1
linux/drivers/misc/genwqe/card_utils.c
Kirill A. Shutemov 5e0a760b44 mm, treewide: rename MAX_ORDER to MAX_PAGE_ORDER
commit 23baf831a3 ("mm, treewide: redefine MAX_ORDER sanely") has
changed the definition of MAX_ORDER to be inclusive.  This has caused
issues with code that was not yet upstream and depended on the previous
definition.

To draw attention to the altered meaning of the define, rename MAX_ORDER
to MAX_PAGE_ORDER.

Link: https://lkml.kernel.org/r/20231228144704.14033-2-kirill.shutemov@linux.intel.com
Signed-off-by: Kirill A. Shutemov <kirill.shutemov@linux.intel.com>
Cc: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
2024-01-08 15:27:15 -08:00

1050 lines
27 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* IBM Accelerator Family 'GenWQE'
*
* (C) Copyright IBM Corp. 2013
*
* Author: Frank Haverkamp <haver@linux.vnet.ibm.com>
* Author: Joerg-Stephan Vogt <jsvogt@de.ibm.com>
* Author: Michael Jung <mijung@gmx.net>
* Author: Michael Ruettger <michael@ibmra.de>
*/
/*
* Miscelanous functionality used in the other GenWQE driver parts.
*/
#include <linux/kernel.h>
#include <linux/sched.h>
#include <linux/vmalloc.h>
#include <linux/page-flags.h>
#include <linux/scatterlist.h>
#include <linux/hugetlb.h>
#include <linux/iommu.h>
#include <linux/pci.h>
#include <linux/dma-mapping.h>
#include <linux/ctype.h>
#include <linux/module.h>
#include <linux/platform_device.h>
#include <linux/delay.h>
#include <linux/pgtable.h>
#include "genwqe_driver.h"
#include "card_base.h"
#include "card_ddcb.h"
/**
* __genwqe_writeq() - Write 64-bit register
* @cd: genwqe device descriptor
* @byte_offs: byte offset within BAR
* @val: 64-bit value
*
* Return: 0 if success; < 0 if error
*/
int __genwqe_writeq(struct genwqe_dev *cd, u64 byte_offs, u64 val)
{
struct pci_dev *pci_dev = cd->pci_dev;
if (cd->err_inject & GENWQE_INJECT_HARDWARE_FAILURE)
return -EIO;
if (cd->mmio == NULL)
return -EIO;
if (pci_channel_offline(pci_dev))
return -EIO;
__raw_writeq((__force u64)cpu_to_be64(val), cd->mmio + byte_offs);
return 0;
}
/**
* __genwqe_readq() - Read 64-bit register
* @cd: genwqe device descriptor
* @byte_offs: offset within BAR
*
* Return: value from register
*/
u64 __genwqe_readq(struct genwqe_dev *cd, u64 byte_offs)
{
if (cd->err_inject & GENWQE_INJECT_HARDWARE_FAILURE)
return 0xffffffffffffffffull;
if ((cd->err_inject & GENWQE_INJECT_GFIR_FATAL) &&
(byte_offs == IO_SLC_CFGREG_GFIR))
return 0x000000000000ffffull;
if ((cd->err_inject & GENWQE_INJECT_GFIR_INFO) &&
(byte_offs == IO_SLC_CFGREG_GFIR))
return 0x00000000ffff0000ull;
if (cd->mmio == NULL)
return 0xffffffffffffffffull;
return be64_to_cpu((__force __be64)__raw_readq(cd->mmio + byte_offs));
}
/**
* __genwqe_writel() - Write 32-bit register
* @cd: genwqe device descriptor
* @byte_offs: byte offset within BAR
* @val: 32-bit value
*
* Return: 0 if success; < 0 if error
*/
int __genwqe_writel(struct genwqe_dev *cd, u64 byte_offs, u32 val)
{
struct pci_dev *pci_dev = cd->pci_dev;
if (cd->err_inject & GENWQE_INJECT_HARDWARE_FAILURE)
return -EIO;
if (cd->mmio == NULL)
return -EIO;
if (pci_channel_offline(pci_dev))
return -EIO;
__raw_writel((__force u32)cpu_to_be32(val), cd->mmio + byte_offs);
return 0;
}
/**
* __genwqe_readl() - Read 32-bit register
* @cd: genwqe device descriptor
* @byte_offs: offset within BAR
*
* Return: Value from register
*/
u32 __genwqe_readl(struct genwqe_dev *cd, u64 byte_offs)
{
if (cd->err_inject & GENWQE_INJECT_HARDWARE_FAILURE)
return 0xffffffff;
if (cd->mmio == NULL)
return 0xffffffff;
return be32_to_cpu((__force __be32)__raw_readl(cd->mmio + byte_offs));
}
/**
* genwqe_read_app_id() - Extract app_id
* @cd: genwqe device descriptor
* @app_name: carrier used to pass-back name
* @len: length of data for name
*
* app_unitcfg need to be filled with valid data first
*/
int genwqe_read_app_id(struct genwqe_dev *cd, char *app_name, int len)
{
int i, j;
u32 app_id = (u32)cd->app_unitcfg;
memset(app_name, 0, len);
for (i = 0, j = 0; j < min(len, 4); j++) {
char ch = (char)((app_id >> (24 - j*8)) & 0xff);
if (ch == ' ')
continue;
app_name[i++] = isprint(ch) ? ch : 'X';
}
return i;
}
#define CRC32_POLYNOMIAL 0x20044009
static u32 crc32_tab[256]; /* crc32 lookup table */
/**
* genwqe_init_crc32() - Prepare a lookup table for fast crc32 calculations
*
* Existing kernel functions seem to use a different polynom,
* therefore we could not use them here.
