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zircon-guest/third_party/linux/refs/heads/master/./drivers/pci/endpoint/functions/pci-epf-test.c
blob: 591d301fa89d89addf5df16e775e80460b689589 [file] [edit]
// SPDX-License-Identifier: GPL-2.0
/*
* Test driver to test endpoint functionality
*
* Copyright (C) 2017 Texas Instruments
* Author: Kishon Vijay Abraham I <kishon@ti.com>
*/
#include <linux/crc32.h>
#include <linux/delay.h>
#include <linux/dmaengine.h>
#include <linux/io.h>
#include <linux/module.h>
#include <linux/msi.h>
#include <linux/slab.h>
#include <linux/pci_ids.h>
#include <linux/random.h>
#include <linux/pci-epc.h>
#include <linux/pci-epf.h>
#include <linux/pci-ep-msi.h>
#include <linux/pci_regs.h>
#define IRQ_TYPE_INTX 0
#define IRQ_TYPE_MSI 1
#define IRQ_TYPE_MSIX 2
#define COMMAND_RAISE_INTX_IRQ BIT(0)
#define COMMAND_RAISE_MSI_IRQ BIT(1)
#define COMMAND_RAISE_MSIX_IRQ BIT(2)
#define COMMAND_READ BIT(3)
#define COMMAND_WRITE BIT(4)
#define COMMAND_COPY BIT(5)
#define COMMAND_ENABLE_DOORBELL BIT(6)
#define COMMAND_DISABLE_DOORBELL BIT(7)
#define COMMAND_BAR_SUBRANGE_SETUP BIT(8)
#define COMMAND_BAR_SUBRANGE_CLEAR BIT(9)
#define STATUS_READ_SUCCESS BIT(0)
#define STATUS_READ_FAIL BIT(1)
#define STATUS_WRITE_SUCCESS BIT(2)
#define STATUS_WRITE_FAIL BIT(3)
#define STATUS_COPY_SUCCESS BIT(4)
#define STATUS_COPY_FAIL BIT(5)
#define STATUS_IRQ_RAISED BIT(6)
#define STATUS_SRC_ADDR_INVALID BIT(7)
#define STATUS_DST_ADDR_INVALID BIT(8)
#define STATUS_DOORBELL_SUCCESS BIT(9)
#define STATUS_DOORBELL_ENABLE_SUCCESS BIT(10)
#define STATUS_DOORBELL_ENABLE_FAIL BIT(11)
#define STATUS_DOORBELL_DISABLE_SUCCESS BIT(12)
#define STATUS_DOORBELL_DISABLE_FAIL BIT(13)
#define STATUS_BAR_SUBRANGE_SETUP_SUCCESS BIT(14)
#define STATUS_BAR_SUBRANGE_SETUP_FAIL BIT(15)
#define STATUS_BAR_SUBRANGE_CLEAR_SUCCESS BIT(16)
#define STATUS_BAR_SUBRANGE_CLEAR_FAIL BIT(17)
#define STATUS_NO_RESOURCE BIT(18)
#define FLAG_USE_DMA BIT(0)
#define TIMER_RESOLUTION 1
#define CAP_UNALIGNED_ACCESS BIT(0)
#define CAP_MSI BIT(1)
#define CAP_MSIX BIT(2)
#define CAP_INTX BIT(3)
#define CAP_SUBRANGE_MAPPING BIT(4)
#define CAP_DYNAMIC_INBOUND_MAPPING BIT(5)
#define CAP_BAR0_RESERVED BIT(6)
#define CAP_BAR1_RESERVED BIT(7)
#define CAP_BAR2_RESERVED BIT(8)
#define CAP_BAR3_RESERVED BIT(9)
#define CAP_BAR4_RESERVED BIT(10)
#define CAP_BAR5_RESERVED BIT(11)
#define PCI_EPF_TEST_BAR_SUBRANGE_NSUB 2
static struct workqueue_struct *kpcitest_workqueue;
struct pci_epf_test {
void *reg[PCI_STD_NUM_BARS];
struct pci_epf *epf;
struct config_group group;
enum pci_barno test_reg_bar;
size_t msix_table_offset;
struct delayed_work cmd_handler;
struct dma_chan *dma_chan_tx;
struct dma_chan *dma_chan_rx;
struct dma_chan *transfer_chan;
dma_cookie_t transfer_cookie;
enum dma_status transfer_status;
struct completion transfer_complete;
bool dma_supported;
bool dma_private;
const struct pci_epc_features *epc_features;
struct pci_epf_bar db_bar;
size_t bar_size[PCI_STD_NUM_BARS];
};
struct pci_epf_test_reg {
__le32 magic;
__le32 command;
__le32 status;
__le64 src_addr;
__le64 dst_addr;
__le32 size;
__le32 checksum;
__le32 irq_type;
__le32 irq_number;
__le32 flags;
__le32 caps;
__le32 doorbell_bar;
__le32 doorbell_offset;
__le32 doorbell_data;
} __packed;
static struct pci_epf_header test_header = {
.vendorid = PCI_ANY_ID,
.deviceid = PCI_ANY_ID,
.baseclass_code = PCI_CLASS_OTHERS,
.interrupt_pin = PCI_INTERRUPT_INTA,
};
/* default BAR sizes, can be overridden by the user using configfs */
static size_t default_bar_size[] = { 131072, 131072, 131072, 131072, 131072, 1048576 };
static void pci_epf_test_dma_callback(void *param)
{
struct pci_epf_test *epf_test = param;
struct dma_tx_state state;
epf_test->transfer_status =
dmaengine_tx_status(epf_test->transfer_chan,
epf_test->transfer_cookie, &state);
if (epf_test->transfer_status == DMA_COMPLETE ||
epf_test->transfer_status == DMA_ERROR)
complete(&epf_test->transfer_complete);
}
/**
* pci_epf_test_data_transfer() - Function that uses dmaengine API to transfer
* data between PCIe EP and remote PCIe RC
* @epf_test: the EPF test device that performs the data transfer operation
* @dma_dst: The destination address of the data transfer. It can be a physical
* address given by pci_epc_mem_alloc_addr or DMA mapping APIs.
