vlpi_lock);
if (!its_dev->event_map.vm) {
struct its_vlpi_map *maps;
maps = kcalloc(its_dev->event_map.nr_lpis, sizeof(*maps),
GFP_ATOMIC);
if (!maps) {
ret = -ENOMEM;
goto out;
}
its_dev->event_map.vm = info->map->vm;
its_dev->event_map.vlpi_maps = maps;
} else if (its_dev->event_map.vm != info->map->vm) {
ret = -EINVAL;
goto out;
}
/* Get our private copy of the mapping information */
its_dev->event_map.vlpi_maps[event] = *info->map;
if (irqd_is_forwarded_to_vcpu(d)) {
/* Already mapped, move it around */
its_send_vmovi(its_dev, event);
} else {
/* Ensure all the VPEs are mapped on this ITS */
its_map_vm(its_dev->its, info->map->vm);
/*
* Flag the interrupt as forwarded so that we can
* start poking the virtual property table.
*/
irqd_set_forwarded_to_vcpu(d);
/* Write out the property to the prop table */
lpi_write_config(d, 0xff, info->map->properties);
/* Drop the physical mapping */
its_send_discard(its_dev, event);
/* and install the virtual one */
its_send_vmapti(its_dev, event);
/* Increment the number of VLPIs */
its_dev->event_map.nr_vlpis++;
}
out:
raw_spin_unlock(&its_dev->event_map.vlpi_lock);
return ret;
}
static int its_vlpi_get(struct irq_data *d, struct its_cmd_info *info)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
struct its_vlpi_map *map;
int ret = 0;
raw_spin_lock(&its_dev->event_map.vlpi_lock);
map = get_vlpi_map(d);
if (!its_dev->event_map.vm || !map) {
ret = -EINVAL;
goto out;
}
/* Copy our mapping information to the incoming request */
*info->map = *map;
out:
raw_spin_unlock(&its_dev->event_map.vlpi_lock);
return ret;
}
static int its_vlpi_unmap(struct irq_data *d)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
int ret = 0;
raw_spin_lock(&its_dev->event_map.vlpi_lock);
if (!its_dev->event_map.vm || !irqd_is_forwarded_to_vcpu(d)) {
ret = -EINVAL;
goto out;
}
/* Drop the virtual mapping */
its_send_discard(its_dev, event);
/* and restore the physical one */
irqd_clr_forwarded_to_vcpu(d);
its_send_mapti(its_dev, d->hwirq, event);
lpi_update_config(d, 0xff, (LPI_PROP_DEFAULT_PRIO |
LPI_PROP_ENABLED |
LPI_PROP_GROUP1));
/* Potentially unmap the VM from this ITS */
its_unmap_vm(its_dev->its, its_dev->event_map.vm);
/*
* Drop the refcount and make the device available again if
* this was the last VLPI.
*/
if (!--its_dev->event_map.nr_vlpis) {
its_dev->event_map.vm = NULL;
kfree(its_dev->event_map.vlpi_maps);
}
out:
raw_spin_unlock(&its_dev->event_map.vlpi_lock);
return ret;
}
static int its_vlpi_prop_update(struct irq_data *d, struct its_cmd_info *info)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
if (!its_dev->event_map.vm || !irqd_is_forwarded_to_vcpu(d))
return -EINVAL;
if (info->cmd_type == PROP_UPDATE_AND_INV_VLPI)
lpi_update_config(d, 0xff, info->config);
else
lpi_write_config(d, 0xff, info->config);
its_vlpi_set_doorbell(d, !!(info->config & LPI_PROP_ENABLED));
return 0;
}
static int its_irq_set_vcpu_affinity(struct irq_data *d, void *vcpu_info)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
struct its_cmd_info *info = vcpu_info;
/* Need a v4 ITS */
if (!is_v4(its_dev->its))
return -EINVAL;
/* Unmap request? */
if (!info)
return its_vlpi_unmap(d);
switch (info->cmd_type) {
case MAP_VLPI:
return its_vlpi_map(d, info);
case GET_VLPI:
return its_vlpi_get(d, info);
case PROP_UPDATE_VLPI:
case PROP_UPDATE_AND_INV_VLPI:
return its_vlpi_prop_update(d, info);
default:
return -EINVAL;
}
}
static struct irq_chip its_irq_chip = {
.name = "ITS",
.irq_mask = its_mask_irq,
.irq_unmask = its_unmask_irq,
.irq_eoi = irq_chip_eoi_parent,
.irq_set_affinity = its_set_affinity,
.irq_compose_msi_msg = its_irq_compose_msi_msg,
.irq_set_irqchip_state = its_irq_set_irqchip_state,
.irq_retrigger = its_irq_retrigger,
.irq_set_vcpu_affinity = its_irq_set_vcpu_affinity,
};
/*
* How we allocate LPIs:
*
* lpi_range_list contains ranges of LPIs that are to available to
* allocate from. To allocate LPIs, just pick the first range that
* fits the required allocation, and reduce it by the required
* amount. Once empty, remove the range from the list.
*
* To free a range of LPIs, add a free range to the list, sort it and
* merge the result if the new range happens to be adjacent to an
* already free block.
*
* The consequence of the above is that allocation is cost is low, but
* freeing is expensive. We assumes that freeing rarely occurs.
*/
#define ITS_MAX_LPI_NRBITS 16 /* 64K LPIs */
static DEFINE_MUTEX(lpi_range_lock);
static LIST_HEAD(lpi_range_list);
struct lpi_range {
struct list_head entry;
u32 base_id;
u32 span;
};
static struct lpi_range *mk_lpi_range(u32 base, u32 span)
{
struct lpi_range *range;
range = kmalloc(sizeof(*range), GFP_KERNEL);
if (range) {
range->base_id = base;
range->span = span;
}
return range;
}
static int alloc_lpi_range(u32 nr_lpis, u32 *base)
{
struct lpi_range *range, *tmp;
int err = -ENOSPC;
mutex_lock(&lpi_range_lock);
list_for_each_entry_safe(range, tmp, &lpi_range_list, entry) {
if (range->span >= nr_lpis) {
*base = range->base_id;
range->base_id += nr_lpis;
range->span -= nr_lpis;
if (range->span == 0) {
list_del(&range->entry);
kfree(range);
}
err = 0;
break;
}
}
mutex_unlock(&lpi_range_lock);
pr_debug("ITS: alloc %u:%u\n", *base, nr_lpis);
return err;
}
static void merge_lpi_ranges(struct lpi_range *a, struct lpi_range *b)
{
if (&a->entry == &lpi_range_list || &b->entry == &lpi_range_list)
return;
if (a->base_id + a->span != b->base_id)
return;
b->base_id = a->base_id;
b->span += a->span;
list_del(&a->entry);
kfree(a);
}
static int free_lpi_range(u32 base, u32 nr_lpis)
{
struct lpi_range *new, *old;
new = mk_lpi_range(base, nr_lpis);
if (!new)
return -ENOMEM;
mutex_lock(&lpi_range_lock);
list_for_each_entry_reverse(old, &lpi_range_list, entry) {
if (old->base_id < base)
break;
}
/*
* old is the last element with ->base_id smaller than base,
* so new goes right after it. If there are no elements with
* ->base_id smaller than base, &old->entry ends up pointing
* at the head of the list, and inserting new it the start of
* the list is the right thing to do in that case as well.
*/
list_add(&new->entry, &old->entry);
/*
* Now check if we can merge with the preceding and/or
* following ranges.
*/
merge_lpi_ranges(old, new);
merge_lpi_ranges(new, list_next_entry(new, entry));
mutex_unlock(&lpi_range_lock);
return 0;
}
static int __init its_lpi_init(u32 id_bits)
{
u32 lpis = (1UL << id_bits) - 8192;
u32 numlpis;
int err;
numlpis = 1UL << GICD_TYPER_NUM_LPIS(gic_rdists->gicd_typer);
if (numlpis > 2 && !WARN_ON(numlpis > lpis)) {
lpis = numlpis;
pr_info("ITS: Using hypervisor restricted LPI range [%u]\n",
lpis);
}
/*
* Initializing the allocator is just the same as freeing the
* full range of LPIs.
*/
err = free_lpi_range(8192, lpis);
pr_debug("ITS: Allocator initialized for %u LPIs\n", lpis);
return err;
}
static unsigned long *its_lpi_alloc(int nr_irqs, u32 *base, int *nr_ids)
{
unsigned long *bitmap = NULL;
int err = 0;
do {
err = alloc_lpi_range(nr_irqs, base);
if (!err)
break;
nr_irqs /= 2;
} while (nr_irqs > 0);
if (!nr_irqs)
err = -ENOSPC;
if (err)
goto out;
bitmap = bitmap_zalloc(nr_irqs, GFP_ATOMIC);
if (!bitmap)
goto out;
*nr_ids = nr_irqs;
out:
if (!bitmap)
*base = *nr_ids = 0;
return bitmap;
}
static void its_lpi_free(unsigned long *bitmap, u32 base, u32 nr_ids)
{
WARN_ON(free_lpi_range(base, nr_ids));
bitmap_free(bitmap);
}
static void gic_reset_prop_table(void *va)
{
/* Priority 0xa0, Group-1, disabled */
memset(va, LPI_PROP_DEFAULT_PRIO | LPI_PROP_GROUP1, LPI_PROPBASE_SZ);
/* Make sure the GIC will observe the written configuration */
gic_flush_dcache_to_poc(va, LPI_PROPBASE_SZ);
}
static struct page *its_allocate_prop_table(gfp_t gfp_flags)
{
struct page *prop_page;
prop_page = alloc_pages(gfp_flags, get_order(LPI_PROPBASE_SZ));
if (!prop_page)
return NULL;
gic_reset_prop_table(page_address(prop_page));
return prop_page;
}
static void its_free_prop_table(struct page *prop_page)
{
free_pages((unsigned long)page_address(prop_page),
get_order(LPI_PROPBASE_SZ));
}
static bool gic_check_reserved_range(phys_addr_t addr, unsigned long size)
{
phys_addr_t start, end, addr_end;
u64 i;
/*
* We don't bother checking for a kdump kernel as by
* construction, the LPI tables are out of this kernel's
* memory map.
*/
if (is_kdump_kernel())
return true;
addr_end = addr + size - 1;
for_each_reserved_mem_range(i, &start, &end) {
if (addr >= start && addr_end <= end)
return true;
}
/* Not found, not a good sign... */
pr_warn("GICv3: Expected reserved range [%pa:%pa], not found\n",
&addr, &addr_end);
add_taint(TAINT_CRAP, LOCKDEP_STILL_OK);
return false;
}
static int gic_reserve_range(phys_addr_t addr, unsigned long size)
{
if (efi_enabled(EFI_CONFIG_TABLES))
return efi_mem_reserve_persistent(addr, size);
return 0;
}
static int __init its_setup_lpi_prop_table(void)
{
if (gic_rdists->flags & RDIST_FLAGS_RD_TABLES_PREALLOCATED) {
u64 val;
val = gicr_read_propbaser(gic_data_rdist_rd_base() + GICR_PROPBASER);
lpi_id_bits = (val & GICR_PROPBASER_IDBITS_MASK) + 1;
gic_rdists->prop_table_pa = val & GENMASK_ULL(51, 12);
gic_rdists->prop_table_va = memremap(gic_rdists->prop_table_pa,
LPI_PROPBASE_SZ,
MEMREMAP_WB);
gic_reset_prop_table(gic_rdists->prop_table_va);
} else {
struct page *page;
lpi_id_bits = min_t(u32,
GICD_TYPER_ID_BITS(gic_rdists->gicd_typer),
ITS_MAX_LPI_NRBITS);
page = its_allocate_prop_table(GFP_NOWAIT);
if (!page) {
pr_err("Failed to allocate PROPBASE\n");
return -ENOMEM;
}
gic_rdists->prop_table_pa = page_to_phys(page);
gic_rdists->prop_table_va = page_address(page);
WARN_ON(gic_reserve_range(gic_rdists->prop_table_pa,
LPI_PROPBASE_SZ));
}
pr_info("GICv3: using LPI property table @%pa\n",
&gic_rdists->prop_table_pa);
return its_lpi_init(lpi_id_bits);
}
static const char *its_base_type_string[] = {
[GITS_BASER_TYPE_DEVICE] = "Devices",
[GITS_BASER_TYPE_VCPU] = "Virtual CPUs",
[GITS_BASER_TYPE_RESERVED3] = "Reserved (3)",
[GITS_BASER_TYPE_COLLECTION] = "Interrupt Collections",
[GITS_BASER_TYPE_RESERVED5] = "Reserved (5)",
[GITS_BASER_TYPE_RESERVED6] = "Reserved (6)",
[GITS_BASER_TYPE_RESERVED7] = "Reserved (7)",
};
static u64 its_read_baser(struct its_node *its, struct its_baser *baser)
{
u32 idx = baser - its->tables;
return gits_read_baser(its->base + GITS_BASER + (idx << 3));
}
static void its_write_baser(struct its_node *its, struct its_baser *baser,
u64 val)
{
u32 idx = baser - its->tables;
gits_write_baser(val, its->base + GITS_BASER + (idx << 3));
baser->val = its_read_baser(its, baser);
}
static int its_setup_baser(struct its_node *its, struct its_baser *baser,
u64 cache, u64 shr, u32 order, bool indirect)
{
u64 val = its_read_baser(its, baser);
u64 esz = GITS_BASER_ENTRY_SIZE(val);
u64 type = GITS_BASER_TYPE(val);
u64 baser_phys, tmp;
u32 alloc_pages, psz;
struct page *page;
void *base;
psz = baser->psz;
alloc_pages = (PAGE_ORDER_TO_SIZE(order) / psz);
if (alloc_pages > GITS_BASER_PAGES_MAX) {
pr_warn("ITS@%pa: %s too large, reduce ITS pages %u->%u\n",
&its->phys_base, its_base_type_string[type],
alloc_pages, GITS_BASER_PAGES_MAX);
alloc_pages = GITS_BASER_PAGES_MAX;
order = get_order(GITS_BASER_PAGES_MAX * psz);
}
page = alloc_pages_node(its->numa_node, GFP_KERNEL | __GFP_ZERO, order);
if (!page)
return -ENOMEM;
base = (void *)page_address(page);
baser_phys = virt_to_phys(base);
/* Check if the physical address of the memory is above 48bits */
if (IS_ENABLED(CONFIG_ARM64_64K_PAGES) && (baser_phys >> 48)) {
/* 52bit PA is supported only when PageSize=64K */
if (psz != SZ_64K) {
pr_err("ITS: no 52bit PA support when psz=%d\n", psz);
free_pages((unsigned long)base, order);
return -ENXIO;
}
/* Convert 52bit PA to 48bit field */
baser_phys = GITS_BASER_PHYS_52_to_48(baser_phys);
}
retry_baser:
val = (baser_phys |
(type << GITS_BASER_TYPE_SHIFT) |
((esz - 1) << GITS_BASER_ENTRY_SIZE_SHIFT) |
((alloc_pages - 1) << GITS_BASER_PAGES_SHIFT) |
cache |
shr |
GITS_BASER_VALID);
val |= indirect ? GITS_BASER_INDIRECT : 0x0;
switch (psz) {
case SZ_4K:
val |= GITS_BASER_PAGE_SIZE_4K;
break;
case SZ_16K:
val |= GITS_BASER_PAGE_SIZE_16K;
break;
case SZ_64K:
val |= GITS_BASER_PAGE_SIZE_64K;
break;
}
if (!shr)
gic_flush_dcache_to_poc(base, PAGE_ORDER_TO_SIZE(order));
its_write_baser(its, baser, val);
tmp = baser->val;
if ((val ^ tmp) & GITS_BASER_SHAREABILITY_MASK) {
/*
* Shareability didn't stick. Just use
* whatever the read reported, which is likely
* to be the only thing this redistributor
* supports. If that's zero, make it
* non-cacheable as well.