*
* Genwqe's Polynomial = 0x20044009
*/
void genwqe_init_crc32(void)
{
int i, j;
u32 crc;
for (i = 0; i < 256; i++) {
crc = i << 24;
for (j = 0; j < 8; j++) {
if (crc & 0x80000000)
crc = (crc << 1) ^ CRC32_POLYNOMIAL;
else
crc = (crc << 1);
}
crc32_tab[i] = crc;
}
}
/**
* genwqe_crc32() - Generate 32-bit crc as required for DDCBs
* @buff: pointer to data buffer
* @len: length of data for calculation
* @init: initial crc (0xffffffff at start)
*
* polynomial = x^32 * + x^29 + x^18 + x^14 + x^3 + 1 (0x20044009)
*
* Example: 4 bytes 0x01 0x02 0x03 0x04 with init=0xffffffff should
* result in a crc32 of 0xf33cb7d3.
*
* The existing kernel crc functions did not cover this polynom yet.
*
* Return: crc32 checksum.
*/
u32 genwqe_crc32(u8 *buff, size_t len, u32 init)
{
int i;
u32 crc;
crc = init;
while (len--) {
i = ((crc >> 24) ^ *buff++) & 0xFF;
crc = (crc << 8) ^ crc32_tab[i];
}
return crc;
}
void *__genwqe_alloc_consistent(struct genwqe_dev *cd, size_t size,
dma_addr_t *dma_handle)
{
if (get_order(size) > MAX_PAGE_ORDER)
return NULL;
return dma_alloc_coherent(&cd->pci_dev->dev, size, dma_handle,
GFP_KERNEL);
}
void __genwqe_free_consistent(struct genwqe_dev *cd, size_t size,
void *vaddr, dma_addr_t dma_handle)
{
if (vaddr == NULL)
return;
dma_free_coherent(&cd->pci_dev->dev, size, vaddr, dma_handle);
}
static void genwqe_unmap_pages(struct genwqe_dev *cd, dma_addr_t *dma_list,
int num_pages)
{
int i;
struct pci_dev *pci_dev = cd->pci_dev;
for (i = 0; (i < num_pages) && (dma_list[i] != 0x0); i++) {
dma_unmap_page(&pci_dev->dev, dma_list[i], PAGE_SIZE,
DMA_BIDIRECTIONAL);
dma_list[i] = 0x0;
}
}
static int genwqe_map_pages(struct genwqe_dev *cd,
struct page **page_list, int num_pages,
dma_addr_t *dma_list)
{
int i;
struct pci_dev *pci_dev = cd->pci_dev;
/* establish DMA mapping for requested pages */
for (i = 0; i < num_pages; i++) {
dma_addr_t daddr;
dma_list[i] = 0x0;
daddr = dma_map_page(&pci_dev->dev, page_list[i],
0, /* map_offs */
PAGE_SIZE,
DMA_BIDIRECTIONAL); /* FIXME rd/rw */
if (dma_mapping_error(&pci_dev->dev, daddr)) {
dev_err(&pci_dev->dev,
"[%s] err: no dma addr daddr=%016llx!\n",
__func__, (long long)daddr);
goto err;
}
dma_list[i] = daddr;
}
return 0;
err:
genwqe_unmap_pages(cd, dma_list, num_pages);
return -EIO;
}
static int genwqe_sgl_size(int num_pages)
{
int len, num_tlb = num_pages / 7;
len = sizeof(struct sg_entry) * (num_pages+num_tlb + 1);
return roundup(len, PAGE_SIZE);
}
/*
* genwqe_alloc_sync_sgl() - Allocate memory for sgl and overlapping pages
*
* Allocates memory for sgl and overlapping pages. Pages which might
* overlap other user-space memory blocks are being cached for DMAs,
* such that we do not run into syncronization issues. Data is copied
* from user-space into the cached pages.
