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* Driver for Altera PCIe core chaining DMA reference design.
*
* Copyright (C) 2008 Leon Woestenberg <leon.woestenberg@axon.tv>
* Copyright (C) 2008 Nickolas Heppermann <heppermannwdt@gmail.com>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*
*
* Rationale: This driver exercises the chaining DMA read and write engine
* in the reference design. It is meant as a complementary reference
* driver that can be used for testing early designs as well as a basis to
* write your custom driver.
*
* Status: Test results from Leon Woestenberg <leon.woestenberg@axon.tv>:
*
* Sendero Board w/ Cyclone II EP2C35F672C6N, PX1011A PCIe x1 PHY on a
* Dell Precision 370 PC, x86, kernel 2.6.20 from Ubuntu 7.04.
*
* Sendero Board w/ Cyclone II EP2C35F672C6N, PX1011A PCIe x1 PHY on a
* Freescale MPC8313E-RDB board, PowerPC, 2.6.24 w/ Freescale patches.
*
* Driver tests passed with PCIe Compiler 8.1. With PCIe 8.0 the DMA
* loopback test had reproducable compare errors. I assume a change
* in the compiler or reference design, but could not find evidence nor
* documentation on a change or fix in that direction.
*
* The reference design does not have readable locations and thus a
* dummy read, used to flush PCI posted writes, cannot be performed.
*
*/
#include <linux/kernel.h>
#include <linux/cdev.h>
#include <linux/delay.h>
#include <linux/dma-mapping.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/jiffies.h>
#include <linux/module.h>
#include <linux/pci.h>
/* by default do not build the character device interface */
/* XXX It is non-functional yet */
#ifndef ALTPCIECHDMA_CDEV
# define ALTPCIECHDMA_CDEV 0
#endif
/* build the character device interface? */
#if ALTPCIECHDMA_CDEV
# define MAX_CHDMA_SIZE (8 * 1024 * 1024)
# include "mapper_user_to_sg.h"
#endif
/** driver name, mimicks Altera naming of the reference design */
#define DRV_NAME "altpciechdma"
/** number of BARs on the device */
#define APE_BAR_NUM (6)
/** BAR number where the RCSLAVE memory sits */
#define APE_BAR_RCSLAVE (0)
/** BAR number where the Descriptor Header sits */
#define APE_BAR_HEADER (2)
/** maximum size in bytes of the descriptor table, chdma logic limit */
#define APE_CHDMA_TABLE_SIZE (4096)
/* single transfer must not exceed 255 table entries. worst case this can be
* achieved by 255 scattered pages, with only a single byte in the head and
* tail pages. 253 * PAGE_SIZE is a safe upper bound for the transfer size.
*/
#define APE_CHDMA_MAX_TRANSFER_LEN (253 * PAGE_SIZE)
/**
* Specifies those BARs to be mapped and the length of each mapping.
*
* Zero (0) means do not map, otherwise specifies the BAR lengths to be mapped.
* If the actual BAR length is less, this is considered an error; then
* reconfigure your PCIe core.
*
* @see ug_pci_express 8.0, table 7-2 at page 7-13.
*/
static const unsigned long bar_min_len[APE_BAR_NUM] =
{ 32768, 0, 256, 0, 32768, 0 };
/**
* Descriptor Header, controls the DMA read engine or write engine.
*
* The descriptor header is the main data structure for starting DMA transfers.
*
* It sits in End Point (FPGA) memory BAR[2] for 32-bit or BAR[3:2] for 64-bit.
* It references a descriptor table which exists in Root Complex (PC) memory.
* Writing the rclast field starts the DMA operation, thus all other structures
* and fields must be setup before doing so.
*
* @see ug_pci_express 8.0, tables 7-3, 7-4 and 7-5 at page 7-14.
* @note This header must be written in four 32-bit (PCI DWORD) writes.
*/
struct ape_chdma_header {
/**
* w0 consists of two 16-bit fields:
* lsb u16 number; number of descriptors in ape_chdma_table
* msb u16 control; global control flags
*/
u32 w0;
/* bus address to ape_chdma_table in Root Complex memory */
u32 bdt_addr_h;
u32 bdt_addr_l;
/**
* w3 consists of two 16-bit fields:
* - lsb u16 rclast; last descriptor number available in Root Complex
* - zero (0) means the first descriptor is ready,
* - one (1) means two descriptors are ready, etc.
* - msb u16 reserved;
*
* @note writing to this memory location starts the DMA operation!
*/
u32 w3;
} __attribute__ ((packed));
/**
* Descriptor Entry, describing a (non-scattered) single memory block transfer.
*
* There is one descriptor for each memory block involved in the transfer, a
* block being a contiguous address range on the bus.
*
* Multiple descriptors are chained by means of the ape_chdma_table data
* structure.
*
* @see ug_pci_express 8.0, tables 7-6, 7-7 and 7-8 at page 7-14 and page 7-15.
*/
struct ape_chdma_desc {
/**
* w0 consists of two 16-bit fields:
* number of DWORDS to transfer
* - lsb u16 length;
* global control
* - msb u16 control;
*/
u32 w0;
/* address of memory in the End Point */
u32 ep_addr;
/* bus address of source or destination memory in the Root Complex */
u32 rc_addr_h;
u32 rc_addr_l;
} __attribute__ ((packed));
/**
* Descriptor Table, an array of descriptors describing a chained transfer.
*
* An array of descriptors, preceded by workspace for the End Point.
