OpenCloudOS-Kernel/include/rdma/ib_verbs.h

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/*
* Copyright (c) 2004 Mellanox Technologies Ltd. All rights reserved.
* Copyright (c) 2004 Infinicon Corporation. All rights reserved.
* Copyright (c) 2004 Intel Corporation. All rights reserved.
* Copyright (c) 2004 Topspin Corporation. All rights reserved.
* Copyright (c) 2004 Voltaire Corporation. All rights reserved.
* Copyright (c) 2005 Sun Microsystems, Inc. All rights reserved.
IB/uverbs: Export ib_umem_get()/ib_umem_release() to modules Export ib_umem_get()/ib_umem_release() and put low-level drivers in control of when to call ib_umem_get() to pin and DMA map userspace, rather than always calling it in ib_uverbs_reg_mr() before calling the low-level driver's reg_user_mr method. Also move these functions to be in the ib_core module instead of ib_uverbs, so that driver modules using them do not depend on ib_uverbs. This has a number of advantages: - It is better design from the standpoint of making generic code a library that can be used or overridden by device-specific code as the details of specific devices dictate. - Drivers that do not need to pin userspace memory regions do not need to take the performance hit of calling ib_mem_get(). For example, although I have not tried to implement it in this patch, the ipath driver should be able to avoid pinning memory and just use copy_{to,from}_user() to access userspace memory regions. - Buffers that need special mapping treatment can be identified by the low-level driver. For example, it may be possible to solve some Altix-specific memory ordering issues with mthca CQs in userspace by mapping CQ buffers with extra flags. - Drivers that need to pin and DMA map userspace memory for things other than memory regions can use ib_umem_get() directly, instead of hacks using extra parameters to their reg_phys_mr method. For example, the mlx4 driver that is pending being merged needs to pin and DMA map QP and CQ buffers, but it does not need to create a memory key for these buffers. So the cleanest solution is for mlx4 to call ib_umem_get() in the create_qp and create_cq methods. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-03-05 08:15:11 +08:00
* Copyright (c) 2005, 2006, 2007 Cisco Systems. All rights reserved.
*
* This software is available to you under a choice of one of two
* licenses. You may choose to be licensed under the terms of the GNU
* General Public License (GPL) Version 2, available from the file
* COPYING in the main directory of this source tree, or the
* OpenIB.org BSD license below:
*
* 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
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials
* provided with the distribution.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#if !defined(IB_VERBS_H)
#define IB_VERBS_H
#include <linux/types.h>
#include <linux/device.h>
#include <linux/mm.h>
#include <linux/dma-mapping.h>
#include <linux/kref.h>
#include <linux/list.h>
#include <linux/rwsem.h>
#include <linux/scatterlist.h>
#include <linux/workqueue.h>
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
#include <uapi/linux/if_ether.h>
#include <linux/atomic.h>
IB/core: Implement support for MMU notifiers regarding on demand paging regions * Add an interval tree implementation for ODP umems. Create an interval tree for each ucontext (including a count of the number of ODP MRs in this context, semaphore, etc.), and register ODP umems in the interval tree. * Add MMU notifiers handling functions, using the interval tree to notify only the relevant umems and underlying MRs. * Register to receive MMU notifier events from the MM subsystem upon ODP MR registration (and unregister accordingly). * Add a completion object to synchronize the destruction of ODP umems. * Add mechanism to abort page faults when there's a concurrent invalidation. The way we synchronize between concurrent invalidations and page faults is by keeping a counter of currently running invalidations, and a sequence number that is incremented whenever an invalidation is caught. The page fault code checks the counter and also verifies that the sequence number hasn't progressed before it updates the umem's page tables. This is similar to what the kvm module does. In order to prevent the case where we register a umem in the middle of an ongoing notifier, we also keep a per ucontext counter of the total number of active mmu notifiers. We only enable new umems when all the running notifiers complete. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Shachar Raindel <raindel@mellanox.com> Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Yuval Dagan <yuvalda@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-12-11 23:04:18 +08:00
#include <linux/mmu_notifier.h>
#include <asm/uaccess.h>
extern struct workqueue_struct *ib_wq;
union ib_gid {
u8 raw[16];
struct {
__be64 subnet_prefix;
__be64 interface_id;
} global;
};
enum rdma_node_type {
/* IB values map to NodeInfo:NodeType. */
RDMA_NODE_IB_CA = 1,
RDMA_NODE_IB_SWITCH,
RDMA_NODE_IB_ROUTER,
RDMA_NODE_RNIC,
RDMA_NODE_USNIC,
RDMA_NODE_USNIC_UDP,
};
enum rdma_transport_type {
RDMA_TRANSPORT_IB,
RDMA_TRANSPORT_IWARP,
RDMA_TRANSPORT_USNIC,
RDMA_TRANSPORT_USNIC_UDP
};
enum rdma_protocol_type {
RDMA_PROTOCOL_IB,
RDMA_PROTOCOL_IBOE,
RDMA_PROTOCOL_IWARP,
RDMA_PROTOCOL_USNIC_UDP
};
__attribute_const__ enum rdma_transport_type
rdma_node_get_transport(enum rdma_node_type node_type);
enum rdma_link_layer {
IB_LINK_LAYER_UNSPECIFIED,
IB_LINK_LAYER_INFINIBAND,
IB_LINK_LAYER_ETHERNET,
};
enum ib_device_cap_flags {
IB_DEVICE_RESIZE_MAX_WR = 1,
IB_DEVICE_BAD_PKEY_CNTR = (1<<1),
IB_DEVICE_BAD_QKEY_CNTR = (1<<2),
IB_DEVICE_RAW_MULTI = (1<<3),
IB_DEVICE_AUTO_PATH_MIG = (1<<4),
IB_DEVICE_CHANGE_PHY_PORT = (1<<5),
IB_DEVICE_UD_AV_PORT_ENFORCE = (1<<6),
IB_DEVICE_CURR_QP_STATE_MOD = (1<<7),
IB_DEVICE_SHUTDOWN_PORT = (1<<8),
IB_DEVICE_INIT_TYPE = (1<<9),
IB_DEVICE_PORT_ACTIVE_EVENT = (1<<10),
IB_DEVICE_SYS_IMAGE_GUID = (1<<11),
IB_DEVICE_RC_RNR_NAK_GEN = (1<<12),
IB_DEVICE_SRQ_RESIZE = (1<<13),
IB_DEVICE_N_NOTIFY_CQ = (1<<14),
IB_DEVICE_LOCAL_DMA_LKEY = (1<<15),
2008-04-17 12:09:32 +08:00
IB_DEVICE_RESERVED = (1<<16), /* old SEND_W_INV */
IB_DEVICE_MEM_WINDOW = (1<<17),
/*
* Devices should set IB_DEVICE_UD_IP_SUM if they support
* insertion of UDP and TCP checksum on outgoing UD IPoIB
* messages and can verify the validity of checksum for
* incoming messages. Setting this flag implies that the
* IPoIB driver may set NETIF_F_IP_CSUM for datagram mode.
*/
IB_DEVICE_UD_IP_CSUM = (1<<18),
IB_DEVICE_UD_TSO = (1<<19),
IB_DEVICE_XRC = (1<<20),
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
IB_DEVICE_MEM_MGT_EXTENSIONS = (1<<21),
IB_DEVICE_BLOCK_MULTICAST_LOOPBACK = (1<<22),
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
IB_DEVICE_MEM_WINDOW_TYPE_2A = (1<<23),
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
IB_DEVICE_MEM_WINDOW_TYPE_2B = (1<<24),
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
IB_DEVICE_MANAGED_FLOW_STEERING = (1<<29),
IB_DEVICE_SIGNATURE_HANDOVER = (1<<30),
IB_DEVICE_ON_DEMAND_PAGING = (1<<31),
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
};
enum ib_signature_prot_cap {
IB_PROT_T10DIF_TYPE_1 = 1,
IB_PROT_T10DIF_TYPE_2 = 1 << 1,
IB_PROT_T10DIF_TYPE_3 = 1 << 2,
};
enum ib_signature_guard_cap {
IB_GUARD_T10DIF_CRC = 1,
IB_GUARD_T10DIF_CSUM = 1 << 1,
};
enum ib_atomic_cap {
IB_ATOMIC_NONE,
IB_ATOMIC_HCA,
IB_ATOMIC_GLOB
};
enum ib_odp_general_cap_bits {
IB_ODP_SUPPORT = 1 << 0,
};
enum ib_odp_transport_cap_bits {
IB_ODP_SUPPORT_SEND = 1 << 0,
IB_ODP_SUPPORT_RECV = 1 << 1,
IB_ODP_SUPPORT_WRITE = 1 << 2,
IB_ODP_SUPPORT_READ = 1 << 3,
IB_ODP_SUPPORT_ATOMIC = 1 << 4,
};
struct ib_odp_caps {
uint64_t general_caps;
struct {
uint32_t rc_odp_caps;
uint32_t uc_odp_caps;
uint32_t ud_odp_caps;
} per_transport_caps;
};
struct ib_device_attr {
u64 fw_ver;
__be64 sys_image_guid;
u64 max_mr_size;
u64 page_size_cap;
u32 vendor_id;
u32 vendor_part_id;
u32 hw_ver;
int max_qp;
int max_qp_wr;
int device_cap_flags;
int max_sge;
int max_sge_rd;
int max_cq;
int max_cqe;
int max_mr;
int max_pd;
int max_qp_rd_atom;
int max_ee_rd_atom;
int max_res_rd_atom;
int max_qp_init_rd_atom;
int max_ee_init_rd_atom;
enum ib_atomic_cap atomic_cap;
IB/core: Add support for masked atomic operations - Add new IB_WR_MASKED_ATOMIC_CMP_AND_SWP and IB_WR_MASKED_ATOMIC_FETCH_AND_ADD send opcodes that can be used to post "masked atomic compare and swap" and "masked atomic fetch and add" work request respectively. - Add masked_atomic_cap capability. - Add mask fields to atomic struct of ib_send_wr - Add new opcodes to ib_wc_opcode The new operations are described more precisely below: * Masked Compare and Swap (MskCmpSwap) The MskCmpSwap atomic operation is an extension to the CmpSwap operation defined in the IB spec. MskCmpSwap allows the user to select a portion of the 64 bit target data for the “compare” check as well as to restrict the swap to a (possibly different) portion. The pseudo code below describes the operation: | atomic_response = *va | if (!((compare_add ^ *va) & compare_add_mask)) then | *va = (*va & ~(swap_mask)) | (swap & swap_mask) | | return atomic_response The additional operands are carried in the Extended Transport Header. Atomic response generation and packet format for MskCmpSwap is as for standard IB Atomic operations. * Masked Fetch and Add (MFetchAdd) The MFetchAdd Atomic operation extends the functionality of the standard IB FetchAdd by allowing the user to split the target into multiple fields of selectable length. The atomic add is done independently on each one of this fields. A bit set in the field_boundary parameter specifies the field boundaries. The pseudo code below describes the operation: | bit_adder(ci, b1, b2, *co) | { | value = ci + b1 + b2 | *co = !!(value & 2) | | return value & 1 | } | | #define MASK_IS_SET(mask, attr) (!!((mask)&(attr))) | bit_position = 1 | carry = 0 | atomic_response = 0 | | for i = 0 to 63 | { | if ( i != 0 ) | bit_position = bit_position << 1 | | bit_add_res = bit_adder(carry, MASK_IS_SET(*va, bit_position), | MASK_IS_SET(compare_add, bit_position), &new_carry) | if (bit_add_res) | atomic_response |= bit_position | | carry = ((new_carry) && (!MASK_IS_SET(compare_add_mask, bit_position))) | } | | return atomic_response Signed-off-by: Vladimir Sokolovsky <vlad@mellanox.co.il> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2010-04-14 22:23:01 +08:00
enum ib_atomic_cap masked_atomic_cap;
int max_ee;
int max_rdd;
int max_mw;
int max_raw_ipv6_qp;
int max_raw_ethy_qp;
int max_mcast_grp;
int max_mcast_qp_attach;
int max_total_mcast_qp_attach;
int max_ah;
int max_fmr;
int max_map_per_fmr;
int max_srq;
int max_srq_wr;
int max_srq_sge;
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
unsigned int max_fast_reg_page_list_len;
u16 max_pkeys;
u8 local_ca_ack_delay;
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
int sig_prot_cap;
int sig_guard_cap;
struct ib_odp_caps odp_caps;
};
enum ib_mtu {
IB_MTU_256 = 1,
IB_MTU_512 = 2,
IB_MTU_1024 = 3,
IB_MTU_2048 = 4,
IB_MTU_4096 = 5
};
static inline int ib_mtu_enum_to_int(enum ib_mtu mtu)
{
switch (mtu) {
case IB_MTU_256: return 256;
case IB_MTU_512: return 512;
case IB_MTU_1024: return 1024;
case IB_MTU_2048: return 2048;
case IB_MTU_4096: return 4096;
default: return -1;
}
}
enum ib_port_state {
IB_PORT_NOP = 0,
IB_PORT_DOWN = 1,
IB_PORT_INIT = 2,
IB_PORT_ARMED = 3,
IB_PORT_ACTIVE = 4,
IB_PORT_ACTIVE_DEFER = 5
};
enum ib_port_cap_flags {
IB_PORT_SM = 1 << 1,
IB_PORT_NOTICE_SUP = 1 << 2,
IB_PORT_TRAP_SUP = 1 << 3,
IB_PORT_OPT_IPD_SUP = 1 << 4,
IB_PORT_AUTO_MIGR_SUP = 1 << 5,
IB_PORT_SL_MAP_SUP = 1 << 6,
IB_PORT_MKEY_NVRAM = 1 << 7,
IB_PORT_PKEY_NVRAM = 1 << 8,
IB_PORT_LED_INFO_SUP = 1 << 9,
IB_PORT_SM_DISABLED = 1 << 10,
IB_PORT_SYS_IMAGE_GUID_SUP = 1 << 11,
IB_PORT_PKEY_SW_EXT_PORT_TRAP_SUP = 1 << 12,
IB_PORT_EXTENDED_SPEEDS_SUP = 1 << 14,
IB_PORT_CM_SUP = 1 << 16,
IB_PORT_SNMP_TUNNEL_SUP = 1 << 17,
IB_PORT_REINIT_SUP = 1 << 18,
IB_PORT_DEVICE_MGMT_SUP = 1 << 19,
IB_PORT_VENDOR_CLASS_SUP = 1 << 20,
IB_PORT_DR_NOTICE_SUP = 1 << 21,
IB_PORT_CAP_MASK_NOTICE_SUP = 1 << 22,
IB_PORT_BOOT_MGMT_SUP = 1 << 23,
IB_PORT_LINK_LATENCY_SUP = 1 << 24,
IB_PORT_CLIENT_REG_SUP = 1 << 25,
IB_PORT_IP_BASED_GIDS = 1 << 26
};
enum ib_port_width {
IB_WIDTH_1X = 1,
IB_WIDTH_4X = 2,
IB_WIDTH_8X = 4,
IB_WIDTH_12X = 8
};
static inline int ib_width_enum_to_int(enum ib_port_width width)
{
switch (width) {
case IB_WIDTH_1X: return 1;
case IB_WIDTH_4X: return 4;
case IB_WIDTH_8X: return 8;
case IB_WIDTH_12X: return 12;
default: return -1;
}
}
enum ib_port_speed {
IB_SPEED_SDR = 1,
IB_SPEED_DDR = 2,
IB_SPEED_QDR = 4,
IB_SPEED_FDR10 = 8,
IB_SPEED_FDR = 16,
IB_SPEED_EDR = 32
};
struct ib_protocol_stats {
/* TBD... */
};
struct iw_protocol_stats {
u64 ipInReceives;
u64 ipInHdrErrors;
u64 ipInTooBigErrors;
u64 ipInNoRoutes;
u64 ipInAddrErrors;
u64 ipInUnknownProtos;
u64 ipInTruncatedPkts;
u64 ipInDiscards;
u64 ipInDelivers;
u64 ipOutForwDatagrams;
u64 ipOutRequests;
u64 ipOutDiscards;
u64 ipOutNoRoutes;
u64 ipReasmTimeout;
u64 ipReasmReqds;
u64 ipReasmOKs;
u64 ipReasmFails;
u64 ipFragOKs;
u64 ipFragFails;
u64 ipFragCreates;
u64 ipInMcastPkts;
u64 ipOutMcastPkts;
u64 ipInBcastPkts;
u64 ipOutBcastPkts;
u64 tcpRtoAlgorithm;
u64 tcpRtoMin;
u64 tcpRtoMax;
u64 tcpMaxConn;
u64 tcpActiveOpens;
u64 tcpPassiveOpens;
u64 tcpAttemptFails;
u64 tcpEstabResets;
u64 tcpCurrEstab;
u64 tcpInSegs;
u64 tcpOutSegs;
u64 tcpRetransSegs;
u64 tcpInErrs;
u64 tcpOutRsts;
};
union rdma_protocol_stats {
struct ib_protocol_stats ib;
struct iw_protocol_stats iw;
};
/* Define bits for the various functionality this port needs to be supported by
* the core.
