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staging: silicom: remove driver

Browse source 
The driver hasn't been cleaned up and it doesn't look like anyone is
working on it anymore (including the original author). So remove it.
If someone wants to work on cleaning the driver up and moving it out of
staging, this commit can be reverted.

In addition, since this removes the CONFIG_NET_VENDOR_SILICOM config
symbol, remove the symbol from all defconfig files that reference it.

Signed-off-by: Kristina Martšenko <kristina.martsenko@gmail.com>
Cc: Daniel Cotey <puff65537@bansheeslibrary.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
This commit is contained in:
Kristina Martšenko 2014-07-25 02:30:46 +03:00 committed by Greg Kroah-Hartman
parent 8fa6cfc732
commit ad8c12eea0
20 changed files with 0 additions and 10576 deletions
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1
arch/mips/configs/cavium_octeon_defconfig
View file

@ -124,7 +124,6 @@ CONFIG_RTC_CLASS=y
CONFIG_RTC_DRV_DS1307=y
CONFIG_STAGING=y
CONFIG_OCTEON_ETHERNET=y
# CONFIG_NET_VENDOR_SILICOM is not set
# CONFIG_IOMMU_SUPPORT is not set
CONFIG_EXT4_FS=y
CONFIG_EXT4_FS_POSIX_ACL=y

1
arch/parisc/configs/generic-64bit_defconfig
View file

@ -241,7 +241,6 @@ CONFIG_UIO_AEC=m
CONFIG_UIO_SERCOS3=m
CONFIG_UIO_PCI_GENERIC=m
CONFIG_STAGING=y
# CONFIG_NET_VENDOR_SILICOM is not set
CONFIG_EXT2_FS=y
CONFIG_EXT2_FS_XATTR=y
CONFIG_EXT2_FS_SECURITY=y

1
arch/powerpc/configs/85xx/kmp204x_defconfig
View file

@ -192,7 +192,6 @@ CONFIG_RTC_DRV_DS3232=y
CONFIG_RTC_DRV_CMOS=y
CONFIG_UIO=y
CONFIG_STAGING=y
# CONFIG_NET_VENDOR_SILICOM is not set
CONFIG_CLK_PPC_CORENET=y
CONFIG_EXT2_FS=y
CONFIG_NTFS_FS=y

2
drivers/staging/Kconfig
View file

@ -96,8 +96,6 @@ source "drivers/staging/gdm72xx/Kconfig"
source "drivers/staging/gdm724x/Kconfig"
source "drivers/staging/silicom/Kconfig"
source "drivers/staging/imx-drm/Kconfig"
source "drivers/staging/fwserial/Kconfig"

1
drivers/staging/Makefile
View file

@ -41,7 +41,6 @@ obj-$(CONFIG_STAGING_BOARD) += board/
obj-$(CONFIG_USB_WPAN_HCD) += ozwpan/
obj-$(CONFIG_WIMAX_GDM72XX) += gdm72xx/
obj-$(CONFIG_LTE_GDM724X) += gdm724x/
obj-$(CONFIG_NET_VENDOR_SILICOM) += silicom/
obj-$(CONFIG_DRM_IMX) += imx-drm/
obj-$(CONFIG_FIREWIRE_SERIAL) += fwserial/
obj-$(CONFIG_GOLDFISH) += goldfish/

45
drivers/staging/silicom/Kconfig
View file

@ -1,45 +0,0 @@
#
# Silicom device configuration
#
config NET_VENDOR_SILICOM
bool "Silicom devices"
default y
depends on PCI && NETDEVICES
---help---
If you have a network card (Ethernet) belonging to this class,
say Y.
Note that the answer to this question does not directly affect
the kernel: saying N will just case the configurator to skip all
the questions regarding Silicom chipsets. If you say Y, you will be asked
for your specific chipset/driver in the following questions.
if NET_VENDOR_SILICOM
config SBYPASS
tristate "Silicom BypassCTL library support"
depends on PCI
depends on m
---help---
If you have a network (Ethernet) controller of this type, say Y
To compile this driver as a module, choose M here. The module
will be called bypass.
config BPCTL
tristate "Silicom BypassCTL net support"
depends on PCI
depends on m
select SBYPASS
select MII
---help---
If you have a network (Ethernet) controller of this type, say Y
or M and read the Ethernet-HOWTO, available from
<http://www.tldp.org/docs.html#howto>.
To compile this driver as a module, choose M here. The module
will be called bpctl_mod.
endif # NET_VENDOR_SILICOM

6
drivers/staging/silicom/Makefile
View file

@ -1,6 +0,0 @@
#
# Makefile for the Bypass network device drivers.
#
obj-$(CONFIG_BPCTL) += bpctl_mod.o
obj-$(CONFIG_SBYPASS) += bypasslib/

14
drivers/staging/silicom/README
View file

@ -1,14 +0,0 @@
Theory of Operation:
The Silicom Bypass Network Interface Cards (NICs) are network cards with paired ports (2 or 4).
The pairs either act as a "wire" allowing the network packets to pass or insert the device in
between the two ports. When paired with the on-board hardware watchdog or other failsafe,
they provide high availability for the network in the face of software outages or maintenance.
The software requirements are for a kernel level driver that interfaces with the bypass and watchdog,
as well as for control software. User control can be either the provided standalone executable
(/bin/bpctl) or the API exposed by the Silicom library.

8
drivers/staging/silicom/TODO
View file

@ -1,8 +0,0 @@
TODO:
- checkpatch.pl cleanups
- locking audit
- single module with all functionality
- userland
- fix monolithic build.

56
drivers/staging/silicom/bits.h
View file

@ -1,56 +0,0 @@
/******************************************************************************/
/* */
/* Broadcom BCM5700 Linux Network Driver, Copyright (c) 2000 - 2004 Broadcom */
/* Corporation. */
/* All rights reserved. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* History: */
/* 02/25/00 Hav Khauv Initial version. */
/******************************************************************************/
#ifndef BITS_H
#define BITS_H
/******************************************************************************/
/* Bit Mask definitions */
/******************************************************************************/
#define BIT_NONE 0x00
#define BIT_0 0x01
#define BIT_1 0x02
#define BIT_2 0x04
#define BIT_3 0x08
#define BIT_4 0x10
#define BIT_5 0x20
#define BIT_6 0x40
#define BIT_7 0x80
#define BIT_8 0x0100
#define BIT_9 0x0200
#define BIT_10 0x0400
#define BIT_11 0x0800
#define BIT_12 0x1000
#define BIT_13 0x2000
#define BIT_14 0x4000
#define BIT_15 0x8000
#define BIT_16 0x010000
#define BIT_17 0x020000
#define BIT_18 0x040000
#define BIT_19 0x080000
#define BIT_20 0x100000
#define BIT_21 0x200000
#define BIT_22 0x400000
#define BIT_23 0x800000
#define BIT_24 0x01000000
#define BIT_25 0x02000000
#define BIT_26 0x04000000
#define BIT_27 0x08000000
#define BIT_28 0x10000000
#define BIT_29 0x20000000
#define BIT_30 0x40000000
#define BIT_31 0x80000000
#endif /* BITS_H */

140
drivers/staging/silicom/bp_ioctl.h
View file

@ -1,140 +0,0 @@
/******************************************************************************/
/* */
/* Silicom Bypass Control Utility, Copyright (c) 2005-2007 Silicom */
/* All rights reserved. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/******************************************************************************/
#ifndef BP_IOCTL_H
#define BP_IOCTL_H
#define BP_CAP 0x01 /* BIT_0 */
#define BP_STATUS_CAP 0x02
#define BP_STATUS_CHANGE_CAP 0x04
#define SW_CTL_CAP 0x08
#define BP_DIS_CAP 0x10
#define BP_DIS_STATUS_CAP 0x20
#define STD_NIC_CAP 0x40
#define BP_PWOFF_ON_CAP 0x80
#define BP_PWOFF_OFF_CAP 0x0100
#define BP_PWOFF_CTL_CAP 0x0200
#define BP_PWUP_ON_CAP 0x0400
#define BP_PWUP_OFF_CAP 0x0800
#define BP_PWUP_CTL_CAP 0x1000
#define WD_CTL_CAP 0x2000
#define WD_STATUS_CAP 0x4000
#define WD_TIMEOUT_CAP 0x8000
#define TX_CTL_CAP 0x10000
#define TX_STATUS_CAP 0x20000
#define TAP_CAP 0x40000
#define TAP_STATUS_CAP 0x80000
#define TAP_STATUS_CHANGE_CAP 0x100000
#define TAP_DIS_CAP 0x200000
#define TAP_DIS_STATUS_CAP 0x400000
#define TAP_PWUP_ON_CAP 0x800000
#define TAP_PWUP_OFF_CAP 0x1000000
#define TAP_PWUP_CTL_CAP 0x2000000
#define NIC_CAP_NEG 0x4000000
#define TPL_CAP 0x8000000
#define DISC_CAP 0x10000000
#define DISC_DIS_CAP 0x20000000
#define DISC_PWUP_CTL_CAP 0x40000000
#define TPL2_CAP_EX 0x01
#define DISC_PORT_CAP_EX 0x02
#define WD_MIN_TIME_MASK(val) (val & 0xf)
#define WD_STEP_COUNT_MASK(val) ((val & 0xf) << 5)
#define WDT_STEP_TIME 0x10 /* BIT_4 */
#define WD_MIN_TIME_GET(desc) (desc & 0xf)
#define WD_STEP_COUNT_GET(desc) ((desc>>5) & 0xf)
typedef enum {
IF_SCAN,
GET_DEV_NUM,
IS_BYPASS,
GET_BYPASS_SLAVE,
GET_BYPASS_CAPS,
GET_WD_SET_CAPS,
SET_BYPASS,
GET_BYPASS,
GET_BYPASS_CHANGE,
SET_BYPASS_WD,
GET_BYPASS_WD,
GET_WD_EXPIRE_TIME,
RESET_BYPASS_WD_TIMER,
SET_DIS_BYPASS,
GET_DIS_BYPASS,
SET_BYPASS_PWOFF,
GET_BYPASS_PWOFF,
SET_BYPASS_PWUP,
GET_BYPASS_PWUP,
SET_STD_NIC,
GET_STD_NIC,
SET_TX,
GET_TX,
SET_TAP,
GET_TAP,
GET_TAP_CHANGE,
SET_DIS_TAP,
GET_DIS_TAP,
SET_TAP_PWUP,
GET_TAP_PWUP,
SET_WD_EXP_MODE,
GET_WD_EXP_MODE,
SET_WD_AUTORESET,
GET_WD_AUTORESET,
SET_TPL,
GET_TPL,
SET_DISC,
GET_DISC,
GET_DISC_CHANGE,
SET_DIS_DISC,
GET_DIS_DISC,
SET_DISC_PWUP,
GET_DISC_PWUP,
GET_BYPASS_INFO = 100,
GET_BP_WAIT_AT_PWUP,
SET_BP_WAIT_AT_PWUP,
GET_BP_HW_RESET,
SET_BP_HW_RESET,
SET_DISC_PORT,
GET_DISC_PORT,
SET_DISC_PORT_PWUP,
GET_DISC_PORT_PWUP,
SET_BP_FORCE_LINK,
GET_BP_FORCE_LINK,
#ifdef BP_SELF_TEST
SET_BP_SELF_TEST = 200,
GET_BP_SELF_TEST,
#endif
} CMND_TYPE_SD;
/*
* The major device number. We can't rely on dynamic
* registration any more, because ioctls need to know
* it.
*/
#define MAGIC_NUM 'J'
/* for passing single values */
struct bpctl_cmd {
int status;
int data[8];
int in_param[8];
int out_param[8];
};
#define IOCTL_TX_MSG(cmd) _IOWR(MAGIC_NUM, cmd, struct bpctl_cmd)
#define DEVICE_NAME "bpctl"
#endif