* @dma_src: The source address of the data transfer. It can be a physical
* address given by pci_epc_mem_alloc_addr or DMA mapping APIs.
* @len: The size of the data transfer
* @dma_remote: remote RC physical address
* @dir: DMA transfer direction
*
* Function that uses dmaengine API to transfer data between PCIe EP and remote
* PCIe RC. The source and destination address can be a physical address given
* by pci_epc_mem_alloc_addr or the one obtained using DMA mapping APIs.
*
* The function returns '0' on success and negative value on failure.
*/
static int pci_epf_test_data_transfer(struct pci_epf_test *epf_test,
dma_addr_t dma_dst, dma_addr_t dma_src,
size_t len, dma_addr_t dma_remote,
enum dma_transfer_direction dir)
{
struct dma_chan *chan = (dir == DMA_MEM_TO_DEV) ?
epf_test->dma_chan_tx : epf_test->dma_chan_rx;
dma_addr_t dma_local = (dir == DMA_MEM_TO_DEV) ? dma_src : dma_dst;
enum dma_ctrl_flags flags = DMA_CTRL_ACK | DMA_PREP_INTERRUPT;
struct pci_epf *epf = epf_test->epf;
struct dma_async_tx_descriptor *tx;
struct dma_slave_config sconf = {};
struct device *dev = &epf->dev;
int ret;
if (IS_ERR_OR_NULL(chan)) {
dev_err(dev, "Invalid DMA memcpy channel\n");
return -EINVAL;
}
if (epf_test->dma_private) {
sconf.direction = dir;
if (dir == DMA_MEM_TO_DEV)
sconf.dst_addr = dma_remote;
else
sconf.src_addr = dma_remote;
if (dmaengine_slave_config(chan, &sconf)) {
dev_err(dev, "DMA slave config fail\n");
return -EIO;
}
tx = dmaengine_prep_slave_single(chan, dma_local, len, dir,
flags);
} else {
tx = dmaengine_prep_dma_memcpy(chan, dma_dst, dma_src, len,
flags);
}
if (!tx) {
dev_err(dev, "Failed to prepare DMA memcpy\n");
return -EIO;
}
reinit_completion(&epf_test->transfer_complete);
epf_test->transfer_chan = chan;
tx->callback = pci_epf_test_dma_callback;
tx->callback_param = epf_test;
epf_test->transfer_cookie = dmaengine_submit(tx);
ret = dma_submit_error(epf_test->transfer_cookie);
if (ret) {
dev_err(dev, "Failed to do DMA tx_submit %d\n", ret);
goto terminate;
}
dma_async_issue_pending(chan);
ret = wait_for_completion_interruptible(&epf_test->transfer_complete);
if (ret < 0) {
dev_err(dev, "DMA wait_for_completion interrupted\n");
goto terminate;
}
if (epf_test->transfer_status == DMA_ERROR) {
dev_err(dev, "DMA transfer failed\n");
ret = -EIO;
}
terminate:
dmaengine_terminate_sync(chan);
return ret;
}
struct epf_dma_filter {
struct device *dev;
u32 dma_mask;
};
static bool epf_dma_filter_fn(struct dma_chan *chan, void *node)
{
struct epf_dma_filter *filter = node;
struct dma_slave_caps caps;
memset(&caps, 0, sizeof(caps));
dma_get_slave_caps(chan, &caps);
return chan->device->dev == filter->dev
&& (filter->dma_mask & caps.directions);
}
/**
* pci_epf_test_init_dma_chan() - Function to initialize EPF test DMA channel
* @epf_test: the EPF test device that performs data transfer operation
*
* Function to initialize EPF test DMA channel.
*/
static int pci_epf_test_init_dma_chan(struct pci_epf_test *epf_test)
{
struct pci_epf *epf = epf_test->epf;
struct device *dev = &epf->dev;
struct epf_dma_filter filter;
struct dma_chan *dma_chan;
dma_cap_mask_t mask;
int ret;
filter.dev = epf->epc->dev.parent;
filter.dma_mask = BIT(DMA_DEV_TO_MEM);
dma_cap_zero(mask);
dma_cap_set(DMA_SLAVE, mask);
dma_chan = dma_request_channel(mask, epf_dma_filter_fn, &filter);
if (!dma_chan) {
dev_info(dev, "Failed to get private DMA rx channel. Falling back to generic one\n");
goto fail_back_tx;
}
epf_test->dma_chan_rx = dma_chan;
filter.dma_mask = BIT(DMA_MEM_TO_DEV);
dma_chan = dma_request_channel(mask, epf_dma_filter_fn, &filter);
if (!dma_chan) {
dev_info(dev, "Failed to get private DMA tx channel. Falling back to generic one\n");
goto fail_back_rx;
}
epf_test->dma_chan_tx = dma_chan;
epf_test->dma_private = true;
init_completion(&epf_test->transfer_complete);
return 0;
fail_back_rx:
dma_release_channel(epf_test->dma_chan_rx);
epf_test->dma_chan_rx = NULL;
fail_back_tx:
dma_cap_zero(mask);
dma_cap_set(DMA_MEMCPY, mask);
dma_chan = dma_request_chan_by_mask(&mask);
if (IS_ERR(dma_chan)) {
ret = PTR_ERR(dma_chan);
if (ret != -EPROBE_DEFER)
dev_err(dev, "Failed to get DMA channel\n");
return ret;
}
init_completion(&epf_test->transfer_complete);
epf_test->dma_chan_tx = epf_test->dma_chan_rx = dma_chan;
return 0;
}
/**
* pci_epf_test_clean_dma_chan() - Function to cleanup EPF test DMA channel
* @epf_test: the EPF test device that performs data transfer operation
*
* Helper to cleanup EPF test DMA channel.