*/
/* Management 0x00000FFF */
#define RDMA_CORE_CAP_IB_MAD 0x00000001
#define RDMA_CORE_CAP_IB_SMI 0x00000002
#define RDMA_CORE_CAP_IB_CM 0x00000004
#define RDMA_CORE_CAP_IW_CM 0x00000008
#define RDMA_CORE_CAP_IB_SA 0x00000010
/* Address format 0x000FF000 */
#define RDMA_CORE_CAP_AF_IB 0x00001000
#define RDMA_CORE_CAP_ETH_AH 0x00002000
/* Protocol 0xFFF00000 */
#define RDMA_CORE_CAP_PROT_IB 0x00100000
#define RDMA_CORE_CAP_PROT_ROCE 0x00200000
#define RDMA_CORE_CAP_PROT_IWARP 0x00400000
#define RDMA_CORE_PORT_IBA_IB (RDMA_CORE_CAP_PROT_IB \
| RDMA_CORE_CAP_IB_MAD \
| RDMA_CORE_CAP_IB_SMI \
| RDMA_CORE_CAP_IB_CM \
| RDMA_CORE_CAP_IB_SA \
| RDMA_CORE_CAP_AF_IB)
#define RDMA_CORE_PORT_IBA_ROCE (RDMA_CORE_CAP_PROT_ROCE \
| RDMA_CORE_CAP_IB_MAD \
| RDMA_CORE_CAP_IB_CM \
| RDMA_CORE_CAP_IB_SA \
| RDMA_CORE_CAP_AF_IB \
| RDMA_CORE_CAP_ETH_AH)
#define RDMA_CORE_PORT_IWARP (RDMA_CORE_CAP_PROT_IWARP \
| RDMA_CORE_CAP_IW_CM)
struct ib_port_attr {
enum ib_port_state state;
enum ib_mtu max_mtu;
enum ib_mtu active_mtu;
int gid_tbl_len;
u32 port_cap_flags;
u32 max_msg_sz;
u32 bad_pkey_cntr;
u32 qkey_viol_cntr;
u16 pkey_tbl_len;
u16 lid;
u16 sm_lid;
u8 lmc;
u8 max_vl_num;
u8 sm_sl;
u8 subnet_timeout;
u8 init_type_reply;
u8 active_width;
u8 active_speed;
u8 phys_state;
};
enum ib_device_modify_flags {
IB_DEVICE_MODIFY_SYS_IMAGE_GUID = 1 << 0,
IB_DEVICE_MODIFY_NODE_DESC = 1 << 1
};
struct ib_device_modify {
u64 sys_image_guid;
char node_desc[64];
};
enum ib_port_modify_flags {
IB_PORT_SHUTDOWN = 1,
IB_PORT_INIT_TYPE = (1<<2),
IB_PORT_RESET_QKEY_CNTR = (1<<3)
};
struct ib_port_modify {
u32 set_port_cap_mask;
u32 clr_port_cap_mask;
u8 init_type;
};
enum ib_event_type {
IB_EVENT_CQ_ERR,
IB_EVENT_QP_FATAL,
IB_EVENT_QP_REQ_ERR,
IB_EVENT_QP_ACCESS_ERR,
IB_EVENT_COMM_EST,
IB_EVENT_SQ_DRAINED,
IB_EVENT_PATH_MIG,
IB_EVENT_PATH_MIG_ERR,
IB_EVENT_DEVICE_FATAL,
IB_EVENT_PORT_ACTIVE,
IB_EVENT_PORT_ERR,
IB_EVENT_LID_CHANGE,
IB_EVENT_PKEY_CHANGE,
IB_EVENT_SM_CHANGE,
IB_EVENT_SRQ_ERR,
IB_EVENT_SRQ_LIMIT_REACHED,
IB_EVENT_QP_LAST_WQE_REACHED,
IB_EVENT_CLIENT_REREGISTER,
IB_EVENT_GID_CHANGE,
};
__attribute_const__ const char *ib_event_msg(enum ib_event_type event);
struct ib_event {
struct ib_device *device;
union {
struct ib_cq *cq;
struct ib_qp *qp;
struct ib_srq *srq;
u8 port_num;
} element;
enum ib_event_type event;
};
struct ib_event_handler {
struct ib_device *device;
void (*handler)(struct ib_event_handler *, struct ib_event *);
struct list_head list;
};
#define INIT_IB_EVENT_HANDLER(_ptr, _device, _handler) \
do { \
(_ptr)->device = _device; \
(_ptr)->handler = _handler; \
INIT_LIST_HEAD(&(_ptr)->list); \
} while (0)
struct ib_global_route {
union ib_gid dgid;
u32 flow_label;
u8 sgid_index;
u8 hop_limit;
u8 traffic_class;
};
struct ib_grh {
__be32 version_tclass_flow;
__be16 paylen;
u8 next_hdr;
u8 hop_limit;
union ib_gid sgid;
union ib_gid dgid;
};
enum {
IB_MULTICAST_QPN = 0xffffff
};
#define IB_LID_PERMISSIVE cpu_to_be16(0xFFFF)
enum ib_ah_flags {
IB_AH_GRH = 1
};
enum ib_rate {
IB_RATE_PORT_CURRENT = 0,
IB_RATE_2_5_GBPS = 2,
IB_RATE_5_GBPS = 5,
IB_RATE_10_GBPS = 3,
IB_RATE_20_GBPS = 6,
IB_RATE_30_GBPS = 4,
IB_RATE_40_GBPS = 7,
IB_RATE_60_GBPS = 8,
IB_RATE_80_GBPS = 9,
IB_RATE_120_GBPS = 10,
IB_RATE_14_GBPS = 11,
IB_RATE_56_GBPS = 12,
IB_RATE_112_GBPS = 13,
IB_RATE_168_GBPS = 14,
IB_RATE_25_GBPS = 15,
IB_RATE_100_GBPS = 16,
IB_RATE_200_GBPS = 17,
IB_RATE_300_GBPS = 18
};
/**
* ib_rate_to_mult - Convert the IB rate enum to a multiple of the
* base rate of 2.5 Gbit/sec. For example, IB_RATE_5_GBPS will be
* converted to 2, since 5 Gbit/sec is 2 * 2.5 Gbit/sec.
* @rate: rate to convert.
*/
__attribute_const__ int ib_rate_to_mult(enum ib_rate rate);
/**
* ib_rate_to_mbps - Convert the IB rate enum to Mbps.
* For example, IB_RATE_2_5_GBPS will be converted to 2500.
* @rate: rate to convert.
*/
__attribute_const__ int ib_rate_to_mbps(enum ib_rate rate);
enum ib_mr_create_flags {
IB_MR_SIGNATURE_EN = 1,
};
/**
* ib_mr_init_attr - Memory region init attributes passed to routine
* ib_create_mr.
* @max_reg_descriptors: max number of registration descriptors that
* may be used with registration work requests.
* @flags: MR creation flags bit mask.
*/
struct ib_mr_init_attr {
int max_reg_descriptors;
u32 flags;
};
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
/**
* Signature types
* IB_SIG_TYPE_NONE: Unprotected.
* IB_SIG_TYPE_T10_DIF: Type T10-DIF
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
*/
enum ib_signature_type {
IB_SIG_TYPE_NONE,
IB_SIG_TYPE_T10_DIF,
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
};
/**
* Signature T10-DIF block-guard types
* IB_T10DIF_CRC: Corresponds to T10-PI mandated CRC checksum rules.
* IB_T10DIF_CSUM: Corresponds to IP checksum rules.
*/
enum ib_t10_dif_bg_type {
IB_T10DIF_CRC,
IB_T10DIF_CSUM
};
/**
* struct ib_t10_dif_domain - Parameters specific for T10-DIF
* domain.
* @bg_type: T10-DIF block guard type (CRC|CSUM)
* @pi_interval: protection information interval.
* @bg: seed of guard computation.
* @app_tag: application tag of guard block
* @ref_tag: initial guard block reference tag.
* @ref_remap: Indicate wethear the reftag increments each block
* @app_escape: Indicate to skip block check if apptag=0xffff
* @ref_escape: Indicate to skip block check if reftag=0xffffffff
* @apptag_check_mask: check bitmask of application tag.
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
*/
struct ib_t10_dif_domain {
enum ib_t10_dif_bg_type bg_type;
u16 pi_interval;
u16 bg;
u16 app_tag;
u32 ref_tag;
bool ref_remap;
bool app_escape;
bool ref_escape;
u16 apptag_check_mask;
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
};
/**
* struct ib_sig_domain - Parameters for signature domain
* @sig_type: specific signauture type
* @sig: union of all signature domain attributes that may
* be used to set domain layout.
*/
struct ib_sig_domain {
enum ib_signature_type sig_type;
union {
struct ib_t10_dif_domain dif;
} sig;
};
/**
* struct ib_sig_attrs - Parameters for signature handover operation
* @check_mask: bitmask for signature byte check (8 bytes)
* @mem: memory domain layout desciptor.
* @wire: wire domain layout desciptor.
*/
struct ib_sig_attrs {
u8 check_mask;
struct ib_sig_domain mem;
struct ib_sig_domain wire;
};
enum ib_sig_err_type {
IB_SIG_BAD_GUARD,
IB_SIG_BAD_REFTAG,
IB_SIG_BAD_APPTAG,
};
/**
* struct ib_sig_err - signature error descriptor
*/
struct ib_sig_err {
enum ib_sig_err_type err_type;
u32 expected;
u32 actual;
u64 sig_err_offset;
u32 key;
};
enum ib_mr_status_check {
IB_MR_CHECK_SIG_STATUS = 1,
};
/**
* struct ib_mr_status - Memory region status container
*
* @fail_status: Bitmask of MR checks status. For each
* failed check a corresponding status bit is set.
* @sig_err: Additional info for IB_MR_CEHCK_SIG_STATUS
* failure.
*/
struct ib_mr_status {
u32 fail_status;
struct ib_sig_err sig_err;
};
/**
* mult_to_ib_rate - Convert a multiple of 2.5 Gbit/sec to an IB rate
* enum.
* @mult: multiple to convert.
*/
__attribute_const__ enum ib_rate mult_to_ib_rate(int mult);
struct ib_ah_attr {
struct ib_global_route grh;
u16 dlid;
u8 sl;
u8 src_path_bits;
u8 static_rate;
u8 ah_flags;
u8 port_num;
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
u8 dmac[ETH_ALEN];
u16 vlan_id;
};
enum ib_wc_status {
IB_WC_SUCCESS,
IB_WC_LOC_LEN_ERR,
IB_WC_LOC_QP_OP_ERR,
IB_WC_LOC_EEC_OP_ERR,
IB_WC_LOC_PROT_ERR,
IB_WC_WR_FLUSH_ERR,
IB_WC_MW_BIND_ERR,
IB_WC_BAD_RESP_ERR,
IB_WC_LOC_ACCESS_ERR,
IB_WC_REM_INV_REQ_ERR,
IB_WC_REM_ACCESS_ERR,
IB_WC_REM_OP_ERR,
IB_WC_RETRY_EXC_ERR,
IB_WC_RNR_RETRY_EXC_ERR,
IB_WC_LOC_RDD_VIOL_ERR,
IB_WC_REM_INV_RD_REQ_ERR,
IB_WC_REM_ABORT_ERR,
IB_WC_INV_EECN_ERR,
IB_WC_INV_EEC_STATE_ERR,
IB_WC_FATAL_ERR,
IB_WC_RESP_TIMEOUT_ERR,
IB_WC_GENERAL_ERR
};
__attribute_const__ const char *ib_wc_status_msg(enum ib_wc_status status);
enum ib_wc_opcode {
IB_WC_SEND,
IB_WC_RDMA_WRITE,
IB_WC_RDMA_READ,
IB_WC_COMP_SWAP,
IB_WC_FETCH_ADD,
IB_WC_BIND_MW,
IB_WC_LSO,
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
IB_WC_LOCAL_INV,
IB_WC_FAST_REG_MR,
IB/core: Add support for masked atomic operations - Add new IB_WR_MASKED_ATOMIC_CMP_AND_SWP and IB_WR_MASKED_ATOMIC_FETCH_AND_ADD send opcodes that can be used to post "masked atomic compare and swap" and "masked atomic fetch and add" work request respectively. - Add masked_atomic_cap capability. - Add mask fields to atomic struct of ib_send_wr - Add new opcodes to ib_wc_opcode The new operations are described more precisely below: * Masked Compare and Swap (MskCmpSwap) The MskCmpSwap atomic operation is an extension to the CmpSwap operation defined in the IB spec. MskCmpSwap allows the user to select a portion of the 64 bit target data for the “compare” check as well as to restrict the swap to a (possibly different) portion. The pseudo code below describes the operation: | atomic_response = *va | if (!((compare_add ^ *va) & compare_add_mask)) then | *va = (*va & ~(swap_mask)) | (swap & swap_mask) | | return atomic_response The additional operands are carried in the Extended Transport Header. Atomic response generation and packet format for MskCmpSwap is as for standard IB Atomic operations. * Masked Fetch and Add (MFetchAdd) The MFetchAdd Atomic operation extends the functionality of the standard IB FetchAdd by allowing the user to split the target into multiple fields of selectable length. The atomic add is done independently on each one of this fields. A bit set in the field_boundary parameter specifies the field boundaries. The pseudo code below describes the operation: | bit_adder(ci, b1, b2, *co) | { | value = ci + b1 + b2 | *co = !!(value & 2) | | return value & 1 | } | | #define MASK_IS_SET(mask, attr) (!!((mask)&(attr))) | bit_position = 1 | carry = 0 | atomic_response = 0 | | for i = 0 to 63 | { | if ( i != 0 ) | bit_position = bit_position << 1 | | bit_add_res = bit_adder(carry, MASK_IS_SET(*va, bit_position), | MASK_IS_SET(compare_add, bit_position), &new_carry) | if (bit_add_res) | atomic_response |= bit_position | | carry = ((new_carry) && (!MASK_IS_SET(compare_add_mask, bit_position))) | } | | return atomic_response Signed-off-by: Vladimir Sokolovsky <vlad@mellanox.co.il> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2010-04-14 22:23:01 +08:00
IB_WC_MASKED_COMP_SWAP,
IB_WC_MASKED_FETCH_ADD,
/*
* Set value of IB_WC_RECV so consumers can test if a completion is a
* receive by testing (opcode & IB_WC_RECV).
*/
IB_WC_RECV = 1 << 7,
IB_WC_RECV_RDMA_WITH_IMM
};
enum ib_wc_flags {
IB_WC_GRH = 1,
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
IB_WC_WITH_IMM = (1<<1),
IB_WC_WITH_INVALIDATE = (1<<2),
IB_WC_IP_CSUM_OK = (1<<3),
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
IB_WC_WITH_SMAC = (1<<4),
IB_WC_WITH_VLAN = (1<<5),
};
struct ib_wc {
u64 wr_id;
enum ib_wc_status status;
enum ib_wc_opcode opcode;
u32 vendor_err;
u32 byte_len;
struct ib_qp *qp;
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
union {
__be32 imm_data;
u32 invalidate_rkey;
} ex;
u32 src_qp;
int wc_flags;
u16 pkey_index;
u16 slid;
u8 sl;
u8 dlid_path_bits;
u8 port_num; /* valid only for DR SMPs on switches */
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
u8 smac[ETH_ALEN];
u16 vlan_id;
};
IB: Return "maybe missed event" hint from ib_req_notify_cq() The semantics defined by the InfiniBand specification say that completion events are only generated when a completions is added to a completion queue (CQ) after completion notification is requested. In other words, this means that the following race is possible: while (CQ is not empty) ib_poll_cq(CQ); // new completion is added after while loop is exited ib_req_notify_cq(CQ); // no event is generated for the existing completion To close this race, the IB spec recommends doing another poll of the CQ after requesting notification. However, it is not always possible to arrange code this way (for example, we have found that NAPI for IPoIB cannot poll after requesting notification). Also, some hardware (eg Mellanox HCAs) actually will generate an event for completions added before the call to ib_req_notify_cq() -- which is allowed by the spec, since there's no way for any upper-layer consumer to know exactly when a completion was really added -- so the extra poll of the CQ is just a waste. Motivated by this, we add a new flag "IB_CQ_REPORT_MISSED_EVENTS" for ib_req_notify_cq() so that it can return a hint about whether the a completion may have been added before the request for notification. The return value of ib_req_notify_cq() is extended so: < 0 means an error occurred while requesting notification == 0 means notification was requested successfully, and if IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events were missed and it is safe to wait for another event. > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed in. It means that the consumer must poll the CQ again to make sure it is empty to avoid the race described above. We add a flag to enable this behavior rather than turning it on unconditionally, because checking for missed events may incur significant overhead for some low-level drivers, and consumers that don't care about the results of this test shouldn't be forced to pay for the test. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-05-07 12:02:48 +08:00
enum ib_cq_notify_flags {
IB_CQ_SOLICITED = 1 << 0,
IB_CQ_NEXT_COMP = 1 << 1,
IB_CQ_SOLICITED_MASK = IB_CQ_SOLICITED | IB_CQ_NEXT_COMP,
IB_CQ_REPORT_MISSED_EVENTS = 1 << 2,
};
enum ib_srq_type {
IB_SRQT_BASIC,
IB_SRQT_XRC
};
enum ib_srq_attr_mask {
IB_SRQ_MAX_WR = 1 << 0,
IB_SRQ_LIMIT = 1 << 1,
};
struct ib_srq_attr {
u32 max_wr;
u32 max_sge;
u32 srq_limit;
};
struct ib_srq_init_attr {
void (*event_handler)(struct ib_event *, void *);
void *srq_context;
struct ib_srq_attr attr;
enum ib_srq_type srq_type;
union {
struct {
struct ib_xrcd *xrcd;
struct ib_cq *cq;
} xrc;
} ext;
};
struct ib_qp_cap {
u32 max_send_wr;
u32 max_recv_wr;
u32 max_send_sge;
u32 max_recv_sge;
u32 max_inline_data;
};
enum ib_sig_type {
IB_SIGNAL_ALL_WR,
IB_SIGNAL_REQ_WR
};
enum ib_qp_type {
/*
* IB_QPT_SMI and IB_QPT_GSI have to be the first two entries
* here (and in that order) since the MAD layer uses them as
* indices into a 2-entry table.
*/
IB_QPT_SMI,
IB_QPT_GSI,
IB_QPT_RC,
IB_QPT_UC,
IB_QPT_UD,
IB_QPT_RAW_IPV6,
IB_QPT_RAW_ETHERTYPE,
IB_QPT_RAW_PACKET = 8,
IB_QPT_XRC_INI = 9,
IB_QPT_XRC_TGT,
IB_QPT_MAX,
/* Reserve a range for qp types internal to the low level driver.