* It exists in Root Complex memory.
*
* The End Point can update its last completed descriptor number in the
* eplast field if requested by setting the EPLAST_ENA bit either
* globally in the header's or locally in any descriptor's control field.
*
* @note this structure may not exceed 4096 bytes. This results in a
* maximum of 4096 / (4 * 4) - 1 = 255 descriptors per chained transfer.
*
* @see ug_pci_express 8.0, tables 7-9, 7-10 and 7-11 at page 7-17 and page 7-18.
*/
struct ape_chdma_table {
/* workspace 0x00-0x0b, reserved */
u32 reserved1[3];
/* workspace 0x0c-0x0f, last descriptor handled by End Point */
u32 w3;
/* the actual array of descriptors
* 0x10-0x1f, 0x20-0x2f, ... 0xff0-0xfff (255 entries)
*/
struct ape_chdma_desc desc[255];
} __attribute__ ((packed));
/**
* Altera PCI Express ('ape') board specific book keeping data
*
* Keeps state of the PCIe core and the Chaining DMA controller
* application.
*/
struct ape_dev {
/** the kernel pci device data structure provided by probe() */
struct pci_dev *pci_dev;
/**
* kernel virtual address of the mapped BAR memory and IO regions of
* the End Point. Used by map_bars()/unmap_bars().
*/
void * __iomem bar[APE_BAR_NUM];
/** kernel virtual address for Descriptor Table in Root Complex memory */
struct ape_chdma_table *table_virt;
/**
* bus address for the Descriptor Table in Root Complex memory, in
* CPU-native endianess
*/
dma_addr_t table_bus;
/* if the device regions could not be allocated, assume and remember it
* is in use by another driver; this driver must not disable the device.
*/
int in_use;
/* whether this driver enabled msi for the device */
int msi_enabled;
/* whether this driver could obtain the regions */
int got_regions;
/* irq line successfully requested by this driver, -1 otherwise */
int irq_line;
/* board revision */
u8 revision;
/* interrupt count, incremented by the interrupt handler */
int irq_count;
#if ALTPCIECHDMA_CDEV
/* character device */
dev_t cdevno;
struct cdev cdev;
/* user space scatter gather mapper */
struct sg_mapping_t *sgm;
#endif
};
/**
* Using the subsystem vendor id and subsystem id, it is possible to
* distinguish between different cards bases around the same
* (third-party) logic core.
*
* Default Altera vendor and device ID's, and some (non-reserved)
* ID's are now used here that are used amongst the testers/developers.
*/
static const struct pci_device_id ids[] = {
{ PCI_DEVICE(0x1172, 0xE001), },
{ PCI_DEVICE(0x2071, 0x2071), },
{ 0, }
};
MODULE_DEVICE_TABLE(pci, ids);
#if ALTPCIECHDMA_CDEV
/* prototypes for character device */
static int sg_init(struct ape_dev *ape);
static void sg_exit(struct ape_dev *ape);
#endif
/**
* altpciechdma_isr() - Interrupt handler
*
*/
static irqreturn_t altpciechdma_isr(int irq, void *dev_id)
{
struct ape_dev *ape = (struct ape_dev *)dev_id;
if (!ape)
return IRQ_NONE;
ape->irq_count++;
return IRQ_HANDLED;
}
static int __devinit scan_bars(struct ape_dev *ape, struct pci_dev *dev)
{
int i;
for (i = 0; i < APE_BAR_NUM; i++) {
unsigned long bar_start = pci_resource_start(dev, i);
if (bar_start) {
unsigned long bar_end = pci_resource_end(dev, i);
unsigned long bar_flags = pci_resource_flags(dev, i);
printk(KERN_DEBUG "BAR%d 0x%08lx-0x%08lx flags 0x%08lx\n",
i, bar_start, bar_end, bar_flags);
}
}
return 0;
}
/**
* Unmap the BAR regions that had been mapped earlier using map_bars()
*/
static void unmap_bars(struct ape_dev *ape, struct pci_dev *dev)
{
int i;
for (i = 0; i < APE_BAR_NUM; i++) {
/* is this BAR mapped? */
if (ape->bar[i]) {
/* unmap BAR */
pci_iounmap(dev, ape->bar[i]);
ape->bar[i] = NULL;
}
}
}
/**
* Map the device memory regions into kernel virtual address space after
* verifying their sizes respect the minimum sizes needed, given by the
* bar_min_len[] array.
