OpenCloudOS-Kernel/drivers/ntb/hw/intel/ntb_hw_intel.h

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PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
/*
* This file is provided under a dual BSD/GPLv2 license. When using or
* redistributing this file, you may do so under either license.
*
* GPL LICENSE SUMMARY
*
* Copyright(c) 2012 Intel Corporation. All rights reserved.
* Copyright (C) 2015 EMC Corporation. All Rights Reserved.
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of version 2 of the GNU General Public License as
* published by the Free Software Foundation.
*
* BSD LICENSE
*
* Copyright(c) 2012 Intel Corporation. All rights reserved.
* Copyright (C) 2015 EMC Corporation. All Rights Reserved.
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copy
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "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 COPYRIGHT
* OWNER OR CONTRIBUTORS 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.
*
* Intel PCIe NTB Linux driver
*
* Contact Information:
* Jon Mason <jon.mason@intel.com>
*/
#ifndef NTB_HW_INTEL_H
#define NTB_HW_INTEL_H
#include <linux/ntb.h>
#include <linux/pci.h>
#define PCI_DEVICE_ID_INTEL_NTB_B2B_JSF 0x3725
#define PCI_DEVICE_ID_INTEL_NTB_PS_JSF 0x3726
#define PCI_DEVICE_ID_INTEL_NTB_SS_JSF 0x3727
#define PCI_DEVICE_ID_INTEL_NTB_B2B_SNB 0x3C0D
#define PCI_DEVICE_ID_INTEL_NTB_PS_SNB 0x3C0E
#define PCI_DEVICE_ID_INTEL_NTB_SS_SNB 0x3C0F
#define PCI_DEVICE_ID_INTEL_NTB_B2B_IVT 0x0E0D
#define PCI_DEVICE_ID_INTEL_NTB_PS_IVT 0x0E0E
#define PCI_DEVICE_ID_INTEL_NTB_SS_IVT 0x0E0F
#define PCI_DEVICE_ID_INTEL_NTB_B2B_HSX 0x2F0D
#define PCI_DEVICE_ID_INTEL_NTB_PS_HSX 0x2F0E
#define PCI_DEVICE_ID_INTEL_NTB_SS_HSX 0x2F0F
#define PCI_DEVICE_ID_INTEL_NTB_B2B_BWD 0x0C4E
#define PCI_DEVICE_ID_INTEL_NTB_B2B_BDX 0x6F0D
#define PCI_DEVICE_ID_INTEL_NTB_PS_BDX 0x6F0E
#define PCI_DEVICE_ID_INTEL_NTB_SS_BDX 0x6F0F
/* Intel Xeon hardware */
#define XEON_PBAR23LMT_OFFSET 0x0000
#define XEON_PBAR45LMT_OFFSET 0x0008
#define XEON_PBAR4LMT_OFFSET 0x0008
#define XEON_PBAR5LMT_OFFSET 0x000c
#define XEON_PBAR23XLAT_OFFSET 0x0010
#define XEON_PBAR45XLAT_OFFSET 0x0018
#define XEON_PBAR4XLAT_OFFSET 0x0018
#define XEON_PBAR5XLAT_OFFSET 0x001c
#define XEON_SBAR23LMT_OFFSET 0x0020
#define XEON_SBAR45LMT_OFFSET 0x0028
#define XEON_SBAR4LMT_OFFSET 0x0028
#define XEON_SBAR5LMT_OFFSET 0x002c
#define XEON_SBAR23XLAT_OFFSET 0x0030
#define XEON_SBAR45XLAT_OFFSET 0x0038
#define XEON_SBAR4XLAT_OFFSET 0x0038
#define XEON_SBAR5XLAT_OFFSET 0x003c
#define XEON_SBAR0BASE_OFFSET 0x0040
#define XEON_SBAR23BASE_OFFSET 0x0048
#define XEON_SBAR45BASE_OFFSET 0x0050
#define XEON_SBAR4BASE_OFFSET 0x0050
#define XEON_SBAR5BASE_OFFSET 0x0054
#define XEON_SBDF_OFFSET 0x005c
#define XEON_NTBCNTL_OFFSET 0x0058
#define XEON_PDOORBELL_OFFSET 0x0060
#define XEON_PDBMSK_OFFSET 0x0062
#define XEON_SDOORBELL_OFFSET 0x0064
#define XEON_SDBMSK_OFFSET 0x0066
#define XEON_USMEMMISS_OFFSET 0x0070
#define XEON_SPAD_OFFSET 0x0080
#define XEON_PBAR23SZ_OFFSET 0x00d0
#define XEON_PBAR45SZ_OFFSET 0x00d1
#define XEON_PBAR4SZ_OFFSET 0x00d1
#define XEON_SBAR23SZ_OFFSET 0x00d2