711
drivers/staging/silicom/bp_mod.h
View file

@ -1,711 +0,0 @@
/******************************************************************************/
/* */
/* Bypass Control utility, Copyright (c) 2005 Silicom */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/* bp_mod.h */
/* */
/******************************************************************************/
#ifndef BP_MOD_H
#define BP_MOD_H
#include "bits.h"
#define usec_delay(x) udelay(x)
#ifndef msec_delay_bp
#define msec_delay_bp(x) \
do { \
int i; \
if (1) { \
for (i = 0; i < 1000; i++) { \
udelay(x); \
} \
} else { \
msleep(x); \
} \
} while (0)
#endif
#include <linux/param.h>
#ifndef jiffies_to_msecs
#define jiffies_to_msecs(x) _kc_jiffies_to_msecs(x)
static inline unsigned int jiffies_to_msecs(const unsigned long j)
{
#if HZ <= 1000 && !(1000 % HZ)
return (1000 / HZ) * j;
#elif HZ > 1000 && !(HZ % 1000)
return (j + (HZ / 1000) - 1) / (HZ / 1000);
#else
return (j * 1000) / HZ;
#endif
}
#endif
#define SILICOM_VID 0x1374
#define SILICOM_SVID 0x1374
#define SILICOM_PXG2BPFI_SSID 0x0026
#define SILICOM_PXG2BPFILX_SSID 0x0027
#define SILICOM_PXGBPI_SSID 0x0028
#define SILICOM_PXGBPIG_SSID 0x0029
#define SILICOM_PXG2TBFI_SSID 0x002a
#define SILICOM_PXG4BPI_SSID 0x002c
#define SILICOM_PXG4BPFI_SSID 0x002d
#define SILICOM_PXG4BPFILX_SSID 0x002e
#define SILICOM_PXG2BPFIL_SSID 0x002F
#define SILICOM_PXG2BPFILLX_SSID 0x0030
#define SILICOM_PEG4BPI_SSID 0x0031
#define SILICOM_PEG2BPI_SSID 0x0037
#define SILICOM_PEG4BPIN_SSID 0x0038
#define SILICOM_PEG2BPFI_SSID 0x0039
#define SILICOM_PEG2BPFILX_SSID 0x003A
#define SILICOM_PMCXG2BPFI_SSID 0x003B
#define NOKIA_PMCXG2BPFIN_SSID 0x0510
#define NOKIA_PMCXG2BPIN_SSID 0x0513
#define NOKIA_PMCXG4BPIN_SSID 0x0514
#define NOKIA_PMCXG2BPFIN_SVID 0x13B8
#define NOKIA_PMCXG2BPIN2_SSID 0x0515
#define NOKIA_PMCXG4BPIN2_SSID 0x0516
#define SILICOM_PMCX2BPI_SSID 0x041
#define SILICOM_PMCX4BPI_SSID 0x042
#define SILICOM_PXG2BISC1_SSID 0x003d
#define SILICOM_PEG2TBFI_SSID 0x003E
#define SILICOM_PXG2TBI_SSID 0x003f
#define SILICOM_PXG4BPFID_SSID 0x0043
#define SILICOM_PEG4BPFI_SSID 0x0040
#define SILICOM_PEG4BPIPT_SSID 0x0044
#define SILICOM_PXG6BPI_SSID 0x0045
#define SILICOM_PEG4BPIL_SSID 0x0046
#define SILICOM_PEG2BPI5_SSID 0x0052
#define SILICOM_PEG6BPI_SSID 0x0053
#define SILICOM_PEG4BPFI5_SSID 0x0050
#define SILICOM_PEG4BPFI5LX_SSID 0x0051
#define SILICOM_PEG2BISC6_SSID 0x54
#define SILICOM_PEG6BPIFC_SSID 0x55
#define SILICOM_PEG2BPFI5_SSID 0x0056
#define SILICOM_PEG2BPFI5LX_SSID 0x0057
#define SILICOM_PXEG4BPFI_SSID 0x0058
#define SILICOM_PEG2BPFID_SSID 0x0047
#define SILICOM_PEG2BPFIDLX_SSID 0x004C
#define SILICOM_MEG2BPFILN_SSID 0x0048
#define SILICOM_MEG2BPFINX_SSID 0x0049
#define SILICOM_PEG4BPFILX_SSID 0x004A
#define SILICOM_MHIO8AD_SSID 0x004F
#define SILICOM_MEG2BPFILXLN_SSID 0x004b
#define SILICOM_PEG2BPIX1_SSID 0x004d
#define SILICOM_MEG2BPFILXNX_SSID 0x004e
#define SILICOM_PE10G2BPISR_SSID 0x0102
#define SILICOM_PE10G2BPILR_SSID 0x0103
#define SILICOM_PE10G2BPICX4_SSID 0x0101
#define SILICOM_XE10G2BPILR_SSID 0x0163
#define SILICOM_XE10G2BPISR_SSID 0x0162
#define SILICOM_XE10G2BPICX4_SSID 0x0161
#define SILICOM_XE10G2BPIT_SSID 0x0160
#define SILICOM_PE10GDBISR_SSID 0x0181
#define SILICOM_PE10GDBILR_SSID 0x0182
#define SILICOM_PE210G2DBi9SR_SSID 0x0188
#define SILICOM_PE210G2DBi9SRRB_SSID 0x0188
#define SILICOM_PE210G2DBi9LR_SSID 0x0189
#define SILICOM_PE210G2DBi9LRRB_SSID 0x0189
#define SILICOM_PE310G4DBi940SR_SSID 0x018C
#define SILICOM_PE310G4BPi9T_SSID 0x130
#define SILICOM_PE310G4BPi9SR_SSID 0x132
#define SILICOM_PE310G4BPi9LR_SSID 0x133
#define NOKIA_XE10G2BPIXR_SVID 0x13B8
#define NOKIA_XE10G2BPIXR_SSID 0x051C
#define INTEL_PEG4BPII_PID 0x10A0
#define INTEL_PEG4BPFII_PID 0x10A1
#define INTEL_PEG4BPII_SSID 0x11A0
#define INTEL_PEG4BPFII_SSID 0x11A1
#define INTEL_PEG4BPIIO_SSID 0x10A0
#define INTEL_PEG4BPIIO_PID 0x105e
#define BROADCOM_VID 0x14e4
#define BROADCOM_PE10G2_PID 0x164e
#define SILICOM_PE10G2BPTCX4_SSID 0x0141
#define SILICOM_PE10G2BPTSR_SSID 0x0142
#define SILICOM_PE10G2BPTLR_SSID 0x0143
#define SILICOM_PE10G2BPTT_SSID 0x0140
#define SILICOM_PEG4BPI6_SSID 0x0320
#define SILICOM_PEG4BPFI6_SSID 0x0321
#define SILICOM_PEG4BPFI6LX_SSID 0x0322
#define SILICOM_PEG4BPFI6ZX_SSID 0x0323
#define SILICOM_PEG2BPI6_SSID 0x0300
#define SILICOM_PEG2BPFI6_SSID 0x0301
#define SILICOM_PEG2BPFI6LX_SSID 0x0302
#define SILICOM_PEG2BPFI6ZX_SSID 0x0303
#define SILICOM_PEG2BPFI6FLXM_SSID 0x0304
#define SILICOM_PEG2DBI6_SSID 0x0308
#define SILICOM_PEG2DBFI6_SSID 0x0309
#define SILICOM_PEG2DBFI6LX_SSID 0x030A
#define SILICOM_PEG2DBFI6ZX_SSID 0x030B
#define SILICOM_MEG2BPI6_SSID 0x0310
#define SILICOM_XEG2BPI6_SSID 0x0318
#define SILICOM_PEG4BPI6FC_SSID 0x0328
#define SILICOM_PEG4BPFI6FC_SSID 0x0329
#define SILICOM_PEG4BPFI6FCLX_SSID 0x032A
#define SILICOM_PEG4BPFI6FCZX_SSID 0x032B
#define SILICOM_PEG6BPI6_SSID 0x0340
#define SILICOM_PEG2BPI6SC6_SSID 0x0360
#define SILICOM_MEG2BPI6_SSID 0x0310
#define SILICOM_XEG2BPI6_SSID 0x0318
#define SILICOM_MEG4BPI6_SSID 0x0330
#define SILICOM_PE2G4BPi80L_SSID 0x0380
#define SILICOM_M6E2G8BPi80A_SSID 0x0474
#define SILICOM_PE2G4BPi35_SSID 0x03d8
#define SILICOM_PE2G4BPFi80_SSID 0x0381
#define SILICOM_PE2G4BPFi80LX_SSID 0x0382
#define SILICOM_PE2G4BPFi80ZX_SSID 0x0383
#define SILICOM_PE2G4BPi80_SSID 0x0388
#define SILICOM_PE2G2BPi80_SSID 0x0390
#define SILICOM_PE2G2BPFi80_SSID 0x0391
#define SILICOM_PE2G2BPFi80LX_SSID 0x0392
#define SILICOM_PE2G2BPFi80ZX_SSID 0x0393
#define SILICOM_PE2G4BPi35L_SSID 0x03D0
#define SILICOM_PE2G4BPFi35_SSID 0x03D1
#define SILICOM_PE2G4BPFi35LX_SSID 0x03D2
#define SILICOM_PE2G4BPFi35ZX_SSID 0x03D3
#define SILICOM_PE2G2BPi35_SSID 0x03c0
#define SILICOM_PAC1200BPi35_SSID 0x03cc
#define SILICOM_PE2G2BPFi35_SSID 0x03C1
#define SILICOM_PE2G2BPFi35LX_SSID 0x03C2
#define SILICOM_PE2G2BPFi35ZX_SSID 0x03C3
#define SILICOM_PE2G6BPi35_SSID 0x03E0
#define SILICOM_PE2G6BPi35CX_SSID 0x0AA0
#define INTEL_PE210G2SPI9_SSID 0x00C
#define SILICOM_M1EG2BPI6_SSID 0x400
#define SILICOM_M1EG2BPFI6_SSID 0x0401
#define SILICOM_M1EG2BPFI6LX_SSID 0x0402
#define SILICOM_M1EG2BPFI6ZX_SSID 0x0403
#define SILICOM_M1EG4BPI6_SSID 0x0420
#define SILICOM_M1EG4BPFI6_SSID 0x0421
#define SILICOM_M1EG4BPFI6LX_SSID 0x0422
#define SILICOM_M1EG4BPFI6ZX_SSID 0x0423
#define SILICOM_M1EG6BPI6_SSID 0x0440
#define SILICOM_M1E2G4BPi80_SSID 0x0460
#define SILICOM_M1E2G4BPFi80_SSID 0x0461
#define SILICOM_M1E2G4BPFi80LX_SSID 0x0462
#define SILICOM_M1E2G4BPFi80ZX_SSID 0x0463
#define SILICOM_M6E2G8BPi80_SSID 0x0470
#define SILICOM_PE210G2BPi40_SSID 0x01a0
#define PEG540_IF_SERIES(pid) \
((pid == SILICOM_PE210G2BPi40_SSID))
#define OLD_IF_SERIES(pid)\
((pid == SILICOM_PXG2BPFI_SSID) || \
(pid == SILICOM_PXG2BPFILX_SSID))
#define P2BPFI_IF_SERIES(pid) \
((pid == SILICOM_PXG2BPFI_SSID) || \
(pid == SILICOM_PXG2BPFILX_SSID) || \
(pid == SILICOM_PEG2BPFI_SSID) || \
(pid == SILICOM_PEG2BPFID_SSID) || \
(pid == SILICOM_PEG2BPFIDLX_SSID) || \
(pid == SILICOM_MEG2BPFILN_SSID) || \
(pid == SILICOM_MEG2BPFINX_SSID) || \
(pid == SILICOM_PEG4BPFILX_SSID) || \
(pid == SILICOM_PEG4BPFI_SSID) || \
(pid == SILICOM_PXEG4BPFI_SSID) || \
(pid == SILICOM_PXG4BPFID_SSID) || \
(pid == SILICOM_PEG2TBFI_SSID) || \
(pid == SILICOM_PE10G2BPISR_SSID) || \
(pid == SILICOM_PE10G2BPILR_SSID) || \
(pid == SILICOM_PEG2BPFILX_SSID) || \
(pid == SILICOM_PMCXG2BPFI_SSID) || \
(pid == SILICOM_MHIO8AD_SSID) || \
(pid == SILICOM_PEG4BPFI5LX_SSID) || \
(pid == SILICOM_PEG4BPFI5_SSID) || \
(pid == SILICOM_PEG4BPFI6FC_SSID) || \
(pid == SILICOM_PEG4BPFI6FCLX_SSID) || \
(pid == SILICOM_PEG4BPFI6FCZX_SSID) || \
(pid == NOKIA_PMCXG2BPFIN_SSID) || \
(pid == SILICOM_MEG2BPFILXLN_SSID) || \
(pid == SILICOM_MEG2BPFILXNX_SSID) || \
(pid == SILICOM_XE10G2BPIT_SSID) || \
(pid == SILICOM_XE10G2BPICX4_SSID) || \
(pid == SILICOM_XE10G2BPISR_SSID) || \
(pid == NOKIA_XE10G2BPIXR_SSID) || \
(pid == SILICOM_PE10GDBISR_SSID) || \
(pid == SILICOM_PE10GDBILR_SSID) || \
(pid == SILICOM_XE10G2BPILR_SSID))
#define INTEL_IF_SERIES(pid) \
((pid == INTEL_PEG4BPII_SSID) || \
(pid == INTEL_PEG4BPIIO_SSID) || \
(pid == INTEL_PEG4BPFII_SSID))
#define NOKIA_SERIES(pid) \
((pid == NOKIA_PMCXG2BPIN_SSID) || \
(pid == NOKIA_PMCXG4BPIN_SSID) || \
(pid == SILICOM_PMCX4BPI_SSID) || \
(pid == NOKIA_PMCXG2BPFIN_SSID) || \
(pid == SILICOM_PMCXG2BPFI_SSID) || \
(pid == NOKIA_PMCXG2BPIN2_SSID) || \
(pid == NOKIA_PMCXG4BPIN2_SSID) || \
(pid == SILICOM_PMCX2BPI_SSID))
#define DISCF_IF_SERIES(pid) \
(pid == SILICOM_PEG2TBFI_SSID)
#define PEGF_IF_SERIES(pid) \
((pid == SILICOM_PEG2BPFI_SSID) || \
(pid == SILICOM_PEG2BPFID_SSID) || \
(pid == SILICOM_PEG2BPFIDLX_SSID) || \
(pid == SILICOM_PEG2BPFILX_SSID) || \
(pid == SILICOM_PEG4BPFI_SSID) || \
(pid == SILICOM_PXEG4BPFI_SSID) || \
(pid == SILICOM_MEG2BPFILN_SSID) || \
(pid == SILICOM_MEG2BPFINX_SSID) || \
(pid == SILICOM_PEG4BPFILX_SSID) || \
(pid == SILICOM_PEG2TBFI_SSID) || \
(pid == SILICOM_MEG2BPFILXLN_SSID) || \
(pid == SILICOM_MEG2BPFILXNX_SSID))
#define TPL_IF_SERIES(pid) \
((pid == SILICOM_PXG2BPFIL_SSID) || \
(pid == SILICOM_PXG2BPFILLX_SSID) || \
(pid == SILICOM_PXG2TBFI_SSID) || \
(pid == SILICOM_PXG4BPFID_SSID) || \
(pid == SILICOM_PXG4BPFI_SSID))
#define BP10G_IF_SERIES(pid) \
((pid == SILICOM_PE10G2BPISR_SSID) || \
(pid == SILICOM_PE10G2BPICX4_SSID) || \
(pid == SILICOM_PE10G2BPILR_SSID) || \
(pid == SILICOM_XE10G2BPIT_SSID) || \
(pid == SILICOM_XE10G2BPICX4_SSID) || \
(pid == SILICOM_XE10G2BPISR_SSID) || \
(pid == NOKIA_XE10G2BPIXR_SSID) || \
(pid == SILICOM_PE10GDBISR_SSID) || \
(pid == SILICOM_PE10GDBILR_SSID) || \
(pid == SILICOM_XE10G2BPILR_SSID))
#define BP10GB_IF_SERIES(pid) \
((pid == SILICOM_PE10G2BPTCX4_SSID) || \
(pid == SILICOM_PE10G2BPTSR_SSID) || \
(pid == SILICOM_PE10G2BPTLR_SSID) || \
(pid == SILICOM_PE10G2BPTT_SSID))
#define BP10G_CX4_SERIES(pid) \
(pid == SILICOM_PE10G2BPICX4_SSID)
#define BP10GB_CX4_SERIES(pid) \
(pid == SILICOM_PE10G2BPTCX4_SSID)
#define SILICOM_M2EG2BPFI6_SSID 0x0501
#define SILICOM_M2EG2BPFI6LX_SSID 0x0502
#define SILICOM_M2EG2BPFI6ZX_SSID 0x0503
#define SILICOM_M2EG4BPI6_SSID 0x0520
#define SILICOM_M2EG4BPFI6_SSID 0x0521
#define SILICOM_M2EG4BPFI6LX_SSID 0x0522
#define SILICOM_M2EG4BPFI6ZX_SSID 0x0523
#define SILICOM_M2EG6BPI6_SSID 0x0540
#define SILICOM_M1E10G2BPI9CX4_SSID 0x481
#define SILICOM_M1E10G2BPI9SR_SSID 0x482
#define SILICOM_M1E10G2BPI9LR_SSID 0x483
#define SILICOM_M1E10G2BPI9T_SSID 0x480
#define SILICOM_M2E10G2BPI9CX4_SSID 0x581
#define SILICOM_M2E10G2BPI9SR_SSID 0x582
#define SILICOM_M2E10G2BPI9LR_SSID 0x583
#define SILICOM_M2E10G2BPI9T_SSID 0x580
#define SILICOM_PE210G2BPI9CX4_SSID 0x121
#define SILICOM_PE210G2BPI9SR_SSID 0x122
#define SILICOM_PE210G2BPI9LR_SSID 0x123
#define SILICOM_PE210G2BPI9T_SSID 0x120
#define DBI_IF_SERIES(pid) \
((pid == SILICOM_PE10GDBISR_SSID) || \
(pid == SILICOM_PE10GDBILR_SSID) || \
(pid == SILICOM_XE10G2BPILR_SSID) || \
(pid == SILICOM_PE210G2DBi9LR_SSID))
#define PEGF5_IF_SERIES(pid) \
((pid == SILICOM_PEG2BPFI5_SSID) || \
(pid == SILICOM_PEG2BPFI5LX_SSID) || \
(pid == SILICOM_PEG4BPFI6_SSID) || \
(pid == SILICOM_PEG4BPFI6LX_SSID) || \
(pid == SILICOM_PEG4BPFI6ZX_SSID) || \
(pid == SILICOM_PEG2BPFI6_SSID) || \
