linux/drivers/infiniband/hw/mlx4/mad.c

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/*
* Copyright (c) 2007 Cisco Systems, Inc. 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.
*/
#include <rdma/ib_mad.h>
#include <rdma/ib_smi.h>
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
#include <rdma/ib_sa.h>
#include <rdma/ib_cache.h>
#include <linux/random.h>
#include <linux/mlx4/cmd.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 16:04:11 +08:00
#include <linux/gfp.h>
#include <rdma/ib_pma.h>
#include <linux/ip.h>
#include <net/ipv6.h>
#include <linux/mlx4/driver.h>
#include "mlx4_ib.h"
enum {
MLX4_IB_VENDOR_CLASS1 = 0x9,
MLX4_IB_VENDOR_CLASS2 = 0xa
};
#define MLX4_TUN_SEND_WRID_SHIFT 34
#define MLX4_TUN_QPN_SHIFT 32
#define MLX4_TUN_WRID_RECV (((u64) 1) << MLX4_TUN_SEND_WRID_SHIFT)
#define MLX4_TUN_SET_WRID_QPN(a) (((u64) ((a) & 0x3)) << MLX4_TUN_QPN_SHIFT)
#define MLX4_TUN_IS_RECV(a) (((a) >> MLX4_TUN_SEND_WRID_SHIFT) & 0x1)
#define MLX4_TUN_WRID_QPN(a) (((a) >> MLX4_TUN_QPN_SHIFT) & 0x3)
/* Port mgmt change event handling */
#define GET_BLK_PTR_FROM_EQE(eqe) be32_to_cpu(eqe->event.port_mgmt_change.params.tbl_change_info.block_ptr)
#define GET_MASK_FROM_EQE(eqe) be32_to_cpu(eqe->event.port_mgmt_change.params.tbl_change_info.tbl_entries_mask)
#define NUM_IDX_IN_PKEY_TBL_BLK 32
#define GUID_TBL_ENTRY_SIZE 8 /* size in bytes */
#define GUID_TBL_BLK_NUM_ENTRIES 8
#define GUID_TBL_BLK_SIZE (GUID_TBL_ENTRY_SIZE * GUID_TBL_BLK_NUM_ENTRIES)
struct mlx4_mad_rcv_buf {
struct ib_grh grh;
u8 payload[256];
} __packed;
struct mlx4_mad_snd_buf {
u8 payload[256];
} __packed;
struct mlx4_tunnel_mad {
struct ib_grh grh;
struct mlx4_ib_tunnel_header hdr;
struct ib_mad mad;
} __packed;
struct mlx4_rcv_tunnel_mad {
struct mlx4_rcv_tunnel_hdr hdr;
struct ib_grh grh;
struct ib_mad mad;
} __packed;
static void handle_client_rereg_event(struct mlx4_ib_dev *dev, u8 port_num);
static void handle_lid_change_event(struct mlx4_ib_dev *dev, u8 port_num);
static void __propagate_pkey_ev(struct mlx4_ib_dev *dev, int port_num,
int block, u32 change_bitmap);
__be64 mlx4_ib_gen_node_guid(void)
{
#define NODE_GUID_HI ((u64) (((u64)IB_OPENIB_OUI) << 40))
return cpu_to_be64(NODE_GUID_HI | prandom_u32());
}
__be64 mlx4_ib_get_new_demux_tid(struct mlx4_ib_demux_ctx *ctx)
{
return cpu_to_be64(atomic_inc_return(&ctx->tid)) |
cpu_to_be64(0xff00000000000000LL);
}
int mlx4_MAD_IFC(struct mlx4_ib_dev *dev, int mad_ifc_flags,
int port, const struct ib_wc *in_wc,
const struct ib_grh *in_grh,
const void *in_mad, void *response_mad)
{
struct mlx4_cmd_mailbox *inmailbox, *outmailbox;
void *inbox;
int err;
u32 in_modifier = port;
u8 op_modifier = 0;
inmailbox = mlx4_alloc_cmd_mailbox(dev->dev);
if (IS_ERR(inmailbox))
return PTR_ERR(inmailbox);
inbox = inmailbox->buf;
outmailbox = mlx4_alloc_cmd_mailbox(dev->dev);
if (IS_ERR(outmailbox)) {
mlx4_free_cmd_mailbox(dev->dev, inmailbox);
return PTR_ERR(outmailbox);
}
memcpy(inbox, in_mad, 256);
/*
* Key check traps can't be generated unless we have in_wc to
* tell us where to send the trap.
*/
if ((mad_ifc_flags & MLX4_MAD_IFC_IGNORE_MKEY) || !in_wc)
op_modifier |= 0x1;
if ((mad_ifc_flags & MLX4_MAD_IFC_IGNORE_BKEY) || !in_wc)
op_modifier |= 0x2;
if (mlx4_is_mfunc(dev->dev) &&
(mad_ifc_flags & MLX4_MAD_IFC_NET_VIEW || in_wc))
op_modifier |= 0x8;
if (in_wc) {
struct {
__be32 my_qpn;
u32 reserved1;
__be32 rqpn;
u8 sl;
u8 g_path;
u16 reserved2[2];
__be16 pkey;
u32 reserved3[11];
u8 grh[40];
} *ext_info;
memset(inbox + 256, 0, 256);
ext_info = inbox + 256;
ext_info->my_qpn = cpu_to_be32(in_wc->qp->qp_num);
ext_info->rqpn = cpu_to_be32(in_wc->src_qp);
ext_info->sl = in_wc->sl << 4;
ext_info->g_path = in_wc->dlid_path_bits |
(in_wc->wc_flags & IB_WC_GRH ? 0x80 : 0);
ext_info->pkey = cpu_to_be16(in_wc->pkey_index);
if (in_grh)
memcpy(ext_info->grh, in_grh, 40);
op_modifier |= 0x4;
in_modifier |= ib_lid_cpu16(in_wc->slid) << 16;
}
err = mlx4_cmd_box(dev->dev, inmailbox->dma, outmailbox->dma, in_modifier,
mlx4_is_master(dev->dev) ? (op_modifier & ~0x8) : op_modifier,
MLX4_CMD_MAD_IFC, MLX4_CMD_TIME_CLASS_C,
(op_modifier & 0x8) ? MLX4_CMD_NATIVE : MLX4_CMD_WRAPPED);
if (!err)
memcpy(response_mad, outmailbox->buf, 256);
mlx4_free_cmd_mailbox(dev->dev, inmailbox);
mlx4_free_cmd_mailbox(dev->dev, outmailbox);
return err;
}
static void update_sm_ah(struct mlx4_ib_dev *dev, u8 port_num, u16 lid, u8 sl)
{
struct ib_ah *new_ah;
struct rdma_ah_attr ah_attr;
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
unsigned long flags;
if (!dev->send_agent[port_num - 1][0])
return;
memset(&ah_attr, 0, sizeof ah_attr);
ah_attr.type = rdma_ah_find_type(&dev->ib_dev, port_num);
rdma_ah_set_dlid(&ah_attr, lid);
rdma_ah_set_sl(&ah_attr, sl);
rdma_ah_set_port_num(&ah_attr, port_num);
new_ah = rdma_create_ah(dev->send_agent[port_num - 1][0]->qp->pd,
&ah_attr);
if (IS_ERR(new_ah))
return;
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_lock_irqsave(&dev->sm_lock, flags);
if (dev->sm_ah[port_num - 1])
rdma_destroy_ah(dev->sm_ah[port_num - 1]);
dev->sm_ah[port_num - 1] = new_ah;
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_unlock_irqrestore(&dev->sm_lock, flags);
}
/*
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
* Snoop SM MADs for port info, GUID info, and P_Key table sets, so we can
* synthesize LID change, Client-Rereg, GID change, and P_Key change events.
*/
static void smp_snoop(struct ib_device *ibdev, u8 port_num, const struct ib_mad *mad,
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
u16 prev_lid)
{
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
struct ib_port_info *pinfo;
u16 lid;
__be16 *base;
u32 bn, pkey_change_bitmap;
int i;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
struct mlx4_ib_dev *dev = to_mdev(ibdev);
if ((mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_LID_ROUTED ||
mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE) &&
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
mad->mad_hdr.method == IB_MGMT_METHOD_SET)
switch (mad->mad_hdr.attr_id) {
case IB_SMP_ATTR_PORT_INFO:
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
if (dev->dev->caps.flags & MLX4_DEV_CAP_FLAG_PORT_MNG_CHG_EV)
return;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
pinfo = (struct ib_port_info *) ((struct ib_smp *) mad)->data;
lid = be16_to_cpu(pinfo->lid);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
update_sm_ah(dev, port_num,
be16_to_cpu(pinfo->sm_lid),
pinfo->neighbormtu_mastersmsl & 0xf);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
if (pinfo->clientrereg_resv_subnetto & 0x80)
handle_client_rereg_event(dev, port_num);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
if (prev_lid != lid)
handle_lid_change_event(dev, port_num);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
case IB_SMP_ATTR_PKEY_TABLE:
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
if (dev->dev->caps.flags & MLX4_DEV_CAP_FLAG_PORT_MNG_CHG_EV)
return;
if (!mlx4_is_mfunc(dev->dev)) {
mlx4_ib_dispatch_event(dev, port_num,
IB_EVENT_PKEY_CHANGE);
break;
}
/* at this point, we are running in the master.
* Slaves do not receive SMPs.
*/
bn = be32_to_cpu(((struct ib_smp *)mad)->attr_mod) & 0xFFFF;
base = (__be16 *) &(((struct ib_smp *)mad)->data[0]);
pkey_change_bitmap = 0;
for (i = 0; i < 32; i++) {
pr_debug("PKEY[%d] = x%x\n",
i + bn*32, be16_to_cpu(base[i]));
if (be16_to_cpu(base[i]) !=
dev->pkeys.phys_pkey_cache[port_num - 1][i + bn*32]) {
pkey_change_bitmap |= (1 << i);
dev->pkeys.phys_pkey_cache[port_num - 1][i + bn*32] =
be16_to_cpu(base[i]);
}
}
pr_debug("PKEY Change event: port=%d, "
"block=0x%x, change_bitmap=0x%x\n",
port_num, bn, pkey_change_bitmap);
if (pkey_change_bitmap) {
mlx4_ib_dispatch_event(dev, port_num,
IB_EVENT_PKEY_CHANGE);
if (!dev->sriov.is_going_down)
__propagate_pkey_ev(dev, port_num, bn,
pkey_change_bitmap);
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
case IB_SMP_ATTR_GUID_INFO:
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
if (dev->dev->caps.flags & MLX4_DEV_CAP_FLAG_PORT_MNG_CHG_EV)
return;
/* paravirtualized master's guid is guid 0 -- does not change */
if (!mlx4_is_master(dev->dev))
mlx4_ib_dispatch_event(dev, port_num,
IB_EVENT_GID_CHANGE);
/*if master, notify relevant slaves*/
if (mlx4_is_master(dev->dev) &&
!dev->sriov.is_going_down) {
bn = be32_to_cpu(((struct ib_smp *)mad)->attr_mod);
mlx4_ib_update_cache_on_guid_change(dev, bn, port_num,
(u8 *)(&((struct ib_smp *)mad)->data));
mlx4_ib_notify_slaves_on_guid_change(dev, bn, port_num,
(u8 *)(&((struct ib_smp *)mad)->data));
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
case IB_SMP_ATTR_SL_TO_VL_TABLE:
/* cache sl to vl mapping changes for use in
* filling QP1 LRH VL field when sending packets
*/
if (dev->dev->caps.flags & MLX4_DEV_CAP_FLAG_PORT_MNG_CHG_EV &&
dev->dev->caps.flags2 & MLX4_DEV_CAP_FLAG2_SL_TO_VL_CHANGE_EVENT)
return;
if (!mlx4_is_slave(dev->dev)) {
union sl2vl_tbl_to_u64 sl2vl64;
int jj;
for (jj = 0; jj < 8; jj++) {
sl2vl64.sl8[jj] = ((struct ib_smp *)mad)->data[jj];
pr_debug("port %u, sl2vl[%d] = %02x\n",
port_num, jj, sl2vl64.sl8[jj]);
}
atomic64_set(&dev->sl2vl[port_num - 1], sl2vl64.sl64);
}
break;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
default:
break;
}
}
static void __propagate_pkey_ev(struct mlx4_ib_dev *dev, int port_num,
int block, u32 change_bitmap)
{
int i, ix, slave, err;
int have_event = 0;
for (slave = 0; slave < dev->dev->caps.sqp_demux; slave++) {
if (slave == mlx4_master_func_num(dev->dev))
continue;
if (!mlx4_is_slave_active(dev->dev, slave))
continue;
have_event = 0;
for (i = 0; i < 32; i++) {
if (!(change_bitmap & (1 << i)))
continue;
for (ix = 0;
ix < dev->dev->caps.pkey_table_len[port_num]; ix++) {
if (dev->pkeys.virt2phys_pkey[slave][port_num - 1]
[ix] == i + 32 * block) {
err = mlx4_gen_pkey_eqe(dev->dev, slave, port_num);
pr_debug("propagate_pkey_ev: slave %d,"
" port %d, ix %d (%d)\n",
slave, port_num, ix, err);
have_event = 1;
break;
}
}
if (have_event)
break;
}
}
}
static void node_desc_override(struct ib_device *dev,
struct ib_mad *mad)
{
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
unsigned long flags;
if ((mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_LID_ROUTED ||
mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE) &&
mad->mad_hdr.method == IB_MGMT_METHOD_GET_RESP &&
mad->mad_hdr.attr_id == IB_SMP_ATTR_NODE_DESC) {
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_lock_irqsave(&to_mdev(dev)->sm_lock, flags);
memcpy(((struct ib_smp *) mad)->data, dev->node_desc,
IB_DEVICE_NODE_DESC_MAX);
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_unlock_irqrestore(&to_mdev(dev)->sm_lock, flags);
}
}
static void forward_trap(struct mlx4_ib_dev *dev, u8 port_num, const struct ib_mad *mad)
{
int qpn = mad->mad_hdr.mgmt_class != IB_MGMT_CLASS_SUBN_LID_ROUTED;
struct ib_mad_send_buf *send_buf;
struct ib_mad_agent *agent = dev->send_agent[port_num - 1][qpn];
int ret;
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
unsigned long flags;
if (agent) {
send_buf = ib_create_send_mad(agent, qpn, 0, 0, IB_MGMT_MAD_HDR,
IB_MGMT_MAD_DATA, GFP_ATOMIC,
IB_MGMT_BASE_VERSION);
if (IS_ERR(send_buf))
return;
/*
* We rely here on the fact that MLX QPs don't use the
* address handle after the send is posted (this is
* wrong following the IB spec strictly, but we know
* it's OK for our devices).