#define XEON_SBAR45SZ_OFFSET 0x00d3
#define XEON_SBAR4SZ_OFFSET 0x00d3
#define XEON_PPD_OFFSET 0x00d4
#define XEON_PBAR5SZ_OFFSET 0x00d5
#define XEON_SBAR5SZ_OFFSET 0x00d6
#define XEON_WCCNTRL_OFFSET 0x00e0
#define XEON_UNCERRSTS_OFFSET 0x014c
#define XEON_CORERRSTS_OFFSET 0x0158
#define XEON_LINK_STATUS_OFFSET 0x01a2
#define XEON_SPCICMD_OFFSET 0x0504
#define XEON_DEVCTRL_OFFSET 0x0598
#define XEON_DEVSTS_OFFSET 0x059a
#define XEON_SLINK_STATUS_OFFSET 0x05a2
#define XEON_B2B_SPAD_OFFSET 0x0100
#define XEON_B2B_DOORBELL_OFFSET 0x0140
#define XEON_B2B_XLAT_OFFSETL 0x0144
#define XEON_B2B_XLAT_OFFSETU 0x0148
#define XEON_PPD_CONN_MASK 0x03
#define XEON_PPD_CONN_TRANSPARENT 0x00
#define XEON_PPD_CONN_B2B 0x01
#define XEON_PPD_CONN_RP 0x02
#define XEON_PPD_DEV_MASK 0x10
#define XEON_PPD_DEV_USD 0x00
#define XEON_PPD_DEV_DSD 0x10
#define XEON_PPD_SPLIT_BAR_MASK 0x40
#define XEON_PPD_TOPO_MASK (XEON_PPD_CONN_MASK | XEON_PPD_DEV_MASK)
#define XEON_PPD_TOPO_PRI_USD (XEON_PPD_CONN_RP | XEON_PPD_DEV_USD)
#define XEON_PPD_TOPO_PRI_DSD (XEON_PPD_CONN_RP | XEON_PPD_DEV_DSD)
#define XEON_PPD_TOPO_SEC_USD (XEON_PPD_CONN_TRANSPARENT | XEON_PPD_DEV_USD)
#define XEON_PPD_TOPO_SEC_DSD (XEON_PPD_CONN_TRANSPARENT | XEON_PPD_DEV_DSD)
#define XEON_PPD_TOPO_B2B_USD (XEON_PPD_CONN_B2B | XEON_PPD_DEV_USD)
#define XEON_PPD_TOPO_B2B_DSD (XEON_PPD_CONN_B2B | XEON_PPD_DEV_DSD)
#define XEON_MW_COUNT 2
#define HSX_SPLIT_BAR_MW_COUNT 3
#define XEON_DB_COUNT 15
#define XEON_DB_LINK 15
#define XEON_DB_LINK_BIT BIT_ULL(XEON_DB_LINK)
#define XEON_DB_MSIX_VECTOR_COUNT 4
#define XEON_DB_MSIX_VECTOR_SHIFT 5
#define XEON_DB_TOTAL_SHIFT 16
#define XEON_SPAD_COUNT 16
/* Intel Atom hardware */
#define ATOM_SBAR2XLAT_OFFSET 0x0008
#define ATOM_PDOORBELL_OFFSET 0x0020
#define ATOM_PDBMSK_OFFSET 0x0028
#define ATOM_NTBCNTL_OFFSET 0x0060
#define ATOM_SPAD_OFFSET 0x0080
#define ATOM_PPD_OFFSET 0x00d4
#define ATOM_PBAR2XLAT_OFFSET 0x8008
#define ATOM_B2B_DOORBELL_OFFSET 0x8020
#define ATOM_B2B_SPAD_OFFSET 0x8080
#define ATOM_SPCICMD_OFFSET 0xb004
#define ATOM_LINK_STATUS_OFFSET 0xb052
#define ATOM_ERRCORSTS_OFFSET 0xb110
#define ATOM_IP_BASE 0xc000
#define ATOM_DESKEWSTS_OFFSET (ATOM_IP_BASE + 0x3024)
#define ATOM_LTSSMERRSTS0_OFFSET (ATOM_IP_BASE + 0x3180)
#define ATOM_LTSSMSTATEJMP_OFFSET (ATOM_IP_BASE + 0x3040)
#define ATOM_IBSTERRRCRVSTS0_OFFSET (ATOM_IP_BASE + 0x3324)
#define ATOM_MODPHY_PCSREG4 0x1c004
#define ATOM_MODPHY_PCSREG6 0x1c006
#define ATOM_PPD_INIT_LINK 0x0008
#define ATOM_PPD_CONN_MASK 0x0300
#define ATOM_PPD_CONN_TRANSPARENT 0x0000
#define ATOM_PPD_CONN_B2B 0x0100
#define ATOM_PPD_CONN_RP 0x0200
#define ATOM_PPD_DEV_MASK 0x1000
#define ATOM_PPD_DEV_USD 0x0000
#define ATOM_PPD_DEV_DSD 0x1000
#define ATOM_PPD_TOPO_MASK (ATOM_PPD_CONN_MASK | ATOM_PPD_DEV_MASK)
#define ATOM_PPD_TOPO_PRI_USD (ATOM_PPD_CONN_TRANSPARENT | ATOM_PPD_DEV_USD)
#define ATOM_PPD_TOPO_PRI_DSD (ATOM_PPD_CONN_TRANSPARENT | ATOM_PPD_DEV_DSD)
#define ATOM_PPD_TOPO_SEC_USD (ATOM_PPD_CONN_RP | ATOM_PPD_DEV_USD)
#define ATOM_PPD_TOPO_SEC_DSD (ATOM_PPD_CONN_RP | ATOM_PPD_DEV_DSD)
#define ATOM_PPD_TOPO_B2B_USD (ATOM_PPD_CONN_B2B | ATOM_PPD_DEV_USD)