*/
int genwqe_alloc_sync_sgl(struct genwqe_dev *cd, struct genwqe_sgl *sgl,
void __user *user_addr, size_t user_size, int write)
{
int ret = -ENOMEM;
struct pci_dev *pci_dev = cd->pci_dev;
sgl->fpage_offs = offset_in_page((unsigned long)user_addr);
sgl->fpage_size = min_t(size_t, PAGE_SIZE-sgl->fpage_offs, user_size);
sgl->nr_pages = DIV_ROUND_UP(sgl->fpage_offs + user_size, PAGE_SIZE);
sgl->lpage_size = (user_size - sgl->fpage_size) % PAGE_SIZE;
dev_dbg(&pci_dev->dev, "[%s] uaddr=%p usize=%8ld nr_pages=%ld fpage_offs=%lx fpage_size=%ld lpage_size=%ld\n",
__func__, user_addr, user_size, sgl->nr_pages,
sgl->fpage_offs, sgl->fpage_size, sgl->lpage_size);
sgl->user_addr = user_addr;
sgl->user_size = user_size;
sgl->write = write;
sgl->sgl_size = genwqe_sgl_size(sgl->nr_pages);
if (get_order(sgl->sgl_size) > MAX_PAGE_ORDER) {
dev_err(&pci_dev->dev,
"[%s] err: too much memory requested!\n", __func__);
return ret;
}
sgl->sgl = __genwqe_alloc_consistent(cd, sgl->sgl_size,
&sgl->sgl_dma_addr);
if (sgl->sgl == NULL) {
dev_err(&pci_dev->dev,
"[%s] err: no memory available!\n", __func__);
return ret;
}
/* Only use buffering on incomplete pages */
if ((sgl->fpage_size != 0) && (sgl->fpage_size != PAGE_SIZE)) {
sgl->fpage = __genwqe_alloc_consistent(cd, PAGE_SIZE,
&sgl->fpage_dma_addr);
if (sgl->fpage == NULL)
goto err_out;
/* Sync with user memory */
if (copy_from_user(sgl->fpage + sgl->fpage_offs,
user_addr, sgl->fpage_size)) {
ret = -EFAULT;
goto err_out;
}
}
if (sgl->lpage_size != 0) {
sgl->lpage = __genwqe_alloc_consistent(cd, PAGE_SIZE,
&sgl->lpage_dma_addr);
if (sgl->lpage == NULL)
goto err_out1;
/* Sync with user memory */
if (copy_from_user(sgl->lpage, user_addr + user_size -
sgl->lpage_size, sgl->lpage_size)) {
ret = -EFAULT;
goto err_out2;
}
}
return 0;
err_out2:
__genwqe_free_consistent(cd, PAGE_SIZE, sgl->lpage,
sgl->lpage_dma_addr);
sgl->lpage = NULL;
sgl->lpage_dma_addr = 0;
err_out1:
__genwqe_free_consistent(cd, PAGE_SIZE, sgl->fpage,
sgl->fpage_dma_addr);
sgl->fpage = NULL;
sgl->fpage_dma_addr = 0;
err_out:
__genwqe_free_consistent(cd, sgl->sgl_size, sgl->sgl,
sgl->sgl_dma_addr);
sgl->sgl = NULL;
sgl->sgl_dma_addr = 0;
sgl->sgl_size = 0;
return ret;
}
int genwqe_setup_sgl(struct genwqe_dev *cd, struct genwqe_sgl *sgl,
dma_addr_t *dma_list)
{
int i = 0, j = 0, p;
unsigned long dma_offs, map_offs;
dma_addr_t prev_daddr = 0;
struct sg_entry *s, *last_s = NULL;
size_t size = sgl->user_size;
dma_offs = 128; /* next block if needed/dma_offset */
map_offs = sgl->fpage_offs; /* offset in first page */
s = &sgl->sgl[0]; /* first set of 8 entries */
p = 0; /* page */
while (p < sgl->nr_pages) {
dma_addr_t daddr;
unsigned int size_to_map;
/* always write the chaining entry, cleanup is done later */
j = 0;
s[j].target_addr = cpu_to_be64(sgl->sgl_dma_addr + dma_offs);
s[j].len = cpu_to_be32(128);
s[j].flags = cpu_to_be32(SG_CHAINED);
j++;
while (j < 8) {
/* DMA mapping for requested page, offs, size */
size_to_map = min(size, PAGE_SIZE - map_offs);
if ((p == 0) && (sgl->fpage != NULL)) {
daddr = sgl->fpage_dma_addr + map_offs;