*/
shr = tmp & GITS_BASER_SHAREABILITY_MASK;
if (!shr)
cache = GITS_BASER_nC;
goto retry_baser;
}
if (val != tmp) {
pr_err("ITS@%pa: %s doesn't stick: %llx %llx\n",
&its->phys_base, its_base_type_string[type],
val, tmp);
free_pages((unsigned long)base, order);
return -ENXIO;
}
baser->order = order;
baser->base = base;
baser->psz = psz;
tmp = indirect ? GITS_LVL1_ENTRY_SIZE : esz;
pr_info("ITS@%pa: allocated %d %s @%lx (%s, esz %d, psz %dK, shr %d)\n",
&its->phys_base, (int)(PAGE_ORDER_TO_SIZE(order) / (int)tmp),
its_base_type_string[type],
(unsigned long)virt_to_phys(base),
indirect ? "indirect" : "flat", (int)esz,
psz / SZ_1K, (int)shr >> GITS_BASER_SHAREABILITY_SHIFT);
return 0;
}
static bool its_parse_indirect_baser(struct its_node *its,
struct its_baser *baser,
u32 *order, u32 ids)
{
u64 tmp = its_read_baser(its, baser);
u64 type = GITS_BASER_TYPE(tmp);
u64 esz = GITS_BASER_ENTRY_SIZE(tmp);
u64 val = GITS_BASER_InnerShareable | GITS_BASER_RaWaWb;
u32 new_order = *order;
u32 psz = baser->psz;
bool indirect = false;
/* No need to enable Indirection if memory requirement < (psz*2)bytes */
if ((esz << ids) > (psz * 2)) {
/*
* Find out whether hw supports a single or two-level table by
* table by reading bit at offset '62' after writing '1' to it.
*/
its_write_baser(its, baser, val | GITS_BASER_INDIRECT);
indirect = !!(baser->val & GITS_BASER_INDIRECT);
if (indirect) {
/*
* The size of the lvl2 table is equal to ITS page size
* which is 'psz'. For computing lvl1 table size,
* subtract ID bits that sparse lvl2 table from 'ids'
* which is reported by ITS hardware times lvl1 table
* entry size.
*/
ids -= ilog2(psz / (int)esz);
esz = GITS_LVL1_ENTRY_SIZE;
}
}
/*
* Allocate as many entries as required to fit the
* range of device IDs that the ITS can grok... The ID
* space being incredibly sparse, this results in a
* massive waste of memory if two-level device table
* feature is not supported by hardware.
*/
new_order = max_t(u32, get_order(esz << ids), new_order);
if (new_order > MAX_PAGE_ORDER) {
new_order = MAX_PAGE_ORDER;
ids = ilog2(PAGE_ORDER_TO_SIZE(new_order) / (int)esz);
pr_warn("ITS@%pa: %s Table too large, reduce ids %llu->%u\n",
&its->phys_base, its_base_type_string[type],
device_ids(its), ids);
}
*order = new_order;
return indirect;
}
static u32 compute_common_aff(u64 val)
{
u32 aff, clpiaff;
aff = FIELD_GET(GICR_TYPER_AFFINITY, val);
clpiaff = FIELD_GET(GICR_TYPER_COMMON_LPI_AFF, val);
return aff & ~(GENMASK(31, 0) >> (clpiaff * 8));
}
static u32 compute_its_aff(struct its_node *its)
{
u64 val;
u32 svpet;
/*
* Reencode the ITS SVPET and MPIDR as a GICR_TYPER, and compute
* the resulting affinity. We then use that to see if this match
* our own affinity.
*/
svpet = FIELD_GET(GITS_TYPER_SVPET, its->typer);
val = FIELD_PREP(GICR_TYPER_COMMON_LPI_AFF, svpet);
val |= FIELD_PREP(GICR_TYPER_AFFINITY, its->mpidr);
return compute_common_aff(val);
}
static struct its_node *find_sibling_its(struct its_node *cur_its)
{
struct its_node *its;
u32 aff;
if (!FIELD_GET(GITS_TYPER_SVPET, cur_its->typer))
return NULL;
aff = compute_its_aff(cur_its);
list_for_each_entry(its, &its_nodes, entry) {
u64 baser;
if (!is_v4_1(its) || its == cur_its)
continue;
if (!FIELD_GET(GITS_TYPER_SVPET, its->typer))
continue;
if (aff != compute_its_aff(its))
continue;
/* GICv4.1 guarantees that the vPE table is GITS_BASER2 */
baser = its->tables[2].val;
if (!(baser & GITS_BASER_VALID))
continue;
return its;
}
return NULL;
}
static void its_free_tables(struct its_node *its)
{
int i;
for (i = 0; i < GITS_BASER_NR_REGS; i++) {
if (its->tables[i].base) {
free_pages((unsigned long)its->tables[i].base,
its->tables[i].order);
its->tables[i].base = NULL;
}
}
}
static int its_probe_baser_psz(struct its_node *its, struct its_baser *baser)
{
u64 psz = SZ_64K;
while (psz) {
u64 val, gpsz;
val = its_read_baser(its, baser);
val &= ~GITS_BASER_PAGE_SIZE_MASK;
switch (psz) {
case SZ_64K:
gpsz = GITS_BASER_PAGE_SIZE_64K;
break;
case SZ_16K:
gpsz = GITS_BASER_PAGE_SIZE_16K;
break;
case SZ_4K:
default:
gpsz = GITS_BASER_PAGE_SIZE_4K;
break;
}
gpsz >>= GITS_BASER_PAGE_SIZE_SHIFT;
val |= FIELD_PREP(GITS_BASER_PAGE_SIZE_MASK, gpsz);
its_write_baser(its, baser, val);
if (FIELD_GET(GITS_BASER_PAGE_SIZE_MASK, baser->val) == gpsz)
break;
switch (psz) {
case SZ_64K:
psz = SZ_16K;
break;
case SZ_16K:
psz = SZ_4K;
break;
case SZ_4K:
default:
return -1;
}
}
baser->psz = psz;
return 0;
}
static int its_alloc_tables(struct its_node *its)
{
u64 shr = GITS_BASER_InnerShareable;
u64 cache = GITS_BASER_RaWaWb;
int err, i;
if (its->flags & ITS_FLAGS_WORKAROUND_CAVIUM_22375)
/* erratum 24313: ignore memory access type */
cache = GITS_BASER_nCnB;
if (its->flags & ITS_FLAGS_FORCE_NON_SHAREABLE) {
cache = GITS_BASER_nC;
shr = 0;
}
for (i = 0; i < GITS_BASER_NR_REGS; i++) {
struct its_baser *baser = its->tables + i;
u64 val = its_read_baser(its, baser);
u64 type = GITS_BASER_TYPE(val);
bool indirect = false;
u32 order;
if (type == GITS_BASER_TYPE_NONE)
continue;
if (its_probe_baser_psz(its, baser)) {
its_free_tables(its);
return -ENXIO;
}
order = get_order(baser->psz);
switch (type) {
case GITS_BASER_TYPE_DEVICE:
indirect = its_parse_indirect_baser(its, baser, &order,
device_ids(its));
break;
case GITS_BASER_TYPE_VCPU:
if (is_v4_1(its)) {
struct its_node *sibling;
WARN_ON(i != 2);
if ((sibling = find_sibling_its(its))) {
*baser = sibling->tables[2];
its_write_baser(its, baser, baser->val);
continue;
}
}
indirect = its_parse_indirect_baser(its, baser, &order,
ITS_MAX_VPEID_BITS);
break;
}
err = its_setup_baser(its, baser, cache, shr, order, indirect);
if (err < 0) {
its_free_tables(its);
return err;
}
/* Update settings which will be used for next BASERn */
cache = baser->val & GITS_BASER_CACHEABILITY_MASK;
shr = baser->val & GITS_BASER_SHAREABILITY_MASK;
}
return 0;
}
static u64 inherit_vpe_l1_table_from_its(void)
{
struct its_node *its;
u64 val;
u32 aff;
val = gic_read_typer(gic_data_rdist_rd_base() + GICR_TYPER);
aff = compute_common_aff(val);
list_for_each_entry(its, &its_nodes, entry) {
u64 baser, addr;
if (!is_v4_1(its))
continue;
if (!FIELD_GET(GITS_TYPER_SVPET, its->typer))
continue;
if (aff != compute_its_aff(its))
continue;
/* GICv4.1 guarantees that the vPE table is GITS_BASER2 */
baser = its->tables[2].val;
if (!(baser & GITS_BASER_VALID))
continue;
/* We have a winner! */
gic_data_rdist()->vpe_l1_base = its->tables[2].base;
val = GICR_VPROPBASER_4_1_VALID;
if (baser & GITS_BASER_INDIRECT)
val |= GICR_VPROPBASER_4_1_INDIRECT;
val |= FIELD_PREP(GICR_VPROPBASER_4_1_PAGE_SIZE,
FIELD_GET(GITS_BASER_PAGE_SIZE_MASK, baser));
switch (FIELD_GET(GITS_BASER_PAGE_SIZE_MASK, baser)) {
case GIC_PAGE_SIZE_64K:
addr = GITS_BASER_ADDR_48_to_52(baser);
break;
default:
addr = baser & GENMASK_ULL(47, 12);
break;
}
val |= FIELD_PREP(GICR_VPROPBASER_4_1_ADDR, addr >> 12);
if (rdists_support_shareable()) {
val |= FIELD_PREP(GICR_VPROPBASER_SHAREABILITY_MASK,
FIELD_GET(GITS_BASER_SHAREABILITY_MASK, baser));
val |= FIELD_PREP(GICR_VPROPBASER_INNER_CACHEABILITY_MASK,
FIELD_GET(GITS_BASER_INNER_CACHEABILITY_MASK, baser));
}
val |= FIELD_PREP(GICR_VPROPBASER_4_1_SIZE, GITS_BASER_NR_PAGES(baser) - 1);
return val;
}
return 0;
}
static u64 inherit_vpe_l1_table_from_rd(cpumask_t **mask)
{
u32 aff;
u64 val;
int cpu;
val = gic_read_typer(gic_data_rdist_rd_base() + GICR_TYPER);
aff = compute_common_aff(val);
for_each_possible_cpu(cpu) {
void __iomem *base = gic_data_rdist_cpu(cpu)->rd_base;
if (!base || cpu == smp_processor_id())
continue;
val = gic_read_typer(base + GICR_TYPER);
if (aff != compute_common_aff(val))
continue;
/*
* At this point, we have a victim. This particular CPU
* has already booted, and has an affinity that matches
* ours wrt CommonLPIAff. Let's use its own VPROPBASER.
* Make sure we don't write the Z bit in that case.
*/
val = gicr_read_vpropbaser(base + SZ_128K + GICR_VPROPBASER);
val &= ~GICR_VPROPBASER_4_1_Z;
gic_data_rdist()->vpe_l1_base = gic_data_rdist_cpu(cpu)->vpe_l1_base;
*mask = gic_data_rdist_cpu(cpu)->vpe_table_mask;
return val;
}
return 0;
}
static bool allocate_vpe_l2_table(int cpu, u32 id)
{
void __iomem *base = gic_data_rdist_cpu(cpu)->rd_base;
unsigned int psz, esz, idx, npg, gpsz;
u64 val;
struct page *page;
__le64 *table;
if (!gic_rdists->has_rvpeid)
return true;
/* Skip non-present CPUs */
if (!base)
return true;
val = gicr_read_vpropbaser(base + SZ_128K + GICR_VPROPBASER);
esz = FIELD_GET(GICR_VPROPBASER_4_1_ENTRY_SIZE, val) + 1;
gpsz = FIELD_GET(GICR_VPROPBASER_4_1_PAGE_SIZE, val);
npg = FIELD_GET(GICR_VPROPBASER_4_1_SIZE, val) + 1;
switch (gpsz) {
default:
WARN_ON(1);
fallthrough;
case GIC_PAGE_SIZE_4K:
psz = SZ_4K;
break;
case GIC_PAGE_SIZE_16K:
psz = SZ_16K;
break;
case GIC_PAGE_SIZE_64K:
psz = SZ_64K;
break;
}
/* Don't allow vpe_id that exceeds single, flat table limit */
if (!(val & GICR_VPROPBASER_4_1_INDIRECT))
return (id < (npg * psz / (esz * SZ_8)));
/* Compute 1st level table index & check if that exceeds table limit */
idx = id >> ilog2(psz / (esz * SZ_8));
if (idx >= (npg * psz / GITS_LVL1_ENTRY_SIZE))
return false;
table = gic_data_rdist_cpu(cpu)->vpe_l1_base;
/* Allocate memory for 2nd level table */
if (!table[idx]) {
page = alloc_pages(GFP_KERNEL | __GFP_ZERO, get_order(psz));
if (!page)
return false;
/* Flush Lvl2 table to PoC if hw doesn't support coherency */
if (!(val & GICR_VPROPBASER_SHAREABILITY_MASK))
gic_flush_dcache_to_poc(page_address(page), psz);
table[idx] = cpu_to_le64(page_to_phys(page) | GITS_BASER_VALID);
/* Flush Lvl1 entry to PoC if hw doesn't support coherency */
if (!(val & GICR_VPROPBASER_SHAREABILITY_MASK))
gic_flush_dcache_to_poc(table + idx, GITS_LVL1_ENTRY_SIZE);
/* Ensure updated table contents are visible to RD hardware */
dsb(sy);
}
return true;
}
static int allocate_vpe_l1_table(void)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val, gpsz, npg, pa;
unsigned int psz = SZ_64K;
unsigned int np, epp, esz;
struct page *page;
if (!gic_rdists->has_rvpeid)
return 0;
/*
* if VPENDBASER.Valid is set, disable any previously programmed
* VPE by setting PendingLast while clearing Valid. This has the
* effect of making sure no doorbell will be generated and we can
* then safely clear VPROPBASER.Valid.