* These qp types will not be visible at the IB core layer, so the
* IB_QPT_MAX usages should not be affected in the core layer
*/
IB_QPT_RESERVED1 = 0x1000,
IB_QPT_RESERVED2,
IB_QPT_RESERVED3,
IB_QPT_RESERVED4,
IB_QPT_RESERVED5,
IB_QPT_RESERVED6,
IB_QPT_RESERVED7,
IB_QPT_RESERVED8,
IB_QPT_RESERVED9,
IB_QPT_RESERVED10,
};
enum ib_qp_create_flags {
IB_QP_CREATE_IPOIB_UD_LSO = 1 << 0,
IB_QP_CREATE_BLOCK_MULTICAST_LOOPBACK = 1 << 1,
IB_QP_CREATE_NETIF_QP = 1 << 5,
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
IB_QP_CREATE_SIGNATURE_EN = 1 << 6,
IB_QP_CREATE_USE_GFP_NOIO = 1 << 7,
/* reserve bits 26-31 for low level drivers' internal use */
IB_QP_CREATE_RESERVED_START = 1 << 26,
IB_QP_CREATE_RESERVED_END = 1 << 31,
};
/*
* Note: users may not call ib_close_qp or ib_destroy_qp from the event_handler
* callback to destroy the passed in QP.
*/
struct ib_qp_init_attr {
void (*event_handler)(struct ib_event *, void *);
void *qp_context;
struct ib_cq *send_cq;
struct ib_cq *recv_cq;
struct ib_srq *srq;
struct ib_xrcd *xrcd; /* XRC TGT QPs only */
struct ib_qp_cap cap;
enum ib_sig_type sq_sig_type;
enum ib_qp_type qp_type;
enum ib_qp_create_flags create_flags;
u8 port_num; /* special QP types only */
};
struct ib_qp_open_attr {
void (*event_handler)(struct ib_event *, void *);
void *qp_context;
u32 qp_num;
enum ib_qp_type qp_type;
};
enum ib_rnr_timeout {
IB_RNR_TIMER_655_36 = 0,
IB_RNR_TIMER_000_01 = 1,
IB_RNR_TIMER_000_02 = 2,
IB_RNR_TIMER_000_03 = 3,
IB_RNR_TIMER_000_04 = 4,
IB_RNR_TIMER_000_06 = 5,
IB_RNR_TIMER_000_08 = 6,
IB_RNR_TIMER_000_12 = 7,
IB_RNR_TIMER_000_16 = 8,
IB_RNR_TIMER_000_24 = 9,
IB_RNR_TIMER_000_32 = 10,
IB_RNR_TIMER_000_48 = 11,
IB_RNR_TIMER_000_64 = 12,
IB_RNR_TIMER_000_96 = 13,
IB_RNR_TIMER_001_28 = 14,
IB_RNR_TIMER_001_92 = 15,
IB_RNR_TIMER_002_56 = 16,
IB_RNR_TIMER_003_84 = 17,
IB_RNR_TIMER_005_12 = 18,
IB_RNR_TIMER_007_68 = 19,
IB_RNR_TIMER_010_24 = 20,
IB_RNR_TIMER_015_36 = 21,
IB_RNR_TIMER_020_48 = 22,
IB_RNR_TIMER_030_72 = 23,
IB_RNR_TIMER_040_96 = 24,
IB_RNR_TIMER_061_44 = 25,
IB_RNR_TIMER_081_92 = 26,
IB_RNR_TIMER_122_88 = 27,
IB_RNR_TIMER_163_84 = 28,
IB_RNR_TIMER_245_76 = 29,
IB_RNR_TIMER_327_68 = 30,
IB_RNR_TIMER_491_52 = 31
};
enum ib_qp_attr_mask {
IB_QP_STATE = 1,
IB_QP_CUR_STATE = (1<<1),
IB_QP_EN_SQD_ASYNC_NOTIFY = (1<<2),
IB_QP_ACCESS_FLAGS = (1<<3),
IB_QP_PKEY_INDEX = (1<<4),
IB_QP_PORT = (1<<5),
IB_QP_QKEY = (1<<6),
IB_QP_AV = (1<<7),
IB_QP_PATH_MTU = (1<<8),
IB_QP_TIMEOUT = (1<<9),
IB_QP_RETRY_CNT = (1<<10),
IB_QP_RNR_RETRY = (1<<11),
IB_QP_RQ_PSN = (1<<12),
IB_QP_MAX_QP_RD_ATOMIC = (1<<13),
IB_QP_ALT_PATH = (1<<14),
IB_QP_MIN_RNR_TIMER = (1<<15),
IB_QP_SQ_PSN = (1<<16),
IB_QP_MAX_DEST_RD_ATOMIC = (1<<17),
IB_QP_PATH_MIG_STATE = (1<<18),
IB_QP_CAP = (1<<19),
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
IB_QP_DEST_QPN = (1<<20),
IB_QP_SMAC = (1<<21),
IB_QP_ALT_SMAC = (1<<22),
IB_QP_VID = (1<<23),
IB_QP_ALT_VID = (1<<24),
};
enum ib_qp_state {
IB_QPS_RESET,
IB_QPS_INIT,
IB_QPS_RTR,
IB_QPS_RTS,
IB_QPS_SQD,
IB_QPS_SQE,
IB_QPS_ERR
};
enum ib_mig_state {
IB_MIG_MIGRATED,
IB_MIG_REARM,
IB_MIG_ARMED
};
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
enum ib_mw_type {
IB_MW_TYPE_1 = 1,
IB_MW_TYPE_2 = 2
};
struct ib_qp_attr {
enum ib_qp_state qp_state;
enum ib_qp_state cur_qp_state;
enum ib_mtu path_mtu;
enum ib_mig_state path_mig_state;
u32 qkey;
u32 rq_psn;
u32 sq_psn;
u32 dest_qp_num;
int qp_access_flags;
struct ib_qp_cap cap;
struct ib_ah_attr ah_attr;
struct ib_ah_attr alt_ah_attr;
u16 pkey_index;
u16 alt_pkey_index;
u8 en_sqd_async_notify;
u8 sq_draining;
u8 max_rd_atomic;
u8 max_dest_rd_atomic;
u8 min_rnr_timer;
u8 port_num;
u8 timeout;
u8 retry_cnt;
u8 rnr_retry;
u8 alt_port_num;
u8 alt_timeout;
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
u8 smac[ETH_ALEN];
u8 alt_smac[ETH_ALEN];
u16 vlan_id;
u16 alt_vlan_id;
};
enum ib_wr_opcode {
IB_WR_RDMA_WRITE,
IB_WR_RDMA_WRITE_WITH_IMM,
IB_WR_SEND,
IB_WR_SEND_WITH_IMM,
IB_WR_RDMA_READ,
IB_WR_ATOMIC_CMP_AND_SWP,
IB_WR_ATOMIC_FETCH_AND_ADD,
2008-04-17 12:09:32 +08:00
IB_WR_LSO,
IB_WR_SEND_WITH_INV,
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
IB_WR_RDMA_READ_WITH_INV,
IB_WR_LOCAL_INV,
IB_WR_FAST_REG_MR,
IB/core: Add support for masked atomic operations - Add new IB_WR_MASKED_ATOMIC_CMP_AND_SWP and IB_WR_MASKED_ATOMIC_FETCH_AND_ADD send opcodes that can be used to post "masked atomic compare and swap" and "masked atomic fetch and add" work request respectively. - Add masked_atomic_cap capability. - Add mask fields to atomic struct of ib_send_wr - Add new opcodes to ib_wc_opcode The new operations are described more precisely below: * Masked Compare and Swap (MskCmpSwap) The MskCmpSwap atomic operation is an extension to the CmpSwap operation defined in the IB spec. MskCmpSwap allows the user to select a portion of the 64 bit target data for the “compare” check as well as to restrict the swap to a (possibly different) portion. The pseudo code below describes the operation: | atomic_response = *va | if (!((compare_add ^ *va) & compare_add_mask)) then | *va = (*va & ~(swap_mask)) | (swap & swap_mask) | | return atomic_response The additional operands are carried in the Extended Transport Header. Atomic response generation and packet format for MskCmpSwap is as for standard IB Atomic operations. * Masked Fetch and Add (MFetchAdd) The MFetchAdd Atomic operation extends the functionality of the standard IB FetchAdd by allowing the user to split the target into multiple fields of selectable length. The atomic add is done independently on each one of this fields. A bit set in the field_boundary parameter specifies the field boundaries. The pseudo code below describes the operation: | bit_adder(ci, b1, b2, *co) | { | value = ci + b1 + b2 | *co = !!(value & 2) | | return value & 1 | } | | #define MASK_IS_SET(mask, attr) (!!((mask)&(attr))) | bit_position = 1 | carry = 0 | atomic_response = 0 | | for i = 0 to 63 | { | if ( i != 0 ) | bit_position = bit_position << 1 | | bit_add_res = bit_adder(carry, MASK_IS_SET(*va, bit_position), | MASK_IS_SET(compare_add, bit_position), &new_carry) | if (bit_add_res) | atomic_response |= bit_position | | carry = ((new_carry) && (!MASK_IS_SET(compare_add_mask, bit_position))) | } | | return atomic_response Signed-off-by: Vladimir Sokolovsky <vlad@mellanox.co.il> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2010-04-14 22:23:01 +08:00
IB_WR_MASKED_ATOMIC_CMP_AND_SWP,
IB_WR_MASKED_ATOMIC_FETCH_AND_ADD,
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
IB_WR_BIND_MW,
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
IB_WR_REG_SIG_MR,
/* reserve values for low level drivers' internal use.
* These values will not be used at all in the ib core layer.
*/
IB_WR_RESERVED1 = 0xf0,
IB_WR_RESERVED2,
IB_WR_RESERVED3,
IB_WR_RESERVED4,
IB_WR_RESERVED5,
IB_WR_RESERVED6,
IB_WR_RESERVED7,
IB_WR_RESERVED8,
IB_WR_RESERVED9,
IB_WR_RESERVED10,
};
enum ib_send_flags {
IB_SEND_FENCE = 1,
IB_SEND_SIGNALED = (1<<1),
IB_SEND_SOLICITED = (1<<2),
IB_SEND_INLINE = (1<<3),
IB_SEND_IP_CSUM = (1<<4),
/* reserve bits 26-31 for low level drivers' internal use */
IB_SEND_RESERVED_START = (1 << 26),
IB_SEND_RESERVED_END = (1 << 31),
};
struct ib_sge {
u64 addr;
u32 length;
u32 lkey;
};
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
struct ib_fast_reg_page_list {
struct ib_device *device;
u64 *page_list;
unsigned int max_page_list_len;
};
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
/**
* struct ib_mw_bind_info - Parameters for a memory window bind operation.
* @mr: A memory region to bind the memory window to.
* @addr: The address where the memory window should begin.
* @length: The length of the memory window, in bytes.
* @mw_access_flags: Access flags from enum ib_access_flags for the window.
*
* This struct contains the shared parameters for type 1 and type 2
* memory window bind operations.
*/
struct ib_mw_bind_info {
struct ib_mr *mr;
u64 addr;
u64 length;
int mw_access_flags;
};
struct ib_send_wr {
struct ib_send_wr *next;
u64 wr_id;
struct ib_sge *sg_list;
int num_sge;
enum ib_wr_opcode opcode;
int send_flags;
2008-04-17 12:09:32 +08:00
union {
__be32 imm_data;
u32 invalidate_rkey;
} ex;
union {
struct {
u64 remote_addr;
u32 rkey;
} rdma;
struct {
u64 remote_addr;
u64 compare_add;
u64 swap;
IB/core: Add support for masked atomic operations - Add new IB_WR_MASKED_ATOMIC_CMP_AND_SWP and IB_WR_MASKED_ATOMIC_FETCH_AND_ADD send opcodes that can be used to post "masked atomic compare and swap" and "masked atomic fetch and add" work request respectively. - Add masked_atomic_cap capability. - Add mask fields to atomic struct of ib_send_wr - Add new opcodes to ib_wc_opcode The new operations are described more precisely below: * Masked Compare and Swap (MskCmpSwap) The MskCmpSwap atomic operation is an extension to the CmpSwap operation defined in the IB spec. MskCmpSwap allows the user to select a portion of the 64 bit target data for the “compare” check as well as to restrict the swap to a (possibly different) portion. The pseudo code below describes the operation: | atomic_response = *va | if (!((compare_add ^ *va) & compare_add_mask)) then | *va = (*va & ~(swap_mask)) | (swap & swap_mask) | | return atomic_response The additional operands are carried in the Extended Transport Header. Atomic response generation and packet format for MskCmpSwap is as for standard IB Atomic operations. * Masked Fetch and Add (MFetchAdd) The MFetchAdd Atomic operation extends the functionality of the standard IB FetchAdd by allowing the user to split the target into multiple fields of selectable length. The atomic add is done independently on each one of this fields. A bit set in the field_boundary parameter specifies the field boundaries. The pseudo code below describes the operation: | bit_adder(ci, b1, b2, *co) | { | value = ci + b1 + b2 | *co = !!(value & 2) | | return value & 1 | } | | #define MASK_IS_SET(mask, attr) (!!((mask)&(attr))) | bit_position = 1 | carry = 0 | atomic_response = 0 | | for i = 0 to 63 | { | if ( i != 0 ) | bit_position = bit_position << 1 | | bit_add_res = bit_adder(carry, MASK_IS_SET(*va, bit_position), | MASK_IS_SET(compare_add, bit_position), &new_carry) | if (bit_add_res) | atomic_response |= bit_position | | carry = ((new_carry) && (!MASK_IS_SET(compare_add_mask, bit_position))) | } | | return atomic_response Signed-off-by: Vladimir Sokolovsky <vlad@mellanox.co.il> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2010-04-14 22:23:01 +08:00
u64 compare_add_mask;
u64 swap_mask;
u32 rkey;
} atomic;
struct {
struct ib_ah *ah;
void *header;
int hlen;
int mss;
u32 remote_qpn;
u32 remote_qkey;
u16 pkey_index; /* valid for GSI only */
u8 port_num; /* valid for DR SMPs on switch only */
} ud;
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
struct {
u64 iova_start;
struct ib_fast_reg_page_list *page_list;
unsigned int page_shift;
unsigned int page_list_len;
u32 length;
int access_flags;
u32 rkey;
} fast_reg;
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
struct {
struct ib_mw *mw;
/* The new rkey for the memory window. */
u32 rkey;
struct ib_mw_bind_info bind_info;
} bind_mw;
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
struct {
struct ib_sig_attrs *sig_attrs;
struct ib_mr *sig_mr;
int access_flags;
struct ib_sge *prot;
} sig_handover;
} wr;
u32 xrc_remote_srq_num; /* XRC TGT QPs only */
};
struct ib_recv_wr {
struct ib_recv_wr *next;
u64 wr_id;
struct ib_sge *sg_list;
int num_sge;
};
enum ib_access_flags {
IB_ACCESS_LOCAL_WRITE = 1,
IB_ACCESS_REMOTE_WRITE = (1<<1),
IB_ACCESS_REMOTE_READ = (1<<2),
IB_ACCESS_REMOTE_ATOMIC = (1<<3),
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
IB_ACCESS_MW_BIND = (1<<4),
IB_ZERO_BASED = (1<<5),
IB_ACCESS_ON_DEMAND = (1<<6),
};
struct ib_phys_buf {
u64 addr;
u64 size;
};
struct ib_mr_attr {
struct ib_pd *pd;
u64 device_virt_addr;
u64 size;
int mr_access_flags;
u32 lkey;
u32 rkey;
};
enum ib_mr_rereg_flags {
IB_MR_REREG_TRANS = 1,
IB_MR_REREG_PD = (1<<1),
IB_MR_REREG_ACCESS = (1<<2),
IB_MR_REREG_SUPPORTED = ((IB_MR_REREG_ACCESS << 1) - 1)
};
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
/**
* struct ib_mw_bind - Parameters for a type 1 memory window bind operation.
* @wr_id: Work request id.
* @send_flags: Flags from ib_send_flags enum.
* @bind_info: More parameters of the bind operation.