*/
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_lock_irqsave(&dev->sm_lock, flags);
memcpy(send_buf->mad, mad, sizeof *mad);
if ((send_buf->ah = dev->sm_ah[port_num - 1]))
ret = ib_post_send_mad(send_buf, NULL);
else
ret = -EINVAL;
IB/mlx4: Fix possible deadlock on sm_lock spinlock The sm_lock spinlock is taken in the process context by mlx4_ib_modify_device, and in the interrupt context by update_sm_ah, so we need to take that spinlock with irqsave, and release it with irqrestore. Lockdeps reports this as follows: [ INFO: inconsistent lock state ] 3.5.0+ #20 Not tainted inconsistent {HARDIRQ-ON-W} -> {IN-HARDIRQ-W} usage. swapper/0/0 [HC1[1]:SC0[0]:HE0:SE1] takes: (&(&ibdev->sm_lock)->rlock){?.+...}, at: [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] {HARDIRQ-ON-W} state was registered at: [<ffffffff810b84a0>] mark_irqflags+0x120/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028d563>] mlx4_ib_modify_device+0x63/0x240 [mlx4_ib] [<ffffffffa026d1fc>] ib_modify_device+0x1c/0x20 [ib_core] [<ffffffffa026c353>] set_node_desc+0x83/0xc0 [ib_core] [<ffffffff8136a150>] dev_attr_store+0x20/0x30 [<ffffffff81201fd6>] sysfs_write_file+0xe6/0x170 [<ffffffff8118da38>] vfs_write+0xc8/0x190 [<ffffffff8118dc01>] sys_write+0x51/0x90 [<ffffffff8155b869>] system_call_fastpath+0x16/0x1b ... *** DEADLOCK *** 1 lock held by swapper/0/0: stack backtrace: Pid: 0, comm: swapper/0 Not tainted 3.5.0+ #20 Call Trace: <IRQ> [<ffffffff810b7bea>] print_usage_bug+0x18a/0x190 [<ffffffff810b7370>] ? print_irq_inversion_bug+0x210/0x210 [<ffffffff810b7fb2>] mark_lock_irq+0xf2/0x280 [<ffffffff810b8290>] mark_lock+0x150/0x240 [<ffffffff810b84ef>] mark_irqflags+0x16f/0x190 [<ffffffff810b9ce7>] __lock_acquire+0x307/0x4c0 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810b9f51>] lock_acquire+0xb1/0x150 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff815523b1>] _raw_spin_lock+0x41/0x50 [<ffffffffa028af1d>] ? update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffffa026b2fa>] ? ib_create_ah+0x1a/0x40 [ib_core] [<ffffffffa028af1d>] update_sm_ah+0xad/0x100 [mlx4_ib] [<ffffffff810c27c3>] ? is_module_address+0x23/0x30 [<ffffffffa028b05b>] handle_port_mgmt_change_event+0xeb/0x150 [mlx4_ib] [<ffffffffa028c177>] mlx4_ib_event+0x117/0x160 [mlx4_ib] [<ffffffff81552501>] ? _raw_spin_lock_irqsave+0x61/0x70 [<ffffffffa022718c>] mlx4_dispatch_event+0x6c/0x90 [mlx4_core] [<ffffffffa0221b40>] mlx4_eq_int+0x500/0x950 [mlx4_core] Reported by: Or Gerlitz <ogerlitz@mellanox.com> Tested-by: Bart Van Assche <bvanassche@acm.org> Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:26:45 +08:00
spin_unlock_irqrestore(&dev->sm_lock, flags);
if (ret)
ib_free_send_mad(send_buf);
}
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
static int mlx4_ib_demux_sa_handler(struct ib_device *ibdev, int port, int slave,
struct ib_sa_mad *sa_mad)
{
int ret = 0;
/* dispatch to different sa handlers */
switch (be16_to_cpu(sa_mad->mad_hdr.attr_id)) {
case IB_SA_ATTR_MC_MEMBER_REC:
ret = mlx4_ib_mcg_demux_handler(ibdev, port, slave, sa_mad);
break;
default:
break;
}
return ret;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
int mlx4_ib_find_real_gid(struct ib_device *ibdev, u8 port, __be64 guid)
{
struct mlx4_ib_dev *dev = to_mdev(ibdev);
int i;
for (i = 0; i < dev->dev->caps.sqp_demux; i++) {
if (dev->sriov.demux[port - 1].guid_cache[i] == guid)
return i;
}
return -1;
}
static int find_slave_port_pkey_ix(struct mlx4_ib_dev *dev, int slave,
u8 port, u16 pkey, u16 *ix)
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
{
int i, ret;
u8 unassigned_pkey_ix, pkey_ix, partial_ix = 0xFF;
u16 slot_pkey;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (slave == mlx4_master_func_num(dev->dev))
return ib_find_cached_pkey(&dev->ib_dev, port, pkey, ix);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
unassigned_pkey_ix = dev->dev->phys_caps.pkey_phys_table_len[port] - 1;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
for (i = 0; i < dev->dev->caps.pkey_table_len[port]; i++) {
if (dev->pkeys.virt2phys_pkey[slave][port - 1][i] == unassigned_pkey_ix)
continue;
pkey_ix = dev->pkeys.virt2phys_pkey[slave][port - 1][i];
ret = ib_get_cached_pkey(&dev->ib_dev, port, pkey_ix, &slot_pkey);
if (ret)
continue;
if ((slot_pkey & 0x7FFF) == (pkey & 0x7FFF)) {
if (slot_pkey & 0x8000) {
*ix = (u16) pkey_ix;
return 0;
} else {
/* take first partial pkey index found */
if (partial_ix == 0xFF)
partial_ix = pkey_ix;
}
}
}
if (partial_ix < 0xFF) {
*ix = (u16) partial_ix;
return 0;
}
return -EINVAL;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
static int get_gids_from_l3_hdr(struct ib_grh *grh, union ib_gid *sgid,
union ib_gid *dgid)
{
int version = ib_get_rdma_header_version((const union rdma_network_hdr *)grh);
enum rdma_network_type net_type;
if (version == 4)
net_type = RDMA_NETWORK_IPV4;
else if (version == 6)
net_type = RDMA_NETWORK_IPV6;
else
return -EINVAL;
return ib_get_gids_from_rdma_hdr((union rdma_network_hdr *)grh, net_type,
sgid, dgid);
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
int mlx4_ib_send_to_slave(struct mlx4_ib_dev *dev, int slave, u8 port,
enum ib_qp_type dest_qpt, struct ib_wc *wc,
struct ib_grh *grh, struct ib_mad *mad)
{
struct ib_sge list;
struct ib_ud_wr wr;
struct ib_send_wr *bad_wr;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
struct mlx4_ib_demux_pv_ctx *tun_ctx;
struct mlx4_ib_demux_pv_qp *tun_qp;
struct mlx4_rcv_tunnel_mad *tun_mad;
struct rdma_ah_attr attr;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
struct ib_ah *ah;
struct ib_qp *src_qp = NULL;
unsigned tun_tx_ix = 0;
int dqpn;
int ret = 0;
u16 tun_pkey_ix;
u16 cached_pkey;
u8 is_eth = dev->dev->caps.port_type[port] == MLX4_PORT_TYPE_ETH;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (dest_qpt > IB_QPT_GSI)
return -EINVAL;
tun_ctx = dev->sriov.demux[port-1].tun[slave];
/* check if proxy qp created */
if (!tun_ctx || tun_ctx->state != DEMUX_PV_STATE_ACTIVE)
return -EAGAIN;
if (!dest_qpt)
tun_qp = &tun_ctx->qp[0];
else
tun_qp = &tun_ctx->qp[1];
/* compute P_Key index to put in tunnel header for slave */
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (dest_qpt) {
u16 pkey_ix;
ret = ib_get_cached_pkey(&dev->ib_dev, port, wc->pkey_index, &cached_pkey);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (ret)
return -EINVAL;
ret = find_slave_port_pkey_ix(dev, slave, port, cached_pkey, &pkey_ix);
if (ret)
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
return -EINVAL;
tun_pkey_ix = pkey_ix;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
} else
tun_pkey_ix = dev->pkeys.virt2phys_pkey[slave][port - 1][0];
dqpn = dev->dev->phys_caps.base_proxy_sqpn + 8 * slave + port + (dest_qpt * 2) - 1;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
/* get tunnel tx data buf for slave */
src_qp = tun_qp->qp;
/* create ah. Just need an empty one with the port num for the post send.
* The driver will set the force loopback bit in post_send */
memset(&attr, 0, sizeof attr);
attr.type = rdma_ah_find_type(&dev->ib_dev, port);
rdma_ah_set_port_num(&attr, port);
if (is_eth) {
union ib_gid sgid;
union ib_gid dgid;
if (get_gids_from_l3_hdr(grh, &sgid, &dgid))
return -EINVAL;
rdma_ah_set_grh(&attr, &dgid, 0, 0, 0, 0);
}
ah = rdma_create_ah(tun_ctx->pd, &attr);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (IS_ERR(ah))
return -ENOMEM;
/* allocate tunnel tx buf after pass failure returns */
spin_lock(&tun_qp->tx_lock);
if (tun_qp->tx_ix_head - tun_qp->tx_ix_tail >=
(MLX4_NUM_TUNNEL_BUFS - 1))
ret = -EAGAIN;
else
tun_tx_ix = (++tun_qp->tx_ix_head) & (MLX4_NUM_TUNNEL_BUFS - 1);
spin_unlock(&tun_qp->tx_lock);
if (ret)
goto end;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
tun_mad = (struct mlx4_rcv_tunnel_mad *) (tun_qp->tx_ring[tun_tx_ix].buf.addr);
if (tun_qp->tx_ring[tun_tx_ix].ah)
rdma_destroy_ah(tun_qp->tx_ring[tun_tx_ix].ah);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
tun_qp->tx_ring[tun_tx_ix].ah = ah;
ib_dma_sync_single_for_cpu(&dev->ib_dev,
tun_qp->tx_ring[tun_tx_ix].buf.map,
sizeof (struct mlx4_rcv_tunnel_mad),
DMA_TO_DEVICE);
/* copy over to tunnel buffer */
if (grh)
memcpy(&tun_mad->grh, grh, sizeof *grh);
memcpy(&tun_mad->mad, mad, sizeof *mad);
/* adjust tunnel data */
tun_mad->hdr.pkey_index = cpu_to_be16(tun_pkey_ix);
tun_mad->hdr.flags_src_qp = cpu_to_be32(wc->src_qp & 0xFFFFFF);
tun_mad->hdr.g_ml_path = (grh && (wc->wc_flags & IB_WC_GRH)) ? 0x80 : 0;
if (is_eth) {
u16 vlan = 0;
if (mlx4_get_slave_default_vlan(dev->dev, port, slave, &vlan,
NULL)) {
/* VST mode */
if (vlan != wc->vlan_id)
/* Packet vlan is not the VST-assigned vlan.