*/
if (gicr_read_vpendbaser(vlpi_base + GICR_VPENDBASER) & GICR_VPENDBASER_Valid)
gicr_write_vpendbaser(GICR_VPENDBASER_PendingLast,
vlpi_base + GICR_VPENDBASER);
/*
* If we can inherit the configuration from another RD, let's do
* so. Otherwise, we have to go through the allocation process. We
* assume that all RDs have the exact same requirements, as
* nothing will work otherwise.
*/
val = inherit_vpe_l1_table_from_rd(&gic_data_rdist()->vpe_table_mask);
if (val & GICR_VPROPBASER_4_1_VALID)
goto out;
gic_data_rdist()->vpe_table_mask = kzalloc(sizeof(cpumask_t), GFP_ATOMIC);
if (!gic_data_rdist()->vpe_table_mask)
return -ENOMEM;
val = inherit_vpe_l1_table_from_its();
if (val & GICR_VPROPBASER_4_1_VALID)
goto out;
/* First probe the page size */
val = FIELD_PREP(GICR_VPROPBASER_4_1_PAGE_SIZE, GIC_PAGE_SIZE_64K);
gicr_write_vpropbaser(val, vlpi_base + GICR_VPROPBASER);
val = gicr_read_vpropbaser(vlpi_base + GICR_VPROPBASER);
gpsz = FIELD_GET(GICR_VPROPBASER_4_1_PAGE_SIZE, val);
esz = FIELD_GET(GICR_VPROPBASER_4_1_ENTRY_SIZE, val);
switch (gpsz) {
default:
gpsz = GIC_PAGE_SIZE_4K;
fallthrough;
case GIC_PAGE_SIZE_4K:
psz = SZ_4K;
break;
case GIC_PAGE_SIZE_16K:
psz = SZ_16K;
break;
case GIC_PAGE_SIZE_64K:
psz = SZ_64K;
break;
}
/*
* Start populating the register from scratch, including RO fields
* (which we want to print in debug cases...)
*/
val = 0;
val |= FIELD_PREP(GICR_VPROPBASER_4_1_PAGE_SIZE, gpsz);
val |= FIELD_PREP(GICR_VPROPBASER_4_1_ENTRY_SIZE, esz);
/* How many entries per GIC page? */
esz++;
epp = psz / (esz * SZ_8);
/*
* If we need more than just a single L1 page, flag the table
* as indirect and compute the number of required L1 pages.
*/
if (epp < ITS_MAX_VPEID) {
int nl2;
val |= GICR_VPROPBASER_4_1_INDIRECT;
/* Number of L2 pages required to cover the VPEID space */
nl2 = DIV_ROUND_UP(ITS_MAX_VPEID, epp);
/* Number of L1 pages to point to the L2 pages */
npg = DIV_ROUND_UP(nl2 * SZ_8, psz);
} else {
npg = 1;
}
val |= FIELD_PREP(GICR_VPROPBASER_4_1_SIZE, npg - 1);
/* Right, that's the number of CPU pages we need for L1 */
np = DIV_ROUND_UP(npg * psz, PAGE_SIZE);
pr_debug("np = %d, npg = %lld, psz = %d, epp = %d, esz = %d\n",
np, npg, psz, epp, esz);
page = alloc_pages(GFP_ATOMIC | __GFP_ZERO, get_order(np * PAGE_SIZE));
if (!page)
return -ENOMEM;
gic_data_rdist()->vpe_l1_base = page_address(page);
pa = virt_to_phys(page_address(page));
WARN_ON(!IS_ALIGNED(pa, psz));
val |= FIELD_PREP(GICR_VPROPBASER_4_1_ADDR, pa >> 12);
if (rdists_support_shareable()) {
val |= GICR_VPROPBASER_RaWb;
val |= GICR_VPROPBASER_InnerShareable;
}
val |= GICR_VPROPBASER_4_1_Z;
val |= GICR_VPROPBASER_4_1_VALID;
out:
gicr_write_vpropbaser(val, vlpi_base + GICR_VPROPBASER);
cpumask_set_cpu(smp_processor_id(), gic_data_rdist()->vpe_table_mask);
pr_debug("CPU%d: VPROPBASER = %llx %*pbl\n",
smp_processor_id(), val,
cpumask_pr_args(gic_data_rdist()->vpe_table_mask));
return 0;
}
static int its_alloc_collections(struct its_node *its)
{
int i;
its->collections = kcalloc(nr_cpu_ids, sizeof(*its->collections),
GFP_KERNEL);
if (!its->collections)
return -ENOMEM;
for (i = 0; i < nr_cpu_ids; i++)
its->collections[i].target_address = ~0ULL;
return 0;
}
static struct page *its_allocate_pending_table(gfp_t gfp_flags)
{
struct page *pend_page;
pend_page = alloc_pages(gfp_flags | __GFP_ZERO,
get_order(LPI_PENDBASE_SZ));
if (!pend_page)
return NULL;
/* Make sure the GIC will observe the zero-ed page */
gic_flush_dcache_to_poc(page_address(pend_page), LPI_PENDBASE_SZ);
return pend_page;
}
static void its_free_pending_table(struct page *pt)
{
free_pages((unsigned long)page_address(pt), get_order(LPI_PENDBASE_SZ));
}
/*
* Booting with kdump and LPIs enabled is generally fine. Any other
* case is wrong in the absence of firmware/EFI support.
*/
static bool enabled_lpis_allowed(void)
{
phys_addr_t addr;
u64 val;
/* Check whether the property table is in a reserved region */
val = gicr_read_propbaser(gic_data_rdist_rd_base() + GICR_PROPBASER);
addr = val & GENMASK_ULL(51, 12);
return gic_check_reserved_range(addr, LPI_PROPBASE_SZ);
}
static int __init allocate_lpi_tables(void)
{
u64 val;
int err, cpu;
/*
* If LPIs are enabled while we run this from the boot CPU,
* flag the RD tables as pre-allocated if the stars do align.
*/
val = readl_relaxed(gic_data_rdist_rd_base() + GICR_CTLR);
if ((val & GICR_CTLR_ENABLE_LPIS) && enabled_lpis_allowed()) {
gic_rdists->flags |= (RDIST_FLAGS_RD_TABLES_PREALLOCATED |
RDIST_FLAGS_PROPBASE_NEEDS_FLUSHING);
pr_info("GICv3: Using preallocated redistributor tables\n");
}
err = its_setup_lpi_prop_table();
if (err)
return err;
/*
* We allocate all the pending tables anyway, as we may have a
* mix of RDs that have had LPIs enabled, and some that
* don't. We'll free the unused ones as each CPU comes online.
*/
for_each_possible_cpu(cpu) {
struct page *pend_page;
pend_page = its_allocate_pending_table(GFP_NOWAIT);
if (!pend_page) {
pr_err("Failed to allocate PENDBASE for CPU%d\n", cpu);
return -ENOMEM;
}
gic_data_rdist_cpu(cpu)->pend_page = pend_page;
}
return 0;
}
static u64 read_vpend_dirty_clear(void __iomem *vlpi_base)
{
u32 count = 1000000; /* 1s! */
bool clean;
u64 val;
do {
val = gicr_read_vpendbaser(vlpi_base + GICR_VPENDBASER);
clean = !(val & GICR_VPENDBASER_Dirty);
if (!clean) {
count--;
cpu_relax();
udelay(1);
}
} while (!clean && count);
if (unlikely(!clean))
pr_err_ratelimited("ITS virtual pending table not cleaning\n");
return val;
}
static u64 its_clear_vpend_valid(void __iomem *vlpi_base, u64 clr, u64 set)
{
u64 val;
/* Make sure we wait until the RD is done with the initial scan */
val = read_vpend_dirty_clear(vlpi_base);
val &= ~GICR_VPENDBASER_Valid;
val &= ~clr;
val |= set;
gicr_write_vpendbaser(val, vlpi_base + GICR_VPENDBASER);
val = read_vpend_dirty_clear(vlpi_base);
if (unlikely(val & GICR_VPENDBASER_Dirty))
val |= GICR_VPENDBASER_PendingLast;
return val;
}
static void its_cpu_init_lpis(void)
{
void __iomem *rbase = gic_data_rdist_rd_base();
struct page *pend_page;
phys_addr_t paddr;
u64 val, tmp;
if (gic_data_rdist()->flags & RD_LOCAL_LPI_ENABLED)
return;
val = readl_relaxed(rbase + GICR_CTLR);
if ((gic_rdists->flags & RDIST_FLAGS_RD_TABLES_PREALLOCATED) &&
(val & GICR_CTLR_ENABLE_LPIS)) {
/*
* Check that we get the same property table on all
* RDs. If we don't, this is hopeless.
*/
paddr = gicr_read_propbaser(rbase + GICR_PROPBASER);
paddr &= GENMASK_ULL(51, 12);
if (WARN_ON(gic_rdists->prop_table_pa != paddr))
add_taint(TAINT_CRAP, LOCKDEP_STILL_OK);
paddr = gicr_read_pendbaser(rbase + GICR_PENDBASER);
paddr &= GENMASK_ULL(51, 16);
WARN_ON(!gic_check_reserved_range(paddr, LPI_PENDBASE_SZ));
gic_data_rdist()->flags |= RD_LOCAL_PENDTABLE_PREALLOCATED;
goto out;
}
pend_page = gic_data_rdist()->pend_page;
paddr = page_to_phys(pend_page);
/* set PROPBASE */
val = (gic_rdists->prop_table_pa |
GICR_PROPBASER_InnerShareable |
GICR_PROPBASER_RaWaWb |
((LPI_NRBITS - 1) & GICR_PROPBASER_IDBITS_MASK));
gicr_write_propbaser(val, rbase + GICR_PROPBASER);
tmp = gicr_read_propbaser(rbase + GICR_PROPBASER);
if (!rdists_support_shareable())
tmp &= ~GICR_PROPBASER_SHAREABILITY_MASK;
if ((tmp ^ val) & GICR_PROPBASER_SHAREABILITY_MASK) {
if (!(tmp & GICR_PROPBASER_SHAREABILITY_MASK)) {
/*
* The HW reports non-shareable, we must
* remove the cacheability attributes as
* well.
*/
val &= ~(GICR_PROPBASER_SHAREABILITY_MASK |
GICR_PROPBASER_CACHEABILITY_MASK);
val |= GICR_PROPBASER_nC;
gicr_write_propbaser(val, rbase + GICR_PROPBASER);
}
pr_info_once("GIC: using cache flushing for LPI property table\n");
gic_rdists->flags |= RDIST_FLAGS_PROPBASE_NEEDS_FLUSHING;
}
/* set PENDBASE */
val = (page_to_phys(pend_page) |
GICR_PENDBASER_InnerShareable |
GICR_PENDBASER_RaWaWb);
gicr_write_pendbaser(val, rbase + GICR_PENDBASER);
tmp = gicr_read_pendbaser(rbase + GICR_PENDBASER);
if (!rdists_support_shareable())
tmp &= ~GICR_PENDBASER_SHAREABILITY_MASK;
if (!(tmp & GICR_PENDBASER_SHAREABILITY_MASK)) {
/*
* The HW reports non-shareable, we must remove the
* cacheability attributes as well.
*/
val &= ~(GICR_PENDBASER_SHAREABILITY_MASK |
GICR_PENDBASER_CACHEABILITY_MASK);
val |= GICR_PENDBASER_nC;
gicr_write_pendbaser(val, rbase + GICR_PENDBASER);
}
/* Enable LPIs */
val = readl_relaxed(rbase + GICR_CTLR);
val |= GICR_CTLR_ENABLE_LPIS;
writel_relaxed(val, rbase + GICR_CTLR);
out:
if (gic_rdists->has_vlpis && !gic_rdists->has_rvpeid) {
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
/*
* It's possible for CPU to receive VLPIs before it is
* scheduled as a vPE, especially for the first CPU, and the
* VLPI with INTID larger than 2^(IDbits+1) will be considered
* as out of range and dropped by GIC.
* So we initialize IDbits to known value to avoid VLPI drop.
*/
val = (LPI_NRBITS - 1) & GICR_VPROPBASER_IDBITS_MASK;
pr_debug("GICv4: CPU%d: Init IDbits to 0x%llx for GICR_VPROPBASER\n",
smp_processor_id(), val);
gicr_write_vpropbaser(val, vlpi_base + GICR_VPROPBASER);
/*
* Also clear Valid bit of GICR_VPENDBASER, in case some
* ancient programming gets left in and has possibility of
* corrupting memory.
*/
val = its_clear_vpend_valid(vlpi_base, 0, 0);
}
if (allocate_vpe_l1_table()) {
/*
* If the allocation has failed, we're in massive trouble.
* Disable direct injection, and pray that no VM was
* already running...
*/
gic_rdists->has_rvpeid = false;
gic_rdists->has_vlpis = false;
}
/* Make sure the GIC has seen the above */
dsb(sy);
gic_data_rdist()->flags |= RD_LOCAL_LPI_ENABLED;
pr_info("GICv3: CPU%d: using %s LPI pending table @%pa\n",
smp_processor_id(),
gic_data_rdist()->flags & RD_LOCAL_PENDTABLE_PREALLOCATED ?
"reserved" : "allocated",
&paddr);
}
static void its_cpu_init_collection(struct its_node *its)
{
int cpu = smp_processor_id();
u64 target;
/* avoid cross node collections and its mapping */
if (its->flags & ITS_FLAGS_WORKAROUND_CAVIUM_23144) {
struct device_node *cpu_node;
cpu_node = of_get_cpu_node(cpu, NULL);
if (its->numa_node != NUMA_NO_NODE &&
its->numa_node != of_node_to_nid(cpu_node))
return;
}
/*
* We now have to bind each collection to its target
* redistributor.
*/
if (gic_read_typer(its->base + GITS_TYPER) & GITS_TYPER_PTA) {
/*
* This ITS wants the physical address of the
* redistributor.