*/
struct ib_mw_bind {
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
u64 wr_id;
int send_flags;
struct ib_mw_bind_info bind_info;
};
struct ib_fmr_attr {
int max_pages;
int max_maps;
u8 page_shift;
};
IB/core: Implement support for MMU notifiers regarding on demand paging regions * Add an interval tree implementation for ODP umems. Create an interval tree for each ucontext (including a count of the number of ODP MRs in this context, semaphore, etc.), and register ODP umems in the interval tree. * Add MMU notifiers handling functions, using the interval tree to notify only the relevant umems and underlying MRs. * Register to receive MMU notifier events from the MM subsystem upon ODP MR registration (and unregister accordingly). * Add a completion object to synchronize the destruction of ODP umems. * Add mechanism to abort page faults when there's a concurrent invalidation. The way we synchronize between concurrent invalidations and page faults is by keeping a counter of currently running invalidations, and a sequence number that is incremented whenever an invalidation is caught. The page fault code checks the counter and also verifies that the sequence number hasn't progressed before it updates the umem's page tables. This is similar to what the kvm module does. In order to prevent the case where we register a umem in the middle of an ongoing notifier, we also keep a per ucontext counter of the total number of active mmu notifiers. We only enable new umems when all the running notifiers complete. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Shachar Raindel <raindel@mellanox.com> Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Yuval Dagan <yuvalda@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-12-11 23:04:18 +08:00
struct ib_umem;
struct ib_ucontext {
struct ib_device *device;
struct list_head pd_list;
struct list_head mr_list;
struct list_head mw_list;
struct list_head cq_list;
struct list_head qp_list;
struct list_head srq_list;
struct list_head ah_list;
struct list_head xrcd_list;
struct list_head rule_list;
IB/uverbs: Export ib_umem_get()/ib_umem_release() to modules Export ib_umem_get()/ib_umem_release() and put low-level drivers in control of when to call ib_umem_get() to pin and DMA map userspace, rather than always calling it in ib_uverbs_reg_mr() before calling the low-level driver's reg_user_mr method. Also move these functions to be in the ib_core module instead of ib_uverbs, so that driver modules using them do not depend on ib_uverbs. This has a number of advantages: - It is better design from the standpoint of making generic code a library that can be used or overridden by device-specific code as the details of specific devices dictate. - Drivers that do not need to pin userspace memory regions do not need to take the performance hit of calling ib_mem_get(). For example, although I have not tried to implement it in this patch, the ipath driver should be able to avoid pinning memory and just use copy_{to,from}_user() to access userspace memory regions. - Buffers that need special mapping treatment can be identified by the low-level driver. For example, it may be possible to solve some Altix-specific memory ordering issues with mthca CQs in userspace by mapping CQ buffers with extra flags. - Drivers that need to pin and DMA map userspace memory for things other than memory regions can use ib_umem_get() directly, instead of hacks using extra parameters to their reg_phys_mr method. For example, the mlx4 driver that is pending being merged needs to pin and DMA map QP and CQ buffers, but it does not need to create a memory key for these buffers. So the cleanest solution is for mlx4 to call ib_umem_get() in the create_qp and create_cq methods. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-03-05 08:15:11 +08:00
int closing;
struct pid *tgid;
IB/core: Implement support for MMU notifiers regarding on demand paging regions * Add an interval tree implementation for ODP umems. Create an interval tree for each ucontext (including a count of the number of ODP MRs in this context, semaphore, etc.), and register ODP umems in the interval tree. * Add MMU notifiers handling functions, using the interval tree to notify only the relevant umems and underlying MRs. * Register to receive MMU notifier events from the MM subsystem upon ODP MR registration (and unregister accordingly). * Add a completion object to synchronize the destruction of ODP umems. * Add mechanism to abort page faults when there's a concurrent invalidation. The way we synchronize between concurrent invalidations and page faults is by keeping a counter of currently running invalidations, and a sequence number that is incremented whenever an invalidation is caught. The page fault code checks the counter and also verifies that the sequence number hasn't progressed before it updates the umem's page tables. This is similar to what the kvm module does. In order to prevent the case where we register a umem in the middle of an ongoing notifier, we also keep a per ucontext counter of the total number of active mmu notifiers. We only enable new umems when all the running notifiers complete. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Shachar Raindel <raindel@mellanox.com> Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Yuval Dagan <yuvalda@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-12-11 23:04:18 +08:00
#ifdef CONFIG_INFINIBAND_ON_DEMAND_PAGING
struct rb_root umem_tree;
/*
* Protects .umem_rbroot and tree, as well as odp_mrs_count and
* mmu notifiers registration.
*/
struct rw_semaphore umem_rwsem;
void (*invalidate_range)(struct ib_umem *umem,
unsigned long start, unsigned long end);
struct mmu_notifier mn;
atomic_t notifier_count;
/* A list of umems that don't have private mmu notifier counters yet. */
struct list_head no_private_counters;
int odp_mrs_count;
#endif
};
struct ib_uobject {
u64 user_handle; /* handle given to us by userspace */
struct ib_ucontext *context; /* associated user context */
void *object; /* containing object */
struct list_head list; /* link to context's list */
int id; /* index into kernel idr */
struct kref ref;
struct rw_semaphore mutex; /* protects .live */
int live;
};
struct ib_udata {
const void __user *inbuf;
void __user *outbuf;
size_t inlen;
size_t outlen;
};
struct ib_pd {
struct ib_device *device;
struct ib_uobject *uobject;
atomic_t usecnt; /* count all resources */
};
struct ib_xrcd {
struct ib_device *device;
atomic_t usecnt; /* count all exposed resources */
struct inode *inode;
struct mutex tgt_qp_mutex;
struct list_head tgt_qp_list;
};
struct ib_ah {
struct ib_device *device;
struct ib_pd *pd;
struct ib_uobject *uobject;
};
typedef void (*ib_comp_handler)(struct ib_cq *cq, void *cq_context);
struct ib_cq {
struct ib_device *device;
struct ib_uobject *uobject;
ib_comp_handler comp_handler;
void (*event_handler)(struct ib_event *, void *);
void *cq_context;
int cqe;
atomic_t usecnt; /* count number of work queues */
};
struct ib_srq {
struct ib_device *device;
struct ib_pd *pd;
struct ib_uobject *uobject;
void (*event_handler)(struct ib_event *, void *);
void *srq_context;
enum ib_srq_type srq_type;
atomic_t usecnt;
union {
struct {
struct ib_xrcd *xrcd;
struct ib_cq *cq;
u32 srq_num;
} xrc;
} ext;
};
struct ib_qp {
struct ib_device *device;
struct ib_pd *pd;
struct ib_cq *send_cq;
struct ib_cq *recv_cq;
struct ib_srq *srq;
struct ib_xrcd *xrcd; /* XRC TGT QPs only */
struct list_head xrcd_list;
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
/* count times opened, mcast attaches, flow attaches */
atomic_t usecnt;
struct list_head open_list;
struct ib_qp *real_qp;
struct ib_uobject *uobject;
void (*event_handler)(struct ib_event *, void *);
void *qp_context;
u32 qp_num;
enum ib_qp_type qp_type;
};
struct ib_mr {
struct ib_device *device;
struct ib_pd *pd;
struct ib_uobject *uobject;
u32 lkey;
u32 rkey;
atomic_t usecnt; /* count number of MWs */
};
struct ib_mw {
struct ib_device *device;
struct ib_pd *pd;
struct ib_uobject *uobject;
u32 rkey;
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
enum ib_mw_type type;
};
struct ib_fmr {
struct ib_device *device;
struct ib_pd *pd;
struct list_head list;
u32 lkey;
u32 rkey;
};
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
/* Supported steering options */
enum ib_flow_attr_type {
/* steering according to rule specifications */
IB_FLOW_ATTR_NORMAL = 0x0,
/* default unicast and multicast rule -
* receive all Eth traffic which isn't steered to any QP
*/
IB_FLOW_ATTR_ALL_DEFAULT = 0x1,
/* default multicast rule -
* receive all Eth multicast traffic which isn't steered to any QP
*/
IB_FLOW_ATTR_MC_DEFAULT = 0x2,
/* sniffer rule - receive all port traffic */
IB_FLOW_ATTR_SNIFFER = 0x3
};
/* Supported steering header types */
enum ib_flow_spec_type {
/* L2 headers*/
IB_FLOW_SPEC_ETH = 0x20,
IB_FLOW_SPEC_IB = 0x22,
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
/* L3 header*/
IB_FLOW_SPEC_IPV4 = 0x30,
/* L4 headers*/
IB_FLOW_SPEC_TCP = 0x40,
IB_FLOW_SPEC_UDP = 0x41
};
#define IB_FLOW_SPEC_LAYER_MASK 0xF0
#define IB_FLOW_SPEC_SUPPORT_LAYERS 4
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
/* Flow steering rule priority is set according to it's domain.
* Lower domain value means higher priority.
*/
enum ib_flow_domain {
IB_FLOW_DOMAIN_USER,
IB_FLOW_DOMAIN_ETHTOOL,
IB_FLOW_DOMAIN_RFS,
IB_FLOW_DOMAIN_NIC,
IB_FLOW_DOMAIN_NUM /* Must be last */
};
struct ib_flow_eth_filter {
u8 dst_mac[6];
u8 src_mac[6];
__be16 ether_type;
__be16 vlan_tag;
};
struct ib_flow_spec_eth {
enum ib_flow_spec_type type;
u16 size;
struct ib_flow_eth_filter val;
struct ib_flow_eth_filter mask;
};
struct ib_flow_ib_filter {
__be16 dlid;
__u8 sl;
};
struct ib_flow_spec_ib {
enum ib_flow_spec_type type;
u16 size;
struct ib_flow_ib_filter val;
struct ib_flow_ib_filter mask;
};
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
struct ib_flow_ipv4_filter {
__be32 src_ip;
__be32 dst_ip;
};
struct ib_flow_spec_ipv4 {
enum ib_flow_spec_type type;
u16 size;
struct ib_flow_ipv4_filter val;
struct ib_flow_ipv4_filter mask;
};
struct ib_flow_tcp_udp_filter {
__be16 dst_port;
__be16 src_port;
};
struct ib_flow_spec_tcp_udp {
enum ib_flow_spec_type type;
u16 size;
struct ib_flow_tcp_udp_filter val;
struct ib_flow_tcp_udp_filter mask;
};
union ib_flow_spec {
struct {
enum ib_flow_spec_type type;
u16 size;
};
struct ib_flow_spec_eth eth;
struct ib_flow_spec_ib ib;
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
struct ib_flow_spec_ipv4 ipv4;
struct ib_flow_spec_tcp_udp tcp_udp;
};
struct ib_flow_attr {
enum ib_flow_attr_type type;
u16 size;
u16 priority;
u32 flags;
u8 num_of_specs;
u8 port;
/* Following are the optional layers according to user request
* struct ib_flow_spec_xxx
* struct ib_flow_spec_yyy
*/
};
struct ib_flow {
struct ib_qp *qp;
struct ib_uobject *uobject;
};
struct ib_mad;
struct ib_grh;
enum ib_process_mad_flags {
IB_MAD_IGNORE_MKEY = 1,
IB_MAD_IGNORE_BKEY = 2,
IB_MAD_IGNORE_ALL = IB_MAD_IGNORE_MKEY | IB_MAD_IGNORE_BKEY
};
enum ib_mad_result {
IB_MAD_RESULT_FAILURE = 0, /* (!SUCCESS is the important flag) */
IB_MAD_RESULT_SUCCESS = 1 << 0, /* MAD was successfully processed */
IB_MAD_RESULT_REPLY = 1 << 1, /* Reply packet needs to be sent */
IB_MAD_RESULT_CONSUMED = 1 << 2 /* Packet consumed: stop processing */
};
#define IB_DEVICE_NAME_MAX 64
struct ib_cache {
rwlock_t lock;
struct ib_event_handler event_handler;
struct ib_pkey_cache **pkey_cache;
struct ib_gid_cache **gid_cache;
u8 *lmc_cache;
};
struct ib_dma_mapping_ops {
int (*mapping_error)(struct ib_device *dev,
u64 dma_addr);
u64 (*map_single)(struct ib_device *dev,
void *ptr, size_t size,
enum dma_data_direction direction);
void (*unmap_single)(struct ib_device *dev,
u64 addr, size_t size,
enum dma_data_direction direction);
u64 (*map_page)(struct ib_device *dev,
struct page *page, unsigned long offset,
size_t size,
enum dma_data_direction direction);
void (*unmap_page)(struct ib_device *dev,
u64 addr, size_t size,
enum dma_data_direction direction);
int (*map_sg)(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction);
void (*unmap_sg)(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction);
void (*sync_single_for_cpu)(struct ib_device *dev,
u64 dma_handle,
size_t size,
enum dma_data_direction dir);
void (*sync_single_for_device)(struct ib_device *dev,
u64 dma_handle,
size_t size,
enum dma_data_direction dir);
void *(*alloc_coherent)(struct ib_device *dev,
size_t size,
u64 *dma_handle,
gfp_t flag);
void (*free_coherent)(struct ib_device *dev,
size_t size, void *cpu_addr,
u64 dma_handle);
};
struct iw_cm_verbs;
struct ib_port_immutable {
int pkey_tbl_len;
int gid_tbl_len;
u32 core_cap_flags;
};
struct ib_device {
struct device *dma_device;
char name[IB_DEVICE_NAME_MAX];
struct list_head event_handler_list;
spinlock_t event_handler_lock;
spinlock_t client_data_lock;
struct list_head core_list;
struct list_head client_data_list;
struct ib_cache cache;
/**
* port_immutable is indexed by port number
*/
struct ib_port_immutable *port_immutable;
int num_comp_vectors;
struct iw_cm_verbs *iwcm;
int (*get_protocol_stats)(struct ib_device *device,
union rdma_protocol_stats *stats);
int (*query_device)(struct ib_device *device,
struct ib_device_attr *device_attr);
int (*query_port)(struct ib_device *device,
u8 port_num,
struct ib_port_attr *port_attr);
enum rdma_link_layer (*get_link_layer)(struct ib_device *device,
u8 port_num);
int (*query_gid)(struct ib_device *device,
u8 port_num, int index,
union ib_gid *gid);
int (*query_pkey)(struct ib_device *device,
u8 port_num, u16 index, u16 *pkey);
int (*modify_device)(struct ib_device *device,
int device_modify_mask,
struct ib_device_modify *device_modify);
int (*modify_port)(struct ib_device *device,
u8 port_num, int port_modify_mask,
struct ib_port_modify *port_modify);
struct ib_ucontext * (*alloc_ucontext)(struct ib_device *device,
struct ib_udata *udata);
int (*dealloc_ucontext)(struct ib_ucontext *context);
int (*mmap)(struct ib_ucontext *context,
struct vm_area_struct *vma);
struct ib_pd * (*alloc_pd)(struct ib_device *device,
struct ib_ucontext *context,
struct ib_udata *udata);
int (*dealloc_pd)(struct ib_pd *pd);
struct ib_ah * (*create_ah)(struct ib_pd *pd,
struct ib_ah_attr *ah_attr);
int (*modify_ah)(struct ib_ah *ah,
struct ib_ah_attr *ah_attr);
int (*query_ah)(struct ib_ah *ah,
struct ib_ah_attr *ah_attr);
int (*destroy_ah)(struct ib_ah *ah);
struct ib_srq * (*create_srq)(struct ib_pd *pd,
struct ib_srq_init_attr *srq_init_attr,
struct ib_udata *udata);
int (*modify_srq)(struct ib_srq *srq,
struct ib_srq_attr *srq_attr,
enum ib_srq_attr_mask srq_attr_mask,
struct ib_udata *udata);
int (*query_srq)(struct ib_srq *srq,
struct ib_srq_attr *srq_attr);
int (*destroy_srq)(struct ib_srq *srq);
int (*post_srq_recv)(struct ib_srq *srq,
struct ib_recv_wr *recv_wr,
struct ib_recv_wr **bad_recv_wr);
struct ib_qp * (*create_qp)(struct ib_pd *pd,
struct ib_qp_init_attr *qp_init_attr,
struct ib_udata *udata);
int (*modify_qp)(struct ib_qp *qp,
struct ib_qp_attr *qp_attr,
int qp_attr_mask,
struct ib_udata *udata);
int (*query_qp)(struct ib_qp *qp,
struct ib_qp_attr *qp_attr,
int qp_attr_mask,
struct ib_qp_init_attr *qp_init_attr);
int (*destroy_qp)(struct ib_qp *qp);
int (*post_send)(struct ib_qp *qp,
struct ib_send_wr *send_wr,
struct ib_send_wr **bad_send_wr);
int (*post_recv)(struct ib_qp *qp,
struct ib_recv_wr *recv_wr,
struct ib_recv_wr **bad_recv_wr);
struct ib_cq * (*create_cq)(struct ib_device *device, int cqe,
int comp_vector,
struct ib_ucontext *context,
struct ib_udata *udata);
int (*modify_cq)(struct ib_cq *cq, u16 cq_count,
u16 cq_period);
int (*destroy_cq)(struct ib_cq *cq);
int (*resize_cq)(struct ib_cq *cq, int cqe,
struct ib_udata *udata);
int (*poll_cq)(struct ib_cq *cq, int num_entries,
struct ib_wc *wc);
int (*peek_cq)(struct ib_cq *cq, int wc_cnt);
int (*req_notify_cq)(struct ib_cq *cq,
IB: Return "maybe missed event" hint from ib_req_notify_cq() The semantics defined by the InfiniBand specification say that completion events are only generated when a completions is added to a completion queue (CQ) after completion notification is requested. In other words, this means that the following race is possible: while (CQ is not empty) ib_poll_cq(CQ); // new completion is added after while loop is exited ib_req_notify_cq(CQ); // no event is generated for the existing completion To close this race, the IB spec recommends doing another poll of the CQ after requesting notification. However, it is not always possible to arrange code this way (for example, we have found that NAPI for IPoIB cannot poll after requesting notification). Also, some hardware (eg Mellanox HCAs) actually will generate an event for completions added before the call to ib_req_notify_cq() -- which is allowed by the spec, since there's no way for any upper-layer consumer to know exactly when a completion was really added -- so the extra poll of the CQ is just a waste. Motivated by this, we add a new flag "IB_CQ_REPORT_MISSED_EVENTS" for ib_req_notify_cq() so that it can return a hint about whether the a completion may have been added before the request for notification. The return value of ib_req_notify_cq() is extended so: < 0 means an error occurred while requesting notification == 0 means notification was requested successfully, and if IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events were missed and it is safe to wait for another event. > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed in. It means that the consumer must poll the CQ again to make sure it is empty to avoid the race described above. We add a flag to enable this behavior rather than turning it on unconditionally, because checking for missed events may incur significant overhead for some low-level drivers, and consumers that don't care about the results of this test shouldn't be forced to pay for the test. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-05-07 12:02:48 +08:00
enum ib_cq_notify_flags flags);
int (*req_ncomp_notif)(struct ib_cq *cq,
int wc_cnt);
struct ib_mr * (*get_dma_mr)(struct ib_pd *pd,
int mr_access_flags);
struct ib_mr * (*reg_phys_mr)(struct ib_pd *pd,
struct ib_phys_buf *phys_buf_array,
int num_phys_buf,
int mr_access_flags,
u64 *iova_start);
struct ib_mr * (*reg_user_mr)(struct ib_pd *pd,