* Drop the packet.
*/
goto out;
else
/* Remove the vlan tag before forwarding
* the packet to the VF.
*/
vlan = 0xffff;
} else {
vlan = wc->vlan_id;
}
tun_mad->hdr.sl_vid = cpu_to_be16(vlan);
memcpy((char *)&tun_mad->hdr.mac_31_0, &(wc->smac[0]), 4);
memcpy((char *)&tun_mad->hdr.slid_mac_47_32, &(wc->smac[4]), 2);
} else {
tun_mad->hdr.sl_vid = cpu_to_be16(((u16)(wc->sl)) << 12);
tun_mad->hdr.slid_mac_47_32 = ib_lid_be16(wc->slid);
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
ib_dma_sync_single_for_device(&dev->ib_dev,
tun_qp->tx_ring[tun_tx_ix].buf.map,
sizeof (struct mlx4_rcv_tunnel_mad),
DMA_TO_DEVICE);
list.addr = tun_qp->tx_ring[tun_tx_ix].buf.map;
list.length = sizeof (struct mlx4_rcv_tunnel_mad);
list.lkey = tun_ctx->pd->local_dma_lkey;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
wr.ah = ah;
wr.port_num = port;
wr.remote_qkey = IB_QP_SET_QKEY;
wr.remote_qpn = dqpn;
wr.wr.next = NULL;
wr.wr.wr_id = ((u64) tun_tx_ix) | MLX4_TUN_SET_WRID_QPN(dest_qpt);
wr.wr.sg_list = &list;
wr.wr.num_sge = 1;
wr.wr.opcode = IB_WR_SEND;
wr.wr.send_flags = IB_SEND_SIGNALED;
ret = ib_post_send(src_qp, &wr.wr, &bad_wr);
if (!ret)
return 0;
out:
spin_lock(&tun_qp->tx_lock);
tun_qp->tx_ix_tail++;
spin_unlock(&tun_qp->tx_lock);
tun_qp->tx_ring[tun_tx_ix].ah = NULL;
end:
rdma_destroy_ah(ah);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
return ret;
}
static int mlx4_ib_demux_mad(struct ib_device *ibdev, u8 port,
struct ib_wc *wc, struct ib_grh *grh,
struct ib_mad *mad)
{
struct mlx4_ib_dev *dev = to_mdev(ibdev);
int err, other_port;
int slave = -1;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
u8 *slave_id;
int is_eth = 0;
if (rdma_port_get_link_layer(ibdev, port) == IB_LINK_LAYER_INFINIBAND)
is_eth = 0;
else
is_eth = 1;
if (is_eth) {
union ib_gid dgid;
union ib_gid sgid;
if (get_gids_from_l3_hdr(grh, &sgid, &dgid))
return -EINVAL;
if (!(wc->wc_flags & IB_WC_GRH)) {
mlx4_ib_warn(ibdev, "RoCE grh not present.\n");
return -EINVAL;
}
if (mad->mad_hdr.mgmt_class != IB_MGMT_CLASS_CM) {
mlx4_ib_warn(ibdev, "RoCE mgmt class is not CM\n");
return -EINVAL;
}
err = mlx4_get_slave_from_roce_gid(dev->dev, port, dgid.raw, &slave);
if (err && mlx4_is_mf_bonded(dev->dev)) {
other_port = (port == 1) ? 2 : 1;
err = mlx4_get_slave_from_roce_gid(dev->dev, other_port, dgid.raw, &slave);
if (!err) {
port = other_port;
pr_debug("resolved slave %d from gid %pI6 wire port %d other %d\n",
slave, grh->dgid.raw, port, other_port);
}
}
if (err) {
mlx4_ib_warn(ibdev, "failed matching grh\n");
return -ENOENT;
}
if (slave >= dev->dev->caps.sqp_demux) {
mlx4_ib_warn(ibdev, "slave id: %d is bigger than allowed:%d\n",
slave, dev->dev->caps.sqp_demux);
return -ENOENT;
}
if (mlx4_ib_demux_cm_handler(ibdev, port, NULL, mad))
return 0;
err = mlx4_ib_send_to_slave(dev, slave, port, wc->qp->qp_type, wc, grh, mad);
if (err)
pr_debug("failed sending to slave %d via tunnel qp (%d)\n",
slave, err);
return 0;
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
/* Initially assume that this mad is for us */
slave = mlx4_master_func_num(dev->dev);
/* See if the slave id is encoded in a response mad */
if (mad->mad_hdr.method & 0x80) {
slave_id = (u8 *) &mad->mad_hdr.tid;
slave = *slave_id;
if (slave != 255) /*255 indicates the dom0*/
*slave_id = 0; /* remap tid */
}
/* If a grh is present, we demux according to it */
if (wc->wc_flags & IB_WC_GRH) {
if (grh->dgid.global.interface_id ==
cpu_to_be64(IB_SA_WELL_KNOWN_GUID) &&
grh->dgid.global.subnet_prefix == cpu_to_be64(
atomic64_read(&dev->sriov.demux[port - 1].subnet_prefix))) {
slave = 0;
} else {
slave = mlx4_ib_find_real_gid(ibdev, port,
grh->dgid.global.interface_id);
if (slave < 0) {
mlx4_ib_warn(ibdev, "failed matching grh\n");
return -ENOENT;
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
}
/* Class-specific handling */
switch (mad->mad_hdr.mgmt_class) {
case IB_MGMT_CLASS_SUBN_LID_ROUTED:
case IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE:
/* 255 indicates the dom0 */
if (slave != 255 && slave != mlx4_master_func_num(dev->dev)) {
if (!mlx4_vf_smi_enabled(dev->dev, slave, port))
return -EPERM;
/* for a VF. drop unsolicited MADs */
if (!(mad->mad_hdr.method & IB_MGMT_METHOD_RESP)) {
mlx4_ib_warn(ibdev, "demux QP0. rejecting unsolicited mad for slave %d class 0x%x, method 0x%x\n",
slave, mad->mad_hdr.mgmt_class,
mad->mad_hdr.method);
return -EINVAL;
}
}
break;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
case IB_MGMT_CLASS_SUBN_ADM:
if (mlx4_ib_demux_sa_handler(ibdev, port, slave,
(struct ib_sa_mad *) mad))
return 0;
break;
case IB_MGMT_CLASS_CM:
if (mlx4_ib_demux_cm_handler(ibdev, port, &slave, mad))
return 0;
break;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
case IB_MGMT_CLASS_DEVICE_MGMT:
if (mad->mad_hdr.method != IB_MGMT_METHOD_GET_RESP)
return 0;
break;
default:
/* Drop unsupported classes for slaves in tunnel mode */
if (slave != mlx4_master_func_num(dev->dev)) {
pr_debug("dropping unsupported ingress mad from class:%d "
"for slave:%d\n", mad->mad_hdr.mgmt_class, slave);
return 0;
}
}
/*make sure that no slave==255 was not handled yet.*/
if (slave >= dev->dev->caps.sqp_demux) {
mlx4_ib_warn(ibdev, "slave id: %d is bigger than allowed:%d\n",
slave, dev->dev->caps.sqp_demux);
return -ENOENT;
}
err = mlx4_ib_send_to_slave(dev, slave, port, wc->qp->qp_type, wc, grh, mad);
if (err)
pr_debug("failed sending to slave %d via tunnel qp (%d)\n",
slave, err);
return 0;
}
static int ib_process_mad(struct ib_device *ibdev, int 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)
{
u16 slid, prev_lid = 0;
int err;
struct ib_port_attr pattr;
if (in_wc && in_wc->qp->qp_num) {
pr_debug("received MAD: slid:%d sqpn:%d "
"dlid_bits:%d dqpn:%d wc_flags:0x%x, cls %x, mtd %x, atr %x\n",
in_wc->slid, in_wc->src_qp,
in_wc->dlid_path_bits,
in_wc->qp->qp_num,
in_wc->wc_flags,
in_mad->mad_hdr.mgmt_class, in_mad->mad_hdr.method,
be16_to_cpu(in_mad->mad_hdr.attr_id));
if (in_wc->wc_flags & IB_WC_GRH) {
pr_debug("sgid_hi:0x%016llx sgid_lo:0x%016llx\n",
be64_to_cpu(in_grh->sgid.global.subnet_prefix),
be64_to_cpu(in_grh->sgid.global.interface_id));
pr_debug("dgid_hi:0x%016llx dgid_lo:0x%016llx\n",
be64_to_cpu(in_grh->dgid.global.subnet_prefix),
be64_to_cpu(in_grh->dgid.global.interface_id));
}
}
slid = in_wc ? ib_lid_cpu16(in_wc->slid) : be16_to_cpu(IB_LID_PERMISSIVE);
if (in_mad->mad_hdr.method == IB_MGMT_METHOD_TRAP && slid == 0) {
forward_trap(to_mdev(ibdev), port_num, in_mad);
return IB_MAD_RESULT_SUCCESS | IB_MAD_RESULT_CONSUMED;
}
if (in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_LID_ROUTED ||
in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE) {
if (in_mad->mad_hdr.method != IB_MGMT_METHOD_GET &&
in_mad->mad_hdr.method != IB_MGMT_METHOD_SET &&
in_mad->mad_hdr.method != IB_MGMT_METHOD_TRAP_REPRESS)
return IB_MAD_RESULT_SUCCESS;
/*
IB/mlx4: pass SMP vendor-specific attribute MADs to firmware In the current code, vendor-specific MADs (e.g with the FDR-10 attribute) are silently dropped by the driver, resulting in timeouts at the sending side and inability to query/configure the relevant feature. However, the ConnectX firmware is able to handle such MADs. For unsupported attributes, the firmware returns a GET_RESPONSE MAD containing an error status. For example, for a FDR-10 node with LID 11: # ibstat mlx4_0 1 CA: 'mlx4_0' Port 1: State: Active Physical state: LinkUp Rate: 40 (FDR10) Base lid: 11 LMC: 0 SM lid: 24 Capability mask: 0x02514868 Port GUID: 0x0002c903002e65d1 Link layer: InfiniBand Extended Port Query (EPI) vendor mad timeouts before the patch: # smpquery MEPI 11 -d ibwarn: [4196] smp_query_via: attr 0xff90 mod 0x0 route Lid 11 ibwarn: [4196] _do_madrpc: retry 1 (timeout 1000 ms) ibwarn: [4196] _do_madrpc: retry 2 (timeout 1000 ms) ibwarn: [4196] _do_madrpc: timeout after 3 retries, 3000 ms ibwarn: [4196] mad_rpc: _do_madrpc failed; dport (Lid 11) smpquery: iberror: [pid 4196] main: failed: operation EPI: ext port info query failed EPI query works OK with the patch: # smpquery MEPI 11 -d ibwarn: [6548] smp_query_via: attr 0xff90 mod 0x0 route Lid 11 ibwarn: [6548] mad_rpc: data offs 64 sz 64 mad data 0000 0000 0000 0001 0000 0001 0000 0001 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 # Ext Port info: Lid 11 port 0 StateChangeEnable:...............0x00 LinkSpeedSupported:..............0x01 LinkSpeedEnabled:................0x01 LinkSpeedActive:.................0x01 Signed-off-by: Jack Morgenstein <jackm@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Acked-by: Ira Weiny <weiny2@llnl.gov> Cc: <stable@vger.kernel.org> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-01-26 22:41:33 +08:00
* Don't process SMInfo queries -- the SMA can't handle them.
