linux_dsm_epyc7002/drivers/pci/controller/pcie-iproc-msi.c
Sandor Bodo-Merle 607caa0801 PCI: iproc: Support multi-MSI only on uniprocessor kernel
[ Upstream commit 2dc0a201d0f59e6818ef443609f0850a32910844 ]

The interrupt affinity scheme used by this driver is incompatible with
multi-MSI as it implies moving the doorbell address to that of another MSI
group.  This isn't possible for multi-MSI, as all the MSIs must have the
same doorbell address. As such it is restricted to systems with a single
CPU.

Link: https://lore.kernel.org/r/20210622152630.40842-2-sbodomerle@gmail.com
Fixes: fc54bae288 ("PCI: iproc: Allow allocation of multiple MSIs")
Reported-by: Marc Zyngier <maz@kernel.org>
Signed-off-by: Sandor Bodo-Merle <sbodomerle@gmail.com>
Signed-off-by: Lorenzo Pieralisi <lorenzo.pieralisi@arm.com>
Acked-by: Marc Zyngier <maz@kernel.org>
Acked-by: Pali Rohár <pali@kernel.org>
Acked-by: Ray Jui <ray.jui@broadcom.com>
Signed-off-by: Sasha Levin <sashal@kernel.org>
2021-07-20 16:05:52 +02:00

685 lines
17 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2015 Broadcom Corporation
*/
#include <linux/interrupt.h>
#include <linux/irqchip/chained_irq.h>
#include <linux/irqdomain.h>
#include <linux/msi.h>
#include <linux/of_irq.h>
#include <linux/of_pci.h>
#include <linux/pci.h>
#include "pcie-iproc.h"
#define IPROC_MSI_INTR_EN_SHIFT 11
#define IPROC_MSI_INTR_EN BIT(IPROC_MSI_INTR_EN_SHIFT)
#define IPROC_MSI_INT_N_EVENT_SHIFT 1
#define IPROC_MSI_INT_N_EVENT BIT(IPROC_MSI_INT_N_EVENT_SHIFT)
#define IPROC_MSI_EQ_EN_SHIFT 0
#define IPROC_MSI_EQ_EN BIT(IPROC_MSI_EQ_EN_SHIFT)
#define IPROC_MSI_EQ_MASK 0x3f
/* Max number of GIC interrupts */
#define NR_HW_IRQS 6
/* Number of entries in each event queue */
#define EQ_LEN 64
/* Size of each event queue memory region */
#define EQ_MEM_REGION_SIZE SZ_4K
/* Size of each MSI address region */
#define MSI_MEM_REGION_SIZE SZ_4K
enum iproc_msi_reg {
IPROC_MSI_EQ_PAGE = 0,
IPROC_MSI_EQ_PAGE_UPPER,
IPROC_MSI_PAGE,
IPROC_MSI_PAGE_UPPER,
IPROC_MSI_CTRL,
IPROC_MSI_EQ_HEAD,
IPROC_MSI_EQ_TAIL,
IPROC_MSI_INTS_EN,
IPROC_MSI_REG_SIZE,
};
struct iproc_msi;
/**
* iProc MSI group
*
* One MSI group is allocated per GIC interrupt, serviced by one iProc MSI
* event queue.
*
* @msi: pointer to iProc MSI data
* @gic_irq: GIC interrupt
* @eq: Event queue number
*/
struct iproc_msi_grp {
struct iproc_msi *msi;
int gic_irq;
unsigned int eq;
};
/**
* iProc event queue based MSI
*
* Only meant to be used on platforms without MSI support integrated into the
* GIC.