} else if ((p == sgl->nr_pages - 1) &&
(sgl->lpage != NULL)) {
daddr = sgl->lpage_dma_addr;
} else {
daddr = dma_list[p] + map_offs;
}
size -= size_to_map;
map_offs = 0;
if (prev_daddr == daddr) {
u32 prev_len = be32_to_cpu(last_s->len);
/* pr_info("daddr combining: "
"%016llx/%08x -> %016llx\n",
prev_daddr, prev_len, daddr); */
last_s->len = cpu_to_be32(prev_len +
size_to_map);
p++; /* process next page */
if (p == sgl->nr_pages)
goto fixup; /* nothing to do */
prev_daddr = daddr + size_to_map;
continue;
}
/* start new entry */
s[j].target_addr = cpu_to_be64(daddr);
s[j].len = cpu_to_be32(size_to_map);
s[j].flags = cpu_to_be32(SG_DATA);
prev_daddr = daddr + size_to_map;
last_s = &s[j];
j++;
p++; /* process next page */
if (p == sgl->nr_pages)
goto fixup; /* nothing to do */
}
dma_offs += 128;
s += 8; /* continue 8 elements further */
}
fixup:
if (j == 1) { /* combining happened on last entry! */
s -= 8; /* full shift needed on previous sgl block */
j = 7; /* shift all elements */
}
for (i = 0; i < j; i++) /* move elements 1 up */
s[i] = s[i + 1];
s[i].target_addr = cpu_to_be64(0);
s[i].len = cpu_to_be32(0);
s[i].flags = cpu_to_be32(SG_END_LIST);
return 0;
}
/**
* genwqe_free_sync_sgl() - Free memory for sgl and overlapping pages
* @cd: genwqe device descriptor
* @sgl: scatter gather list describing user-space memory
*
* After the DMA transfer has been completed we free the memory for
* the sgl and the cached pages. Data is being transferred from cached
* pages into user-space buffers.
*/
int genwqe_free_sync_sgl(struct genwqe_dev *cd, struct genwqe_sgl *sgl)
{
int rc = 0;
size_t offset;
unsigned long res;
struct pci_dev *pci_dev = cd->pci_dev;
if (sgl->fpage) {
if (sgl->write) {
res = copy_to_user(sgl->user_addr,
sgl->fpage + sgl->fpage_offs, sgl->fpage_size);
if (res) {
dev_err(&pci_dev->dev,
"[%s] err: copying fpage! (res=%lu)\n",
__func__, res);
rc = -EFAULT;
}
}
__genwqe_free_consistent(cd, PAGE_SIZE, sgl->fpage,
sgl->fpage_dma_addr);
sgl->fpage = NULL;
sgl->fpage_dma_addr = 0;
}
if (sgl->lpage) {
if (sgl->write) {
offset = sgl->user_size - sgl->lpage_size;
res = copy_to_user(sgl->user_addr + offset, sgl->lpage,
sgl->lpage_size);
if (res) {
dev_err(&pci_dev->dev,
"[%s] err: copying lpage! (res=%lu)\n",
__func__, res);
rc = -EFAULT;
}
}
__genwqe_free_consistent(cd, PAGE_SIZE, sgl->lpage,
sgl->lpage_dma_addr);
sgl->lpage = NULL;
sgl->lpage_dma_addr = 0;
}
__genwqe_free_consistent(cd, sgl->sgl_size, sgl->sgl,
sgl->sgl_dma_addr);
sgl->sgl = NULL;
sgl->sgl_dma_addr = 0x0;
sgl->sgl_size = 0;
return rc;
}
/**
* genwqe_user_vmap() - Map user-space memory to virtual kernel memory
* @cd: pointer to genwqe device
* @m: mapping params
* @uaddr: user virtual address
* @size: size of memory to be mapped
*
* We need to think about how we could speed this up. Of course it is
* not a good idea to do this over and over again, like we are
* currently doing it. Nevertheless, I am curious where on the path
* the performance is spend. Most probably within the memory
* allocation functions, but maybe also in the DMA mapping code.