*/
static void pci_epf_test_clean_dma_chan(struct pci_epf_test *epf_test)
{
if (!epf_test->dma_supported)
return;
if (epf_test->dma_chan_tx) {
dma_release_channel(epf_test->dma_chan_tx);
if (epf_test->dma_chan_tx == epf_test->dma_chan_rx) {
epf_test->dma_chan_tx = NULL;
epf_test->dma_chan_rx = NULL;
return;
}
epf_test->dma_chan_tx = NULL;
}
if (epf_test->dma_chan_rx) {
dma_release_channel(epf_test->dma_chan_rx);
epf_test->dma_chan_rx = NULL;
}
}
static void pci_epf_test_print_rate(struct pci_epf_test *epf_test,
const char *op, u64 size,
struct timespec64 *start,
struct timespec64 *end, bool dma)
{
struct timespec64 ts = timespec64_sub(*end, *start);
u64 rate = 0, ns;
/* calculate the rate */
ns = timespec64_to_ns(&ts);
if (ns)
rate = div64_u64(size * NSEC_PER_SEC, ns * 1000);
dev_info(&epf_test->epf->dev,
"%s => Size: %llu B, DMA: %s, Time: %ptSp s, Rate: %llu KB/s\n",
op, size, dma ? "YES" : "NO", &ts, rate);
}
static void pci_epf_test_copy(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
int ret = 0;
struct timespec64 start, end;
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
struct device *dev = &epf->dev;
struct pci_epc_map src_map, dst_map;
u64 src_addr = le64_to_cpu(reg->src_addr);
u64 dst_addr = le64_to_cpu(reg->dst_addr);
size_t orig_size, copy_size;
ssize_t map_size = 0;
u32 flags = le32_to_cpu(reg->flags);
u32 status = 0;
void *copy_buf = NULL, *buf;
orig_size = copy_size = le32_to_cpu(reg->size);
if (flags & FLAG_USE_DMA) {
if (!dma_has_cap(DMA_MEMCPY, epf_test->dma_chan_tx->device->cap_mask)) {
dev_err(dev, "DMA controller doesn't support MEMCPY\n");
ret = -EINVAL;
goto set_status;
}
} else {
copy_buf = kzalloc(copy_size, GFP_KERNEL);
if (!copy_buf) {
ret = -ENOMEM;
goto set_status;
}
buf = copy_buf;
}
while (copy_size) {
ret = pci_epc_mem_map(epc, epf->func_no, epf->vfunc_no,
src_addr, copy_size, &src_map);
if (ret) {
dev_err(dev, "Failed to map source address\n");
status = STATUS_SRC_ADDR_INVALID;
goto free_buf;
}
ret = pci_epc_mem_map(epf->epc, epf->func_no, epf->vfunc_no,
dst_addr, copy_size, &dst_map);
if (ret) {
dev_err(dev, "Failed to map destination address\n");
status = STATUS_DST_ADDR_INVALID;
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no,
&src_map);
goto free_buf;
}
map_size = min_t(size_t, dst_map.pci_size, src_map.pci_size);
ktime_get_ts64(&start);
if (flags & FLAG_USE_DMA) {
ret = pci_epf_test_data_transfer(epf_test,
dst_map.phys_addr, src_map.phys_addr,
map_size, 0, DMA_MEM_TO_MEM);
if (ret) {
dev_err(dev, "Data transfer failed\n");
goto unmap;
}
} else {
memcpy_fromio(buf, src_map.virt_addr, map_size);
memcpy_toio(dst_map.virt_addr, buf, map_size);
buf += map_size;
}
ktime_get_ts64(&end);
copy_size -= map_size;
src_addr += map_size;
dst_addr += map_size;
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &dst_map);
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &src_map);
map_size = 0;
}
pci_epf_test_print_rate(epf_test, "COPY", orig_size, &start, &end,
flags & FLAG_USE_DMA);
unmap:
if (map_size) {
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &dst_map);
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &src_map);
}
free_buf:
kfree(copy_buf);
set_status:
if (!ret)
status |= STATUS_COPY_SUCCESS;
else
status |= STATUS_COPY_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_read(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
int ret = 0;
void *src_buf, *buf;
u32 crc32;
struct pci_epc_map map;
phys_addr_t dst_phys_addr;
struct timespec64 start, end;
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
struct device *dev = &epf->dev;
struct device *dma_dev = epf->epc->dev.parent;
u64 src_addr = le64_to_cpu(reg->src_addr);
size_t orig_size, src_size;
ssize_t map_size = 0;
u32 flags = le32_to_cpu(reg->flags);
u32 checksum = le32_to_cpu(reg->checksum);
u32 status = 0;
orig_size = src_size = le32_to_cpu(reg->size);
src_buf = kzalloc(src_size, GFP_KERNEL);
if (!src_buf) {
ret = -ENOMEM;
goto set_status;
}
buf = src_buf;
while (src_size) {
ret = pci_epc_mem_map(epc, epf->func_no, epf->vfunc_no,
src_addr, src_size, &map);
if (ret) {
dev_err(dev, "Failed to map address\n");
status = STATUS_SRC_ADDR_INVALID;
goto free_buf;
}
map_size = map.pci_size;
if (flags & FLAG_USE_DMA) {
dst_phys_addr = dma_map_single(dma_dev, buf, map_size,
DMA_FROM_DEVICE);
if (dma_mapping_error(dma_dev, dst_phys_addr)) {
dev_err(dev,
"Failed to map destination buffer addr\n");
ret = -ENOMEM;
goto unmap;
}
ktime_get_ts64(&start);
ret = pci_epf_test_data_transfer(epf_test,
dst_phys_addr, map.phys_addr,
map_size, src_addr, DMA_DEV_TO_MEM);
if (ret)
dev_err(dev, "Data transfer failed\n");
ktime_get_ts64(&end);
dma_unmap_single(dma_dev, dst_phys_addr, map_size,
DMA_FROM_DEVICE);
if (ret)
goto unmap;
} else {
ktime_get_ts64(&start);
memcpy_fromio(buf, map.virt_addr, map_size);
