Commit 5a4faa87 authored by Ron Mercer's avatar Ron Mercer Committed by Jeff Garzik

[PATCH] qla3xxx NIC driver

This is a complementary network driver for our ISP4XXX parts.

There is a concurrent effort underway to get the iSCSI driver (qla4xxx)
integrated upstream as well.

I have been through several iterations with the linux-netdev list and have had
much response from Stephen Hemminger.

- Built and tested using kernel 2.6.17-rc4.

- The chip supports two ethernet and two iSCSI functions.

- The functions ql_sem_lock, ql_sem_spinlock, ql_sem_unlock, and
  ql_wait_for_drvr_lock are used to protect resources that are shared across
  the network and iSCSI functions.  This protection is mostly during chip
  initialization and resets, but also include link management.

- The PHY/MII are not exported through ethtool due to the fact that the
  iSCSI function will control the common link at least 50% of the time.

This driver has been through several iterations on the netdev list and we feel
this driver is ready for inclusion in the upstream kernel.

It has been built and tested on x86 and PPC64 platforms.

Cc: Jeff Garzik <jeff@garzik.org>
Cc: Stephen Hemminger <shemminger@osdl.org>
Signed-off-by: default avatarRon Mercer <ron.mercer@qlogic.com>
Signed-off-by: default avatarAndrew Morton <akpm@osdl.org>
Signed-off-by: default avatarJeff Garzik <jeff@garzik.org>
parent 572e432e
Copyright (c) 2003-2006 QLogic Corporation
QLogic Linux Networking HBA Driver
This program includes a device driver for Linux 2.6 that may be
distributed with QLogic hardware specific firmware binary file.
You may modify and redistribute the device driver code under the
GNU General Public License as published by the Free Software
Foundation (version 2 or a later version).
You may redistribute the hardware specific firmware binary file
under the following terms:
1. Redistribution of source code (only if applicable),
must retain the above copyright notice, this list of
conditions and the following disclaimer.
2. Redistribution in binary form must reproduce the above
copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other
materials provided with the distribution.
3. The name of QLogic Corporation may not be used to
endorse or promote products derived from this software
without specific prior written permission
REGARDLESS OF WHAT LICENSING MECHANISM IS USED OR APPLICABLE,
THIS PROGRAM IS PROVIDED BY QLOGIC CORPORATION "AS IS'' AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR
BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
USER ACKNOWLEDGES AND AGREES THAT USE OF THIS PROGRAM WILL NOT
CREATE OR GIVE GROUNDS FOR A LICENSE BY IMPLICATION, ESTOPPEL, OR
OTHERWISE IN ANY INTELLECTUAL PROPERTY RIGHTS (PATENT, COPYRIGHT,
TRADE SECRET, MASK WORK, OR OTHER PROPRIETARY RIGHT) EMBODIED IN
ANY OTHER QLOGIC HARDWARE OR SOFTWARE EITHER SOLELY OR IN
COMBINATION WITH THIS PROGRAM.
......@@ -2338,6 +2338,12 @@ M: linux-driver@qlogic.com
L: linux-scsi@vger.kernel.org
S: Supported
QLOGIC QLA3XXX NETWORK DRIVER
P: Ron Mercer
M: linux-driver@qlogic.com
L: netdev@vger.kernel.org
S: Supported
QNX4 FILESYSTEM
P: Anders Larsen
M: al@alarsen.net
......
......@@ -2249,6 +2249,15 @@ config MV643XX_ETH_2
This enables support for Port 2 of the Marvell MV643XX Gigabit
Ethernet.
config QLA3XXX
tristate "QLogic QLA3XXX Network Driver Support"
depends on PCI
help
This driver supports QLogic ISP3XXX gigabit Ethernet cards.
To compile this driver as a module, choose M here: the module
will be called qla3xxx.
endmenu
#
......
......@@ -106,6 +106,7 @@ obj-$(CONFIG_FORCEDETH) += forcedeth.o
obj-$(CONFIG_NE_H8300) += ne-h8300.o 8390.o
obj-$(CONFIG_MV643XX_ETH) += mv643xx_eth.o
obj-$(CONFIG_QLA3XXX) += qla3xxx.o
obj-$(CONFIG_PPP) += ppp_generic.o
obj-$(CONFIG_PPP_ASYNC) += ppp_async.o
......
/*
* QLogic QLA3xxx NIC HBA Driver
* Copyright (c) 2003-2006 QLogic Corporation
*
* See LICENSE.qla3xxx for copyright and licensing details.
*/
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/types.h>
#include <linux/module.h>
#include <linux/list.h>
#include <linux/pci.h>
#include <linux/dma-mapping.h>
#include <linux/sched.h>
#include <linux/slab.h>
#include <linux/dmapool.h>
#include <linux/mempool.h>
#include <linux/spinlock.h>
#include <linux/kthread.h>
#include <linux/interrupt.h>
#include <linux/errno.h>
#include <linux/ioport.h>
#include <linux/ip.h>
#include <linux/if_arp.h>
#include <linux/if_ether.h>
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/ethtool.h>
#include <linux/skbuff.h>
#include <linux/rtnetlink.h>
#include <linux/if_vlan.h>
#include <linux/init.h>
#include <linux/delay.h>
#include <linux/mm.h>
#include "qla3xxx.h"
#define DRV_NAME "qla3xxx"
#define DRV_STRING "QLogic ISP3XXX Network Driver"
#define DRV_VERSION "v2.02.00-k36"
#define PFX DRV_NAME " "
static const char ql3xxx_driver_name[] = DRV_NAME;
static const char ql3xxx_driver_version[] = DRV_VERSION;
MODULE_AUTHOR("QLogic Corporation");
MODULE_DESCRIPTION("QLogic ISP3XXX Network Driver " DRV_VERSION " ");
MODULE_LICENSE("GPL");
MODULE_VERSION(DRV_VERSION);
static const u32 default_msg
= NETIF_MSG_DRV | NETIF_MSG_PROBE | NETIF_MSG_LINK
| NETIF_MSG_IFUP | NETIF_MSG_IFDOWN;
static int debug = -1; /* defaults above */
module_param(debug, int, 0);
MODULE_PARM_DESC(debug, "Debug level (0=none,...,16=all)");
static int msi;
module_param(msi, int, 0);
MODULE_PARM_DESC(msi, "Turn on Message Signaled Interrupts.");
static struct pci_device_id ql3xxx_pci_tbl[] __devinitdata = {
{PCI_DEVICE(PCI_VENDOR_ID_QLOGIC, QL3022_DEVICE_ID)},
/* required last entry */
{0,}
};
MODULE_DEVICE_TABLE(pci, ql3xxx_pci_tbl);
/*
* Caller must take hw_lock.
*/
static int ql_sem_spinlock(struct ql3_adapter *qdev,
u32 sem_mask, u32 sem_bits)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
u32 value;
unsigned int seconds = 3;
do {
writel((sem_mask | sem_bits),
&port_regs->CommonRegs.semaphoreReg);
value = readl(&port_regs->CommonRegs.semaphoreReg);
if ((value & (sem_mask >> 16)) == sem_bits)
return 0;
ssleep(1);
} while(--seconds);
return -1;
}
static void ql_sem_unlock(struct ql3_adapter *qdev, u32 sem_mask)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
writel(sem_mask, &port_regs->CommonRegs.semaphoreReg);
readl(&port_regs->CommonRegs.semaphoreReg);
}
static int ql_sem_lock(struct ql3_adapter *qdev, u32 sem_mask, u32 sem_bits)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
u32 value;
writel((sem_mask | sem_bits), &port_regs->CommonRegs.semaphoreReg);
value = readl(&port_regs->CommonRegs.semaphoreReg);
return ((value & (sem_mask >> 16)) == sem_bits);
}
/*
* Caller holds hw_lock.
*/
static int ql_wait_for_drvr_lock(struct ql3_adapter *qdev)
{
int i = 0;
while (1) {
if (!ql_sem_lock(qdev,
QL_DRVR_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index)
* 2) << 1)) {
if (i < 10) {
ssleep(1);
i++;
} else {
printk(KERN_ERR PFX "%s: Timed out waiting for "
"driver lock...\n",
qdev->ndev->name);
return 0;
}
} else {
printk(KERN_DEBUG PFX
"%s: driver lock acquired.\n",
qdev->ndev->name);
return 1;
}
}
}
static void ql_set_register_page(struct ql3_adapter *qdev, u32 page)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
writel(((ISP_CONTROL_NP_MASK << 16) | page),
&port_regs->CommonRegs.ispControlStatus);
readl(&port_regs->CommonRegs.ispControlStatus);
qdev->current_page = page;
}
static u32 ql_read_common_reg_l(struct ql3_adapter *qdev,
u32 __iomem * reg)
{
u32 value;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
value = readl(reg);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return value;
}
static u32 ql_read_common_reg(struct ql3_adapter *qdev,
u32 __iomem * reg)
{
return readl(reg);
}
static u32 ql_read_page0_reg_l(struct ql3_adapter *qdev, u32 __iomem *reg)
{
u32 value;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if (qdev->current_page != 0)
ql_set_register_page(qdev,0);
value = readl(reg);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return value;
}
static u32 ql_read_page0_reg(struct ql3_adapter *qdev, u32 __iomem *reg)
{
if (qdev->current_page != 0)
ql_set_register_page(qdev,0);
return readl(reg);
}
static void ql_write_common_reg_l(struct ql3_adapter *qdev,
u32 * reg, u32 value)
{
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
writel(value, (u32 *) reg);
readl(reg);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return;
}
static void ql_write_common_reg(struct ql3_adapter *qdev,
u32 * reg, u32 value)
{
writel(value, (u32 *) reg);
readl(reg);
return;
}
static void ql_write_page0_reg(struct ql3_adapter *qdev,
u32 * reg, u32 value)
{
if (qdev->current_page != 0)
ql_set_register_page(qdev,0);
writel(value, (u32 *) reg);
readl(reg);
return;
}
/*
* Caller holds hw_lock. Only called during init.
*/
static void ql_write_page1_reg(struct ql3_adapter *qdev,
u32 * reg, u32 value)
{
if (qdev->current_page != 1)
ql_set_register_page(qdev,1);
writel(value, (u32 *) reg);
readl(reg);
return;
}
/*
* Caller holds hw_lock. Only called during init.
*/
static void ql_write_page2_reg(struct ql3_adapter *qdev,
u32 * reg, u32 value)
{
if (qdev->current_page != 2)
ql_set_register_page(qdev,2);
writel(value, (u32 *) reg);
readl(reg);
return;
}
static void ql_disable_interrupts(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
ql_write_common_reg_l(qdev, &port_regs->CommonRegs.ispInterruptMaskReg,
(ISP_IMR_ENABLE_INT << 16));
}
static void ql_enable_interrupts(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
ql_write_common_reg_l(qdev, &port_regs->CommonRegs.ispInterruptMaskReg,
((0xff << 16) | ISP_IMR_ENABLE_INT));
}
static void ql_release_to_lrg_buf_free_list(struct ql3_adapter *qdev,
struct ql_rcv_buf_cb *lrg_buf_cb)
{
u64 map;
lrg_buf_cb->next = NULL;
if (qdev->lrg_buf_free_tail == NULL) { /* The list is empty */
qdev->lrg_buf_free_head = qdev->lrg_buf_free_tail = lrg_buf_cb;
} else {
qdev->lrg_buf_free_tail->next = lrg_buf_cb;
qdev->lrg_buf_free_tail = lrg_buf_cb;
}
if (!lrg_buf_cb->skb) {
lrg_buf_cb->skb = dev_alloc_skb(qdev->lrg_buffer_len);
if (unlikely(!lrg_buf_cb->skb)) {
printk(KERN_ERR PFX "%s: failed dev_alloc_skb().\n",
qdev->ndev->name);
qdev->lrg_buf_skb_check++;
} else {
/*
* We save some space to copy the ethhdr from first
* buffer
*/
skb_reserve(lrg_buf_cb->skb, QL_HEADER_SPACE);
map = pci_map_single(qdev->pdev,
lrg_buf_cb->skb->data,
qdev->lrg_buffer_len -
QL_HEADER_SPACE,
PCI_DMA_FROMDEVICE);
lrg_buf_cb->buf_phy_addr_low =
cpu_to_le32(LS_64BITS(map));
lrg_buf_cb->buf_phy_addr_high =
cpu_to_le32(MS_64BITS(map));
pci_unmap_addr_set(lrg_buf_cb, mapaddr, map);
pci_unmap_len_set(lrg_buf_cb, maplen,
qdev->lrg_buffer_len -
QL_HEADER_SPACE);
}
}
qdev->lrg_buf_free_count++;
}
static struct ql_rcv_buf_cb *ql_get_from_lrg_buf_free_list(struct ql3_adapter
*qdev)
{
struct ql_rcv_buf_cb *lrg_buf_cb;
if ((lrg_buf_cb = qdev->lrg_buf_free_head) != NULL) {
if ((qdev->lrg_buf_free_head = lrg_buf_cb->next) == NULL)
qdev->lrg_buf_free_tail = NULL;
qdev->lrg_buf_free_count--;
}
return lrg_buf_cb;
}
static u32 addrBits = EEPROM_NO_ADDR_BITS;
static u32 dataBits = EEPROM_NO_DATA_BITS;
static void fm93c56a_deselect(struct ql3_adapter *qdev);
static void eeprom_readword(struct ql3_adapter *qdev, u32 eepromAddr,
unsigned short *value);
/*
* Caller holds hw_lock.
*/
static void fm93c56a_select(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
qdev->eeprom_cmd_data = AUBURN_EEPROM_CS_1;
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->eeprom_cmd_data);
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
((ISP_NVRAM_MASK << 16) | qdev->eeprom_cmd_data));
}
/*
* Caller holds hw_lock.
*/
static void fm93c56a_cmd(struct ql3_adapter *qdev, u32 cmd, u32 eepromAddr)
{
int i;
u32 mask;
u32 dataBit;
u32 previousBit;
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
/* Clock in a zero, then do the start bit */
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->eeprom_cmd_data |
AUBURN_EEPROM_DO_1);
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | AUBURN_EEPROM_DO_1 |
AUBURN_EEPROM_CLK_RISE);
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | AUBURN_EEPROM_DO_1 |
AUBURN_EEPROM_CLK_FALL);
mask = 1 << (FM93C56A_CMD_BITS - 1);
/* Force the previous data bit to be different */
previousBit = 0xffff;
for (i = 0; i < FM93C56A_CMD_BITS; i++) {
dataBit =
(cmd & mask) ? AUBURN_EEPROM_DO_1 : AUBURN_EEPROM_DO_0;
if (previousBit != dataBit) {
/*
* If the bit changed, then change the DO state to
* match
*/
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit);
previousBit = dataBit;
}
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit |
AUBURN_EEPROM_CLK_RISE);
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit |
AUBURN_EEPROM_CLK_FALL);
cmd = cmd << 1;
}
mask = 1 << (addrBits - 1);
/* Force the previous data bit to be different */
previousBit = 0xffff;
for (i = 0; i < addrBits; i++) {
dataBit =
(eepromAddr & mask) ? AUBURN_EEPROM_DO_1 :
AUBURN_EEPROM_DO_0;
if (previousBit != dataBit) {
/*
* If the bit changed, then change the DO state to
* match
*/
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit);
previousBit = dataBit;
}
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit |
AUBURN_EEPROM_CLK_RISE);
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->
eeprom_cmd_data | dataBit |
AUBURN_EEPROM_CLK_FALL);
eepromAddr = eepromAddr << 1;
}
}
/*
* Caller holds hw_lock.
*/
static void fm93c56a_deselect(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
qdev->eeprom_cmd_data = AUBURN_EEPROM_CS_0;
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->eeprom_cmd_data);
}
/*
* Caller holds hw_lock.
*/
static void fm93c56a_datain(struct ql3_adapter *qdev, unsigned short *value)
{
int i;
u32 data = 0;
u32 dataBit;
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
/* Read the data bits */
/* The first bit is a dummy. Clock right over it. */
for (i = 0; i < dataBits; i++) {
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->eeprom_cmd_data |
AUBURN_EEPROM_CLK_RISE);
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg,
ISP_NVRAM_MASK | qdev->eeprom_cmd_data |
AUBURN_EEPROM_CLK_FALL);
dataBit =
(ql_read_common_reg
(qdev,
&port_regs->CommonRegs.
serialPortInterfaceReg) & AUBURN_EEPROM_DI_1) ? 1 : 0;
data = (data << 1) | dataBit;
}
*value = (u16) data;
}
/*
* Caller holds hw_lock.
*/
static void eeprom_readword(struct ql3_adapter *qdev,
u32 eepromAddr, unsigned short *value)
{
fm93c56a_select(qdev);
fm93c56a_cmd(qdev, (int)FM93C56A_READ, eepromAddr);
fm93c56a_datain(qdev, value);
fm93c56a_deselect(qdev);
}
static void ql_swap_mac_addr(u8 * macAddress)
{
#ifdef __BIG_ENDIAN
u8 temp;
temp = macAddress[0];
macAddress[0] = macAddress[1];
macAddress[1] = temp;
temp = macAddress[2];
macAddress[2] = macAddress[3];
macAddress[3] = temp;
temp = macAddress[4];
macAddress[4] = macAddress[5];
macAddress[5] = temp;
#endif
}
static int ql_get_nvram_params(struct ql3_adapter *qdev)
{
u16 *pEEPROMData;
u16 checksum = 0;
u32 index;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
pEEPROMData = (u16 *) & qdev->nvram_data;
qdev->eeprom_cmd_data = 0;
if(ql_sem_spinlock(qdev, QL_NVRAM_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 10)) {
printk(KERN_ERR PFX"%s: Failed ql_sem_spinlock().\n",
__func__);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return -1;
}
for (index = 0; index < EEPROM_SIZE; index++) {
eeprom_readword(qdev, index, pEEPROMData);
checksum += *pEEPROMData;
pEEPROMData++;
}
ql_sem_unlock(qdev, QL_NVRAM_SEM_MASK);
if (checksum != 0) {
printk(KERN_ERR PFX "%s: checksum should be zero, is %x!!\n",
qdev->ndev->name, checksum);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return -1;
}
/*
* We have a problem with endianness for the MAC addresses
* and the two 8-bit values version, and numPorts. We
* have to swap them on big endian systems.