*
* @pcie: pointer to iProc PCIe data
* @reg_offsets: MSI register offsets
* @grps: MSI groups
* @nr_irqs: number of total interrupts connected to GIC
* @nr_cpus: number of toal CPUs
* @has_inten_reg: indicates the MSI interrupt enable register needs to be
* set explicitly (required for some legacy platforms)
* @bitmap: MSI vector bitmap
* @bitmap_lock: lock to protect access to the MSI bitmap
* @nr_msi_vecs: total number of MSI vectors
* @inner_domain: inner IRQ domain
* @msi_domain: MSI IRQ domain
* @nr_eq_region: required number of 4K aligned memory region for MSI event
* queues
* @nr_msi_region: required number of 4K aligned address region for MSI posted
* writes
* @eq_cpu: pointer to allocated memory region for MSI event queues
* @eq_dma: DMA address of MSI event queues
* @msi_addr: MSI address
*/
struct iproc_msi {
struct iproc_pcie *pcie;
const u16 (*reg_offsets)[IPROC_MSI_REG_SIZE];
struct iproc_msi_grp *grps;
int nr_irqs;
int nr_cpus;
bool has_inten_reg;
unsigned long *bitmap;
struct mutex bitmap_lock;
unsigned int nr_msi_vecs;
struct irq_domain *inner_domain;
struct irq_domain *msi_domain;
unsigned int nr_eq_region;
unsigned int nr_msi_region;
void *eq_cpu;
dma_addr_t eq_dma;
phys_addr_t msi_addr;
};
static const u16 iproc_msi_reg_paxb[NR_HW_IRQS][IPROC_MSI_REG_SIZE] = {
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x210, 0x250, 0x254, 0x208 },
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x214, 0x258, 0x25c, 0x208 },
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x218, 0x260, 0x264, 0x208 },
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x21c, 0x268, 0x26c, 0x208 },
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x220, 0x270, 0x274, 0x208 },
{ 0x200, 0x2c0, 0x204, 0x2c4, 0x224, 0x278, 0x27c, 0x208 },
};
static const u16 iproc_msi_reg_paxc[NR_HW_IRQS][IPROC_MSI_REG_SIZE] = {
{ 0xc00, 0xc04, 0xc08, 0xc0c, 0xc40, 0xc50, 0xc60 },
{ 0xc10, 0xc14, 0xc18, 0xc1c, 0xc44, 0xc54, 0xc64 },
{ 0xc20, 0xc24, 0xc28, 0xc2c, 0xc48, 0xc58, 0xc68 },
{ 0xc30, 0xc34, 0xc38, 0xc3c, 0xc4c, 0xc5c, 0xc6c },
};
static inline u32 iproc_msi_read_reg(struct iproc_msi *msi,
enum iproc_msi_reg reg,
unsigned int eq)
{
struct iproc_pcie *pcie = msi->pcie;
return readl_relaxed(pcie->base + msi->reg_offsets[eq][reg]);
}
static inline void iproc_msi_write_reg(struct iproc_msi *msi,
enum iproc_msi_reg reg,
int eq, u32 val)
{
struct iproc_pcie *pcie = msi->pcie;
writel_relaxed(val, pcie->base + msi->reg_offsets[eq][reg]);
}
static inline u32 hwirq_to_group(struct iproc_msi *msi, unsigned long hwirq)
{
return (hwirq % msi->nr_irqs);
}
static inline unsigned int iproc_msi_addr_offset(struct iproc_msi *msi,
unsigned long hwirq)
{
if (msi->nr_msi_region > 1)
return hwirq_to_group(msi, hwirq) * MSI_MEM_REGION_SIZE;
else
return hwirq_to_group(msi, hwirq) * sizeof(u32);
}
static inline unsigned int iproc_msi_eq_offset(struct iproc_msi *msi, u32 eq)
{
if (msi->nr_eq_region > 1)
return eq * EQ_MEM_REGION_SIZE;
else
return eq * EQ_LEN * sizeof(u32);
}
static struct irq_chip iproc_msi_irq_chip = {
.name = "iProc-MSI",
};
static struct msi_domain_info iproc_msi_domain_info = {
.flags = MSI_FLAG_USE_DEF_DOM_OPS | MSI_FLAG_USE_DEF_CHIP_OPS |
MSI_FLAG_PCI_MSIX,
.chip = &iproc_msi_irq_chip,
};
/*
* In iProc PCIe core, each MSI group is serviced by a GIC interrupt and a
* dedicated event queue. Each MSI group can support up to 64 MSI vectors.
*
* The number of MSI groups varies between different iProc SoCs. The total
* number of CPU cores also varies. To support MSI IRQ affinity, we
* distribute GIC interrupts across all available CPUs. MSI vector is moved
* from one GIC interrupt to another to steer to the target CPU.