ktime_get_ts64(&end);
}
src_size -= map_size;
src_addr += map_size;
buf += map_size;
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &map);
map_size = 0;
}
pci_epf_test_print_rate(epf_test, "READ", orig_size, &start, &end,
flags & FLAG_USE_DMA);
crc32 = crc32_le(~0, src_buf, orig_size);
if (crc32 != checksum)
ret = -EIO;
unmap:
if (map_size)
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &map);
free_buf:
kfree(src_buf);
set_status:
if (!ret)
status |= STATUS_READ_SUCCESS;
else
status |= STATUS_READ_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_write(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
int ret = 0;
void *dst_buf, *buf;
struct pci_epc_map map;
phys_addr_t src_phys_addr;
struct timespec64 start, end;
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
struct device *dev = &epf->dev;
struct device *dma_dev = epf->epc->dev.parent;
u64 dst_addr = le64_to_cpu(reg->dst_addr);
size_t orig_size, dst_size;
ssize_t map_size = 0;
u32 flags = le32_to_cpu(reg->flags);
u32 status = 0;
orig_size = dst_size = le32_to_cpu(reg->size);
dst_buf = kzalloc(dst_size, GFP_KERNEL);
if (!dst_buf) {
ret = -ENOMEM;
goto set_status;
}
get_random_bytes(dst_buf, dst_size);
reg->checksum = cpu_to_le32(crc32_le(~0, dst_buf, dst_size));
buf = dst_buf;
while (dst_size) {
ret = pci_epc_mem_map(epc, epf->func_no, epf->vfunc_no,
dst_addr, dst_size, &map);
if (ret) {
dev_err(dev, "Failed to map address\n");
status = STATUS_DST_ADDR_INVALID;
goto free_buf;
}
map_size = map.pci_size;
if (flags & FLAG_USE_DMA) {
src_phys_addr = dma_map_single(dma_dev, buf, map_size,
DMA_TO_DEVICE);
if (dma_mapping_error(dma_dev, src_phys_addr)) {
dev_err(dev,
"Failed to map source buffer addr\n");
ret = -ENOMEM;
goto unmap;
}
ktime_get_ts64(&start);
ret = pci_epf_test_data_transfer(epf_test,
map.phys_addr, src_phys_addr,
map_size, dst_addr,
DMA_MEM_TO_DEV);
if (ret)
dev_err(dev, "Data transfer failed\n");
ktime_get_ts64(&end);
dma_unmap_single(dma_dev, src_phys_addr, map_size,
DMA_TO_DEVICE);
if (ret)
goto unmap;
} else {
ktime_get_ts64(&start);
memcpy_toio(map.virt_addr, buf, map_size);
ktime_get_ts64(&end);
}
dst_size -= map_size;
dst_addr += map_size;
buf += map_size;
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &map);
map_size = 0;
}
pci_epf_test_print_rate(epf_test, "WRITE", orig_size, &start, &end,
flags & FLAG_USE_DMA);
/*
* wait 1ms inorder for the write to complete. Without this delay L3
* error in observed in the host system.
*/
usleep_range(1000, 2000);
unmap:
if (map_size)
pci_epc_mem_unmap(epc, epf->func_no, epf->vfunc_no, &map);
free_buf:
kfree(dst_buf);
set_status:
if (!ret)
status |= STATUS_WRITE_SUCCESS;
else
status |= STATUS_WRITE_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_raise_irq(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
struct pci_epf *epf = epf_test->epf;
struct device *dev = &epf->dev;
struct pci_epc *epc = epf->epc;
u32 status = le32_to_cpu(reg->status);
u32 irq_number = le32_to_cpu(reg->irq_number);
u32 irq_type = le32_to_cpu(reg->irq_type);
int count;
/*
* Set the status before raising the IRQ to ensure that the host sees
* the updated value when it gets the IRQ.
*/
status |= STATUS_IRQ_RAISED;
WRITE_ONCE(reg->status, cpu_to_le32(status));
switch (irq_type) {
case IRQ_TYPE_INTX:
pci_epc_raise_irq(epc, epf->func_no, epf->vfunc_no,
PCI_IRQ_INTX, 0);
break;
case IRQ_TYPE_MSI:
count = pci_epc_get_msi(epc, epf->func_no, epf->vfunc_no);
if (irq_number > count || count <= 0) {
dev_err(dev, "Invalid MSI IRQ number %d / %d\n",
irq_number, count);
return;
}
pci_epc_raise_irq(epc, epf->func_no, epf->vfunc_no,
PCI_IRQ_MSI, irq_number);
break;
case IRQ_TYPE_MSIX:
count = pci_epc_get_msix(epc, epf->func_no, epf->vfunc_no);
if (irq_number > count || count <= 0) {
dev_err(dev, "Invalid MSI-X IRQ number %d / %d\n",
irq_number, count);
return;
}
pci_epc_raise_irq(epc, epf->func_no, epf->vfunc_no,
PCI_IRQ_MSIX, irq_number);
break;
default:
dev_err(dev, "Failed to raise IRQ, unknown type\n");
break;
}
}
static irqreturn_t pci_epf_test_doorbell_handler(int irq, void *data)
{
struct pci_epf_test *epf_test = data;
enum pci_barno test_reg_bar = epf_test->test_reg_bar;
struct pci_epf_test_reg *reg = epf_test->reg[test_reg_bar];
u32 status = le32_to_cpu(reg->status);
status |= STATUS_DOORBELL_SUCCESS;
reg->status = cpu_to_le32(status);
pci_epf_test_raise_irq(epf_test, reg);
return IRQ_HANDLED;
}
static void pci_epf_test_doorbell_cleanup(struct pci_epf_test *epf_test)
{
struct pci_epf_test_reg *reg = epf_test->reg[epf_test->test_reg_bar];
struct pci_epf *epf = epf_test->epf;
reg->doorbell_bar = cpu_to_le32(NO_BAR);
pci_epf_free_doorbell(epf);
}
static void pci_epf_test_enable_doorbell(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
u32 status = le32_to_cpu(reg->status);