(pid == SILICOM_PEG2BPFI6LX_SSID) || \
(pid == SILICOM_PEG2BPFI6ZX_SSID) || \
(pid == SILICOM_PEG2BPFI6FLXM_SSID) || \
(pid == SILICOM_PEG2DBFI6_SSID) || \
(pid == SILICOM_PEG2DBFI6LX_SSID) || \
(pid == SILICOM_PEG2DBFI6ZX_SSID) || \
(pid == SILICOM_PEG4BPI6FC_SSID) || \
(pid == SILICOM_PEG4BPFI6FCLX_SSID) || \
(pid == SILICOM_PEG4BPI6FC_SSID) || \
(pid == SILICOM_M1EG2BPFI6_SSID) || \
(pid == SILICOM_M1EG2BPFI6LX_SSID) || \
(pid == SILICOM_M1EG2BPFI6ZX_SSID) || \
(pid == SILICOM_M1EG4BPFI6_SSID) || \
(pid == SILICOM_M1EG4BPFI6LX_SSID) || \
(pid == SILICOM_M1EG4BPFI6ZX_SSID) || \
(pid == SILICOM_M2EG2BPFI6_SSID) || \
(pid == SILICOM_M2EG2BPFI6LX_SSID) || \
(pid == SILICOM_M2EG2BPFI6ZX_SSID) || \
(pid == SILICOM_M2EG4BPFI6_SSID) || \
(pid == SILICOM_M2EG4BPFI6LX_SSID) || \
(pid == SILICOM_M2EG4BPFI6ZX_SSID) || \
(pid == SILICOM_PEG4BPFI6FCZX_SSID))
#define PEG5_IF_SERIES(pid) \
((pid == SILICOM_PEG4BPI6_SSID) || \
(pid == SILICOM_PEG2BPI6_SSID) || \
(pid == SILICOM_PEG4BPI6FC_SSID) || \
(pid == SILICOM_PEG6BPI6_SSID) || \
(pid == SILICOM_PEG2BPI6SC6_SSID) || \
(pid == SILICOM_MEG2BPI6_SSID) || \
(pid == SILICOM_XEG2BPI6_SSID) || \
(pid == SILICOM_MEG4BPI6_SSID) || \
(pid == SILICOM_M1EG2BPI6_SSID) || \
(pid == SILICOM_M1EG4BPI6_SSID) || \
(pid == SILICOM_M1EG6BPI6_SSID) || \
(pid == SILICOM_PEG6BPI_SSID) || \
(pid == SILICOM_PEG4BPIL_SSID) || \
(pid == SILICOM_PEG2BISC6_SSID) || \
(pid == SILICOM_PEG2BPI5_SSID))
#define PEG80_IF_SERIES(pid) \
((pid == SILICOM_M1E2G4BPi80_SSID) || \
(pid == SILICOM_M6E2G8BPi80_SSID) || \
(pid == SILICOM_PE2G4BPi80L_SSID) || \
(pid == SILICOM_M6E2G8BPi80A_SSID) || \
(pid == SILICOM_PE2G2BPi35_SSID) || \
(pid == SILICOM_PAC1200BPi35_SSID) || \
(pid == SILICOM_PE2G4BPi35_SSID) || \
(pid == SILICOM_PE2G4BPi35L_SSID) || \
(pid == SILICOM_PE2G6BPi35_SSID) || \
(pid == SILICOM_PE2G2BPi80_SSID) || \
(pid == SILICOM_PE2G4BPi80_SSID) || \
(pid == SILICOM_PE2G4BPFi80_SSID) || \
(pid == SILICOM_PE2G4BPFi80LX_SSID) || \
(pid == SILICOM_PE2G4BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G4BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G2BPFi80_SSID) || \
(pid == SILICOM_PE2G2BPFi80LX_SSID) || \
(pid == SILICOM_PE2G2BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G2BPFi35_SSID) || \
(pid == SILICOM_PE2G2BPFi35LX_SSID) || \
(pid == SILICOM_PE2G2BPFi35ZX_SSID) || \
(pid == SILICOM_PE2G4BPFi35_SSID) || \
(pid == SILICOM_PE2G4BPFi35LX_SSID) || \
(pid == SILICOM_PE2G4BPFi35ZX_SSID))
#define PEGF80_IF_SERIES(pid) \
((pid == SILICOM_PE2G4BPFi80_SSID) || \
(pid == SILICOM_PE2G4BPFi80LX_SSID) || \
(pid == SILICOM_PE2G4BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G4BPFi80ZX_SSID) || \
(pid == SILICOM_M1E2G4BPFi80_SSID) || \
(pid == SILICOM_M1E2G4BPFi80LX_SSID) || \
(pid == SILICOM_M1E2G4BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G2BPFi80_SSID) || \
(pid == SILICOM_PE2G2BPFi80LX_SSID) || \
(pid == SILICOM_PE2G2BPFi80ZX_SSID) || \
(pid == SILICOM_PE2G2BPFi35_SSID) || \
(pid == SILICOM_PE2G2BPFi35LX_SSID) || \
(pid == SILICOM_PE2G2BPFi35ZX_SSID) || \
(pid == SILICOM_PE2G4BPFi35_SSID) || \
(pid == SILICOM_PE2G4BPFi35LX_SSID) || \
(pid == SILICOM_PE2G4BPFi35ZX_SSID))
#define BP10G9_IF_SERIES(pid) \
((pid == INTEL_PE210G2SPI9_SSID) || \
(pid == SILICOM_M1E10G2BPI9CX4_SSID) || \
(pid == SILICOM_M1E10G2BPI9SR_SSID) || \
(pid == SILICOM_M1E10G2BPI9LR_SSID) || \
(pid == SILICOM_M1E10G2BPI9T_SSID) || \
(pid == SILICOM_M2E10G2BPI9CX4_SSID) || \
(pid == SILICOM_M2E10G2BPI9SR_SSID) || \
(pid == SILICOM_M2E10G2BPI9LR_SSID) || \
(pid == SILICOM_M2E10G2BPI9T_SSID) || \
(pid == SILICOM_PE210G2BPI9CX4_SSID) || \
(pid == SILICOM_PE210G2BPI9SR_SSID) || \
(pid == SILICOM_PE210G2BPI9LR_SSID) || \
(pid == SILICOM_PE210G2DBi9SR_SSID) || \
(pid == SILICOM_PE210G2DBi9SRRB_SSID) || \
(pid == SILICOM_PE210G2DBi9LR_SSID) || \
(pid == SILICOM_PE210G2DBi9LRRB_SSID) || \
(pid == SILICOM_PE310G4DBi940SR_SSID) || \
(pid == SILICOM_PEG2BISC6_SSID) || \
(pid == SILICOM_PE310G4BPi9T_SSID) || \
(pid == SILICOM_PE310G4BPi9SR_SSID) || \
(pid == SILICOM_PE310G4BPi9LR_SSID) || \
(pid == SILICOM_PE210G2BPI9T_SSID))
/*******************************************************/
/* 1G INTERFACE ****************************************/
/*******************************************************/
/* Intel Registers */
#define BPCTLI_CTRL 0x00000
#define BPCTLI_CTRL_SWDPIO0 0x00400000
#define BPCTLI_CTRL_SWDPIN0 0x00040000
#define BPCTLI_CTRL_EXT 0x00018 /* Extended Device Control - RW */
#define BPCTLI_STATUS 0x00008 /* Device Status - RO */
/* HW related */
#define BPCTLI_CTRL_EXT_SDP6_DATA 0x00000040 /* Value of SW
* Defineable Pin 6
*/
#define BPCTLI_CTRL_EXT_SDP7_DATA 0x00000080 /* Value of SW
* Defineable Pin 7
*/
#define BPCTLI_CTRL_SDP0_DATA 0x00040000 /* SWDPIN 0 value */
#define BPCTLI_CTRL_EXT_SDP6_DIR 0x00000400 /* Direction of SDP6
* 0=in 1=out
*/
#define BPCTLI_CTRL_EXT_SDP7_DIR 0x00000800 /* Direction of SDP7
* 0=in 1=out
*/
#define BPCTLI_CTRL_SDP0_DIR 0x00400000 /* SDP0 Input or output */
#define BPCTLI_CTRL_SWDPIN1 0x00080000
#define BPCTLI_CTRL_SDP1_DIR 0x00800000
#define BPCTLI_STATUS_LU 0x00000002 /* Link up.0=no,1=link */
#define BPCTLI_CTRL_SDP0_SHIFT 18
#define BPCTLI_CTRL_EXT_SDP6_SHIFT 6
#define BPCTLI_STATUS_TBIMODE 0x00000020
#define BPCTLI_CTRL_EXT_LINK_MODE_PCIE_SERDES 0x00C00000
#define BPCTLI_CTRL_EXT_LINK_MODE_MASK 0x00C00000
#define BPCTLI_CTRL_EXT_MCLK_DIR BPCTLI_CTRL_EXT_SDP7_DIR
#define BPCTLI_CTRL_EXT_MCLK_DATA BPCTLI_CTRL_EXT_SDP7_DATA
#define BPCTLI_CTRL_EXT_MDIO_DIR BPCTLI_CTRL_EXT_SDP6_DIR
#define BPCTLI_CTRL_EXT_MDIO_DATA BPCTLI_CTRL_EXT_SDP6_DATA
#define BPCTLI_CTRL_EXT_MCLK_DIR5 BPCTLI_CTRL_SDP1_DIR
#define BPCTLI_CTRL_EXT_MCLK_DATA5 BPCTLI_CTRL_SWDPIN1
#define BPCTLI_CTRL_EXT_MCLK_DIR80 BPCTLI_CTRL_EXT_SDP6_DIR
#define BPCTLI_CTRL_EXT_MCLK_DATA80 BPCTLI_CTRL_EXT_SDP6_DATA
#define BPCTLI_CTRL_EXT_MDIO_DIR5 BPCTLI_CTRL_SWDPIO0
#define BPCTLI_CTRL_EXT_MDIO_DATA5 BPCTLI_CTRL_SWDPIN0
#define BPCTLI_CTRL_EXT_MDIO_DIR80 BPCTLI_CTRL_SWDPIO0
#define BPCTLI_CTRL_EXT_MDIO_DATA80 BPCTLI_CTRL_SWDPIN0
#define BPCTL_WRITE_REG(a, reg, value) \
(writel((value), (void *)(((a)->mem_map) + BPCTLI_##reg)))
#define BPCTL_READ_REG(a, reg) ( \
readl((void *)((a)->mem_map) + BPCTLI_##reg))
#define BPCTL_WRITE_FLUSH(a) BPCTL_READ_REG(a, STATUS)
#define BPCTL_BP_WRITE_REG(a, reg, value) ({ \
BPCTL_WRITE_REG(a, reg, value); \
BPCTL_WRITE_FLUSH(a); })
/**************************************************************/
/************** 82575 Interface********************************/
/**************************************************************/
#define BPCTLI_MII_CR_POWER_DOWN 0x0800
#define BPCTLI_PHY_CONTROL 0x00 /* Control Register */
#define BPCTLI_MDIC 0x00020 /* MDI Control - RW */
#define BPCTLI_IGP01E1000_PHY_PAGE_SELECT 0x1F /* Page Select */
#define BPCTLI_MAX_PHY_REG_ADDRESS 0x1F /* 5 bit address bus (0-0x1F) */
#define BPCTLI_MDIC_DATA_MASK 0x0000FFFF
#define BPCTLI_MDIC_REG_MASK 0x001F0000
#define BPCTLI_MDIC_REG_SHIFT 16
#define BPCTLI_MDIC_PHY_MASK 0x03E00000
#define BPCTLI_MDIC_PHY_SHIFT 21
#define BPCTLI_MDIC_OP_WRITE 0x04000000
#define BPCTLI_MDIC_OP_READ 0x08000000
#define BPCTLI_MDIC_READY 0x10000000
#define BPCTLI_MDIC_INT_EN 0x20000000
#define BPCTLI_MDIC_ERROR 0x40000000
#define BPCTLI_SWFW_PHY0_SM 0x02
#define BPCTLI_SWFW_PHY1_SM 0x04
#define BPCTLI_SW_FW_SYNC 0x05B5C /* Software-Firmware
* Synchronization - RW
*/
#define BPCTLI_SWSM 0x05B50 /* SW Semaphore */
#define BPCTLI_FWSM 0x05B54 /* FW Semaphore */
#define BPCTLI_SWSM_SMBI 0x00000001 /* Driver Semaphore bit */
#define BPCTLI_SWSM_SWESMBI 0x00000002 /* FW Semaphore bit */
#define BPCTLI_MAX_PHY_MULTI_PAGE_REG 0xF
#define BPCTLI_GEN_POLL_TIMEOUT 640
/********************************************************/
/********************************************************/
/* 10G INTERFACE ****************************************/
/********************************************************/
#define BP10G_I2CCTL 0x28
/* I2CCTL Bit Masks */
#define BP10G_I2C_CLK_IN 0x00000001
#define BP10G_I2C_CLK_OUT 0x00000002
#define BP10G_I2C_DATA_IN 0x00000004
#define BP10G_I2C_DATA_OUT 0x00000008
#define BP10G_ESDP 0x20
#define BP10G_SDP0_DIR 0x100
#define BP10G_SDP1_DIR 0x200
#define BP10G_SDP3_DIR 0x800
#define BP10G_SDP4_DIR BIT_12
#define BP10G_SDP5_DIR 0x2000
#define BP10G_SDP0_DATA 0x001
#define BP10G_SDP1_DATA 0x002
#define BP10G_SDP3_DATA 0x008
#define BP10G_SDP4_DATA 0x010
#define BP10G_SDP5_DATA 0x020
#define BP10G_SDP2_DIR 0x400
#define BP10G_SDP2_DATA 0x4
#define BP10G_EODSDP 0x28
#define BP10G_SDP6_DATA_IN 0x001
#define BP10G_SDP6_DATA_OUT 0x002
#define BP10G_SDP7_DATA_IN 0x004
#define BP10G_SDP7_DATA_OUT 0x008
#define BP10G_MCLK_DATA_OUT BP10G_SDP7_DATA_OUT
#define BP10G_MDIO_DATA_OUT BP10G_SDP6_DATA_OUT
#define BP10G_MDIO_DATA_IN BP10G_SDP6_DATA_IN
#define BP10G_MDIO_DATA /*BP10G_SDP5_DATA*/ BP10G_SDP3_DATA
#define BP10G_MDIO_DIR /*BP10G_SDP5_DIR*/ BP10G_SDP3_DATA
/*#define BP10G_MCLK_DATA_OUT9 BP10G_I2C_CLK_OUT
#define BP10G_MDIO_DATA_OUT9 BP10G_I2C_DATA_OUT*/
/*#define BP10G_MCLK_DATA_OUT9*/
/*BP10G_I2C_DATA_OUT */
#define BP10G_MDIO_DATA_OUT9 BP10G_I2C_DATA_OUT /*BP10G_I2C_CLK_OUT */
/* VIA EOSDP ! */
#define BP10G_MCLK_DATA_OUT9 BP10G_SDP4_DATA
#define BP10G_MCLK_DIR_OUT9 BP10G_SDP4_DIR
/*#define BP10G_MDIO_DATA_IN9 BP10G_I2C_DATA_IN*/
#define BP10G_MDIO_DATA_IN9 BP10G_I2C_DATA_IN /*BP10G_I2C_CLK_IN */
#define BP540_MDIO_DATA /*BP10G_SDP5_DATA*/ BP10G_SDP0_DATA
#define BP540_MDIO_DIR /*BP10G_SDP5_DIR*/ BP10G_SDP0_DIR
#define BP540_MCLK_DATA BP10G_SDP2_DATA
#define BP540_MCLK_DIR BP10G_SDP2_DIR
#define BP10G_WRITE_REG(a, reg, value) \
(writel((value), (void *)(((a)->mem_map) + BP10G_##reg)))
#define BP10G_READ_REG(a, reg) ( \
readl((void *)((a)->mem_map) + BP10G_##reg))
/*****BROADCOM*******************************************/
#define BP10GB_MISC_REG_GPIO 0xa490
#define BP10GB_GPIO3_P0 BIT_3
#define BP10GB_GPIO3_P1 BIT_7
#define BP10GB_GPIO3_SET_P0 BIT_11
#define BP10GB_GPIO3_CLR_P0 BIT_19
#define BP10GB_GPIO3_OE_P0 BIT_27
#define BP10GB_GPIO3_SET_P1 BIT_15
#define BP10GB_GPIO3_CLR_P1 BIT_23
#define BP10GB_GPIO3_OE_P1 BIT_31
#define BP10GB_GPIO0_P1 0x10
#define BP10GB_GPIO0_P0 0x1
#define BP10GB_GPIO0_CLR_P0 0x10000
#define BP10GB_GPIO0_CLR_P1 0x100000
#define BP10GB_GPIO0_SET_P0 0x100
#define BP10GB_GPIO0_SET_P1 0x1000
#define BP10GB_GPIO0_OE_P1 0x10000000
#define BP10GB_GPIO0_OE_P0 0x1000000
#define BP10GB_MISC_REG_SPIO 0xa4fc
#define BP10GB_GPIO4_OE BIT_28
#define BP10GB_GPIO5_OE BIT_29
#define BP10GB_GPIO4_CLR BIT_20
#define BP10GB_GPIO5_CLR BIT_21
#define BP10GB_GPIO4_SET BIT_12
#define BP10GB_GPIO5_SET BIT_13
#define BP10GB_GPIO4 BIT_4
#define BP10GB_GPIO5 BIT_5
#define BP10GB_MCLK_DIR BP10GB_GPIO5_OE
#define BP10GB_MDIO_DIR BP10GB_GPIO4_OE
#define BP10GB_MCLK_DATA BP10GB_GPIO5
#define BP10GB_MDIO_DATA BP10GB_GPIO4
#define BP10GB_MCLK_SET BP10GB_GPIO5_SET
#define BP10GB_MDIO_SET BP10GB_GPIO4_SET
#define BP10GB_MCLK_CLR BP10GB_GPIO5_CLR
#define BP10GB_MDIO_CLR BP10GB_GPIO4_CLR
#define BP10GB_WRITE_REG(a, reg, value) \
(writel((value), (void *)(((a)->mem_map) + BP10GB_##reg)))
#define BP10GB_READ_REG(a, reg) ( \
readl((void *)((a)->mem_map) + BP10GB_##reg))
#endif