*
* Assuming:
* - the number of MSI groups is M
* - the number of CPU cores is N
* - M is always a multiple of N
*
* Total number of raw MSI vectors = M * 64
* Total number of supported MSI vectors = (M * 64) / N
*/
static inline int hwirq_to_cpu(struct iproc_msi *msi, unsigned long hwirq)
{
return (hwirq % msi->nr_cpus);
}
static inline unsigned long hwirq_to_canonical_hwirq(struct iproc_msi *msi,
unsigned long hwirq)
{
return (hwirq - hwirq_to_cpu(msi, hwirq));
}
static int iproc_msi_irq_set_affinity(struct irq_data *data,
const struct cpumask *mask, bool force)
{
struct iproc_msi *msi = irq_data_get_irq_chip_data(data);
int target_cpu = cpumask_first(mask);
int curr_cpu;
int ret;
curr_cpu = hwirq_to_cpu(msi, data->hwirq);
if (curr_cpu == target_cpu)
ret = IRQ_SET_MASK_OK_DONE;
else {
/* steer MSI to the target CPU */
data->hwirq = hwirq_to_canonical_hwirq(msi, data->hwirq) + target_cpu;
ret = IRQ_SET_MASK_OK;
}
irq_data_update_effective_affinity(data, cpumask_of(target_cpu));
return ret;
}
static void iproc_msi_irq_compose_msi_msg(struct irq_data *data,
struct msi_msg *msg)
{
struct iproc_msi *msi = irq_data_get_irq_chip_data(data);
dma_addr_t addr;
addr = msi->msi_addr + iproc_msi_addr_offset(msi, data->hwirq);
msg->address_lo = lower_32_bits(addr);
msg->address_hi = upper_32_bits(addr);
msg->data = data->hwirq << 5;
}
static struct irq_chip iproc_msi_bottom_irq_chip = {
.name = "MSI",
.irq_set_affinity = iproc_msi_irq_set_affinity,
.irq_compose_msi_msg = iproc_msi_irq_compose_msi_msg,
};
static int iproc_msi_irq_domain_alloc(struct irq_domain *domain,
unsigned int virq, unsigned int nr_irqs,
void *args)
{
struct iproc_msi *msi = domain->host_data;
int hwirq, i;
if (msi->nr_cpus > 1 && nr_irqs > 1)
return -EINVAL;
mutex_lock(&msi->bitmap_lock);
/*
* Allocate 'nr_irqs' multiplied by 'nr_cpus' number of MSI vectors
* each time
*/
hwirq = bitmap_find_free_region(msi->bitmap, msi->nr_msi_vecs,
order_base_2(msi->nr_cpus * nr_irqs));
mutex_unlock(&msi->bitmap_lock);
if (hwirq < 0)
return -ENOSPC;
for (i = 0; i < nr_irqs; i++) {
irq_domain_set_info(domain, virq + i, hwirq + i,
&iproc_msi_bottom_irq_chip,
domain->host_data, handle_simple_irq,
NULL, NULL);
}
return 0;
}
static void iproc_msi_irq_domain_free(struct irq_domain *domain,
unsigned int virq, unsigned int nr_irqs)
{
struct irq_data *data = irq_domain_get_irq_data(domain, virq);
struct iproc_msi *msi = irq_data_get_irq_chip_data(data);
unsigned int hwirq;
mutex_lock(&msi->bitmap_lock);
hwirq = hwirq_to_canonical_hwirq(msi, data->hwirq);
bitmap_release_region(msi->bitmap, hwirq,
order_base_2(msi->nr_cpus * nr_irqs));
mutex_unlock(&msi->bitmap_lock);
irq_domain_free_irqs_parent(domain, virq, nr_irqs);
}
static const struct irq_domain_ops msi_domain_ops = {
.alloc = iproc_msi_irq_domain_alloc,
.free = iproc_msi_irq_domain_free,
};
static inline u32 decode_msi_hwirq(struct iproc_msi *msi, u32 eq, u32 head)
{
u32 __iomem *msg;
u32 hwirq;
unsigned int offs;
offs = iproc_msi_eq_offset(msi, eq) + head * sizeof(u32);
msg = (u32 __iomem *)(msi->eq_cpu + offs);
hwirq = readl(msg);
hwirq = (hwirq >> 5) + (hwirq & 0x1f);
/*
* Since we have multiple hwirq mapped to a single MSI vector,
* now we need to derive the hwirq at CPU0. It can then be used to
* mapped back to virq.