*/
static int __devinit map_bars(struct ape_dev *ape, struct pci_dev *dev)
{
int rc;
int i;
/* iterate through all the BARs */
for (i = 0; i < APE_BAR_NUM; i++) {
unsigned long bar_start = pci_resource_start(dev, i);
unsigned long bar_end = pci_resource_end(dev, i);
unsigned long bar_length = bar_end - bar_start + 1;
ape->bar[i] = NULL;
/* do not map, and skip, BARs with length 0 */
if (!bar_min_len[i])
continue;
/* do not map BARs with address 0 */
if (!bar_start || !bar_end) {
printk(KERN_DEBUG "BAR #%d is not present?!\n", i);
rc = -1;
goto fail;
}
bar_length = bar_end - bar_start + 1;
/* BAR length is less than driver requires? */
if (bar_length < bar_min_len[i]) {
printk(KERN_DEBUG "BAR #%d length = %lu bytes but driver "
"requires at least %lu bytes\n",
i, bar_length, bar_min_len[i]);
rc = -1;
goto fail;
}
/* map the device memory or IO region into kernel virtual
* address space */
ape->bar[i] = pci_iomap(dev, i, bar_min_len[i]);
if (!ape->bar[i]) {
printk(KERN_DEBUG "Could not map BAR #%d.\n", i);
rc = -1;
goto fail;
}
printk(KERN_DEBUG "BAR[%d] mapped at 0x%p with length %lu(/%lu).\n", i,
ape->bar[i], bar_min_len[i], bar_length);
}
/* successfully mapped all required BAR regions */
rc = 0;
goto success;
fail:
/* unmap any BARs that we did map */
unmap_bars(ape, dev);
success:
return rc;
}
#if 0 /* not yet implemented fully FIXME add opcode */
static void __devinit rcslave_test(struct ape_dev *ape, struct pci_dev *dev)
{
u32 *rcslave_mem = (u32 *)ape->bar[APE_BAR_RCSLAVE];
u32 result = 0;
/** this number is assumed to be different each time this test runs */
u32 seed = (u32)jiffies;
u32 value = seed;
int i;
/* write loop */
value = seed;
for (i = 1024; i < 32768 / 4 ; i++) {
printk(KERN_DEBUG "Writing 0x%08x to 0x%p.\n",
(u32)value, (void *)rcslave_mem + i);
iowrite32(value, rcslave_mem + i);
value++;
}
/* read-back loop */
value = seed;
for (i = 1024; i < 32768 / 4; i++) {
result = ioread32(rcslave_mem + i);
if (result != value) {
printk(KERN_DEBUG "Wrote 0x%08x to 0x%p, but read back 0x%08x.\n",
(u32)value, (void *)rcslave_mem + i, (u32)result);
break;
}
value++;
}
}
#endif
/* obtain the 32 most significant (high) bits of a 32-bit or 64-bit address */
#define pci_dma_h(addr) ((addr >> 16) >> 16)
/* obtain the 32 least significant (low) bits of a 32-bit or 64-bit address */
#define pci_dma_l(addr) (addr & 0xffffffffUL)
/* ape_fill_chdma_desc() - Fill a Altera PCI Express Chaining DMA descriptor
*
* @desc pointer to descriptor to be filled
* @addr root complex address
* @ep_addr end point address
* @len number of bytes, must be a multiple of 4.
*/
static inline void ape_chdma_desc_set(struct ape_chdma_desc *desc, dma_addr_t addr, u32 ep_addr, int len)
{
BUG_ON(len & 3);
desc->w0 = cpu_to_le32(len / 4);
desc->ep_addr = cpu_to_le32(ep_addr);
desc->rc_addr_h = cpu_to_le32(pci_dma_h(addr));
desc->rc_addr_l = cpu_to_le32(pci_dma_l(addr));
}
#if ALTPCIECHDMA_CDEV
/*
* ape_sg_to_chdma_table() - Create a device descriptor table from a scatterlist.
*
* The scatterlist must have been mapped by pci_map_sg(sgm->sgl).
*
* @sgl scatterlist.
* @nents Number of entries in the scatterlist.
* @first Start index in the scatterlist sgm->sgl.
* @ep_addr End Point address for the scatter/gather transfer.
* @desc pointer to first descriptor
*
* Returns Number of entries in the table on success, -1 on error.
*/
static int ape_sg_to_chdma_table(struct scatterlist *sgl, int nents, int first, struct ape_chdma_desc *desc, u32 ep_addr)
{
int i = first, j = 0;
/* inspect first entry */
dma_addr_t addr = sg_dma_address(&sgl[i]);
unsigned int len = sg_dma_len(&sgl[i]);
/* contiguous block */
dma_addr_t cont_addr = addr;
unsigned int cont_len = len;
/* iterate over remaining entries */
for (; j < 25 && i < nents - 1; i++) {
/* bus address of next entry i + 1 */
dma_addr_t next = sg_dma_address(&sgl[i + 1]);
/* length of this entry i */
len = sg_dma_len(&sgl[i]);
printk(KERN_DEBUG "%04d: addr=0x%Lx length=0x%08x\n", i,
(unsigned long long)addr, len);
/* entry i + 1 is non-contiguous with entry i? */
if (next != addr + len) {
/* TODO create entry here (we could overwrite i) */
printk(KERN_DEBUG "%4d: cont_addr=0x%Lx cont_len=0x%08x\n", j,
(unsigned long long)cont_addr, cont_len);
/* set descriptor for contiguous transfer */
ape_chdma_desc_set(&desc[j], cont_addr, ep_addr, cont_len);
/* next end point memory address */
ep_addr += cont_len;
/* start new contiguous block */
cont_addr = next;
cont_len = 0;
j++;
}
/* add entry i + 1 to current contiguous block */
cont_len += len;
/* goto entry i + 1 */
addr = next;
}
/* TODO create entry here (we could overwrite i) */
printk(KERN_DEBUG "%04d: addr=0x%Lx length=0x%08x\n", i,
(unsigned long long)addr, len);
printk(KERN_DEBUG "%4d: cont_addr=0x%Lx length=0x%08x\n", j,
(unsigned long long)cont_addr, cont_len);
j++;
return j;
}
#endif
/* compare buffers */
static inline int compare(u32 *p, u32 *q, int len)
{
int result = -1;
int fail = 0;
int i;
for (i = 0; i < len / 4; i++) {
if (*p == *q) {
/* every so many u32 words, show equals */
if ((i & 255) == 0)
printk(KERN_DEBUG "[%p] = 0x%08x [%p] = 0x%08x\n", p, *p, q, *q);
} else {
fail++;
/* show the first few miscompares */
if (fail < 10)
printk(KERN_DEBUG "[%p] = 0x%08x != [%p] = 0x%08x ?!\n", p, *p, q, *q);
/* but stop after a while */
else if (fail == 10)
printk(KERN_DEBUG "---more errors follow! not printed---\n");
else
/* stop compare after this many errors */
break;
}
p++;
q++;
}
if (!fail)
result = 0;
return result;
}
/* dma_test() - Perform DMA loop back test to end point and back to root complex.