*/
IB/mlx4: pass SMP vendor-specific attribute MADs to firmware In the current code, vendor-specific MADs (e.g with the FDR-10 attribute) are silently dropped by the driver, resulting in timeouts at the sending side and inability to query/configure the relevant feature. However, the ConnectX firmware is able to handle such MADs. For unsupported attributes, the firmware returns a GET_RESPONSE MAD containing an error status. For example, for a FDR-10 node with LID 11: # ibstat mlx4_0 1 CA: 'mlx4_0' Port 1: State: Active Physical state: LinkUp Rate: 40 (FDR10) Base lid: 11 LMC: 0 SM lid: 24 Capability mask: 0x02514868 Port GUID: 0x0002c903002e65d1 Link layer: InfiniBand Extended Port Query (EPI) vendor mad timeouts before the patch: # smpquery MEPI 11 -d ibwarn: [4196] smp_query_via: attr 0xff90 mod 0x0 route Lid 11 ibwarn: [4196] _do_madrpc: retry 1 (timeout 1000 ms) ibwarn: [4196] _do_madrpc: retry 2 (timeout 1000 ms) ibwarn: [4196] _do_madrpc: timeout after 3 retries, 3000 ms ibwarn: [4196] mad_rpc: _do_madrpc failed; dport (Lid 11) smpquery: iberror: [pid 4196] main: failed: operation EPI: ext port info query failed EPI query works OK with the patch: # smpquery MEPI 11 -d ibwarn: [6548] smp_query_via: attr 0xff90 mod 0x0 route Lid 11 ibwarn: [6548] mad_rpc: data offs 64 sz 64 mad data 0000 0000 0000 0001 0000 0001 0000 0001 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 # Ext Port info: Lid 11 port 0 StateChangeEnable:...............0x00 LinkSpeedSupported:..............0x01 LinkSpeedEnabled:................0x01 LinkSpeedActive:.................0x01 Signed-off-by: Jack Morgenstein <jackm@mellanox.com> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Acked-by: Ira Weiny <weiny2@llnl.gov> Cc: <stable@vger.kernel.org> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-01-26 22:41:33 +08:00
if (in_mad->mad_hdr.attr_id == IB_SMP_ATTR_SM_INFO)
return IB_MAD_RESULT_SUCCESS;
} else if (in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_PERF_MGMT ||
in_mad->mad_hdr.mgmt_class == MLX4_IB_VENDOR_CLASS1 ||
in_mad->mad_hdr.mgmt_class == MLX4_IB_VENDOR_CLASS2 ||
in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_CONG_MGMT) {
if (in_mad->mad_hdr.method != IB_MGMT_METHOD_GET &&
in_mad->mad_hdr.method != IB_MGMT_METHOD_SET)
return IB_MAD_RESULT_SUCCESS;
} else
return IB_MAD_RESULT_SUCCESS;
if ((in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_LID_ROUTED ||
in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE) &&
in_mad->mad_hdr.method == IB_MGMT_METHOD_SET &&
in_mad->mad_hdr.attr_id == IB_SMP_ATTR_PORT_INFO &&
!ib_query_port(ibdev, port_num, &pattr))
prev_lid = ib_lid_cpu16(pattr.lid);
err = mlx4_MAD_IFC(to_mdev(ibdev),
(mad_flags & IB_MAD_IGNORE_MKEY ? MLX4_MAD_IFC_IGNORE_MKEY : 0) |
(mad_flags & IB_MAD_IGNORE_BKEY ? MLX4_MAD_IFC_IGNORE_BKEY : 0) |
MLX4_MAD_IFC_NET_VIEW,
port_num, in_wc, in_grh, in_mad, out_mad);
if (err)
return IB_MAD_RESULT_FAILURE;
if (!out_mad->mad_hdr.status) {
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
smp_snoop(ibdev, port_num, in_mad, prev_lid);
/* slaves get node desc from FW */
if (!mlx4_is_slave(to_mdev(ibdev)->dev))
node_desc_override(ibdev, out_mad);
}
/* set return bit in status of directed route responses */
if (in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE)
out_mad->mad_hdr.status |= cpu_to_be16(1 << 15);
if (in_mad->mad_hdr.method == IB_MGMT_METHOD_TRAP_REPRESS)
/* no response for trap repress */
return IB_MAD_RESULT_SUCCESS | IB_MAD_RESULT_CONSUMED;
return IB_MAD_RESULT_SUCCESS | IB_MAD_RESULT_REPLY;
}
static void edit_counter(struct mlx4_counter *cnt, void *counters,
__be16 attr_id)
{
switch (attr_id) {
case IB_PMA_PORT_COUNTERS:
{
struct ib_pma_portcounters *pma_cnt =
(struct ib_pma_portcounters *)counters;
ASSIGN_32BIT_COUNTER(pma_cnt->port_xmit_data,
(be64_to_cpu(cnt->tx_bytes) >> 2));
ASSIGN_32BIT_COUNTER(pma_cnt->port_rcv_data,
(be64_to_cpu(cnt->rx_bytes) >> 2));
ASSIGN_32BIT_COUNTER(pma_cnt->port_xmit_packets,
be64_to_cpu(cnt->tx_frames));
ASSIGN_32BIT_COUNTER(pma_cnt->port_rcv_packets,
be64_to_cpu(cnt->rx_frames));
break;
}
case IB_PMA_PORT_COUNTERS_EXT:
{
struct ib_pma_portcounters_ext *pma_cnt_ext =
(struct ib_pma_portcounters_ext *)counters;
pma_cnt_ext->port_xmit_data =
cpu_to_be64(be64_to_cpu(cnt->tx_bytes) >> 2);
pma_cnt_ext->port_rcv_data =
cpu_to_be64(be64_to_cpu(cnt->rx_bytes) >> 2);
pma_cnt_ext->port_xmit_packets = cnt->tx_frames;
pma_cnt_ext->port_rcv_packets = cnt->rx_frames;
break;
}
}
}
static int iboe_process_mad_port_info(void *out_mad)
{
struct ib_class_port_info cpi = {};
cpi.capability_mask = IB_PMA_CLASS_CAP_EXT_WIDTH;
memcpy(out_mad, &cpi, sizeof(cpi));
return IB_MAD_RESULT_SUCCESS | IB_MAD_RESULT_REPLY;
}
static int iboe_process_mad(struct ib_device *ibdev, int 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 mlx4_counter counter_stats;
struct mlx4_ib_dev *dev = to_mdev(ibdev);
struct counter_index *tmp_counter;
int err = IB_MAD_RESULT_FAILURE, stats_avail = 0;
if (in_mad->mad_hdr.mgmt_class != IB_MGMT_CLASS_PERF_MGMT)
return -EINVAL;
if (in_mad->mad_hdr.attr_id == IB_PMA_CLASS_PORT_INFO)
return iboe_process_mad_port_info((void *)(out_mad->data + 40));
memset(&counter_stats, 0, sizeof(counter_stats));
mutex_lock(&dev->counters_table[port_num - 1].mutex);
list_for_each_entry(tmp_counter,
&dev->counters_table[port_num - 1].counters_list,
list) {
err = mlx4_get_counter_stats(dev->dev,
tmp_counter->index,
&counter_stats, 0);
if (err) {
err = IB_MAD_RESULT_FAILURE;
stats_avail = 0;
break;
}
stats_avail = 1;
}
mutex_unlock(&dev->counters_table[port_num - 1].mutex);
if (stats_avail) {
memset(out_mad->data, 0, sizeof out_mad->data);
switch (counter_stats.counter_mode & 0xf) {
case 0:
edit_counter(&counter_stats,
(void *)(out_mad->data + 40),
in_mad->mad_hdr.attr_id);
err = IB_MAD_RESULT_SUCCESS | IB_MAD_RESULT_REPLY;
break;
default:
err = IB_MAD_RESULT_FAILURE;
}
}
return err;
}
int mlx4_ib_process_mad(struct ib_device *ibdev, int mad_flags, u8 port_num,
const struct ib_wc *in_wc, const struct ib_grh *in_grh,
const struct ib_mad_hdr *in, size_t in_mad_size,
struct ib_mad_hdr *out, size_t *out_mad_size,
u16 *out_mad_pkey_index)
{
struct mlx4_ib_dev *dev = to_mdev(ibdev);
const struct ib_mad *in_mad = (const struct ib_mad *)in;
struct ib_mad *out_mad = (struct ib_mad *)out;
enum rdma_link_layer link = rdma_port_get_link_layer(ibdev, port_num);
if (WARN_ON_ONCE(in_mad_size != sizeof(*in_mad) ||
*out_mad_size != sizeof(*out_mad)))
return IB_MAD_RESULT_FAILURE;
/* iboe_process_mad() which uses the HCA flow-counters to implement IB PMA
* queries, should be called only by VFs and for that specific purpose
*/
if (link == IB_LINK_LAYER_INFINIBAND) {
if (mlx4_is_slave(dev->dev) &&
(in_mad->mad_hdr.mgmt_class == IB_MGMT_CLASS_PERF_MGMT &&
(in_mad->mad_hdr.attr_id == IB_PMA_PORT_COUNTERS ||
in_mad->mad_hdr.attr_id == IB_PMA_PORT_COUNTERS_EXT ||
in_mad->mad_hdr.attr_id == IB_PMA_CLASS_PORT_INFO)))
return iboe_process_mad(ibdev, mad_flags, port_num, in_wc,
in_grh, in_mad, out_mad);
return ib_process_mad(ibdev, mad_flags, port_num, in_wc,
in_grh, in_mad, out_mad);
}
if (link == IB_LINK_LAYER_ETHERNET)
return iboe_process_mad(ibdev, mad_flags, port_num, in_wc,
in_grh, in_mad, out_mad);
return -EINVAL;
}
static void send_handler(struct ib_mad_agent *agent,
struct ib_mad_send_wc *mad_send_wc)
{
if (mad_send_wc->send_buf->context[0])
rdma_destroy_ah(mad_send_wc->send_buf->context[0]);
ib_free_send_mad(mad_send_wc->send_buf);
}
int mlx4_ib_mad_init(struct mlx4_ib_dev *dev)
{
struct ib_mad_agent *agent;
int p, q;
int ret;
enum rdma_link_layer ll;
for (p = 0; p < dev->num_ports; ++p) {
ll = rdma_port_get_link_layer(&dev->ib_dev, p + 1);
for (q = 0; q <= 1; ++q) {
if (ll == IB_LINK_LAYER_INFINIBAND) {
agent = ib_register_mad_agent(&dev->ib_dev, p + 1,
q ? IB_QPT_GSI : IB_QPT_SMI,
NULL, 0, send_handler,
NULL, NULL, 0);
if (IS_ERR(agent)) {
ret = PTR_ERR(agent);
goto err;
}
dev->send_agent[p][q] = agent;
} else
dev->send_agent[p][q] = NULL;
}
}
return 0;
err:
for (p = 0; p < dev->num_ports; ++p)
for (q = 0; q <= 1; ++q)
if (dev->send_agent[p][q])
ib_unregister_mad_agent(dev->send_agent[p][q]);
return ret;
}
void mlx4_ib_mad_cleanup(struct mlx4_ib_dev *dev)
{
struct ib_mad_agent *agent;
int p, q;
for (p = 0; p < dev->num_ports; ++p) {
for (q = 0; q <= 1; ++q) {
agent = dev->send_agent[p][q];
if (agent) {
dev->send_agent[p][q] = NULL;
ib_unregister_mad_agent(agent);
}
}
if (dev->sm_ah[p])
rdma_destroy_ah(dev->sm_ah[p]);
}
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
static void handle_lid_change_event(struct mlx4_ib_dev *dev, u8 port_num)
{
mlx4_ib_dispatch_event(dev, port_num, IB_EVENT_LID_CHANGE);
if (mlx4_is_master(dev->dev) && !dev->sriov.is_going_down)
mlx4_gen_slaves_port_mgt_ev(dev->dev, port_num,
MLX4_EQ_PORT_INFO_LID_CHANGE_MASK);
}
static void handle_client_rereg_event(struct mlx4_ib_dev *dev, u8 port_num)
{
/* re-configure the alias-guid and mcg's */
if (mlx4_is_master(dev->dev)) {
mlx4_ib_invalidate_all_guid_record(dev, port_num);
if (!dev->sriov.is_going_down) {
mlx4_ib_mcg_port_cleanup(&dev->sriov.demux[port_num - 1], 0);
mlx4_gen_slaves_port_mgt_ev(dev->dev, port_num,
MLX4_EQ_PORT_INFO_CLIENT_REREG_MASK);
}
}
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
/* Update the sl to vl table from inside client rereg
* only if in secure-host mode (snooping is not possible)
* and the sl-to-vl change event is not generated by FW.