*
* Restrictions: The maximum size of the possible mapping currently depends
* on the amount of memory we can get using kzalloc() for the
* page_list and pci_alloc_consistent for the sg_list.
* The sg_list is currently itself not scattered, which could
* be fixed with some effort. The page_list must be split into
* PAGE_SIZE chunks too. All that will make the complicated
* code more complicated.
*
* Return: 0 if success
*/
int genwqe_user_vmap(struct genwqe_dev *cd, struct dma_mapping *m, void *uaddr,
unsigned long size)
{
int rc = -EINVAL;
unsigned long data, offs;
struct pci_dev *pci_dev = cd->pci_dev;
if ((uaddr == NULL) || (size == 0)) {
m->size = 0; /* mark unused and not added */
return -EINVAL;
}
m->u_vaddr = uaddr;
m->size = size;
/* determine space needed for page_list. */
data = (unsigned long)uaddr;
offs = offset_in_page(data);
if (size > ULONG_MAX - PAGE_SIZE - offs) {
m->size = 0; /* mark unused and not added */
return -EINVAL;
}
m->nr_pages = DIV_ROUND_UP(offs + size, PAGE_SIZE);
m->page_list = kcalloc(m->nr_pages,
sizeof(struct page *) + sizeof(dma_addr_t),
GFP_KERNEL);
if (!m->page_list) {
dev_err(&pci_dev->dev, "err: alloc page_list failed\n");
m->nr_pages = 0;
m->u_vaddr = NULL;
m->size = 0; /* mark unused and not added */
return -ENOMEM;
}
m->dma_list = (dma_addr_t *)(m->page_list + m->nr_pages);
/* pin user pages in memory */
rc = pin_user_pages_fast(data & PAGE_MASK, /* page aligned addr */
m->nr_pages,
m->write ? FOLL_WRITE : 0, /* readable/writable */
m->page_list); /* ptrs to pages */
if (rc < 0)
goto fail_pin_user_pages;
/* assumption: pin_user_pages can be killed by signals. */
if (rc < m->nr_pages) {
unpin_user_pages_dirty_lock(m->page_list, rc, m->write);
rc = -EFAULT;
goto fail_pin_user_pages;
}
rc = genwqe_map_pages(cd, m->page_list, m->nr_pages, m->dma_list);
if (rc != 0)
goto fail_free_user_pages;
return 0;
fail_free_user_pages:
unpin_user_pages_dirty_lock(m->page_list, m->nr_pages, m->write);
fail_pin_user_pages:
kfree(m->page_list);
m->page_list = NULL;
m->dma_list = NULL;
m->nr_pages = 0;
m->u_vaddr = NULL;
m->size = 0; /* mark unused and not added */
return rc;
}
/**
* genwqe_user_vunmap() - Undo mapping of user-space mem to virtual kernel
* memory
* @cd: pointer to genwqe device
* @m: mapping params
*/
int genwqe_user_vunmap(struct genwqe_dev *cd, struct dma_mapping *m)
{
struct pci_dev *pci_dev = cd->pci_dev;
if (!dma_mapping_used(m)) {
dev_err(&pci_dev->dev, "[%s] err: mapping %p not used!\n",
__func__, m);
return -EINVAL;
}
if (m->dma_list)
genwqe_unmap_pages(cd, m->dma_list, m->nr_pages);
if (m->page_list) {
unpin_user_pages_dirty_lock(m->page_list, m->nr_pages,
m->write);
kfree(m->page_list);
m->page_list = NULL;
m->dma_list = NULL;
m->nr_pages = 0;
}
m->u_vaddr = NULL;
m->size = 0; /* mark as unused and not added */
return 0;
}
/**
* genwqe_card_type() - Get chip type SLU Configuration Register
* @cd: pointer to the genwqe device descriptor
* Return: 0: Altera Stratix-IV 230
* 1: Altera Stratix-IV 530
* 2: Altera Stratix-V A4
* 3: Altera Stratix-V A7
*/
u8 genwqe_card_type(struct genwqe_dev *cd)
{
u64 card_type = cd->slu_unitcfg;
return (u8)((card_type & IO_SLU_UNITCFG_TYPE_MASK) >> 20);
}
/**
* genwqe_card_reset() - Reset the card
* @cd: pointer to the genwqe device descriptor
*/
int genwqe_card_reset(struct genwqe_dev *cd)
{
u64 softrst;
struct pci_dev *pci_dev = cd->pci_dev;
if (!genwqe_is_privileged(cd))
return -ENODEV;
/* new SL */
__genwqe_writeq(cd, IO_SLC_CFGREG_SOFTRESET, 0x1ull);
msleep(1000);
__genwqe_readq(cd, IO_HSU_FIR_CLR);
__genwqe_readq(cd, IO_APP_FIR_CLR);
__genwqe_readq(cd, IO_SLU_FIR_CLR);
/*
* Read-modify-write to preserve the stealth bits
*
* For SL >= 039, Stealth WE bit allows removing
* the read-modify-wrote.