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
struct msi_msg *msg;
enum pci_barno bar;
size_t offset;
int ret;
ret = pci_epf_alloc_doorbell(epf, 1);
if (ret)
goto set_status_err;
msg = &epf->db_msg[0].msg;
bar = pci_epc_get_next_free_bar(epf_test->epc_features, epf_test->test_reg_bar + 1);
if (bar < BAR_0)
goto err_doorbell_cleanup;
ret = request_threaded_irq(epf->db_msg[0].virq, NULL,
pci_epf_test_doorbell_handler, IRQF_ONESHOT,
"pci-ep-test-doorbell", epf_test);
if (ret) {
dev_err(&epf->dev,
"Failed to request doorbell IRQ: %d\n",
epf->db_msg[0].virq);
goto err_doorbell_cleanup;
}
reg->doorbell_data = cpu_to_le32(msg->data);
reg->doorbell_bar = cpu_to_le32(bar);
msg = &epf->db_msg[0].msg;
ret = pci_epf_align_inbound_addr(epf, bar, ((u64)msg->address_hi << 32) | msg->address_lo,
&epf_test->db_bar.phys_addr, &offset);
if (ret)
goto err_free_irq;
reg->doorbell_offset = cpu_to_le32(offset);
epf_test->db_bar.barno = bar;
epf_test->db_bar.size = epf->bar[bar].size;
epf_test->db_bar.flags = epf->bar[bar].flags;
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no, &epf_test->db_bar);
if (ret)
goto err_free_irq;
status |= STATUS_DOORBELL_ENABLE_SUCCESS;
reg->status = cpu_to_le32(status);
return;
err_free_irq:
free_irq(epf->db_msg[0].virq, epf_test);
err_doorbell_cleanup:
pci_epf_test_doorbell_cleanup(epf_test);
set_status_err:
status |= STATUS_DOORBELL_ENABLE_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_disable_doorbell(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
enum pci_barno bar = le32_to_cpu(reg->doorbell_bar);
u32 status = le32_to_cpu(reg->status);
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
int ret;
if (bar < BAR_0)
goto set_status_err;
free_irq(epf->db_msg[0].virq, epf_test);
pci_epf_test_doorbell_cleanup(epf_test);
/*
* The doorbell feature temporarily overrides the inbound translation
* to point to the address stored in epf_test->db_bar.phys_addr, i.e.,
* it calls set_bar() twice without ever calling clear_bar(), as
* calling clear_bar() would clear the BAR's PCI address assigned by
* the host. Thus, when disabling the doorbell, restore the inbound
* translation to point to the memory allocated for the BAR.
*/
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no, &epf->bar[bar]);
if (ret)
goto set_status_err;
status |= STATUS_DOORBELL_DISABLE_SUCCESS;
reg->status = cpu_to_le32(status);
return;
set_status_err:
status |= STATUS_DOORBELL_DISABLE_FAIL;
reg->status = cpu_to_le32(status);
}
static u8 pci_epf_test_subrange_sig_byte(enum pci_barno barno,
unsigned int subno)
{
return 0x50 + (barno * 8) + subno;
}
static void pci_epf_test_bar_subrange_setup(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
struct pci_epf_bar_submap *submap, *old_submap;
struct pci_epf *epf = epf_test->epf;
struct pci_epc *epc = epf->epc;
struct pci_epf_bar *bar;
unsigned int nsub = PCI_EPF_TEST_BAR_SUBRANGE_NSUB, old_nsub;
/* reg->size carries BAR number for BAR_SUBRANGE_* commands. */
enum pci_barno barno = le32_to_cpu(reg->size);
u32 status = le32_to_cpu(reg->status);
unsigned int i, phys_idx;
size_t sub_size;
u8 *addr;
int ret;
if (barno >= PCI_STD_NUM_BARS) {
dev_err(&epf->dev, "Invalid barno: %d\n", barno);
goto err;
}
/* Host side should've avoided test_reg_bar, this is a safeguard. */
if (barno == epf_test->test_reg_bar) {
dev_err(&epf->dev, "test_reg_bar cannot be used for subrange test\n");
goto err;
}
if (!epf_test->epc_features->dynamic_inbound_mapping ||
!epf_test->epc_features->subrange_mapping) {
dev_err(&epf->dev, "epc driver does not support subrange mapping\n");
goto err;
}
bar = &epf->bar[barno];
if (!bar->size || !bar->addr) {
dev_err(&epf->dev, "bar size/addr (%zu/%p) is invalid\n",
bar->size, bar->addr);
goto err;
}
if (bar->size % nsub) {
dev_err(&epf->dev, "BAR size %zu is not divisible by %u\n",
bar->size, nsub);
goto err;
}
sub_size = bar->size / nsub;
submap = kzalloc_objs(*submap, nsub);
if (!submap)
goto err;
for (i = 0; i < nsub; i++) {
/* Swap the two halves so RC can verify ordering. */
phys_idx = i ^ 1;
submap[i].phys_addr = bar->phys_addr + (phys_idx * sub_size);
submap[i].size = sub_size;
}
old_submap = bar->submap;
old_nsub = bar->num_submap;
bar->submap = submap;
bar->num_submap = nsub;
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no, bar);
if (ret) {
dev_err(&epf->dev, "pci_epc_set_bar() failed: %d\n", ret);
if (ret == -ENOSPC)
status |= STATUS_NO_RESOURCE;
bar->submap = old_submap;
bar->num_submap = old_nsub;
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no, bar);
if (ret)
dev_warn(&epf->dev, "Failed to restore the original BAR mapping: %d\n",
ret);
kfree(submap);
goto err;
}
kfree(old_submap);
/*
* Fill deterministic signatures into the physical regions that
* each BAR subrange maps to. RC verifies these to ensure the
* submap order is really applied.