*/
if (!mlx4_is_slave(dev->dev) &&
dev->dev->flags & MLX4_FLAG_SECURE_HOST &&
!(dev->dev->caps.flags2 & MLX4_DEV_CAP_FLAG2_SL_TO_VL_CHANGE_EVENT)) {
if (mlx4_is_master(dev->dev))
/* already in work queue from mlx4_ib_event queueing
* mlx4_handle_port_mgmt_change_event, which calls
* this procedure. Therefore, call sl2vl_update directly.
*/
mlx4_ib_sl2vl_update(dev, port_num);
else
mlx4_sched_ib_sl2vl_update_work(dev, port_num);
}
mlx4_ib_dispatch_event(dev, port_num, IB_EVENT_CLIENT_REREGISTER);
}
static void propagate_pkey_ev(struct mlx4_ib_dev *dev, int port_num,
struct mlx4_eqe *eqe)
{
__propagate_pkey_ev(dev, port_num, GET_BLK_PTR_FROM_EQE(eqe),
GET_MASK_FROM_EQE(eqe));
}
static void handle_slaves_guid_change(struct mlx4_ib_dev *dev, u8 port_num,
u32 guid_tbl_blk_num, u32 change_bitmap)
{
struct ib_smp *in_mad = NULL;
struct ib_smp *out_mad = NULL;
u16 i;
if (!mlx4_is_mfunc(dev->dev) || !mlx4_is_master(dev->dev))
return;
in_mad = kmalloc(sizeof *in_mad, GFP_KERNEL);
out_mad = kmalloc(sizeof *out_mad, GFP_KERNEL);
if (!in_mad || !out_mad)
goto out;
guid_tbl_blk_num *= 4;
for (i = 0; i < 4; i++) {
if (change_bitmap && (!((change_bitmap >> (8 * i)) & 0xff)))
continue;
memset(in_mad, 0, sizeof *in_mad);
memset(out_mad, 0, sizeof *out_mad);
in_mad->base_version = 1;
in_mad->mgmt_class = IB_MGMT_CLASS_SUBN_LID_ROUTED;
in_mad->class_version = 1;
in_mad->method = IB_MGMT_METHOD_GET;
in_mad->attr_id = IB_SMP_ATTR_GUID_INFO;
in_mad->attr_mod = cpu_to_be32(guid_tbl_blk_num + i);
if (mlx4_MAD_IFC(dev,
MLX4_MAD_IFC_IGNORE_KEYS | MLX4_MAD_IFC_NET_VIEW,
port_num, NULL, NULL, in_mad, out_mad)) {
mlx4_ib_warn(&dev->ib_dev, "Failed in get GUID INFO MAD_IFC\n");
goto out;
}
mlx4_ib_update_cache_on_guid_change(dev, guid_tbl_blk_num + i,
port_num,
(u8 *)(&((struct ib_smp *)out_mad)->data));
mlx4_ib_notify_slaves_on_guid_change(dev, guid_tbl_blk_num + i,
port_num,
(u8 *)(&((struct ib_smp *)out_mad)->data));
}
out:
kfree(in_mad);
kfree(out_mad);
return;
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
void handle_port_mgmt_change_event(struct work_struct *work)
{
struct ib_event_work *ew = container_of(work, struct ib_event_work, work);
struct mlx4_ib_dev *dev = ew->ib_dev;
struct mlx4_eqe *eqe = &(ew->ib_eqe);
u8 port = eqe->event.port_mgmt_change.port;
u32 changed_attr;
u32 tbl_block;
u32 change_bitmap;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
switch (eqe->subtype) {
case MLX4_DEV_PMC_SUBTYPE_PORT_INFO:
changed_attr = be32_to_cpu(eqe->event.port_mgmt_change.params.port_info.changed_attr);
/* Update the SM ah - This should be done before handling
the other changed attributes so that MADs can be sent to the SM */
if (changed_attr & MSTR_SM_CHANGE_MASK) {
u16 lid = be16_to_cpu(eqe->event.port_mgmt_change.params.port_info.mstr_sm_lid);
u8 sl = eqe->event.port_mgmt_change.params.port_info.mstr_sm_sl & 0xf;
update_sm_ah(dev, port, lid, sl);
}
/* Check if it is a lid change event */
if (changed_attr & MLX4_EQ_PORT_INFO_LID_CHANGE_MASK)
handle_lid_change_event(dev, port);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
/* Generate GUID changed event */
if (changed_attr & MLX4_EQ_PORT_INFO_GID_PFX_CHANGE_MASK) {
IB/mlx4: Use correct subnet-prefix in QP1 mads under SR-IOV When sending QP1 MAD packets which use a GRH, the source GID (which consists of the 64-bit subnet prefix, and the 64 bit port GUID) must be included in the packet GRH. For SR-IOV, a GID cache is used, since the source GID needs to be the slave's source GID, and not the Hypervisor's GID. This cache also included a subnet_prefix. Unfortunately, the subnet_prefix field in the cache was never initialized (to the default subnet prefix 0xfe80::0). As a result, this field remained all zeroes. Therefore, when SR-IOV was active, all QP1 packets which included a GRH had a source GID subnet prefix of all-zeroes. However, the subnet-prefix should initially be 0xfe80::0 (the default subnet prefix). In addition, if OpenSM modifies a port's subnet prefix, the new subnet prefix must be used in the GRH when sending QP1 packets. To fix this we now initialize the subnet prefix in the SR-IOV GID cache to the default subnet prefix. We update the cached value if/when OpenSM modifies the port's subnet prefix. We take this cached value when sending QP1 packets when SR-IOV is active. Note that the value is stored as an atomic64. This eliminates any need for locking when the subnet prefix is being updated. Note also that we depend on the FW generating the "port management change" event for tracking subnet-prefix changes performed by OpenSM. If running early FW (before 2.9.4630), subnet prefix changes will not be tracked (but the default subnet prefix still will be stored in the cache; therefore users who do not modify the subnet prefix will not have a problem). IF there is a need for such tracking also for early FW, we will add that capability in a subsequent patch. Fixes: 1ffeb2eb8be9 ("IB/mlx4: SR-IOV IB context objects and proxy/tunnel SQP support") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:20 +08:00
if (mlx4_is_master(dev->dev)) {
union ib_gid gid;
int err = 0;
if (!eqe->event.port_mgmt_change.params.port_info.gid_prefix)
err = __mlx4_ib_query_gid(&dev->ib_dev, port, 0, &gid, 1);
else
gid.global.subnet_prefix =
eqe->event.port_mgmt_change.params.port_info.gid_prefix;
if (err) {
pr_warn("Could not change QP1 subnet prefix for port %d: query_gid error (%d)\n",
port, err);
} else {
pr_debug("Changing QP1 subnet prefix for port %d. old=0x%llx. new=0x%llx\n",
port,
(u64)atomic64_read(&dev->sriov.demux[port - 1].subnet_prefix),
be64_to_cpu(gid.global.subnet_prefix));
atomic64_set(&dev->sriov.demux[port - 1].subnet_prefix,
be64_to_cpu(gid.global.subnet_prefix));
}
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
mlx4_ib_dispatch_event(dev, port, IB_EVENT_GID_CHANGE);
/*if master, notify all slaves*/
if (mlx4_is_master(dev->dev))
mlx4_gen_slaves_port_mgt_ev(dev->dev, port,
MLX4_EQ_PORT_INFO_GID_PFX_CHANGE_MASK);
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
if (changed_attr & MLX4_EQ_PORT_INFO_CLIENT_REREG_MASK)
handle_client_rereg_event(dev, port);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
case MLX4_DEV_PMC_SUBTYPE_PKEY_TABLE:
mlx4_ib_dispatch_event(dev, port, IB_EVENT_PKEY_CHANGE);
if (mlx4_is_master(dev->dev) && !dev->sriov.is_going_down)
propagate_pkey_ev(dev, port, eqe);
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
case MLX4_DEV_PMC_SUBTYPE_GUID_INFO:
/* paravirtualized master's guid is guid 0 -- does not change */
if (!mlx4_is_master(dev->dev))
mlx4_ib_dispatch_event(dev, port, IB_EVENT_GID_CHANGE);
/*if master, notify relevant slaves*/
else if (!dev->sriov.is_going_down) {
tbl_block = GET_BLK_PTR_FROM_EQE(eqe);
change_bitmap = GET_MASK_FROM_EQE(eqe);
handle_slaves_guid_change(dev, port, tbl_block, change_bitmap);
}
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
break;
IB/mlx4: Fix possible vl/sl field mismatch in LRH header in QP1 packets In MLX qp packets, the LRH (built by the driver) has both a VL field and an SL field. When building a QP1 packet, the VL field should reflect the SLtoVL mapping and not arbitrarily contain zero (as is done now). This bug causes credit problems in IB switches at high rates of QP1 packets. The fix is to cache the SL to VL mapping in the driver, and look up the VL mapped to the SL provided in the send request when sending QP1 packets. For FW versions which support generating a port_management_config_change event with subtype sl-to-vl-table-change, the driver uses that event to update its sl-to-vl mapping cache. Otherwise, the driver snoops incoming SMP mads to update the cache. There remains the case where the FW is running in secure-host mode (so no QP0 packets are delivered to the driver), and the FW does not generate the sl2vl mapping change event. To support this case, the driver updates (via querying the FW) its sl2vl mapping cache when running in secure-host mode when it receives either a Port Up event or a client-reregister event (where the port is still up, but there may have been an opensm failover). OpenSM modifies the sl2vl mapping before Port Up and Client-reregister events occur, so if there is a mapping change the driver's cache will be properly updated. Fixes: 225c7b1feef1 ("IB/mlx4: Add a driver Mellanox ConnectX InfiniBand adapters") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:21 +08:00
case MLX4_DEV_PMC_SUBTYPE_SL_TO_VL_MAP:
/* cache sl to vl mapping changes for use in
* filling QP1 LRH VL field when sending packets
*/
if (!mlx4_is_slave(dev->dev)) {
union sl2vl_tbl_to_u64 sl2vl64;
int jj;
for (jj = 0; jj < 8; jj++) {
sl2vl64.sl8[jj] =
eqe->event.port_mgmt_change.params.sl2vl_tbl_change_info.sl2vl_table[jj];
pr_debug("port %u, sl2vl[%d] = %02x\n",
port, jj, sl2vl64.sl8[jj]);
}
atomic64_set(&dev->sl2vl[port - 1], sl2vl64.sl64);
}
break;
mlx4: Use port management change event instead of smp_snoop The port management change event can replace smp_snoop. If the capability bit for this event is set in dev-caps, the event is used (by the driver setting the PORT_MNG_CHG_EVENT bit in the async event mask in the MAP_EQ fw command). In this case, when the driver passes incoming SMP PORT_INFO SET mads to the FW, the FW generates port management change events to signal any changes to the driver. If the FW generates these events, smp_snoop shouldn't be invoked in ib_process_mad(), or duplicate events will occur (once from the FW-generated event, and once from smp_snoop). In the case where the FW does not generate port management change events smp_snoop needs to be invoked to create these events. The flow in smp_snoop has been modified to make use of the same procedures as in the fw-generated-event event case to generate the port management events (LID change, Client-rereg, Pkey change, and/or GID change). Port management change event handling required changing the mlx4_ib_event and mlx4_dispatch_event prototypes; the "param" argument (last argument) had to be changed to unsigned long in order to accomodate passing the EQE pointer. We also needed to move the definition of struct mlx4_eqe from net/mlx4.h to file device.h -- to make it available to the IB driver, to handle port management change events. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-06-19 16:21:40 +08:00
default:
pr_warn("Unsupported subtype 0x%x for "
"Port Management Change event\n", eqe->subtype);
}
kfree(ew);
}
void mlx4_ib_dispatch_event(struct mlx4_ib_dev *dev, u8 port_num,
enum ib_event_type type)
{
struct ib_event event;
event.device = &dev->ib_dev;
event.element.port_num = port_num;
event.event = type;
ib_dispatch_event(&event);
}
static void mlx4_ib_tunnel_comp_handler(struct ib_cq *cq, void *arg)
{
unsigned long flags;
struct mlx4_ib_demux_pv_ctx *ctx = cq->cq_context;
struct mlx4_ib_dev *dev = to_mdev(ctx->ib_dev);
spin_lock_irqsave(&dev->sriov.going_down_lock, flags);
if (!dev->sriov.is_going_down && ctx->state == DEMUX_PV_STATE_ACTIVE)
queue_work(ctx->wq, &ctx->work);
spin_unlock_irqrestore(&dev->sriov.going_down_lock, flags);
}
static int mlx4_ib_post_pv_qp_buf(struct mlx4_ib_demux_pv_ctx *ctx,
struct mlx4_ib_demux_pv_qp *tun_qp,
int index)
{
struct ib_sge sg_list;
struct ib_recv_wr recv_wr, *bad_recv_wr;
int size;
size = (tun_qp->qp->qp_type == IB_QPT_UD) ?