*/
target = gic_data_rdist()->phys_base;
} else {
/* This ITS wants a linear CPU number. */
target = gic_read_typer(gic_data_rdist_rd_base() + GICR_TYPER);
target = GICR_TYPER_CPU_NUMBER(target) << 16;
}
/* Perform collection mapping */
its->collections[cpu].target_address = target;
its->collections[cpu].col_id = cpu;
its_send_mapc(its, &its->collections[cpu], 1);
its_send_invall(its, &its->collections[cpu]);
}
static void its_cpu_init_collections(void)
{
struct its_node *its;
raw_spin_lock(&its_lock);
list_for_each_entry(its, &its_nodes, entry)
its_cpu_init_collection(its);
raw_spin_unlock(&its_lock);
}
static struct its_device *its_find_device(struct its_node *its, u32 dev_id)
{
struct its_device *its_dev = NULL, *tmp;
unsigned long flags;
raw_spin_lock_irqsave(&its->lock, flags);
list_for_each_entry(tmp, &its->its_device_list, entry) {
if (tmp->device_id == dev_id) {
its_dev = tmp;
break;
}
}
raw_spin_unlock_irqrestore(&its->lock, flags);
return its_dev;
}
static struct its_baser *its_get_baser(struct its_node *its, u32 type)
{
int i;
for (i = 0; i < GITS_BASER_NR_REGS; i++) {
if (GITS_BASER_TYPE(its->tables[i].val) == type)
return &its->tables[i];
}
return NULL;
}
static bool its_alloc_table_entry(struct its_node *its,
struct its_baser *baser, u32 id)
{
struct page *page;
u32 esz, idx;
__le64 *table;
/* Don't allow device id that exceeds single, flat table limit */
esz = GITS_BASER_ENTRY_SIZE(baser->val);
if (!(baser->val & GITS_BASER_INDIRECT))
return (id < (PAGE_ORDER_TO_SIZE(baser->order) / esz));
/* Compute 1st level table index & check if that exceeds table limit */
idx = id >> ilog2(baser->psz / esz);
if (idx >= (PAGE_ORDER_TO_SIZE(baser->order) / GITS_LVL1_ENTRY_SIZE))
return false;
table = baser->base;
/* Allocate memory for 2nd level table */
if (!table[idx]) {
page = alloc_pages_node(its->numa_node, GFP_KERNEL | __GFP_ZERO,
get_order(baser->psz));
if (!page)
return false;
/* Flush Lvl2 table to PoC if hw doesn't support coherency */
if (!(baser->val & GITS_BASER_SHAREABILITY_MASK))
gic_flush_dcache_to_poc(page_address(page), baser->psz);
table[idx] = cpu_to_le64(page_to_phys(page) | GITS_BASER_VALID);
/* Flush Lvl1 entry to PoC if hw doesn't support coherency */
if (!(baser->val & GITS_BASER_SHAREABILITY_MASK))
gic_flush_dcache_to_poc(table + idx, GITS_LVL1_ENTRY_SIZE);
/* Ensure updated table contents are visible to ITS hardware */
dsb(sy);
}
return true;
}
static bool its_alloc_device_table(struct its_node *its, u32 dev_id)
{
struct its_baser *baser;
baser = its_get_baser(its, GITS_BASER_TYPE_DEVICE);
/* Don't allow device id that exceeds ITS hardware limit */
if (!baser)
return (ilog2(dev_id) < device_ids(its));
return its_alloc_table_entry(its, baser, dev_id);
}
static bool its_alloc_vpe_table(u32 vpe_id)
{
struct its_node *its;
int cpu;
/*
* Make sure the L2 tables are allocated on *all* v4 ITSs. We
* could try and only do it on ITSs corresponding to devices
* that have interrupts targeted at this VPE, but the
* complexity becomes crazy (and you have tons of memory
* anyway, right?).
*/
list_for_each_entry(its, &its_nodes, entry) {
struct its_baser *baser;
if (!is_v4(its))
continue;
baser = its_get_baser(its, GITS_BASER_TYPE_VCPU);
if (!baser)
return false;
if (!its_alloc_table_entry(its, baser, vpe_id))
return false;
}
/* Non v4.1? No need to iterate RDs and go back early. */
if (!gic_rdists->has_rvpeid)
return true;
/*
* Make sure the L2 tables are allocated for all copies of
* the L1 table on *all* v4.1 RDs.
*/
for_each_possible_cpu(cpu) {
if (!allocate_vpe_l2_table(cpu, vpe_id))
return false;
}
return true;
}
static struct its_device *its_create_device(struct its_node *its, u32 dev_id,
int nvecs, bool alloc_lpis)
{
struct its_device *dev;
unsigned long *lpi_map = NULL;
unsigned long flags;
u16 *col_map = NULL;
void *itt;
int lpi_base;
int nr_lpis;
int nr_ites;
int sz;
if (!its_alloc_device_table(its, dev_id))
return NULL;
if (WARN_ON(!is_power_of_2(nvecs)))
nvecs = roundup_pow_of_two(nvecs);
dev = kzalloc(sizeof(*dev), GFP_KERNEL);
/*
* Even if the device wants a single LPI, the ITT must be
* sized as a power of two (and you need at least one bit...).
*/
nr_ites = max(2, nvecs);
sz = nr_ites * (FIELD_GET(GITS_TYPER_ITT_ENTRY_SIZE, its->typer) + 1);
sz = max(sz, ITS_ITT_ALIGN) + ITS_ITT_ALIGN - 1;
itt = kzalloc_node(sz, GFP_KERNEL, its->numa_node);
if (alloc_lpis) {
lpi_map = its_lpi_alloc(nvecs, &lpi_base, &nr_lpis);
if (lpi_map)
col_map = kcalloc(nr_lpis, sizeof(*col_map),
GFP_KERNEL);
} else {
col_map = kcalloc(nr_ites, sizeof(*col_map), GFP_KERNEL);
nr_lpis = 0;
lpi_base = 0;
}
if (!dev || !itt || !col_map || (!lpi_map && alloc_lpis)) {
kfree(dev);
kfree(itt);
bitmap_free(lpi_map);
kfree(col_map);
return NULL;
}
gic_flush_dcache_to_poc(itt, sz);
dev->its = its;
dev->itt = itt;
dev->nr_ites = nr_ites;
dev->event_map.lpi_map = lpi_map;
dev->event_map.col_map = col_map;
dev->event_map.lpi_base = lpi_base;
dev->event_map.nr_lpis = nr_lpis;
raw_spin_lock_init(&dev->event_map.vlpi_lock);
dev->device_id = dev_id;
INIT_LIST_HEAD(&dev->entry);
raw_spin_lock_irqsave(&its->lock, flags);
list_add(&dev->entry, &its->its_device_list);
raw_spin_unlock_irqrestore(&its->lock, flags);
/* Map device to its ITT */
its_send_mapd(dev, 1);
return dev;
}
static void its_free_device(struct its_device *its_dev)
{
unsigned long flags;
raw_spin_lock_irqsave(&its_dev->its->lock, flags);
list_del(&its_dev->entry);
raw_spin_unlock_irqrestore(&its_dev->its->lock, flags);
kfree(its_dev->event_map.col_map);
kfree(its_dev->itt);
kfree(its_dev);
}
static int its_alloc_device_irq(struct its_device *dev, int nvecs, irq_hw_number_t *hwirq)
{
int idx;
/* Find a free LPI region in lpi_map and allocate them. */
idx = bitmap_find_free_region(dev->event_map.lpi_map,
dev->event_map.nr_lpis,
get_count_order(nvecs));
if (idx < 0)
return -ENOSPC;
*hwirq = dev->event_map.lpi_base + idx;
return 0;
}
static int its_msi_prepare(struct irq_domain *domain, struct device *dev,
int nvec, msi_alloc_info_t *info)
{
struct its_node *its;
struct its_device *its_dev;
struct msi_domain_info *msi_info;
u32 dev_id;
int err = 0;
/*
* We ignore "dev" entirely, and rely on the dev_id that has
* been passed via the scratchpad. This limits this domain's
* usefulness to upper layers that definitely know that they
* are built on top of the ITS.
*/
dev_id = info->scratchpad[0].ul;
msi_info = msi_get_domain_info(domain);
its = msi_info->data;
if (!gic_rdists->has_direct_lpi &&
vpe_proxy.dev &&
vpe_proxy.dev->its == its &&
dev_id == vpe_proxy.dev->device_id) {
/* Bad luck. Get yourself a better implementation */
WARN_ONCE(1, "DevId %x clashes with GICv4 VPE proxy device\n",
dev_id);
return -EINVAL;
}
mutex_lock(&its->dev_alloc_lock);
its_dev = its_find_device(its, dev_id);
if (its_dev) {
/*
* We already have seen this ID, probably through
* another alias (PCI bridge of some sort). No need to
* create the device.
*/
its_dev->shared = true;
pr_debug("Reusing ITT for devID %x\n", dev_id);
goto out;
}
its_dev = its_create_device(its, dev_id, nvec, true);
if (!its_dev) {
err = -ENOMEM;
goto out;
}
if (info->flags & MSI_ALLOC_FLAGS_PROXY_DEVICE)
its_dev->shared = true;
pr_debug("ITT %d entries, %d bits\n", nvec, ilog2(nvec));
out:
mutex_unlock(&its->dev_alloc_lock);
info->scratchpad[0].ptr = its_dev;
return err;
}
static struct msi_domain_ops its_msi_domain_ops = {
.msi_prepare = its_msi_prepare,
};
static int its_irq_gic_domain_alloc(struct irq_domain *domain,
unsigned int virq,
irq_hw_number_t hwirq)
{
struct irq_fwspec fwspec;
if (irq_domain_get_of_node(domain->parent)) {
fwspec.fwnode = domain->parent->fwnode;
fwspec.param_count = 3;
fwspec.param[0] = GIC_IRQ_TYPE_LPI;
fwspec.param[1] = hwirq;
fwspec.param[2] = IRQ_TYPE_EDGE_RISING;
} else if (is_fwnode_irqchip(domain->parent->fwnode)) {
fwspec.fwnode = domain->parent->fwnode;
fwspec.param_count = 2;
fwspec.param[0] = hwirq;
fwspec.param[1] = IRQ_TYPE_EDGE_RISING;
} else {
return -EINVAL;
}
return irq_domain_alloc_irqs_parent(domain, virq, 1, &fwspec);
}
static int its_irq_domain_alloc(struct irq_domain *domain, unsigned int virq,
unsigned int nr_irqs, void *args)
{
msi_alloc_info_t *info = args;
struct its_device *its_dev = info->scratchpad[0].ptr;
struct its_node *its = its_dev->its;
struct irq_data *irqd;
irq_hw_number_t hwirq;
int err;
int i;
err = its_alloc_device_irq(its_dev, nr_irqs, &hwirq);
if (err)
return err;
err = iommu_dma_prepare_msi(info->desc, its->get_msi_base(its_dev));
if (err)
return err;
for (i = 0; i < nr_irqs; i++) {
err = its_irq_gic_domain_alloc(domain, virq + i, hwirq + i);
if (err)
return err;
irq_domain_set_hwirq_and_chip(domain, virq + i,
hwirq + i, &its_irq_chip, its_dev);
irqd = irq_get_irq_data(virq + i);
irqd_set_single_target(irqd);
irqd_set_affinity_on_activate(irqd);
irqd_set_resend_when_in_progress(irqd);
pr_debug("ID:%d pID:%d vID:%d\n",
(int)(hwirq + i - its_dev->event_map.lpi_base),
(int)(hwirq + i), virq + i);
}
return 0;
}
static int its_irq_domain_activate(struct irq_domain *domain,
struct irq_data *d, bool reserve)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
int cpu;
cpu = its_select_cpu(d, cpu_online_mask);
if (cpu < 0 || cpu >= nr_cpu_ids)
return -EINVAL;
its_inc_lpi_count(d, cpu);
its_dev->event_map.col_map[event] = cpu;
irq_data_update_effective_affinity(d, cpumask_of(cpu));
/* Map the GIC IRQ and event to the device */
its_send_mapti(its_dev, d->hwirq, event);
return 0;
}
static void its_irq_domain_deactivate(struct irq_domain *domain,
struct irq_data *d)
{
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
u32 event = its_get_event_id(d);
its_dec_lpi_count(d, its_dev->event_map.col_map[event]);
/* Stop the delivery of interrupts */
its_send_discard(its_dev, event);
}
static void its_irq_domain_free(struct irq_domain *domain, unsigned int virq,
unsigned int nr_irqs)
{
struct irq_data *d = irq_domain_get_irq_data(domain, virq);
struct its_device *its_dev = irq_data_get_irq_chip_data(d);
struct its_node *its = its_dev->its;
int i;
bitmap_release_region(its_dev->event_map.lpi_map,
its_get_event_id(irq_domain_get_irq_data(domain, virq)),
get_count_order(nr_irqs));
for (i = 0; i < nr_irqs; i++) {
struct irq_data *data = irq_domain_get_irq_data(domain,
virq + i);
/* Nuke the entry in the domain */
irq_domain_reset_irq_data(data);
}
mutex_lock(&its->dev_alloc_lock);
/*
* If all interrupts have been freed, start mopping the
* floor. This is conditioned on the device not being shared.
*/
if (!its_dev->shared &&
bitmap_empty(its_dev->event_map.lpi_map,
its_dev->event_map.nr_lpis)) {
its_lpi_free(its_dev->event_map.lpi_map,
its_dev->event_map.lpi_base,
its_dev->event_map.nr_lpis);
/* Unmap device/itt */
its_send_mapd(its_dev, 0);
its_free_device(its_dev);
}
mutex_unlock(&its->dev_alloc_lock);
irq_domain_free_irqs_parent(domain, virq, nr_irqs);
}
static const struct irq_domain_ops its_domain_ops = {
.alloc = its_irq_domain_alloc,
.free = its_irq_domain_free,
.activate = its_irq_domain_activate,
.deactivate = its_irq_domain_deactivate,
};
/*
* This is insane.
*
* If a GICv4.0 doesn't implement Direct LPIs (which is extremely
* likely), the only way to perform an invalidate is to use a fake
* device to issue an INV command, implying that the LPI has first
* been mapped to some event on that device. Since this is not exactly
* cheap, we try to keep that mapping around as long as possible, and
* only issue an UNMAP if we're short on available slots.
*
* Broken by design(tm).
*
* GICv4.1, on the other hand, mandates that we're able to invalidate
* by writing to a MMIO register. It doesn't implement the whole of
* DirectLPI, but that's good enough. And most of the time, we don't
* even have to invalidate anything, as the redistributor can be told
* whether to generate a doorbell or not (we thus leave it enabled,
* always).
*/
static void its_vpe_db_proxy_unmap_locked(struct its_vpe *vpe)
{
/* GICv4.1 doesn't use a proxy, so nothing to do here */
if (gic_rdists->has_rvpeid)
return;
/* Already unmapped? */
if (vpe->vpe_proxy_event == -1)
return;
its_send_discard(vpe_proxy.dev, vpe->vpe_proxy_event);
vpe_proxy.vpes[vpe->vpe_proxy_event] = NULL;
/*
* We don't track empty slots at all, so let's move the
* next_victim pointer if we can quickly reuse that slot
* instead of nuking an existing entry. Not clear that this is
* always a win though, and this might just generate a ripple
* effect... Let's just hope VPEs don't migrate too often.