* r-m-w may require a mask 0x3C to avoid hitting hard
* reset again for error reset (should be 0, chicken).
*/
softrst = __genwqe_readq(cd, IO_SLC_CFGREG_SOFTRESET) & 0x3cull;
__genwqe_writeq(cd, IO_SLC_CFGREG_SOFTRESET, softrst | 0x2ull);
/* give ERRORRESET some time to finish */
msleep(50);
if (genwqe_need_err_masking(cd)) {
dev_info(&pci_dev->dev,
"[%s] masking errors for old bitstreams\n", __func__);
__genwqe_writeq(cd, IO_SLC_MISC_DEBUG, 0x0aull);
}
return 0;
}
int genwqe_read_softreset(struct genwqe_dev *cd)
{
u64 bitstream;
if (!genwqe_is_privileged(cd))
return -ENODEV;
bitstream = __genwqe_readq(cd, IO_SLU_BITSTREAM) & 0x1;
cd->softreset = (bitstream == 0) ? 0x8ull : 0xcull;
return 0;
}
/**
* genwqe_set_interrupt_capability() - Configure MSI capability structure
* @cd: pointer to the device
* @count: number of vectors to allocate
* Return: 0 if no error
*/
int genwqe_set_interrupt_capability(struct genwqe_dev *cd, int count)
{
int rc;
rc = pci_alloc_irq_vectors(cd->pci_dev, 1, count, PCI_IRQ_MSI);
if (rc < 0)
return rc;
return 0;
}
/**
* genwqe_reset_interrupt_capability() - Undo genwqe_set_interrupt_capability()
* @cd: pointer to the device
*/
void genwqe_reset_interrupt_capability(struct genwqe_dev *cd)
{
pci_free_irq_vectors(cd->pci_dev);
}
/**
* set_reg_idx() - Fill array with data. Ignore illegal offsets.
* @cd: card device
* @r: debug register array
* @i: index to desired entry
* @m: maximum possible entries
* @addr: addr which is read
* @idx: index in debug array
* @val: read value
*/
static int set_reg_idx(struct genwqe_dev *cd, struct genwqe_reg *r,
unsigned int *i, unsigned int m, u32 addr, u32 idx,
u64 val)
{
if (WARN_ON_ONCE(*i >= m))
return -EFAULT;
r[*i].addr = addr;
r[*i].idx = idx;
r[*i].val = val;
++*i;
return 0;
}
static int set_reg(struct genwqe_dev *cd, struct genwqe_reg *r,
unsigned int *i, unsigned int m, u32 addr, u64 val)
{
return set_reg_idx(cd, r, i, m, addr, 0, val);
}
int genwqe_read_ffdc_regs(struct genwqe_dev *cd, struct genwqe_reg *regs,
unsigned int max_regs, int all)
{
unsigned int i, j, idx = 0;
u32 ufir_addr, ufec_addr, sfir_addr, sfec_addr;
u64 gfir, sluid, appid, ufir, ufec, sfir, sfec;
/* Global FIR */
gfir = __genwqe_readq(cd, IO_SLC_CFGREG_GFIR);
set_reg(cd, regs, &idx, max_regs, IO_SLC_CFGREG_GFIR, gfir);
/* UnitCfg for SLU */
sluid = __genwqe_readq(cd, IO_SLU_UNITCFG); /* 0x00000000 */
set_reg(cd, regs, &idx, max_regs, IO_SLU_UNITCFG, sluid);
/* UnitCfg for APP */
appid = __genwqe_readq(cd, IO_APP_UNITCFG); /* 0x02000000 */
set_reg(cd, regs, &idx, max_regs, IO_APP_UNITCFG, appid);
/* Check all chip Units */
for (i = 0; i < GENWQE_MAX_UNITS; i++) {
/* Unit FIR */
ufir_addr = (i << 24) | 0x008;
ufir = __genwqe_readq(cd, ufir_addr);
set_reg(cd, regs, &idx, max_regs, ufir_addr, ufir);
/* Unit FEC */
ufec_addr = (i << 24) | 0x018;
ufec = __genwqe_readq(cd, ufec_addr);
set_reg(cd, regs, &idx, max_regs, ufec_addr, ufec);
for (j = 0; j < 64; j++) {
/* wherever there is a primary 1, read the 2ndary */