sizeof (struct mlx4_tunnel_mad) : sizeof (struct mlx4_mad_rcv_buf);
sg_list.addr = tun_qp->ring[index].map;
sg_list.length = size;
sg_list.lkey = ctx->pd->local_dma_lkey;
recv_wr.next = NULL;
recv_wr.sg_list = &sg_list;
recv_wr.num_sge = 1;
recv_wr.wr_id = (u64) index | MLX4_TUN_WRID_RECV |
MLX4_TUN_SET_WRID_QPN(tun_qp->proxy_qpt);
ib_dma_sync_single_for_device(ctx->ib_dev, tun_qp->ring[index].map,
size, DMA_FROM_DEVICE);
return ib_post_recv(tun_qp->qp, &recv_wr, &bad_recv_wr);
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
static int mlx4_ib_multiplex_sa_handler(struct ib_device *ibdev, int port,
int slave, struct ib_sa_mad *sa_mad)
{
int ret = 0;
/* dispatch to different sa handlers */
switch (be16_to_cpu(sa_mad->mad_hdr.attr_id)) {
case IB_SA_ATTR_MC_MEMBER_REC:
ret = mlx4_ib_mcg_multiplex_handler(ibdev, port, slave, sa_mad);
break;
default:
break;
}
return ret;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
static int is_proxy_qp0(struct mlx4_ib_dev *dev, int qpn, int slave)
{
int proxy_start = dev->dev->phys_caps.base_proxy_sqpn + 8 * slave;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
return (qpn >= proxy_start && qpn <= proxy_start + 1);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
int mlx4_ib_send_to_wire(struct mlx4_ib_dev *dev, int slave, u8 port,
enum ib_qp_type dest_qpt, u16 pkey_index,
u32 remote_qpn, u32 qkey, struct rdma_ah_attr *attr,
u8 *s_mac, u16 vlan_id, struct ib_mad *mad)
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
{
struct ib_sge list;
struct ib_ud_wr wr;
struct ib_send_wr *bad_wr;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
struct mlx4_ib_demux_pv_ctx *sqp_ctx;
struct mlx4_ib_demux_pv_qp *sqp;
struct mlx4_mad_snd_buf *sqp_mad;
struct ib_ah *ah;
struct ib_qp *send_qp = NULL;
struct ib_global_route *grh;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
unsigned wire_tx_ix = 0;
int ret = 0;
u16 wire_pkey_ix;
int src_qpnum;
u8 sgid_index;
sqp_ctx = dev->sriov.sqps[port-1];
/* check if proxy qp created */
if (!sqp_ctx || sqp_ctx->state != DEMUX_PV_STATE_ACTIVE)
return -EAGAIN;
if (dest_qpt == IB_QPT_SMI) {
src_qpnum = 0;
sqp = &sqp_ctx->qp[0];
wire_pkey_ix = dev->pkeys.virt2phys_pkey[slave][port - 1][0];
} else {
src_qpnum = 1;
sqp = &sqp_ctx->qp[1];
wire_pkey_ix = dev->pkeys.virt2phys_pkey[slave][port - 1][pkey_index];
}
send_qp = sqp->qp;
/* create ah */
grh = rdma_ah_retrieve_grh(attr);
sgid_index = grh->sgid_index;
grh->sgid_index = 0;
ah = rdma_create_ah(sqp_ctx->pd, attr);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (IS_ERR(ah))
return -ENOMEM;
grh->sgid_index = sgid_index;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
to_mah(ah)->av.ib.gid_index = sgid_index;
/* get rid of force-loopback bit */
to_mah(ah)->av.ib.port_pd &= cpu_to_be32(0x7FFFFFFF);
spin_lock(&sqp->tx_lock);
if (sqp->tx_ix_head - sqp->tx_ix_tail >=
(MLX4_NUM_TUNNEL_BUFS - 1))
ret = -EAGAIN;
else
wire_tx_ix = (++sqp->tx_ix_head) & (MLX4_NUM_TUNNEL_BUFS - 1);
spin_unlock(&sqp->tx_lock);
if (ret)
goto out;
sqp_mad = (struct mlx4_mad_snd_buf *) (sqp->tx_ring[wire_tx_ix].buf.addr);
if (sqp->tx_ring[wire_tx_ix].ah)
rdma_destroy_ah(sqp->tx_ring[wire_tx_ix].ah);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
sqp->tx_ring[wire_tx_ix].ah = ah;
ib_dma_sync_single_for_cpu(&dev->ib_dev,
sqp->tx_ring[wire_tx_ix].buf.map,
sizeof (struct mlx4_mad_snd_buf),
DMA_TO_DEVICE);
memcpy(&sqp_mad->payload, mad, sizeof *mad);
ib_dma_sync_single_for_device(&dev->ib_dev,
sqp->tx_ring[wire_tx_ix].buf.map,
sizeof (struct mlx4_mad_snd_buf),
DMA_TO_DEVICE);
list.addr = sqp->tx_ring[wire_tx_ix].buf.map;
list.length = sizeof (struct mlx4_mad_snd_buf);
list.lkey = sqp_ctx->pd->local_dma_lkey;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
wr.ah = ah;
wr.port_num = port;
wr.pkey_index = wire_pkey_ix;
wr.remote_qkey = qkey;
wr.remote_qpn = remote_qpn;
wr.wr.next = NULL;
wr.wr.wr_id = ((u64) wire_tx_ix) | MLX4_TUN_SET_WRID_QPN(src_qpnum);
wr.wr.sg_list = &list;
wr.wr.num_sge = 1;
wr.wr.opcode = IB_WR_SEND;
wr.wr.send_flags = IB_SEND_SIGNALED;
if (s_mac)
memcpy(to_mah(ah)->av.eth.s_mac, s_mac, 6);
if (vlan_id < 0x1000)
vlan_id |= (rdma_ah_get_sl(attr) & 7) << 13;
to_mah(ah)->av.eth.vlan = cpu_to_be16(vlan_id);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
ret = ib_post_send(send_qp, &wr.wr, &bad_wr);
if (!ret)
return 0;
spin_lock(&sqp->tx_lock);
sqp->tx_ix_tail++;
spin_unlock(&sqp->tx_lock);
sqp->tx_ring[wire_tx_ix].ah = NULL;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
out:
rdma_destroy_ah(ah);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
return ret;
}
static int get_slave_base_gid_ix(struct mlx4_ib_dev *dev, int slave, int port)
{
if (rdma_port_get_link_layer(&dev->ib_dev, port) == IB_LINK_LAYER_INFINIBAND)
return slave;
return mlx4_get_base_gid_ix(dev->dev, slave, port);
}
static void fill_in_real_sgid_index(struct mlx4_ib_dev *dev, int slave, int port,
struct rdma_ah_attr *ah_attr)
{
struct ib_global_route *grh = rdma_ah_retrieve_grh(ah_attr);
if (rdma_port_get_link_layer(&dev->ib_dev, port) == IB_LINK_LAYER_INFINIBAND)
grh->sgid_index = slave;
else
grh->sgid_index += get_slave_base_gid_ix(dev, slave, port);
}
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
static void mlx4_ib_multiplex_mad(struct mlx4_ib_demux_pv_ctx *ctx, struct ib_wc *wc)
{
struct mlx4_ib_dev *dev = to_mdev(ctx->ib_dev);
struct mlx4_ib_demux_pv_qp *tun_qp = &ctx->qp[MLX4_TUN_WRID_QPN(wc->wr_id)];
int wr_ix = wc->wr_id & (MLX4_NUM_TUNNEL_BUFS - 1);
struct mlx4_tunnel_mad *tunnel = tun_qp->ring[wr_ix].addr;
struct mlx4_ib_ah ah;
struct rdma_ah_attr ah_attr;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
u8 *slave_id;
int slave;
int port;
u16 vlan_id;
u8 qos;
u8 *dmac;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
/* Get slave that sent this packet */
if (wc->src_qp < dev->dev->phys_caps.base_proxy_sqpn ||
wc->src_qp >= dev->dev->phys_caps.base_proxy_sqpn + 8 * MLX4_MFUNC_MAX ||
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
(wc->src_qp & 0x1) != ctx->port - 1 ||
wc->src_qp & 0x4) {
mlx4_ib_warn(ctx->ib_dev, "can't multiplex bad sqp:%d\n", wc->src_qp);
return;
}
slave = ((wc->src_qp & ~0x7) - dev->dev->phys_caps.base_proxy_sqpn) / 8;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
if (slave != ctx->slave) {
mlx4_ib_warn(ctx->ib_dev, "can't multiplex bad sqp:%d: "
"belongs to another slave\n", wc->src_qp);
return;
}
/* Map transaction ID */
ib_dma_sync_single_for_cpu(ctx->ib_dev, tun_qp->ring[wr_ix].map,
sizeof (struct mlx4_tunnel_mad),
DMA_FROM_DEVICE);
switch (tunnel->mad.mad_hdr.method) {
case IB_MGMT_METHOD_SET:
case IB_MGMT_METHOD_GET:
case IB_MGMT_METHOD_REPORT:
case IB_SA_METHOD_GET_TABLE:
case IB_SA_METHOD_DELETE:
case IB_SA_METHOD_GET_MULTI:
case IB_SA_METHOD_GET_TRACE_TBL:
slave_id = (u8 *) &tunnel->mad.mad_hdr.tid;
if (*slave_id) {
mlx4_ib_warn(ctx->ib_dev, "egress mad has non-null tid msb:%d "
"class:%d slave:%d\n", *slave_id,
tunnel->mad.mad_hdr.mgmt_class, slave);
return;
} else
*slave_id = slave;
default:
/* nothing */;
}
/* Class-specific handling */
switch (tunnel->mad.mad_hdr.mgmt_class) {
case IB_MGMT_CLASS_SUBN_LID_ROUTED:
case IB_MGMT_CLASS_SUBN_DIRECTED_ROUTE:
if (slave != mlx4_master_func_num(dev->dev) &&
!mlx4_vf_smi_enabled(dev->dev, slave, ctx->port))
return;
break;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
case IB_MGMT_CLASS_SUBN_ADM:
if (mlx4_ib_multiplex_sa_handler(ctx->ib_dev, ctx->port, slave,
(struct ib_sa_mad *) &tunnel->mad))
return;
break;
case IB_MGMT_CLASS_CM:
if (mlx4_ib_multiplex_cm_handler(ctx->ib_dev, ctx->port, slave,
(struct ib_mad *) &tunnel->mad))
return;
break;
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
case IB_MGMT_CLASS_DEVICE_MGMT:
if (tunnel->mad.mad_hdr.method != IB_MGMT_METHOD_GET &&
tunnel->mad.mad_hdr.method != IB_MGMT_METHOD_SET)
return;
break;
default:
/* Drop unsupported classes for slaves in tunnel mode */
if (slave != mlx4_master_func_num(dev->dev)) {
mlx4_ib_warn(ctx->ib_dev, "dropping unsupported egress mad from class:%d "
"for slave:%d\n", tunnel->mad.mad_hdr.mgmt_class, slave);
return;
}
}
/* We are using standard ib_core services to send the mad, so generate a
* stadard address handle by decoding the tunnelled mlx4_ah fields */
memcpy(&ah.av, &tunnel->hdr.av, sizeof (struct mlx4_av));
ah.ibah.device = ctx->ib_dev;
port = be32_to_cpu(ah.av.ib.port_pd) >> 24;
port = mlx4_slave_convert_port(dev->dev, slave, port);
if (port < 0)
return;
ah.av.ib.port_pd = cpu_to_be32(port << 24 | (be32_to_cpu(ah.av.ib.port_pd) & 0xffffff));
ah.ibah.type = rdma_ah_find_type(&dev->ib_dev, port);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
mlx4_ib_query_ah(&ah.ibah, &ah_attr);
if (rdma_ah_get_ah_flags(&ah_attr) & IB_AH_GRH)
fill_in_real_sgid_index(dev, slave, ctx->port, &ah_attr);
dmac = rdma_ah_retrieve_dmac(&ah_attr);
if (dmac)
memcpy(dmac, tunnel->hdr.mac, ETH_ALEN);
vlan_id = be16_to_cpu(tunnel->hdr.vlan);
/* if slave have default vlan use it */
if (mlx4_get_slave_default_vlan(dev->dev, ctx->port, slave,
&vlan_id, &qos))
rdma_ah_set_sl(&ah_attr, qos);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
mlx4_ib_send_to_wire(dev, slave, ctx->port,
is_proxy_qp0(dev, wc->src_qp, slave) ?