*/
if (vpe_proxy.vpes[vpe_proxy.next_victim])
vpe_proxy.next_victim = vpe->vpe_proxy_event;
vpe->vpe_proxy_event = -1;
}
static void its_vpe_db_proxy_unmap(struct its_vpe *vpe)
{
/* GICv4.1 doesn't use a proxy, so nothing to do here */
if (gic_rdists->has_rvpeid)
return;
if (!gic_rdists->has_direct_lpi) {
unsigned long flags;
raw_spin_lock_irqsave(&vpe_proxy.lock, flags);
its_vpe_db_proxy_unmap_locked(vpe);
raw_spin_unlock_irqrestore(&vpe_proxy.lock, flags);
}
}
static void its_vpe_db_proxy_map_locked(struct its_vpe *vpe)
{
/* GICv4.1 doesn't use a proxy, so nothing to do here */
if (gic_rdists->has_rvpeid)
return;
/* Already mapped? */
if (vpe->vpe_proxy_event != -1)
return;
/* This slot was already allocated. Kick the other VPE out. */
if (vpe_proxy.vpes[vpe_proxy.next_victim])
its_vpe_db_proxy_unmap_locked(vpe_proxy.vpes[vpe_proxy.next_victim]);
/* Map the new VPE instead */
vpe_proxy.vpes[vpe_proxy.next_victim] = vpe;
vpe->vpe_proxy_event = vpe_proxy.next_victim;
vpe_proxy.next_victim = (vpe_proxy.next_victim + 1) % vpe_proxy.dev->nr_ites;
vpe_proxy.dev->event_map.col_map[vpe->vpe_proxy_event] = vpe->col_idx;
its_send_mapti(vpe_proxy.dev, vpe->vpe_db_lpi, vpe->vpe_proxy_event);
}
static void its_vpe_db_proxy_move(struct its_vpe *vpe, int from, int to)
{
unsigned long flags;
struct its_collection *target_col;
/* GICv4.1 doesn't use a proxy, so nothing to do here */
if (gic_rdists->has_rvpeid)
return;
if (gic_rdists->has_direct_lpi) {
void __iomem *rdbase;
rdbase = per_cpu_ptr(gic_rdists->rdist, from)->rd_base;
gic_write_lpir(vpe->vpe_db_lpi, rdbase + GICR_CLRLPIR);
wait_for_syncr(rdbase);
return;
}
raw_spin_lock_irqsave(&vpe_proxy.lock, flags);
its_vpe_db_proxy_map_locked(vpe);
target_col = &vpe_proxy.dev->its->collections[to];
its_send_movi(vpe_proxy.dev, target_col, vpe->vpe_proxy_event);
vpe_proxy.dev->event_map.col_map[vpe->vpe_proxy_event] = to;
raw_spin_unlock_irqrestore(&vpe_proxy.lock, flags);
}
static int its_vpe_set_affinity(struct irq_data *d,
const struct cpumask *mask_val,
bool force)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct cpumask common, *table_mask;
unsigned long flags;
int from, cpu;
/*
* Changing affinity is mega expensive, so let's be as lazy as
* we can and only do it if we really have to. Also, if mapped
* into the proxy device, we need to move the doorbell
* interrupt to its new location.
*
* Another thing is that changing the affinity of a vPE affects
* *other interrupts* such as all the vLPIs that are routed to
* this vPE. This means that the irq_desc lock is not enough to
* protect us, and that we must ensure nobody samples vpe->col_idx
* during the update, hence the lock below which must also be
* taken on any vLPI handling path that evaluates vpe->col_idx.
*/
from = vpe_to_cpuid_lock(vpe, &flags);
table_mask = gic_data_rdist_cpu(from)->vpe_table_mask;
/*
* If we are offered another CPU in the same GICv4.1 ITS
* affinity, pick this one. Otherwise, any CPU will do.
*/
if (table_mask && cpumask_and(&common, mask_val, table_mask))
cpu = cpumask_test_cpu(from, &common) ? from : cpumask_first(&common);
else
cpu = cpumask_first(mask_val);
if (from == cpu)
goto out;
vpe->col_idx = cpu;
its_send_vmovp(vpe);
its_vpe_db_proxy_move(vpe, from, cpu);
out:
irq_data_update_effective_affinity(d, cpumask_of(cpu));
vpe_to_cpuid_unlock(vpe, flags);
return IRQ_SET_MASK_OK_DONE;
}
static void its_wait_vpt_parse_complete(void)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val;
if (!gic_rdists->has_vpend_valid_dirty)
return;
WARN_ON_ONCE(readq_relaxed_poll_timeout_atomic(vlpi_base + GICR_VPENDBASER,
val,
!(val & GICR_VPENDBASER_Dirty),
1, 500));
}
static void its_vpe_schedule(struct its_vpe *vpe)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val;
/* Schedule the VPE */
val = virt_to_phys(page_address(vpe->its_vm->vprop_page)) &
GENMASK_ULL(51, 12);
val |= (LPI_NRBITS - 1) & GICR_VPROPBASER_IDBITS_MASK;
if (rdists_support_shareable()) {
val |= GICR_VPROPBASER_RaWb;
val |= GICR_VPROPBASER_InnerShareable;
}
gicr_write_vpropbaser(val, vlpi_base + GICR_VPROPBASER);
val = virt_to_phys(page_address(vpe->vpt_page)) &
GENMASK_ULL(51, 16);
if (rdists_support_shareable()) {
val |= GICR_VPENDBASER_RaWaWb;
val |= GICR_VPENDBASER_InnerShareable;
}
/*
* There is no good way of finding out if the pending table is
* empty as we can race against the doorbell interrupt very
* easily. So in the end, vpe->pending_last is only an
* indication that the vcpu has something pending, not one
* that the pending table is empty. A good implementation
* would be able to read its coarse map pretty quickly anyway,
* making this a tolerable issue.
*/
val |= GICR_VPENDBASER_PendingLast;
val |= vpe->idai ? GICR_VPENDBASER_IDAI : 0;
val |= GICR_VPENDBASER_Valid;
gicr_write_vpendbaser(val, vlpi_base + GICR_VPENDBASER);
}
static void its_vpe_deschedule(struct its_vpe *vpe)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val;
val = its_clear_vpend_valid(vlpi_base, 0, 0);
vpe->idai = !!(val & GICR_VPENDBASER_IDAI);
vpe->pending_last = !!(val & GICR_VPENDBASER_PendingLast);
}
static void its_vpe_invall(struct its_vpe *vpe)
{
struct its_node *its;
list_for_each_entry(its, &its_nodes, entry) {
if (!is_v4(its))
continue;
if (its_list_map && !vpe->its_vm->vlpi_count[its->list_nr])
continue;
/*
* Sending a VINVALL to a single ITS is enough, as all
* we need is to reach the redistributors.
*/
its_send_vinvall(its, vpe);
return;
}
}
static int its_vpe_set_vcpu_affinity(struct irq_data *d, void *vcpu_info)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_cmd_info *info = vcpu_info;
switch (info->cmd_type) {
case SCHEDULE_VPE:
its_vpe_schedule(vpe);
return 0;
case DESCHEDULE_VPE:
its_vpe_deschedule(vpe);
return 0;
case COMMIT_VPE:
its_wait_vpt_parse_complete();
return 0;
case INVALL_VPE:
its_vpe_invall(vpe);
return 0;
default:
return -EINVAL;
}
}
static void its_vpe_send_cmd(struct its_vpe *vpe,
void (*cmd)(struct its_device *, u32))
{
unsigned long flags;
raw_spin_lock_irqsave(&vpe_proxy.lock, flags);
its_vpe_db_proxy_map_locked(vpe);
cmd(vpe_proxy.dev, vpe->vpe_proxy_event);
raw_spin_unlock_irqrestore(&vpe_proxy.lock, flags);
}
static void its_vpe_send_inv(struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
if (gic_rdists->has_direct_lpi)
__direct_lpi_inv(d, d->parent_data->hwirq);
else
its_vpe_send_cmd(vpe, its_send_inv);
}
static void its_vpe_mask_irq(struct irq_data *d)
{
/*
* We need to unmask the LPI, which is described by the parent
* irq_data. Instead of calling into the parent (which won't
* exactly do the right thing, let's simply use the
* parent_data pointer. Yes, I'm naughty.
*/
lpi_write_config(d->parent_data, LPI_PROP_ENABLED, 0);
its_vpe_send_inv(d);
}
static void its_vpe_unmask_irq(struct irq_data *d)
{
/* Same hack as above... */
lpi_write_config(d->parent_data, 0, LPI_PROP_ENABLED);
its_vpe_send_inv(d);
}
static int its_vpe_set_irqchip_state(struct irq_data *d,
enum irqchip_irq_state which,
bool state)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
if (which != IRQCHIP_STATE_PENDING)
return -EINVAL;
if (gic_rdists->has_direct_lpi) {
void __iomem *rdbase;
rdbase = per_cpu_ptr(gic_rdists->rdist, vpe->col_idx)->rd_base;
if (state) {
gic_write_lpir(vpe->vpe_db_lpi, rdbase + GICR_SETLPIR);
} else {
gic_write_lpir(vpe->vpe_db_lpi, rdbase + GICR_CLRLPIR);
wait_for_syncr(rdbase);
}
} else {
if (state)
its_vpe_send_cmd(vpe, its_send_int);
else
its_vpe_send_cmd(vpe, its_send_clear);
}
return 0;
}
static int its_vpe_retrigger(struct irq_data *d)
{
return !its_vpe_set_irqchip_state(d, IRQCHIP_STATE_PENDING, true);
}
static struct irq_chip its_vpe_irq_chip = {
.name = "GICv4-vpe",
.irq_mask = its_vpe_mask_irq,
.irq_unmask = its_vpe_unmask_irq,
.irq_eoi = irq_chip_eoi_parent,
.irq_set_affinity = its_vpe_set_affinity,
.irq_retrigger = its_vpe_retrigger,
.irq_set_irqchip_state = its_vpe_set_irqchip_state,
.irq_set_vcpu_affinity = its_vpe_set_vcpu_affinity,
};
static struct its_node *find_4_1_its(void)
{
static struct its_node *its = NULL;
if (!its) {
list_for_each_entry(its, &its_nodes, entry) {
if (is_v4_1(its))
return its;
}
/* Oops? */
its = NULL;
}
return its;
}
static void its_vpe_4_1_send_inv(struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_node *its;
/*
* GICv4.1 wants doorbells to be invalidated using the
* INVDB command in order to be broadcast to all RDs. Send
* it to the first valid ITS, and let the HW do its magic.
*/
its = find_4_1_its();
if (its)
its_send_invdb(its, vpe);
}
static void its_vpe_4_1_mask_irq(struct irq_data *d)
{
lpi_write_config(d->parent_data, LPI_PROP_ENABLED, 0);
its_vpe_4_1_send_inv(d);
}
static void its_vpe_4_1_unmask_irq(struct irq_data *d)
{
lpi_write_config(d->parent_data, 0, LPI_PROP_ENABLED);
its_vpe_4_1_send_inv(d);
}
static void its_vpe_4_1_schedule(struct its_vpe *vpe,
struct its_cmd_info *info)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val = 0;
/* Schedule the VPE */
val |= GICR_VPENDBASER_Valid;
val |= info->g0en ? GICR_VPENDBASER_4_1_VGRP0EN : 0;
val |= info->g1en ? GICR_VPENDBASER_4_1_VGRP1EN : 0;
val |= FIELD_PREP(GICR_VPENDBASER_4_1_VPEID, vpe->vpe_id);
gicr_write_vpendbaser(val, vlpi_base + GICR_VPENDBASER);
}
static void its_vpe_4_1_deschedule(struct its_vpe *vpe,
struct its_cmd_info *info)
{
void __iomem *vlpi_base = gic_data_rdist_vlpi_base();
u64 val;
if (info->req_db) {
unsigned long flags;
/*
* vPE is going to block: make the vPE non-resident with
* PendingLast clear and DB set. The GIC guarantees that if
* we read-back PendingLast clear, then a doorbell will be
* delivered when an interrupt comes.
*
* Note the locking to deal with the concurrent update of
* pending_last from the doorbell interrupt handler that can
* run concurrently.
*/
raw_spin_lock_irqsave(&vpe->vpe_lock, flags);
val = its_clear_vpend_valid(vlpi_base,
GICR_VPENDBASER_PendingLast,
GICR_VPENDBASER_4_1_DB);
vpe->pending_last = !!(val & GICR_VPENDBASER_PendingLast);
raw_spin_unlock_irqrestore(&vpe->vpe_lock, flags);
} else {
/*
* We're not blocking, so just make the vPE non-resident
* with PendingLast set, indicating that we'll be back.
*/
val = its_clear_vpend_valid(vlpi_base,
0,
GICR_VPENDBASER_PendingLast);
vpe->pending_last = true;
}
}
static void its_vpe_4_1_invall(struct its_vpe *vpe)
{
void __iomem *rdbase;
unsigned long flags;
u64 val;
int cpu;
val = GICR_INVALLR_V;
val |= FIELD_PREP(GICR_INVALLR_VPEID, vpe->vpe_id);
/* Target the redistributor this vPE is currently known on */
cpu = vpe_to_cpuid_lock(vpe, &flags);
raw_spin_lock(&gic_data_rdist_cpu(cpu)->rd_lock);
rdbase = per_cpu_ptr(gic_rdists->rdist, cpu)->rd_base;
gic_write_lpir(val, rdbase + GICR_INVALLR);
wait_for_syncr(rdbase);
raw_spin_unlock(&gic_data_rdist_cpu(cpu)->rd_lock);
vpe_to_cpuid_unlock(vpe, flags);
}
static int its_vpe_4_1_set_vcpu_affinity(struct irq_data *d, void *vcpu_info)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_cmd_info *info = vcpu_info;
switch (info->cmd_type) {
case SCHEDULE_VPE:
its_vpe_4_1_schedule(vpe, info);
return 0;
case DESCHEDULE_VPE:
its_vpe_4_1_deschedule(vpe, info);
return 0;
case COMMIT_VPE:
its_wait_vpt_parse_complete();
return 0;
case INVALL_VPE:
its_vpe_4_1_invall(vpe);
return 0;
default:
return -EINVAL;
}
}
static struct irq_chip its_vpe_4_1_irq_chip = {
.name = "GICv4.1-vpe",
.irq_mask = its_vpe_4_1_mask_irq,
.irq_unmask = its_vpe_4_1_unmask_irq,
.irq_eoi = irq_chip_eoi_parent,
.irq_set_affinity = its_vpe_set_affinity,
.irq_set_vcpu_affinity = its_vpe_4_1_set_vcpu_affinity,
};
static void its_configure_sgi(struct irq_data *d, bool clear)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_cmd_desc desc;
desc.its_vsgi_cmd.vpe = vpe;
desc.its_vsgi_cmd.sgi = d->hwirq;
desc.its_vsgi_cmd.priority = vpe->sgi_config[d->hwirq].priority;
desc.its_vsgi_cmd.enable = vpe->sgi_config[d->hwirq].enabled;
desc.its_vsgi_cmd.group = vpe->sgi_config[d->hwirq].group;
desc.its_vsgi_cmd.clear = clear;
/*
* GICv4.1 allows us to send VSGI commands to any ITS as long as the
* destination VPE is mapped there. Since we map them eagerly at
* activation time, we're pretty sure the first GICv4.1 ITS will do.