*
* Allocate a cache-coherent buffer in host memory, consisting of four pages.
*
* Fill the four memory pages such that each 32-bit word contains its own address.
*
* Now perform a loop back test, have the end point device copy the first buffer
* half to end point memory, then have it copy back into the second half.
*
* Create a descriptor table to copy the first buffer half into End Point
* memory. Instruct the End Point to do a DMA read using that table.
*
* Create a descriptor table to copy End Point memory to the second buffer
* half. Instruct the End Point to do a DMA write using that table.
*
* Compare results, fail or pass.
*
*/
static int __devinit dma_test(struct ape_dev *ape, struct pci_dev *dev)
{
/* test result; guilty until proven innocent */
int result = -1;
/* the DMA read header sits at address 0x00 of the DMA engine BAR */
struct ape_chdma_header *write_header = (struct ape_chdma_header *)ape->bar[APE_BAR_HEADER];
/* the write DMA header sits after the read header at address 0x10 */
struct ape_chdma_header *read_header = write_header + 1;
/* virtual address of the allocated buffer */
u8 *buffer_virt = 0;
/* bus address of the allocated buffer */
dma_addr_t buffer_bus = 0;
int i, n = 0, irq_count;
/* temporary value used to construct 32-bit data words */
u32 w;
printk(KERN_DEBUG "bar_tests(), PAGE_SIZE = 0x%0x\n", (int)PAGE_SIZE);
printk(KERN_DEBUG "write_header = 0x%p.\n", write_header);
printk(KERN_DEBUG "read_header = 0x%p.\n", read_header);
printk(KERN_DEBUG "&write_header->w3 = 0x%p\n", &write_header->w3);
printk(KERN_DEBUG "&read_header->w3 = 0x%p\n", &read_header->w3);
printk(KERN_DEBUG "ape->table_virt = 0x%p.\n", ape->table_virt);
if (!write_header || !read_header || !ape->table_virt)
goto fail;
/* allocate and map coherently-cached memory for a DMA-able buffer */
/* @see Documentation/PCI/PCI-DMA-mapping.txt, near line 318 */
buffer_virt = (u8 *)pci_alloc_consistent(dev, PAGE_SIZE * 4, &buffer_bus);
if (!buffer_virt) {
printk(KERN_DEBUG "Could not allocate coherent DMA buffer.\n");
goto fail;
}
printk(KERN_DEBUG "Allocated cache-coherent DMA buffer (virtual address = %p, bus address = 0x%016llx).\n",
buffer_virt, (u64)buffer_bus);
/* fill first half of buffer with its virtual address as data */
for (i = 0; i < 4 * PAGE_SIZE; i += 4)
#if 0
*(u32 *)(buffer_virt + i) = i / PAGE_SIZE + 1;
#else
*(u32 *)(buffer_virt + i) = (u32)(unsigned long)(buffer_virt + i);
#endif
#if 0
compare((u32 *)buffer_virt, (u32 *)(buffer_virt + 2 * PAGE_SIZE), 8192);
#endif
#if 0
/* fill second half of buffer with zeroes */
for (i = 2 * PAGE_SIZE; i < 4 * PAGE_SIZE; i += 4)
*(u32 *)(buffer_virt + i) = 0;
#endif
/* invalidate EPLAST, outside 0-255, 0xFADE is from the testbench */
ape->table_virt->w3 = cpu_to_le32(0x0000FADE);
/* fill in first descriptor */
n = 0;
/* read 8192 bytes from RC buffer to EP address 4096 */
ape_chdma_desc_set(&ape->table_virt->desc[n], buffer_bus, 4096, 2 * PAGE_SIZE);
#if 1
for (i = 0; i < 255; i++)
ape_chdma_desc_set(&ape->table_virt->desc[i], buffer_bus, 4096, 2 * PAGE_SIZE);
/* index of last descriptor */
n = i - 1;
#endif
#if 0
/* fill in next descriptor */
n++;
/* read 1024 bytes from RC buffer to EP address 4096 + 1024 */
ape_chdma_desc_set(&ape->table_virt->desc[n], buffer_bus + 1024, 4096 + 1024, 1024);
#endif
#if 1
/* enable MSI after the last descriptor is completed */
if (ape->msi_enabled)
ape->table_virt->desc[n].w0 |= cpu_to_le32(1UL << 16)/*local MSI*/;
#endif
#if 0
/* dump descriptor table for debugging */
printk(KERN_DEBUG "Descriptor Table (Read, in Root Complex Memory, # = %d)\n", n + 1);
for (i = 0; i < 4 + (n + 1) * 4; i += 4) {
u32 *p = (u32 *)ape->table_virt;
p += i;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (LEN=0x%x)\n", (u32)p, (u32)p & 15, *p, 4 * le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (EPA=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (RCH=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (RCL=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
}
#endif
/* set available number of descriptors in table */
w = (u32)(n + 1);
w |= (1UL << 18)/*global EPLAST_EN*/;
#if 0
if (ape->msi_enabled)
w |= (1UL << 17)/*global MSI*/;
#endif
printk(KERN_DEBUG "writing 0x%08x to 0x%p\n", w, (void *)&read_header->w0);
iowrite32(w, &read_header->w0);
/* write table address (higher 32-bits) */
printk(KERN_DEBUG "writing 0x%08x to 0x%p\n", (u32)((ape->table_bus >> 16) >> 16), (void *)&read_header->bdt_addr_h);
iowrite32(pci_dma_h(ape->table_bus), &read_header->bdt_addr_h);
/* write table address (lower 32-bits) */