IB/uverbs: Export ib_umem_get()/ib_umem_release() to modules Export ib_umem_get()/ib_umem_release() and put low-level drivers in control of when to call ib_umem_get() to pin and DMA map userspace, rather than always calling it in ib_uverbs_reg_mr() before calling the low-level driver's reg_user_mr method. Also move these functions to be in the ib_core module instead of ib_uverbs, so that driver modules using them do not depend on ib_uverbs. This has a number of advantages: - It is better design from the standpoint of making generic code a library that can be used or overridden by device-specific code as the details of specific devices dictate. - Drivers that do not need to pin userspace memory regions do not need to take the performance hit of calling ib_mem_get(). For example, although I have not tried to implement it in this patch, the ipath driver should be able to avoid pinning memory and just use copy_{to,from}_user() to access userspace memory regions. - Buffers that need special mapping treatment can be identified by the low-level driver. For example, it may be possible to solve some Altix-specific memory ordering issues with mthca CQs in userspace by mapping CQ buffers with extra flags. - Drivers that need to pin and DMA map userspace memory for things other than memory regions can use ib_umem_get() directly, instead of hacks using extra parameters to their reg_phys_mr method. For example, the mlx4 driver that is pending being merged needs to pin and DMA map QP and CQ buffers, but it does not need to create a memory key for these buffers. So the cleanest solution is for mlx4 to call ib_umem_get() in the create_qp and create_cq methods. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-03-05 08:15:11 +08:00
u64 start, u64 length,
u64 virt_addr,
int mr_access_flags,
struct ib_udata *udata);
int (*rereg_user_mr)(struct ib_mr *mr,
int flags,
u64 start, u64 length,
u64 virt_addr,
int mr_access_flags,
struct ib_pd *pd,
struct ib_udata *udata);
int (*query_mr)(struct ib_mr *mr,
struct ib_mr_attr *mr_attr);
int (*dereg_mr)(struct ib_mr *mr);
int (*destroy_mr)(struct ib_mr *mr);
struct ib_mr * (*create_mr)(struct ib_pd *pd,
struct ib_mr_init_attr *mr_init_attr);
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
struct ib_mr * (*alloc_fast_reg_mr)(struct ib_pd *pd,
int max_page_list_len);
struct ib_fast_reg_page_list * (*alloc_fast_reg_page_list)(struct ib_device *device,
int page_list_len);
void (*free_fast_reg_page_list)(struct ib_fast_reg_page_list *page_list);
int (*rereg_phys_mr)(struct ib_mr *mr,
int mr_rereg_mask,
struct ib_pd *pd,
struct ib_phys_buf *phys_buf_array,
int num_phys_buf,
int mr_access_flags,
u64 *iova_start);
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
struct ib_mw * (*alloc_mw)(struct ib_pd *pd,
enum ib_mw_type type);
int (*bind_mw)(struct ib_qp *qp,
struct ib_mw *mw,
struct ib_mw_bind *mw_bind);
int (*dealloc_mw)(struct ib_mw *mw);
struct ib_fmr * (*alloc_fmr)(struct ib_pd *pd,
int mr_access_flags,
struct ib_fmr_attr *fmr_attr);
int (*map_phys_fmr)(struct ib_fmr *fmr,
u64 *page_list, int list_len,
u64 iova);
int (*unmap_fmr)(struct list_head *fmr_list);
int (*dealloc_fmr)(struct ib_fmr *fmr);
int (*attach_mcast)(struct ib_qp *qp,
union ib_gid *gid,
u16 lid);
int (*detach_mcast)(struct ib_qp *qp,
union ib_gid *gid,
u16 lid);
int (*process_mad)(struct ib_device *device,
int process_mad_flags,
u8 port_num,
const struct ib_wc *in_wc,
const struct ib_grh *in_grh,
const struct ib_mad *in_mad,
struct ib_mad *out_mad);
struct ib_xrcd * (*alloc_xrcd)(struct ib_device *device,
struct ib_ucontext *ucontext,
struct ib_udata *udata);
int (*dealloc_xrcd)(struct ib_xrcd *xrcd);
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
struct ib_flow * (*create_flow)(struct ib_qp *qp,
struct ib_flow_attr
*flow_attr,
int domain);
int (*destroy_flow)(struct ib_flow *flow_id);
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
int (*check_mr_status)(struct ib_mr *mr, u32 check_mask,
struct ib_mr_status *mr_status);
struct ib_dma_mapping_ops *dma_ops;
struct module *owner;
struct device dev;
struct kobject *ports_parent;
struct list_head port_list;
enum {
IB_DEV_UNINITIALIZED,
IB_DEV_REGISTERED,
IB_DEV_UNREGISTERED
} reg_state;
int uverbs_abi_ver;
u64 uverbs_cmd_mask;
IB/core: extended command: an improved infrastructure for uverbs commands Commit 400dbc96583f ("IB/core: Infrastructure for extensible uverbs commands") added an infrastructure for extensible uverbs commands while later commit 436f2ad05a0b ("IB/core: Export ib_create/destroy_flow through uverbs") exported ib_create_flow()/ib_destroy_flow() functions using this new infrastructure. According to the commit 400dbc96583f, the purpose of this infrastructure is to support passing around provider (eg. hardware) specific buffers when userspace issue commands to the kernel, so that it would be possible to extend uverbs (eg. core) buffers independently from the provider buffers. But the new kernel command function prototypes were not modified to take advantage of this extension. This issue was exposed by Roland Dreier in a previous review[1]. So the following patch is an attempt to a revised extensible command infrastructure. This improved extensible command infrastructure distinguish between core (eg. legacy)'s command/response buffers from provider (eg. hardware)'s command/response buffers: each extended command implementing function is given a struct ib_udata to hold core (eg. uverbs) input and output buffers, and another struct ib_udata to hold the hw (eg. provider) input and output buffers. Having those buffers identified separately make it easier to increase one buffer to support extension without having to add some code to guess the exact size of each command/response parts: This should make the extended functions more reliable. Additionally, instead of relying on command identifier being greater than IB_USER_VERBS_CMD_THRESHOLD, the proposed infrastructure rely on unused bits in command field: on the 32 bits provided by command field, only 6 bits are really needed to encode the identifier of commands currently supported by the kernel. (Even using only 6 bits leaves room for about 23 new commands). So this patch makes use of some high order bits in command field to store flags, leaving enough room for more command identifiers than one will ever need (eg. 256). The new flags are used to specify if the command should be processed as an extended one or a legacy one. While designing the new command format, care was taken to make usage of flags itself extensible. Using high order bits of the commands field ensure that newer libibverbs on older kernel will properly fail when trying to call extended commands. On the other hand, older libibverbs on newer kernel will never be able to issue calls to extended commands. The extended command header includes the optional response pointer so that output buffer length and output buffer pointer are located together in the command, allowing proper parameters checking. This should make implementing functions easier and safer. Additionally the extended header ensure 64bits alignment, while making all sizes multiple of 8 bytes, extending the maximum buffer size: legacy extended Maximum command buffer: 256KBytes 1024KBytes (512KBytes + 512KBytes) Maximum response buffer: 256KBytes 1024KBytes (512KBytes + 512KBytes) For the purpose of doing proper buffer size accounting, the headers size are no more taken in account in "in_words". One of the odds of the current extensible infrastructure, reading twice the "legacy" command header, is fixed by removing the "legacy" command header from the extended command header: they are processed as two different parts of the command: memory is read once and information are not duplicated: it's making clear that's an extended command scheme and not a different command scheme. The proposed scheme will format input (command) and output (response) buffers this way: - command: legacy header + extended header + command data (core + hw): +----------------------------------------+ | flags | 00 00 | command | | in_words | out_words | +----------------------------------------+ | response | | response | | provider_in_words | provider_out_words | | padding | +----------------------------------------+ | | . <uverbs input> . . (in_words * 8) . | | +----------------------------------------+ | | . <provider input> . . (provider_in_words * 8) . | | +----------------------------------------+ - response, if present: +----------------------------------------+ | | . <uverbs output space> . . (out_words * 8) . | | +----------------------------------------+ | | . <provider output space> . . (provider_out_words * 8) . | | +----------------------------------------+ The overall design is to ensure that the extensible infrastructure is itself extensible while begin more reliable with more input and bound checking. Note: The unused field in the extended header would be perfect candidate to hold the command "comp_mask" (eg. bit field used to handle compatibility). This was suggested by Roland Dreier in a previous review[2]. But "comp_mask" field is likely to be present in the uverb input and/or provider input, likewise for the response, as noted by Matan Barak[3], so it doesn't make sense to put "comp_mask" in the header. [1]: http://marc.info/?i=CAL1RGDWxmM17W2o_era24A-TTDeKyoL6u3NRu_=t_dhV_ZA9MA@mail.gmail.com [2]: http://marc.info/?i=CAL1RGDXJtrc849M6_XNZT5xO1+ybKtLWGq6yg6LhoSsKpsmkYA@mail.gmail.com [3]: http://marc.info/?i=525C1149.6000701@mellanox.com Signed-off-by: Yann Droneaud <ydroneaud@opteya.com> Link: http://marc.info/?i=cover.1383773832.git.ydroneaud@opteya.com [ Convert "ret ? ret : 0" to the equivalent "ret". - Roland ] Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-11-07 06:21:49 +08:00
u64 uverbs_ex_cmd_mask;
char node_desc[64];
__be64 node_guid;
u32 local_dma_lkey;
u8 node_type;
u8 phys_port_cnt;
/**
* The following mandatory functions are used only at device
* registration. Keep functions such as these at the end of this
* structure to avoid cache line misses when accessing struct ib_device
* in fast paths.
*/
int (*get_port_immutable)(struct ib_device *, u8, struct ib_port_immutable *);
};
struct ib_client {
char *name;
void (*add) (struct ib_device *);
void (*remove)(struct ib_device *);
struct list_head list;
};
struct ib_device *ib_alloc_device(size_t size);
void ib_dealloc_device(struct ib_device *device);
int ib_register_device(struct ib_device *device,
int (*port_callback)(struct ib_device *,
u8, struct kobject *));
void ib_unregister_device(struct ib_device *device);
int ib_register_client (struct ib_client *client);
void ib_unregister_client(struct ib_client *client);
void *ib_get_client_data(struct ib_device *device, struct ib_client *client);
void ib_set_client_data(struct ib_device *device, struct ib_client *client,
void *data);
static inline int ib_copy_from_udata(void *dest, struct ib_udata *udata, size_t len)
{
return copy_from_user(dest, udata->inbuf, len) ? -EFAULT : 0;
}
static inline int ib_copy_to_udata(struct ib_udata *udata, void *src, size_t len)
{
Revert "IB/core: Add support for extended query device caps" While commit 7e36ef8205ff ("IB/core: Temporarily disable ex_query_device uverb") is correct as it makes the extended QUERY_DEVICE uverb (which came as part of commit 5a77abf9a97a ("IB/core: Add support for extended query device caps") and commit 860f10a799c8 ("IB/core: Add flags for on demand paging support")) not available to userspace, it doesn't address the initial issue regarding ib_copy_to_udata() [1][2]. Additionally, further discussions around this new uverb seems to conclude it would require a different data structure than the one currently described in <rdma/ib_user_verbs.h> [3]. Both of these issues require a revert of the changes, so this patch partially reverts commit 8cdd312cfed7 ("IB/mlx5: Implement the ODP capability query verb") and commit 860f10a799c8 ("IB/core: Add flags for on demand paging support") and fully reverts commit 5a77abf9a97a ("IB/core: Add support for extended query device caps"). [1] "Re: [PATCH v3 06/17] IB/core: Add support for extended query device caps" http://mid.gmane.org/1418733236.2779.26.camel@opteya.com [2] "Re: [PATCH] IB/core: Temporarily disable ex_query_device uverb" http://mid.gmane.org/1423067503.3030.83.camel@opteya.com [3] "RE: [PATCH v1 1/5] IB/uverbs: ex_query_device: answer must not depend on request's comp_mask" http://mid.gmane.org/2807E5FD2F6FDA4886F6618EAC48510E0CC12C30@CRSMSX101.amr.corp.intel.com Cc: Eli Cohen <eli@mellanox.com> Cc: Haggai Eran <haggaie@mellanox.com> Cc: Ira Weiny <ira.weiny@intel.com> Cc: Jason Gunthorpe <jgunthorpe@obsidianresearch.com> Cc: Sagi Grimberg <sagig@mellanox.com> Cc: Shachar Raindel <raindel@mellanox.com> Signed-off-by: Yann Droneaud <ydroneaud@opteya.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2015-02-06 05:10:18 +08:00
return copy_to_user(udata->outbuf, src, len) ? -EFAULT : 0;
}
/**
* ib_modify_qp_is_ok - Check that the supplied attribute mask
* contains all required attributes and no attributes not allowed for
* the given QP state transition.
* @cur_state: Current QP state
* @next_state: Next QP state
* @type: QP type
* @mask: Mask of supplied QP attributes
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
* @ll : link layer of port
*
* This function is a helper function that a low-level driver's
* modify_qp method can use to validate the consumer's input. It
* checks that cur_state and next_state are valid QP states, that a
* transition from cur_state to next_state is allowed by the IB spec,
* and that the attribute mask supplied is allowed for the transition.
*/
int ib_modify_qp_is_ok(enum ib_qp_state cur_state, enum ib_qp_state next_state,
IB/core: Ethernet L2 attributes in verbs/cm structures This patch add the support for Ethernet L2 attributes in the verbs/cm/cma structures. When dealing with L2 Ethernet, we should use smac, dmac, vlan ID and priority in a similar manner that the IB L2 (and the L4 PKEY) attributes are used. Thus, those attributes were added to the following structures: * ib_ah_attr - added dmac * ib_qp_attr - added smac and vlan_id, (sl remains vlan priority) * ib_wc - added smac, vlan_id * ib_sa_path_rec - added smac, dmac, vlan_id * cm_av - added smac and vlan_id For the path record structure, extra care was taken to avoid the new fields when packing it into wire format, so we don't break the IB CM and SA wire protocol. On the active side, the CM fills. its internal structures from the path provided by the ULP. We add there taking the ETH L2 attributes and placing them into the CM Address Handle (struct cm_av). On the passive side, the CM fills its internal structures from the WC associated with the REQ message. We add there taking the ETH L2 attributes from the WC. When the HW driver provides the required ETH L2 attributes in the WC, they set the IB_WC_WITH_SMAC and IB_WC_WITH_VLAN flags. The IB core code checks for the presence of these flags, and in their absence does address resolution from the ib_init_ah_from_wc() helper function. ib_modify_qp_is_ok is also updated to consider the link layer. Some parameters are mandatory for Ethernet link layer, while they are irrelevant for IB. Vendor drivers are modified to support the new function signature. Signed-off-by: Matan Barak <matanb@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-12-13 00:03:11 +08:00
enum ib_qp_type type, enum ib_qp_attr_mask mask,
enum rdma_link_layer ll);
int ib_register_event_handler (struct ib_event_handler *event_handler);
int ib_unregister_event_handler(struct ib_event_handler *event_handler);
void ib_dispatch_event(struct ib_event *event);
int ib_query_device(struct ib_device *device,
struct ib_device_attr *device_attr);
int ib_query_port(struct ib_device *device,
u8 port_num, struct ib_port_attr *port_attr);
enum rdma_link_layer rdma_port_get_link_layer(struct ib_device *device,
u8 port_num);
/**
* rdma_start_port - Return the first valid port number for the device
* specified
*
* @device: Device to be checked
*
* Return start port number
*/
static inline u8 rdma_start_port(const struct ib_device *device)
{
return (device->node_type == RDMA_NODE_IB_SWITCH) ? 0 : 1;
}
/**
* rdma_end_port - Return the last valid port number for the device
* specified
*
* @device: Device to be checked
*
* Return last port number
*/
static inline u8 rdma_end_port(const struct ib_device *device)
{
return (device->node_type == RDMA_NODE_IB_SWITCH) ?
0 : device->phys_port_cnt;
}
static inline bool rdma_protocol_ib(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_PROT_IB;
}
static inline bool rdma_protocol_roce(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_PROT_ROCE;
}
static inline bool rdma_protocol_iwarp(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_PROT_IWARP;
}
static inline bool rdma_ib_or_roce(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags &
(RDMA_CORE_CAP_PROT_IB | RDMA_CORE_CAP_PROT_ROCE);
}
/**
* rdma_cap_ib_mad - Check if the port of a device supports Infiniband
* Management Datagrams.
* @device: Device to check
* @port_num: Port number to check
*
* Management Datagrams (MAD) are a required part of the InfiniBand
* specification and are supported on all InfiniBand devices. A slightly
* extended version are also supported on OPA interfaces.
*
* Return: true if the port supports sending/receiving of MAD packets.
*/
static inline bool rdma_cap_ib_mad(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_IB_MAD;
}
/**
* rdma_cap_ib_smi - Check if the port of a device provides an Infiniband
* Subnet Management Agent (SMA) on the Subnet Management Interface (SMI).
* @device: Device to check
* @port_num: Port number to check
*
* Each InfiniBand node is required to provide a Subnet Management Agent
* that the subnet manager can access. Prior to the fabric being fully
* configured by the subnet manager, the SMA is accessed via a well known
* interface called the Subnet Management Interface (SMI). This interface
* uses directed route packets to communicate with the SM to get around the
* chicken and egg problem of the SM needing to know what's on the fabric
* in order to configure the fabric, and needing to configure the fabric in
* order to send packets to the devices on the fabric. These directed
* route packets do not need the fabric fully configured in order to reach
* their destination. The SMI is the only method allowed to send
* directed route packets on an InfiniBand fabric.
*
* Return: true if the port provides an SMI.
*/
static inline bool rdma_cap_ib_smi(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_IB_SMI;
}
/**
* rdma_cap_ib_cm - Check if the port of device has the capability Infiniband
* Communication Manager.