IB_QPT_SMI : IB_QPT_GSI,
be16_to_cpu(tunnel->hdr.pkey_index),
be32_to_cpu(tunnel->hdr.remote_qpn),
be32_to_cpu(tunnel->hdr.qkey),
&ah_attr, wc->smac, vlan_id, &tunnel->mad);
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
}
static int mlx4_ib_alloc_pv_bufs(struct mlx4_ib_demux_pv_ctx *ctx,
enum ib_qp_type qp_type, int is_tun)
{
int i;
struct mlx4_ib_demux_pv_qp *tun_qp;
int rx_buf_size, tx_buf_size;
if (qp_type > IB_QPT_GSI)
return -EINVAL;
tun_qp = &ctx->qp[qp_type];
treewide: kzalloc() -> kcalloc() The kzalloc() function has a 2-factor argument form, kcalloc(). This patch replaces cases of: kzalloc(a * b, gfp) with: kcalloc(a * b, gfp) as well as handling cases of: kzalloc(a * b * c, gfp) with: kzalloc(array3_size(a, b, c), gfp) as it's slightly less ugly than: kzalloc_array(array_size(a, b), c, gfp) This does, however, attempt to ignore constant size factors like: kzalloc(4 * 1024, gfp) though any constants defined via macros get caught up in the conversion. Any factors with a sizeof() of "unsigned char", "char", and "u8" were dropped, since they're redundant. The Coccinelle script used for this was: // Fix redundant parens around sizeof(). @@ type TYPE; expression THING, E; @@ ( kzalloc( - (sizeof(TYPE)) * E + sizeof(TYPE) * E , ...) | kzalloc( - (sizeof(THING)) * E + sizeof(THING) * E , ...) ) // Drop single-byte sizes and redundant parens. @@ expression COUNT; typedef u8; typedef __u8; @@ ( kzalloc( - sizeof(u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(__u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(unsigned char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(__u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(char) * COUNT + COUNT , ...) | kzalloc( - sizeof(unsigned char) * COUNT + COUNT , ...) ) // 2-factor product with sizeof(type/expression) and identifier or constant. @@ type TYPE; expression THING; identifier COUNT_ID; constant COUNT_CONST; @@ ( - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_ID) + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_ID + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_CONST) + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_CONST + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_ID) + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_ID + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_CONST) + COUNT_CONST, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_CONST + COUNT_CONST, sizeof(THING) , ...) ) // 2-factor product, only identifiers. @@ identifier SIZE, COUNT; @@ - kzalloc + kcalloc ( - SIZE * COUNT + COUNT, SIZE , ...) // 3-factor product with 1 sizeof(type) or sizeof(expression), with // redundant parens removed. @@ expression THING; identifier STRIDE, COUNT; type TYPE; @@ ( kzalloc( - sizeof(TYPE) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) ) // 3-factor product with 2 sizeof(variable), with redundant parens removed. @@ expression THING1, THING2; identifier COUNT; type TYPE1, TYPE2; @@ ( kzalloc( - sizeof(TYPE1) * sizeof(TYPE2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) ) // 3-factor product, only identifiers, with redundant parens removed. @@ identifier STRIDE, SIZE, COUNT; @@ ( kzalloc( - (COUNT) * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) ) // Any remaining multi-factor products, first at least 3-factor products, // when they're not all constants... @@ expression E1, E2, E3; constant C1, C2, C3; @@ ( kzalloc(C1 * C2 * C3, ...) | kzalloc( - (E1) * E2 * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * (E3) + array3_size(E1, E2, E3) , ...) | kzalloc( - E1 * E2 * E3 + array3_size(E1, E2, E3) , ...) ) // And then all remaining 2 factors products when they're not all constants, // keeping sizeof() as the second factor argument. @@ expression THING, E1, E2; type TYPE; constant C1, C2, C3; @@ ( kzalloc(sizeof(THING) * C2, ...) | kzalloc(sizeof(TYPE) * C2, ...) | kzalloc(C1 * C2 * C3, ...) | kzalloc(C1 * C2, ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (E2) + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * E2 + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (E2) + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * E2 + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - (E1) * E2 + E1, E2 , ...) | - kzalloc + kcalloc ( - (E1) * (E2) + E1, E2 , ...) | - kzalloc + kcalloc ( - E1 * E2 + E1, E2 , ...) ) Signed-off-by: Kees Cook <keescook@chromium.org>
2018-06-13 05:03:40 +08:00
tun_qp->ring = kcalloc(MLX4_NUM_TUNNEL_BUFS,
sizeof(struct mlx4_ib_buf),
GFP_KERNEL);
if (!tun_qp->ring)
return -ENOMEM;
tun_qp->tx_ring = kcalloc(MLX4_NUM_TUNNEL_BUFS,
sizeof (struct mlx4_ib_tun_tx_buf),
GFP_KERNEL);
if (!tun_qp->tx_ring) {
kfree(tun_qp->ring);
tun_qp->ring = NULL;
return -ENOMEM;
}
if (is_tun) {
rx_buf_size = sizeof (struct mlx4_tunnel_mad);
tx_buf_size = sizeof (struct mlx4_rcv_tunnel_mad);
} else {
rx_buf_size = sizeof (struct mlx4_mad_rcv_buf);
tx_buf_size = sizeof (struct mlx4_mad_snd_buf);
}
for (i = 0; i < MLX4_NUM_TUNNEL_BUFS; i++) {
tun_qp->ring[i].addr = kmalloc(rx_buf_size, GFP_KERNEL);
if (!tun_qp->ring[i].addr)
goto err;
tun_qp->ring[i].map = ib_dma_map_single(ctx->ib_dev,
tun_qp->ring[i].addr,
rx_buf_size,
DMA_FROM_DEVICE);
if (ib_dma_mapping_error(ctx->ib_dev, tun_qp->ring[i].map)) {
kfree(tun_qp->ring[i].addr);
goto err;
}
}
for (i = 0; i < MLX4_NUM_TUNNEL_BUFS; i++) {
tun_qp->tx_ring[i].buf.addr =
kmalloc(tx_buf_size, GFP_KERNEL);
if (!tun_qp->tx_ring[i].buf.addr)
goto tx_err;
tun_qp->tx_ring[i].buf.map =
ib_dma_map_single(ctx->ib_dev,
tun_qp->tx_ring[i].buf.addr,
tx_buf_size,
DMA_TO_DEVICE);
if (ib_dma_mapping_error(ctx->ib_dev,
tun_qp->tx_ring[i].buf.map)) {
kfree(tun_qp->tx_ring[i].buf.addr);
goto tx_err;
}
tun_qp->tx_ring[i].ah = NULL;
}
spin_lock_init(&tun_qp->tx_lock);
tun_qp->tx_ix_head = 0;
tun_qp->tx_ix_tail = 0;
tun_qp->proxy_qpt = qp_type;
return 0;
tx_err:
while (i > 0) {
--i;
ib_dma_unmap_single(ctx->ib_dev, tun_qp->tx_ring[i].buf.map,
tx_buf_size, DMA_TO_DEVICE);
kfree(tun_qp->tx_ring[i].buf.addr);
}
kfree(tun_qp->tx_ring);
tun_qp->tx_ring = NULL;
i = MLX4_NUM_TUNNEL_BUFS;
err:
while (i > 0) {
--i;
ib_dma_unmap_single(ctx->ib_dev, tun_qp->ring[i].map,
rx_buf_size, DMA_FROM_DEVICE);
kfree(tun_qp->ring[i].addr);
}
kfree(tun_qp->ring);
tun_qp->ring = NULL;
return -ENOMEM;
}
static void mlx4_ib_free_pv_qp_bufs(struct mlx4_ib_demux_pv_ctx *ctx,
enum ib_qp_type qp_type, int is_tun)
{
int i;
struct mlx4_ib_demux_pv_qp *tun_qp;
int rx_buf_size, tx_buf_size;
if (qp_type > IB_QPT_GSI)
return;
tun_qp = &ctx->qp[qp_type];
if (is_tun) {
rx_buf_size = sizeof (struct mlx4_tunnel_mad);
tx_buf_size = sizeof (struct mlx4_rcv_tunnel_mad);
} else {
rx_buf_size = sizeof (struct mlx4_mad_rcv_buf);
tx_buf_size = sizeof (struct mlx4_mad_snd_buf);
}
for (i = 0; i < MLX4_NUM_TUNNEL_BUFS; i++) {
ib_dma_unmap_single(ctx->ib_dev, tun_qp->ring[i].map,
rx_buf_size, DMA_FROM_DEVICE);
kfree(tun_qp->ring[i].addr);
}
for (i = 0; i < MLX4_NUM_TUNNEL_BUFS; i++) {
ib_dma_unmap_single(ctx->ib_dev, tun_qp->tx_ring[i].buf.map,
tx_buf_size, DMA_TO_DEVICE);
kfree(tun_qp->tx_ring[i].buf.addr);
if (tun_qp->tx_ring[i].ah)
rdma_destroy_ah(tun_qp->tx_ring[i].ah);
}
kfree(tun_qp->tx_ring);
kfree(tun_qp->ring);
}
static void mlx4_ib_tunnel_comp_worker(struct work_struct *work)
{
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
struct mlx4_ib_demux_pv_ctx *ctx;
struct mlx4_ib_demux_pv_qp *tun_qp;
struct ib_wc wc;
int ret;
ctx = container_of(work, struct mlx4_ib_demux_pv_ctx, work);
ib_req_notify_cq(ctx->cq, IB_CQ_NEXT_COMP);
while (ib_poll_cq(ctx->cq, 1, &wc) == 1) {
tun_qp = &ctx->qp[MLX4_TUN_WRID_QPN(wc.wr_id)];
if (wc.status == IB_WC_SUCCESS) {
switch (wc.opcode) {
case IB_WC_RECV:
mlx4_ib_multiplex_mad(ctx, &wc);
ret = mlx4_ib_post_pv_qp_buf(ctx, tun_qp,
wc.wr_id &
(MLX4_NUM_TUNNEL_BUFS - 1));
if (ret)
pr_err("Failed reposting tunnel "
"buf:%lld\n", wc.wr_id);
break;
case IB_WC_SEND:
pr_debug("received tunnel send completion:"
"wrid=0x%llx, status=0x%x\n",
wc.wr_id, wc.status);
rdma_destroy_ah(tun_qp->tx_ring[wc.wr_id &
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
(MLX4_NUM_TUNNEL_BUFS - 1)].ah);
tun_qp->tx_ring[wc.wr_id & (MLX4_NUM_TUNNEL_BUFS - 1)].ah
= NULL;
spin_lock(&tun_qp->tx_lock);
tun_qp->tx_ix_tail++;
spin_unlock(&tun_qp->tx_lock);
break;
default:
break;
}
} else {
pr_debug("mlx4_ib: completion error in tunnel: %d."