*/
ql_swap_mac_addr(qdev->nvram_data.funcCfg_fn0.macAddress);
ql_swap_mac_addr(qdev->nvram_data.funcCfg_fn1.macAddress);
ql_swap_mac_addr(qdev->nvram_data.funcCfg_fn2.macAddress);
ql_swap_mac_addr(qdev->nvram_data.funcCfg_fn3.macAddress);
pEEPROMData = (u16 *) & qdev->nvram_data.version;
*pEEPROMData = le16_to_cpu(*pEEPROMData);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return checksum;
}
static const u32 PHYAddr[2] = {
PORT0_PHY_ADDRESS, PORT1_PHY_ADDRESS
};
static int ql_wait_for_mii_ready(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 temp;
int count = 1000;
while (count) {
temp = ql_read_page0_reg(qdev, &port_regs->macMIIStatusReg);
if (!(temp & MAC_MII_STATUS_BSY))
return 0;
udelay(10);
count--;
}
return -1;
}
static void ql_mii_enable_scan_mode(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 scanControl;
if (qdev->numPorts > 1) {
/* Auto scan will cycle through multiple ports */
scanControl = MAC_MII_CONTROL_AS | MAC_MII_CONTROL_SC;
} else {
scanControl = MAC_MII_CONTROL_SC;
}
/*
* Scan register 1 of PHY/PETBI,
* Set up to scan both devices
* The autoscan starts from the first register, completes
* the last one before rolling over to the first
*/
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
PHYAddr[0] | MII_SCAN_REGISTER);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
(scanControl) |
((MAC_MII_CONTROL_SC | MAC_MII_CONTROL_AS) << 16));
}
static u8 ql_mii_disable_scan_mode(struct ql3_adapter *qdev)
{
u8 ret;
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
/* See if scan mode is enabled before we turn it off */
if (ql_read_page0_reg(qdev, &port_regs->macMIIMgmtControlReg) &
(MAC_MII_CONTROL_AS | MAC_MII_CONTROL_SC)) {
/* Scan is enabled */
ret = 1;
} else {
/* Scan is disabled */
ret = 0;
}
/*
* When disabling scan mode you must first change the MII register
* address
*/
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
PHYAddr[0] | MII_SCAN_REGISTER);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
((MAC_MII_CONTROL_SC | MAC_MII_CONTROL_AS |
MAC_MII_CONTROL_RC) << 16));
return ret;
}
static int ql_mii_write_reg_ex(struct ql3_adapter *qdev,
u16 regAddr, u16 value, u32 mac_index)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u8 scanWasEnabled;
scanWasEnabled = ql_mii_disable_scan_mode(qdev);
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
PHYAddr[mac_index] | regAddr);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtDataReg, value);
/* Wait for write to complete 9/10/04 SJP */
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to"
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
if (scanWasEnabled)
ql_mii_enable_scan_mode(qdev);
return 0;
}
static int ql_mii_read_reg_ex(struct ql3_adapter *qdev, u16 regAddr,
u16 * value, u32 mac_index)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u8 scanWasEnabled;
u32 temp;
scanWasEnabled = ql_mii_disable_scan_mode(qdev);
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
PHYAddr[mac_index] | regAddr);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
(MAC_MII_CONTROL_RC << 16));
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
(MAC_MII_CONTROL_RC << 16) | MAC_MII_CONTROL_RC);
/* Wait for the read to complete */
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free after issuing command.\n",
qdev->ndev->name);
return -1;
}
temp = ql_read_page0_reg(qdev, &port_regs->macMIIMgmtDataReg);
*value = (u16) temp;
if (scanWasEnabled)
ql_mii_enable_scan_mode(qdev);
return 0;
}
static int ql_mii_write_reg(struct ql3_adapter *qdev, u16 regAddr, u16 value)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
ql_mii_disable_scan_mode(qdev);
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
qdev->PHYAddr | regAddr);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtDataReg, value);
/* Wait for write to complete. */
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
ql_mii_enable_scan_mode(qdev);
return 0;
}
static int ql_mii_read_reg(struct ql3_adapter *qdev, u16 regAddr, u16 *value)
{
u32 temp;
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
ql_mii_disable_scan_mode(qdev);
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtAddrReg,
qdev->PHYAddr | regAddr);
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
(MAC_MII_CONTROL_RC << 16));
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
(MAC_MII_CONTROL_RC << 16) | MAC_MII_CONTROL_RC);
/* Wait for the read to complete */
if (ql_wait_for_mii_ready(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Timed out waiting for management port to "
"get free before issuing command.\n",
qdev->ndev->name);
return -1;
}
temp = ql_read_page0_reg(qdev, &port_regs->macMIIMgmtDataReg);
*value = (u16) temp;
ql_mii_enable_scan_mode(qdev);
return 0;
}
static void ql_petbi_reset(struct ql3_adapter *qdev)
{
ql_mii_write_reg(qdev, PETBI_CONTROL_REG, PETBI_CTRL_SOFT_RESET);
}
static void ql_petbi_start_neg(struct ql3_adapter *qdev)
{
u16 reg;
/* Enable Auto-negotiation sense */
ql_mii_read_reg(qdev, PETBI_TBI_CTRL, &reg);
reg |= PETBI_TBI_AUTO_SENSE;
ql_mii_write_reg(qdev, PETBI_TBI_CTRL, reg);
ql_mii_write_reg(qdev, PETBI_NEG_ADVER,
PETBI_NEG_PAUSE | PETBI_NEG_DUPLEX);
ql_mii_write_reg(qdev, PETBI_CONTROL_REG,
PETBI_CTRL_AUTO_NEG | PETBI_CTRL_RESTART_NEG |
PETBI_CTRL_FULL_DUPLEX | PETBI_CTRL_SPEED_1000);
}
static void ql_petbi_reset_ex(struct ql3_adapter *qdev, u32 mac_index)
{
ql_mii_write_reg_ex(qdev, PETBI_CONTROL_REG, PETBI_CTRL_SOFT_RESET,
mac_index);
}
static void ql_petbi_start_neg_ex(struct ql3_adapter *qdev, u32 mac_index)
{
u16 reg;
/* Enable Auto-negotiation sense */
ql_mii_read_reg_ex(qdev, PETBI_TBI_CTRL, &reg, mac_index);
reg |= PETBI_TBI_AUTO_SENSE;
ql_mii_write_reg_ex(qdev, PETBI_TBI_CTRL, reg, mac_index);
ql_mii_write_reg_ex(qdev, PETBI_NEG_ADVER,
PETBI_NEG_PAUSE | PETBI_NEG_DUPLEX, mac_index);
ql_mii_write_reg_ex(qdev, PETBI_CONTROL_REG,
PETBI_CTRL_AUTO_NEG | PETBI_CTRL_RESTART_NEG |
PETBI_CTRL_FULL_DUPLEX | PETBI_CTRL_SPEED_1000,
mac_index);
}
static void ql_petbi_init(struct ql3_adapter *qdev)
{
ql_petbi_reset(qdev);
ql_petbi_start_neg(qdev);
}
static void ql_petbi_init_ex(struct ql3_adapter *qdev, u32 mac_index)
{
ql_petbi_reset_ex(qdev, mac_index);
ql_petbi_start_neg_ex(qdev, mac_index);
}
static int ql_is_petbi_neg_pause(struct ql3_adapter *qdev)
{
u16 reg;
if (ql_mii_read_reg(qdev, PETBI_NEG_PARTNER, &reg) < 0)
return 0;
return (reg & PETBI_NEG_PAUSE_MASK) == PETBI_NEG_PAUSE;
}
static int ql_phy_get_speed(struct ql3_adapter *qdev)
{
u16 reg;
if (ql_mii_read_reg(qdev, AUX_CONTROL_STATUS, &reg) < 0)
return 0;
reg = (((reg & 0x18) >> 3) & 3);
if (reg == 2)
return SPEED_1000;
else if (reg == 1)
return SPEED_100;
else if (reg == 0)
return SPEED_10;
else
return -1;
}
static int ql_is_full_dup(struct ql3_adapter *qdev)
{
u16 reg;
if (ql_mii_read_reg(qdev, AUX_CONTROL_STATUS, &reg) < 0)
return 0;
return (reg & PHY_AUX_DUPLEX_STAT) != 0;
}
static int ql_is_phy_neg_pause(struct ql3_adapter *qdev)
{
u16 reg;
if (ql_mii_read_reg(qdev, PHY_NEG_PARTNER, &reg) < 0)
return 0;
return (reg & PHY_NEG_PAUSE) != 0;
}
/*
* Caller holds hw_lock.
*/
static void ql_mac_enable(struct ql3_adapter *qdev, u32 enable)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 value;
if (enable)
value = (MAC_CONFIG_REG_PE | (MAC_CONFIG_REG_PE << 16));
else
value = (MAC_CONFIG_REG_PE << 16);
if (qdev->mac_index)
ql_write_page0_reg(qdev, &port_regs->mac1ConfigReg, value);
else
ql_write_page0_reg(qdev, &port_regs->mac0ConfigReg, value);
}
/*
* Caller holds hw_lock.
*/
static void ql_mac_cfg_soft_reset(struct ql3_adapter *qdev, u32 enable)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 value;
if (enable)
value = (MAC_CONFIG_REG_SR | (MAC_CONFIG_REG_SR << 16));
else
value = (MAC_CONFIG_REG_SR << 16);
if (qdev->mac_index)
ql_write_page0_reg(qdev, &port_regs->mac1ConfigReg, value);
else
ql_write_page0_reg(qdev, &port_regs->mac0ConfigReg, value);
}
/*
* Caller holds hw_lock.
*/
static void ql_mac_cfg_gig(struct ql3_adapter *qdev, u32 enable)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 value;
if (enable)
value = (MAC_CONFIG_REG_GM | (MAC_CONFIG_REG_GM << 16));
else
value = (MAC_CONFIG_REG_GM << 16);
if (qdev->mac_index)
ql_write_page0_reg(qdev, &port_regs->mac1ConfigReg, value);
else
ql_write_page0_reg(qdev, &port_regs->mac0ConfigReg, value);
}
/*
* Caller holds hw_lock.
*/
static void ql_mac_cfg_full_dup(struct ql3_adapter *qdev, u32 enable)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 value;
if (enable)
value = (MAC_CONFIG_REG_FD | (MAC_CONFIG_REG_FD << 16));
else
value = (MAC_CONFIG_REG_FD << 16);
if (qdev->mac_index)
ql_write_page0_reg(qdev, &port_regs->mac1ConfigReg, value);
else
ql_write_page0_reg(qdev, &port_regs->mac0ConfigReg, value);
}
/*
* Caller holds hw_lock.
*/
static void ql_mac_cfg_pause(struct ql3_adapter *qdev, u32 enable)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 value;
if (enable)
value =
((MAC_CONFIG_REG_TF | MAC_CONFIG_REG_RF) |
((MAC_CONFIG_REG_TF | MAC_CONFIG_REG_RF) << 16));
else
value = ((MAC_CONFIG_REG_TF | MAC_CONFIG_REG_RF) << 16);
if (qdev->mac_index)
ql_write_page0_reg(qdev, &port_regs->mac1ConfigReg, value);
else
ql_write_page0_reg(qdev, &port_regs->mac0ConfigReg, value);
}
/*
* Caller holds hw_lock.
*/
static int ql_is_fiber(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp;
switch (qdev->mac_index) {
case 0:
bitToCheck = PORT_STATUS_SM0;
break;
case 1:
bitToCheck = PORT_STATUS_SM1;
break;
}
temp = ql_read_page0_reg(qdev, &port_regs->portStatus);
return (temp & bitToCheck) != 0;
}
static int ql_is_auto_cfg(struct ql3_adapter *qdev)
{
u16 reg;
ql_mii_read_reg(qdev, 0x00, &reg);
return (reg & 0x1000) != 0;
}
/*
* Caller holds hw_lock.
*/
static int ql_is_auto_neg_complete(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp;
switch (qdev->mac_index) {
case 0:
bitToCheck = PORT_STATUS_AC0;
break;
case 1:
bitToCheck = PORT_STATUS_AC1;
break;
}
temp = ql_read_page0_reg(qdev, &port_regs->portStatus);
if (temp & bitToCheck) {
if (netif_msg_link(qdev))
printk(KERN_INFO PFX
"%s: Auto-Negotiate complete.\n",
qdev->ndev->name);
return 1;
} else {
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Auto-Negotiate incomplete.\n",
qdev->ndev->name);
return 0;
}
}
/*
* ql_is_neg_pause() returns 1 if pause was negotiated to be on
*/
static int ql_is_neg_pause(struct ql3_adapter *qdev)
{
if (ql_is_fiber(qdev))
return ql_is_petbi_neg_pause(qdev);
else
return ql_is_phy_neg_pause(qdev);
}
static int ql_auto_neg_error(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp;
switch (qdev->mac_index) {
case 0:
bitToCheck = PORT_STATUS_AE0;
break;
case 1:
bitToCheck = PORT_STATUS_AE1;
break;
}
temp = ql_read_page0_reg(qdev, &port_regs->portStatus);
return (temp & bitToCheck) != 0;
}
static u32 ql_get_link_speed(struct ql3_adapter *qdev)
{
if (ql_is_fiber(qdev))
return SPEED_1000;
else
return ql_phy_get_speed(qdev);
}
static int ql_is_link_full_dup(struct ql3_adapter *qdev)
{
if (ql_is_fiber(qdev))
return 1;
else
return ql_is_full_dup(qdev);
}
/*
* Caller holds hw_lock.
*/
static int ql_link_down_detect(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp;
switch (qdev->mac_index) {
case 0:
bitToCheck = ISP_CONTROL_LINK_DN_0;
break;
case 1:
bitToCheck = ISP_CONTROL_LINK_DN_1;
break;
}
temp =
ql_read_common_reg(qdev, &port_regs->CommonRegs.ispControlStatus);
return (temp & bitToCheck) != 0;
}
/*
* Caller holds hw_lock.
*/
static int ql_link_down_detect_clear(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
switch (qdev->mac_index) {
case 0:
ql_write_common_reg(qdev,
&port_regs->CommonRegs.ispControlStatus,
(ISP_CONTROL_LINK_DN_0) |
(ISP_CONTROL_LINK_DN_0 << 16));
break;
case 1:
ql_write_common_reg(qdev,
&port_regs->CommonRegs.ispControlStatus,
(ISP_CONTROL_LINK_DN_1) |
(ISP_CONTROL_LINK_DN_1 << 16));
break;
default:
return 1;
}
return 0;
}
/*
* Caller holds hw_lock.
*/
static int ql_this_adapter_controls_port(struct ql3_adapter *qdev,
u32 mac_index)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp;
switch (mac_index) {
case 0:
bitToCheck = PORT_STATUS_F1_ENABLED;
break;
case 1:
bitToCheck = PORT_STATUS_F3_ENABLED;
break;
default:
break;
}
temp = ql_read_page0_reg(qdev, &port_regs->portStatus);
if (temp & bitToCheck) {
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: is not link master.\n", qdev->ndev->name);
return 0;
} else {
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: is link master.\n", qdev->ndev->name);
return 1;
}
}
static void ql_phy_reset_ex(struct ql3_adapter *qdev, u32 mac_index)
{
ql_mii_write_reg_ex(qdev, CONTROL_REG, PHY_CTRL_SOFT_RESET, mac_index);
}
static void ql_phy_start_neg_ex(struct ql3_adapter *qdev, u32 mac_index)
{
u16 reg;
ql_mii_write_reg_ex(qdev, PHY_NEG_ADVER,
PHY_NEG_PAUSE | PHY_NEG_ADV_SPEED | 1, mac_index);
ql_mii_read_reg_ex(qdev, CONTROL_REG, &reg, mac_index);
ql_mii_write_reg_ex(qdev, CONTROL_REG, reg | PHY_CTRL_RESTART_NEG,
mac_index);
}
static void ql_phy_init_ex(struct ql3_adapter *qdev, u32 mac_index)
{
ql_phy_reset_ex(qdev, mac_index);
ql_phy_start_neg_ex(qdev, mac_index);
}
/*
* Caller holds hw_lock.
*/
static u32 ql_get_link_state(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
u32 bitToCheck = 0;
u32 temp, linkState;
switch (qdev->mac_index) {
case 0:
bitToCheck = PORT_STATUS_UP0;
break;
case 1:
bitToCheck = PORT_STATUS_UP1;
break;
}
temp = ql_read_page0_reg(qdev, &port_regs->portStatus);
if (temp & bitToCheck) {
linkState = LS_UP;
} else {
linkState = LS_DOWN;
if (netif_msg_link(qdev))
printk(KERN_WARNING PFX
"%s: Link is down.\n", qdev->ndev->name);
}
return linkState;
}
static int ql_port_start(struct ql3_adapter *qdev)
{
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return -1;
if (ql_is_fiber(qdev)) {
ql_petbi_init(qdev);
} else {
/* Copper port */
ql_phy_init_ex(qdev, qdev->mac_index);
}
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
return 0;
}
static int ql_finish_auto_neg(struct ql3_adapter *qdev)
{
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return -1;
if (!ql_auto_neg_error(qdev)) {
if (test_bit(QL_LINK_MASTER,&qdev->flags)) {
/* configure the MAC */
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: Configuring link.\n",
qdev->ndev->
name);
ql_mac_cfg_soft_reset(qdev, 1);
ql_mac_cfg_gig(qdev,
(ql_get_link_speed
(qdev) ==
SPEED_1000));
ql_mac_cfg_full_dup(qdev,
ql_is_link_full_dup
(qdev));
ql_mac_cfg_pause(qdev,
ql_is_neg_pause
(qdev));
ql_mac_cfg_soft_reset(qdev, 0);
/* enable the MAC */
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: Enabling mac.\n",
qdev->ndev->
name);
ql_mac_enable(qdev, 1);
}
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: Change port_link_state LS_DOWN to LS_UP.\n",
qdev->ndev->name);
qdev->port_link_state = LS_UP;
netif_start_queue(qdev->ndev);
netif_carrier_on(qdev->ndev);
if (netif_msg_link(qdev))
printk(KERN_INFO PFX
"%s: Link is up at %d Mbps, %s duplex.\n",
qdev->ndev->name,
ql_get_link_speed(qdev),
ql_is_link_full_dup(qdev)
? "full" : "half");
} else { /* Remote error detected */
if (test_bit(QL_LINK_MASTER,&qdev->flags)) {
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: Remote error detected. "
"Calling ql_port_start().\n",
qdev->ndev->
name);
/*
* ql_port_start() is shared code and needs
* to lock the PHY on it's own.
*/
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
if(ql_port_start(qdev)) {/* Restart port */
return -1;
} else
return 0;
}
}
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
return 0;
}
static void ql_link_state_machine(struct ql3_adapter *qdev)
{
u32 curr_link_state;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
curr_link_state = ql_get_link_state(qdev);
if (test_bit(QL_RESET_ACTIVE,&qdev->flags)) {
if (netif_msg_link(qdev))
printk(KERN_INFO PFX
"%s: Reset in progress, skip processing link "
"state.\n", qdev->ndev->name);
return;
}
switch (qdev->port_link_state) {
default:
if (test_bit(QL_LINK_MASTER,&qdev->flags)) {
ql_port_start(qdev);
}
qdev->port_link_state = LS_DOWN;
/* Fall Through */
case LS_DOWN:
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: port_link_state = LS_DOWN.\n",
qdev->ndev->name);
if (curr_link_state == LS_UP) {
if (netif_msg_link(qdev))
printk(KERN_DEBUG PFX
"%s: curr_link_state = LS_UP.\n",
qdev->ndev->name);
if (ql_is_auto_neg_complete(qdev))
ql_finish_auto_neg(qdev);
if (qdev->port_link_state == LS_UP)
ql_link_down_detect_clear(qdev);
}
break;
case LS_UP:
/*
* See if the link is currently down or went down and came
* back up
*/
if ((curr_link_state == LS_DOWN) || ql_link_down_detect(qdev)) {
if (netif_msg_link(qdev))
printk(KERN_INFO PFX "%s: Link is down.\n",
qdev->ndev->name);
qdev->port_link_state = LS_DOWN;
}
break;
}
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
}
/*
* Caller must take hw_lock and QL_PHY_GIO_SEM.
*/
static void ql_get_phy_owner(struct ql3_adapter *qdev)
{
if (ql_this_adapter_controls_port(qdev, qdev->mac_index))
set_bit(QL_LINK_MASTER,&qdev->flags);
else
clear_bit(QL_LINK_MASTER,&qdev->flags);
}
/*
* Caller must take hw_lock and QL_PHY_GIO_SEM.
*/
static void ql_init_scan_mode(struct ql3_adapter *qdev)
{
ql_mii_enable_scan_mode(qdev);
if (test_bit(QL_LINK_OPTICAL,&qdev->flags)) {
if (ql_this_adapter_controls_port(qdev, qdev->mac_index))
ql_petbi_init_ex(qdev, qdev->mac_index);
} else {
if (ql_this_adapter_controls_port(qdev, qdev->mac_index))
ql_phy_init_ex(qdev, qdev->mac_index);
}
}
/*
* MII_Setup needs to be called before taking the PHY out of reset so that the
* management interface clock speed can be set properly. It would be better if
* we had a way to disable MDC until after the PHY is out of reset, but we
* don't have that capability.