if (!all && (!(ufir & (1ull << j))))
continue;
sfir_addr = (i << 24) | (0x100 + 8 * j);
sfir = __genwqe_readq(cd, sfir_addr);
set_reg(cd, regs, &idx, max_regs, sfir_addr, sfir);
sfec_addr = (i << 24) | (0x300 + 8 * j);
sfec = __genwqe_readq(cd, sfec_addr);
set_reg(cd, regs, &idx, max_regs, sfec_addr, sfec);
}
}
/* fill with invalid data until end */
for (i = idx; i < max_regs; i++) {
regs[i].addr = 0xffffffff;
regs[i].val = 0xffffffffffffffffull;
}
return idx;
}
/**
* genwqe_ffdc_buff_size() - Calculates the number of dump registers
* @cd: genwqe device descriptor
* @uid: unit ID
*/
int genwqe_ffdc_buff_size(struct genwqe_dev *cd, int uid)
{
int entries = 0, ring, traps, traces, trace_entries;
u32 eevptr_addr, l_addr, d_len, d_type;
u64 eevptr, val, addr;
eevptr_addr = GENWQE_UID_OFFS(uid) | IO_EXTENDED_ERROR_POINTER;
eevptr = __genwqe_readq(cd, eevptr_addr);
if ((eevptr != 0x0) && (eevptr != -1ull)) {
l_addr = GENWQE_UID_OFFS(uid) | eevptr;
while (1) {
val = __genwqe_readq(cd, l_addr);
if ((val == 0x0) || (val == -1ull))
break;
/* 38:24 */
d_len = (val & 0x0000007fff000000ull) >> 24;
/* 39 */
d_type = (val & 0x0000008000000000ull) >> 36;
if (d_type) { /* repeat */
entries += d_len;
} else { /* size in bytes! */
entries += d_len >> 3;
}
l_addr += 8;
}
}
for (ring = 0; ring < 8; ring++) {
addr = GENWQE_UID_OFFS(uid) | IO_EXTENDED_DIAG_MAP(ring);
val = __genwqe_readq(cd, addr);
if ((val == 0x0ull) || (val == -1ull))
continue;
traps = (val >> 24) & 0xff;
traces = (val >> 16) & 0xff;
trace_entries = val & 0xffff;
entries += traps + (traces * trace_entries);
}
return entries;
}
/**
* genwqe_ffdc_buff_read() - Implements LogoutExtendedErrorRegisters procedure
* @cd: genwqe device descriptor
* @uid: unit ID
* @regs: register information
* @max_regs: number of register entries
*/
int genwqe_ffdc_buff_read(struct genwqe_dev *cd, int uid,
struct genwqe_reg *regs, unsigned int max_regs)
{
int i, traps, traces, trace, trace_entries, trace_entry, ring;
unsigned int idx = 0;
u32 eevptr_addr, l_addr, d_addr, d_len, d_type;
u64 eevptr, e, val, addr;
eevptr_addr = GENWQE_UID_OFFS(uid) | IO_EXTENDED_ERROR_POINTER;
eevptr = __genwqe_readq(cd, eevptr_addr);
if ((eevptr != 0x0) && (eevptr != 0xffffffffffffffffull)) {
l_addr = GENWQE_UID_OFFS(uid) | eevptr;
while (1) {
e = __genwqe_readq(cd, l_addr);
if ((e == 0x0) || (e == 0xffffffffffffffffull))
break;
d_addr = (e & 0x0000000000ffffffull); /* 23:0 */
d_len = (e & 0x0000007fff000000ull) >> 24; /* 38:24 */
d_type = (e & 0x0000008000000000ull) >> 36; /* 39 */
d_addr |= GENWQE_UID_OFFS(uid);
if (d_type) {
for (i = 0; i < (int)d_len; i++) {
val = __genwqe_readq(cd, d_addr);
set_reg_idx(cd, regs, &idx, max_regs,
d_addr, i, val);
}
} else {
d_len >>= 3; /* Size in bytes! */
for (i = 0; i < (int)d_len; i++, d_addr += 8) {
val = __genwqe_readq(cd, d_addr);
set_reg_idx(cd, regs, &idx, max_regs,
d_addr, 0, val);
}
}
l_addr += 8;
}
}
/*
* To save time, there are only 6 traces poplulated on Uid=2,
* Ring=1. each with iters=512.