*/
addr = (u8 *)bar->addr;
for (i = 0; i < nsub; i++) {
phys_idx = i ^ 1;
memset(addr + (phys_idx * sub_size),
pci_epf_test_subrange_sig_byte(barno, i),
sub_size);
}
status |= STATUS_BAR_SUBRANGE_SETUP_SUCCESS;
reg->status = cpu_to_le32(status);
return;
err:
status |= STATUS_BAR_SUBRANGE_SETUP_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_bar_subrange_clear(struct pci_epf_test *epf_test,
struct pci_epf_test_reg *reg)
{
struct pci_epf *epf = epf_test->epf;
struct pci_epf_bar_submap *submap;
struct pci_epc *epc = epf->epc;
/* reg->size carries BAR number for BAR_SUBRANGE_* commands. */
enum pci_barno barno = le32_to_cpu(reg->size);
u32 status = le32_to_cpu(reg->status);
struct pci_epf_bar *bar;
unsigned int nsub;
int ret;
if (barno >= PCI_STD_NUM_BARS) {
dev_err(&epf->dev, "Invalid barno: %d\n", barno);
goto err;
}
bar = &epf->bar[barno];
submap = bar->submap;
nsub = bar->num_submap;
if (!submap || !nsub)
goto err;
bar->submap = NULL;
bar->num_submap = 0;
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no, bar);
if (ret) {
bar->submap = submap;
bar->num_submap = nsub;
dev_err(&epf->dev, "pci_epc_set_bar() failed: %d\n", ret);
goto err;
}
kfree(submap);
status |= STATUS_BAR_SUBRANGE_CLEAR_SUCCESS;
reg->status = cpu_to_le32(status);
return;
err:
status |= STATUS_BAR_SUBRANGE_CLEAR_FAIL;
reg->status = cpu_to_le32(status);
}
static void pci_epf_test_cmd_handler(struct work_struct *work)
{
u32 command;
struct pci_epf_test *epf_test = container_of(work, struct pci_epf_test,
cmd_handler.work);
struct pci_epf *epf = epf_test->epf;
struct device *dev = &epf->dev;
enum pci_barno test_reg_bar = epf_test->test_reg_bar;
struct pci_epf_test_reg *reg = epf_test->reg[test_reg_bar];
u32 irq_type = le32_to_cpu(reg->irq_type);
command = le32_to_cpu(READ_ONCE(reg->command));
if (!command)
goto reset_handler;
WRITE_ONCE(reg->command, 0);
WRITE_ONCE(reg->status, 0);
if ((le32_to_cpu(READ_ONCE(reg->flags)) & FLAG_USE_DMA) &&
!epf_test->dma_supported) {
dev_err(dev, "Cannot transfer data using DMA\n");
goto reset_handler;
}
if (irq_type > IRQ_TYPE_MSIX) {
dev_err(dev, "Failed to detect IRQ type\n");
goto reset_handler;
}
switch (command) {
case COMMAND_RAISE_INTX_IRQ:
case COMMAND_RAISE_MSI_IRQ:
case COMMAND_RAISE_MSIX_IRQ:
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_WRITE:
pci_epf_test_write(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_READ:
pci_epf_test_read(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_COPY:
pci_epf_test_copy(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_ENABLE_DOORBELL:
pci_epf_test_enable_doorbell(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_DISABLE_DOORBELL:
pci_epf_test_disable_doorbell(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_BAR_SUBRANGE_SETUP:
pci_epf_test_bar_subrange_setup(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
case COMMAND_BAR_SUBRANGE_CLEAR:
pci_epf_test_bar_subrange_clear(epf_test, reg);
pci_epf_test_raise_irq(epf_test, reg);
break;
default:
dev_err(dev, "Invalid command 0x%x\n", command);
break;
}
reset_handler:
queue_delayed_work(kpcitest_workqueue, &epf_test->cmd_handler,
msecs_to_jiffies(1));
}
static int pci_epf_test_set_bar(struct pci_epf *epf)
{
int bar, ret;
struct pci_epc *epc = epf->epc;
struct device *dev = &epf->dev;
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
enum pci_barno test_reg_bar = epf_test->test_reg_bar;
for (bar = 0; bar < PCI_STD_NUM_BARS; bar++) {
if (!epf_test->reg[bar])
continue;
ret = pci_epc_set_bar(epc, epf->func_no, epf->vfunc_no,
&epf->bar[bar]);
if (ret) {
pci_epf_free_space(epf, epf_test->reg[bar], bar,
PRIMARY_INTERFACE);
epf_test->reg[bar] = NULL;
dev_err(dev, "Failed to set BAR%d\n", bar);
if (bar == test_reg_bar)
return ret;
}
}
return 0;
}
static void pci_epf_test_clear_bar(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
struct pci_epc *epc = epf->epc;
int bar;
for (bar = 0; bar < PCI_STD_NUM_BARS; bar++) {
if (!epf_test->reg[bar])
continue;
pci_epc_clear_bar(epc, epf->func_no, epf->vfunc_no,
&epf->bar[bar]);
}
}
static void pci_epf_test_set_capabilities(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
enum pci_barno test_reg_bar = epf_test->test_reg_bar;
struct pci_epf_test_reg *reg = epf_test->reg[test_reg_bar];
struct pci_epc *epc = epf->epc;
u32 caps = 0;
if (epc->ops->align_addr)
caps |= CAP_UNALIGNED_ACCESS;
if (epf_test->epc_features->msi_capable)
caps |= CAP_MSI;
if (epf_test->epc_features->msix_capable)
caps |= CAP_MSIX;
if (epf_test->epc_features->intx_capable)
caps |= CAP_INTX;
if (epf_test->epc_features->dynamic_inbound_mapping)
caps |= CAP_DYNAMIC_INBOUND_MAPPING;
if (epf_test->epc_features->dynamic_inbound_mapping &&
epf_test->epc_features->subrange_mapping)
caps |= CAP_SUBRANGE_MAPPING;