#define ATOM_PPD_TOPO_B2B_DSD (ATOM_PPD_CONN_B2B | ATOM_PPD_DEV_DSD)
#define ATOM_MW_COUNT 2
#define ATOM_DB_COUNT 34
#define ATOM_DB_VALID_MASK (BIT_ULL(ATOM_DB_COUNT) - 1)
#define ATOM_DB_MSIX_VECTOR_COUNT 34
#define ATOM_DB_MSIX_VECTOR_SHIFT 1
#define ATOM_DB_TOTAL_SHIFT 34
#define ATOM_SPAD_COUNT 16
#define ATOM_NTB_CTL_DOWN_BIT BIT(16)
#define ATOM_NTB_CTL_ACTIVE(x) !(x & ATOM_NTB_CTL_DOWN_BIT)
#define ATOM_DESKEWSTS_DBERR BIT(15)
#define ATOM_LTSSMERRSTS0_UNEXPECTEDEI BIT(20)
#define ATOM_LTSSMSTATEJMP_FORCEDETECT BIT(2)
#define ATOM_IBIST_ERR_OFLOW 0x7FFF7FFF
#define ATOM_LINK_HB_TIMEOUT msecs_to_jiffies(1000)
#define ATOM_LINK_RECOVERY_TIME msecs_to_jiffies(500)
/* Ntb control and link status */
#define NTB_CTL_CFG_LOCK BIT(0)
#define NTB_CTL_DISABLE BIT(1)
#define NTB_CTL_S2P_BAR2_SNOOP BIT(2)
#define NTB_CTL_P2S_BAR2_SNOOP BIT(4)
#define NTB_CTL_S2P_BAR4_SNOOP BIT(6)
#define NTB_CTL_P2S_BAR4_SNOOP BIT(8)
#define NTB_CTL_S2P_BAR5_SNOOP BIT(12)
#define NTB_CTL_P2S_BAR5_SNOOP BIT(14)
#define NTB_LNK_STA_ACTIVE_BIT 0x2000
#define NTB_LNK_STA_SPEED_MASK 0x000f
#define NTB_LNK_STA_WIDTH_MASK 0x03f0
#define NTB_LNK_STA_ACTIVE(x) (!!((x) & NTB_LNK_STA_ACTIVE_BIT))
#define NTB_LNK_STA_SPEED(x) ((x) & NTB_LNK_STA_SPEED_MASK)
#define NTB_LNK_STA_WIDTH(x) (((x) & NTB_LNK_STA_WIDTH_MASK) >> 4)
/* Use the following addresses for translation between b2b ntb devices in case
* the hardware default values are not reliable. */
#define XEON_B2B_BAR0_ADDR 0x1000000000000000ull
#define XEON_B2B_BAR2_ADDR64 0x2000000000000000ull
#define XEON_B2B_BAR4_ADDR64 0x4000000000000000ull
#define XEON_B2B_BAR4_ADDR32 0x20000000u
#define XEON_B2B_BAR5_ADDR32 0x40000000u
/* The peer ntb secondary config space is 32KB fixed size */
#define XEON_B2B_MIN_SIZE 0x8000
/* flags to indicate hardware errata */
#define NTB_HWERR_SDOORBELL_LOCKUP BIT_ULL(0)
#define NTB_HWERR_SB01BASE_LOCKUP BIT_ULL(1)
#define NTB_HWERR_B2BDOORBELL_BIT14 BIT_ULL(2)
/* flags to indicate unsafe api */
#define NTB_UNSAFE_DB BIT_ULL(0)
#define NTB_UNSAFE_SPAD BIT_ULL(1)
#define NTB_BAR_MASK_64 ~(0xfull)
#define NTB_BAR_MASK_32 ~(0xfu)
struct intel_ntb_dev;
struct intel_ntb_reg {
int (*poll_link)(struct intel_ntb_dev *ndev);
int (*link_is_up)(struct intel_ntb_dev *ndev);
u64 (*db_ioread)(void __iomem *mmio);
void (*db_iowrite)(u64 db_bits, void __iomem *mmio);
unsigned long ntb_ctl;
resource_size_t db_size;
int mw_bar[];
};
struct intel_ntb_alt_reg {
unsigned long db_bell;
unsigned long db_mask;
unsigned long spad;
};
struct intel_ntb_xlat_reg {
unsigned long bar0_base;
unsigned long bar2_xlat;
unsigned long bar2_limit;
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
};
struct intel_b2b_addr {
phys_addr_t bar0_addr;
phys_addr_t bar2_addr64;
phys_addr_t bar4_addr64;
phys_addr_t bar4_addr32;
phys_addr_t bar5_addr32;
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
};
struct intel_ntb_vec {
struct intel_ntb_dev *ndev;
int num;
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
};
struct intel_ntb_dev {
struct ntb_dev ntb;
/* offset of peer bar0 in b2b bar */
unsigned long b2b_off;
/* mw idx used to access peer bar0 */