*/
for (ring = 0; ring < 8; ring++) { /* 0 is fls, 1 is fds,
2...7 are ASI rings */
addr = GENWQE_UID_OFFS(uid) | IO_EXTENDED_DIAG_MAP(ring);
val = __genwqe_readq(cd, addr);
if ((val == 0x0ull) || (val == -1ull))
continue;
traps = (val >> 24) & 0xff; /* Number of Traps */
traces = (val >> 16) & 0xff; /* Number of Traces */
trace_entries = val & 0xffff; /* Entries per trace */
/* Note: This is a combined loop that dumps both the traps */
/* (for the trace == 0 case) as well as the traces 1 to */
/* 'traces'. */
for (trace = 0; trace <= traces; trace++) {
u32 diag_sel =
GENWQE_EXTENDED_DIAG_SELECTOR(ring, trace);
addr = (GENWQE_UID_OFFS(uid) |
IO_EXTENDED_DIAG_SELECTOR);
__genwqe_writeq(cd, addr, diag_sel);
for (trace_entry = 0;
trace_entry < (trace ? trace_entries : traps);
trace_entry++) {
addr = (GENWQE_UID_OFFS(uid) |
IO_EXTENDED_DIAG_READ_MBX);
val = __genwqe_readq(cd, addr);
set_reg_idx(cd, regs, &idx, max_regs, addr,
(diag_sel<<16) | trace_entry, val);
}
}
}
return 0;
}
/**
* genwqe_write_vreg() - Write register in virtual window
* @cd: genwqe device descriptor
* @reg: register (byte) offset within BAR
* @val: value to write
* @func: PCI virtual function
*
* Note, these registers are only accessible to the PF through the
* VF-window. It is not intended for the VF to access.
*/
int genwqe_write_vreg(struct genwqe_dev *cd, u32 reg, u64 val, int func)
{
__genwqe_writeq(cd, IO_PF_SLC_VIRTUAL_WINDOW, func & 0xf);
__genwqe_writeq(cd, reg, val);
return 0;
}
/**
* genwqe_read_vreg() - Read register in virtual window
* @cd: genwqe device descriptor
* @reg: register (byte) offset within BAR
* @func: PCI virtual function
*
* Note, these registers are only accessible to the PF through the
* VF-window. It is not intended for the VF to access.
*/
u64 genwqe_read_vreg(struct genwqe_dev *cd, u32 reg, int func)
{
__genwqe_writeq(cd, IO_PF_SLC_VIRTUAL_WINDOW, func & 0xf);
return __genwqe_readq(cd, reg);
}
/**
* genwqe_base_clock_frequency() - Deteremine base clock frequency of the card
* @cd: genwqe device descriptor
*
* Note: From a design perspective it turned out to be a bad idea to
* use codes here to specifiy the frequency/speed values. An old
* driver cannot understand new codes and is therefore always a
* problem. Better is to measure out the value or put the
* speed/frequency directly into a register which is always a valid
* value for old as well as for new software.
*
* Return: Card clock in MHz
*/
int genwqe_base_clock_frequency(struct genwqe_dev *cd)
{
u16 speed; /* MHz MHz MHz MHz */
static const int speed_grade[] = { 250, 200, 166, 175 };
speed = (u16)((cd->slu_unitcfg >> 28) & 0x0full);
if (speed >= ARRAY_SIZE(speed_grade))
return 0; /* illegal value */
return speed_grade[speed];
}
/**
* genwqe_stop_traps() - Stop traps
* @cd: genwqe device descriptor
*
* Before reading out the analysis data, we need to stop the traps.
*/
void genwqe_stop_traps(struct genwqe_dev *cd)
{
__genwqe_writeq(cd, IO_SLC_MISC_DEBUG_SET, 0xcull);
}
/**
* genwqe_start_traps() - Start traps
* @cd: genwqe device descriptor
*
* After having read the data, we can/must enable the traps again.
*/
void genwqe_start_traps(struct genwqe_dev *cd)
{
__genwqe_writeq(cd, IO_SLC_MISC_DEBUG_CLR, 0xcull);
if (genwqe_need_err_masking(cd))
__genwqe_writeq(cd, IO_SLC_MISC_DEBUG, 0x0aull);
}