* @device: Device to check
* @port_num: Port number to check
*
* The InfiniBand Communication Manager is one of many pre-defined General
* Service Agents (GSA) that are accessed via the General Service
* Interface (GSI). It's role is to facilitate establishment of connections
* between nodes as well as other management related tasks for established
* connections.
*
* Return: true if the port supports an IB CM (this does not guarantee that
* a CM is actually running however).
*/
static inline bool rdma_cap_ib_cm(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_IB_CM;
}
/**
* rdma_cap_iw_cm - Check if the port of device has the capability IWARP
* Communication Manager.
* @device: Device to check
* @port_num: Port number to check
*
* Similar to above, but specific to iWARP connections which have a different
* managment protocol than InfiniBand.
*
* Return: true if the port supports an iWARP CM (this does not guarantee that
* a CM is actually running however).
*/
static inline bool rdma_cap_iw_cm(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_IW_CM;
}
/**
* rdma_cap_ib_sa - Check if the port of device has the capability Infiniband
* Subnet Administration.
* @device: Device to check
* @port_num: Port number to check
*
* An InfiniBand Subnet Administration (SA) service is a pre-defined General
* Service Agent (GSA) provided by the Subnet Manager (SM). On InfiniBand
* fabrics, devices should resolve routes to other hosts by contacting the
* SA to query the proper route.
*
* Return: true if the port should act as a client to the fabric Subnet
* Administration interface. This does not imply that the SA service is
* running locally.
*/
static inline bool rdma_cap_ib_sa(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_IB_SA;
}
/**
* rdma_cap_ib_mcast - Check if the port of device has the capability Infiniband
* Multicast.
* @device: Device to check
* @port_num: Port number to check
*
* InfiniBand multicast registration is more complex than normal IPv4 or
* IPv6 multicast registration. Each Host Channel Adapter must register
* with the Subnet Manager when it wishes to join a multicast group. It
* should do so only once regardless of how many queue pairs it subscribes
* to this group. And it should leave the group only after all queue pairs
* attached to the group have been detached.
*
* Return: true if the port must undertake the additional adminstrative
* overhead of registering/unregistering with the SM and tracking of the
* total number of queue pairs attached to the multicast group.
*/
static inline bool rdma_cap_ib_mcast(const struct ib_device *device, u8 port_num)
{
return rdma_cap_ib_sa(device, port_num);
}
/**
* rdma_cap_af_ib - Check if the port of device has the capability
* Native Infiniband Address.
* @device: Device to check
* @port_num: Port number to check
*
* InfiniBand addressing uses a port's GUID + Subnet Prefix to make a default
* GID. RoCE uses a different mechanism, but still generates a GID via
* a prescribed mechanism and port specific data.
*
* Return: true if the port uses a GID address to identify devices on the
* network.
*/
static inline bool rdma_cap_af_ib(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_AF_IB;
}
/**
* rdma_cap_eth_ah - Check if the port of device has the capability
* Ethernet Address Handle.
* @device: Device to check
* @port_num: Port number to check
*
* RoCE is InfiniBand over Ethernet, and it uses a well defined technique
* to fabricate GIDs over Ethernet/IP specific addresses native to the
* port. Normally, packet headers are generated by the sending host
* adapter, but when sending connectionless datagrams, we must manually
* inject the proper headers for the fabric we are communicating over.
*
* Return: true if we are running as a RoCE port and must force the
* addition of a Global Route Header built from our Ethernet Address
* Handle into our header list for connectionless packets.
*/
static inline bool rdma_cap_eth_ah(const struct ib_device *device, u8 port_num)
{
return device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_ETH_AH;
}
/**
* rdma_cap_read_multi_sge - Check if the port of device has the capability
* RDMA Read Multiple Scatter-Gather Entries.
* @device: Device to check
* @port_num: Port number to check
*
* iWARP has a restriction that RDMA READ requests may only have a single
* Scatter/Gather Entry (SGE) in the work request.
*
* NOTE: although the linux kernel currently assumes all devices are either
* single SGE RDMA READ devices or identical SGE maximums for RDMA READs and
* WRITEs, according to Tom Talpey, this is not accurate. There are some
* devices out there that support more than a single SGE on RDMA READ
* requests, but do not support the same number of SGEs as they do on
* RDMA WRITE requests. The linux kernel would need rearchitecting to
* support these imbalanced READ/WRITE SGEs allowed devices. So, for now,
* suffice with either the device supports the same READ/WRITE SGEs, or
* it only gets one READ sge.
*
* Return: true for any device that allows more than one SGE in RDMA READ
* requests.
*/
static inline bool rdma_cap_read_multi_sge(struct ib_device *device,
u8 port_num)
{
return !(device->port_immutable[port_num].core_cap_flags & RDMA_CORE_CAP_PROT_IWARP);
}
int ib_query_gid(struct ib_device *device,
u8 port_num, int index, union ib_gid *gid);
int ib_query_pkey(struct ib_device *device,
u8 port_num, u16 index, u16 *pkey);
int ib_modify_device(struct ib_device *device,
int device_modify_mask,
struct ib_device_modify *device_modify);
int ib_modify_port(struct ib_device *device,
u8 port_num, int port_modify_mask,
struct ib_port_modify *port_modify);
int ib_find_gid(struct ib_device *device, union ib_gid *gid,
u8 *port_num, u16 *index);
int ib_find_pkey(struct ib_device *device,
u8 port_num, u16 pkey, u16 *index);
/**
* ib_alloc_pd - Allocates an unused protection domain.
* @device: The device on which to allocate the protection domain.
*
* A protection domain object provides an association between QPs, shared
* receive queues, address handles, memory regions, and memory windows.
*/
struct ib_pd *ib_alloc_pd(struct ib_device *device);
/**
* ib_dealloc_pd - Deallocates a protection domain.
* @pd: The protection domain to deallocate.
*/
int ib_dealloc_pd(struct ib_pd *pd);
/**
* ib_create_ah - Creates an address handle for the given address vector.
* @pd: The protection domain associated with the address handle.
* @ah_attr: The attributes of the address vector.
*
* The address handle is used to reference a local or global destination
* in all UD QP post sends.
*/
struct ib_ah *ib_create_ah(struct ib_pd *pd, struct ib_ah_attr *ah_attr);
/**
* ib_init_ah_from_wc - Initializes address handle attributes from a
* work completion.
* @device: Device on which the received message arrived.
* @port_num: Port on which the received message arrived.
* @wc: Work completion associated with the received message.
* @grh: References the received global route header. This parameter is
* ignored unless the work completion indicates that the GRH is valid.
* @ah_attr: Returned attributes that can be used when creating an address
* handle for replying to the message.
*/
int ib_init_ah_from_wc(struct ib_device *device, u8 port_num, struct ib_wc *wc,
struct ib_grh *grh, struct ib_ah_attr *ah_attr);
/**
* ib_create_ah_from_wc - Creates an address handle associated with the
* sender of the specified work completion.
* @pd: The protection domain associated with the address handle.
* @wc: Work completion information associated with a received message.
* @grh: References the received global route header. This parameter is
* ignored unless the work completion indicates that the GRH is valid.
* @port_num: The outbound port number to associate with the address.
*
* The address handle is used to reference a local or global destination
* in all UD QP post sends.
*/
struct ib_ah *ib_create_ah_from_wc(struct ib_pd *pd, struct ib_wc *wc,
struct ib_grh *grh, u8 port_num);
/**
* ib_modify_ah - Modifies the address vector associated with an address
* handle.
* @ah: The address handle to modify.
* @ah_attr: The new address vector attributes to associate with the
* address handle.
*/
int ib_modify_ah(struct ib_ah *ah, struct ib_ah_attr *ah_attr);
/**
* ib_query_ah - Queries the address vector associated with an address
* handle.
* @ah: The address handle to query.
* @ah_attr: The address vector attributes associated with the address
* handle.
*/
int ib_query_ah(struct ib_ah *ah, struct ib_ah_attr *ah_attr);
/**
* ib_destroy_ah - Destroys an address handle.
* @ah: The address handle to destroy.
*/
int ib_destroy_ah(struct ib_ah *ah);
/**
* ib_create_srq - Creates a SRQ associated with the specified protection
* domain.
* @pd: The protection domain associated with the SRQ.
* @srq_init_attr: A list of initial attributes required to create the
* SRQ. If SRQ creation succeeds, then the attributes are updated to
* the actual capabilities of the created SRQ.
*
* srq_attr->max_wr and srq_attr->max_sge are read the determine the
* requested size of the SRQ, and set to the actual values allocated
* on return. If ib_create_srq() succeeds, then max_wr and max_sge
* will always be at least as large as the requested values.
*/
struct ib_srq *ib_create_srq(struct ib_pd *pd,
struct ib_srq_init_attr *srq_init_attr);
/**
* ib_modify_srq - Modifies the attributes for the specified SRQ.
* @srq: The SRQ to modify.
* @srq_attr: On input, specifies the SRQ attributes to modify. On output,
* the current values of selected SRQ attributes are returned.
* @srq_attr_mask: A bit-mask used to specify which attributes of the SRQ
* are being modified.
*
* The mask may contain IB_SRQ_MAX_WR to resize the SRQ and/or
* IB_SRQ_LIMIT to set the SRQ's limit and request notification when
* the number of receives queued drops below the limit.
*/
int ib_modify_srq(struct ib_srq *srq,
struct ib_srq_attr *srq_attr,
enum ib_srq_attr_mask srq_attr_mask);
/**
* ib_query_srq - Returns the attribute list and current values for the
* specified SRQ.
* @srq: The SRQ to query.
* @srq_attr: The attributes of the specified SRQ.
*/
int ib_query_srq(struct ib_srq *srq,
struct ib_srq_attr *srq_attr);
/**
* ib_destroy_srq - Destroys the specified SRQ.
* @srq: The SRQ to destroy.
*/
int ib_destroy_srq(struct ib_srq *srq);
/**
* ib_post_srq_recv - Posts a list of work requests to the specified SRQ.
* @srq: The SRQ to post the work request on.
* @recv_wr: A list of work requests to post on the receive queue.
* @bad_recv_wr: On an immediate failure, this parameter will reference
* the work request that failed to be posted on the QP.
*/
static inline int ib_post_srq_recv(struct ib_srq *srq,
struct ib_recv_wr *recv_wr,
struct ib_recv_wr **bad_recv_wr)
{
return srq->device->post_srq_recv(srq, recv_wr, bad_recv_wr);
}
/**
* ib_create_qp - Creates a QP associated with the specified protection
* domain.
* @pd: The protection domain associated with the QP.
* @qp_init_attr: A list of initial attributes required to create the
* QP. If QP creation succeeds, then the attributes are updated to
* the actual capabilities of the created QP.
*/
struct ib_qp *ib_create_qp(struct ib_pd *pd,
struct ib_qp_init_attr *qp_init_attr);
/**
* ib_modify_qp - Modifies the attributes for the specified QP and then
* transitions the QP to the given state.
* @qp: The QP to modify.
* @qp_attr: On input, specifies the QP attributes to modify. On output,
* the current values of selected QP attributes are returned.
* @qp_attr_mask: A bit-mask used to specify which attributes of the QP
* are being modified.
*/
int ib_modify_qp(struct ib_qp *qp,
struct ib_qp_attr *qp_attr,
int qp_attr_mask);
/**
* ib_query_qp - Returns the attribute list and current values for the
* specified QP.
* @qp: The QP to query.
* @qp_attr: The attributes of the specified QP.
* @qp_attr_mask: A bit-mask used to select specific attributes to query.
* @qp_init_attr: Additional attributes of the selected QP.
*
* The qp_attr_mask may be used to limit the query to gathering only the
* selected attributes.
*/
int ib_query_qp(struct ib_qp *qp,
struct ib_qp_attr *qp_attr,
int qp_attr_mask,
struct ib_qp_init_attr *qp_init_attr);
/**
* ib_destroy_qp - Destroys the specified QP.
* @qp: The QP to destroy.
*/
int ib_destroy_qp(struct ib_qp *qp);
/**
* ib_open_qp - Obtain a reference to an existing sharable QP.
* @xrcd - XRC domain
* @qp_open_attr: Attributes identifying the QP to open.
*
* Returns a reference to a sharable QP.
*/
struct ib_qp *ib_open_qp(struct ib_xrcd *xrcd,
struct ib_qp_open_attr *qp_open_attr);
/**
* ib_close_qp - Release an external reference to a QP.
* @qp: The QP handle to release
*
* The opened QP handle is released by the caller. The underlying
* shared QP is not destroyed until all internal references are released.
*/
int ib_close_qp(struct ib_qp *qp);
/**
* ib_post_send - Posts a list of work requests to the send queue of
* the specified QP.
* @qp: The QP to post the work request on.
* @send_wr: A list of work requests to post on the send queue.
* @bad_send_wr: On an immediate failure, this parameter will reference
* the work request that failed to be posted on the QP.
*
* While IBA Vol. 1 section 11.4.1.1 specifies that if an immediate
* error is returned, the QP state shall not be affected,
* ib_post_send() will return an immediate error after queueing any
* earlier work requests in the list.
*/
static inline int ib_post_send(struct ib_qp *qp,
struct ib_send_wr *send_wr,
struct ib_send_wr **bad_send_wr)
{
return qp->device->post_send(qp, send_wr, bad_send_wr);
}
/**
* ib_post_recv - Posts a list of work requests to the receive queue of
* the specified QP.
* @qp: The QP to post the work request on.
* @recv_wr: A list of work requests to post on the receive queue.
* @bad_recv_wr: On an immediate failure, this parameter will reference
* the work request that failed to be posted on the QP.
*/
static inline int ib_post_recv(struct ib_qp *qp,
struct ib_recv_wr *recv_wr,
struct ib_recv_wr **bad_recv_wr)
{
return qp->device->post_recv(qp, recv_wr, bad_recv_wr);
}
/**
* ib_create_cq - Creates a CQ on the specified device.
* @device: The device on which to create the CQ.
* @comp_handler: A user-specified callback that is invoked when a
* completion event occurs on the CQ.
* @event_handler: A user-specified callback that is invoked when an
* asynchronous event not associated with a completion occurs on the CQ.
* @cq_context: Context associated with the CQ returned to the user via
* the associated completion and event handlers.
* @cqe: The minimum size of the CQ.
* @comp_vector - Completion vector used to signal completion events.
* Must be >= 0 and < context->num_comp_vectors.
*
* Users can examine the cq structure to determine the actual CQ size.
*/
struct ib_cq *ib_create_cq(struct ib_device *device,
ib_comp_handler comp_handler,
void (*event_handler)(struct ib_event *, void *),
void *cq_context, int cqe, int comp_vector);
/**
* ib_resize_cq - Modifies the capacity of the CQ.
* @cq: The CQ to resize.
* @cqe: The minimum size of the CQ.
*
* Users can examine the cq structure to determine the actual CQ size.
*/
int ib_resize_cq(struct ib_cq *cq, int cqe);
/**
* ib_modify_cq - Modifies moderation params of the CQ
* @cq: The CQ to modify.
* @cq_count: number of CQEs that will trigger an event
* @cq_period: max period of time in usec before triggering an event
*
*/
int ib_modify_cq(struct ib_cq *cq, u16 cq_count, u16 cq_period);
/**
* ib_destroy_cq - Destroys the specified CQ.
* @cq: The CQ to destroy.
*/
int ib_destroy_cq(struct ib_cq *cq);
/**
* ib_poll_cq - poll a CQ for completion(s)
* @cq:the CQ being polled
* @num_entries:maximum number of completions to return
* @wc:array of at least @num_entries &struct ib_wc where completions
* will be returned
*
* Poll a CQ for (possibly multiple) completions. If the return value
* is < 0, an error occurred. If the return value is >= 0, it is the
* number of completions returned. If the return value is
* non-negative and < num_entries, then the CQ was emptied.
*/
static inline int ib_poll_cq(struct ib_cq *cq, int num_entries,
struct ib_wc *wc)
{
return cq->device->poll_cq(cq, num_entries, wc);
}
/**
* ib_peek_cq - Returns the number of unreaped completions currently
* on the specified CQ.
* @cq: The CQ to peek.
* @wc_cnt: A minimum number of unreaped completions to check for.
*
* If the number of unreaped completions is greater than or equal to wc_cnt,
* this function returns wc_cnt, otherwise, it returns the actual number of
* unreaped completions.
*/
int ib_peek_cq(struct ib_cq *cq, int wc_cnt);
/**
* ib_req_notify_cq - Request completion notification on a CQ.
* @cq: The CQ to generate an event for.
IB: Return "maybe missed event" hint from ib_req_notify_cq() The semantics defined by the InfiniBand specification say that completion events are only generated when a completions is added to a completion queue (CQ) after completion notification is requested. In other words, this means that the following race is possible: while (CQ is not empty) ib_poll_cq(CQ); // new completion is added after while loop is exited ib_req_notify_cq(CQ); // no event is generated for the existing completion To close this race, the IB spec recommends doing another poll of the CQ after requesting notification. However, it is not always possible to arrange code this way (for example, we have found that NAPI for IPoIB cannot poll after requesting notification). Also, some hardware (eg Mellanox HCAs) actually will generate an event for completions added before the call to ib_req_notify_cq() -- which is allowed by the spec, since there's no way for any upper-layer consumer to know exactly when a completion was really added -- so the extra poll of the CQ is just a waste. Motivated by this, we add a new flag "IB_CQ_REPORT_MISSED_EVENTS" for ib_req_notify_cq() so that it can return a hint about whether the a completion may have been added before the request for notification. The return value of ib_req_notify_cq() is extended so: < 0 means an error occurred while requesting notification == 0 means notification was requested successfully, and if IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events were missed and it is safe to wait for another event. > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed in. It means that the consumer must poll the CQ again to make sure it is empty to avoid the race described above. We add a flag to enable this behavior rather than turning it on unconditionally, because checking for missed events may incur significant overhead for some low-level drivers, and consumers that don't care about the results of this test shouldn't be forced to pay for the test. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-05-07 12:02:48 +08:00
* @flags:
* Must contain exactly one of %IB_CQ_SOLICITED or %IB_CQ_NEXT_COMP
* to request an event on the next solicited event or next work
* completion at any type, respectively. %IB_CQ_REPORT_MISSED_EVENTS
* may also be |ed in to request a hint about missed events, as
* described below.