printk(KERN_DEBUG "writing 0x%08x to 0x%p\n", (u32)(ape->table_bus & 0xffffffffUL), (void *)&read_header->bdt_addr_l);
iowrite32(pci_dma_l(ape->table_bus), &read_header->bdt_addr_l);
/* memory write barrier */
wmb();
printk(KERN_DEBUG "Flush posted writes\n");
/** FIXME Add dummy read to flush posted writes but need a readable location! */
#if 0
(void)ioread32();
#endif
/* remember IRQ count before the transfer */
irq_count = ape->irq_count;
/* write number of descriptors - this starts the DMA */
printk(KERN_DEBUG "\nStart DMA read\n");
printk(KERN_DEBUG "writing 0x%08x to 0x%p\n", (u32)n, (void *)&read_header->w3);
iowrite32(n, &read_header->w3);
printk(KERN_DEBUG "EPLAST = %lu\n", le32_to_cpu(*(u32 *)&ape->table_virt->w3) & 0xffffUL);
/** memory write barrier */
wmb();
/* dummy read to flush posted writes */
/* FIXME Need a readable location! */
#if 0
(void)ioread32();
#endif
printk(KERN_DEBUG "POLL FOR READ:\n");
/* poll for chain completion, 1000 times 1 millisecond */
for (i = 0; i < 100; i++) {
volatile u32 *p = &ape->table_virt->w3;
u32 eplast = le32_to_cpu(*p) & 0xffffUL;
printk(KERN_DEBUG "EPLAST = %u, n = %d\n", eplast, n);
if (eplast == n) {
printk(KERN_DEBUG "DONE\n");
/* print IRQ count before the transfer */
printk(KERN_DEBUG "#IRQs during transfer: %d\n", ape->irq_count - irq_count);
break;
}
udelay(100);
}
/* invalidate EPLAST, outside 0-255, 0xFADE is from the testbench */
ape->table_virt->w3 = cpu_to_le32(0x0000FADE);
/* setup first descriptor */
n = 0;
ape_chdma_desc_set(&ape->table_virt->desc[n], buffer_bus + 8192, 4096, 2 * PAGE_SIZE);
#if 1
for (i = 0; i < 255; i++)
ape_chdma_desc_set(&ape->table_virt->desc[i], buffer_bus + 8192, 4096, 2 * PAGE_SIZE);
/* index of last descriptor */
n = i - 1;
#endif
#if 1 /* test variable, make a module option later */
if (ape->msi_enabled)
ape->table_virt->desc[n].w0 |= cpu_to_le32(1UL << 16)/*local MSI*/;
#endif
#if 0
/* dump descriptor table for debugging */
printk(KERN_DEBUG "Descriptor Table (Write, in Root Complex Memory, # = %d)\n", n + 1);
for (i = 0; i < 4 + (n + 1) * 4; i += 4) {
u32 *p = (u32 *)ape->table_virt;
p += i;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (LEN=0x%x)\n", (u32)p, (u32)p & 15, *p, 4 * le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (EPA=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (RCH=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
p++;
printk(KERN_DEBUG "0x%08x/0x%02x: 0x%08x (RCL=0x%x)\n", (u32)p, (u32)p & 15, *p, le32_to_cpu(*p));
}
#endif
/* set number of available descriptors in the table */
w = (u32)(n + 1);
/* enable updates of eplast for each descriptor completion */
w |= (u32)(1UL << 18)/*global EPLAST_EN*/;
#if 0 /* test variable, make a module option later */
/* enable MSI for each descriptor completion */
if (ape->msi_enabled)
w |= (1UL << 17)/*global MSI*/;
#endif
iowrite32(w, &write_header->w0);
iowrite32(pci_dma_h(ape->table_bus), &write_header->bdt_addr_h);
iowrite32(pci_dma_l(ape->table_bus), &write_header->bdt_addr_l);
/** memory write barrier and flush posted writes */
wmb();
/* dummy read to flush posted writes */
/* FIXME Need a readable location! */
#if 0
(void)ioread32();
#endif
irq_count = ape->irq_count;
printk(KERN_DEBUG "\nStart DMA write\n");
iowrite32(n, &write_header->w3);
/** memory write barrier */
wmb();
/** dummy read to flush posted writes */
/* (void) ioread32(); */
printk(KERN_DEBUG "POLL FOR WRITE:\n");
/* poll for completion, 1000 times 1 millisecond */
for (i = 0; i < 100; i++) {
volatile u32 *p = &ape->table_virt->w3;
u32 eplast = le32_to_cpu(*p) & 0xffffUL;
printk(KERN_DEBUG "EPLAST = %u, n = %d\n", eplast, n);
if (eplast == n) {
printk(KERN_DEBUG "DONE\n");
/* print IRQ count before the transfer */
printk(KERN_DEBUG "#IRQs during transfer: %d\n", ape->irq_count - irq_count);
break;
}
udelay(100);
}
/* soft-reset DMA write engine */
iowrite32(0x0000ffffUL, &write_header->w0);
/* soft-reset DMA read engine */
iowrite32(0x0000ffffUL, &read_header->w0);
/** memory write barrier */
wmb();
/* dummy read to flush posted writes */
/* FIXME Need a readable location! */
#if 0
(void)ioread32();
#endif
/* compare first half of buffer with second half, should be identical */
result = compare((u32 *)buffer_virt, (u32 *)(buffer_virt + 2 * PAGE_SIZE), 8192);
printk(KERN_DEBUG "DMA loop back test %s.\n", result ? "FAILED" : "PASSED");
pci_free_consistent(dev, 4 * PAGE_SIZE, buffer_virt, buffer_bus);
fail:
printk(KERN_DEBUG "bar_tests() end, result %d\n", result);
return result;
}
/* Called when the PCI sub system thinks we can control the given device.