if (epf_test->epc_features->bar[BAR_0].type == BAR_RESERVED)
caps |= CAP_BAR0_RESERVED;
if (epf_test->epc_features->bar[BAR_1].type == BAR_RESERVED)
caps |= CAP_BAR1_RESERVED;
if (epf_test->epc_features->bar[BAR_2].type == BAR_RESERVED)
caps |= CAP_BAR2_RESERVED;
if (epf_test->epc_features->bar[BAR_3].type == BAR_RESERVED)
caps |= CAP_BAR3_RESERVED;
if (epf_test->epc_features->bar[BAR_4].type == BAR_RESERVED)
caps |= CAP_BAR4_RESERVED;
if (epf_test->epc_features->bar[BAR_5].type == BAR_RESERVED)
caps |= CAP_BAR5_RESERVED;
reg->caps = cpu_to_le32(caps);
}
static int pci_epf_test_epc_init(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
struct pci_epf_header *header = epf->header;
const struct pci_epc_features *epc_features = epf_test->epc_features;
struct pci_epc *epc = epf->epc;
struct device *dev = &epf->dev;
bool linkup_notifier = false;
int ret;
epf_test->dma_supported = true;
ret = pci_epf_test_init_dma_chan(epf_test);
if (ret)
epf_test->dma_supported = false;
if (epf->vfunc_no <= 1) {
ret = pci_epc_write_header(epc, epf->func_no, epf->vfunc_no, header);
if (ret) {
dev_err(dev, "Configuration header write failed\n");
return ret;
}
}
pci_epf_test_set_capabilities(epf);
ret = pci_epf_test_set_bar(epf);
if (ret)
return ret;
if (epc_features->msi_capable) {
ret = pci_epc_set_msi(epc, epf->func_no, epf->vfunc_no,
epf->msi_interrupts);
if (ret) {
dev_err(dev, "MSI configuration failed\n");
return ret;
}
}
if (epc_features->msix_capable) {
ret = pci_epc_set_msix(epc, epf->func_no, epf->vfunc_no,
epf->msix_interrupts,
epf_test->test_reg_bar,
epf_test->msix_table_offset);
if (ret) {
dev_err(dev, "MSI-X configuration failed\n");
return ret;
}
}
linkup_notifier = epc_features->linkup_notifier;
if (!linkup_notifier)
queue_work(kpcitest_workqueue, &epf_test->cmd_handler.work);
return 0;
}
static void pci_epf_test_epc_deinit(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
cancel_delayed_work_sync(&epf_test->cmd_handler);
pci_epf_test_clean_dma_chan(epf_test);
pci_epf_test_clear_bar(epf);
}
static int pci_epf_test_link_up(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
queue_delayed_work(kpcitest_workqueue, &epf_test->cmd_handler,
msecs_to_jiffies(1));
return 0;
}
static int pci_epf_test_link_down(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
cancel_delayed_work_sync(&epf_test->cmd_handler);
return 0;
}
static const struct pci_epc_event_ops pci_epf_test_event_ops = {
.epc_init = pci_epf_test_epc_init,
.epc_deinit = pci_epf_test_epc_deinit,
.link_up = pci_epf_test_link_up,
.link_down = pci_epf_test_link_down,
};
static int pci_epf_test_alloc_space(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
struct device *dev = &epf->dev;
size_t msix_table_size = 0;
size_t test_reg_bar_size;
size_t pba_size = 0;
void *base;
enum pci_barno test_reg_bar = epf_test->test_reg_bar;
enum pci_barno bar;
const struct pci_epc_features *epc_features = epf_test->epc_features;
size_t test_reg_size;
test_reg_bar_size = ALIGN(sizeof(struct pci_epf_test_reg), 128);
if (epc_features->msix_capable) {
msix_table_size = PCI_MSIX_ENTRY_SIZE * epf->msix_interrupts;
epf_test->msix_table_offset = test_reg_bar_size;
/* Align to QWORD or 8 Bytes */
pba_size = ALIGN(DIV_ROUND_UP(epf->msix_interrupts, 8), 8);
}
test_reg_size = test_reg_bar_size + msix_table_size + pba_size;
base = pci_epf_alloc_space(epf, test_reg_size, test_reg_bar,
epc_features, PRIMARY_INTERFACE);
if (!base) {
dev_err(dev, "Failed to allocated register space\n");
return -ENOMEM;
}
epf_test->reg[test_reg_bar] = base;
for (bar = BAR_0; bar < PCI_STD_NUM_BARS; bar++) {
bar = pci_epc_get_next_free_bar(epc_features, bar);
if (bar == NO_BAR)
break;
if (bar == test_reg_bar)
continue;
if (epc_features->bar[bar].type == BAR_FIXED)
test_reg_size = epc_features->bar[bar].fixed_size;
else
test_reg_size = epf_test->bar_size[bar];
base = pci_epf_alloc_space(epf, test_reg_size, bar,
epc_features, PRIMARY_INTERFACE);
if (!base)
dev_err(dev, "Failed to allocate space for BAR%d\n",
bar);
epf_test->reg[bar] = base;
}
return 0;
}
static void pci_epf_test_free_space(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
int bar;
for (bar = 0; bar < PCI_STD_NUM_BARS; bar++) {
if (!epf_test->reg[bar])
continue;
pci_epf_free_space(epf, epf_test->reg[bar], bar,
PRIMARY_INTERFACE);
epf_test->reg[bar] = NULL;
}
}
static int pci_epf_test_bind(struct pci_epf *epf)
{
int ret;
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
const struct pci_epc_features *epc_features;
enum pci_barno test_reg_bar = BAR_0;
struct pci_epc *epc = epf->epc;
if (WARN_ON_ONCE(!epc))
return -EINVAL;
epc_features = pci_epc_get_features(epc, epf->func_no, epf->vfunc_no);
if (!epc_features) {
dev_err(&epf->dev, "epc_features not implemented\n");
return -EOPNOTSUPP;
}