*/
static int ql_mii_setup(struct ql3_adapter *qdev)
{
u32 reg;
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return -1;
/* Divide 125MHz clock by 28 to meet PHY timing requirements */
reg = MAC_MII_CONTROL_CLK_SEL_DIV28;
ql_write_page0_reg(qdev, &port_regs->macMIIMgmtControlReg,
reg | ((MAC_MII_CONTROL_CLK_SEL_MASK) << 16));
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
return 0;
}
static u32 ql_supported_modes(struct ql3_adapter *qdev)
{
u32 supported;
if (test_bit(QL_LINK_OPTICAL,&qdev->flags)) {
supported = SUPPORTED_1000baseT_Full | SUPPORTED_FIBRE
| SUPPORTED_Autoneg;
} else {
supported = SUPPORTED_10baseT_Half
| SUPPORTED_10baseT_Full
| SUPPORTED_100baseT_Half
| SUPPORTED_100baseT_Full
| SUPPORTED_1000baseT_Half
| SUPPORTED_1000baseT_Full
| SUPPORTED_Autoneg | SUPPORTED_TP;
}
return supported;
}
static int ql_get_auto_cfg_status(struct ql3_adapter *qdev)
{
int status;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return 0;
status = ql_is_auto_cfg(qdev);
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return status;
}
static u32 ql_get_speed(struct ql3_adapter *qdev)
{
u32 status;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return 0;
status = ql_get_link_speed(qdev);
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return status;
}
static int ql_get_full_dup(struct ql3_adapter *qdev)
{
int status;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7))
return 0;
status = ql_is_link_full_dup(qdev);
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return status;
}
static int ql_get_settings(struct net_device *ndev, struct ethtool_cmd *ecmd)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
ecmd->transceiver = XCVR_INTERNAL;
ecmd->supported = ql_supported_modes(qdev);
if (test_bit(QL_LINK_OPTICAL,&qdev->flags)) {
ecmd->port = PORT_FIBRE;
} else {
ecmd->port = PORT_TP;
ecmd->phy_address = qdev->PHYAddr;
}
ecmd->advertising = ql_supported_modes(qdev);
ecmd->autoneg = ql_get_auto_cfg_status(qdev);
ecmd->speed = ql_get_speed(qdev);
ecmd->duplex = ql_get_full_dup(qdev);
return 0;
}
static void ql_get_drvinfo(struct net_device *ndev,
struct ethtool_drvinfo *drvinfo)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
strncpy(drvinfo->driver, ql3xxx_driver_name, 32);
strncpy(drvinfo->version, ql3xxx_driver_version, 32);
strncpy(drvinfo->fw_version, "N/A", 32);
strncpy(drvinfo->bus_info, pci_name(qdev->pdev), 32);
drvinfo->n_stats = 0;
drvinfo->testinfo_len = 0;
drvinfo->regdump_len = 0;
drvinfo->eedump_len = 0;
}
static u32 ql_get_msglevel(struct net_device *ndev)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
return qdev->msg_enable;
}
static void ql_set_msglevel(struct net_device *ndev, u32 value)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
qdev->msg_enable = value;
}
static struct ethtool_ops ql3xxx_ethtool_ops = {
.get_settings = ql_get_settings,
.get_drvinfo = ql_get_drvinfo,
.get_perm_addr = ethtool_op_get_perm_addr,
.get_link = ethtool_op_get_link,
.get_msglevel = ql_get_msglevel,
.set_msglevel = ql_set_msglevel,
};
static int ql_populate_free_queue(struct ql3_adapter *qdev)
{
struct ql_rcv_buf_cb *lrg_buf_cb = qdev->lrg_buf_free_head;
u64 map;
while (lrg_buf_cb) {
if (!lrg_buf_cb->skb) {
lrg_buf_cb->skb = dev_alloc_skb(qdev->lrg_buffer_len);
if (unlikely(!lrg_buf_cb->skb)) {
printk(KERN_DEBUG PFX
"%s: Failed dev_alloc_skb().\n",
qdev->ndev->name);
break;
} else {
/*
* We save some space to copy the ethhdr from
* first buffer
*/
skb_reserve(lrg_buf_cb->skb, QL_HEADER_SPACE);
map = pci_map_single(qdev->pdev,
lrg_buf_cb->skb->data,
qdev->lrg_buffer_len -
QL_HEADER_SPACE,
PCI_DMA_FROMDEVICE);
lrg_buf_cb->buf_phy_addr_low =
cpu_to_le32(LS_64BITS(map));
lrg_buf_cb->buf_phy_addr_high =
cpu_to_le32(MS_64BITS(map));
pci_unmap_addr_set(lrg_buf_cb, mapaddr, map);
pci_unmap_len_set(lrg_buf_cb, maplen,
qdev->lrg_buffer_len -
QL_HEADER_SPACE);
--qdev->lrg_buf_skb_check;
if (!qdev->lrg_buf_skb_check)
return 1;
}
}
lrg_buf_cb = lrg_buf_cb->next;
}
return 0;
}
/*
* Caller holds hw_lock.
*/
static void ql_update_lrg_bufq_prod_index(struct ql3_adapter *qdev)
{
struct bufq_addr_element *lrg_buf_q_ele;
int i;
struct ql_rcv_buf_cb *lrg_buf_cb;
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
if ((qdev->lrg_buf_free_count >= 8)
&& (qdev->lrg_buf_release_cnt >= 16)) {
if (qdev->lrg_buf_skb_check)
if (!ql_populate_free_queue(qdev))
return;
lrg_buf_q_ele = qdev->lrg_buf_next_free;
while ((qdev->lrg_buf_release_cnt >= 16)
&& (qdev->lrg_buf_free_count >= 8)) {
for (i = 0; i < 8; i++) {
lrg_buf_cb =
ql_get_from_lrg_buf_free_list(qdev);
lrg_buf_q_ele->addr_high =
lrg_buf_cb->buf_phy_addr_high;
lrg_buf_q_ele->addr_low =
lrg_buf_cb->buf_phy_addr_low;
lrg_buf_q_ele++;
qdev->lrg_buf_release_cnt--;
}
qdev->lrg_buf_q_producer_index++;
if (qdev->lrg_buf_q_producer_index == NUM_LBUFQ_ENTRIES)
qdev->lrg_buf_q_producer_index = 0;
if (qdev->lrg_buf_q_producer_index ==
(NUM_LBUFQ_ENTRIES - 1)) {
lrg_buf_q_ele = qdev->lrg_buf_q_virt_addr;
}
}
qdev->lrg_buf_next_free = lrg_buf_q_ele;
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
rxLargeQProducerIndex,
qdev->lrg_buf_q_producer_index);
}
}
static void ql_process_mac_tx_intr(struct ql3_adapter *qdev,
struct ob_mac_iocb_rsp *mac_rsp)
{
struct ql_tx_buf_cb *tx_cb;
tx_cb = &qdev->tx_buf[mac_rsp->transaction_id];
pci_unmap_single(qdev->pdev,
pci_unmap_addr(tx_cb, mapaddr),
pci_unmap_len(tx_cb, maplen), PCI_DMA_TODEVICE);
dev_kfree_skb_irq(tx_cb->skb);
qdev->stats.tx_packets++;
qdev->stats.tx_bytes += tx_cb->skb->len;
tx_cb->skb = NULL;
atomic_inc(&qdev->tx_count);
}
static void ql_process_mac_rx_intr(struct ql3_adapter *qdev,
struct ib_mac_iocb_rsp *ib_mac_rsp_ptr)
{
long int offset;
u32 lrg_buf_phy_addr_low = 0;
struct ql_rcv_buf_cb *lrg_buf_cb1 = NULL;
struct ql_rcv_buf_cb *lrg_buf_cb2 = NULL;
u32 *curr_ial_ptr;
struct sk_buff *skb;
u16 length = le16_to_cpu(ib_mac_rsp_ptr->length);
/*
* Get the inbound address list (small buffer).
*/
offset = qdev->small_buf_index * QL_SMALL_BUFFER_SIZE;
if (++qdev->small_buf_index == NUM_SMALL_BUFFERS)
qdev->small_buf_index = 0;
curr_ial_ptr = (u32 *) (qdev->small_buf_virt_addr + offset);
qdev->last_rsp_offset = qdev->small_buf_phy_addr_low + offset;
qdev->small_buf_release_cnt++;
/* start of first buffer */
lrg_buf_phy_addr_low = le32_to_cpu(*curr_ial_ptr);
lrg_buf_cb1 = &qdev->lrg_buf[qdev->lrg_buf_index];
qdev->lrg_buf_release_cnt++;
if (++qdev->lrg_buf_index == NUM_LARGE_BUFFERS)
qdev->lrg_buf_index = 0;
curr_ial_ptr++; /* 64-bit pointers require two incs. */
curr_ial_ptr++;
/* start of second buffer */
lrg_buf_phy_addr_low = le32_to_cpu(*curr_ial_ptr);
lrg_buf_cb2 = &qdev->lrg_buf[qdev->lrg_buf_index];
/*
* Second buffer gets sent up the stack.
*/
qdev->lrg_buf_release_cnt++;
if (++qdev->lrg_buf_index == NUM_LARGE_BUFFERS)
qdev->lrg_buf_index = 0;
skb = lrg_buf_cb2->skb;
qdev->stats.rx_packets++;
qdev->stats.rx_bytes += length;
skb_put(skb, length);
pci_unmap_single(qdev->pdev,
pci_unmap_addr(lrg_buf_cb2, mapaddr),
pci_unmap_len(lrg_buf_cb2, maplen),
PCI_DMA_FROMDEVICE);
prefetch(skb->data);
skb->dev = qdev->ndev;
skb->ip_summed = CHECKSUM_NONE;
skb->protocol = eth_type_trans(skb, qdev->ndev);
netif_receive_skb(skb);
qdev->ndev->last_rx = jiffies;
lrg_buf_cb2->skb = NULL;
ql_release_to_lrg_buf_free_list(qdev, lrg_buf_cb1);
ql_release_to_lrg_buf_free_list(qdev, lrg_buf_cb2);
}
static void ql_process_macip_rx_intr(struct ql3_adapter *qdev,
struct ib_ip_iocb_rsp *ib_ip_rsp_ptr)
{
long int offset;
u32 lrg_buf_phy_addr_low = 0;
struct ql_rcv_buf_cb *lrg_buf_cb1 = NULL;
struct ql_rcv_buf_cb *lrg_buf_cb2 = NULL;
u32 *curr_ial_ptr;
struct sk_buff *skb1, *skb2;
struct net_device *ndev = qdev->ndev;
u16 length = le16_to_cpu(ib_ip_rsp_ptr->length);
u16 size = 0;
/*
* Get the inbound address list (small buffer).
*/
offset = qdev->small_buf_index * QL_SMALL_BUFFER_SIZE;
if (++qdev->small_buf_index == NUM_SMALL_BUFFERS)
qdev->small_buf_index = 0;
curr_ial_ptr = (u32 *) (qdev->small_buf_virt_addr + offset);
qdev->last_rsp_offset = qdev->small_buf_phy_addr_low + offset;
qdev->small_buf_release_cnt++;
/* start of first buffer */
lrg_buf_phy_addr_low = le32_to_cpu(*curr_ial_ptr);
lrg_buf_cb1 = &qdev->lrg_buf[qdev->lrg_buf_index];
qdev->lrg_buf_release_cnt++;
if (++qdev->lrg_buf_index == NUM_LARGE_BUFFERS)
qdev->lrg_buf_index = 0;
skb1 = lrg_buf_cb1->skb;
curr_ial_ptr++; /* 64-bit pointers require two incs. */
curr_ial_ptr++;
/* start of second buffer */
lrg_buf_phy_addr_low = le32_to_cpu(*curr_ial_ptr);
lrg_buf_cb2 = &qdev->lrg_buf[qdev->lrg_buf_index];
skb2 = lrg_buf_cb2->skb;
qdev->lrg_buf_release_cnt++;
if (++qdev->lrg_buf_index == NUM_LARGE_BUFFERS)
qdev->lrg_buf_index = 0;
qdev->stats.rx_packets++;
qdev->stats.rx_bytes += length;
/*
* Copy the ethhdr from first buffer to second. This
* is necessary for IP completions.
*/
if (*((u16 *) skb1->data) != 0xFFFF)
size = VLAN_ETH_HLEN;
else
size = ETH_HLEN;
skb_put(skb2, length); /* Just the second buffer length here. */
pci_unmap_single(qdev->pdev,
pci_unmap_addr(lrg_buf_cb2, mapaddr),
pci_unmap_len(lrg_buf_cb2, maplen),
PCI_DMA_FROMDEVICE);
prefetch(skb2->data);
memcpy(skb_push(skb2, size), skb1->data + VLAN_ID_LEN, size);
skb2->dev = qdev->ndev;
skb2->ip_summed = CHECKSUM_NONE;
skb2->protocol = eth_type_trans(skb2, qdev->ndev);
netif_receive_skb(skb2);
ndev->last_rx = jiffies;
lrg_buf_cb2->skb = NULL;
ql_release_to_lrg_buf_free_list(qdev, lrg_buf_cb1);
ql_release_to_lrg_buf_free_list(qdev, lrg_buf_cb2);
}
static int ql_tx_rx_clean(struct ql3_adapter *qdev,
int *tx_cleaned, int *rx_cleaned, int work_to_do)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
struct net_rsp_iocb *net_rsp;
struct net_device *ndev = qdev->ndev;
unsigned long hw_flags;
/* While there are entries in the completion queue. */
while ((cpu_to_le32(*(qdev->prsp_producer_index)) !=
qdev->rsp_consumer_index) && (*rx_cleaned < work_to_do)) {
net_rsp = qdev->rsp_current;
switch (net_rsp->opcode) {
case OPCODE_OB_MAC_IOCB_FN0:
case OPCODE_OB_MAC_IOCB_FN2:
ql_process_mac_tx_intr(qdev, (struct ob_mac_iocb_rsp *)
net_rsp);
(*tx_cleaned)++;
break;
case OPCODE_IB_MAC_IOCB:
ql_process_mac_rx_intr(qdev, (struct ib_mac_iocb_rsp *)
net_rsp);
(*rx_cleaned)++;
break;
case OPCODE_IB_IP_IOCB:
ql_process_macip_rx_intr(qdev, (struct ib_ip_iocb_rsp *)
net_rsp);
(*rx_cleaned)++;
break;
default:
{
u32 *tmp = (u32 *) net_rsp;
printk(KERN_ERR PFX
"%s: Hit default case, not "
"handled!\n"
" dropping the packet, opcode = "
"%x.\n",
ndev->name, net_rsp->opcode);
printk(KERN_ERR PFX
"0x%08lx 0x%08lx 0x%08lx 0x%08lx \n",
(unsigned long int)tmp[0],
(unsigned long int)tmp[1],
(unsigned long int)tmp[2],
(unsigned long int)tmp[3]);
}
}
qdev->rsp_consumer_index++;
if (qdev->rsp_consumer_index == NUM_RSP_Q_ENTRIES) {
qdev->rsp_consumer_index = 0;
qdev->rsp_current = qdev->rsp_q_virt_addr;
} else {
qdev->rsp_current++;
}
}
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
ql_update_lrg_bufq_prod_index(qdev);
if (qdev->small_buf_release_cnt >= 16) {
while (qdev->small_buf_release_cnt >= 16) {
qdev->small_buf_q_producer_index++;
if (qdev->small_buf_q_producer_index ==
NUM_SBUFQ_ENTRIES)
qdev->small_buf_q_producer_index = 0;
qdev->small_buf_release_cnt -= 8;
}
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
rxSmallQProducerIndex,
qdev->small_buf_q_producer_index);
}
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.rspQConsumerIndex,
qdev->rsp_consumer_index);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
if (unlikely(netif_queue_stopped(qdev->ndev))) {
if (netif_queue_stopped(qdev->ndev) &&
(atomic_read(&qdev->tx_count) > (NUM_REQ_Q_ENTRIES / 4)))
netif_wake_queue(qdev->ndev);
}
return *tx_cleaned + *rx_cleaned;
}
static int ql_poll(struct net_device *ndev, int *budget)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
int work_to_do = min(*budget, ndev->quota);
int rx_cleaned = 0, tx_cleaned = 0;
if (!netif_carrier_ok(ndev))
goto quit_polling;
ql_tx_rx_clean(qdev, &tx_cleaned, &rx_cleaned, work_to_do);
*budget -= rx_cleaned;
ndev->quota -= rx_cleaned;
if ((!tx_cleaned && !rx_cleaned) || !netif_running(ndev)) {
quit_polling:
netif_rx_complete(ndev);
ql_enable_interrupts(qdev);
return 0;
}
return 1;
}
static irqreturn_t ql3xxx_isr(int irq, void *dev_id, struct pt_regs *regs)
{
struct net_device *ndev = dev_id;
struct ql3_adapter *qdev = netdev_priv(ndev);
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
u32 value;
int handled = 1;
u32 var;
port_regs = qdev->mem_map_registers;
value =
ql_read_common_reg_l(qdev, &port_regs->CommonRegs.ispControlStatus);
if (value & (ISP_CONTROL_FE | ISP_CONTROL_RI)) {
spin_lock(&qdev->adapter_lock);
netif_stop_queue(qdev->ndev);
netif_carrier_off(qdev->ndev);
ql_disable_interrupts(qdev);
qdev->port_link_state = LS_DOWN;
set_bit(QL_RESET_ACTIVE,&qdev->flags) ;
if (value & ISP_CONTROL_FE) {
/*
* Chip Fatal Error.
*/
var =
ql_read_page0_reg_l(qdev,
&port_regs->PortFatalErrStatus);
printk(KERN_WARNING PFX
"%s: Resetting chip. PortFatalErrStatus "
"register = 0x%x\n", ndev->name, var);
set_bit(QL_RESET_START,&qdev->flags) ;
} else {
/*
* Soft Reset Requested.