*/
return hwirq_to_canonical_hwirq(msi, hwirq);
}
static void iproc_msi_handler(struct irq_desc *desc)
{
struct irq_chip *chip = irq_desc_get_chip(desc);
struct iproc_msi_grp *grp;
struct iproc_msi *msi;
u32 eq, head, tail, nr_events;
unsigned long hwirq;
int virq;
chained_irq_enter(chip, desc);
grp = irq_desc_get_handler_data(desc);
msi = grp->msi;
eq = grp->eq;
/*
* iProc MSI event queue is tracked by head and tail pointers. Head
* pointer indicates the next entry (MSI data) to be consumed by SW in
* the queue and needs to be updated by SW. iProc MSI core uses the
* tail pointer as the next data insertion point.
*
* Entries between head and tail pointers contain valid MSI data. MSI
* data is guaranteed to be in the event queue memory before the tail
* pointer is updated by the iProc MSI core.
*/
head = iproc_msi_read_reg(msi, IPROC_MSI_EQ_HEAD,
eq) & IPROC_MSI_EQ_MASK;
do {
tail = iproc_msi_read_reg(msi, IPROC_MSI_EQ_TAIL,
eq) & IPROC_MSI_EQ_MASK;
/*
* Figure out total number of events (MSI data) to be
* processed.
*/
nr_events = (tail < head) ?
(EQ_LEN - (head - tail)) : (tail - head);
if (!nr_events)
break;
/* process all outstanding events */
while (nr_events--) {
hwirq = decode_msi_hwirq(msi, eq, head);
virq = irq_find_mapping(msi->inner_domain, hwirq);
generic_handle_irq(virq);
head++;
head %= EQ_LEN;
}
/*
* Now all outstanding events have been processed. Update the
* head pointer.
*/
iproc_msi_write_reg(msi, IPROC_MSI_EQ_HEAD, eq, head);
/*
* Now go read the tail pointer again to see if there are new
* outstanding events that came in during the above window.
*/
} while (true);
chained_irq_exit(chip, desc);
}
static void iproc_msi_enable(struct iproc_msi *msi)
{
int i, eq;
u32 val;
/* Program memory region for each event queue */
for (i = 0; i < msi->nr_eq_region; i++) {
dma_addr_t addr = msi->eq_dma + (i * EQ_MEM_REGION_SIZE);
iproc_msi_write_reg(msi, IPROC_MSI_EQ_PAGE, i,
lower_32_bits(addr));
iproc_msi_write_reg(msi, IPROC_MSI_EQ_PAGE_UPPER, i,
upper_32_bits(addr));
}
/* Program address region for MSI posted writes */
for (i = 0; i < msi->nr_msi_region; i++) {
phys_addr_t addr = msi->msi_addr + (i * MSI_MEM_REGION_SIZE);
iproc_msi_write_reg(msi, IPROC_MSI_PAGE, i,
lower_32_bits(addr));
iproc_msi_write_reg(msi, IPROC_MSI_PAGE_UPPER, i,
upper_32_bits(addr));
}
for (eq = 0; eq < msi->nr_irqs; eq++) {
/* Enable MSI event queue */
val = IPROC_MSI_INTR_EN | IPROC_MSI_INT_N_EVENT |
IPROC_MSI_EQ_EN;
iproc_msi_write_reg(msi, IPROC_MSI_CTRL, eq, val);
/*
* Some legacy platforms require the MSI interrupt enable
* register to be set explicitly.