test_reg_bar = pci_epc_get_first_free_bar(epc_features);
if (test_reg_bar < 0)
return -EINVAL;
epf_test->test_reg_bar = test_reg_bar;
epf_test->epc_features = epc_features;
ret = pci_epf_test_alloc_space(epf);
if (ret)
return ret;
return 0;
}
static void pci_epf_test_unbind(struct pci_epf *epf)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
struct pci_epc *epc = epf->epc;
cancel_delayed_work_sync(&epf_test->cmd_handler);
if (epc->init_complete) {
pci_epf_test_clean_dma_chan(epf_test);
pci_epf_test_clear_bar(epf);
}
pci_epf_test_free_space(epf);
}
#define PCI_EPF_TEST_BAR_SIZE_R(_name, _id) \
static ssize_t pci_epf_test_##_name##_show(struct config_item *item, \
char *page) \
{ \
struct config_group *group = to_config_group(item); \
struct pci_epf_test *epf_test = \
container_of(group, struct pci_epf_test, group); \
\
return sysfs_emit(page, "%zu\n", epf_test->bar_size[_id]); \
}
#define PCI_EPF_TEST_BAR_SIZE_W(_name, _id) \
static ssize_t pci_epf_test_##_name##_store(struct config_item *item, \
const char *page, \
size_t len) \
{ \
struct config_group *group = to_config_group(item); \
struct pci_epf_test *epf_test = \
container_of(group, struct pci_epf_test, group); \
int val, ret; \
\
/* \
* BAR sizes can only be modified before binding to an EPC, \
* because pci_epf_test_alloc_space() is called in .bind(). \
*/ \
if (epf_test->epf->epc) \
return -EOPNOTSUPP; \
\
ret = kstrtouint(page, 0, &val); \
if (ret) \
return ret; \
\
if (!is_power_of_2(val)) \
return -EINVAL; \
\
epf_test->bar_size[_id] = val; \
\
return len; \
}
PCI_EPF_TEST_BAR_SIZE_R(bar0_size, BAR_0)
PCI_EPF_TEST_BAR_SIZE_W(bar0_size, BAR_0)
PCI_EPF_TEST_BAR_SIZE_R(bar1_size, BAR_1)
PCI_EPF_TEST_BAR_SIZE_W(bar1_size, BAR_1)
PCI_EPF_TEST_BAR_SIZE_R(bar2_size, BAR_2)
PCI_EPF_TEST_BAR_SIZE_W(bar2_size, BAR_2)
PCI_EPF_TEST_BAR_SIZE_R(bar3_size, BAR_3)
PCI_EPF_TEST_BAR_SIZE_W(bar3_size, BAR_3)
PCI_EPF_TEST_BAR_SIZE_R(bar4_size, BAR_4)
PCI_EPF_TEST_BAR_SIZE_W(bar4_size, BAR_4)
PCI_EPF_TEST_BAR_SIZE_R(bar5_size, BAR_5)
PCI_EPF_TEST_BAR_SIZE_W(bar5_size, BAR_5)
CONFIGFS_ATTR(pci_epf_test_, bar0_size);
CONFIGFS_ATTR(pci_epf_test_, bar1_size);
CONFIGFS_ATTR(pci_epf_test_, bar2_size);
CONFIGFS_ATTR(pci_epf_test_, bar3_size);
CONFIGFS_ATTR(pci_epf_test_, bar4_size);
CONFIGFS_ATTR(pci_epf_test_, bar5_size);
static struct configfs_attribute *pci_epf_test_attrs[] = {
&pci_epf_test_attr_bar0_size,
&pci_epf_test_attr_bar1_size,
&pci_epf_test_attr_bar2_size,
&pci_epf_test_attr_bar3_size,
&pci_epf_test_attr_bar4_size,
&pci_epf_test_attr_bar5_size,
NULL,
};
static const struct config_item_type pci_epf_test_group_type = {
.ct_attrs = pci_epf_test_attrs,
.ct_owner = THIS_MODULE,
};
static struct config_group *pci_epf_test_add_cfs(struct pci_epf *epf,
struct config_group *group)
{
struct pci_epf_test *epf_test = epf_get_drvdata(epf);
struct config_group *epf_group = &epf_test->group;
struct device *dev = &epf->dev;
config_group_init_type_name(epf_group, dev_name(dev),
&pci_epf_test_group_type);
return epf_group;
}
static const struct pci_epf_device_id pci_epf_test_ids[] = {
{
.name = "pci_epf_test",
},
{},
};
static int pci_epf_test_probe(struct pci_epf *epf,
const struct pci_epf_device_id *id)
{
struct pci_epf_test *epf_test;
struct device *dev = &epf->dev;
enum pci_barno bar;
epf_test = devm_kzalloc(dev, sizeof(*epf_test), GFP_KERNEL);
if (!epf_test)
return -ENOMEM;
epf->header = &test_header;
epf_test->epf = epf;
for (bar = BAR_0; bar < PCI_STD_NUM_BARS; bar++)
epf_test->bar_size[bar] = default_bar_size[bar];
INIT_DELAYED_WORK(&epf_test->cmd_handler, pci_epf_test_cmd_handler);
epf->event_ops = &pci_epf_test_event_ops;
epf_set_drvdata(epf, epf_test);
return 0;
}
static const struct pci_epf_ops ops = {
.unbind = pci_epf_test_unbind,
.bind = pci_epf_test_bind,
.add_cfs = pci_epf_test_add_cfs,
};
static struct pci_epf_driver test_driver = {
.driver.name = "pci_epf_test",
.probe = pci_epf_test_probe,
.id_table = pci_epf_test_ids,
.ops = &ops,
.owner = THIS_MODULE,
};
static int __init pci_epf_test_init(void)
{
int ret;
kpcitest_workqueue = alloc_workqueue("kpcitest",
WQ_MEM_RECLAIM | WQ_HIGHPRI | WQ_PERCPU, 0);
if (!kpcitest_workqueue) {
pr_err("Failed to allocate the kpcitest work queue\n");
return -ENOMEM;
}
ret = pci_epf_register_driver(&test_driver);
if (ret) {
destroy_workqueue(kpcitest_workqueue);
pr_err("Failed to register pci epf test driver --> %d\n", ret);
return ret;
}
return 0;
}
module_init(pci_epf_test_init);
static void __exit pci_epf_test_exit(void)
{
if (kpcitest_workqueue)
destroy_workqueue(kpcitest_workqueue);
pci_epf_unregister_driver(&test_driver);
}
module_exit(pci_epf_test_exit);
MODULE_DESCRIPTION("PCI EPF TEST DRIVER");
MODULE_AUTHOR("Kishon Vijay Abraham I <kishon@ti.com>");
MODULE_LICENSE("GPL v2");