* Inspect if we can support the device and if so take control of it.
*
* Return 0 when we have taken control of the given device.
*
* - allocate board specific bookkeeping
* - allocate coherently-mapped memory for the descriptor table
* - enable the board
* - verify board revision
* - request regions
* - query DMA mask
* - obtain and request irq
* - map regions into kernel address space
*/
static int __devinit probe(struct pci_dev *dev, const struct pci_device_id *id)
{
int rc = 0;
struct ape_dev *ape = NULL;
u8 irq_pin, irq_line;
printk(KERN_DEBUG "probe(dev = 0x%p, pciid = 0x%p)\n", dev, id);
/* allocate memory for per-board book keeping */
ape = kzalloc(sizeof(struct ape_dev), GFP_KERNEL);
if (!ape) {
printk(KERN_DEBUG "Could not kzalloc()ate memory.\n");
goto err_ape;
}
ape->pci_dev = dev;
dev_set_drvdata(&dev->dev, ape);
printk(KERN_DEBUG "probe() ape = 0x%p\n", ape);
printk(KERN_DEBUG "sizeof(struct ape_chdma_table) = %d.\n",
(int)sizeof(struct ape_chdma_table));
/* the reference design has a size restriction on the table size */
BUG_ON(sizeof(struct ape_chdma_table) > APE_CHDMA_TABLE_SIZE);
/* allocate and map coherently-cached memory for a descriptor table */
/* @see LDD3 page 446 */
ape->table_virt = (struct ape_chdma_table *)pci_alloc_consistent(dev,
APE_CHDMA_TABLE_SIZE, &ape->table_bus);
/* could not allocate table? */
if (!ape->table_virt) {
printk(KERN_DEBUG "Could not dma_alloc()ate_coherent memory.\n");
goto err_table;
}
printk(KERN_DEBUG "table_virt = %p, table_bus = 0x%16llx.\n",
ape->table_virt, (u64)ape->table_bus);
/* enable device */
rc = pci_enable_device(dev);
if (rc) {
printk(KERN_DEBUG "pci_enable_device() failed\n");
goto err_enable;
}
/* enable bus master capability on device */
pci_set_master(dev);
/* enable message signaled interrupts */
rc = pci_enable_msi(dev);
/* could not use MSI? */
if (rc) {
/* resort to legacy interrupts */
printk(KERN_DEBUG "Could not enable MSI interrupting.\n");
ape->msi_enabled = 0;
/* MSI enabled, remember for cleanup */
} else {
printk(KERN_DEBUG "Enabled MSI interrupting.\n");
ape->msi_enabled = 1;
}
pci_read_config_byte(dev, PCI_REVISION_ID, &ape->revision);
#if 0 /* example */
/* (for example) this driver does not support revision 0x42 */
if (ape->revision == 0x42) {
printk(KERN_DEBUG "Revision 0x42 is not supported by this driver.\n");
rc = -ENODEV;
goto err_rev;
}
#endif
/** XXX check for native or legacy PCIe endpoint? */
rc = pci_request_regions(dev, DRV_NAME);
/* could not request all regions? */
if (rc) {
/* assume device is in use (and do not disable it later!) */
ape->in_use = 1;
goto err_regions;
}
ape->got_regions = 1;
#if 1 /* @todo For now, disable 64-bit, because I do not understand the implications (DAC!) */
/* query for DMA transfer */
/* @see Documentation/PCI/PCI-DMA-mapping.txt */
if (!pci_set_dma_mask(dev, DMA_BIT_MASK(64))) {
pci_set_consistent_dma_mask(dev, DMA_BIT_MASK(64));
/* use 64-bit DMA */
printk(KERN_DEBUG "Using a 64-bit DMA mask.\n");
} else
#endif
if (!pci_set_dma_mask(dev, DMA_BIT_MASK(32))) {
printk(KERN_DEBUG "Could not set 64-bit DMA mask.\n");
pci_set_consistent_dma_mask(dev, DMA_BIT_MASK(32));
/* use 32-bit DMA */
printk(KERN_DEBUG "Using a 32-bit DMA mask.\n");
} else {
printk(KERN_DEBUG "No suitable DMA possible.\n");
/** @todo Choose proper error return code */
rc = -1;
goto err_mask;
}
rc = pci_read_config_byte(dev, PCI_INTERRUPT_PIN, &irq_pin);
/* could not read? */
if (rc)
goto err_irq;
printk(KERN_DEBUG "IRQ pin #%d (0=none, 1=INTA#...4=INTD#).\n", irq_pin);
/* @see LDD3, page 318 */
rc = pci_read_config_byte(dev, PCI_INTERRUPT_LINE, &irq_line);
/* could not read? */
if (rc) {
printk(KERN_DEBUG "Could not query PCI_INTERRUPT_LINE, error %d\n", rc);
goto err_irq;
}
printk(KERN_DEBUG "IRQ line #%d.\n", irq_line);
#if 1