*/
if (msi->has_inten_reg) {
val = iproc_msi_read_reg(msi, IPROC_MSI_INTS_EN, eq);
val |= BIT(eq);
iproc_msi_write_reg(msi, IPROC_MSI_INTS_EN, eq, val);
}
}
}
static void iproc_msi_disable(struct iproc_msi *msi)
{
u32 eq, val;
for (eq = 0; eq < msi->nr_irqs; eq++) {
if (msi->has_inten_reg) {
val = iproc_msi_read_reg(msi, IPROC_MSI_INTS_EN, eq);
val &= ~BIT(eq);
iproc_msi_write_reg(msi, IPROC_MSI_INTS_EN, eq, val);
}
val = iproc_msi_read_reg(msi, IPROC_MSI_CTRL, eq);
val &= ~(IPROC_MSI_INTR_EN | IPROC_MSI_INT_N_EVENT |
IPROC_MSI_EQ_EN);
iproc_msi_write_reg(msi, IPROC_MSI_CTRL, eq, val);
}
}
static int iproc_msi_alloc_domains(struct device_node *node,
struct iproc_msi *msi)
{
msi->inner_domain = irq_domain_add_linear(NULL, msi->nr_msi_vecs,
&msi_domain_ops, msi);
if (!msi->inner_domain)
return -ENOMEM;
msi->msi_domain = pci_msi_create_irq_domain(of_node_to_fwnode(node),
&iproc_msi_domain_info,
msi->inner_domain);
if (!msi->msi_domain) {
irq_domain_remove(msi->inner_domain);
return -ENOMEM;
}
return 0;
}
static void iproc_msi_free_domains(struct iproc_msi *msi)
{
if (msi->msi_domain)
irq_domain_remove(msi->msi_domain);
if (msi->inner_domain)
irq_domain_remove(msi->inner_domain);
}
static void iproc_msi_irq_free(struct iproc_msi *msi, unsigned int cpu)
{
int i;
for (i = cpu; i < msi->nr_irqs; i += msi->nr_cpus) {
irq_set_chained_handler_and_data(msi->grps[i].gic_irq,
NULL, NULL);
}
}
static int iproc_msi_irq_setup(struct iproc_msi *msi, unsigned int cpu)
{
int i, ret;
cpumask_var_t mask;
struct iproc_pcie *pcie = msi->pcie;
for (i = cpu; i < msi->nr_irqs; i += msi->nr_cpus) {
irq_set_chained_handler_and_data(msi->grps[i].gic_irq,
iproc_msi_handler,
&msi->grps[i]);
/* Dedicate GIC interrupt to each CPU core */
if (alloc_cpumask_var(&mask, GFP_KERNEL)) {
cpumask_clear(mask);
cpumask_set_cpu(cpu, mask);
ret = irq_set_affinity(msi->grps[i].gic_irq, mask);
if (ret)
dev_err(pcie->dev,
"failed to set affinity for IRQ%d\n",
msi->grps[i].gic_irq);
free_cpumask_var(mask);
} else {
dev_err(pcie->dev, "failed to alloc CPU mask\n");
ret = -EINVAL;
}
if (ret) {
/* Free all configured/unconfigured IRQs */
iproc_msi_irq_free(msi, cpu);
return ret;
}
}
return 0;
}
int iproc_msi_init(struct iproc_pcie *pcie, struct device_node *node)
{
struct iproc_msi *msi;
int i, ret;
unsigned int cpu;
if (!of_device_is_compatible(node, "brcm,iproc-msi"))
return -ENODEV;
if (!of_find_property(node, "msi-controller", NULL))
return -ENODEV;
if (pcie->msi)
return -EBUSY;
msi = devm_kzalloc(pcie->dev, sizeof(*msi), GFP_KERNEL);
if (!msi)
return -ENOMEM;
msi->pcie = pcie;
pcie->msi = msi;
msi->msi_addr = pcie->base_addr;
mutex_init(&msi->bitmap_lock);
msi->nr_cpus = num_possible_cpus();
if (msi->nr_cpus == 1)
iproc_msi_domain_info.flags |= MSI_FLAG_MULTI_PCI_MSI;
msi->nr_irqs = of_irq_count(node);
if (!msi->nr_irqs) {