*/
its_send_single_vcommand(find_4_1_its(), its_build_vsgi_cmd, &desc);
}
static void its_sgi_mask_irq(struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
vpe->sgi_config[d->hwirq].enabled = false;
its_configure_sgi(d, false);
}
static void its_sgi_unmask_irq(struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
vpe->sgi_config[d->hwirq].enabled = true;
its_configure_sgi(d, false);
}
static int its_sgi_set_affinity(struct irq_data *d,
const struct cpumask *mask_val,
bool force)
{
/*
* There is no notion of affinity for virtual SGIs, at least
* not on the host (since they can only be targeting a vPE).
* Tell the kernel we've done whatever it asked for.
*/
irq_data_update_effective_affinity(d, mask_val);
return IRQ_SET_MASK_OK;
}
static int its_sgi_set_irqchip_state(struct irq_data *d,
enum irqchip_irq_state which,
bool state)
{
if (which != IRQCHIP_STATE_PENDING)
return -EINVAL;
if (state) {
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_node *its = find_4_1_its();
u64 val;
val = FIELD_PREP(GITS_SGIR_VPEID, vpe->vpe_id);
val |= FIELD_PREP(GITS_SGIR_VINTID, d->hwirq);
writeq_relaxed(val, its->sgir_base + GITS_SGIR - SZ_128K);
} else {
its_configure_sgi(d, true);
}
return 0;
}
static int its_sgi_get_irqchip_state(struct irq_data *d,
enum irqchip_irq_state which, bool *val)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
void __iomem *base;
unsigned long flags;
u32 count = 1000000; /* 1s! */
u32 status;
int cpu;
if (which != IRQCHIP_STATE_PENDING)
return -EINVAL;
/*
* Locking galore! We can race against two different events:
*
* - Concurrent vPE affinity change: we must make sure it cannot
* happen, or we'll talk to the wrong redistributor. This is
* identical to what happens with vLPIs.
*
* - Concurrent VSGIPENDR access: As it involves accessing two
* MMIO registers, this must be made atomic one way or another.
*/
cpu = vpe_to_cpuid_lock(vpe, &flags);
raw_spin_lock(&gic_data_rdist_cpu(cpu)->rd_lock);
base = gic_data_rdist_cpu(cpu)->rd_base + SZ_128K;
writel_relaxed(vpe->vpe_id, base + GICR_VSGIR);
do {
status = readl_relaxed(base + GICR_VSGIPENDR);
if (!(status & GICR_VSGIPENDR_BUSY))
goto out;
count--;
if (!count) {
pr_err_ratelimited("Unable to get SGI status\n");
goto out;
}
cpu_relax();
udelay(1);
} while (count);
out:
raw_spin_unlock(&gic_data_rdist_cpu(cpu)->rd_lock);
vpe_to_cpuid_unlock(vpe, flags);
if (!count)
return -ENXIO;
*val = !!(status & (1 << d->hwirq));
return 0;
}
static int its_sgi_set_vcpu_affinity(struct irq_data *d, void *vcpu_info)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_cmd_info *info = vcpu_info;
switch (info->cmd_type) {
case PROP_UPDATE_VSGI:
vpe->sgi_config[d->hwirq].priority = info->priority;
vpe->sgi_config[d->hwirq].group = info->group;
its_configure_sgi(d, false);
return 0;
default:
return -EINVAL;
}
}
static struct irq_chip its_sgi_irq_chip = {
.name = "GICv4.1-sgi",
.irq_mask = its_sgi_mask_irq,
.irq_unmask = its_sgi_unmask_irq,
.irq_set_affinity = its_sgi_set_affinity,
.irq_set_irqchip_state = its_sgi_set_irqchip_state,
.irq_get_irqchip_state = its_sgi_get_irqchip_state,
.irq_set_vcpu_affinity = its_sgi_set_vcpu_affinity,
};
static int its_sgi_irq_domain_alloc(struct irq_domain *domain,
unsigned int virq, unsigned int nr_irqs,
void *args)
{
struct its_vpe *vpe = args;
int i;
/* Yes, we do want 16 SGIs */
WARN_ON(nr_irqs != 16);
for (i = 0; i < 16; i++) {
vpe->sgi_config[i].priority = 0;
vpe->sgi_config[i].enabled = false;
vpe->sgi_config[i].group = false;
irq_domain_set_hwirq_and_chip(domain, virq + i, i,
&its_sgi_irq_chip, vpe);
irq_set_status_flags(virq + i, IRQ_DISABLE_UNLAZY);
}
return 0;
}
static void its_sgi_irq_domain_free(struct irq_domain *domain,
unsigned int virq,
unsigned int nr_irqs)
{
/* Nothing to do */
}
static int its_sgi_irq_domain_activate(struct irq_domain *domain,
struct irq_data *d, bool reserve)
{
/* Write out the initial SGI configuration */
its_configure_sgi(d, false);
return 0;
}
static void its_sgi_irq_domain_deactivate(struct irq_domain *domain,
struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
/*
* The VSGI command is awkward:
*
* - To change the configuration, CLEAR must be set to false,
* leaving the pending bit unchanged.
* - To clear the pending bit, CLEAR must be set to true, leaving
* the configuration unchanged.
*
* You just can't do both at once, hence the two commands below.
*/
vpe->sgi_config[d->hwirq].enabled = false;
its_configure_sgi(d, false);
its_configure_sgi(d, true);
}
static const struct irq_domain_ops its_sgi_domain_ops = {
.alloc = its_sgi_irq_domain_alloc,
.free = its_sgi_irq_domain_free,
.activate = its_sgi_irq_domain_activate,
.deactivate = its_sgi_irq_domain_deactivate,
};
static int its_vpe_id_alloc(void)
{
return ida_simple_get(&its_vpeid_ida, 0, ITS_MAX_VPEID, GFP_KERNEL);
}
static void its_vpe_id_free(u16 id)
{
ida_simple_remove(&its_vpeid_ida, id);
}
static int its_vpe_init(struct its_vpe *vpe)
{
struct page *vpt_page;
int vpe_id;
/* Allocate vpe_id */
vpe_id = its_vpe_id_alloc();
if (vpe_id < 0)
return vpe_id;
/* Allocate VPT */
vpt_page = its_allocate_pending_table(GFP_KERNEL);
if (!vpt_page) {
its_vpe_id_free(vpe_id);
return -ENOMEM;
}
if (!its_alloc_vpe_table(vpe_id)) {
its_vpe_id_free(vpe_id);
its_free_pending_table(vpt_page);
return -ENOMEM;
}
raw_spin_lock_init(&vpe->vpe_lock);
vpe->vpe_id = vpe_id;
vpe->vpt_page = vpt_page;
if (gic_rdists->has_rvpeid)
atomic_set(&vpe->vmapp_count, 0);
else
vpe->vpe_proxy_event = -1;
return 0;
}
static void its_vpe_teardown(struct its_vpe *vpe)
{
its_vpe_db_proxy_unmap(vpe);
its_vpe_id_free(vpe->vpe_id);
its_free_pending_table(vpe->vpt_page);
}
static void its_vpe_irq_domain_free(struct irq_domain *domain,
unsigned int virq,
unsigned int nr_irqs)
{
struct its_vm *vm = domain->host_data;
int i;
irq_domain_free_irqs_parent(domain, virq, nr_irqs);
for (i = 0; i < nr_irqs; i++) {
struct irq_data *data = irq_domain_get_irq_data(domain,
virq + i);
struct its_vpe *vpe = irq_data_get_irq_chip_data(data);
BUG_ON(vm != vpe->its_vm);
clear_bit(data->hwirq, vm->db_bitmap);
its_vpe_teardown(vpe);
irq_domain_reset_irq_data(data);
}
if (bitmap_empty(vm->db_bitmap, vm->nr_db_lpis)) {
its_lpi_free(vm->db_bitmap, vm->db_lpi_base, vm->nr_db_lpis);
its_free_prop_table(vm->vprop_page);
}
}
static int its_vpe_irq_domain_alloc(struct irq_domain *domain, unsigned int virq,
unsigned int nr_irqs, void *args)
{
struct irq_chip *irqchip = &its_vpe_irq_chip;
struct its_vm *vm = args;
unsigned long *bitmap;
struct page *vprop_page;
int base, nr_ids, i, err = 0;
BUG_ON(!vm);
bitmap = its_lpi_alloc(roundup_pow_of_two(nr_irqs), &base, &nr_ids);
if (!bitmap)
return -ENOMEM;
if (nr_ids < nr_irqs) {
its_lpi_free(bitmap, base, nr_ids);
return -ENOMEM;
}
vprop_page = its_allocate_prop_table(GFP_KERNEL);
if (!vprop_page) {
its_lpi_free(bitmap, base, nr_ids);
return -ENOMEM;
}
vm->db_bitmap = bitmap;
vm->db_lpi_base = base;
vm->nr_db_lpis = nr_ids;
vm->vprop_page = vprop_page;
if (gic_rdists->has_rvpeid)
irqchip = &its_vpe_4_1_irq_chip;
for (i = 0; i < nr_irqs; i++) {
vm->vpes[i]->vpe_db_lpi = base + i;
err = its_vpe_init(vm->vpes[i]);
if (err)
break;
err = its_irq_gic_domain_alloc(domain, virq + i,
vm->vpes[i]->vpe_db_lpi);
if (err)
break;
irq_domain_set_hwirq_and_chip(domain, virq + i, i,
irqchip, vm->vpes[i]);
set_bit(i, bitmap);
irqd_set_resend_when_in_progress(irq_get_irq_data(virq + i));
}
if (err)
its_vpe_irq_domain_free(domain, virq, i);
return err;
}
static int its_vpe_irq_domain_activate(struct irq_domain *domain,
struct irq_data *d, bool reserve)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_node *its;
/*
* If we use the list map, we issue VMAPP on demand... Unless
* we're on a GICv4.1 and we eagerly map the VPE on all ITSs
* so that VSGIs can work.
*/
if (!gic_requires_eager_mapping())
return 0;
/* Map the VPE to the first possible CPU */
vpe->col_idx = cpumask_first(cpu_online_mask);
list_for_each_entry(its, &its_nodes, entry) {
if (!is_v4(its))
continue;
its_send_vmapp(its, vpe, true);
its_send_vinvall(its, vpe);
}
irq_data_update_effective_affinity(d, cpumask_of(vpe->col_idx));
return 0;
}
static void its_vpe_irq_domain_deactivate(struct irq_domain *domain,
struct irq_data *d)
{
struct its_vpe *vpe = irq_data_get_irq_chip_data(d);
struct its_node *its;
/*
* If we use the list map on GICv4.0, we unmap the VPE once no
* VLPIs are associated with the VM.
*/
if (!gic_requires_eager_mapping())
return;
list_for_each_entry(its, &its_nodes, entry) {
if (!is_v4(its))
continue;
its_send_vmapp(its, vpe, false);
}
/*
* There may be a direct read to the VPT after unmapping the
* vPE, to guarantee the validity of this, we make the VPT
* memory coherent with the CPU caches here.
*/
if (find_4_1_its() && !atomic_read(&vpe->vmapp_count))
gic_flush_dcache_to_poc(page_address(vpe->vpt_page),
LPI_PENDBASE_SZ);
}
static const struct irq_domain_ops its_vpe_domain_ops = {
.alloc = its_vpe_irq_domain_alloc,
.free = its_vpe_irq_domain_free,
.activate = its_vpe_irq_domain_activate,
.deactivate = its_vpe_irq_domain_deactivate,
};
static int its_force_quiescent(void __iomem *base)
{
u32 count = 1000000; /* 1s */
u32 val;
val = readl_relaxed(base + GITS_CTLR);
/*
* GIC architecture specification requires the ITS to be both
* disabled and quiescent for writes to GITS_BASER<n> or
* GITS_CBASER to not have UNPREDICTABLE results.
*/
if ((val & GITS_CTLR_QUIESCENT) && !(val & GITS_CTLR_ENABLE))
return 0;
/* Disable the generation of all interrupts to this ITS */
val &= ~(GITS_CTLR_ENABLE | GITS_CTLR_ImDe);
writel_relaxed(val, base + GITS_CTLR);
/* Poll GITS_CTLR and wait until ITS becomes quiescent */
while (1) {
val = readl_relaxed(base + GITS_CTLR);
if (val & GITS_CTLR_QUIESCENT)
return 0;
count--;
if (!count)
return -EBUSY;
cpu_relax();
udelay(1);
}
}
static bool __maybe_unused its_enable_quirk_cavium_22375(void *data)
{
struct its_node *its = data;
/* erratum 22375: only alloc 8MB table size (20 bits) */
its->typer &= ~GITS_TYPER_DEVBITS;
its->typer |= FIELD_PREP(GITS_TYPER_DEVBITS, 20 - 1);
its->flags |= ITS_FLAGS_WORKAROUND_CAVIUM_22375;
return true;
}
static bool __maybe_unused its_enable_quirk_cavium_23144(void *data)
{
struct its_node *its = data;
its->flags |= ITS_FLAGS_WORKAROUND_CAVIUM_23144;
return true;
}
static bool __maybe_unused its_enable_quirk_qdf2400_e0065(void *data)
{
struct its_node *its = data;
/* On QDF2400, the size of the ITE is 16Bytes */
its->typer &= ~GITS_TYPER_ITT_ENTRY_SIZE;
its->typer |= FIELD_PREP(GITS_TYPER_ITT_ENTRY_SIZE, 16 - 1);
return true;
}
static u64 its_irq_get_msi_base_pre_its(struct its_device *its_dev)
{
struct its_node *its = its_dev->its;
/*
* The Socionext Synquacer SoC has a so-called 'pre-ITS',
* which maps 32-bit writes targeted at a separate window of
* size '4 << device_id_bits' onto writes to GITS_TRANSLATER
* with device ID taken from bits [device_id_bits + 1:2] of
* the window offset.