7530
drivers/staging/silicom/bpctl_mod.c
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202
drivers/staging/silicom/bypass.h
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@ -1,202 +0,0 @@
/******************************************************************************/
/* */
/* Bypass Control utility, Copyright (c) 2005 Silicom */
/* All rights reserved. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/******************************************************************************/
#ifndef BYPASS_H
#define BYPASS_H
/* Bypass related */
#define SYNC_CMD_VAL 2 /* 10b */
#define SYNC_CMD_LEN 2
#define WR_CMD_VAL 2 /* 10b */
#define WR_CMD_LEN 2
#define RD_CMD_VAL 1 /* 10b */
#define RD_CMD_LEN 2
#define ADDR_CMD_LEN 4
#define WR_DATA_LEN 8
#define RD_DATA_LEN 8
#define PIC_SIGN_REG_ADDR 0x7
#define PIC_SIGN_VALUE 0xcd
#define STATUS_REG_ADDR 0
#define WDT_EN_MASK 0x01 /* BIT_0 */
#define CMND_EN_MASK 0x02 /* BIT_1 */
#define DIS_BYPASS_CAP_MASK 0x04 /* BIT_2 Bypass Cap is disable*/
#define DFLT_PWRON_MASK 0x08 /* BIT_3 */
#define BYPASS_OFF_MASK 0x10 /* BIT_4 */
#define BYPASS_FLAG_MASK 0x20 /* BIT_5 */
#define STD_NIC_MASK (DIS_BYPASS_CAP_MASK | BYPASS_OFF_MASK | DFLT_PWRON_MASK)
#define WD_EXP_FLAG_MASK 0x40 /* BIT_6 */
#define DFLT_PWROFF_MASK 0x80 /* BIT_7 */
#define STD_NIC_PWOFF_MASK (DIS_BYPASS_CAP_MASK | BYPASS_OFF_MASK | DFLT_PWRON_MASK | DFLT_PWROFF_MASK)
#define PRODUCT_CAP_REG_ADDR 0x5
#define BYPASS_SUPPORT_MASK 0x01 /* BIT_0 */
#define TAP_SUPPORT_MASK 0x02 /* BIT_1 */
#define NORMAL_UNSUPPORT_MASK 0x04 /* BIT_2 */
#define DISC_SUPPORT_MASK 0x08 /* BIT_3 */
#define TPL2_SUPPORT_MASK 0x10 /* BIT_4 */
#define DISC_PORT_SUPPORT_MASK 0x20 /* BIT_5 */
#define STATUS_TAP_REG_ADDR 0x6
#define WDTE_TAP_BPN_MASK 0x01 /* BIT_1 1 when wdt expired -> TAP, 0 - Bypass */
#define DIS_TAP_CAP_MASK 0x04 /* BIT_2 TAP Cap is disable*/
#define DFLT_PWRON_TAP_MASK 0x08 /* BIT_3 */
#define TAP_OFF_MASK 0x10 /* BIT_4 */
#define TAP_FLAG_MASK 0x20 /* BIT_5 */
#define TX_DISA_MASK 0x40
#define TX_DISB_MASK 0x80
#define STD_NIC_TAP_MASK (DIS_TAP_CAP_MASK | TAP_OFF_MASK | DFLT_PWRON_TAP_MASK)
#define STATUS_DISC_REG_ADDR 13
#define WDTE_DISC_BPN_MASK 0x01 /* BIT_0 1 when wdt expired -> TAP, 0 - Bypass */
#define STD_NIC_ON_MASK 0x02 /* BIT_1 */
#define DIS_DISC_CAP_MASK 0x04 /* BIT_2 TAP Cap is disable*/
#define DFLT_PWRON_DISC_MASK 0x08 /* BIT_3 */
#define DISC_OFF_MASK 0x10 /* BIT_4 */
#define DISC_FLAG_MASK 0x20 /* BIT_5 */
#define TPL2_FLAG_MASK 0x40 /* BIT_6 */
#define STD_NIC_DISC_MASK DIS_DISC_CAP_MASK
#define CONT_CONFIG_REG_ADDR 12
#define EN_HW_RESET_MASK 0x2 /* BIT_1 */
#define WAIT_AT_PWUP_MASK 0x1 /* BIT_0 */
#define VER_REG_ADDR 0x1
#define BP_FW_VER_A0 0xa0
#define BP_FW_VER_A1 0xa1
#define INT_VER_MASK 0xf0
#define EXT_VER_MASK 0xf
/* */
#define PXG2BPI_VER 0x0
#define PXG2TBPI_VER 0x1
#define PXE2TBPI_VER 0x2
#define PXG4BPFI_VER 0x4
#define BP_FW_EXT_VER7 0x6
#define BP_FW_EXT_VER8 0x8
#define BP_FW_EXT_VER9 0x9
#define OLD_IF_VER -1
#define CMND_REG_ADDR 10 /* 1010b */
#define WDT_REG_ADDR 4
#define TMRL_REG_ADDR 2
#define TMRH_REG_ADDR 3
/* NEW_FW */
#define WDT_INTERVAL 1 /* 5 //8 */
#define WDT_CMND_INTERVAL 200 /* 50 */
#define CMND_INTERVAL 200 /* 100 usec */
#define PULSE_TIME 100
/* OLD_FW */
#define INIT_CMND_INTERVAL 40
#define PULSE_INTERVAL 5
#define WDT_TIME_CNT 3
/* Intel Commands */
#define CMND_OFF_INT 0xf
#define PWROFF_BYPASS_ON_INT 0x5
#define BYPASS_ON_INT 0x6
#define DIS_BYPASS_CAP_INT 0x4
#define RESET_WDT_INT 0x1
/* Intel timing */
#define BYPASS_DELAY_INT 4 /* msec */
#define CMND_INTERVAL_INT 2 /* msec */
/* Silicom Commands */
#define CMND_ON 0x4
#define CMND_OFF 0x2
#define BYPASS_ON 0xa
#define BYPASS_OFF 0x8
#define PORT_LINK_EN 0xe
#define PORT_LINK_DIS 0xc
#define WDT_ON 0x10 /* 0x1f (11111) - max */
#define TIMEOUT_UNIT 100
#define TIMEOUT_MAX_STEP 15
#define WDT_TIMEOUT_MIN 100 /* msec */
#define WDT_TIMEOUT_MAX 3276800 /* msec */
#define WDT_AUTO_MIN_INT 500
#define WDT_TIMEOUT_DEF WDT_TIMEOUT_MIN
#define WDT_OFF 0x6
#define WDT_RELOAD 0x9
#define RESET_CONT 0x20
#define DIS_BYPASS_CAP 0x22
#define EN_BYPASS_CAP 0x24
#define BYPASS_STATE_PWRON 0x26
#define NORMAL_STATE_PWRON 0x28
#define BYPASS_STATE_PWROFF 0x27
#define NORMAL_STATE_PWROFF 0x29
#define TAP_ON 0xb
#define TAP_OFF 0x9
#define TAP_STATE_PWRON 0x2a
#define DIS_TAP_CAP 0x2c
#define EN_TAP_CAP 0x2e
#define STD_NIC_OFF 0x86
#define STD_NIC_ON 0x84
#define DISC_ON 0x85
#define DISC_OFF 0x8a
#define DISC_STATE_PWRON 0x87
#define DIS_DISC_CAP 0x88
#define EN_DISC_CAP 0x89
#define TPL2_ON 0x8c
#define TPL2_OFF 0x8b
#define BP_WAIT_AT_PWUP_EN 0x80
#define BP_WAIT_AT_PWUP_DIS 0x81
#define BP_HW_RESET_EN 0x82
#define BP_HW_RESET_DIS 0x83
#define TX_DISA 0x8d
#define TX_DISB 0x8e
#define TX_ENA 0xA0
#define TX_ENB 0xA1
#define TX_DISA_PWRUP 0xA2
#define TX_DISB_PWRUP 0xA3
#define TX_ENA_PWRUP 0xA4
#define TX_ENB_PWRUP 0xA5
#define BYPASS_CAP_DELAY 21 /* msec */
#define DFLT_PWRON_DELAY 10 /* msec */
#define LATCH_DELAY 13 /* msec */
#define EEPROM_WR_DELAY 8 /* msec */
#define BP_LINK_MON_DELAY 4 /* sec */
#define BP_FW_EXT_VER0 0xa0
#define BP_FW_EXT_VER1 0xa1
#define BP_FW_EXT_VER2 0xb1
#define BP_OK 0
#define BP_NOT_CAP -1
#define WDT_STATUS_EXP -2
#define WDT_STATUS_UNKNOWN -1
#define WDT_STATUS_EN 1
#define WDT_STATUS_DIS 0
#ifdef BP_SELF_TEST
#define ETH_P_BPTEST 0xabba
#define BPTEST_DATA_LEN 60
#endif
#endif /* BYPASS_H */