*/
set_bit(QL_RESET_PER_SCSI,&qdev->flags) ;
printk(KERN_ERR PFX
"%s: Another function issued a reset to the "
"chip. ISR value = %x.\n", ndev->name, value);
}
queue_work(qdev->workqueue, &qdev->reset_work);
spin_unlock(&qdev->adapter_lock);
} else if (value & ISP_IMR_DISABLE_CMPL_INT) {
ql_disable_interrupts(qdev);
if (likely(netif_rx_schedule_prep(ndev)))
__netif_rx_schedule(ndev);
else
ql_enable_interrupts(qdev);
} else {
return IRQ_NONE;
}
return IRQ_RETVAL(handled);
}
static int ql3xxx_send(struct sk_buff *skb, struct net_device *ndev)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)netdev_priv(ndev);
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
struct ql_tx_buf_cb *tx_cb;
struct ob_mac_iocb_req *mac_iocb_ptr;
u64 map;
if (unlikely(atomic_read(&qdev->tx_count) < 2)) {
if (!netif_queue_stopped(ndev))
netif_stop_queue(ndev);
return NETDEV_TX_BUSY;
}
tx_cb = &qdev->tx_buf[qdev->req_producer_index] ;
mac_iocb_ptr = tx_cb->queue_entry;
memset((void *)mac_iocb_ptr, 0, sizeof(struct ob_mac_iocb_req));
mac_iocb_ptr->opcode = qdev->mac_ob_opcode;
mac_iocb_ptr->flags |= qdev->mb_bit_mask;
mac_iocb_ptr->transaction_id = qdev->req_producer_index;
mac_iocb_ptr->data_len = cpu_to_le16((u16) skb->len);
tx_cb->skb = skb;
map = pci_map_single(qdev->pdev, skb->data, skb->len, PCI_DMA_TODEVICE);
mac_iocb_ptr->buf_addr0_low = cpu_to_le32(LS_64BITS(map));
mac_iocb_ptr->buf_addr0_high = cpu_to_le32(MS_64BITS(map));
mac_iocb_ptr->buf_0_len = cpu_to_le32(skb->len | OB_MAC_IOCB_REQ_E);
pci_unmap_addr_set(tx_cb, mapaddr, map);
pci_unmap_len_set(tx_cb, maplen, skb->len);
atomic_dec(&qdev->tx_count);
qdev->req_producer_index++;
if (qdev->req_producer_index == NUM_REQ_Q_ENTRIES)
qdev->req_producer_index = 0;
wmb();
ql_write_common_reg_l(qdev,
(u32 *) & port_regs->CommonRegs.reqQProducerIndex,
qdev->req_producer_index);
ndev->trans_start = jiffies;
if (netif_msg_tx_queued(qdev))
printk(KERN_DEBUG PFX "%s: tx queued, slot %d, len %d\n",
ndev->name, qdev->req_producer_index, skb->len);
return NETDEV_TX_OK;
}
static int ql_alloc_net_req_rsp_queues(struct ql3_adapter *qdev)
{
qdev->req_q_size =
(u32) (NUM_REQ_Q_ENTRIES * sizeof(struct ob_mac_iocb_req));
qdev->req_q_virt_addr =
pci_alloc_consistent(qdev->pdev,
(size_t) qdev->req_q_size,
&qdev->req_q_phy_addr);
if ((qdev->req_q_virt_addr == NULL) ||
LS_64BITS(qdev->req_q_phy_addr) & (qdev->req_q_size - 1)) {
printk(KERN_ERR PFX "%s: reqQ failed.\n",
qdev->ndev->name);
return -ENOMEM;
}
qdev->rsp_q_size = NUM_RSP_Q_ENTRIES * sizeof(struct net_rsp_iocb);
qdev->rsp_q_virt_addr =
pci_alloc_consistent(qdev->pdev,
(size_t) qdev->rsp_q_size,
&qdev->rsp_q_phy_addr);
if ((qdev->rsp_q_virt_addr == NULL) ||
LS_64BITS(qdev->rsp_q_phy_addr) & (qdev->rsp_q_size - 1)) {
printk(KERN_ERR PFX
"%s: rspQ allocation failed\n",
qdev->ndev->name);
pci_free_consistent(qdev->pdev, (size_t) qdev->req_q_size,
qdev->req_q_virt_addr,
qdev->req_q_phy_addr);
return -ENOMEM;
}
set_bit(QL_ALLOC_REQ_RSP_Q_DONE,&qdev->flags);
return 0;
}
static void ql_free_net_req_rsp_queues(struct ql3_adapter *qdev)
{
if (!test_bit(QL_ALLOC_REQ_RSP_Q_DONE,&qdev->flags)) {
printk(KERN_INFO PFX
"%s: Already done.\n", qdev->ndev->name);
return;
}
pci_free_consistent(qdev->pdev,
qdev->req_q_size,
qdev->req_q_virt_addr, qdev->req_q_phy_addr);
qdev->req_q_virt_addr = NULL;
pci_free_consistent(qdev->pdev,
qdev->rsp_q_size,
qdev->rsp_q_virt_addr, qdev->rsp_q_phy_addr);
qdev->rsp_q_virt_addr = NULL;
clear_bit(QL_ALLOC_REQ_RSP_Q_DONE,&qdev->flags);
}
static int ql_alloc_buffer_queues(struct ql3_adapter *qdev)
{
/* Create Large Buffer Queue */
qdev->lrg_buf_q_size =
NUM_LBUFQ_ENTRIES * sizeof(struct lrg_buf_q_entry);
if (qdev->lrg_buf_q_size < PAGE_SIZE)
qdev->lrg_buf_q_alloc_size = PAGE_SIZE;
else
qdev->lrg_buf_q_alloc_size = qdev->lrg_buf_q_size * 2;
qdev->lrg_buf_q_alloc_virt_addr =
pci_alloc_consistent(qdev->pdev,
qdev->lrg_buf_q_alloc_size,
&qdev->lrg_buf_q_alloc_phy_addr);
if (qdev->lrg_buf_q_alloc_virt_addr == NULL) {
printk(KERN_ERR PFX
"%s: lBufQ failed\n", qdev->ndev->name);
return -ENOMEM;
}
qdev->lrg_buf_q_virt_addr = qdev->lrg_buf_q_alloc_virt_addr;
qdev->lrg_buf_q_phy_addr = qdev->lrg_buf_q_alloc_phy_addr;
/* Create Small Buffer Queue */
qdev->small_buf_q_size =
NUM_SBUFQ_ENTRIES * sizeof(struct lrg_buf_q_entry);
if (qdev->small_buf_q_size < PAGE_SIZE)
qdev->small_buf_q_alloc_size = PAGE_SIZE;
else
qdev->small_buf_q_alloc_size = qdev->small_buf_q_size * 2;
qdev->small_buf_q_alloc_virt_addr =
pci_alloc_consistent(qdev->pdev,
qdev->small_buf_q_alloc_size,
&qdev->small_buf_q_alloc_phy_addr);
if (qdev->small_buf_q_alloc_virt_addr == NULL) {
printk(KERN_ERR PFX
"%s: Small Buffer Queue allocation failed.\n",
qdev->ndev->name);
pci_free_consistent(qdev->pdev, qdev->lrg_buf_q_alloc_size,
qdev->lrg_buf_q_alloc_virt_addr,
qdev->lrg_buf_q_alloc_phy_addr);
return -ENOMEM;
}
qdev->small_buf_q_virt_addr = qdev->small_buf_q_alloc_virt_addr;
qdev->small_buf_q_phy_addr = qdev->small_buf_q_alloc_phy_addr;
set_bit(QL_ALLOC_BUFQS_DONE,&qdev->flags);
return 0;
}
static void ql_free_buffer_queues(struct ql3_adapter *qdev)
{
if (!test_bit(QL_ALLOC_BUFQS_DONE,&qdev->flags)) {
printk(KERN_INFO PFX
"%s: Already done.\n", qdev->ndev->name);
return;
}
pci_free_consistent(qdev->pdev,
qdev->lrg_buf_q_alloc_size,
qdev->lrg_buf_q_alloc_virt_addr,
qdev->lrg_buf_q_alloc_phy_addr);
qdev->lrg_buf_q_virt_addr = NULL;
pci_free_consistent(qdev->pdev,
qdev->small_buf_q_alloc_size,
qdev->small_buf_q_alloc_virt_addr,
qdev->small_buf_q_alloc_phy_addr);
qdev->small_buf_q_virt_addr = NULL;
clear_bit(QL_ALLOC_BUFQS_DONE,&qdev->flags);
}
static int ql_alloc_small_buffers(struct ql3_adapter *qdev)
{
int i;
struct bufq_addr_element *small_buf_q_entry;
/* Currently we allocate on one of memory and use it for smallbuffers */
qdev->small_buf_total_size =
(QL_ADDR_ELE_PER_BUFQ_ENTRY * NUM_SBUFQ_ENTRIES *
QL_SMALL_BUFFER_SIZE);
qdev->small_buf_virt_addr =
pci_alloc_consistent(qdev->pdev,
qdev->small_buf_total_size,
&qdev->small_buf_phy_addr);
if (qdev->small_buf_virt_addr == NULL) {
printk(KERN_ERR PFX
"%s: Failed to get small buffer memory.\n",
qdev->ndev->name);
return -ENOMEM;
}
qdev->small_buf_phy_addr_low = LS_64BITS(qdev->small_buf_phy_addr);
qdev->small_buf_phy_addr_high = MS_64BITS(qdev->small_buf_phy_addr);
small_buf_q_entry = qdev->small_buf_q_virt_addr;
qdev->last_rsp_offset = qdev->small_buf_phy_addr_low;
/* Initialize the small buffer queue. */
for (i = 0; i < (QL_ADDR_ELE_PER_BUFQ_ENTRY * NUM_SBUFQ_ENTRIES); i++) {
small_buf_q_entry->addr_high =
cpu_to_le32(qdev->small_buf_phy_addr_high);
small_buf_q_entry->addr_low =
cpu_to_le32(qdev->small_buf_phy_addr_low +
(i * QL_SMALL_BUFFER_SIZE));
small_buf_q_entry++;
}
qdev->small_buf_index = 0;
set_bit(QL_ALLOC_SMALL_BUF_DONE,&qdev->flags);
return 0;
}
static void ql_free_small_buffers(struct ql3_adapter *qdev)
{
if (!test_bit(QL_ALLOC_SMALL_BUF_DONE,&qdev->flags)) {
printk(KERN_INFO PFX
"%s: Already done.\n", qdev->ndev->name);
return;
}
if (qdev->small_buf_virt_addr != NULL) {
pci_free_consistent(qdev->pdev,
qdev->small_buf_total_size,
qdev->small_buf_virt_addr,
qdev->small_buf_phy_addr);
qdev->small_buf_virt_addr = NULL;
}
}
static void ql_free_large_buffers(struct ql3_adapter *qdev)
{
int i = 0;
struct ql_rcv_buf_cb *lrg_buf_cb;
for (i = 0; i < NUM_LARGE_BUFFERS; i++) {
lrg_buf_cb = &qdev->lrg_buf[i];
if (lrg_buf_cb->skb) {
dev_kfree_skb(lrg_buf_cb->skb);
pci_unmap_single(qdev->pdev,
pci_unmap_addr(lrg_buf_cb, mapaddr),
pci_unmap_len(lrg_buf_cb, maplen),
PCI_DMA_FROMDEVICE);
memset(lrg_buf_cb, 0, sizeof(struct ql_rcv_buf_cb));
} else {
break;
}
}
}
static void ql_init_large_buffers(struct ql3_adapter *qdev)
{
int i;
struct ql_rcv_buf_cb *lrg_buf_cb;
struct bufq_addr_element *buf_addr_ele = qdev->lrg_buf_q_virt_addr;
for (i = 0; i < NUM_LARGE_BUFFERS; i++) {
lrg_buf_cb = &qdev->lrg_buf[i];
buf_addr_ele->addr_high = lrg_buf_cb->buf_phy_addr_high;
buf_addr_ele->addr_low = lrg_buf_cb->buf_phy_addr_low;
buf_addr_ele++;
}
qdev->lrg_buf_index = 0;
qdev->lrg_buf_skb_check = 0;
}
static int ql_alloc_large_buffers(struct ql3_adapter *qdev)
{
int i;
struct ql_rcv_buf_cb *lrg_buf_cb;
struct sk_buff *skb;
u64 map;
for (i = 0; i < NUM_LARGE_BUFFERS; i++) {
skb = dev_alloc_skb(qdev->lrg_buffer_len);
if (unlikely(!skb)) {
/* Better luck next round */
printk(KERN_ERR PFX
"%s: large buff alloc failed, "
"for %d bytes at index %d.\n",
qdev->ndev->name,
qdev->lrg_buffer_len * 2, i);
ql_free_large_buffers(qdev);
return -ENOMEM;
} else {
lrg_buf_cb = &qdev->lrg_buf[i];
memset(lrg_buf_cb, 0, sizeof(struct ql_rcv_buf_cb));
lrg_buf_cb->index = i;
lrg_buf_cb->skb = skb;
/*
* We save some space to copy the ethhdr from first
* buffer
*/
skb_reserve(skb, QL_HEADER_SPACE);
map = pci_map_single(qdev->pdev,
skb->data,
qdev->lrg_buffer_len -
QL_HEADER_SPACE,
PCI_DMA_FROMDEVICE);
pci_unmap_addr_set(lrg_buf_cb, mapaddr, map);
pci_unmap_len_set(lrg_buf_cb, maplen,
qdev->lrg_buffer_len -
QL_HEADER_SPACE);
lrg_buf_cb->buf_phy_addr_low =
cpu_to_le32(LS_64BITS(map));
lrg_buf_cb->buf_phy_addr_high =
cpu_to_le32(MS_64BITS(map));
}
}
return 0;
}
static void ql_create_send_free_list(struct ql3_adapter *qdev)
{
struct ql_tx_buf_cb *tx_cb;
int i;
struct ob_mac_iocb_req *req_q_curr =
qdev->req_q_virt_addr;
/* Create free list of transmit buffers */
for (i = 0; i < NUM_REQ_Q_ENTRIES; i++) {
tx_cb = &qdev->tx_buf[i];
tx_cb->skb = NULL;
tx_cb->queue_entry = req_q_curr;
req_q_curr++;
}
}
static int ql_alloc_mem_resources(struct ql3_adapter *qdev)
{
if (qdev->ndev->mtu == NORMAL_MTU_SIZE)
qdev->lrg_buffer_len = NORMAL_MTU_SIZE;
else if (qdev->ndev->mtu == JUMBO_MTU_SIZE) {
qdev->lrg_buffer_len = JUMBO_MTU_SIZE;
} else {
printk(KERN_ERR PFX
"%s: Invalid mtu size. Only 1500 and 9000 are accepted.\n",
qdev->ndev->name);
return -ENOMEM;
}
qdev->lrg_buffer_len += VLAN_ETH_HLEN + VLAN_ID_LEN + QL_HEADER_SPACE;
qdev->max_frame_size =
(qdev->lrg_buffer_len - QL_HEADER_SPACE) + ETHERNET_CRC_SIZE;
/*
* First allocate a page of shared memory and use it for shadow
* locations of Network Request Queue Consumer Address Register and
* Network Completion Queue Producer Index Register
*/
qdev->shadow_reg_virt_addr =
pci_alloc_consistent(qdev->pdev,
PAGE_SIZE, &qdev->shadow_reg_phy_addr);
if (qdev->shadow_reg_virt_addr != NULL) {
qdev->preq_consumer_index = (u16 *) qdev->shadow_reg_virt_addr;
qdev->req_consumer_index_phy_addr_high =
MS_64BITS(qdev->shadow_reg_phy_addr);
qdev->req_consumer_index_phy_addr_low =
LS_64BITS(qdev->shadow_reg_phy_addr);
qdev->prsp_producer_index =
(u32 *) (((u8 *) qdev->preq_consumer_index) + 8);
qdev->rsp_producer_index_phy_addr_high =
qdev->req_consumer_index_phy_addr_high;
qdev->rsp_producer_index_phy_addr_low =
qdev->req_consumer_index_phy_addr_low + 8;
} else {
printk(KERN_ERR PFX
"%s: shadowReg Alloc failed.\n", qdev->ndev->name);
return -ENOMEM;
}
if (ql_alloc_net_req_rsp_queues(qdev) != 0) {
printk(KERN_ERR PFX
"%s: ql_alloc_net_req_rsp_queues failed.\n",
qdev->ndev->name);
goto err_req_rsp;
}
if (ql_alloc_buffer_queues(qdev) != 0) {
printk(KERN_ERR PFX
"%s: ql_alloc_buffer_queues failed.\n",
qdev->ndev->name);
goto err_buffer_queues;
}
if (ql_alloc_small_buffers(qdev) != 0) {
printk(KERN_ERR PFX
"%s: ql_alloc_small_buffers failed\n", qdev->ndev->name);
goto err_small_buffers;
}
if (ql_alloc_large_buffers(qdev) != 0) {
printk(KERN_ERR PFX
"%s: ql_alloc_large_buffers failed\n", qdev->ndev->name);
goto err_small_buffers;
}
/* Initialize the large buffer queue. */
ql_init_large_buffers(qdev);
ql_create_send_free_list(qdev);
qdev->rsp_current = qdev->rsp_q_virt_addr;
return 0;
err_small_buffers:
ql_free_buffer_queues(qdev);
err_buffer_queues:
ql_free_net_req_rsp_queues(qdev);
err_req_rsp:
pci_free_consistent(qdev->pdev,
PAGE_SIZE,
qdev->shadow_reg_virt_addr,
qdev->shadow_reg_phy_addr);
return -ENOMEM;
}
static void ql_free_mem_resources(struct ql3_adapter *qdev)
{
ql_free_large_buffers(qdev);
ql_free_small_buffers(qdev);
ql_free_buffer_queues(qdev);
ql_free_net_req_rsp_queues(qdev);
if (qdev->shadow_reg_virt_addr != NULL) {
pci_free_consistent(qdev->pdev,
PAGE_SIZE,
qdev->shadow_reg_virt_addr,
qdev->shadow_reg_phy_addr);
qdev->shadow_reg_virt_addr = NULL;
}
}
static int ql_init_misc_registers(struct ql3_adapter *qdev)
{
struct ql3xxx_local_ram_registers *local_ram =
(struct ql3xxx_local_ram_registers *)qdev->mem_map_registers;
if(ql_sem_spinlock(qdev, QL_DDR_RAM_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 4))
return -1;
ql_write_page2_reg(qdev,
&local_ram->bufletSize, qdev->nvram_data.bufletSize);
ql_write_page2_reg(qdev,
&local_ram->maxBufletCount,
qdev->nvram_data.bufletCount);
ql_write_page2_reg(qdev,
&local_ram->freeBufletThresholdLow,
(qdev->nvram_data.tcpWindowThreshold25 << 16) |
(qdev->nvram_data.tcpWindowThreshold0));
ql_write_page2_reg(qdev,
&local_ram->freeBufletThresholdHigh,
qdev->nvram_data.tcpWindowThreshold50);
ql_write_page2_reg(qdev,
&local_ram->ipHashTableBase,
(qdev->nvram_data.ipHashTableBaseHi << 16) |
qdev->nvram_data.ipHashTableBaseLo);
ql_write_page2_reg(qdev,
&local_ram->ipHashTableCount,
qdev->nvram_data.ipHashTableSize);
ql_write_page2_reg(qdev,
&local_ram->tcpHashTableBase,
(qdev->nvram_data.tcpHashTableBaseHi << 16) |
qdev->nvram_data.tcpHashTableBaseLo);
ql_write_page2_reg(qdev,
&local_ram->tcpHashTableCount,
qdev->nvram_data.tcpHashTableSize);
ql_write_page2_reg(qdev,
&local_ram->ncbBase,
(qdev->nvram_data.ncbTableBaseHi << 16) |
qdev->nvram_data.ncbTableBaseLo);
ql_write_page2_reg(qdev,
&local_ram->maxNcbCount,
qdev->nvram_data.ncbTableSize);
ql_write_page2_reg(qdev,
&local_ram->drbBase,
(qdev->nvram_data.drbTableBaseHi << 16) |
qdev->nvram_data.drbTableBaseLo);
ql_write_page2_reg(qdev,
&local_ram->maxDrbCount,
qdev->nvram_data.drbTableSize);
ql_sem_unlock(qdev, QL_DDR_RAM_SEM_MASK);
return 0;
}
static int ql_adapter_initialize(struct ql3_adapter *qdev)
{
u32 value;
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
struct ql3xxx_host_memory_registers __iomem *hmem_regs =
(struct ql3xxx_host_memory_registers *)port_regs;
u32 delay = 10;
int status = 0;
if(ql_mii_setup(qdev))
return -1;
/* Bring out PHY out of reset */
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
(ISP_SERIAL_PORT_IF_WE |
(ISP_SERIAL_PORT_IF_WE << 16)));
qdev->port_link_state = LS_DOWN;
netif_carrier_off(qdev->ndev);
/* V2 chip fix for ARS-39168. */
ql_write_common_reg(qdev, &port_regs->CommonRegs.serialPortInterfaceReg,
(ISP_SERIAL_PORT_IF_SDE |
(ISP_SERIAL_PORT_IF_SDE << 16)));
/* Request Queue Registers */
*((u32 *) (qdev->preq_consumer_index)) = 0;
atomic_set(&qdev->tx_count,NUM_REQ_Q_ENTRIES);
qdev->req_producer_index = 0;
ql_write_page1_reg(qdev,
&hmem_regs->reqConsumerIndexAddrHigh,
qdev->req_consumer_index_phy_addr_high);
ql_write_page1_reg(qdev,
&hmem_regs->reqConsumerIndexAddrLow,
qdev->req_consumer_index_phy_addr_low);
ql_write_page1_reg(qdev,
&hmem_regs->reqBaseAddrHigh,
MS_64BITS(qdev->req_q_phy_addr));
ql_write_page1_reg(qdev,
&hmem_regs->reqBaseAddrLow,
LS_64BITS(qdev->req_q_phy_addr));
ql_write_page1_reg(qdev, &hmem_regs->reqLength, NUM_REQ_Q_ENTRIES);
/* Response Queue Registers */
*((u16 *) (qdev->prsp_producer_index)) = 0;
qdev->rsp_consumer_index = 0;
qdev->rsp_current = qdev->rsp_q_virt_addr;
ql_write_page1_reg(qdev,
&hmem_regs->rspProducerIndexAddrHigh,
qdev->rsp_producer_index_phy_addr_high);
ql_write_page1_reg(qdev,
&hmem_regs->rspProducerIndexAddrLow,
qdev->rsp_producer_index_phy_addr_low);
ql_write_page1_reg(qdev,
&hmem_regs->rspBaseAddrHigh,
MS_64BITS(qdev->rsp_q_phy_addr));
ql_write_page1_reg(qdev,
&hmem_regs->rspBaseAddrLow,
LS_64BITS(qdev->rsp_q_phy_addr));
ql_write_page1_reg(qdev, &hmem_regs->rspLength, NUM_RSP_Q_ENTRIES);
/* Large Buffer Queue */
ql_write_page1_reg(qdev,
&hmem_regs->rxLargeQBaseAddrHigh,
MS_64BITS(qdev->lrg_buf_q_phy_addr));
ql_write_page1_reg(qdev,
&hmem_regs->rxLargeQBaseAddrLow,
LS_64BITS(qdev->lrg_buf_q_phy_addr));
ql_write_page1_reg(qdev, &hmem_regs->rxLargeQLength, NUM_LBUFQ_ENTRIES);
ql_write_page1_reg(qdev,
&hmem_regs->rxLargeBufferLength,
qdev->lrg_buffer_len);
/* Small Buffer Queue */
ql_write_page1_reg(qdev,
&hmem_regs->rxSmallQBaseAddrHigh,
MS_64BITS(qdev->small_buf_q_phy_addr));
ql_write_page1_reg(qdev,
&hmem_regs->rxSmallQBaseAddrLow,
LS_64BITS(qdev->small_buf_q_phy_addr));
ql_write_page1_reg(qdev, &hmem_regs->rxSmallQLength, NUM_SBUFQ_ENTRIES);
ql_write_page1_reg(qdev,
&hmem_regs->rxSmallBufferLength,
QL_SMALL_BUFFER_SIZE);
qdev->small_buf_q_producer_index = NUM_SBUFQ_ENTRIES - 1;
qdev->small_buf_release_cnt = 8;
qdev->lrg_buf_q_producer_index = NUM_LBUFQ_ENTRIES - 1;
qdev->lrg_buf_release_cnt = 8;
qdev->lrg_buf_next_free =
(struct bufq_addr_element *)qdev->lrg_buf_q_virt_addr;
qdev->small_buf_index = 0;
qdev->lrg_buf_index = 0;
qdev->lrg_buf_free_count = 0;
qdev->lrg_buf_free_head = NULL;
qdev->lrg_buf_free_tail = NULL;
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
rxSmallQProducerIndex,
qdev->small_buf_q_producer_index);
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
rxLargeQProducerIndex,
qdev->lrg_buf_q_producer_index);
/*
* Find out if the chip has already been initialized. If it has, then
* we skip some of the initialization.