dev_err(pcie->dev, "found no MSI GIC interrupt\n");
return -ENODEV;
}
if (msi->nr_irqs > NR_HW_IRQS) {
dev_warn(pcie->dev, "too many MSI GIC interrupts defined %d\n",
msi->nr_irqs);
msi->nr_irqs = NR_HW_IRQS;
}
if (msi->nr_irqs < msi->nr_cpus) {
dev_err(pcie->dev,
"not enough GIC interrupts for MSI affinity\n");
return -EINVAL;
}
if (msi->nr_irqs % msi->nr_cpus != 0) {
msi->nr_irqs -= msi->nr_irqs % msi->nr_cpus;
dev_warn(pcie->dev, "Reducing number of interrupts to %d\n",
msi->nr_irqs);
}
switch (pcie->type) {
case IPROC_PCIE_PAXB_BCMA:
case IPROC_PCIE_PAXB:
msi->reg_offsets = iproc_msi_reg_paxb;
msi->nr_eq_region = 1;
msi->nr_msi_region = 1;
break;
case IPROC_PCIE_PAXC:
msi->reg_offsets = iproc_msi_reg_paxc;
msi->nr_eq_region = msi->nr_irqs;
msi->nr_msi_region = msi->nr_irqs;
break;
default:
dev_err(pcie->dev, "incompatible iProc PCIe interface\n");
return -EINVAL;
}
if (of_find_property(node, "brcm,pcie-msi-inten", NULL))
msi->has_inten_reg = true;
msi->nr_msi_vecs = msi->nr_irqs * EQ_LEN;
msi->bitmap = devm_kcalloc(pcie->dev, BITS_TO_LONGS(msi->nr_msi_vecs),
sizeof(*msi->bitmap), GFP_KERNEL);
if (!msi->bitmap)
return -ENOMEM;
msi->grps = devm_kcalloc(pcie->dev, msi->nr_irqs, sizeof(*msi->grps),
GFP_KERNEL);
if (!msi->grps)
return -ENOMEM;
for (i = 0; i < msi->nr_irqs; i++) {
unsigned int irq = irq_of_parse_and_map(node, i);
if (!irq) {
dev_err(pcie->dev, "unable to parse/map interrupt\n");
ret = -ENODEV;
goto free_irqs;
}
msi->grps[i].gic_irq = irq;
msi->grps[i].msi = msi;
msi->grps[i].eq = i;
}
/* Reserve memory for event queue and make sure memories are zeroed */
msi->eq_cpu = dma_alloc_coherent(pcie->dev,
msi->nr_eq_region * EQ_MEM_REGION_SIZE,
&msi->eq_dma, GFP_KERNEL);
if (!msi->eq_cpu) {
ret = -ENOMEM;
goto free_irqs;
}
ret = iproc_msi_alloc_domains(node, msi);
if (ret) {
dev_err(pcie->dev, "failed to create MSI domains\n");
goto free_eq_dma;
}
for_each_online_cpu(cpu) {
ret = iproc_msi_irq_setup(msi, cpu);
if (ret)
goto free_msi_irq;
}
iproc_msi_enable(msi);
return 0;
free_msi_irq:
for_each_online_cpu(cpu)
iproc_msi_irq_free(msi, cpu);
iproc_msi_free_domains(msi);
free_eq_dma:
dma_free_coherent(pcie->dev, msi->nr_eq_region * EQ_MEM_REGION_SIZE,
msi->eq_cpu, msi->eq_dma);
free_irqs:
for (i = 0; i < msi->nr_irqs; i++) {
if (msi->grps[i].gic_irq)
irq_dispose_mapping(msi->grps[i].gic_irq);
}
pcie->msi = NULL;
return ret;
}
EXPORT_SYMBOL(iproc_msi_init);
void iproc_msi_exit(struct iproc_pcie *pcie)
{
struct iproc_msi *msi = pcie->msi;
unsigned int i, cpu;
if (!msi)
return;
iproc_msi_disable(msi);
for_each_online_cpu(cpu)
iproc_msi_irq_free(msi, cpu);
iproc_msi_free_domains(msi);
dma_free_coherent(pcie->dev, msi->nr_eq_region * EQ_MEM_REGION_SIZE,
msi->eq_cpu, msi->eq_dma);
for (i = 0; i < msi->nr_irqs; i++) {
if (msi->grps[i].gic_irq)
irq_dispose_mapping(msi->grps[i].gic_irq);
}
}
EXPORT_SYMBOL(iproc_msi_exit);