6
drivers/staging/silicom/bypasslib/Makefile
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@ -1,6 +0,0 @@
#
# Makefile for the Bypass network device drivers.
#
obj-$(CONFIG_SBYPASS) += bypass.o

198
drivers/staging/silicom/bypasslib/bp_ioctl.h
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@ -1,198 +0,0 @@
/******************************************************************************/
/* */
/* bypass library, Copyright (c) 2004-2006 Silicom, Ltd */
/* Corporation. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/* */
/******************************************************************************/
#ifndef BP_IOCTL_H
#define BP_IOCTL_H
#define BP_CAP 0x01 /* BIT_0 */
#define BP_STATUS_CAP 0x02 /* BIT_1 */
#define BP_STATUS_CHANGE_CAP 0x04 /* BIT_2 */
#define SW_CTL_CAP 0x08 /* BIT_3 */
#define BP_DIS_CAP 0x10 /* BIT_4 */
#define BP_DIS_STATUS_CAP 0x20 /* BIT_5 */
#define STD_NIC_CAP 0x40 /* BIT_6 */
#define BP_PWOFF_ON_CAP 0x80 /* BIT_7 */
#define BP_PWOFF_OFF_CAP 0x0100 /* BIT_8 */
#define BP_PWOFF_CTL_CAP 0x0200 /* BIT_9 */
#define BP_PWUP_ON_CAP 0x0400 /* BIT_10 */
#define BP_PWUP_OFF_CAP 0x0800 /* BIT_11 */
#define BP_PWUP_CTL_CAP 0x1000 /* BIT_12 */
#define WD_CTL_CAP 0x2000 /* BIT_13 */
#define WD_STATUS_CAP 0x4000 /* BIT_14 */
#define WD_TIMEOUT_CAP 0x8000 /* BIT_15 */
#define TX_CTL_CAP 0x10000 /* BIT_16 */
#define TX_STATUS_CAP 0x20000 /* BIT_17 */
#define TAP_CAP 0x40000 /* BIT_18 */
#define TAP_STATUS_CAP 0x80000 /* BIT_19 */
#define TAP_STATUS_CHANGE_CAP 0x100000 /* BIT_20 */
#define TAP_DIS_CAP 0x200000 /* BIT_21 */
#define TAP_DIS_STATUS_CAP 0x400000 /* BIT_22 */
#define TAP_PWUP_ON_CAP 0x800000 /* BIT_23 */
#define TAP_PWUP_OFF_CAP 0x1000000 /* BIT 24 */
#define TAP_PWUP_CTL_CAP 0x2000000 /* BIT 25 */
#define NIC_CAP_NEG 0x4000000 /* BIT 26 */
#define TPL_CAP 0x8000000 /* BIT 27 */
#define DISC_CAP 0x10000000 /* BIT 28 */
#define DISC_DIS_CAP 0x20000000 /* BIT 29 */
#define DISC_PWUP_CTL_CAP 0x40000000 /* BIT 30 */
#define WD_MIN_TIME_MASK(val) (val & 0xf)
#define WD_STEP_COUNT_MASK(val) ((val & 0xf) << 5)
#define WDT_STEP_TIME 0x10 /* BIT_4 */
#define WD_MIN_TIME_GET(desc) (desc & 0xf)
#define WD_STEP_COUNT_GET(desc) ((desc>>5) & 0xf)
enum {
IS_BYPASS = 1,
GET_BYPASS_SLAVE,
GET_BYPASS_CAPS,
GET_WD_SET_CAPS,
SET_BYPASS,
GET_BYPASS,
GET_BYPASS_CHANGE,
SET_BYPASS_WD,
GET_BYPASS_WD,
GET_WD_EXPIRE_TIME,
RESET_BYPASS_WD_TIMER,
SET_DIS_BYPASS,
GET_DIS_BYPASS,
SET_BYPASS_PWOFF,
GET_BYPASS_PWOFF,
SET_BYPASS_PWUP,
GET_BYPASS_PWUP,
SET_STD_NIC,
GET_STD_NIC,
SET_TX,
GET_TX,
SET_TAP,
GET_TAP,
GET_TAP_CHANGE,
SET_DIS_TAP,
GET_DIS_TAP,
SET_TAP_PWUP,
GET_TAP_PWUP,
SET_WD_EXP_MODE,
GET_WD_EXP_MODE,
SET_WD_AUTORESET,
GET_WD_AUTORESET,
SET_TPL,
GET_TPL,
SET_DISC,
GET_DISC,
GET_DISC_CHANGE,
SET_DIS_DISC,
GET_DIS_DISC,
SET_DISC_PWUP,
GET_DISC_PWUP,
GET_BYPASS_INFO = 100,
GET_BP_WAIT_AT_PWUP,
SET_BP_WAIT_AT_PWUP,
GET_BP_HW_RESET,
SET_BP_HW_RESET,
};
enum {
IF_SCAN_SD,
GET_DEV_NUM_SD,
IS_BYPASS_SD,
GET_BYPASS_SLAVE_SD,
GET_BYPASS_CAPS_SD,
GET_WD_SET_CAPS_SD,
SET_BYPASS_SD,
GET_BYPASS_SD,
GET_BYPASS_CHANGE_SD,
SET_BYPASS_WD_SD,
GET_BYPASS_WD_SD,
GET_WD_EXPIRE_TIME_SD,
RESET_BYPASS_WD_TIMER_SD,
SET_DIS_BYPASS_SD,
GET_DIS_BYPASS_SD,
SET_BYPASS_PWOFF_SD,
GET_BYPASS_PWOFF_SD,
SET_BYPASS_PWUP_SD,
GET_BYPASS_PWUP_SD,
SET_STD_NIC_SD,
GET_STD_NIC_SD,
SET_TX_SD,
GET_TX_SD,
SET_TAP_SD,
GET_TAP_SD,
GET_TAP_CHANGE_SD,
SET_DIS_TAP_SD,
GET_DIS_TAP_SD,
SET_TAP_PWUP_SD,
GET_TAP_PWUP_SD,
SET_WD_EXP_MODE_SD,
GET_WD_EXP_MODE_SD,
SET_WD_AUTORESET_SD,
GET_WD_AUTORESET_SD,
SET_TPL_SD,
GET_TPL_SD,
SET_DISC_SD,
GET_DISC_SD,
GET_DISC_CHANGE_SD,
SET_DIS_DISC_SD,
GET_DIS_DISC_SD,
SET_DISC_PWUP_SD,
GET_DISC_PWUP_SD,
GET_BYPASS_INFO_SD = 100,
GET_BP_WAIT_AT_PWUP_SD,
SET_BP_WAIT_AT_PWUP_SD,
GET_BP_HW_RESET_SD,
SET_BP_HW_RESET_SD,
};
#define SIOCGIFBYPASS (SIOCDEVPRIVATE+10)
struct bp_info {
char prod_name[14];
unsigned char fw_ver;
};
/* for passing single values */
struct if_bypass {
char if_name[IFNAMSIZ];
int cmd;
int data;
};
struct if_bypass_info {
char if_name[IFNAMSIZ];
char cmd;
struct bp_info bp_info;
};
/*
* The major device number. We can't rely on dynamic
* registration any more, because ioctls need to know
* it.
*/
#define MAGIC_NUM 'J'
/* for passing single values */
struct bpctl_cmd {
int status;
int data[8];
int in_param[8];
int out_param[8];
};
#define IOCTL_TX_MSG(cmd) _IOWR(MAGIC_NUM, cmd, struct bpctl_cmd)
#define DEVICE_NAME "bpctl"
#endif

36
drivers/staging/silicom/bypasslib/bplibk.h
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@ -1,36 +0,0 @@
/******************************************************************************/
/* */
/* bypass library, Copyright (c) 2004 Silicom, Ltd */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/* bplib.h */
/* */
/******************************************************************************/
#ifndef BYPASS_H
#define BYPASS_H
#include "bp_ioctl.h"
#include "libbp_sd.h"
#define IF_NAME "eth"
#define SILICOM_VID 0x1374
#define SILICOM_BP_PID_MIN 0x24
#define SILICOM_BP_PID_MAX 0x5f
#define INTEL_PEG4BPII_PID 0x10a0
#define INTEL_PEG4BPFII_PID 0x10a1
#define PEGII_IF_SERIES(vid, pid) \
((vid == 0x8086) && \
((pid == INTEL_PEG4BPII_PID) || \
(pid == INTEL_PEG4BPFII_PID)))
#ifdef BP_VENDOR_SUPPORT
char *bp_desc_array[] = { "e1000bp", "e1000bpe", "slcm5700",
"bnx2xbp", "ixgbp", "ixgbpe", NULL };
#endif
#endif