*/
clear_bit(QL_LINK_MASTER, &qdev->flags);
value = ql_read_page0_reg(qdev, &port_regs->portStatus);
if ((value & PORT_STATUS_IC) == 0) {
/* Chip has not been configured yet, so let it rip. */
if(ql_init_misc_registers(qdev)) {
status = -1;
goto out;
}
if (qdev->mac_index)
ql_write_page0_reg(qdev,
&port_regs->mac1MaxFrameLengthReg,
qdev->max_frame_size);
else
ql_write_page0_reg(qdev,
&port_regs->mac0MaxFrameLengthReg,
qdev->max_frame_size);
value = qdev->nvram_data.tcpMaxWindowSize;
ql_write_page0_reg(qdev, &port_regs->tcpMaxWindow, value);
value = (0xFFFF << 16) | qdev->nvram_data.extHwConfig;
if(ql_sem_spinlock(qdev, QL_FLASH_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index)
* 2) << 13)) {
status = -1;
goto out;
}
ql_write_page0_reg(qdev, &port_regs->ExternalHWConfig, value);
ql_write_page0_reg(qdev, &port_regs->InternalChipConfig,
(((INTERNAL_CHIP_SD | INTERNAL_CHIP_WE) <<
16) | (INTERNAL_CHIP_SD |
INTERNAL_CHIP_WE)));
ql_sem_unlock(qdev, QL_FLASH_SEM_MASK);
}
if(ql_sem_spinlock(qdev, QL_PHY_GIO_SEM_MASK,
(QL_RESOURCE_BITS_BASE_CODE | (qdev->mac_index) *
2) << 7)) {
status = -1;
goto out;
}
ql_init_scan_mode(qdev);
ql_get_phy_owner(qdev);
/* Load the MAC Configuration */
/* Program lower 32 bits of the MAC address */
ql_write_page0_reg(qdev, &port_regs->macAddrIndirectPtrReg,
(MAC_ADDR_INDIRECT_PTR_REG_RP_MASK << 16));
ql_write_page0_reg(qdev, &port_regs->macAddrDataReg,
((qdev->ndev->dev_addr[2] << 24)
| (qdev->ndev->dev_addr[3] << 16)
| (qdev->ndev->dev_addr[4] << 8)
| qdev->ndev->dev_addr[5]));
/* Program top 16 bits of the MAC address */
ql_write_page0_reg(qdev, &port_regs->macAddrIndirectPtrReg,
((MAC_ADDR_INDIRECT_PTR_REG_RP_MASK << 16) | 1));
ql_write_page0_reg(qdev, &port_regs->macAddrDataReg,
((qdev->ndev->dev_addr[0] << 8)
| qdev->ndev->dev_addr[1]));
/* Enable Primary MAC */
ql_write_page0_reg(qdev, &port_regs->macAddrIndirectPtrReg,
((MAC_ADDR_INDIRECT_PTR_REG_PE << 16) |
MAC_ADDR_INDIRECT_PTR_REG_PE));
/* Clear Primary and Secondary IP addresses */
ql_write_page0_reg(qdev, &port_regs->ipAddrIndexReg,
((IP_ADDR_INDEX_REG_MASK << 16) |
(qdev->mac_index << 2)));
ql_write_page0_reg(qdev, &port_regs->ipAddrDataReg, 0);
ql_write_page0_reg(qdev, &port_regs->ipAddrIndexReg,
((IP_ADDR_INDEX_REG_MASK << 16) |
((qdev->mac_index << 2) + 1)));
ql_write_page0_reg(qdev, &port_regs->ipAddrDataReg, 0);
ql_sem_unlock(qdev, QL_PHY_GIO_SEM_MASK);
/* Indicate Configuration Complete */
ql_write_page0_reg(qdev,
&port_regs->portControl,
((PORT_CONTROL_CC << 16) | PORT_CONTROL_CC));
do {
value = ql_read_page0_reg(qdev, &port_regs->portStatus);
if (value & PORT_STATUS_IC)
break;
msleep(500);
} while (--delay);
if (delay == 0) {
printk(KERN_ERR PFX
"%s: Hw Initialization timeout.\n", qdev->ndev->name);
status = -1;
goto out;
}
/* Enable Ethernet Function */
value =
(PORT_CONTROL_EF | PORT_CONTROL_ET | PORT_CONTROL_EI |
PORT_CONTROL_HH);
ql_write_page0_reg(qdev, &port_regs->portControl,
((value << 16) | value));
out:
return status;
}
/*
* Caller holds hw_lock.
*/
static int ql_adapter_reset(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
int status = 0;
u16 value;
int max_wait_time;
set_bit(QL_RESET_ACTIVE, &qdev->flags);
clear_bit(QL_RESET_DONE, &qdev->flags);
/*
* Issue soft reset to chip.
*/
printk(KERN_DEBUG PFX
"%s: Issue soft reset to chip.\n",
qdev->ndev->name);
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.ispControlStatus,
((ISP_CONTROL_SR << 16) | ISP_CONTROL_SR));
/* Wait 3 seconds for reset to complete. */
printk(KERN_DEBUG PFX
"%s: Wait 10 milliseconds for reset to complete.\n",
qdev->ndev->name);
/* Wait until the firmware tells us the Soft Reset is done */
max_wait_time = 5;
do {
value =
ql_read_common_reg(qdev,
&port_regs->CommonRegs.ispControlStatus);
if ((value & ISP_CONTROL_SR) == 0)
break;
ssleep(1);
} while ((--max_wait_time));
/*
* Also, make sure that the Network Reset Interrupt bit has been
* cleared after the soft reset has taken place.
*/
value =
ql_read_common_reg(qdev, &port_regs->CommonRegs.ispControlStatus);
if (value & ISP_CONTROL_RI) {
printk(KERN_DEBUG PFX
"ql_adapter_reset: clearing RI after reset.\n");
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
ispControlStatus,
((ISP_CONTROL_RI << 16) | ISP_CONTROL_RI));
}
if (max_wait_time == 0) {
/* Issue Force Soft Reset */
ql_write_common_reg(qdev,
(u32 *) & port_regs->CommonRegs.
ispControlStatus,
((ISP_CONTROL_FSR << 16) |
ISP_CONTROL_FSR));
/*
* Wait until the firmware tells us the Force Soft Reset is
* done
*/
max_wait_time = 5;
do {
value =
ql_read_common_reg(qdev,
&port_regs->CommonRegs.
ispControlStatus);
if ((value & ISP_CONTROL_FSR) == 0) {
break;
}
ssleep(1);
} while ((--max_wait_time));
}
if (max_wait_time == 0)
status = 1;
clear_bit(QL_RESET_ACTIVE, &qdev->flags);
set_bit(QL_RESET_DONE, &qdev->flags);
return status;
}
static void ql_set_mac_info(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
u32 value, port_status;
u8 func_number;
/* Get the function number */
value =
ql_read_common_reg_l(qdev, &port_regs->CommonRegs.ispControlStatus);
func_number = (u8) ((value >> 4) & OPCODE_FUNC_ID_MASK);
port_status = ql_read_page0_reg(qdev, &port_regs->portStatus);
switch (value & ISP_CONTROL_FN_MASK) {
case ISP_CONTROL_FN0_NET:
qdev->mac_index = 0;
qdev->mac_ob_opcode = OUTBOUND_MAC_IOCB | func_number;
qdev->tcp_ob_opcode = OUTBOUND_TCP_IOCB | func_number;
qdev->update_ob_opcode = UPDATE_NCB_IOCB | func_number;
qdev->mb_bit_mask = FN0_MA_BITS_MASK;
qdev->PHYAddr = PORT0_PHY_ADDRESS;
if (port_status & PORT_STATUS_SM0)
set_bit(QL_LINK_OPTICAL,&qdev->flags);
else
clear_bit(QL_LINK_OPTICAL,&qdev->flags);
break;
case ISP_CONTROL_FN1_NET:
qdev->mac_index = 1;
qdev->mac_ob_opcode = OUTBOUND_MAC_IOCB | func_number;
qdev->tcp_ob_opcode = OUTBOUND_TCP_IOCB | func_number;
qdev->update_ob_opcode = UPDATE_NCB_IOCB | func_number;
qdev->mb_bit_mask = FN1_MA_BITS_MASK;
qdev->PHYAddr = PORT1_PHY_ADDRESS;
if (port_status & PORT_STATUS_SM1)
set_bit(QL_LINK_OPTICAL,&qdev->flags);
else
clear_bit(QL_LINK_OPTICAL,&qdev->flags);
break;
case ISP_CONTROL_FN0_SCSI:
case ISP_CONTROL_FN1_SCSI:
default:
printk(KERN_DEBUG PFX
"%s: Invalid function number, ispControlStatus = 0x%x\n",
qdev->ndev->name,value);
break;
}
qdev->numPorts = qdev->nvram_data.numPorts;
}
static void ql_display_dev_info(struct net_device *ndev)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)netdev_priv(ndev);
struct pci_dev *pdev = qdev->pdev;
printk(KERN_INFO PFX
"\n%s Adapter %d RevisionID %d found on PCI slot %d.\n",
DRV_NAME, qdev->index, qdev->chip_rev_id, qdev->pci_slot);
printk(KERN_INFO PFX
"%s Interface.\n",
test_bit(QL_LINK_OPTICAL,&qdev->flags) ? "OPTICAL" : "COPPER");
/*
* Print PCI bus width/type.
*/
printk(KERN_INFO PFX
"Bus interface is %s %s.\n",
((qdev->pci_width == 64) ? "64-bit" : "32-bit"),
((qdev->pci_x) ? "PCI-X" : "PCI"));
printk(KERN_INFO PFX
"mem IO base address adjusted = 0x%p\n",
qdev->mem_map_registers);
printk(KERN_INFO PFX "Interrupt number = %d\n", pdev->irq);
if (netif_msg_probe(qdev))
printk(KERN_INFO PFX
"%s: MAC address %02x:%02x:%02x:%02x:%02x:%02x\n",
ndev->name, ndev->dev_addr[0], ndev->dev_addr[1],
ndev->dev_addr[2], ndev->dev_addr[3], ndev->dev_addr[4],
ndev->dev_addr[5]);
}
static int ql_adapter_down(struct ql3_adapter *qdev, int do_reset)
{
struct net_device *ndev = qdev->ndev;
int retval = 0;
netif_stop_queue(ndev);
netif_carrier_off(ndev);
clear_bit(QL_ADAPTER_UP,&qdev->flags);
clear_bit(QL_LINK_MASTER,&qdev->flags);
ql_disable_interrupts(qdev);
free_irq(qdev->pdev->irq, ndev);
if (qdev->msi && test_bit(QL_MSI_ENABLED,&qdev->flags)) {
printk(KERN_INFO PFX
"%s: calling pci_disable_msi().\n", qdev->ndev->name);
clear_bit(QL_MSI_ENABLED,&qdev->flags);
pci_disable_msi(qdev->pdev);
}
del_timer_sync(&qdev->adapter_timer);
netif_poll_disable(ndev);
if (do_reset) {
int soft_reset;
unsigned long hw_flags;
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if (ql_wait_for_drvr_lock(qdev)) {
if ((soft_reset = ql_adapter_reset(qdev))) {
printk(KERN_ERR PFX
"%s: ql_adapter_reset(%d) FAILED!\n",
ndev->name, qdev->index);
}
printk(KERN_ERR PFX
"%s: Releaseing driver lock via chip reset.\n",ndev->name);
} else {
printk(KERN_ERR PFX
"%s: Could not acquire driver lock to do "
"reset!\n", ndev->name);
retval = -1;
}
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
}
ql_free_mem_resources(qdev);
return retval;
}
static int ql_adapter_up(struct ql3_adapter *qdev)
{
struct net_device *ndev = qdev->ndev;
int err;
unsigned long irq_flags = SA_SAMPLE_RANDOM | SA_SHIRQ;
unsigned long hw_flags;
if (ql_alloc_mem_resources(qdev)) {
printk(KERN_ERR PFX
"%s Unable to allocate buffers.\n", ndev->name);
return -ENOMEM;
}
if (qdev->msi) {
if (pci_enable_msi(qdev->pdev)) {
printk(KERN_ERR PFX
"%s: User requested MSI, but MSI failed to "
"initialize. Continuing without MSI.\n",
qdev->ndev->name);
qdev->msi = 0;
} else {
printk(KERN_INFO PFX "%s: MSI Enabled...\n", qdev->ndev->name);
set_bit(QL_MSI_ENABLED,&qdev->flags);
irq_flags &= ~SA_SHIRQ;
}
}
if ((err = request_irq(qdev->pdev->irq,
ql3xxx_isr,
irq_flags, ndev->name, ndev))) {
printk(KERN_ERR PFX
"%s: Failed to reserve interrupt %d already in use.\n",
ndev->name, qdev->pdev->irq);
goto err_irq;
}
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
if ((err = ql_wait_for_drvr_lock(qdev))) {
if ((err = ql_adapter_initialize(qdev))) {
printk(KERN_ERR PFX
"%s: Unable to initialize adapter.\n",
ndev->name);
goto err_init;
}
printk(KERN_ERR PFX
"%s: Releaseing driver lock.\n",ndev->name);
ql_sem_unlock(qdev, QL_DRVR_SEM_MASK);
} else {
printk(KERN_ERR PFX
"%s: Could not aquire driver lock.\n",
ndev->name);
goto err_lock;
}
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
set_bit(QL_ADAPTER_UP,&qdev->flags);
mod_timer(&qdev->adapter_timer, jiffies + HZ * 1);
netif_poll_enable(ndev);
ql_enable_interrupts(qdev);
return 0;
err_init:
ql_sem_unlock(qdev, QL_DRVR_SEM_MASK);
err_lock:
free_irq(qdev->pdev->irq, ndev);
err_irq:
if (qdev->msi && test_bit(QL_MSI_ENABLED,&qdev->flags)) {
printk(KERN_INFO PFX
"%s: calling pci_disable_msi().\n",
qdev->ndev->name);
clear_bit(QL_MSI_ENABLED,&qdev->flags);
pci_disable_msi(qdev->pdev);
}
return err;
}
static int ql_cycle_adapter(struct ql3_adapter *qdev, int reset)
{
if( ql_adapter_down(qdev,reset) || ql_adapter_up(qdev)) {
printk(KERN_ERR PFX
"%s: Driver up/down cycle failed, "
"closing device\n",qdev->ndev->name);
dev_close(qdev->ndev);
return -1;
}
return 0;
}
static int ql3xxx_close(struct net_device *ndev)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
/*
* Wait for device to recover from a reset.
* (Rarely happens, but possible.)
*/
while (!test_bit(QL_ADAPTER_UP,&qdev->flags))
msleep(50);
ql_adapter_down(qdev,QL_DO_RESET);
return 0;
}
static int ql3xxx_open(struct net_device *ndev)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
return (ql_adapter_up(qdev));
}
static struct net_device_stats *ql3xxx_get_stats(struct net_device *dev)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)dev->priv;
return &qdev->stats;
}
static int ql3xxx_change_mtu(struct net_device *ndev, int new_mtu)
{
struct ql3_adapter *qdev = netdev_priv(ndev);
printk(KERN_ERR PFX "%s: new mtu size = %d.\n", ndev->name, new_mtu);
if (new_mtu != NORMAL_MTU_SIZE && new_mtu != JUMBO_MTU_SIZE) {
printk(KERN_ERR PFX
"%s: mtu size of %d is not valid. Use exactly %d or "
"%d.\n", ndev->name, new_mtu, NORMAL_MTU_SIZE,
JUMBO_MTU_SIZE);
return -EINVAL;
}
if (!netif_running(ndev)) {
ndev->mtu = new_mtu;
return 0;
}
ndev->mtu = new_mtu;
return ql_cycle_adapter(qdev,QL_DO_RESET);
}
static void ql3xxx_set_multicast_list(struct net_device *ndev)
{
/*
* We are manually parsing the list in the net_device structure.
*/
return;
}
static int ql3xxx_set_mac_address(struct net_device *ndev, void *p)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)netdev_priv(ndev);
struct ql3xxx_port_registers __iomem *port_regs =
qdev->mem_map_registers;
struct sockaddr *addr = p;
unsigned long hw_flags;
if (netif_running(ndev))
return -EBUSY;
if (!is_valid_ether_addr(addr->sa_data))
return -EADDRNOTAVAIL;
memcpy(ndev->dev_addr, addr->sa_data, ndev->addr_len);
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
/* Program lower 32 bits of the MAC address */
ql_write_page0_reg(qdev, &port_regs->macAddrIndirectPtrReg,
(MAC_ADDR_INDIRECT_PTR_REG_RP_MASK << 16));
ql_write_page0_reg(qdev, &port_regs->macAddrDataReg,
((ndev->dev_addr[2] << 24) | (ndev->
dev_addr[3] << 16) |
(ndev->dev_addr[4] << 8) | ndev->dev_addr[5]));
/* Program top 16 bits of the MAC address */
ql_write_page0_reg(qdev, &port_regs->macAddrIndirectPtrReg,
((MAC_ADDR_INDIRECT_PTR_REG_RP_MASK << 16) | 1));
ql_write_page0_reg(qdev, &port_regs->macAddrDataReg,
((ndev->dev_addr[0] << 8) | ndev->dev_addr[1]));
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
return 0;
}
static void ql3xxx_tx_timeout(struct net_device *ndev)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)netdev_priv(ndev);
printk(KERN_ERR PFX "%s: Resetting...\n", ndev->name);
/*
* Stop the queues, we've got a problem.
*/
netif_stop_queue(ndev);
/*
* Wake up the worker to process this event.
*/
queue_work(qdev->workqueue, &qdev->tx_timeout_work);
}
static void ql_reset_work(struct ql3_adapter *qdev)
{
struct net_device *ndev = qdev->ndev;
u32 value;
struct ql_tx_buf_cb *tx_cb;
int max_wait_time, i;
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
unsigned long hw_flags;
if (test_bit((QL_RESET_PER_SCSI | QL_RESET_START),&qdev->flags)) {
clear_bit(QL_LINK_MASTER,&qdev->flags);
/*
* Loop through the active list and return the skb.