*/
return its->pre_its_base + (its_dev->device_id << 2);
}
static bool __maybe_unused its_enable_quirk_socionext_synquacer(void *data)
{
struct its_node *its = data;
u32 pre_its_window[2];
u32 ids;
if (!fwnode_property_read_u32_array(its->fwnode_handle,
"socionext,synquacer-pre-its",
pre_its_window,
ARRAY_SIZE(pre_its_window))) {
its->pre_its_base = pre_its_window[0];
its->get_msi_base = its_irq_get_msi_base_pre_its;
ids = ilog2(pre_its_window[1]) - 2;
if (device_ids(its) > ids) {
its->typer &= ~GITS_TYPER_DEVBITS;
its->typer |= FIELD_PREP(GITS_TYPER_DEVBITS, ids - 1);
}
/* the pre-ITS breaks isolation, so disable MSI remapping */
its->msi_domain_flags &= ~IRQ_DOMAIN_FLAG_ISOLATED_MSI;
return true;
}
return false;
}
static bool __maybe_unused its_enable_quirk_hip07_161600802(void *data)
{
struct its_node *its = data;
/*
* Hip07 insists on using the wrong address for the VLPI
* page. Trick it into doing the right thing...
*/
its->vlpi_redist_offset = SZ_128K;
return true;
}
static bool __maybe_unused its_enable_rk3588001(void *data)
{
struct its_node *its = data;
if (!of_machine_is_compatible("rockchip,rk3588") &&
!of_machine_is_compatible("rockchip,rk3588s"))
return false;
its->flags |= ITS_FLAGS_FORCE_NON_SHAREABLE;
gic_rdists->flags |= RDIST_FLAGS_FORCE_NON_SHAREABLE;
return true;
}
static bool its_set_non_coherent(void *data)
{
struct its_node *its = data;
its->flags |= ITS_FLAGS_FORCE_NON_SHAREABLE;
return true;
}
static const struct gic_quirk its_quirks[] = {
#ifdef CONFIG_CAVIUM_ERRATUM_22375
{
.desc = "ITS: Cavium errata 22375, 24313",
.iidr = 0xa100034c, /* ThunderX pass 1.x */
.mask = 0xffff0fff,
.init = its_enable_quirk_cavium_22375,
},
#endif
#ifdef CONFIG_CAVIUM_ERRATUM_23144
{
.desc = "ITS: Cavium erratum 23144",
.iidr = 0xa100034c, /* ThunderX pass 1.x */
.mask = 0xffff0fff,
.init = its_enable_quirk_cavium_23144,
},
#endif
#ifdef CONFIG_QCOM_QDF2400_ERRATUM_0065
{
.desc = "ITS: QDF2400 erratum 0065",
.iidr = 0x00001070, /* QDF2400 ITS rev 1.x */
.mask = 0xffffffff,
.init = its_enable_quirk_qdf2400_e0065,
},
#endif
#ifdef CONFIG_SOCIONEXT_SYNQUACER_PREITS
{
/*
* The Socionext Synquacer SoC incorporates ARM's own GIC-500
* implementation, but with a 'pre-ITS' added that requires
* special handling in software.
*/
.desc = "ITS: Socionext Synquacer pre-ITS",
.iidr = 0x0001143b,
.mask = 0xffffffff,
.init = its_enable_quirk_socionext_synquacer,
},
#endif
#ifdef CONFIG_HISILICON_ERRATUM_161600802
{
.desc = "ITS: Hip07 erratum 161600802",
.iidr = 0x00000004,
.mask = 0xffffffff,
.init = its_enable_quirk_hip07_161600802,
},
#endif
#ifdef CONFIG_ROCKCHIP_ERRATUM_3588001
{
.desc = "ITS: Rockchip erratum RK3588001",
.iidr = 0x0201743b,
.mask = 0xffffffff,
.init = its_enable_rk3588001,
},
#endif
{
.desc = "ITS: non-coherent attribute",
.property = "dma-noncoherent",
.init = its_set_non_coherent,
},
{
}
};
static void its_enable_quirks(struct its_node *its)
{
u32 iidr = readl_relaxed(its->base + GITS_IIDR);
gic_enable_quirks(iidr, its_quirks, its);
if (is_of_node(its->fwnode_handle))
gic_enable_of_quirks(to_of_node(its->fwnode_handle),
its_quirks, its);
}
static int its_save_disable(void)
{
struct its_node *its;
int err = 0;
raw_spin_lock(&its_lock);
list_for_each_entry(its, &its_nodes, entry) {
void __iomem *base;
base = its->base;
its->ctlr_save = readl_relaxed(base + GITS_CTLR);
err = its_force_quiescent(base);
if (err) {
pr_err("ITS@%pa: failed to quiesce: %d\n",
&its->phys_base, err);
writel_relaxed(its->ctlr_save, base + GITS_CTLR);
goto err;
}
its->cbaser_save = gits_read_cbaser(base + GITS_CBASER);
}
err:
if (err) {
list_for_each_entry_continue_reverse(its, &its_nodes, entry) {
void __iomem *base;
base = its->base;
writel_relaxed(its->ctlr_save, base + GITS_CTLR);
}
}
raw_spin_unlock(&its_lock);
return err;
}
static void its_restore_enable(void)
{
struct its_node *its;
int ret;
raw_spin_lock(&its_lock);
list_for_each_entry(its, &its_nodes, entry) {
void __iomem *base;
int i;
base = its->base;
/*
* Make sure that the ITS is disabled. If it fails to quiesce,
* don't restore it since writing to CBASER or BASER<n>
* registers is undefined according to the GIC v3 ITS
* Specification.
*
* Firmware resuming with the ITS enabled is terminally broken.
*/
WARN_ON(readl_relaxed(base + GITS_CTLR) & GITS_CTLR_ENABLE);
ret = its_force_quiescent(base);
if (ret) {
pr_err("ITS@%pa: failed to quiesce on resume: %d\n",
&its->phys_base, ret);
continue;
}
gits_write_cbaser(its->cbaser_save, base + GITS_CBASER);
/*
* Writing CBASER resets CREADR to 0, so make CWRITER and
* cmd_write line up with it.
*/
its->cmd_write = its->cmd_base;
gits_write_cwriter(0, base + GITS_CWRITER);
/* Restore GITS_BASER from the value cache. */
for (i = 0; i < GITS_BASER_NR_REGS; i++) {
struct its_baser *baser = &its->tables[i];
if (!(baser->val & GITS_BASER_VALID))
continue;
its_write_baser(its, baser, baser->val);
}
writel_relaxed(its->ctlr_save, base + GITS_CTLR);
/*
* Reinit the collection if it's stored in the ITS. This is
* indicated by the col_id being less than the HCC field.
* CID < HCC as specified in the GIC v3 Documentation.
*/
if (its->collections[smp_processor_id()].col_id <
GITS_TYPER_HCC(gic_read_typer(base + GITS_TYPER)))
its_cpu_init_collection(its);
}
raw_spin_unlock(&its_lock);
}
static struct syscore_ops its_syscore_ops = {
.suspend = its_save_disable,
.resume = its_restore_enable,
};
static void __init __iomem *its_map_one(struct resource *res, int *err)
{
void __iomem *its_base;
u32 val;
its_base = ioremap(res->start, SZ_64K);
if (!its_base) {
pr_warn("ITS@%pa: Unable to map ITS registers\n", &res->start);
*err = -ENOMEM;
return NULL;
}
val = readl_relaxed(its_base + GITS_PIDR2) & GIC_PIDR2_ARCH_MASK;
if (val != 0x30 && val != 0x40) {
pr_warn("ITS@%pa: No ITS detected, giving up\n", &res->start);
*err = -ENODEV;
goto out_unmap;
}
*err = its_force_quiescent(its_base);
if (*err) {
pr_warn("ITS@%pa: Failed to quiesce, giving up\n", &res->start);
goto out_unmap;
}
return its_base;
out_unmap:
iounmap(its_base);
return NULL;
}
static int its_init_domain(struct its_node *its)
{
struct irq_domain *inner_domain;
struct msi_domain_info *info;
info = kzalloc(sizeof(*info), GFP_KERNEL);
if (!info)
return -ENOMEM;
info->ops = &its_msi_domain_ops;
info->data = its;
inner_domain = irq_domain_create_hierarchy(its_parent,
its->msi_domain_flags, 0,
its->fwnode_handle, &its_domain_ops,
info);
if (!inner_domain) {
kfree(info);
return -ENOMEM;
}
irq_domain_update_bus_token(inner_domain, DOMAIN_BUS_NEXUS);
return 0;
}
static int its_init_vpe_domain(void)
{
struct its_node *its;
u32 devid;
int entries;
if (gic_rdists->has_direct_lpi) {
pr_info("ITS: Using DirectLPI for VPE invalidation\n");
return 0;
}
/* Any ITS will do, even if not v4 */
its = list_first_entry(&its_nodes, struct its_node, entry);
entries = roundup_pow_of_two(nr_cpu_ids);
vpe_proxy.vpes = kcalloc(entries, sizeof(*vpe_proxy.vpes),
GFP_KERNEL);
if (!vpe_proxy.vpes)
return -ENOMEM;
/* Use the last possible DevID */
devid = GENMASK(device_ids(its) - 1, 0);
vpe_proxy.dev = its_create_device(its, devid, entries, false);
if (!vpe_proxy.dev) {
kfree(vpe_proxy.vpes);
pr_err("ITS: Can't allocate GICv4 proxy device\n");
return -ENOMEM;
}
BUG_ON(entries > vpe_proxy.dev->nr_ites);
raw_spin_lock_init(&vpe_proxy.lock);
vpe_proxy.next_victim = 0;
pr_info("ITS: Allocated DevID %x as GICv4 proxy device (%d slots)\n",
devid, vpe_proxy.dev->nr_ites);
return 0;
}
static int __init its_compute_its_list_map(struct its_node *its)
{
int its_number;
u32 ctlr;
/*
* This is assumed to be done early enough that we're
* guaranteed to be single-threaded, hence no
* locking. Should this change, we should address
* this.
*/
its_number = find_first_zero_bit(&its_list_map, GICv4_ITS_LIST_MAX);
if (its_number >= GICv4_ITS_LIST_MAX) {
pr_err("ITS@%pa: No ITSList entry available!\n",
&its->phys_base);
return -EINVAL;
}
ctlr = readl_relaxed(its->base + GITS_CTLR);
ctlr &= ~GITS_CTLR_ITS_NUMBER;
ctlr |= its_number << GITS_CTLR_ITS_NUMBER_SHIFT;
writel_relaxed(ctlr, its->base + GITS_CTLR);
ctlr = readl_relaxed(its->base + GITS_CTLR);
if ((ctlr & GITS_CTLR_ITS_NUMBER) != (its_number << GITS_CTLR_ITS_NUMBER_SHIFT)) {
its_number = ctlr & GITS_CTLR_ITS_NUMBER;
its_number >>= GITS_CTLR_ITS_NUMBER_SHIFT;
}
if (test_and_set_bit(its_number, &its_list_map)) {
pr_err("ITS@%pa: Duplicate ITSList entry %d\n",
&its->phys_base, its_number);
return -EINVAL;
}
return its_number;
}
static int __init its_probe_one(struct its_node *its)
{
u64 baser, tmp;
struct page *page;
u32 ctlr;
int err;
its_enable_quirks(its);
if (is_v4(its)) {
if (!(its->typer & GITS_TYPER_VMOVP)) {
err = its_compute_its_list_map(its);
if (err < 0)
goto out;
its->list_nr = err;
pr_info("ITS@%pa: Using ITS number %d\n",
&its->phys_base, err);
} else {
pr_info("ITS@%pa: Single VMOVP capable\n", &its->phys_base);
}
if (is_v4_1(its)) {
u32 svpet = FIELD_GET(GITS_TYPER_SVPET, its->typer);
its->sgir_base = ioremap(its->phys_base + SZ_128K, SZ_64K);
if (!its->sgir_base) {
err = -ENOMEM;
goto out;
}
its->mpidr = readl_relaxed(its->base + GITS_MPIDR);
pr_info("ITS@%pa: Using GICv4.1 mode %08x %08x\n",
&its->phys_base, its->mpidr, svpet);
}
}
page = alloc_pages_node(its->numa_node, GFP_KERNEL | __GFP_ZERO,
get_order(ITS_CMD_QUEUE_SZ));
if (!page) {
err = -ENOMEM;
goto out_unmap_sgir;
}
its->cmd_base = (void *)page_address(page);
its->cmd_write = its->cmd_base;
err = its_alloc_tables(its);
if (err)
goto out_free_cmd;
err = its_alloc_collections(its);
if (err)
goto out_free_tables;
baser = (virt_to_phys(its->cmd_base) |
GITS_CBASER_RaWaWb |
GITS_CBASER_InnerShareable |
(ITS_CMD_QUEUE_SZ / SZ_4K - 1) |
GITS_CBASER_VALID);
gits_write_cbaser(baser, its->base + GITS_CBASER);
tmp = gits_read_cbaser(its->base + GITS_CBASER);
if (its->flags & ITS_FLAGS_FORCE_NON_SHAREABLE)
tmp &= ~GITS_CBASER_SHAREABILITY_MASK;
if ((tmp ^ baser) & GITS_CBASER_SHAREABILITY_MASK) {
if (!(tmp & GITS_CBASER_SHAREABILITY_MASK)) {
/*
* The HW reports non-shareable, we must
* remove the cacheability attributes as
* well.
*/
baser &= ~(GITS_CBASER_SHAREABILITY_MASK |
GITS_CBASER_CACHEABILITY_MASK);
baser |= GITS_CBASER_nC;
gits_write_cbaser(baser, its->base + GITS_CBASER);
}
pr_info("ITS: using cache flushing for cmd queue\n");
its->flags |= ITS_FLAGS_CMDQ_NEEDS_FLUSHING;
}
gits_write_cwriter(0, its->base + GITS_CWRITER);
ctlr = readl_relaxed(its->base + GITS_CTLR);
ctlr |= GITS_CTLR_ENABLE;
if (is_v4(its))
ctlr |= GITS_CTLR_ImDe;
writel_relaxed(ctlr, its->base + GITS_CTLR);
err = its_init_domain(its);
if (err)
goto out_free_tables;
raw_spin_lock(&its_lock);
list_add(&its->entry, &its_nodes);
raw_spin_unlock(&its_lock);
return 0;
out_free_tables:
its_free_tables(its);
out_free_cmd:
free_pages((unsigned long)its->cmd_base, get_order(ITS_CMD_QUEUE_SZ));
out_unmap_sgir:
if (its->sgir_base)
iounmap(its->sgir_base);
out:
pr_err("ITS@%pa: failed probing (%d)\n", &its->phys_base, err);
return err;
}
static bool gic_rdists_supports_plpis(void)
{
return !!(gic_read_typer(gic_data_rdist_rd_base() + GICR_TYPER) & GICR_TYPER_PLPIS);
}
static int redist_disable_lpis(void)
{
void __iomem *rbase = gic_data_rdist_rd_base();
u64 timeout = USEC_PER_SEC;
u64 val;
if (!gic_rdists_supports_plpis()) {
pr_info("CPU%d: LPIs not supported\n", smp_processor_id());
return -ENXIO;
}
val = readl_relaxed(rbase + GICR_CTLR);
if (!(val & GICR_CTLR_ENABLE_LPIS))
return 0;
/*
* If coming via a CPU hotplug event, we don't need to disable
* LPIs before trying to re-enable them. They are already
* configured and all is well in the world.