536
drivers/staging/silicom/bypasslib/bypass.c
View file

@ -1,536 +0,0 @@
/******************************************************************************/
/* */
/* bypass library, Copyright (c) 2004-2007 Silicom, Ltd */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* */
/* bypass.c */
/* */
/******************************************************************************/
#if defined(CONFIG_SMP) && !defined(__SMP__)
#define __SMP__
#endif
#include <linux/module.h>
#include <linux/kernel.h>
#include <asm/unistd.h>
#include <linux/sched.h>
#include <linux/wait.h>
#include <linux/netdevice.h> /* struct device, and other headers */
#include <linux/kernel_stat.h>
#include <linux/pci.h>
#include <linux/rtnetlink.h>
#include <linux/ethtool.h>
#include <net/net_namespace.h>
#include "bplibk.h"
#define MOD_NAME "bypass"
#define VERSION "\n"MOD_NAME" version 9.0.4\n"
MODULE_AUTHOR("www.silicom.co.il");
MODULE_LICENSE("GPL");
static int do_cmd(struct net_device *dev, struct ifreq *ifr, int cmd, int *data)
{
int ret = -1;
struct if_bypass *bypass_cb;
bypass_cb = (struct if_bypass *)ifr;
bypass_cb->cmd = cmd;
bypass_cb->data = *data;
if (dev->netdev_ops && dev->netdev_ops->ndo_do_ioctl) {
ret = dev->netdev_ops->ndo_do_ioctl(dev, ifr, SIOCGIFBYPASS);
*data = bypass_cb->data;
}
return ret;
}
static int doit(int cmd, int if_index, int *data)
{
struct ifreq ifr;
int ret = -1;
struct net_device *dev;
struct net_device *n;
for_each_netdev_safe(&init_net, dev, n) {
if (dev->ifindex == if_index) {
ret = do_cmd(dev, &ifr, cmd, data);
if (ret < 0)
ret = -1;
}
}
return ret;
}
#define bp_symbol_get(fn_name) symbol_get(fn_name)
#define bp_symbol_put(fn_name) symbol_put(fn_name)
#define SET_BPLIB_INT_FN(fn_name, arg_type, arg, ret) \
({ int (*fn_ex)(arg_type) = NULL; \
fn_ex = bp_symbol_get(fn_name##_sd); \
if (fn_ex) { \
ret = fn_ex(arg); \
bp_symbol_put(fn_name##_sd); \
} else { \
ret = -1; \
} \
})
#define SET_BPLIB_INT_FN2(fn_name, arg_type, arg, arg_type1, arg1, ret)\
({ int (*fn_ex)(arg_type, arg_type1) = NULL; \
fn_ex = bp_symbol_get(fn_name##_sd); \
if (fn_ex) { \
ret = fn_ex(arg, arg1); \
bp_symbol_put(fn_name##_sd); \
} else { \
ret = -1; \
} \
})
#define SET_BPLIB_INT_FN3(fn_name, arg_type, arg, arg_type1, arg1, \
arg_type2, arg2, ret) \
({ int (*fn_ex)(arg_type, arg_type1, arg_type2) = NULL; \
fn_ex = bp_symbol_get(fn_name##_sd); \
if (fn_ex) { \
ret = fn_ex(arg, arg1, arg2); \
bp_symbol_put(fn_name##_sd); \
} else { \
ret = -1; \
} \
})
#define DO_BPLIB_GET_ARG_FN(fn_name, ioctl_val, if_index) \
({ int data, ret = 0; \
if (is_dev_sd(if_index)) { \
SET_BPLIB_INT_FN(fn_name, int, if_index, ret); \
return ret; \
} \
return doit(ioctl_val, if_index, &data); \
})
#define DO_BPLIB_SET_ARG_FN(fn_name, ioctl_val, if_index, arg) \
({ int data, ret = 0; \
if (is_dev_sd(if_index)) { \
SET_BPLIB_INT_FN2(fn_name, int, if_index, int, \
arg, ret); \
return ret; \
} \
data = arg; \
return doit(ioctl_val, if_index, &data); \
})
static int is_dev_sd(int if_index)
{
int ret = 0;
SET_BPLIB_INT_FN(is_bypass, int, if_index, ret);
return ret >= 0 ? 1 : 0;
}
static int is_bypass_dev(int if_index)
{
struct pci_dev *pdev = NULL;
struct net_device *dev = NULL;
struct ifreq ifr;
int ret = 0;
int data = 0;
while ((pdev = pci_get_class(PCI_CLASS_NETWORK_ETHERNET << 8, pdev))) {
dev = pci_get_drvdata(pdev);
if ((dev != NULL) && (dev->ifindex == if_index)) {
if ((pdev->vendor == SILICOM_VID) &&
(pdev->device >= SILICOM_BP_PID_MIN) &&
(pdev->device <= SILICOM_BP_PID_MAX)) {
goto send_cmd;
}
#if defined(BP_VENDOR_SUPPORT) && defined(ETHTOOL_GDRVINFO)
else {
struct ethtool_drvinfo info;
const struct ethtool_ops *ops =
dev->ethtool_ops;
int k = 0;
if (ops->get_drvinfo) {
memset(&info, 0, sizeof(info));
info.cmd = ETHTOOL_GDRVINFO;
ops->get_drvinfo(dev, &info);
for (; bp_desc_array[k]; k++)
if (!(strcmp(bp_desc_array[k],
info.driver)))
goto send_cmd;
}
}
#endif
return -1;
}
}
send_cmd:
ret = do_cmd(dev, &ifr, IS_BYPASS, &data);
return ret < 0 ? -1 : ret;
}
static int is_bypass(int if_index)
{
int ret = 0;
SET_BPLIB_INT_FN(is_bypass, int, if_index, ret);
if (ret < 0)
return is_bypass_dev(if_index);
return ret;
}
EXPORT_SYMBOL(is_bypass);
static int get_bypass_slave(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass_slave, GET_BYPASS_SLAVE, if_index);
}
EXPORT_SYMBOL(get_bypass_slave);
static int get_bypass_caps(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass_caps, GET_BYPASS_CAPS, if_index);
}
EXPORT_SYMBOL(get_bypass_caps);
static int get_wd_set_caps(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_wd_set_caps, GET_WD_SET_CAPS, if_index);
}
EXPORT_SYMBOL(get_wd_set_caps);
static int set_bypass(int if_index, int bypass_mode)
{
DO_BPLIB_SET_ARG_FN(set_bypass, SET_BYPASS, if_index, bypass_mode);
}
EXPORT_SYMBOL(set_bypass);
static int get_bypass(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass, GET_BYPASS, if_index);
}
EXPORT_SYMBOL(get_bypass);
static int get_bypass_change(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass_change, GET_BYPASS_CHANGE, if_index);
}
EXPORT_SYMBOL(get_bypass_change);
static int set_dis_bypass(int if_index, int dis_bypass)
{
DO_BPLIB_SET_ARG_FN(set_dis_bypass, SET_DIS_BYPASS, if_index,
dis_bypass);
}
EXPORT_SYMBOL(set_dis_bypass);
static int get_dis_bypass(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_dis_bypass, GET_DIS_BYPASS, if_index);
}
EXPORT_SYMBOL(get_dis_bypass);
static int set_bypass_pwoff(int if_index, int bypass_mode)
{
DO_BPLIB_SET_ARG_FN(set_bypass_pwoff, SET_BYPASS_PWOFF, if_index,
bypass_mode);
}
EXPORT_SYMBOL(set_bypass_pwoff);
static int get_bypass_pwoff(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass_pwoff, GET_BYPASS_PWOFF, if_index);
}
EXPORT_SYMBOL(get_bypass_pwoff);
static int set_bypass_pwup(int if_index, int bypass_mode)
{
DO_BPLIB_SET_ARG_FN(set_bypass_pwup, SET_BYPASS_PWUP, if_index,
bypass_mode);
}
EXPORT_SYMBOL(set_bypass_pwup);
static int get_bypass_pwup(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bypass_pwup, GET_BYPASS_PWUP, if_index);
}
EXPORT_SYMBOL(get_bypass_pwup);
static int set_bypass_wd(int if_index, int ms_timeout, int *ms_timeout_set)
{
int data = ms_timeout;
int ret = 0;
if (is_dev_sd(if_index)) {
SET_BPLIB_INT_FN3(set_bypass_wd, int, if_index, int, ms_timeout,
int *, ms_timeout_set, ret);
} else {
ret = doit(SET_BYPASS_WD, if_index, &data);
if (ret > 0) {
*ms_timeout_set = ret;
ret = 0;
}
}
return ret;
}
EXPORT_SYMBOL(set_bypass_wd);
static int get_bypass_wd(int if_index, int *ms_timeout_set)
{
int *data = ms_timeout_set;
int ret = 0;
if (is_dev_sd(if_index))
SET_BPLIB_INT_FN2(get_bypass_wd, int, if_index, int *,
ms_timeout_set, ret);
else
ret = doit(GET_BYPASS_WD, if_index, data);
return ret;
}
EXPORT_SYMBOL(get_bypass_wd);
static int get_wd_expire_time(int if_index, int *ms_time_left)
{
int *data = ms_time_left, ret = 0;
if (is_dev_sd(if_index)) {
SET_BPLIB_INT_FN2(get_wd_expire_time, int, if_index, int *,
ms_time_left, ret);
} else {
ret = doit(GET_WD_EXPIRE_TIME, if_index, data);
if ((ret == 0) && (*data != 0))
ret = 1;
}
return ret;
}
EXPORT_SYMBOL(get_wd_expire_time);
static int reset_bypass_wd_timer(int if_index)
{
DO_BPLIB_GET_ARG_FN(reset_bypass_wd_timer, RESET_BYPASS_WD_TIMER,
if_index);
}
EXPORT_SYMBOL(reset_bypass_wd_timer);
static int set_std_nic(int if_index, int bypass_mode)
{
DO_BPLIB_SET_ARG_FN(set_std_nic, SET_STD_NIC, if_index, bypass_mode);
}
EXPORT_SYMBOL(set_std_nic);
static int get_std_nic(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_std_nic, GET_STD_NIC, if_index);
}
EXPORT_SYMBOL(get_std_nic);
static int set_tx(int if_index, int tx_state)
{
DO_BPLIB_SET_ARG_FN(set_tx, SET_TX, if_index, tx_state);
}
EXPORT_SYMBOL(set_tx);
static int get_tx(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tx, GET_TX, if_index);
}
EXPORT_SYMBOL(get_tx);
static int set_tap(int if_index, int tap_mode)
{
DO_BPLIB_SET_ARG_FN(set_tap, SET_TAP, if_index, tap_mode);
}
EXPORT_SYMBOL(set_tap);
static int get_tap(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tap, GET_TAP, if_index);
}
EXPORT_SYMBOL(get_tap);
static int get_tap_change(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tap_change, GET_TAP_CHANGE, if_index);
}
EXPORT_SYMBOL(get_tap_change);
static int set_dis_tap(int if_index, int dis_tap)
{
DO_BPLIB_SET_ARG_FN(set_dis_tap, SET_DIS_TAP, if_index, dis_tap);
}
EXPORT_SYMBOL(set_dis_tap);
static int get_dis_tap(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_dis_tap, GET_DIS_TAP, if_index);
}
EXPORT_SYMBOL(get_dis_tap);
static int set_tap_pwup(int if_index, int tap_mode)
{
DO_BPLIB_SET_ARG_FN(set_tap_pwup, SET_TAP_PWUP, if_index, tap_mode);
}
EXPORT_SYMBOL(set_tap_pwup);
static int get_tap_pwup(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tap_pwup, GET_TAP_PWUP, if_index);
}
EXPORT_SYMBOL(get_tap_pwup);
static int set_bp_disc(int if_index, int disc_mode)
{
DO_BPLIB_SET_ARG_FN(set_bp_disc, SET_DISC, if_index, disc_mode);
}
EXPORT_SYMBOL(set_bp_disc);
static int get_bp_disc(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bp_disc, GET_DISC, if_index);
}
EXPORT_SYMBOL(get_bp_disc);
static int get_bp_disc_change(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bp_disc_change, GET_DISC_CHANGE, if_index);
}
EXPORT_SYMBOL(get_bp_disc_change);
static int set_bp_dis_disc(int if_index, int dis_disc)
{
DO_BPLIB_SET_ARG_FN(set_bp_dis_disc, SET_DIS_DISC, if_index, dis_disc);
}
EXPORT_SYMBOL(set_bp_dis_disc);
static int get_bp_dis_disc(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bp_dis_disc, GET_DIS_DISC, if_index);
}
EXPORT_SYMBOL(get_bp_dis_disc);
static int set_bp_disc_pwup(int if_index, int disc_mode)
{
DO_BPLIB_SET_ARG_FN(set_bp_disc_pwup, SET_DISC_PWUP, if_index,
disc_mode);
}
EXPORT_SYMBOL(set_bp_disc_pwup);
static int get_bp_disc_pwup(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_bp_disc_pwup, GET_DISC_PWUP, if_index);
}
EXPORT_SYMBOL(get_bp_disc_pwup);
static int set_wd_exp_mode(int if_index, int mode)
{
DO_BPLIB_SET_ARG_FN(set_wd_exp_mode, SET_WD_EXP_MODE, if_index, mode);
}
EXPORT_SYMBOL(set_wd_exp_mode);
static int get_wd_exp_mode(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_wd_exp_mode, GET_WD_EXP_MODE, if_index);
}
EXPORT_SYMBOL(get_wd_exp_mode);
static int set_wd_autoreset(int if_index, int time)
{
DO_BPLIB_SET_ARG_FN(set_wd_autoreset, SET_WD_AUTORESET, if_index, time);
}
EXPORT_SYMBOL(set_wd_autoreset);
static int get_wd_autoreset(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_wd_autoreset, GET_WD_AUTORESET, if_index);
}
EXPORT_SYMBOL(get_wd_autoreset);
static int set_tpl(int if_index, int tpl_mode)
{
DO_BPLIB_SET_ARG_FN(set_tpl, SET_TPL, if_index, tpl_mode);
}
EXPORT_SYMBOL(set_tpl);
static int get_tpl(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tpl, GET_TPL, if_index);
}
EXPORT_SYMBOL(get_tpl);
static int set_bp_hw_reset(int if_index, int mode)
{
DO_BPLIB_SET_ARG_FN(set_tpl, SET_BP_HW_RESET, if_index, mode);
}
EXPORT_SYMBOL(set_bp_hw_reset);
static int get_bp_hw_reset(int if_index)
{
DO_BPLIB_GET_ARG_FN(get_tpl, GET_BP_HW_RESET, if_index);
}
EXPORT_SYMBOL(get_bp_hw_reset);
static int get_bypass_info(int if_index, struct bp_info *bp_info)
{
int ret = 0;
if (is_dev_sd(if_index)) {
SET_BPLIB_INT_FN2(get_bypass_info, int, if_index,
struct bp_info *, bp_info, ret);
} else {
struct net_device *dev;
struct net_device *n;
for_each_netdev_safe(&init_net, dev, n) {
if (dev->ifindex == if_index) {
struct if_bypass_info *bypass_cb;
struct ifreq ifr;
memset(&ifr, 0, sizeof(ifr));
bypass_cb = (struct if_bypass_info *)&ifr;
bypass_cb->cmd = GET_BYPASS_INFO;
if (dev->netdev_ops &&
dev->netdev_ops->ndo_do_ioctl)
ret = dev->netdev_ops->ndo_do_ioctl(dev,
&ifr, SIOCGIFBYPASS);
else
ret = -1;
if (ret == 0)
memcpy(bp_info, &bypass_cb->bp_info,
sizeof(struct bp_info));
ret = ret < 0 ? -1 : 0;
break;
}
}
}
return ret;
}
EXPORT_SYMBOL(get_bypass_info);
static int __init init_lib_module(void)
{
printk(VERSION);
return 0;
}
static void __exit cleanup_lib_module(void)
{
}
module_init(init_lib_module);
module_exit(cleanup_lib_module);