*/
for (i = 0; i < NUM_REQ_Q_ENTRIES; i++) {
tx_cb = &qdev->tx_buf[i];
if (tx_cb->skb) {
printk(KERN_DEBUG PFX
"%s: Freeing lost SKB.\n",
qdev->ndev->name);
pci_unmap_single(qdev->pdev,
pci_unmap_addr(tx_cb, mapaddr),
pci_unmap_len(tx_cb, maplen), PCI_DMA_TODEVICE);
dev_kfree_skb(tx_cb->skb);
tx_cb->skb = NULL;
}
}
printk(KERN_ERR PFX
"%s: Clearing NRI after reset.\n", qdev->ndev->name);
spin_lock_irqsave(&qdev->hw_lock, hw_flags);
ql_write_common_reg(qdev,
&port_regs->CommonRegs.
ispControlStatus,
((ISP_CONTROL_RI << 16) | ISP_CONTROL_RI));
/*
* Wait the for Soft Reset to Complete.
*/
max_wait_time = 10;
do {
value = ql_read_common_reg(qdev,
&port_regs->CommonRegs.
ispControlStatus);
if ((value & ISP_CONTROL_SR) == 0) {
printk(KERN_DEBUG PFX
"%s: reset completed.\n",
qdev->ndev->name);
break;
}
if (value & ISP_CONTROL_RI) {
printk(KERN_DEBUG PFX
"%s: clearing NRI after reset.\n",
qdev->ndev->name);
ql_write_common_reg(qdev,
(u32 *) &
port_regs->
CommonRegs.
ispControlStatus,
((ISP_CONTROL_RI <<
16) | ISP_CONTROL_RI));
}
ssleep(1);
} while (--max_wait_time);
spin_unlock_irqrestore(&qdev->hw_lock, hw_flags);
if (value & ISP_CONTROL_SR) {
/*
* Set the reset flags and clear the board again.
* Nothing else to do...
*/
printk(KERN_ERR PFX
"%s: Timed out waiting for reset to "
"complete.\n", ndev->name);
printk(KERN_ERR PFX
"%s: Do a reset.\n", ndev->name);
clear_bit(QL_RESET_PER_SCSI,&qdev->flags);
clear_bit(QL_RESET_START,&qdev->flags);
ql_cycle_adapter(qdev,QL_DO_RESET);
return;
}
clear_bit(QL_RESET_ACTIVE,&qdev->flags);
clear_bit(QL_RESET_PER_SCSI,&qdev->flags);
clear_bit(QL_RESET_START,&qdev->flags);
ql_cycle_adapter(qdev,QL_NO_RESET);
}
}
static void ql_tx_timeout_work(struct ql3_adapter *qdev)
{
ql_cycle_adapter(qdev,QL_DO_RESET);
}
static void ql_get_board_info(struct ql3_adapter *qdev)
{
struct ql3xxx_port_registers __iomem *port_regs = qdev->mem_map_registers;
u32 value;
value = ql_read_page0_reg_l(qdev, &port_regs->portStatus);
qdev->chip_rev_id = ((value & PORT_STATUS_REV_ID_MASK) >> 12);
if (value & PORT_STATUS_64)
qdev->pci_width = 64;
else
qdev->pci_width = 32;
if (value & PORT_STATUS_X)
qdev->pci_x = 1;
else
qdev->pci_x = 0;
qdev->pci_slot = (u8) PCI_SLOT(qdev->pdev->devfn);
}
static void ql3xxx_timer(unsigned long ptr)
{
struct ql3_adapter *qdev = (struct ql3_adapter *)ptr;
if (test_bit(QL_RESET_ACTIVE,&qdev->flags)) {
printk(KERN_DEBUG PFX
"%s: Reset in progress.\n",
qdev->ndev->name);
goto end;
}
ql_link_state_machine(qdev);
/* Restart timer on 2 second interval. */
end:
mod_timer(&qdev->adapter_timer, jiffies + HZ * 1);
}
static int __devinit ql3xxx_probe(struct pci_dev *pdev,
const struct pci_device_id *pci_entry)
{
struct net_device *ndev = NULL;
struct ql3_adapter *qdev = NULL;
static int cards_found = 0;
int pci_using_dac, err;
err = pci_enable_device(pdev);
if (err) {
printk(KERN_ERR PFX "%s cannot enable PCI device\n",
pci_name(pdev));
goto err_out;
}
err = pci_request_regions(pdev, DRV_NAME);
if (err) {
printk(KERN_ERR PFX "%s cannot obtain PCI resources\n",
pci_name(pdev));
goto err_out_disable_pdev;
}
pci_set_master(pdev);
if (!pci_set_dma_mask(pdev, DMA_64BIT_MASK)) {
pci_using_dac = 1;
err = pci_set_consistent_dma_mask(pdev, DMA_64BIT_MASK);
} else if (!(err = pci_set_dma_mask(pdev, DMA_32BIT_MASK))) {
pci_using_dac = 0;
err = pci_set_consistent_dma_mask(pdev, DMA_32BIT_MASK);
}
if (err) {
printk(KERN_ERR PFX "%s no usable DMA configuration\n",
pci_name(pdev));
goto err_out_free_regions;
}
ndev = alloc_etherdev(sizeof(struct ql3_adapter));
if (!ndev)
goto err_out_free_regions;
SET_MODULE_OWNER(ndev);
SET_NETDEV_DEV(ndev, &pdev->dev);
ndev->features = NETIF_F_LLTX;
if (pci_using_dac)
ndev->features |= NETIF_F_HIGHDMA;
pci_set_drvdata(pdev, ndev);
qdev = netdev_priv(ndev);
qdev->index = cards_found;
qdev->ndev = ndev;
qdev->pdev = pdev;
qdev->port_link_state = LS_DOWN;
if (msi)
qdev->msi = 1;
qdev->msg_enable = netif_msg_init(debug, default_msg);
qdev->mem_map_registers =
ioremap_nocache(pci_resource_start(pdev, 1),
pci_resource_len(qdev->pdev, 1));
if (!qdev->mem_map_registers) {
printk(KERN_ERR PFX "%s: cannot map device registers\n",
pci_name(pdev));
goto err_out_free_ndev;
}
spin_lock_init(&qdev->adapter_lock);
spin_lock_init(&qdev->hw_lock);
/* Set driver entry points */
ndev->open = ql3xxx_open;
ndev->hard_start_xmit = ql3xxx_send;
ndev->stop = ql3xxx_close;
ndev->get_stats = ql3xxx_get_stats;
ndev->change_mtu = ql3xxx_change_mtu;
ndev->set_multicast_list = ql3xxx_set_multicast_list;
SET_ETHTOOL_OPS(ndev, &ql3xxx_ethtool_ops);
ndev->set_mac_address = ql3xxx_set_mac_address;
ndev->tx_timeout = ql3xxx_tx_timeout;
ndev->watchdog_timeo = 5 * HZ;
ndev->poll = &ql_poll;
ndev->weight = 64;
ndev->irq = pdev->irq;
/* make sure the EEPROM is good */
if (ql_get_nvram_params(qdev)) {
printk(KERN_ALERT PFX
"ql3xxx_probe: Adapter #%d, Invalid NVRAM parameters.\n",
qdev->index);
goto err_out_iounmap;
}
ql_set_mac_info(qdev);
/* Validate and set parameters */
if (qdev->mac_index) {
memcpy(ndev->dev_addr, &qdev->nvram_data.funcCfg_fn2.macAddress,
ETH_ALEN);
} else {
memcpy(ndev->dev_addr, &qdev->nvram_data.funcCfg_fn0.macAddress,
ETH_ALEN);
}
memcpy(ndev->perm_addr, ndev->dev_addr, ndev->addr_len);
ndev->tx_queue_len = NUM_REQ_Q_ENTRIES;
/* Turn off support for multicasting */
ndev->flags &= ~IFF_MULTICAST;
/* Record PCI bus information. */
ql_get_board_info(qdev);
/*
* Set the Maximum Memory Read Byte Count value. We do this to handle
* jumbo frames.
*/
if (qdev->pci_x) {
pci_write_config_word(pdev, (int)0x4e, (u16) 0x0036);
}
err = register_netdev(ndev);
if (err) {
printk(KERN_ERR PFX "%s: cannot register net device\n",
pci_name(pdev));
goto err_out_iounmap;
}
/* we're going to reset, so assume we have no link for now */
netif_carrier_off(ndev);
netif_stop_queue(ndev);
qdev->workqueue = create_singlethread_workqueue(ndev->name);
INIT_WORK(&qdev->reset_work, (void (*)(void *))ql_reset_work, qdev);
INIT_WORK(&qdev->tx_timeout_work,
(void (*)(void *))ql_tx_timeout_work, qdev);
init_timer(&qdev->adapter_timer);
qdev->adapter_timer.function = ql3xxx_timer;
qdev->adapter_timer.expires = jiffies + HZ * 2; /* two second delay */
qdev->adapter_timer.data = (unsigned long)qdev;
if(!cards_found) {
printk(KERN_ALERT PFX "%s\n", DRV_STRING);
printk(KERN_ALERT PFX "Driver name: %s, Version: %s.\n",
DRV_NAME, DRV_VERSION);
}
ql_display_dev_info(ndev);
cards_found++;
return 0;
err_out_iounmap:
iounmap(qdev->mem_map_registers);
err_out_free_ndev:
free_netdev(ndev);
err_out_free_regions:
pci_release_regions(pdev);
err_out_disable_pdev:
pci_disable_device(pdev);
pci_set_drvdata(pdev, NULL);
err_out:
return err;
}
static void __devexit ql3xxx_remove(struct pci_dev *pdev)
{
struct net_device *ndev = pci_get_drvdata(pdev);
struct ql3_adapter *qdev = netdev_priv(ndev);
unregister_netdev(ndev);
qdev = netdev_priv(ndev);
ql_disable_interrupts(qdev);
if (qdev->workqueue) {
cancel_delayed_work(&qdev->reset_work);
cancel_delayed_work(&qdev->tx_timeout_work);
destroy_workqueue(qdev->workqueue);
qdev->workqueue = NULL;
}
iounmap((void *)qdev->mmap_virt_base);
pci_release_regions(pdev);
pci_set_drvdata(pdev, NULL);
free_netdev(ndev);
}
static struct pci_driver ql3xxx_driver = {
.name = DRV_NAME,
.id_table = ql3xxx_pci_tbl,
.probe = ql3xxx_probe,
.remove = __devexit_p(ql3xxx_remove),
};
static int __init ql3xxx_init_module(void)
{
return pci_register_driver(&ql3xxx_driver);
}
static void __exit ql3xxx_exit(void)
{
pci_unregister_driver(&ql3xxx_driver);
}
module_init(ql3xxx_init_module);
module_exit(ql3xxx_exit);
/*
* QLogic QLA3xxx NIC HBA Driver
* Copyright (c) 2003-2006 QLogic Corporation
*
* See LICENSE.qla3xxx for copyright and licensing details.
*/
#ifndef _QLA3XXX_H_
#define _QLA3XXX_H_
/*
* IOCB Definitions...
*/
#pragma pack(1)
#define OPCODE_OB_MAC_IOCB_FN0 0x01
#define OPCODE_OB_MAC_IOCB_FN2 0x21
#define OPCODE_OB_TCP_IOCB_FN0 0x03
#define OPCODE_OB_TCP_IOCB_FN2 0x23
#define OPCODE_UPDATE_NCB_IOCB_FN0 0x00
#define OPCODE_UPDATE_NCB_IOCB_FN2 0x20
#define OPCODE_UPDATE_NCB_IOCB 0xF0
#define OPCODE_IB_MAC_IOCB 0xF9
#define OPCODE_IB_IP_IOCB 0xFA
#define OPCODE_IB_TCP_IOCB 0xFB
#define OPCODE_DUMP_PROTO_IOCB 0xFE
#define OPCODE_BUFFER_ALERT_IOCB 0xFB
#define OPCODE_FUNC_ID_MASK 0x30
#define OUTBOUND_MAC_IOCB 0x01 /* plus function bits */
#define OUTBOUND_TCP_IOCB 0x03 /* plus function bits */
#define UPDATE_NCB_IOCB 0x00 /* plus function bits */
#define FN0_MA_BITS_MASK 0x00
#define FN1_MA_BITS_MASK 0x80
struct ob_mac_iocb_req {
u8 opcode;
u8 flags;
#define OB_MAC_IOCB_REQ_MA 0xC0
#define OB_MAC_IOCB_REQ_F 0x20
#define OB_MAC_IOCB_REQ_X 0x10
#define OB_MAC_IOCB_REQ_D 0x02
#define OB_MAC_IOCB_REQ_I 0x01
__le16 reserved0;
__le32 transaction_id;
__le16 data_len;
__le16 reserved1;
__le32 reserved2;
__le32 reserved3;
__le32 buf_addr0_low;
__le32 buf_addr0_high;
__le32 buf_0_len;
__le32 buf_addr1_low;
__le32 buf_addr1_high;
__le32 buf_1_len;
__le32 buf_addr2_low;
__le32 buf_addr2_high;
__le32 buf_2_len;
__le32 reserved4;
__le32 reserved5;
};
/*
* The following constants define control bits for buffer
* length fields for all IOCB's.
*/
#define OB_MAC_IOCB_REQ_E 0x80000000 /* Last valid buffer in list. */
#define OB_MAC_IOCB_REQ_C 0x40000000 /* points to an OAL. (continuation) */
#define OB_MAC_IOCB_REQ_L 0x20000000 /* Auburn local address pointer. */
#define OB_MAC_IOCB_REQ_R 0x10000000 /* 32-bit address pointer. */
struct ob_mac_iocb_rsp {
u8 opcode;
u8 flags;
#define OB_MAC_IOCB_RSP_P 0x08
#define OB_MAC_IOCB_RSP_S 0x02
#define OB_MAC_IOCB_RSP_I 0x01
__le16 reserved0;
__le32 transaction_id;
__le32 reserved1;
__le32 reserved2;
};
struct ib_mac_iocb_rsp {
u8 opcode;
u8 flags;
#define IB_MAC_IOCB_RSP_S 0x80
#define IB_MAC_IOCB_RSP_H1 0x40
#define IB_MAC_IOCB_RSP_H0 0x20
#define IB_MAC_IOCB_RSP_B 0x10
#define IB_MAC_IOCB_RSP_M 0x08
#define IB_MAC_IOCB_RSP_MA 0x07
__le16 length;
__le32 reserved;
__le32 ial_low;
__le32 ial_high;
};
struct ob_ip_iocb_req {
u8 opcode;
__le16 flags;
#define OB_IP_IOCB_REQ_O 0x100
#define OB_IP_IOCB_REQ_H 0x008
#define OB_IP_IOCB_REQ_U 0x004
#define OB_IP_IOCB_REQ_D 0x002
#define OB_IP_IOCB_REQ_I 0x001
u8 reserved0;
__le32 transaction_id;
__le16 data_len;
__le16 reserved1;
__le32 hncb_ptr_low;
__le32 hncb_ptr_high;
__le32 buf_addr0_low;
__le32 buf_addr0_high;
__le32 buf_0_len;
__le32 buf_addr1_low;
__le32 buf_addr1_high;
__le32 buf_1_len;
__le32 buf_addr2_low;
__le32 buf_addr2_high;
__le32 buf_2_len;
__le32 reserved2;
__le32 reserved3;
};
/* defines for BufferLength fields above */
#define OB_IP_IOCB_REQ_E 0x80000000
#define OB_IP_IOCB_REQ_C 0x40000000
#define OB_IP_IOCB_REQ_L 0x20000000
#define OB_IP_IOCB_REQ_R 0x10000000
struct ob_ip_iocb_rsp {
u8 opcode;
u8 flags;
#define OB_MAC_IOCB_RSP_E 0x08
#define OB_MAC_IOCB_RSP_L 0x04
#define OB_MAC_IOCB_RSP_S 0x02
#define OB_MAC_IOCB_RSP_I 0x01
__le16 reserved0;
__le32 transaction_id;
__le32 reserved1;
__le32 reserved2;
};
struct ob_tcp_iocb_req {
u8 opcode;
u8 flags0;
#define OB_TCP_IOCB_REQ_P 0x80
#define OB_TCP_IOCB_REQ_CI 0x20
#define OB_TCP_IOCB_REQ_H 0x10
#define OB_TCP_IOCB_REQ_LN 0x08
#define OB_TCP_IOCB_REQ_K 0x04
#define OB_TCP_IOCB_REQ_D 0x02
#define OB_TCP_IOCB_REQ_I 0x01
u8 flags1;
#define OB_TCP_IOCB_REQ_OSM 0x40
#define OB_TCP_IOCB_REQ_URG 0x20
#define OB_TCP_IOCB_REQ_ACK 0x10
#define OB_TCP_IOCB_REQ_PSH 0x08
#define OB_TCP_IOCB_REQ_RST 0x04
#define OB_TCP_IOCB_REQ_SYN 0x02
#define OB_TCP_IOCB_REQ_FIN 0x01
u8 options_len;
#define OB_TCP_IOCB_REQ_OMASK 0xF0
#define OB_TCP_IOCB_REQ_SHIFT 4
__le32 transaction_id;
__le32 data_len;
__le32 hncb_ptr_low;
__le32 hncb_ptr_high;
__le32 buf_addr0_low;
__le32 buf_addr0_high;
__le32 buf_0_len;
__le32 buf_addr1_low;
__le32 buf_addr1_high;
__le32 buf_1_len;
__le32 buf_addr2_low;
__le32 buf_addr2_high;
__le32 buf_2_len;
__le32 time_stamp;
__le32 reserved1;
};
struct ob_tcp_iocb_rsp {
u8 opcode;
u8 flags0;
#define OB_TCP_IOCB_RSP_C 0x20
#define OB_TCP_IOCB_RSP_H 0x10
#define OB_TCP_IOCB_RSP_LN 0x08
#define OB_TCP_IOCB_RSP_K 0x04
#define OB_TCP_IOCB_RSP_D 0x02
#define OB_TCP_IOCB_RSP_I 0x01
u8 flags1;
#define OB_TCP_IOCB_RSP_E 0x10
#define OB_TCP_IOCB_RSP_W 0x08
#define OB_TCP_IOCB_RSP_P 0x04
#define OB_TCP_IOCB_RSP_T 0x02
#define OB_TCP_IOCB_RSP_F 0x01
u8 state;
#define OB_TCP_IOCB_RSP_SMASK 0xF0
#define OB_TCP_IOCB_RSP_SHIFT 4
__le32 transaction_id;
__le32 local_ncb_ptr;
__le32 reserved0;
};
struct ib_ip_iocb_rsp {
u8 opcode;
u8 flags;
#define IB_IP_IOCB_RSP_S 0x80
#define IB_IP_IOCB_RSP_H1 0x40
#define IB_IP_IOCB_RSP_H0 0x20
#define IB_IP_IOCB_RSP_B 0x10
#define IB_IP_IOCB_RSP_M 0x08
#define IB_IP_IOCB_RSP_MA 0x07
__le16 length;
__le16 checksum;
__le16 reserved;
#define IB_IP_IOCB_RSP_R 0x01
__le32 ial_low;
__le32 ial_high;
};
struct ib_tcp_iocb_rsp {
u8 opcode;
u8 flags;
#define IB_TCP_IOCB_RSP_P 0x80
#define IB_TCP_IOCB_RSP_T 0x40
#define IB_TCP_IOCB_RSP_D 0x20
#define IB_TCP_IOCB_RSP_N 0x10
#define IB_TCP_IOCB_RSP_IP 0x03
#define IB_TCP_FLAG_MASK 0xf0
#define IB_TCP_FLAG_IOCB_SYN 0x00
#define TCP_IB_RSP_FLAGS(x) (x->flags & ~IB_TCP_FLAG_MASK)
__le16 length;
__le32 hncb_ref_num;
__le32 ial_low;
__le32 ial_high;
};
struct net_rsp_iocb {
u8 opcode;
u8 flags;
__le16 reserved0;
__le32 reserved[3];
};
#pragma pack()
/*
* Register Definitions...