*
* If running with preallocated tables, there is nothing to do.
*/
if ((gic_data_rdist()->flags & RD_LOCAL_LPI_ENABLED) ||
(gic_rdists->flags & RDIST_FLAGS_RD_TABLES_PREALLOCATED))
return 0;
/*
* From that point on, we only try to do some damage control.
*/
pr_warn("GICv3: CPU%d: Booted with LPIs enabled, memory probably corrupted\n",
smp_processor_id());
add_taint(TAINT_CRAP, LOCKDEP_STILL_OK);
/* Disable LPIs */
val &= ~GICR_CTLR_ENABLE_LPIS;
writel_relaxed(val, rbase + GICR_CTLR);
/* Make sure any change to GICR_CTLR is observable by the GIC */
dsb(sy);
/*
* Software must observe RWP==0 after clearing GICR_CTLR.EnableLPIs
* from 1 to 0 before programming GICR_PEND{PROP}BASER registers.
* Error out if we time out waiting for RWP to clear.
*/
while (readl_relaxed(rbase + GICR_CTLR) & GICR_CTLR_RWP) {
if (!timeout) {
pr_err("CPU%d: Timeout while disabling LPIs\n",
smp_processor_id());
return -ETIMEDOUT;
}
udelay(1);
timeout--;
}
/*
* After it has been written to 1, it is IMPLEMENTATION
* DEFINED whether GICR_CTLR.EnableLPI becomes RES1 or can be
* cleared to 0. Error out if clearing the bit failed.
*/
if (readl_relaxed(rbase + GICR_CTLR) & GICR_CTLR_ENABLE_LPIS) {
pr_err("CPU%d: Failed to disable LPIs\n", smp_processor_id());
return -EBUSY;
}
return 0;
}
int its_cpu_init(void)
{
if (!list_empty(&its_nodes)) {
int ret;
ret = redist_disable_lpis();
if (ret)
return ret;
its_cpu_init_lpis();
its_cpu_init_collections();
}
return 0;
}
static void rdist_memreserve_cpuhp_cleanup_workfn(struct work_struct *work)
{
cpuhp_remove_state_nocalls(gic_rdists->cpuhp_memreserve_state);
gic_rdists->cpuhp_memreserve_state = CPUHP_INVALID;
}
static DECLARE_WORK(rdist_memreserve_cpuhp_cleanup_work,
rdist_memreserve_cpuhp_cleanup_workfn);
static int its_cpu_memreserve_lpi(unsigned int cpu)
{
struct page *pend_page;
int ret = 0;
/* This gets to run exactly once per CPU */
if (gic_data_rdist()->flags & RD_LOCAL_MEMRESERVE_DONE)
return 0;
pend_page = gic_data_rdist()->pend_page;
if (WARN_ON(!pend_page)) {
ret = -ENOMEM;
goto out;
}
/*
* If the pending table was pre-programmed, free the memory we
* preemptively allocated. Otherwise, reserve that memory for
* later kexecs.
*/
if (gic_data_rdist()->flags & RD_LOCAL_PENDTABLE_PREALLOCATED) {
its_free_pending_table(pend_page);
gic_data_rdist()->pend_page = NULL;
} else {
phys_addr_t paddr = page_to_phys(pend_page);
WARN_ON(gic_reserve_range(paddr, LPI_PENDBASE_SZ));
}
out:
/* Last CPU being brought up gets to issue the cleanup */
if (!IS_ENABLED(CONFIG_SMP) ||
cpumask_equal(&cpus_booted_once_mask, cpu_possible_mask))
schedule_work(&rdist_memreserve_cpuhp_cleanup_work);
gic_data_rdist()->flags |= RD_LOCAL_MEMRESERVE_DONE;
return ret;
}
/* Mark all the BASER registers as invalid before they get reprogrammed */
static int __init its_reset_one(struct resource *res)
{
void __iomem *its_base;
int err, i;
its_base = its_map_one(res, &err);
if (!its_base)
return err;
for (i = 0; i < GITS_BASER_NR_REGS; i++)
gits_write_baser(0, its_base + GITS_BASER + (i << 3));
iounmap(its_base);
return 0;
}
static const struct of_device_id its_device_id[] = {
{ .compatible = "arm,gic-v3-its", },
{},
};
static struct its_node __init *its_node_init(struct resource *res,
struct fwnode_handle *handle, int numa_node)
{
void __iomem *its_base;
struct its_node *its;
int err;
its_base = its_map_one(res, &err);
if (!its_base)
return NULL;
pr_info("ITS %pR\n", res);
its = kzalloc(sizeof(*its), GFP_KERNEL);
if (!its)
goto out_unmap;
raw_spin_lock_init(&its->lock);
mutex_init(&its->dev_alloc_lock);
INIT_LIST_HEAD(&its->entry);
INIT_LIST_HEAD(&its->its_device_list);
its->typer = gic_read_typer(its_base + GITS_TYPER);
its->base = its_base;
its->phys_base = res->start;
its->get_msi_base = its_irq_get_msi_base;
its->msi_domain_flags = IRQ_DOMAIN_FLAG_ISOLATED_MSI;
its->numa_node = numa_node;
its->fwnode_handle = handle;
return its;
out_unmap:
iounmap(its_base);
return NULL;
}
static void its_node_destroy(struct its_node *its)
{
iounmap(its->base);
kfree(its);
}
static int __init its_of_probe(struct device_node *node)
{
struct device_node *np;
struct resource res;
int err;
/*
* Make sure *all* the ITS are reset before we probe any, as
* they may be sharing memory. If any of the ITS fails to
* reset, don't even try to go any further, as this could
* result in something even worse.
*/
for (np = of_find_matching_node(node, its_device_id); np;
np = of_find_matching_node(np, its_device_id)) {
if (!of_device_is_available(np) ||
!of_property_read_bool(np, "msi-controller") ||
of_address_to_resource(np, 0, &res))
continue;
err = its_reset_one(&res);
if (err)
return err;
}
for (np = of_find_matching_node(node, its_device_id); np;
np = of_find_matching_node(np, its_device_id)) {
struct its_node *its;
if (!of_device_is_available(np))
continue;
if (!of_property_read_bool(np, "msi-controller")) {
pr_warn("%pOF: no msi-controller property, ITS ignored\n",
np);
continue;
}
if (of_address_to_resource(np, 0, &res)) {
pr_warn("%pOF: no regs?\n", np);
continue;
}
its = its_node_init(&res, &np->fwnode, of_node_to_nid(np));
if (!its)
return -ENOMEM;
err = its_probe_one(its);
if (err) {
its_node_destroy(its);
return err;
}
}
return 0;
}
#ifdef CONFIG_ACPI
#define ACPI_GICV3_ITS_MEM_SIZE (SZ_128K)
#ifdef CONFIG_ACPI_NUMA
struct its_srat_map {
/* numa node id */
u32 numa_node;
/* GIC ITS ID */
u32 its_id;
};
static struct its_srat_map *its_srat_maps __initdata;
static int its_in_srat __initdata;
static int __init acpi_get_its_numa_node(u32 its_id)
{
int i;
for (i = 0; i < its_in_srat; i++) {
if (its_id == its_srat_maps[i].its_id)
return its_srat_maps[i].numa_node;
}
return NUMA_NO_NODE;
}
static int __init gic_acpi_match_srat_its(union acpi_subtable_headers *header,
const unsigned long end)
{
return 0;
}
static int __init gic_acpi_parse_srat_its(union acpi_subtable_headers *header,
const unsigned long end)
{
int node;
struct acpi_srat_gic_its_affinity *its_affinity;
its_affinity = (struct acpi_srat_gic_its_affinity *)header;
if (!its_affinity)
return -EINVAL;
if (its_affinity->header.length < sizeof(*its_affinity)) {
pr_err("SRAT: Invalid header length %d in ITS affinity\n",
its_affinity->header.length);
return -EINVAL;
}
/*
* Note that in theory a new proximity node could be created by this
* entry as it is an SRAT resource allocation structure.
* We do not currently support doing so.
*/
node = pxm_to_node(its_affinity->proximity_domain);
if (node == NUMA_NO_NODE || node >= MAX_NUMNODES) {
pr_err("SRAT: Invalid NUMA node %d in ITS affinity\n", node);
return 0;
}
its_srat_maps[its_in_srat].numa_node = node;
its_srat_maps[its_in_srat].its_id = its_affinity->its_id;
its_in_srat++;
pr_info("SRAT: PXM %d -> ITS %d -> Node %d\n",
its_affinity->proximity_domain, its_affinity->its_id, node);
return 0;
}
static void __init acpi_table_parse_srat_its(void)
{
int count;
count = acpi_table_parse_entries(ACPI_SIG_SRAT,
sizeof(struct acpi_table_srat),
ACPI_SRAT_TYPE_GIC_ITS_AFFINITY,
gic_acpi_match_srat_its, 0);
if (count <= 0)
return;
its_srat_maps = kmalloc_array(count, sizeof(struct its_srat_map),
GFP_KERNEL);
if (!its_srat_maps)
return;
acpi_table_parse_entries(ACPI_SIG_SRAT,
sizeof(struct acpi_table_srat),
ACPI_SRAT_TYPE_GIC_ITS_AFFINITY,
gic_acpi_parse_srat_its, 0);
}
/* free the its_srat_maps after ITS probing */
static void __init acpi_its_srat_maps_free(void)
{
kfree(its_srat_maps);
}
#else
static void __init acpi_table_parse_srat_its(void) { }
static int __init acpi_get_its_numa_node(u32 its_id) { return NUMA_NO_NODE; }
static void __init acpi_its_srat_maps_free(void) { }
#endif
static int __init gic_acpi_parse_madt_its(union acpi_subtable_headers *header,
const unsigned long end)
{
struct acpi_madt_generic_translator *its_entry;
struct fwnode_handle *dom_handle;
struct its_node *its;
struct resource res;
int err;
its_entry = (struct acpi_madt_generic_translator *)header;
memset(&res, 0, sizeof(res));
res.start = its_entry->base_address;
res.end = its_entry->base_address + ACPI_GICV3_ITS_MEM_SIZE - 1;
res.flags = IORESOURCE_MEM;
dom_handle = irq_domain_alloc_fwnode(&res.start);
if (!dom_handle) {
pr_err("ITS@%pa: Unable to allocate GICv3 ITS domain token\n",
&res.start);
return -ENOMEM;
}
err = iort_register_domain_token(its_entry->translation_id, res.start,
dom_handle);
if (err) {
pr_err("ITS@%pa: Unable to register GICv3 ITS domain token (ITS ID %d) to IORT\n",
&res.start, its_entry->translation_id);
goto dom_err;
}
its = its_node_init(&res, dom_handle,
acpi_get_its_numa_node(its_entry->translation_id));
if (!its) {
err = -ENOMEM;
goto node_err;
}
err = its_probe_one(its);
if (!err)
return 0;
node_err:
iort_deregister_domain_token(its_entry->translation_id);
dom_err:
irq_domain_free_fwnode(dom_handle);
return err;
}
static int __init its_acpi_reset(union acpi_subtable_headers *header,
const unsigned long end)
{
struct acpi_madt_generic_translator *its_entry;
struct resource res;
its_entry = (struct acpi_madt_generic_translator *)header;
res = (struct resource) {
.start = its_entry->base_address,
.end = its_entry->base_address + ACPI_GICV3_ITS_MEM_SIZE - 1,
.flags = IORESOURCE_MEM,
};
return its_reset_one(&res);
}
static void __init its_acpi_probe(void)
{
acpi_table_parse_srat_its();
/*
* Make sure *all* the ITS are reset before we probe any, as
* they may be sharing memory. If any of the ITS fails to
* reset, don't even try to go any further, as this could
* result in something even worse.
*/
if (acpi_table_parse_madt(ACPI_MADT_TYPE_GENERIC_TRANSLATOR,
its_acpi_reset, 0) > 0)
acpi_table_parse_madt(ACPI_MADT_TYPE_GENERIC_TRANSLATOR,
gic_acpi_parse_madt_its, 0);
acpi_its_srat_maps_free();
}
#else
static void __init its_acpi_probe(void) { }
#endif
int __init its_lpi_memreserve_init(void)
{
int state;
if (!efi_enabled(EFI_CONFIG_TABLES))
return 0;
if (list_empty(&its_nodes))
return 0;
gic_rdists->cpuhp_memreserve_state = CPUHP_INVALID;
state = cpuhp_setup_state(CPUHP_AP_ONLINE_DYN,
"irqchip/arm/gicv3/memreserve:online",
its_cpu_memreserve_lpi,
NULL);
if (state < 0)
return state;
gic_rdists->cpuhp_memreserve_state = state;
return 0;
}
int __init its_init(struct fwnode_handle *handle, struct rdists *rdists,
struct irq_domain *parent_domain)
{
struct device_node *of_node;
struct its_node *its;
bool has_v4 = false;
bool has_v4_1 = false;
int err;
gic_rdists = rdists;
its_parent = parent_domain;
of_node = to_of_node(handle);
if (of_node)
its_of_probe(of_node);
else
its_acpi_probe();
if (list_empty(&its_nodes)) {
pr_warn("ITS: No ITS available, not enabling LPIs\n");
return -ENXIO;
}
err = allocate_lpi_tables();
if (err)
return err;
list_for_each_entry(its, &its_nodes, entry) {
has_v4 |= is_v4(its);
has_v4_1 |= is_v4_1(its);
}
/* Don't bother with inconsistent systems */
if (WARN_ON(!has_v4_1 && rdists->has_rvpeid))
rdists->has_rvpeid = false;
if (has_v4 & rdists->has_vlpis) {
const struct irq_domain_ops *sgi_ops;
if (has_v4_1)
sgi_ops = &its_sgi_domain_ops;
else
sgi_ops = NULL;
if (its_init_vpe_domain() ||
its_init_v4(parent_domain, &its_vpe_domain_ops, sgi_ops)) {
rdists->has_vlpis = false;
pr_err("ITS: Disabling GICv4 support\n");
}
}
register_syscore_ops(&its_syscore_ops);
return 0;
}
|