*
* Return Value:
* < 0 means an error occurred while requesting notification
* == 0 means notification was requested successfully, and if
* IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events
* were missed and it is safe to wait for another event. In
* this case is it guaranteed that any work completions added
* to the CQ since the last CQ poll will trigger a completion
* notification event.
* > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed
* in. It means that the consumer must poll the CQ again to
* make sure it is empty to avoid missing an event because of a
* race between requesting notification and an entry being
* added to the CQ. This return value means it is possible
* (but not guaranteed) that a work completion has been added
* to the CQ since the last poll without triggering a
* completion notification event.
*/
static inline int ib_req_notify_cq(struct ib_cq *cq,
IB: Return "maybe missed event" hint from ib_req_notify_cq() The semantics defined by the InfiniBand specification say that completion events are only generated when a completions is added to a completion queue (CQ) after completion notification is requested. In other words, this means that the following race is possible: while (CQ is not empty) ib_poll_cq(CQ); // new completion is added after while loop is exited ib_req_notify_cq(CQ); // no event is generated for the existing completion To close this race, the IB spec recommends doing another poll of the CQ after requesting notification. However, it is not always possible to arrange code this way (for example, we have found that NAPI for IPoIB cannot poll after requesting notification). Also, some hardware (eg Mellanox HCAs) actually will generate an event for completions added before the call to ib_req_notify_cq() -- which is allowed by the spec, since there's no way for any upper-layer consumer to know exactly when a completion was really added -- so the extra poll of the CQ is just a waste. Motivated by this, we add a new flag "IB_CQ_REPORT_MISSED_EVENTS" for ib_req_notify_cq() so that it can return a hint about whether the a completion may have been added before the request for notification. The return value of ib_req_notify_cq() is extended so: < 0 means an error occurred while requesting notification == 0 means notification was requested successfully, and if IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events were missed and it is safe to wait for another event. > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed in. It means that the consumer must poll the CQ again to make sure it is empty to avoid the race described above. We add a flag to enable this behavior rather than turning it on unconditionally, because checking for missed events may incur significant overhead for some low-level drivers, and consumers that don't care about the results of this test shouldn't be forced to pay for the test. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-05-07 12:02:48 +08:00
enum ib_cq_notify_flags flags)
{
IB: Return "maybe missed event" hint from ib_req_notify_cq() The semantics defined by the InfiniBand specification say that completion events are only generated when a completions is added to a completion queue (CQ) after completion notification is requested. In other words, this means that the following race is possible: while (CQ is not empty) ib_poll_cq(CQ); // new completion is added after while loop is exited ib_req_notify_cq(CQ); // no event is generated for the existing completion To close this race, the IB spec recommends doing another poll of the CQ after requesting notification. However, it is not always possible to arrange code this way (for example, we have found that NAPI for IPoIB cannot poll after requesting notification). Also, some hardware (eg Mellanox HCAs) actually will generate an event for completions added before the call to ib_req_notify_cq() -- which is allowed by the spec, since there's no way for any upper-layer consumer to know exactly when a completion was really added -- so the extra poll of the CQ is just a waste. Motivated by this, we add a new flag "IB_CQ_REPORT_MISSED_EVENTS" for ib_req_notify_cq() so that it can return a hint about whether the a completion may have been added before the request for notification. The return value of ib_req_notify_cq() is extended so: < 0 means an error occurred while requesting notification == 0 means notification was requested successfully, and if IB_CQ_REPORT_MISSED_EVENTS was passed in, then no events were missed and it is safe to wait for another event. > 0 is only returned if IB_CQ_REPORT_MISSED_EVENTS was passed in. It means that the consumer must poll the CQ again to make sure it is empty to avoid the race described above. We add a flag to enable this behavior rather than turning it on unconditionally, because checking for missed events may incur significant overhead for some low-level drivers, and consumers that don't care about the results of this test shouldn't be forced to pay for the test. Signed-off-by: Roland Dreier <rolandd@cisco.com>
2007-05-07 12:02:48 +08:00
return cq->device->req_notify_cq(cq, flags);
}
/**
* ib_req_ncomp_notif - Request completion notification when there are
* at least the specified number of unreaped completions on the CQ.
* @cq: The CQ to generate an event for.
* @wc_cnt: The number of unreaped completions that should be on the
* CQ before an event is generated.
*/
static inline int ib_req_ncomp_notif(struct ib_cq *cq, int wc_cnt)
{
return cq->device->req_ncomp_notif ?
cq->device->req_ncomp_notif(cq, wc_cnt) :
-ENOSYS;
}
/**
* ib_get_dma_mr - Returns a memory region for system memory that is
* usable for DMA.
* @pd: The protection domain associated with the memory region.
* @mr_access_flags: Specifies the memory access rights.
*
* Note that the ib_dma_*() functions defined below must be used
* to create/destroy addresses used with the Lkey or Rkey returned
* by ib_get_dma_mr().
*/
struct ib_mr *ib_get_dma_mr(struct ib_pd *pd, int mr_access_flags);
/**
* ib_dma_mapping_error - check a DMA addr for error
* @dev: The device for which the dma_addr was created
* @dma_addr: The DMA address to check
*/
static inline int ib_dma_mapping_error(struct ib_device *dev, u64 dma_addr)
{
if (dev->dma_ops)
return dev->dma_ops->mapping_error(dev, dma_addr);
dma-mapping: add the device argument to dma_mapping_error() Add per-device dma_mapping_ops support for CONFIG_X86_64 as POWER architecture does: This enables us to cleanly fix the Calgary IOMMU issue that some devices are not behind the IOMMU (http://lkml.org/lkml/2008/5/8/423). I think that per-device dma_mapping_ops support would be also helpful for KVM people to support PCI passthrough but Andi thinks that this makes it difficult to support the PCI passthrough (see the above thread). So I CC'ed this to KVM camp. Comments are appreciated. A pointer to dma_mapping_ops to struct dev_archdata is added. If the pointer is non NULL, DMA operations in asm/dma-mapping.h use it. If it's NULL, the system-wide dma_ops pointer is used as before. If it's useful for KVM people, I plan to implement a mechanism to register a hook called when a new pci (or dma capable) device is created (it works with hot plugging). It enables IOMMUs to set up an appropriate dma_mapping_ops per device. The major obstacle is that dma_mapping_error doesn't take a pointer to the device unlike other DMA operations. So x86 can't have dma_mapping_ops per device. Note all the POWER IOMMUs use the same dma_mapping_error function so this is not a problem for POWER but x86 IOMMUs use different dma_mapping_error functions. The first patch adds the device argument to dma_mapping_error. The patch is trivial but large since it touches lots of drivers and dma-mapping.h in all the architecture. This patch: dma_mapping_error() doesn't take a pointer to the device unlike other DMA operations. So we can't have dma_mapping_ops per device. Note that POWER already has dma_mapping_ops per device but all the POWER IOMMUs use the same dma_mapping_error function. x86 IOMMUs use device argument. [akpm@linux-foundation.org: fix sge] [akpm@linux-foundation.org: fix svc_rdma] [akpm@linux-foundation.org: build fix] [akpm@linux-foundation.org: fix bnx2x] [akpm@linux-foundation.org: fix s2io] [akpm@linux-foundation.org: fix pasemi_mac] [akpm@linux-foundation.org: fix sdhci] [akpm@linux-foundation.org: build fix] [akpm@linux-foundation.org: fix sparc] [akpm@linux-foundation.org: fix ibmvscsi] Signed-off-by: FUJITA Tomonori <fujita.tomonori@lab.ntt.co.jp> Cc: Muli Ben-Yehuda <muli@il.ibm.com> Cc: Andi Kleen <andi@firstfloor.org> Cc: Thomas Gleixner <tglx@linutronix.de> Cc: Ingo Molnar <mingo@elte.hu> Cc: Avi Kivity <avi@qumranet.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2008-07-26 10:44:49 +08:00
return dma_mapping_error(dev->dma_device, dma_addr);
}
/**
* ib_dma_map_single - Map a kernel virtual address to DMA address
* @dev: The device for which the dma_addr is to be created
* @cpu_addr: The kernel virtual address
* @size: The size of the region in bytes
* @direction: The direction of the DMA
*/
static inline u64 ib_dma_map_single(struct ib_device *dev,
void *cpu_addr, size_t size,
enum dma_data_direction direction)
{
if (dev->dma_ops)
return dev->dma_ops->map_single(dev, cpu_addr, size, direction);
return dma_map_single(dev->dma_device, cpu_addr, size, direction);
}
/**
* ib_dma_unmap_single - Destroy a mapping created by ib_dma_map_single()
* @dev: The device for which the DMA address was created
* @addr: The DMA address
* @size: The size of the region in bytes
* @direction: The direction of the DMA
*/
static inline void ib_dma_unmap_single(struct ib_device *dev,
u64 addr, size_t size,
enum dma_data_direction direction)
{
if (dev->dma_ops)
dev->dma_ops->unmap_single(dev, addr, size, direction);
else
dma_unmap_single(dev->dma_device, addr, size, direction);
}
static inline u64 ib_dma_map_single_attrs(struct ib_device *dev,
void *cpu_addr, size_t size,
enum dma_data_direction direction,
struct dma_attrs *attrs)
{
return dma_map_single_attrs(dev->dma_device, cpu_addr, size,
direction, attrs);
}
static inline void ib_dma_unmap_single_attrs(struct ib_device *dev,
u64 addr, size_t size,
enum dma_data_direction direction,
struct dma_attrs *attrs)
{
return dma_unmap_single_attrs(dev->dma_device, addr, size,
direction, attrs);
}
/**
* ib_dma_map_page - Map a physical page to DMA address
* @dev: The device for which the dma_addr is to be created
* @page: The page to be mapped
* @offset: The offset within the page
* @size: The size of the region in bytes
* @direction: The direction of the DMA
*/
static inline u64 ib_dma_map_page(struct ib_device *dev,
struct page *page,
unsigned long offset,
size_t size,
enum dma_data_direction direction)
{
if (dev->dma_ops)
return dev->dma_ops->map_page(dev, page, offset, size, direction);
return dma_map_page(dev->dma_device, page, offset, size, direction);
}
/**
* ib_dma_unmap_page - Destroy a mapping created by ib_dma_map_page()
* @dev: The device for which the DMA address was created
* @addr: The DMA address
* @size: The size of the region in bytes
* @direction: The direction of the DMA
*/
static inline void ib_dma_unmap_page(struct ib_device *dev,
u64 addr, size_t size,
enum dma_data_direction direction)
{
if (dev->dma_ops)
dev->dma_ops->unmap_page(dev, addr, size, direction);
else
dma_unmap_page(dev->dma_device, addr, size, direction);
}
/**
* ib_dma_map_sg - Map a scatter/gather list to DMA addresses
* @dev: The device for which the DMA addresses are to be created
* @sg: The array of scatter/gather entries
* @nents: The number of scatter/gather entries
* @direction: The direction of the DMA
*/
static inline int ib_dma_map_sg(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction)
{
if (dev->dma_ops)
return dev->dma_ops->map_sg(dev, sg, nents, direction);
return dma_map_sg(dev->dma_device, sg, nents, direction);
}
/**
* ib_dma_unmap_sg - Unmap a scatter/gather list of DMA addresses
* @dev: The device for which the DMA addresses were created
* @sg: The array of scatter/gather entries
* @nents: The number of scatter/gather entries
* @direction: The direction of the DMA
*/
static inline void ib_dma_unmap_sg(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction)
{
if (dev->dma_ops)
dev->dma_ops->unmap_sg(dev, sg, nents, direction);
else
dma_unmap_sg(dev->dma_device, sg, nents, direction);
}
static inline int ib_dma_map_sg_attrs(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction,
struct dma_attrs *attrs)
{
return dma_map_sg_attrs(dev->dma_device, sg, nents, direction, attrs);
}
static inline void ib_dma_unmap_sg_attrs(struct ib_device *dev,
struct scatterlist *sg, int nents,
enum dma_data_direction direction,
struct dma_attrs *attrs)
{
dma_unmap_sg_attrs(dev->dma_device, sg, nents, direction, attrs);
}
/**
* ib_sg_dma_address - Return the DMA address from a scatter/gather entry
* @dev: The device for which the DMA addresses were created
* @sg: The scatter/gather entry
*
* Note: this function is obsolete. To do: change all occurrences of
* ib_sg_dma_address() into sg_dma_address().
*/
static inline u64 ib_sg_dma_address(struct ib_device *dev,
struct scatterlist *sg)
{
return sg_dma_address(sg);
}
/**
* ib_sg_dma_len - Return the DMA length from a scatter/gather entry
* @dev: The device for which the DMA addresses were created
* @sg: The scatter/gather entry
*
* Note: this function is obsolete. To do: change all occurrences of
* ib_sg_dma_len() into sg_dma_len().
*/
static inline unsigned int ib_sg_dma_len(struct ib_device *dev,
struct scatterlist *sg)
{
return sg_dma_len(sg);
}
/**
* ib_dma_sync_single_for_cpu - Prepare DMA region to be accessed by CPU
* @dev: The device for which the DMA address was created
* @addr: The DMA address
* @size: The size of the region in bytes
* @dir: The direction of the DMA
*/
static inline void ib_dma_sync_single_for_cpu(struct ib_device *dev,
u64 addr,
size_t size,
enum dma_data_direction dir)
{
if (dev->dma_ops)
dev->dma_ops->sync_single_for_cpu(dev, addr, size, dir);
else
dma_sync_single_for_cpu(dev->dma_device, addr, size, dir);
}
/**
* ib_dma_sync_single_for_device - Prepare DMA region to be accessed by device
* @dev: The device for which the DMA address was created
* @addr: The DMA address
* @size: The size of the region in bytes
* @dir: The direction of the DMA
*/
static inline void ib_dma_sync_single_for_device(struct ib_device *dev,
u64 addr,
size_t size,
enum dma_data_direction dir)
{
if (dev->dma_ops)
dev->dma_ops->sync_single_for_device(dev, addr, size, dir);
else
dma_sync_single_for_device(dev->dma_device, addr, size, dir);
}
/**
* ib_dma_alloc_coherent - Allocate memory and map it for DMA
* @dev: The device for which the DMA address is requested
* @size: The size of the region to allocate in bytes
* @dma_handle: A pointer for returning the DMA address of the region
* @flag: memory allocator flags
*/
static inline void *ib_dma_alloc_coherent(struct ib_device *dev,
size_t size,
u64 *dma_handle,
gfp_t flag)
{
if (dev->dma_ops)
return dev->dma_ops->alloc_coherent(dev, size, dma_handle, flag);
else {
dma_addr_t handle;
void *ret;
ret = dma_alloc_coherent(dev->dma_device, size, &handle, flag);
*dma_handle = handle;
return ret;
}
}
/**
* ib_dma_free_coherent - Free memory allocated by ib_dma_alloc_coherent()
* @dev: The device for which the DMA addresses were allocated
* @size: The size of the region
* @cpu_addr: the address returned by ib_dma_alloc_coherent()
* @dma_handle: the DMA address returned by ib_dma_alloc_coherent()
*/
static inline void ib_dma_free_coherent(struct ib_device *dev,
size_t size, void *cpu_addr,
u64 dma_handle)
{
if (dev->dma_ops)
dev->dma_ops->free_coherent(dev, size, cpu_addr, dma_handle);
else
dma_free_coherent(dev->dma_device, size, cpu_addr, dma_handle);
}
/**
* ib_reg_phys_mr - Prepares a virtually addressed memory region for use
* by an HCA.
* @pd: The protection domain associated assigned to the registered region.
* @phys_buf_array: Specifies a list of physical buffers to use in the
* memory region.
* @num_phys_buf: Specifies the size of the phys_buf_array.
* @mr_access_flags: Specifies the memory access rights.
* @iova_start: The offset of the region's starting I/O virtual address.
*/
struct ib_mr *ib_reg_phys_mr(struct ib_pd *pd,
struct ib_phys_buf *phys_buf_array,
int num_phys_buf,
int mr_access_flags,
u64 *iova_start);
/**
* ib_rereg_phys_mr - Modifies the attributes of an existing memory region.
* Conceptually, this call performs the functions deregister memory region
* followed by register physical memory region. Where possible,
* resources are reused instead of deallocated and reallocated.
* @mr: The memory region to modify.
* @mr_rereg_mask: A bit-mask used to indicate which of the following
* properties of the memory region are being modified.
* @pd: If %IB_MR_REREG_PD is set in mr_rereg_mask, this field specifies
* the new protection domain to associated with the memory region,
* otherwise, this parameter is ignored.
* @phys_buf_array: If %IB_MR_REREG_TRANS is set in mr_rereg_mask, this
* field specifies a list of physical buffers to use in the new
* translation, otherwise, this parameter is ignored.
* @num_phys_buf: If %IB_MR_REREG_TRANS is set in mr_rereg_mask, this
* field specifies the size of the phys_buf_array, otherwise, this
* parameter is ignored.
* @mr_access_flags: If %IB_MR_REREG_ACCESS is set in mr_rereg_mask, this
* field specifies the new memory access rights, otherwise, this
* parameter is ignored.
* @iova_start: The offset of the region's starting I/O virtual address.