*/
#define PORT0_PHY_ADDRESS 0x1e00
#define PORT1_PHY_ADDRESS 0x1f00
#define ETHERNET_CRC_SIZE 4
#define MII_SCAN_REGISTER 0x00000001
/* 32-bit ispControlStatus */
enum {
ISP_CONTROL_NP_MASK = 0x0003,
ISP_CONTROL_NP_PCSR = 0x0000,
ISP_CONTROL_NP_HMCR = 0x0001,
ISP_CONTROL_NP_LRAMCR = 0x0002,
ISP_CONTROL_NP_PSR = 0x0003,
ISP_CONTROL_RI = 0x0008,
ISP_CONTROL_CI = 0x0010,
ISP_CONTROL_PI = 0x0020,
ISP_CONTROL_IN = 0x0040,
ISP_CONTROL_BE = 0x0080,
ISP_CONTROL_FN_MASK = 0x0700,
ISP_CONTROL_FN0_NET = 0x0400,
ISP_CONTROL_FN0_SCSI = 0x0500,
ISP_CONTROL_FN1_NET = 0x0600,
ISP_CONTROL_FN1_SCSI = 0x0700,
ISP_CONTROL_LINK_DN_0 = 0x0800,
ISP_CONTROL_LINK_DN_1 = 0x1000,
ISP_CONTROL_FSR = 0x2000,
ISP_CONTROL_FE = 0x4000,
ISP_CONTROL_SR = 0x8000,
};
/* 32-bit ispInterruptMaskReg */
enum {
ISP_IMR_ENABLE_INT = 0x0004,
ISP_IMR_DISABLE_RESET_INT = 0x0008,
ISP_IMR_DISABLE_CMPL_INT = 0x0010,
ISP_IMR_DISABLE_PROC_INT = 0x0020,
};
/* 32-bit serialPortInterfaceReg */
enum {
ISP_SERIAL_PORT_IF_CLK = 0x0001,
ISP_SERIAL_PORT_IF_CS = 0x0002,
ISP_SERIAL_PORT_IF_D0 = 0x0004,
ISP_SERIAL_PORT_IF_DI = 0x0008,
ISP_NVRAM_MASK = (0x000F << 16),
ISP_SERIAL_PORT_IF_WE = 0x0010,
ISP_SERIAL_PORT_IF_NVR_MASK = 0x001F,
ISP_SERIAL_PORT_IF_SCI = 0x0400,
ISP_SERIAL_PORT_IF_SC0 = 0x0800,
ISP_SERIAL_PORT_IF_SCE = 0x1000,
ISP_SERIAL_PORT_IF_SDI = 0x2000,
ISP_SERIAL_PORT_IF_SDO = 0x4000,
ISP_SERIAL_PORT_IF_SDE = 0x8000,
ISP_SERIAL_PORT_IF_I2C_MASK = 0xFC00,
};
/* semaphoreReg */
enum {
QL_RESOURCE_MASK_BASE_CODE = 0x7,
QL_RESOURCE_BITS_BASE_CODE = 0x4,
QL_DRVR_SEM_BITS = (QL_RESOURCE_BITS_BASE_CODE << 1),
QL_DDR_RAM_SEM_BITS = (QL_RESOURCE_BITS_BASE_CODE << 4),
QL_PHY_GIO_SEM_BITS = (QL_RESOURCE_BITS_BASE_CODE << 7),
QL_NVRAM_SEM_BITS = (QL_RESOURCE_BITS_BASE_CODE << 10),
QL_FLASH_SEM_BITS = (QL_RESOURCE_BITS_BASE_CODE << 13),
QL_DRVR_SEM_MASK = (QL_RESOURCE_MASK_BASE_CODE << (1 + 16)),
QL_DDR_RAM_SEM_MASK = (QL_RESOURCE_MASK_BASE_CODE << (4 + 16)),
QL_PHY_GIO_SEM_MASK = (QL_RESOURCE_MASK_BASE_CODE << (7 + 16)),
QL_NVRAM_SEM_MASK = (QL_RESOURCE_MASK_BASE_CODE << (10 + 16)),
QL_FLASH_SEM_MASK = (QL_RESOURCE_MASK_BASE_CODE << (13 + 16)),
};
/*
* QL3XXX memory-mapped registers
* QL3XXX has 4 "pages" of registers, each page occupying
* 256 bytes. Each page has a "common" area at the start and then
* page-specific registers after that.
*/
struct ql3xxx_common_registers {
u32 MB0; /* Offset 0x00 */
u32 MB1; /* Offset 0x04 */
u32 MB2; /* Offset 0x08 */
u32 MB3; /* Offset 0x0c */
u32 MB4; /* Offset 0x10 */
u32 MB5; /* Offset 0x14 */
u32 MB6; /* Offset 0x18 */
u32 MB7; /* Offset 0x1c */
u32 flashBiosAddr;
u32 flashBiosData;
u32 ispControlStatus;
u32 ispInterruptMaskReg;
u32 serialPortInterfaceReg;
u32 semaphoreReg;
u32 reqQProducerIndex;
u32 rspQConsumerIndex;
u32 rxLargeQProducerIndex;
u32 rxSmallQProducerIndex;
u32 arcMadiCommand;
u32 arcMadiData;
};
enum {
EXT_HW_CONFIG_SP_MASK = 0x0006,
EXT_HW_CONFIG_SP_NONE = 0x0000,
EXT_HW_CONFIG_SP_BYTE_PARITY = 0x0002,
EXT_HW_CONFIG_SP_ECC = 0x0004,
EXT_HW_CONFIG_SP_ECCx = 0x0006,
EXT_HW_CONFIG_SIZE_MASK = 0x0060,
EXT_HW_CONFIG_SIZE_128M = 0x0000,
EXT_HW_CONFIG_SIZE_256M = 0x0020,
EXT_HW_CONFIG_SIZE_512M = 0x0040,
EXT_HW_CONFIG_SIZE_INVALID = 0x0060,
EXT_HW_CONFIG_PD = 0x0080,
EXT_HW_CONFIG_FW = 0x0200,
EXT_HW_CONFIG_US = 0x0400,
EXT_HW_CONFIG_DCS_MASK = 0x1800,
EXT_HW_CONFIG_DCS_9MA = 0x0000,
EXT_HW_CONFIG_DCS_15MA = 0x0800,
EXT_HW_CONFIG_DCS_18MA = 0x1000,
EXT_HW_CONFIG_DCS_24MA = 0x1800,
EXT_HW_CONFIG_DDS_MASK = 0x6000,
EXT_HW_CONFIG_DDS_9MA = 0x0000,
EXT_HW_CONFIG_DDS_15MA = 0x2000,
EXT_HW_CONFIG_DDS_18MA = 0x4000,
EXT_HW_CONFIG_DDS_24MA = 0x6000,
};
/* InternalChipConfig */
enum {
INTERNAL_CHIP_DM = 0x0001,
INTERNAL_CHIP_SD = 0x0002,
INTERNAL_CHIP_RAP_MASK = 0x000C,
INTERNAL_CHIP_RAP_RR = 0x0000,
INTERNAL_CHIP_RAP_NRM = 0x0004,
INTERNAL_CHIP_RAP_ERM = 0x0008,
INTERNAL_CHIP_RAP_ERMx = 0x000C,
INTERNAL_CHIP_WE = 0x0010,
INTERNAL_CHIP_EF = 0x0020,
INTERNAL_CHIP_FR = 0x0040,
INTERNAL_CHIP_FW = 0x0080,
INTERNAL_CHIP_FI = 0x0100,
INTERNAL_CHIP_FT = 0x0200,
};
/* portControl */
enum {
PORT_CONTROL_DS = 0x0001,
PORT_CONTROL_HH = 0x0002,
PORT_CONTROL_EI = 0x0004,
PORT_CONTROL_ET = 0x0008,
PORT_CONTROL_EF = 0x0010,
PORT_CONTROL_DRM = 0x0020,
PORT_CONTROL_RLB = 0x0040,
PORT_CONTROL_RCB = 0x0080,
PORT_CONTROL_MAC = 0x0100,
PORT_CONTROL_IPV = 0x0200,
PORT_CONTROL_IFP = 0x0400,
PORT_CONTROL_ITP = 0x0800,
PORT_CONTROL_FI = 0x1000,
PORT_CONTROL_DFP = 0x2000,
PORT_CONTROL_OI = 0x4000,
PORT_CONTROL_CC = 0x8000,
};
/* portStatus */
enum {
PORT_STATUS_SM0 = 0x0001,
PORT_STATUS_SM1 = 0x0002,
PORT_STATUS_X = 0x0008,
PORT_STATUS_DL = 0x0080,
PORT_STATUS_IC = 0x0200,
PORT_STATUS_MRC = 0x0400,
PORT_STATUS_NL = 0x0800,
PORT_STATUS_REV_ID_MASK = 0x7000,
PORT_STATUS_REV_ID_1 = 0x1000,
PORT_STATUS_REV_ID_2 = 0x2000,
PORT_STATUS_REV_ID_3 = 0x3000,
PORT_STATUS_64 = 0x8000,
PORT_STATUS_UP0 = 0x10000,
PORT_STATUS_AC0 = 0x20000,
PORT_STATUS_AE0 = 0x40000,
PORT_STATUS_UP1 = 0x100000,
PORT_STATUS_AC1 = 0x200000,
PORT_STATUS_AE1 = 0x400000,
PORT_STATUS_F0_ENABLED = 0x1000000,
PORT_STATUS_F1_ENABLED = 0x2000000,
PORT_STATUS_F2_ENABLED = 0x4000000,
PORT_STATUS_F3_ENABLED = 0x8000000,
};
/* macMIIMgmtControlReg */
enum {
MAC_ADDR_INDIRECT_PTR_REG_RP_MASK = 0x0003,
MAC_ADDR_INDIRECT_PTR_REG_RP_PRI_LWR = 0x0000,
MAC_ADDR_INDIRECT_PTR_REG_RP_PRI_UPR = 0x0001,
MAC_ADDR_INDIRECT_PTR_REG_RP_SEC_LWR = 0x0002,
MAC_ADDR_INDIRECT_PTR_REG_RP_SEC_UPR = 0x0003,
MAC_ADDR_INDIRECT_PTR_REG_PR = 0x0008,
MAC_ADDR_INDIRECT_PTR_REG_SS = 0x0010,
MAC_ADDR_INDIRECT_PTR_REG_SE = 0x0020,
MAC_ADDR_INDIRECT_PTR_REG_SP = 0x0040,
MAC_ADDR_INDIRECT_PTR_REG_PE = 0x0080,
};
/* macMIIMgmtControlReg */
enum {
MAC_MII_CONTROL_RC = 0x0001,
MAC_MII_CONTROL_SC = 0x0002,
MAC_MII_CONTROL_AS = 0x0004,
MAC_MII_CONTROL_NP = 0x0008,
MAC_MII_CONTROL_CLK_SEL_MASK = 0x0070,
MAC_MII_CONTROL_CLK_SEL_DIV2 = 0x0000,
MAC_MII_CONTROL_CLK_SEL_DIV4 = 0x0010,
MAC_MII_CONTROL_CLK_SEL_DIV6 = 0x0020,
MAC_MII_CONTROL_CLK_SEL_DIV8 = 0x0030,
MAC_MII_CONTROL_CLK_SEL_DIV10 = 0x0040,
MAC_MII_CONTROL_CLK_SEL_DIV14 = 0x0050,
MAC_MII_CONTROL_CLK_SEL_DIV20 = 0x0060,
MAC_MII_CONTROL_CLK_SEL_DIV28 = 0x0070,
MAC_MII_CONTROL_RM = 0x8000,
};
/* macMIIStatusReg */
enum {
MAC_MII_STATUS_BSY = 0x0001,
MAC_MII_STATUS_SC = 0x0002,
MAC_MII_STATUS_NV = 0x0004,
};
enum {
MAC_CONFIG_REG_PE = 0x0001,
MAC_CONFIG_REG_TF = 0x0002,
MAC_CONFIG_REG_RF = 0x0004,
MAC_CONFIG_REG_FD = 0x0008,
MAC_CONFIG_REG_GM = 0x0010,
MAC_CONFIG_REG_LB = 0x0020,
MAC_CONFIG_REG_SR = 0x8000,
};
enum {
MAC_HALF_DUPLEX_REG_ED = 0x10000,
MAC_HALF_DUPLEX_REG_NB = 0x20000,
MAC_HALF_DUPLEX_REG_BNB = 0x40000,
MAC_HALF_DUPLEX_REG_ALT = 0x80000,
};
enum {
IP_ADDR_INDEX_REG_MASK = 0x000f,
IP_ADDR_INDEX_REG_FUNC_0_PRI = 0x0000,
IP_ADDR_INDEX_REG_FUNC_0_SEC = 0x0001,
IP_ADDR_INDEX_REG_FUNC_1_PRI = 0x0002,
IP_ADDR_INDEX_REG_FUNC_1_SEC = 0x0003,
IP_ADDR_INDEX_REG_FUNC_2_PRI = 0x0004,
IP_ADDR_INDEX_REG_FUNC_2_SEC = 0x0005,
IP_ADDR_INDEX_REG_FUNC_3_PRI = 0x0006,
IP_ADDR_INDEX_REG_FUNC_3_SEC = 0x0007,
};
enum {
PROBE_MUX_ADDR_REG_MUX_SEL_MASK = 0x003f,
PROBE_MUX_ADDR_REG_SYSCLK = 0x0000,
PROBE_MUX_ADDR_REG_PCICLK = 0x0040,
PROBE_MUX_ADDR_REG_NRXCLK = 0x0080,
PROBE_MUX_ADDR_REG_CPUCLK = 0x00C0,
PROBE_MUX_ADDR_REG_MODULE_SEL_MASK = 0x3f00,
PROBE_MUX_ADDR_REG_UP = 0x4000,
PROBE_MUX_ADDR_REG_RE = 0x8000,
};
enum {
STATISTICS_INDEX_REG_MASK = 0x01ff,
STATISTICS_INDEX_REG_MAC0_TX_FRAME = 0x0000,
STATISTICS_INDEX_REG_MAC0_TX_BYTES = 0x0001,
STATISTICS_INDEX_REG_MAC0_TX_STAT1 = 0x0002,
STATISTICS_INDEX_REG_MAC0_TX_STAT2 = 0x0003,
STATISTICS_INDEX_REG_MAC0_TX_STAT3 = 0x0004,
STATISTICS_INDEX_REG_MAC0_TX_STAT4 = 0x0005,
STATISTICS_INDEX_REG_MAC0_TX_STAT5 = 0x0006,
STATISTICS_INDEX_REG_MAC0_RX_FRAME = 0x0007,
STATISTICS_INDEX_REG_MAC0_RX_BYTES = 0x0008,
STATISTICS_INDEX_REG_MAC0_RX_STAT1 = 0x0009,
STATISTICS_INDEX_REG_MAC0_RX_STAT2 = 0x000a,
STATISTICS_INDEX_REG_MAC0_RX_STAT3 = 0x000b,
STATISTICS_INDEX_REG_MAC0_RX_ERR_CRC = 0x000c,
STATISTICS_INDEX_REG_MAC0_RX_ERR_ENC = 0x000d,
STATISTICS_INDEX_REG_MAC0_RX_ERR_LEN = 0x000e,
STATISTICS_INDEX_REG_MAC0_RX_STAT4 = 0x000f,
STATISTICS_INDEX_REG_MAC1_TX_FRAME = 0x0010,
STATISTICS_INDEX_REG_MAC1_TX_BYTES = 0x0011,
STATISTICS_INDEX_REG_MAC1_TX_STAT1 = 0x0012,
STATISTICS_INDEX_REG_MAC1_TX_STAT2 = 0x0013,
STATISTICS_INDEX_REG_MAC1_TX_STAT3 = 0x0014,
STATISTICS_INDEX_REG_MAC1_TX_STAT4 = 0x0015,
STATISTICS_INDEX_REG_MAC1_TX_STAT5 = 0x0016,
STATISTICS_INDEX_REG_MAC1_RX_FRAME = 0x0017,
STATISTICS_INDEX_REG_MAC1_RX_BYTES = 0x0018,
STATISTICS_INDEX_REG_MAC1_RX_STAT1 = 0x0019,
STATISTICS_INDEX_REG_MAC1_RX_STAT2 = 0x001a,
STATISTICS_INDEX_REG_MAC1_RX_STAT3 = 0x001b,
STATISTICS_INDEX_REG_MAC1_RX_ERR_CRC = 0x001c,
STATISTICS_INDEX_REG_MAC1_RX_ERR_ENC = 0x001d,
STATISTICS_INDEX_REG_MAC1_RX_ERR_LEN = 0x001e,
STATISTICS_INDEX_REG_MAC1_RX_STAT4 = 0x001f,
STATISTICS_INDEX_REG_IP_TX_PKTS = 0x0020,
STATISTICS_INDEX_REG_IP_TX_BYTES = 0x0021,
STATISTICS_INDEX_REG_IP_TX_FRAG = 0x0022,
STATISTICS_INDEX_REG_IP_RX_PKTS = 0x0023,
STATISTICS_INDEX_REG_IP_RX_BYTES = 0x0024,
STATISTICS_INDEX_REG_IP_RX_FRAG = 0x0025,
STATISTICS_INDEX_REG_IP_DGRM_REASSEMBLY = 0x0026,
STATISTICS_INDEX_REG_IP_V6_RX_PKTS = 0x0027,
STATISTICS_INDEX_REG_IP_RX_PKTERR = 0x0028,
STATISTICS_INDEX_REG_IP_REASSEMBLY_ERR = 0x0029,
STATISTICS_INDEX_REG_TCP_TX_SEG = 0x0030,
STATISTICS_INDEX_REG_TCP_TX_BYTES = 0x0031,
STATISTICS_INDEX_REG_TCP_RX_SEG = 0x0032,
STATISTICS_INDEX_REG_TCP_RX_BYTES = 0x0033,
STATISTICS_INDEX_REG_TCP_TIMER_EXP = 0x0034,
STATISTICS_INDEX_REG_TCP_RX_ACK = 0x0035,
STATISTICS_INDEX_REG_TCP_TX_ACK = 0x0036,
STATISTICS_INDEX_REG_TCP_RX_ERR = 0x0037,
STATISTICS_INDEX_REG_TCP_RX_WIN_PROBE = 0x0038,
STATISTICS_INDEX_REG_TCP_ECC_ERR_CORR = 0x003f,
};
enum {
PORT_FATAL_ERROR_STATUS_OFB_RE_MAC0 = 0x00000001,
PORT_FATAL_ERROR_STATUS_OFB_RE_MAC1 = 0x00000002,
PORT_FATAL_ERROR_STATUS_OFB_WE = 0x00000004,
PORT_FATAL_ERROR_STATUS_IFB_RE = 0x00000008,
PORT_FATAL_ERROR_STATUS_IFB_WE_MAC0 = 0x00000010,
PORT_FATAL_ERROR_STATUS_IFB_WE_MAC1 = 0x00000020,
PORT_FATAL_ERROR_STATUS_ODE_RE = 0x00000040,
PORT_FATAL_ERROR_STATUS_ODE_WE = 0x00000080,
PORT_FATAL_ERROR_STATUS_IDE_RE = 0x00000100,
PORT_FATAL_ERROR_STATUS_IDE_WE = 0x00000200,
PORT_FATAL_ERROR_STATUS_SDE_RE = 0x00000400,
PORT_FATAL_ERROR_STATUS_SDE_WE = 0x00000800,
PORT_FATAL_ERROR_STATUS_BLE = 0x00001000,
PORT_FATAL_ERROR_STATUS_SPE = 0x00002000,
PORT_FATAL_ERROR_STATUS_EP0 = 0x00004000,
PORT_FATAL_ERROR_STATUS_EP1 = 0x00008000,
PORT_FATAL_ERROR_STATUS_ICE = 0x00010000,
PORT_FATAL_ERROR_STATUS_ILE = 0x00020000,
PORT_FATAL_ERROR_STATUS_OPE = 0x00040000,
PORT_FATAL_ERROR_STATUS_TA = 0x00080000,
PORT_FATAL_ERROR_STATUS_MA = 0x00100000,
PORT_FATAL_ERROR_STATUS_SCE = 0x00200000,
PORT_FATAL_ERROR_STATUS_RPE = 0x00400000,
PORT_FATAL_ERROR_STATUS_MPE = 0x00800000,
PORT_FATAL_ERROR_STATUS_OCE = 0x01000000,
};
/*
* port control and status page - page 0
*/
struct ql3xxx_port_registers {
struct ql3xxx_common_registers CommonRegs;
u32 ExternalHWConfig;
u32 InternalChipConfig;
u32 portControl;
u32 portStatus;
u32 macAddrIndirectPtrReg;
u32 macAddrDataReg;
u32 macMIIMgmtControlReg;
u32 macMIIMgmtAddrReg;
u32 macMIIMgmtDataReg;
u32 macMIIStatusReg;
u32 mac0ConfigReg;
u32 mac0IpgIfgReg;
u32 mac0HalfDuplexReg;
u32 mac0MaxFrameLengthReg;
u32 mac0PauseThresholdReg;
u32 mac1ConfigReg;
u32 mac1IpgIfgReg;
u32 mac1HalfDuplexReg;
u32 mac1MaxFrameLengthReg;
u32 mac1PauseThresholdReg;
u32 ipAddrIndexReg;
u32 ipAddrDataReg;
u32 ipReassemblyTimeout;
u32 tcpMaxWindow;
u32 currentTcpTimestamp[2];
u32 internalRamRWAddrReg;
u32 internalRamWDataReg;
u32 reclaimedBufferAddrRegLow;
u32 reclaimedBufferAddrRegHigh;
u32 reserved[2];
u32 fpgaRevID;
u32 localRamAddr;
u32 localRamDataAutoIncr;
u32 localRamDataNonIncr;
u32 gpOutput;
u32 gpInput;
u32 probeMuxAddr;
u32 probeMuxData;
u32 statisticsIndexReg;
u32 statisticsReadDataRegAutoIncr;
u32 statisticsReadDataRegNoIncr;
u32 PortFatalErrStatus;
};
/*
* port host memory config page - page 1
*/
struct ql3xxx_host_memory_registers {
struct ql3xxx_common_registers CommonRegs;