532
drivers/staging/silicom/bypasslib/libbp_sd.h
View file

@ -1,532 +0,0 @@
/******************************************************************************/
/* */
/* bypass library, Copyright (c) 2004 Silicom, Ltd */
/* Corporation. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* Ver 1.0.0 */
/* */
/* libbypass.h */
/* */
/******************************************************************************/
/**
* is_bypass - check if device is a Bypass controlling device
* @if_index: network device index
*
* Output:
* 1 - if device is bypass controlling device,
* 0 - if device is bypass slave device
* -1 - device not support Bypass
**/
int is_bypass_sd(int if_index);
/**
* get_bypass_slave - get second port participate in the Bypass pair
* @if_index: network device index
*
* Output:
* network device index of the slave device
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_slave_sd(int if_index);
/**
* get_bypass_caps - get second port participate in the Bypass pair
* @if_index: network device index
*
* Output:
* flags word on success;flag word is a 32-bit mask word with each bit defines
* different capability as described bellow.
* Value of 1 for supporting this feature. 0 for not supporting this feature.
* -1 - on failure (if the device is not capable of the operation or not a
* Bypass device)
* Bit feature description
*
* 0 BP_CAP The interface is Bypass capable in general
*
* 1 BP_STATUS_CAP The interface can report of the current Bypass
* mode
*
* 2 BP_STATUS_CHANGE_CAP The interface can report on a change to bypass
* mode from the last time the mode was defined
*
* 3 SW_CTL_CAP The interface is Software controlled capable for
* bypass/non bypass modes.
*
* 4 BP_DIS_CAP The interface is capable of disabling the Bypass
* mode at all times. This mode will retain its
* mode even during power loss and also after power
* recovery. This will overcome on any bypass
* operation due to watchdog timeout or set bypass
* command.
*
* 5 BP_DIS_STATUS_CAP The interface can report of the current
* DIS_BP_CAP
*
* 6 STD_NIC_CAP The interface is capable to be configured to
* operate as standard, non Bypass, NIC interface
* (have direct connection to interfaces at all
* power modes)
*
* 7 BP_PWOFF_NO_CAP The interface can be in Bypass mode at power off
* state
*
* 8 BP_PWOFF_OFF_CAP The interface can disconnect the Bypass mode at
* power off state without effecting all the other
* states of operation
*
* 9 BP_PWOFF_CTL_CAP The behavior of the Bypass mode at Power-off
* state can be controlled by software without
* effecting any other state
*
*10 BP_PWUP_ON_CAP The interface can be in Bypass mode when power
* is turned on (until the system take control of
* the bypass functionality)
*
*11 BP_PWUP_OFF_CAP The interface can disconnect from Bypass mode
* when power is turned on (until the system take
* control of the bypass functionality)
*
*12 BP_PWUP_CTL_CAP The behavior of the Bypass mode at Power-up can
* be controlled by software
*
*13 WD_CTL_CAP The interface has watchdog capabilities to turn
* to Bypass mode when not reset for defined period
* of time.
*
*14 WD_STATUS_CAP The interface can report on the watchdog status
* (Active/inactive)
*
*15 WD_TIMEOUT_CAP The interface can report the time left till
* watchdog triggers to Bypass mode.
*
*16-31 RESERVED
*
* **/
int get_bypass_caps_sd(int if_index);
/**
* get_wd_set_caps - Obtain watchdog timer setting capabilities
* @if_index: network device index
*
* Output:
*
* Set of numbers defining the various parameters of the watchdog capable
* to be set to as described bellow.
* -1 - on failure (device not support Bypass or it's a slave device)
*
* Bit feature description
*
* 0-3 WD_MIN_TIME The interface WD minimal time period in 100mS units
*
* 4 WD_STEP_TIME The steps of the WD timer in
* 0 - for linear steps (WD_MIN_TIME * X)
* 1 - for multiply by 2 from previous step
* (WD_MIN_TIME * 2^X)
*
* 5-8 WD_STEP_COUNT Number of steps the WD timer supports in 2^X
* (X bit available for defining the value)
*
*
*
**/
int get_wd_set_caps_sd(int if_index);
/**
* set_bypass - set Bypass state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode (1=on, 0=off)
* Output:
* 0 - on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int set_bypass_sd(int if_index, int bypass_mode);
/**
* get_bypass - Get Bypass mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_sd(int if_index);
/**
* get_bypass_change - Get change of Bypass mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_change_sd(int if_index);
/**
* set_dis_bypass - Set Disable Bypass mode
* @if_index: network device index of the controlling device
* @dis_bypass: disable bypass(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int set_dis_bypass_sd(int if_index, int dis_bypass);
/**
* get_dis_bypass - Get Disable Bypass mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal Bypass mode/ Disable bypass)
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int get_dis_bypass_sd(int if_index);
/**
* set_bypass_pwoff - Set Bypass mode at power-off state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode setting at power off state (1=BP en, 0=BP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int set_bypass_pwoff_sd(int if_index, int bypass_mode);
/**
* get_bypass_pwoff - Get Bypass mode state at power-off state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable bypass at power off state / normal Bypass mode)
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int get_bypass_pwoff_sd(int if_index);
/**
* set_bypass_pwup - Set Bypass mode at power-up state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode setting at power up state (1=BP en, 0=BP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int set_bypass_pwup_sd(int if_index, int bypass_mode);
/**
* get_bypass_pwup - Get Bypass mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable bypass at power up state / normal Bypass mode)
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int get_bypass_pwup_sd(int if_index);
/**
* set_bypass_wd - Set watchdog state
* @if_index: network device index of the controlling device
* @ms_timeout: requested timeout (in ms units), 0 for disabling the watchdog
* timer
* @ms_timeout_set(output): requested timeout (in ms units), that the adapter
* supports and will be used by the watchdog
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int set_bypass_wd_sd(int if_index, int ms_timeout, int *ms_timeout_set);
/**
* get_bypass_wd - Get watchdog state
* @if_index: network device index of the controlling device
* @ms_timeout (output): WDT timeout (in ms units),
* -1 for unknown wdt status
* 0 if WDT is disabled
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int get_bypass_wd_sd(int if_index, int *ms_timeout_set);
/**
* get_wd_expire_time - Get watchdog expire
* @if_index: network device index of the controlling device
* @ms_time_left (output): time left till watchdog time expire,
* -1 if WDT has expired
* 0 if WDT is disabled
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device or unknown wdt status)
**/
int get_wd_expire_time_sd(int if_index, int *ms_time_left);
/**
* reset_bypass_wd_timer - Reset watchdog timer
* @if_index: network device index of the controlling device
*
* Output:
* 1 - on success
* 0 - watchdog is not configured
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device or unknown wdt status)
**/
int reset_bypass_wd_timer_sd(int if_index);
/**
* set_std_nic - Standard NIC mode of operation
* @if_index: network device index of the controlling device
* @nic_mode: 0/1 (Default Bypass mode / Standard NIC mode)
*
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int set_std_nic_sd(int if_index, int nic_mode);
/**
* get_std_nic - Get Standard NIC mode setting
* @if_index: network device index of the controlling device
*
* Output:
* 0/1 (Default Bypass mode / Standard NIC mode) on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass or it's a slave device)
**/
int get_std_nic_sd(int if_index);
/**
* set_tx - set transmitter enable/disable
* @if_index: network device index of the controlling device
* @tx_state: 0/1 (Transmit Disable / Transmit Enable)
*
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation )
**/
int set_tx_sd(int if_index, int tx_state);
/**
* get_std_nic - get transmitter state (disable / enable)
* @if_index: network device index of the controlling device
*
* Output:
* 0/1 (ransmit Disable / Transmit Enable) on success
* -1 - on failure (device is not capable of the operation or device not support
* Bypass)
**/
int get_tx_sd(int if_index);
/**
* set_tap - set TAP state
* @if_index: network device index of the controlling device
* @tap_mode: 1 tap mode , 0 normal nic mode
* Output:
* 0 - on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int set_tap_sd(int if_index, int tap_mode);
/**
* get_tap - Get TAP mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int get_tap_sd(int if_index);
/**
* get_tap_change - Get change of TAP mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int get_tap_change_sd(int if_index);
/**
* set_dis_tap - Set Disable TAP mode
* @if_index: network device index of the controlling device
* @dis_tap: disable tap(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not support
* TAP or it's a slave device)
**/
int set_dis_tap_sd(int if_index, int dis_tap);
/**
* get_dis_tap - Get Disable TAP mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal TAP mode/ Disable TAP)
* -1 - on failure (device is not capable of the operation or device not support
* TAP or it's a slave device)
**/
int get_dis_tap_sd(int if_index);
/**
* set_tap_pwup - Set TAP mode at power-up state
* @if_index: network device index of the controlling device
* @bypass_mode: tap mode setting at power up state (1=TAP en, 0=TAP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not
* support TAP or it's a slave device)
**/
int set_tap_pwup_sd(int if_index, int tap_mode);
/**
* get_tap_pwup - Get TAP mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable TAP at power up state / normal TAP mode)
* -1 - on failure (device is not capable of the operation or device not
* support TAP or it's a slave device)
**/
int get_tap_pwup_sd(int if_index);
/**
* set_bp_disc - set Disconnect state
* @if_index: network device index of the controlling device
* @tap_mode: 1 disc mode , 0 non-disc mode
* Output:
* 0 - on success
* -1 - on failure (device not support Disconnect or it's a slave device)
**/
int set_bp_disc_sd(int if_index, int disc_mode);
/**
* get_bp_disc - Get Disconnect mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Disconnect or it's a slave device)
**/
int get_bp_disc_sd(int if_index);
/**
* get_bp_disc_change - Get change of Disconnect mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Disconnect or it's a slave device)
**/
int get_bp_disc_change_sd(int if_index);
/**
* set_bp_dis_disc - Set Disable Disconnect mode
* @if_index: network device index of the controlling device
* @dis_tap: disable tap(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable ofthe operation or device not
* support Disconnect or it's a slave device)
**/
int set_bp_dis_disc_sd(int if_index, int dis_disc);
/**
* get_dis_tap - Get Disable Disconnect mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal Disconnect mode/ Disable Disconnect)
* -1 - on failure (device is not capable of the operation or device not
* support Disconnect or it's a slave device)
**/
int get_bp_dis_disc_sd(int if_index);
/**
* set_bp_disc_pwup - Set Disconnect mode at power-up state
* @if_index: network device index of the controlling device
* @disc_mode: tap mode setting at power up state (1=Disc en, 0=Disc Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation or device not
* support Disconnect or it's a slave device)
**/
int set_bp_disc_pwup_sd(int if_index, int disc_mode);
/**
* get_bp_disc_pwup - Get Disconnect mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable Disconnect at power up state / normal Disconnect
* mode)
* -1 - on failure (device is not capable of the operation or device not
* support TAP or it's a slave device)
**/
int get_bp_disc_pwup_sd(int if_index);
/**
* set_wd_exp_mode - Set adapter state when WDT expired.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 0 - on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int set_wd_exp_mode_sd(int if_index, int bypass_mode);
/**
* get_wd_exp_mode - Get adapter state when WDT expired.
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (bypass/tap) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_wd_exp_mode_sd(int if_index);
/**
* set_wd_autoreset - reset WDT periodically.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 1 - on success
* -1 - on failure (device is not capable of the operation or device not
* support Bypass or it's a slave device or unknown wdt
* status)
**/
int set_wd_autoreset_sd(int if_index, int time);
/**
* set_wd_autoreset - reset WDT periodically.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 1 - on success
* -1 - on failure (device is not capable of the operation or device not
* support Bypass or it's a slave device or unknown wdt
* status)
**/
int get_wd_autoreset_sd(int if_index);
/**
* set_tpl - set TPL state
* @if_index: network device index of the controlling device
* @tpl_mode: 1 tpl mode , 0 normal nic mode
* Output:
* 0 - on success
* -1 - on failure (device not support TPL)
**/
int set_tpl_sd(int if_index, int tpl_mode);
/**
* get_tpl - Get TPL mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support TPL or it's a slave device)
**/
int get_tpl_sd(int if_index);
int get_bypass_info_sd(int if_index, struct bp_info *bp_info);
int bp_if_scan_sd(void);
/*int get_dev_num_sd(void);*/