*/
int ib_rereg_phys_mr(struct ib_mr *mr,
int mr_rereg_mask,
struct ib_pd *pd,
struct ib_phys_buf *phys_buf_array,
int num_phys_buf,
int mr_access_flags,
u64 *iova_start);
/**
* ib_query_mr - Retrieves information about a specific memory region.
* @mr: The memory region to retrieve information about.
* @mr_attr: The attributes of the specified memory region.
*/
int ib_query_mr(struct ib_mr *mr, struct ib_mr_attr *mr_attr);
/**
* ib_dereg_mr - Deregisters a memory region and removes it from the
* HCA translation table.
* @mr: The memory region to deregister.
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
*
* This function can fail, if the memory region has memory windows bound to it.
*/
int ib_dereg_mr(struct ib_mr *mr);
/**
* ib_create_mr - Allocates a memory region that may be used for
* signature handover operations.
* @pd: The protection domain associated with the region.
* @mr_init_attr: memory region init attributes.
*/
struct ib_mr *ib_create_mr(struct ib_pd *pd,
struct ib_mr_init_attr *mr_init_attr);
/**
* ib_destroy_mr - Destroys a memory region that was created using
* ib_create_mr and removes it from HW translation tables.
* @mr: The memory region to destroy.
*
* This function can fail, if the memory region has memory windows bound to it.
*/
int ib_destroy_mr(struct ib_mr *mr);
RDMA/core: Add memory management extensions support This patch adds support for the IB "base memory management extension" (BMME) and the equivalent iWARP operations (which the iWARP verbs mandates all devices must implement). The new operations are: - Allocate an ib_mr for use in fast register work requests. - Allocate/free a physical buffer lists for use in fast register work requests. This allows device drivers to allocate this memory as needed for use in posting send requests (eg via dma_alloc_coherent). - New send queue work requests: * send with remote invalidate * fast register memory region * local invalidate memory region * RDMA read with invalidate local memory region (iWARP only) Consumer interface details: - A new device capability flag IB_DEVICE_MEM_MGT_EXTENSIONS is added to indicate device support for these features. - New send work request opcodes IB_WR_FAST_REG_MR, IB_WR_LOCAL_INV, IB_WR_RDMA_READ_WITH_INV are added. - A new consumer API function, ib_alloc_mr() is added to allocate fast register memory regions. - New consumer API functions, ib_alloc_fast_reg_page_list() and ib_free_fast_reg_page_list() are added to allocate and free device-specific memory for fast registration page lists. - A new consumer API function, ib_update_fast_reg_key(), is added to allow the key portion of the R_Key and L_Key of a fast registration MR to be updated. Consumers call this if desired before posting a IB_WR_FAST_REG_MR work request. Consumers can use this as follows: - MR is allocated with ib_alloc_mr(). - Page list memory is allocated with ib_alloc_fast_reg_page_list(). - MR R_Key/L_Key "key" field is updated with ib_update_fast_reg_key(). - MR made VALID and bound to a specific page list via ib_post_send(IB_WR_FAST_REG_MR) - MR made INVALID via ib_post_send(IB_WR_LOCAL_INV), ib_post_send(IB_WR_RDMA_READ_WITH_INV) or an incoming send with invalidate operation. - MR is deallocated with ib_dereg_mr() - page lists dealloced via ib_free_fast_reg_page_list(). Applications can allocate a fast register MR once, and then can repeatedly bind the MR to different physical block lists (PBLs) via posting work requests to a send queue (SQ). For each outstanding MR-to-PBL binding in the SQ pipe, a fast_reg_page_list needs to be allocated (the fast_reg_page_list is owned by the low-level driver from the consumer posting a work request until the request completes). Thus pipelining can be achieved while still allowing device-specific page_list processing. The 32-bit fast register memory key/STag is composed of a 24-bit index and an 8-bit key. The application can change the key each time it fast registers thus allowing more control over the peer's use of the key/STag (ie it can effectively be changed each time the rkey is rebound to a page list). Signed-off-by: Steve Wise <swise@opengridcomputing.com> Signed-off-by: Roland Dreier <rolandd@cisco.com>
2008-07-15 14:48:45 +08:00
/**
* ib_alloc_fast_reg_mr - Allocates memory region usable with the
* IB_WR_FAST_REG_MR send work request.
* @pd: The protection domain associated with the region.
* @max_page_list_len: requested max physical buffer list length to be
* used with fast register work requests for this MR.
*/
struct ib_mr *ib_alloc_fast_reg_mr(struct ib_pd *pd, int max_page_list_len);
/**
* ib_alloc_fast_reg_page_list - Allocates a page list array
* @device - ib device pointer.
* @page_list_len - size of the page list array to be allocated.
*
* This allocates and returns a struct ib_fast_reg_page_list * and a
* page_list array that is at least page_list_len in size. The actual
* size is returned in max_page_list_len. The caller is responsible
* for initializing the contents of the page_list array before posting
* a send work request with the IB_WC_FAST_REG_MR opcode.
*
* The page_list array entries must be translated using one of the
* ib_dma_*() functions just like the addresses passed to
* ib_map_phys_fmr(). Once the ib_post_send() is issued, the struct
* ib_fast_reg_page_list must not be modified by the caller until the
* IB_WC_FAST_REG_MR work request completes.
*/
struct ib_fast_reg_page_list *ib_alloc_fast_reg_page_list(
struct ib_device *device, int page_list_len);
/**
* ib_free_fast_reg_page_list - Deallocates a previously allocated
* page list array.
* @page_list - struct ib_fast_reg_page_list pointer to be deallocated.
*/
void ib_free_fast_reg_page_list(struct ib_fast_reg_page_list *page_list);
/**
* ib_update_fast_reg_key - updates the key portion of the fast_reg MR
* R_Key and L_Key.
* @mr - struct ib_mr pointer to be updated.
* @newkey - new key to be used.
*/
static inline void ib_update_fast_reg_key(struct ib_mr *mr, u8 newkey)
{
mr->lkey = (mr->lkey & 0xffffff00) | newkey;
mr->rkey = (mr->rkey & 0xffffff00) | newkey;
}
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
/**
* ib_inc_rkey - increments the key portion of the given rkey. Can be used
* for calculating a new rkey for type 2 memory windows.
* @rkey - the rkey to increment.
*/
static inline u32 ib_inc_rkey(u32 rkey)
{
const u32 mask = 0x000000ff;
return ((rkey + 1) & mask) | (rkey & ~mask);
}
/**
* ib_alloc_mw - Allocates a memory window.
* @pd: The protection domain associated with the memory window.
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
* @type: The type of the memory window (1 or 2).
*/
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
struct ib_mw *ib_alloc_mw(struct ib_pd *pd, enum ib_mw_type type);
/**
* ib_bind_mw - Posts a work request to the send queue of the specified
* QP, which binds the memory window to the given address range and
* remote access attributes.
* @qp: QP to post the bind work request on.
* @mw: The memory window to bind.
* @mw_bind: Specifies information about the memory window, including
* its address range, remote access rights, and associated memory region.
IB/core: Add "type 2" memory windows support This patch enhances the IB core support for Memory Windows (MWs). MWs allow an application to have better/flexible control over remote access to memory. Two types of MWs are supported, with the second type having two flavors: Type 1 - associated with PD only Type 2A - associated with QPN only Type 2B - associated with PD and QPN Applications can allocate a MW once, and then repeatedly bind the MW to different ranges in MRs that are associated to the same PD. Type 1 windows are bound through a verb, while type 2 windows are bound by posting a work request. The 32-bit memory key is composed of a 24-bit index and an 8-bit key. The key is changed with each bind, thus allowing more control over the peer's use of the memory key. The changes introduced are the following: * add memory window type enum and a corresponding parameter to ib_alloc_mw. * type 2 memory window bind work request support. * create a struct that contains the common part of the bind verb struct ibv_mw_bind and the bind work request into a single struct. * add the ib_inc_rkey helper function to advance the tag part of an rkey. Consumer interface details: * new device capability flags IB_DEVICE_MEM_WINDOW_TYPE_2A and IB_DEVICE_MEM_WINDOW_TYPE_2B are added to indicate device support for these features. Devices can set either IB_DEVICE_MEM_WINDOW_TYPE_2A or IB_DEVICE_MEM_WINDOW_TYPE_2B if it supports type 2A or type 2B memory windows. It can set neither to indicate it doesn't support type 2 windows at all. * modify existing provides and consumers code to the new param of ib_alloc_mw and the ib_mw_bind_info structure Signed-off-by: Haggai Eran <haggaie@mellanox.com> Signed-off-by: Shani Michaeli <shanim@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-02-07 00:19:12 +08:00
*
* If there is no immediate error, the function will update the rkey member
* of the mw parameter to its new value. The bind operation can still fail
* asynchronously.
*/
static inline int ib_bind_mw(struct ib_qp *qp,
struct ib_mw *mw,
struct ib_mw_bind *mw_bind)
{
/* XXX reference counting in corresponding MR? */
return mw->device->bind_mw ?
mw->device->bind_mw(qp, mw, mw_bind) :
-ENOSYS;
}
/**
* ib_dealloc_mw - Deallocates a memory window.
* @mw: The memory window to deallocate.
*/
int ib_dealloc_mw(struct ib_mw *mw);
/**
* ib_alloc_fmr - Allocates a unmapped fast memory region.
* @pd: The protection domain associated with the unmapped region.
* @mr_access_flags: Specifies the memory access rights.
* @fmr_attr: Attributes of the unmapped region.
*
* A fast memory region must be mapped before it can be used as part of
* a work request.
*/
struct ib_fmr *ib_alloc_fmr(struct ib_pd *pd,
int mr_access_flags,
struct ib_fmr_attr *fmr_attr);
/**
* ib_map_phys_fmr - Maps a list of physical pages to a fast memory region.
* @fmr: The fast memory region to associate with the pages.
* @page_list: An array of physical pages to map to the fast memory region.
* @list_len: The number of pages in page_list.
* @iova: The I/O virtual address to use with the mapped region.
*/
static inline int ib_map_phys_fmr(struct ib_fmr *fmr,
u64 *page_list, int list_len,
u64 iova)
{
return fmr->device->map_phys_fmr(fmr, page_list, list_len, iova);
}
/**
* ib_unmap_fmr - Removes the mapping from a list of fast memory regions.
* @fmr_list: A linked list of fast memory regions to unmap.
*/
int ib_unmap_fmr(struct list_head *fmr_list);
/**
* ib_dealloc_fmr - Deallocates a fast memory region.
* @fmr: The fast memory region to deallocate.
*/
int ib_dealloc_fmr(struct ib_fmr *fmr);
/**
* ib_attach_mcast - Attaches the specified QP to a multicast group.
* @qp: QP to attach to the multicast group. The QP must be type
* IB_QPT_UD.
* @gid: Multicast group GID.
* @lid: Multicast group LID in host byte order.
*
* In order to send and receive multicast packets, subnet
* administration must have created the multicast group and configured
* the fabric appropriately. The port associated with the specified
* QP must also be a member of the multicast group.
*/
int ib_attach_mcast(struct ib_qp *qp, union ib_gid *gid, u16 lid);
/**
* ib_detach_mcast - Detaches the specified QP from a multicast group.
* @qp: QP to detach from the multicast group.
* @gid: Multicast group GID.
* @lid: Multicast group LID in host byte order.
*/
int ib_detach_mcast(struct ib_qp *qp, union ib_gid *gid, u16 lid);
/**
* ib_alloc_xrcd - Allocates an XRC domain.
* @device: The device on which to allocate the XRC domain.
*/
struct ib_xrcd *ib_alloc_xrcd(struct ib_device *device);
/**
* ib_dealloc_xrcd - Deallocates an XRC domain.
* @xrcd: The XRC domain to deallocate.
*/
int ib_dealloc_xrcd(struct ib_xrcd *xrcd);
IB/core: Add receive flow steering support The RDMA stack allows for applications to create IB_QPT_RAW_PACKET QPs, which receive plain Ethernet packets, specifically packets that don't carry any QPN to be matched by the receiving side. Applications using these QPs must be provided with a method to program some steering rule with the HW so packets arriving at the local port can be routed to them. This patch adds ib_create_flow(), which allow providing a flow specification for a QP. When there's a match between the specification and a received packet, the packet is forwarded to that QP, in a the same way one uses ib_attach_multicast() for IB UD multicast handling. Flow specifications are provided as instances of struct ib_flow_spec_yyy, which describe L2, L3 and L4 headers. Currently specs for Ethernet, IPv4, TCP and UDP are defined. Flow specs are made of values and masks. The input to ib_create_flow() is a struct ib_flow_attr, which contains a few mandatory control elements and optional flow specs. struct ib_flow_attr { enum ib_flow_attr_type type; u16 size; u16 priority; u32 flags; u8 num_of_specs; u8 port; /* Following are the optional layers according to user request * struct ib_flow_spec_yyy * struct ib_flow_spec_zzz */ }; As these specs are eventually coming from user space, they are defined and used in a way which allows adding new spec types without kernel/user ABI change, just with a little API enhancement which defines the newly added spec. The flow spec structures are defined with TLV (Type-Length-Value) entries, which allows calling ib_create_flow() with a list of variable length of optional specs. For the actual processing of ib_flow_attr the driver uses the number of specs and the size mandatory fields along with the TLV nature of the specs. Steering rules processing order is according to the domain over which the rule is set and the rule priority. All rules set by user space applicatations fall into the IB_FLOW_DOMAIN_USER domain, other domains could be used by future IPoIB RFS and Ethetool flow-steering interface implementation. Lower numerical value for the priority field means higher priority. The returned value from ib_create_flow() is a struct ib_flow, which contains a database pointer (handle) provided by the HW driver to be used when calling ib_destroy_flow(). Applications that offload TCP/IP traffic can also be written over IB UD QPs. The ib_create_flow() / ib_destroy_flow() API is designed to support UD QPs too. A HW driver can set IB_DEVICE_MANAGED_FLOW_STEERING to denote support for flow steering. The ib_flow_attr enum type supports usage of flow steering for promiscuous and sniffer purposes: IB_FLOW_ATTR_NORMAL - "regular" rule, steering according to rule specification IB_FLOW_ATTR_ALL_DEFAULT - default unicast and multicast rule, receive all Ethernet traffic which isn't steered to any QP IB_FLOW_ATTR_MC_DEFAULT - same as IB_FLOW_ATTR_ALL_DEFAULT but only for multicast IB_FLOW_ATTR_SNIFFER - sniffer rule, receive all port traffic ALL_DEFAULT and MC_DEFAULT rules options are valid only for Ethernet link type. Signed-off-by: Hadar Hen Zion <hadarh@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-08-07 19:01:59 +08:00
struct ib_flow *ib_create_flow(struct ib_qp *qp,
struct ib_flow_attr *flow_attr, int domain);
int ib_destroy_flow(struct ib_flow *flow_id);
static inline int ib_check_mr_access(int flags)
{
/*
* Local write permission is required if remote write or
* remote atomic permission is also requested.
*/
if (flags & (IB_ACCESS_REMOTE_ATOMIC | IB_ACCESS_REMOTE_WRITE) &&
!(flags & IB_ACCESS_LOCAL_WRITE))
return -EINVAL;
return 0;
}
IB/core: Introduce signature verbs API Introduce a verbs interface for signature-related operations. A signature handover operation configures the layouts of data and protection attributes both in memory and wire domains. Signature operations are: - INSERT: Generate and insert protection information when handing over data from input space to output space. - validate and STRIP: Validate protection information and remove it when handing over data from input space to output space. - validate and PASS: Validate protection information and pass it when handing over data from input space to output space. Once the signature handover opration is done, the HCA will offload data integrity generation/validation while performing the actual data transfer. Additions: 1. HCA signature capabilities in device attributes Verbs provider supporting signature handover operations fills relevant fields in device attributes structure returned by ib_query_device. 2. QP creation flag IB_QP_CREATE_SIGNATURE_EN Creating a QP that will carry signature handover operations may require some special preparations from the verbs provider. So we add QP creation flag IB_QP_CREATE_SIGNATURE_EN to declare that the created QP may carry out signature handover operations. Expose signature support to verbs layer (no support for now). 3. New send work request IB_WR_REG_SIG_MR Signature handover work request. This WR will define the signature handover properties of the memory/wire domains as well as the domains layout. The purpose of this work request is to bind all the needed information for the signature operation: - data to be transferred: wr->sg_list (ib_sge). * The raw data, pre-registered to a single MR (normally, before signature, this MR would have been used directly for the data transfer) - data protection guards: sig_handover.prot (ib_sge). * The data protection buffer, pre-registered to a single MR, which contains the data integrity guards of the raw data blocks. Note that it may not always exist, only in cases where the user is interested in storing protection guards in memory. - signature operation attributes: sig_handover.sig_attrs. * Tells the HCA how to validate/generate the protection information. Once the work request is executed, the memory region that will describe the signature transaction will be the sig_mr. The application can now go ahead and send the sig_mr.rkey or use the sig_mr.lkey for data transfer. 4. New Verb ib_check_mr_status check_mr_status verb checks the status of the memory region post transaction. The first check that may be used is IB_MR_CHECK_SIG_STATUS, which will indicate if any signature errors are pending for a specific signature-enabled ib_mr. This verb is a lightwight check and is allowed to be taken from interrupt context. An application must call this verb after it is known that the actual data transfer has finished. Signed-off-by: Sagi Grimberg <sagig@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2014-02-23 20:19:05 +08:00
/**
* ib_check_mr_status: lightweight check of MR status.
* This routine may provide status checks on a selected
* ib_mr. first use is for signature status check.
*
* @mr: A memory region.
* @check_mask: Bitmask of which checks to perform from
* ib_mr_status_check enumeration.
* @mr_status: The container of relevant status checks.
* failed checks will be indicated in the status bitmask
* and the relevant info shall be in the error item.
*/
int ib_check_mr_status(struct ib_mr *mr, u32 check_mask,
struct ib_mr_status *mr_status);
#endif /* IB_VERBS_H */