irq_line = dev->irq;
/* @see LDD3, page 259 */
rc = request_irq(irq_line, altpciechdma_isr, IRQF_SHARED, DRV_NAME, (void *)ape);
if (rc) {
printk(KERN_DEBUG "Could not request IRQ #%d, error %d\n", irq_line, rc);
ape->irq_line = -1;
goto err_irq;
}
/* remember which irq we allocated */
ape->irq_line = (int)irq_line;
printk(KERN_DEBUG "Succesfully requested IRQ #%d with dev_id 0x%p\n", irq_line, ape);
#endif
/* show BARs */
scan_bars(ape, dev);
/* map BARs */
rc = map_bars(ape, dev);
if (rc)
goto err_map;
#if ALTPCIECHDMA_CDEV
/* initialize character device */
rc = sg_init(ape);
if (rc)
goto err_cdev;
#endif
/* perform DMA engines loop back test */
rc = dma_test(ape, dev);
(void)rc;
/* successfully took the device */
rc = 0;
printk(KERN_DEBUG "probe() successful.\n");
goto end;
#if ALTPCIECHDMA_CDEV
err_cdev:
/* unmap the BARs */
unmap_bars(ape, dev);
#endif
err_map:
/* free allocated irq */
if (ape->irq_line >= 0)
free_irq(ape->irq_line, (void *)ape);
err_irq:
if (ape->msi_enabled)
pci_disable_msi(dev);
/* disable the device iff it is not in use */
if (!ape->in_use)
pci_disable_device(dev);
if (ape->got_regions)
pci_release_regions(dev);
err_mask:
err_regions:
/*err_rev:*/
/* clean up everything before device enable() */
err_enable:
if (ape->table_virt)
pci_free_consistent(dev, APE_CHDMA_TABLE_SIZE, ape->table_virt, ape->table_bus);
/* clean up everything before allocating descriptor table */
err_table:
if (ape)
kfree(ape);
err_ape:
end:
return rc;
}
static void __devexit remove(struct pci_dev *dev)
{
struct ape_dev *ape = dev_get_drvdata(&dev->dev);
printk(KERN_DEBUG "remove(0x%p)\n", dev);
printk(KERN_DEBUG "remove(dev = 0x%p) where ape = 0x%p\n", dev, ape);
/* remove character device */
#if ALTPCIECHDMA_CDEV
sg_exit(ape);
#endif
if (ape->table_virt)
pci_free_consistent(dev, APE_CHDMA_TABLE_SIZE, ape->table_virt, ape->table_bus);
/* free IRQ
* @see LDD3 page 279
*/
if (ape->irq_line >= 0) {
printk(KERN_DEBUG "Freeing IRQ #%d for dev_id 0x%08lx.\n",
ape->irq_line, (unsigned long)ape);
free_irq(ape->irq_line, (void *)ape);
}
/* MSI was enabled? */
if (ape->msi_enabled) {
/* Disable MSI @see Documentation/MSI-HOWTO.txt */
pci_disable_msi(dev);
ape->msi_enabled = 0;
}
/* unmap the BARs */
unmap_bars(ape, dev);
if (!ape->in_use)
pci_disable_device(dev);
if (ape->got_regions)
/* to be called after device disable */
pci_release_regions(dev);
}
#if ALTPCIECHDMA_CDEV
/*
* Called when the device goes from unused to used.
*/
static int sg_open(struct inode *inode, struct file *file)
{
struct ape_dev *ape;
printk(KERN_DEBUG DRV_NAME "_open()\n");
/* pointer to containing data structure of the character device inode */
ape = container_of(inode->i_cdev, struct ape_dev, cdev);
/* create a reference to our device state in the opened file */
file->private_data = ape;
/* create virtual memory mapper */
ape->sgm = sg_create_mapper(MAX_CHDMA_SIZE);
return 0;
}
/*
* Called when the device goes from used to unused.
*/
static int sg_close(struct inode *inode, struct file *file)
{
/* fetch device specific data stored earlier during open */
struct ape_dev *ape = (struct ape_dev *)file->private_data;
printk(KERN_DEBUG DRV_NAME "_close()\n");
/* destroy virtual memory mapper */
sg_destroy_mapper(ape->sgm);
return 0;
}
static ssize_t sg_read(struct file *file, char __user *buf, size_t count, loff_t *pos)
{
/* fetch device specific data stored earlier during open */
struct ape_dev *ape = (struct ape_dev *)file->private_data;
(void)ape;
printk(KERN_DEBUG DRV_NAME "_read(buf=0x%p, count=%lld, pos=%llu)\n", buf, (s64)count, (u64)*pos);
return count;
}
/* sg_write() - Write to the device
*
* @buf userspace buffer
* @count number of bytes in the userspace buffer
*
* Iterate over the userspace buffer, taking at most 255 * PAGE_SIZE bytes for
* each DMA transfer.