550
drivers/staging/silicom/libbp_sd.h
View file

@ -1,550 +0,0 @@
/******************************************************************************/
/* */
/* bypass library, Copyright (c) 2004 Silicom, Ltd */
/* Corporation. */
/* */
/* This program is free software; you can redistribute it and/or modify */
/* it under the terms of the GNU General Public License as published by */
/* the Free Software Foundation, located in the file LICENSE. */
/* */
/* Ver 1.0.0 */
/* */
/* libbypass.h */
/* */
/******************************************************************************/
#define BP_CAP 0x01 /* BIT_0 */
#define BP_STATUS_CAP 0x02
#define BP_STATUS_CHANGE_CAP 0x04
#define SW_CTL_CAP 0x08
#define BP_DIS_CAP 0x10
#define BP_DIS_STATUS_CAP 0x20
#define STD_NIC_CAP 0x40
#define BP_PWOFF_ON_CAP 0x80
#define BP_PWOFF_OFF_CAP 0x0100
#define BP_PWOFF_CTL_CAP 0x0200
#define BP_PWUP_ON_CAP 0x0400
#define BP_PWUP_OFF_CAP 0x0800
#define BP_PWUP_CTL_CAP 0x1000
#define WD_CTL_CAP 0x2000
#define WD_STATUS_CAP 0x4000
#define WD_TIMEOUT_CAP 0x8000
#define TX_CTL_CAP 0x10000
#define TX_STATUS_CAP 0x20000
#define TAP_CAP 0x40000
#define TAP_STATUS_CAP 0x80000
#define TAP_STATUS_CHANGE_CAP 0x100000
#define TAP_DIS_CAP 0x200000
#define TAP_DIS_STATUS_CAP 0x400000
#define TAP_PWUP_ON_CAP 0x800000
#define TAP_PWUP_OFF_CAP 0x1000000
#define TAP_PWUP_CTL_CAP 0x2000000
#define NIC_CAP_NEG 0x4000000 /* BIT 26 */
#define WD_MIN_TIME_GET(desc) (desc & 0xf)
#define WDT_STEP_TIME 0x10
struct bp_info {
char prod_name[14];
unsigned char fw_ver;
};
/**
* is_bypass - check if device is a Bypass controlling device
* @if_index: network device index
*
* Output:
* 1 - if device is bypass controlling device,
* 0 - if device is bypass slave device
* -1 - device not support Bypass
**/
int is_bypass_sd(int if_index);
/**
* get_bypass_slave - get second port participate in the Bypass pair
* @if_index: network device index
*
* Output:
* network device index of the slave device
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_slave_sd(int if_index);
/**
* get_bypass_caps - get second port participate in the Bypass pair
* @if_index: network device index
*
* Output:
* flags word on success;flag word is a 32-bit mask word with each bit defines different
* capability as described bellow.
* Value of 1 for supporting this feature. 0 for not supporting this feature.
* -1 - on failure (if the device is not capable of the operation or not a Bypass device)
* Bit feature description
*
* 0 BP_CAP The interface is Bypass capable in general
*
* 1 BP_STATUS_CAP The interface can report of the current Bypass mode
*
* 2 BP_STATUS_CHANGE_CAP The interface can report on a change to bypass mode from
* the last time the mode was defined
*
* 3 SW_CTL_CAP The interface is Software controlled capable for bypass/non bypass modes.
*
* 4 BP_DIS_CAP The interface is capable of disabling the Bypass mode at all times.
* This mode will retain its mode even during power loss and also after
* power recovery. This will overcome on any bypass operation due to
* watchdog timeout or set bypass command.
*
* 5 BP_DIS_STATUS_CAP The interface can report of the current DIS_BP_CAP
*
* 6 STD_NIC_CAP The interface is capable to be configured to operate as standard, non Bypass,
* NIC interface (have direct connection to interfaces at all power modes)
*
* 7 BP_PWOFF_NO_CAP The interface can be in Bypass mode at power off state
*
* 8 BP_PWOFF_OFF_CAP The interface can disconnect the Bypass mode at power off state without
* effecting all the other states of operation
*
* 9 BP_PWOFF_CTL_CAP The behavior of the Bypass mode at Power-off state can be controlled by
* software without effecting any other state
*
*10 BP_PWUP_ON_CAP The interface can be in Bypass mode when power is turned on
* (until the system take control of the bypass functionality)
*
*11 BP_PWUP_OFF_CAP The interface can disconnect from Bypass mode when power is turned on
* (until the system take control of the bypass functionality)
*
*12 BP_PWUP_CTL_CAP The behavior of the Bypass mode at Power-up can be controlled by software
*
*13 WD_CTL_CAP The interface has watchdog capabilities to turn to Bypass mode when not reset
* for defined period of time.
*
*14 WD_STATUS_CAP The interface can report on the watchdog status (Active/inactive)
*
*15 WD_TIMEOUT_CAP The interface can report the time left till watchdog triggers to Bypass mode.
*
*16-31 RESERVED
*
* **/
int get_bypass_caps_sd(int if_index);
/**
* get_wd_set_caps - Obtain watchdog timer setting capabilities
* @if_index: network device index
*
* Output:
*
* Set of numbers defining the various parameters of the watchdog capable
* to be set to as described bellow.
* -1 - on failure (device not support Bypass or it's a slave device)
*
* Bit feature description
*
* 0-3 WD_MIN_TIME The interface WD minimal time period in 100mS units
*
* 4 WD_STEP_TIME The steps of the WD timer in
* 0 - for linear steps (WD_MIN_TIME * X)
* 1 - for multiply by 2 from previous step (WD_MIN_TIME * 2^X)
*
* 5-8 WD_STEP_COUNT Number of steps the WD timer supports in 2^X
* (X bit available for defining the value)
*
*
*
**/
int get_wd_set_caps_sd(int if_index);
/**
* set_bypass - set Bypass state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode (1=on, 0=off)
* Output:
* 0 - on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int set_bypass_sd(int if_index, int bypass_mode);
/**
* get_bypass - Get Bypass mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_sd(int if_index);
/**
* get_bypass_change - Get change of Bypass mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_bypass_change_sd(int if_index);
/**
* set_dis_bypass - Set Disable Bypass mode
* @if_index: network device index of the controlling device
* @dis_bypass: disable bypass(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int set_dis_bypass_sd(int if_index, int dis_bypass);
/**
* get_dis_bypass - Get Disable Bypass mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal Bypass mode/ Disable bypass)
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int get_dis_bypass_sd(int if_index);
/**
* set_bypass_pwoff - Set Bypass mode at power-off state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode setting at power off state (1=BP en, 0=BP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int set_bypass_pwoff_sd(int if_index, int bypass_mode);
/**
* get_bypass_pwoff - Get Bypass mode state at power-off state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable bypass at power off state / normal Bypass mode)
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int get_bypass_pwoff_sd(int if_index);
/**
* set_bypass_pwup - Set Bypass mode at power-up state
* @if_index: network device index of the controlling device
* @bypass_mode: bypass mode setting at power up state (1=BP en, 0=BP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int set_bypass_pwup_sd(int if_index, int bypass_mode);
/**
* get_bypass_pwup - Get Bypass mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable bypass at power up state / normal Bypass mode)
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int get_bypass_pwup_sd(int if_index);
/**
* set_bypass_wd - Set watchdog state
* @if_index: network device index of the controlling device
* @ms_timeout: requested timeout (in ms units), 0 for disabling the watchdog timer
* @ms_timeout_set(output): requested timeout (in ms units),
* that the adapter supports and will be used by the watchdog
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int set_bypass_wd_sd(int if_index, int ms_timeout, int *ms_timeout_set);
/**
* get_bypass_wd - Get watchdog state
* @if_index: network device index of the controlling device
* @ms_timeout (output): WDT timeout (in ms units),
* -1 for unknown wdt status
* 0 if WDT is disabled
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int get_bypass_wd_sd(int if_index, int *ms_timeout_set);
/**
* get_wd_expire_time - Get watchdog expire
* @if_index: network device index of the controlling device
* @ms_time_left (output): time left till watchdog time expire,
* -1 if WDT has expired
* 0 if WDT is disabled
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device or unknown wdt status)
**/
int get_wd_expire_time_sd(int if_index, int *ms_time_left);
/**
* reset_bypass_wd_timer - Reset watchdog timer
* @if_index: network device index of the controlling device
*
* Output:
* 1 - on success
* 0 - watchdog is not configured
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device or unknown wdt status)
**/
int reset_bypass_wd_timer_sd(int if_index);
/**
* set_std_nic - Standard NIC mode of operation
* @if_index: network device index of the controlling device
* @nic_mode: 0/1 (Default Bypass mode / Standard NIC mode)
*
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int set_std_nic_sd(int if_index, int nic_mode);
/**
* get_std_nic - Get Standard NIC mode setting
* @if_index: network device index of the controlling device
*
* Output:
* 0/1 (Default Bypass mode / Standard NIC mode) on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device)
**/
int get_std_nic_sd(int if_index);
/**
* set_tx - set transmitter enable/disable
* @if_index: network device index of the controlling device
* @tx_state: 0/1 (Transmit Disable / Transmit Enable)
*
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation )
**/
int set_tx_sd(int if_index, int tx_state);
/**
* get_tx - get transmitter state (disable / enable)
* @if_index: network device index of the controlling device
*
* Output:
* 0/1 (ransmit Disable / Transmit Enable) on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass)
**/
int get_tx_sd(int if_index);
/**
* set_tpl - set TPL enable/disable
* @if_index: network device index of the controlling device
* @tx_state: 0/1 (TPL Disable / TPL Enable)
*
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation )
**/
int set_tpl_sd(int if_index, int tpl_state);
/**
* get_tpl - get TPL state (disable / enable)
* @if_index: network device index of the controlling device
*
* Output:
* 0/1 (TPL Disable / TPL Enable) on success
* -1 - on failure (device is not capable of the operation)
**/
int get_tpl_sd(int if_index);
int get_bp_hw_reset_sd(int if_index);
int set_bp_hw_reset_sd(int if_index, int status);
/**
* set_tap - set TAP state
* @if_index: network device index of the controlling device
* @tap_mode: 1 tap mode , 0 normal nic mode
* Output:
* 0 - on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int set_tap_sd(int if_index, int tap_mode);
/**
* get_tap - Get TAP mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int get_tap_sd(int if_index);
/**
* get_tap_change - Get change of TAP mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support TAP or it's a slave device)
**/
int get_tap_change_sd(int if_index);
/**
* set_dis_tap - Set Disable TAP mode
* @if_index: network device index of the controlling device
* @dis_tap: disable tap(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support TAP
* or it's a slave device)
**/
int set_dis_tap_sd(int if_index, int dis_tap);
/**
* get_dis_tap - Get Disable TAP mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal TAP mode/ Disable TAP)
* -1 - on failure (device is not capable of the operation ordevice not support TAP
* or it's a slave device)
**/
int get_dis_tap_sd(int if_index);
/**
* set_tap_pwup - Set TAP mode at power-up state
* @if_index: network device index of the controlling device
* @bypass_mode: tap mode setting at power up state (1=TAP en, 0=TAP Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support TAP
* or it's a slave device)
**/
int set_tap_pwup_sd(int if_index, int tap_mode);
/**
* get_tap_pwup - Get TAP mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable TAP at power up state / normal TAP mode)
* -1 - on failure (device is not capable of the operation ordevice not support TAP
* or it's a slave device)
**/
int get_tap_pwup_sd(int if_index);
/**
* set_wd_exp_mode - Set adapter state when WDT expired.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 0 - on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int set_wd_exp_mode_sd(int if_index, int bypass_mode);
/**
* get_wd_exp_mode - Get adapter state when WDT expired.
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (bypass/tap) on success
* -1 - on failure (device not support Bypass or it's a slave device)
**/
int get_wd_exp_mode_sd(int if_index);
/**
* set_wd_autoreset - reset WDT periodically.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 1 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device or unknown wdt status)
**/
int set_wd_autoreset_sd(int if_index, int time);
/**
* set_wd_autoreset - reset WDT periodically.
* @if_index: network device index of the controlling device
* @bypass_mode: adapter mode (1=tap mode, 0=bypass mode)
* Output:
* 1 - on success
* -1 - on failure (device is not capable of the operation ordevice not support Bypass
* or it's a slave device or unknown wdt status)
**/
int get_wd_autoreset_sd(int if_index);
/**
* set_disc - set DISC state
* @if_index: network device index of the controlling device
* @tap_mode: 1 DISC mode , 0 normal nic mode
* Output:
* 0 - on success
* -1 - on failure (device not support disconnect or it's a slave device)
**/
int set_bp_disc_sd(int if_index, int disc_mode);
/**
* get_disc - Get disc mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support disconnect or it's a slave device)
**/
int get_bp_disc_sd(int if_index);
/**
* get_disc_change - Get change of DISC mode state from last status check
* @if_index: network device index of the controlling device
* Output:
* 0/1 - (off/on) on success
* -1 - on failure (device not support disconnect or it's a slave device)
**/
int get_bp_disc_change_sd(int if_index);
/**
* set_dis_disc - Set Disable DISC mode
* @if_index: network device index of the controlling device
* @dis_disc: disable disconnect(1=dis, 0=en)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support DISC
* or it's a slave device)
**/
int set_bp_dis_disc_sd(int if_index, int dis_disc);
/**
* get_dis_disc - Get Disable DISC mode state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (normal DISC mode/ Disable DISC)
* -1 - on failure (device is not capable of the operation ordevice not support TAP
* or it's a slave device)
**/
int get_bp_dis_disc_sd(int if_index);
/**
* set_disc_pwup - Set DISC mode at power-up state
* @if_index: network device index of the controlling device
* @disc_mode: DISC mode setting at power up state (1= en, 0= Dis)
* Output:
* 0 - on success
* -1 - on failure (device is not capable of the operation ordevice not support DISC
* or it's a slave device)
**/
int set_bp_disc_pwup_sd(int if_index, int disc_mode);
/**
* get_disc_pwup - Get DISC mode state at power-up state
* @if_index: network device index of the controlling device
* Output:
* 0/1 - on success (Disable DISC at power up state / normal DISC mode)
* -1 - on failure (device is not capable of the operation ordevice not support DISC
* or it's a slave device)
**/
int get_bp_disc_pwup_sd(int if_index);
int get_bypass_info_sd(int if_index, struct bp_info *bp_info);
int bp_if_scan_sd(void);
/*int get_dev_num_sd(void);*/