unsigned int b2b_idx;
/* BAR45 is split into BAR4 and BAR5 */
bool bar4_split;
u32 ntb_ctl;
u32 lnk_sta;
unsigned char mw_count;
unsigned char spad_count;
unsigned char db_count;
unsigned char db_vec_count;
unsigned char db_vec_shift;
u64 db_valid_mask;
u64 db_link_mask;
u64 db_mask;
/* synchronize rmw access of db_mask and hw reg */
spinlock_t db_mask_lock;
struct msix_entry *msix;
struct intel_ntb_vec *vec;
const struct intel_ntb_reg *reg;
const struct intel_ntb_alt_reg *self_reg;
const struct intel_ntb_alt_reg *peer_reg;
const struct intel_ntb_xlat_reg *xlat_reg;
void __iomem *self_mmio;
void __iomem *peer_mmio;
phys_addr_t peer_addr;
unsigned long last_ts;
struct delayed_work hb_timer;
unsigned long hwerr_flags;
unsigned long unsafe_flags;
unsigned long unsafe_flags_ignore;
struct dentry *debugfs_dir;
struct dentry *debugfs_info;
PCI-Express Non-Transparent Bridge Support A PCI-Express non-transparent bridge (NTB) is a point-to-point PCIe bus connecting 2 systems, providing electrical isolation between the two subsystems. A non-transparent bridge is functionally similar to a transparent bridge except that both sides of the bridge have their own independent address domains. The host on one side of the bridge will not have the visibility of the complete memory or I/O space on the other side of the bridge. To communicate across the non-transparent bridge, each NTB endpoint has one (or more) apertures exposed to the local system. Writes to these apertures are mirrored to memory on the remote system. Communications can also occur through the use of doorbell registers that initiate interrupts to the alternate domain, and scratch-pad registers accessible from both sides. The NTB device driver is needed to configure these memory windows, doorbell, and scratch-pad registers as well as use them in such a way as they can be turned into a viable communication channel to the remote system. ntb_hw.[ch] determines the usage model (NTB to NTB or NTB to Root Port) and abstracts away the underlying hardware to provide access and a common interface to the doorbell registers, scratch pads, and memory windows. These hardware interfaces are exported so that other, non-mainlined kernel drivers can access these. ntb_transport.[ch] also uses the exported interfaces in ntb_hw.[ch] to setup a communication channel(s) and provide a reliable way of transferring data from one side to the other, which it then exports so that "client" drivers can access them. These client drivers are used to provide a standard kernel interface (i.e., Ethernet device) to NTB, such that Linux can transfer data from one system to the other in a standard way. Signed-off-by: Jon Mason <jon.mason@intel.com> Reviewed-by: Nicholas Bellinger <nab@linux-iscsi.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-11-17 10:27:12 +08:00
};
#define ndev_pdev(ndev) ((ndev)->ntb.pdev)
#define ndev_name(ndev) pci_name(ndev_pdev(ndev))
#define ndev_dev(ndev) (&ndev_pdev(ndev)->dev)
#define ntb_ndev(ntb) container_of(ntb, struct intel_ntb_dev, ntb)
#define hb_ndev(work) container_of(work, struct intel_ntb_dev, hb_timer.work)
#endif