* For each transfer, get the user pages, build a sglist, map, build a
* descriptor table. submit the transfer. wait for the interrupt handler
* to wake us on completion.
*/
static ssize_t sg_write(struct file *file, const char __user *buf, size_t count, loff_t *pos)
{
int hwnents, tents;
size_t transfer_len, remaining = count, done = 0;
u64 transfer_addr = (u64)buf;
/* fetch device specific data stored earlier during open */
struct ape_dev *ape = (struct ape_dev *)file->private_data;
printk(KERN_DEBUG DRV_NAME "_write(buf=0x%p, count=%lld, pos=%llu)\n",
buf, (s64)count, (u64)*pos);
/* TODO transfer boundaries at PAGE_SIZE granularity */
while (remaining > 0) {
/* limit DMA transfer size */
transfer_len = (remaining < APE_CHDMA_MAX_TRANSFER_LEN) ? remaining :
APE_CHDMA_MAX_TRANSFER_LEN;
/* get all user space buffer pages and create a scattergather list */
sgm_map_user_pages(ape->sgm, transfer_addr, transfer_len, 0/*read from userspace*/);
printk(KERN_DEBUG DRV_NAME "mapped_pages=%d\n", ape->sgm->mapped_pages);
/* map all entries in the scattergather list */
hwnents = pci_map_sg(ape->pci_dev, ape->sgm->sgl, ape->sgm->mapped_pages, DMA_TO_DEVICE);
printk(KERN_DEBUG DRV_NAME "hwnents=%d\n", hwnents);
/* build device descriptor tables and submit them to the DMA engine */
tents = ape_sg_to_chdma_table(ape->sgm->sgl, hwnents, 0, &ape->table_virt->desc[0], 4096);
printk(KERN_DEBUG DRV_NAME "tents=%d\n", hwnents);
#if 0
while (tables) {
/* TODO build table */
/* TODO submit table to the device */
/* if engine stopped and unfinished work then start engine */
}
put ourselves on wait queue
#endif
dma_unmap_sg(NULL, ape->sgm->sgl, ape->sgm->mapped_pages, DMA_TO_DEVICE);
/* dirty and free the pages */
sgm_unmap_user_pages(ape->sgm, 1/*dirtied*/);
/* book keeping */
transfer_addr += transfer_len;
remaining -= transfer_len;
done += transfer_len;
}
return done;
}
/*
* character device file operations
*/
static const struct file_operations sg_fops = {
.owner = THIS_MODULE,
.open = sg_open,
.release = sg_close,
.read = sg_read,
.write = sg_write,
};
/* sg_init() - Initialize character device
*
* XXX Should ideally be tied to the device, on device probe, not module init.
*/
static int sg_init(struct ape_dev *ape)
{
int rc;
printk(KERN_DEBUG DRV_NAME " sg_init()\n");
/* allocate a dynamically allocated character device node */
rc = alloc_chrdev_region(&ape->cdevno, 0/*requested minor*/, 1/*count*/, DRV_NAME);
/* allocation failed? */
if (rc < 0) {
printk("alloc_chrdev_region() = %d\n", rc);
goto fail_alloc;
}
/* couple the device file operations to the character device */
cdev_init(&ape->cdev, &sg_fops);
ape->cdev.owner = THIS_MODULE;
/* bring character device live */
rc = cdev_add(&ape->cdev, ape->cdevno, 1/*count*/);
if (rc < 0) {
printk("cdev_add() = %d\n", rc);
goto fail_add;
}
printk(KERN_DEBUG "altpciechdma = %d:%d\n", MAJOR(ape->cdevno), MINOR(ape->cdevno));
return 0;
fail_add:
/* free the dynamically allocated character device node */
unregister_chrdev_region(ape->cdevno, 1/*count*/);
fail_alloc:
return -1;
}
/* sg_exit() - Cleanup character device
*
* XXX Should ideally be tied to the device, on device remove, not module exit.
*/
static void sg_exit(struct ape_dev *ape)
{
printk(KERN_DEBUG DRV_NAME " sg_exit()\n");
/* remove the character device */
cdev_del(&ape->cdev);
/* free the dynamically allocated character device node */
unregister_chrdev_region(ape->cdevno, 1/*count*/);
}
#endif /* ALTPCIECHDMA_CDEV */
/* used to register the driver with the PCI kernel sub system
* @see LDD3 page 311
*/
static struct pci_driver pci_driver = {
.name = DRV_NAME,
.id_table = ids,
.probe = probe,
.remove = __devexit_p(remove),
/* resume, suspend are optional */
};
/**
* alterapciechdma_init() - Module initialization, registers devices.
*/
static int __init alterapciechdma_init(void)
{
int rc = 0;
printk(KERN_DEBUG DRV_NAME " init(), built at " __DATE__ " " __TIME__ "\n");
/* register this driver with the PCI bus driver */
rc = pci_register_driver(&pci_driver);
if (rc < 0)
return rc;
return 0;
}
/**
* alterapciechdma_init() - Module cleanup, unregisters devices.
*/
static void __exit alterapciechdma_exit(void)
{
printk(KERN_DEBUG DRV_NAME " exit(), built at " __DATE__ " " __TIME__ "\n");
/* unregister this driver from the PCI bus driver */
pci_unregister_driver(&pci_driver);
}
MODULE_LICENSE("GPL");
module_init(alterapciechdma_init);
module_exit(alterapciechdma_exit);
|