u32 reserved[12];
/* Network Request Queue */
u32 reqConsumerIndex;
u32 reqConsumerIndexAddrLow;
u32 reqConsumerIndexAddrHigh;
u32 reqBaseAddrLow;
u32 reqBaseAddrHigh;
u32 reqLength;
/* Network Completion Queue */
u32 rspProducerIndex;
u32 rspProducerIndexAddrLow;
u32 rspProducerIndexAddrHigh;
u32 rspBaseAddrLow;
u32 rspBaseAddrHigh;
u32 rspLength;
/* RX Large Buffer Queue */
u32 rxLargeQConsumerIndex;
u32 rxLargeQBaseAddrLow;
u32 rxLargeQBaseAddrHigh;
u32 rxLargeQLength;
u32 rxLargeBufferLength;
/* RX Small Buffer Queue */
u32 rxSmallQConsumerIndex;
u32 rxSmallQBaseAddrLow;
u32 rxSmallQBaseAddrHigh;
u32 rxSmallQLength;
u32 rxSmallBufferLength;
};
/*
* port local RAM page - page 2
*/
struct ql3xxx_local_ram_registers {
struct ql3xxx_common_registers CommonRegs;
u32 bufletSize;
u32 maxBufletCount;
u32 currentBufletCount;
u32 reserved;
u32 freeBufletThresholdLow;
u32 freeBufletThresholdHigh;
u32 ipHashTableBase;
u32 ipHashTableCount;
u32 tcpHashTableBase;
u32 tcpHashTableCount;
u32 ncbBase;
u32 maxNcbCount;
u32 currentNcbCount;
u32 drbBase;
u32 maxDrbCount;
u32 currentDrbCount;
};
/*
* definitions for Semaphore bits in Semaphore/Serial NVRAM interface register
*/
#define LS_64BITS(x) (u32)(0xffffffff & ((u64)x))
#define MS_64BITS(x) (u32)(0xffffffff & (((u64)x)>>16>>16) )
/*
* I/O register
*/
enum {
CONTROL_REG = 0,
STATUS_REG = 1,
PHY_STAT_LINK_UP = 0x0004,
PHY_CTRL_LOOPBACK = 0x4000,
PETBI_CONTROL_REG = 0x00,
PETBI_CTRL_SOFT_RESET = 0x8000,
PETBI_CTRL_AUTO_NEG = 0x1000,
PETBI_CTRL_RESTART_NEG = 0x0200,
PETBI_CTRL_FULL_DUPLEX = 0x0100,
PETBI_CTRL_SPEED_1000 = 0x0040,
PETBI_STATUS_REG = 0x01,
PETBI_STAT_NEG_DONE = 0x0020,
PETBI_STAT_LINK_UP = 0x0004,
PETBI_NEG_ADVER = 0x04,
PETBI_NEG_PAUSE = 0x0080,
PETBI_NEG_PAUSE_MASK = 0x0180,
PETBI_NEG_DUPLEX = 0x0020,
PETBI_NEG_DUPLEX_MASK = 0x0060,
PETBI_NEG_PARTNER = 0x05,
PETBI_NEG_ERROR_MASK = 0x3000,
PETBI_EXPANSION_REG = 0x06,
PETBI_EXP_PAGE_RX = 0x0002,
PETBI_TBI_CTRL = 0x11,
PETBI_TBI_RESET = 0x8000,
PETBI_TBI_AUTO_SENSE = 0x0100,
PETBI_TBI_SERDES_MODE = 0x0010,
PETBI_TBI_SERDES_WRAP = 0x0002,
AUX_CONTROL_STATUS = 0x1c,
PHY_AUX_NEG_DONE = 0x8000,
PHY_NEG_PARTNER = 5,
PHY_AUX_DUPLEX_STAT = 0x0020,
PHY_AUX_SPEED_STAT = 0x0018,
PHY_AUX_NO_HW_STRAP = 0x0004,
PHY_AUX_RESET_STICK = 0x0002,
PHY_NEG_PAUSE = 0x0400,
PHY_CTRL_SOFT_RESET = 0x8000,
PHY_NEG_ADVER = 4,
PHY_NEG_ADV_SPEED = 0x01e0,
PHY_CTRL_RESTART_NEG = 0x0200,
};
enum {
/* AM29LV Flash definitions */
FM93C56A_START = 0x1,
/* Commands */
FM93C56A_READ = 0x2,
FM93C56A_WEN = 0x0,
FM93C56A_WRITE = 0x1,
FM93C56A_WRITE_ALL = 0x0,
FM93C56A_WDS = 0x0,
FM93C56A_ERASE = 0x3,
FM93C56A_ERASE_ALL = 0x0,
/* Command Extentions */
FM93C56A_WEN_EXT = 0x3,
FM93C56A_WRITE_ALL_EXT = 0x1,
FM93C56A_WDS_EXT = 0x0,
FM93C56A_ERASE_ALL_EXT = 0x2,
/* Special Bits */
FM93C56A_READ_DUMMY_BITS = 1,
FM93C56A_READY = 0,
FM93C56A_BUSY = 1,
FM93C56A_CMD_BITS = 2,
/* AM29LV Flash definitions */
FM93C56A_SIZE_8 = 0x100,
FM93C56A_SIZE_16 = 0x80,
FM93C66A_SIZE_8 = 0x200,
FM93C66A_SIZE_16 = 0x100,
FM93C86A_SIZE_16 = 0x400,
/* Address Bits */
FM93C56A_NO_ADDR_BITS_16 = 8,
FM93C56A_NO_ADDR_BITS_8 = 9,
FM93C86A_NO_ADDR_BITS_16 = 10,
/* Data Bits */
FM93C56A_DATA_BITS_16 = 16,
FM93C56A_DATA_BITS_8 = 8,
};
enum {
/* Auburn Bits */
AUBURN_EEPROM_DI = 0x8,
AUBURN_EEPROM_DI_0 = 0x0,
AUBURN_EEPROM_DI_1 = 0x8,
AUBURN_EEPROM_DO = 0x4,
AUBURN_EEPROM_DO_0 = 0x0,
AUBURN_EEPROM_DO_1 = 0x4,
AUBURN_EEPROM_CS = 0x2,
AUBURN_EEPROM_CS_0 = 0x0,
AUBURN_EEPROM_CS_1 = 0x2,
AUBURN_EEPROM_CLK_RISE = 0x1,
AUBURN_EEPROM_CLK_FALL = 0x0,
};
enum {EEPROM_SIZE = FM93C86A_SIZE_16,
EEPROM_NO_ADDR_BITS = FM93C86A_NO_ADDR_BITS_16,
EEPROM_NO_DATA_BITS = FM93C56A_DATA_BITS_16,
};
/*
* MAC Config data structure
*/
struct eeprom_port_cfg {
u16 etherMtu_mac;
u16 pauseThreshold_mac;
u16 resumeThreshold_mac;
u16 portConfiguration;
#define PORT_CONFIG_AUTO_NEG_ENABLED 0x8000
#define PORT_CONFIG_SYM_PAUSE_ENABLED 0x4000
#define PORT_CONFIG_FULL_DUPLEX_ENABLED 0x2000
#define PORT_CONFIG_HALF_DUPLEX_ENABLED 0x1000
#define PORT_CONFIG_1000MB_SPEED 0x0400
#define PORT_CONFIG_100MB_SPEED 0x0200
#define PORT_CONFIG_10MB_SPEED 0x0100
#define PORT_CONFIG_LINK_SPEED_MASK 0x0F00
u16 reserved[12];
};
/*
* BIOS data structure
*/
struct eeprom_bios_cfg {
u16 SpinDlyEn:1, disBios:1, EnMemMap:1, EnSelectBoot:1, Reserved:12;
u8 bootID0:7, boodID0Valid:1;
u8 bootLun0[8];
u8 bootID1:7, boodID1Valid:1;
u8 bootLun1[8];
u16 MaxLunsTrgt;
u8 reserved[10];
};
/*
* Function Specific Data structure
*/
struct eeprom_function_cfg {
u8 reserved[30];
u8 macAddress[6];
u8 macAddressSecondary[6];
u16 subsysVendorId;
u16 subsysDeviceId;
};
/*
* EEPROM format
*/
struct eeprom_data {
u8 asicId[4];
u8 version;
u8 numPorts;
u16 boardId;
#define EEPROM_BOARDID_STR_SIZE 16
#define EEPROM_SERIAL_NUM_SIZE 16
u8 boardIdStr[16];
u8 serialNumber[16];
u16 extHwConfig;
struct eeprom_port_cfg macCfg_port0;
struct eeprom_port_cfg macCfg_port1;
u16 bufletSize;
u16 bufletCount;
u16 tcpWindowThreshold50;
u16 tcpWindowThreshold25;
u16 tcpWindowThreshold0;
u16 ipHashTableBaseHi;
u16 ipHashTableBaseLo;
u16 ipHashTableSize;
u16 tcpHashTableBaseHi;
u16 tcpHashTableBaseLo;
u16 tcpHashTableSize;
u16 ncbTableBaseHi;
u16 ncbTableBaseLo;
u16 ncbTableSize;
u16 drbTableBaseHi;
u16 drbTableBaseLo;
u16 drbTableSize;
u16 reserved_142[4];
u16 ipReassemblyTimeout;
u16 tcpMaxWindowSize;
u16 ipSecurity;
#define IPSEC_CONFIG_PRESENT 0x0001
u8 reserved_156[294];
u16 qDebug[8];
struct eeprom_function_cfg funcCfg_fn0;
u16 reserved_510;
u8 oemSpace[432];
struct eeprom_bios_cfg biosCfg_fn1;
struct eeprom_function_cfg funcCfg_fn1;
u16 reserved_1022;
u8 reserved_1024[464];
struct eeprom_function_cfg funcCfg_fn2;
u16 reserved_1534;
u8 reserved_1536[432];
struct eeprom_bios_cfg biosCfg_fn3;
struct eeprom_function_cfg funcCfg_fn3;
u16 checksum;
};
/*
* General definitions...
*/
/*
* Below are a number compiler switches for controlling driver behavior.
* Some are not supported under certain conditions and are notated as such.
*/
#define QL3XXX_VENDOR_ID 0x1077
#define QL3022_DEVICE_ID 0x3022
/* MTU & Frame Size stuff */
#define NORMAL_MTU_SIZE ETH_DATA_LEN
#define JUMBO_MTU_SIZE 9000
#define VLAN_ID_LEN 2
/* Request Queue Related Definitions */
#define NUM_REQ_Q_ENTRIES 256 /* so that 64 * 64 = 4096 (1 page) */
/* Response Queue Related Definitions */
#define NUM_RSP_Q_ENTRIES 256 /* so that 256 * 16 = 4096 (1 page) */
/* Transmit and Receive Buffers */
#define NUM_LBUFQ_ENTRIES 128
#define NUM_SBUFQ_ENTRIES 64
#define QL_SMALL_BUFFER_SIZE 32
#define QL_ADDR_ELE_PER_BUFQ_ENTRY \
(sizeof(struct lrg_buf_q_entry) / sizeof(struct bufq_addr_element))
/* Each send has at least control block. This is how many we keep. */
#define NUM_SMALL_BUFFERS NUM_SBUFQ_ENTRIES * QL_ADDR_ELE_PER_BUFQ_ENTRY
#define NUM_LARGE_BUFFERS NUM_LBUFQ_ENTRIES * QL_ADDR_ELE_PER_BUFQ_ENTRY
#define QL_HEADER_SPACE 32 /* make header space at top of skb. */
/*
* Large & Small Buffers for Receives
*/
struct lrg_buf_q_entry {
u32 addr0_lower;
#define IAL_LAST_ENTRY 0x00000001
#define IAL_CONT_ENTRY 0x00000002
#define IAL_FLAG_MASK 0x00000003
u32 addr0_upper;
u32 addr1_lower;
u32 addr1_upper;
u32 addr2_lower;
u32 addr2_upper;
u32 addr3_lower;
u32 addr3_upper;
u32 addr4_lower;
u32 addr4_upper;
u32 addr5_lower;
u32 addr5_upper;
u32 addr6_lower;
u32 addr6_upper;
u32 addr7_lower;
u32 addr7_upper;
};
struct bufq_addr_element {
u32 addr_low;
u32 addr_high;
};
#define QL_NO_RESET 0
#define QL_DO_RESET 1
enum link_state_t {
LS_UNKNOWN = 0,
LS_DOWN,
LS_DEGRADE,
LS_RECOVER,
LS_UP,
};
struct ql_rcv_buf_cb {
struct ql_rcv_buf_cb *next;
struct sk_buff *skb;
DECLARE_PCI_UNMAP_ADDR(mapaddr);
DECLARE_PCI_UNMAP_LEN(maplen);
__le32 buf_phy_addr_low;
__le32 buf_phy_addr_high;
int index;
};
struct ql_tx_buf_cb {
struct sk_buff *skb;
struct ob_mac_iocb_req *queue_entry ;
DECLARE_PCI_UNMAP_ADDR(mapaddr);
DECLARE_PCI_UNMAP_LEN(maplen);
};
/* definitions for type field */
#define QL_BUF_TYPE_MACIOCB 0x01
#define QL_BUF_TYPE_IPIOCB 0x02
#define QL_BUF_TYPE_TCPIOCB 0x03
/* qdev->flags definitions. */
enum { QL_RESET_DONE = 1, /* Reset finished. */
QL_RESET_ACTIVE = 2, /* Waiting for reset to finish. */
QL_RESET_START = 3, /* Please reset the chip. */
QL_RESET_PER_SCSI = 4, /* SCSI driver requests reset. */
QL_TX_TIMEOUT = 5, /* Timeout in progress. */
QL_LINK_MASTER = 6, /* This driver controls the link. */
QL_ADAPTER_UP = 7, /* Adapter has been brought up. */
QL_THREAD_UP = 8, /* This flag is available. */
QL_LINK_UP = 9, /* Link Status. */
QL_ALLOC_REQ_RSP_Q_DONE = 10,
QL_ALLOC_BUFQS_DONE = 11,
QL_ALLOC_SMALL_BUF_DONE = 12,
QL_LINK_OPTICAL = 13,
QL_MSI_ENABLED = 14,
};
/*
* ql3_adapter - The main Adapter structure definition.
* This structure has all fields relevant to the hardware.
*/
struct ql3_adapter {
u32 reserved_00;
unsigned long flags;
/* PCI Configuration information for this device */
struct pci_dev *pdev;
struct net_device *ndev; /* Parent NET device */
/* Hardware information */
u8 chip_rev_id;
u8 pci_slot;
u8 pci_width;
u8 pci_x;
u32 msi;
int index;
struct timer_list adapter_timer; /* timer used for various functions */
spinlock_t adapter_lock;
spinlock_t hw_lock;
/* PCI Bus Relative Register Addresses */
u8 *mmap_virt_base; /* stores return value from ioremap() */
struct ql3xxx_port_registers __iomem *mem_map_registers;
u32 current_page; /* tracks current register page */
u32 msg_enable;
u8 reserved_01[2];
u8 reserved_02[2];
/* Page for Shadow Registers */
void *shadow_reg_virt_addr;
dma_addr_t shadow_reg_phy_addr;
/* Net Request Queue */
u32 req_q_size;
u32 reserved_03;
struct ob_mac_iocb_req *req_q_virt_addr;
dma_addr_t req_q_phy_addr;
u16 req_producer_index;
u16 reserved_04;
u16 *preq_consumer_index;
u32 req_consumer_index_phy_addr_high;
u32 req_consumer_index_phy_addr_low;
atomic_t tx_count;
struct ql_tx_buf_cb tx_buf[NUM_REQ_Q_ENTRIES];
/* Net Response Queue */
u32 rsp_q_size;
u32 eeprom_cmd_data;
struct net_rsp_iocb *rsp_q_virt_addr;
dma_addr_t rsp_q_phy_addr;
struct net_rsp_iocb *rsp_current;
u16 rsp_consumer_index;
u16 reserved_06;
u32 *prsp_producer_index;
u32 rsp_producer_index_phy_addr_high;
u32 rsp_producer_index_phy_addr_low;
/* Large Buffer Queue */
u32 lrg_buf_q_alloc_size;
u32 lrg_buf_q_size;
void *lrg_buf_q_alloc_virt_addr;
void *lrg_buf_q_virt_addr;
dma_addr_t lrg_buf_q_alloc_phy_addr;
dma_addr_t lrg_buf_q_phy_addr;
u32 lrg_buf_q_producer_index;
u32 lrg_buf_release_cnt;
struct bufq_addr_element *lrg_buf_next_free;
/* Large (Receive) Buffers */
struct ql_rcv_buf_cb lrg_buf[NUM_LARGE_BUFFERS];
struct ql_rcv_buf_cb *lrg_buf_free_head;
struct ql_rcv_buf_cb *lrg_buf_free_tail;
u32 lrg_buf_free_count;
u32 lrg_buffer_len;
u32 lrg_buf_index;
u32 lrg_buf_skb_check;
/* Small Buffer Queue */
u32 small_buf_q_alloc_size;
u32 small_buf_q_size;
u32 small_buf_q_producer_index;
void *small_buf_q_alloc_virt_addr;
void *small_buf_q_virt_addr;
dma_addr_t small_buf_q_alloc_phy_addr;
dma_addr_t small_buf_q_phy_addr;
u32 small_buf_index;
/* Small (Receive) Buffers */
void *small_buf_virt_addr;
dma_addr_t small_buf_phy_addr;
u32 small_buf_phy_addr_low;
u32 small_buf_phy_addr_high;
u32 small_buf_release_cnt;
u32 small_buf_total_size;
/* ISR related, saves status for DPC. */
u32 control_status;
struct eeprom_data nvram_data;
struct timer_list ioctl_timer;
u32 port_link_state;
u32 last_rsp_offset;
/* 4022 specific */
u32 mac_index; /* Driver's MAC number can be 0 or 1 for first and second networking functions respectively */
u32 PHYAddr; /* Address of PHY 0x1e00 Port 0 and 0x1f00 Port 1 */
u32 mac_ob_opcode; /* Opcode to use on mac transmission */
u32 tcp_ob_opcode; /* Opcode to use on tcp transmission */
u32 update_ob_opcode; /* Opcode to use for updating NCB */
u32 mb_bit_mask; /* MA Bits mask to use on transmission */
u32 numPorts;
struct net_device_stats stats;
struct workqueue_struct *workqueue;
struct work_struct reset_work;
struct work_struct tx_timeout_work;
u32 max_frame_size;
};
#endif /* _QLA3XXX_H_ */
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