" status = %d, wrid = 0x%llx\n",
ctx->slave, wc.status, wc.wr_id);
if (!MLX4_TUN_IS_RECV(wc.wr_id)) {
rdma_destroy_ah(tun_qp->tx_ring[wc.wr_id &
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
(MLX4_NUM_TUNNEL_BUFS - 1)].ah);
tun_qp->tx_ring[wc.wr_id & (MLX4_NUM_TUNNEL_BUFS - 1)].ah
= NULL;
spin_lock(&tun_qp->tx_lock);
tun_qp->tx_ix_tail++;
spin_unlock(&tun_qp->tx_lock);
}
}
}
}
static void pv_qp_event_handler(struct ib_event *event, void *qp_context)
{
struct mlx4_ib_demux_pv_ctx *sqp = qp_context;
/* It's worse than that! He's dead, Jim! */
pr_err("Fatal error (%d) on a MAD QP on port %d\n",
event->event, sqp->port);
}
static int create_pv_sqp(struct mlx4_ib_demux_pv_ctx *ctx,
enum ib_qp_type qp_type, int create_tun)
{
int i, ret;
struct mlx4_ib_demux_pv_qp *tun_qp;
struct mlx4_ib_qp_tunnel_init_attr qp_init_attr;
struct ib_qp_attr attr;
int qp_attr_mask_INIT;
if (qp_type > IB_QPT_GSI)
return -EINVAL;
tun_qp = &ctx->qp[qp_type];
memset(&qp_init_attr, 0, sizeof qp_init_attr);
qp_init_attr.init_attr.send_cq = ctx->cq;
qp_init_attr.init_attr.recv_cq = ctx->cq;
qp_init_attr.init_attr.sq_sig_type = IB_SIGNAL_ALL_WR;
qp_init_attr.init_attr.cap.max_send_wr = MLX4_NUM_TUNNEL_BUFS;
qp_init_attr.init_attr.cap.max_recv_wr = MLX4_NUM_TUNNEL_BUFS;
qp_init_attr.init_attr.cap.max_send_sge = 1;
qp_init_attr.init_attr.cap.max_recv_sge = 1;
if (create_tun) {
qp_init_attr.init_attr.qp_type = IB_QPT_UD;
qp_init_attr.init_attr.create_flags = MLX4_IB_SRIOV_TUNNEL_QP;
qp_init_attr.port = ctx->port;
qp_init_attr.slave = ctx->slave;
qp_init_attr.proxy_qp_type = qp_type;
qp_attr_mask_INIT = IB_QP_STATE | IB_QP_PKEY_INDEX |
IB_QP_QKEY | IB_QP_PORT;
} else {
qp_init_attr.init_attr.qp_type = qp_type;
qp_init_attr.init_attr.create_flags = MLX4_IB_SRIOV_SQP;
qp_attr_mask_INIT = IB_QP_STATE | IB_QP_PKEY_INDEX | IB_QP_QKEY;
}
qp_init_attr.init_attr.port_num = ctx->port;
qp_init_attr.init_attr.qp_context = ctx;
qp_init_attr.init_attr.event_handler = pv_qp_event_handler;
tun_qp->qp = ib_create_qp(ctx->pd, &qp_init_attr.init_attr);
if (IS_ERR(tun_qp->qp)) {
ret = PTR_ERR(tun_qp->qp);
tun_qp->qp = NULL;
pr_err("Couldn't create %s QP (%d)\n",
create_tun ? "tunnel" : "special", ret);
return ret;
}
memset(&attr, 0, sizeof attr);
attr.qp_state = IB_QPS_INIT;
IB/mlx4: Use default pkey when creating tunnel QPs When creating tunnel QPs for special QP tunneling, look for the default pkey in the slave's virtual pkey table. If it is present, use the real pkey index where the default pkey is located. If the default pkey is not found in the pkey table, use the real pkey index which is stored at index 0 in the slave's virtual pkey table (this is the current behavior). This change is required to support cloud computing, where the paravirtualized index of the default pkey is moved to index 1 or higher. The pkey at paravirtualized index 0 is used for the default IPoIB interface created by the VF. Its possible for the pkey value at paravirtualized index 0 to be invalid (zero) at VF probe time (pkey index 0 is mapped to real pkey index 127, which contains pkey = 0). At some point after the VF probe, the cloud computing interface at the hypervisor maps virtual index 0 for the VF to the pkey index containing the pkey that IPoIB will use in its operation. However, when the tunnel QP is created, the pkey at the slave's virtual index 0 is still mapped to the invalid pkey index, so tunnel QP creation fails. This commit causes the hypervisor to search for the default pkey in the slave's pkey table -- and this pkey is present in the table (at index > 0) at tunnel QP creation time, so that the tunnel QP creation will succeed. Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Roland Dreier <roland@purestorage.com>
2013-07-18 19:02:30 +08:00
ret = 0;
if (create_tun)
ret = find_slave_port_pkey_ix(to_mdev(ctx->ib_dev), ctx->slave,
ctx->port, IB_DEFAULT_PKEY_FULL,
&attr.pkey_index);
if (ret || !create_tun)
attr.pkey_index =
to_mdev(ctx->ib_dev)->pkeys.virt2phys_pkey[ctx->slave][ctx->port - 1][0];
attr.qkey = IB_QP1_QKEY;
attr.port_num = ctx->port;
ret = ib_modify_qp(tun_qp->qp, &attr, qp_attr_mask_INIT);
if (ret) {
pr_err("Couldn't change %s qp state to INIT (%d)\n",
create_tun ? "tunnel" : "special", ret);
goto err_qp;
}
attr.qp_state = IB_QPS_RTR;
ret = ib_modify_qp(tun_qp->qp, &attr, IB_QP_STATE);
if (ret) {
pr_err("Couldn't change %s qp state to RTR (%d)\n",
create_tun ? "tunnel" : "special", ret);
goto err_qp;
}
attr.qp_state = IB_QPS_RTS;
attr.sq_psn = 0;
ret = ib_modify_qp(tun_qp->qp, &attr, IB_QP_STATE | IB_QP_SQ_PSN);
if (ret) {
pr_err("Couldn't change %s qp state to RTS (%d)\n",
create_tun ? "tunnel" : "special", ret);
goto err_qp;
}
for (i = 0; i < MLX4_NUM_TUNNEL_BUFS; i++) {
ret = mlx4_ib_post_pv_qp_buf(ctx, tun_qp, i);
if (ret) {
pr_err(" mlx4_ib_post_pv_buf error"
" (err = %d, i = %d)\n", ret, i);
goto err_qp;
}
}
return 0;
err_qp:
ib_destroy_qp(tun_qp->qp);
tun_qp->qp = NULL;
return ret;
}
/*
* IB MAD completion callback for real SQPs
*/
static void mlx4_ib_sqp_comp_worker(struct work_struct *work)
{
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
struct mlx4_ib_demux_pv_ctx *ctx;
struct mlx4_ib_demux_pv_qp *sqp;
struct ib_wc wc;
struct ib_grh *grh;
struct ib_mad *mad;
ctx = container_of(work, struct mlx4_ib_demux_pv_ctx, work);
ib_req_notify_cq(ctx->cq, IB_CQ_NEXT_COMP);
while (mlx4_ib_poll_cq(ctx->cq, 1, &wc) == 1) {
sqp = &ctx->qp[MLX4_TUN_WRID_QPN(wc.wr_id)];
if (wc.status == IB_WC_SUCCESS) {
switch (wc.opcode) {
case IB_WC_SEND:
rdma_destroy_ah(sqp->tx_ring[wc.wr_id &
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
(MLX4_NUM_TUNNEL_BUFS - 1)].ah);
sqp->tx_ring[wc.wr_id & (MLX4_NUM_TUNNEL_BUFS - 1)].ah
= NULL;
spin_lock(&sqp->tx_lock);
sqp->tx_ix_tail++;
spin_unlock(&sqp->tx_lock);
break;
case IB_WC_RECV:
mad = (struct ib_mad *) &(((struct mlx4_mad_rcv_buf *)
(sqp->ring[wc.wr_id &
(MLX4_NUM_TUNNEL_BUFS - 1)].addr))->payload);
grh = &(((struct mlx4_mad_rcv_buf *)
(sqp->ring[wc.wr_id &
(MLX4_NUM_TUNNEL_BUFS - 1)].addr))->grh);
mlx4_ib_demux_mad(ctx->ib_dev, ctx->port, &wc, grh, mad);
if (mlx4_ib_post_pv_qp_buf(ctx, sqp, wc.wr_id &
(MLX4_NUM_TUNNEL_BUFS - 1)))
pr_err("Failed reposting SQP "
"buf:%lld\n", wc.wr_id);
break;
default:
break;
}
} else {
pr_debug("mlx4_ib: completion error in tunnel: %d."
" status = %d, wrid = 0x%llx\n",
ctx->slave, wc.status, wc.wr_id);
if (!MLX4_TUN_IS_RECV(wc.wr_id)) {
rdma_destroy_ah(sqp->tx_ring[wc.wr_id &
IB/mlx4: SR-IOV multiplex and demultiplex MADs Special QPs are paravirtualized. vHCAs are not given direct access to QP0/1. Rather, these QPs are operated by a special context hosted by the PF, which mediates access to/from vHCAs. This is done by opening a "tunnel" per vHCA port per QP0/1. A tunnel comprises a pair of UD QPs: a "Tunnel QP" in the PF-context and a "Proxy QP" in the vHCA. All vHCA MAD traffic must pass through the corresponding tunnel. vHCA QPs cannot be assigned to VL15 and are denied of the well-known QKey. Outgoing messages are "de-multiplexed" (i.e., directed to the wire via the real special QP). Incoming messages are "multiplexed" (i.e. steered by the PPF to the correct VF or to the PF) QP0 access is restricted to the PF vHCA. VF vHCAs also have (virtual) QP0s, but they never receive any SMPs and all SMPs sent are discarded. QP1 traffic is allowed for all vHCAs, but special care is required to bridge the gap between the host and network views. Specifically: - Transaction IDs are mapped to guarantee uniqueness among vHCAs - CM para-virtualization o Incoming requests are steered to the correct vHCA according to the embedded GID o Local communication IDs are mapped to ensure uniqueness among vHCAs (see the patch that adds CM paravirtualization.) - Multicast para-virtualization o The PF context aggregates membership state from all vHCAs o The SA is contacted only when the aggregate membership changes o If the aggregate does not change, the PF context will provide the requesting vHCA with the proper response. (see the patch that adds multicast group paravirtualization) Incoming MADs are steered according to: - the DGID If a GRH is present - the mapped transaction ID for response MADs - the embedded GID in CM requests - the remote communication ID in other CM messages Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Roland Dreier <roland@purestorage.com>
2012-08-03 16:40:44 +08:00
(MLX4_NUM_TUNNEL_BUFS - 1)].ah);
sqp->tx_ring[wc.wr_id & (MLX4_NUM_TUNNEL_BUFS - 1)].ah
= NULL;
spin_lock(&sqp->tx_lock);
sqp->tx_ix_tail++;
spin_unlock(&sqp->tx_lock);
}
}
}
}
static int alloc_pv_object(struct mlx4_ib_dev *dev, int slave, int port,
struct mlx4_ib_demux_pv_ctx **ret_ctx)
{
struct mlx4_ib_demux_pv_ctx *ctx;
*ret_ctx = NULL;
ctx = kzalloc(sizeof (struct mlx4_ib_demux_pv_ctx), GFP_KERNEL);
if (!ctx)
return -ENOMEM;
ctx->ib_dev = &dev->ib_dev;
ctx->port = port;
ctx->slave = slave;
*ret_ctx = ctx;
return 0;
}
static void free_pv_object(struct mlx4_ib_dev *dev, int slave, int port)
{
if (dev->sriov.demux[port - 1].tun[slave]) {
kfree(dev->sriov.demux[port - 1].tun[slave]);
dev->sriov.demux[port - 1].tun[slave] = NULL;
}
}
static int create_pv_resources(struct ib_device *ibdev, int slave, int port,
int create_tun, struct mlx4_ib_demux_pv_ctx *ctx)
{
int ret, cq_size;
struct ib_cq_init_attr cq_attr = {};
if (ctx->state != DEMUX_PV_STATE_DOWN)
return -EEXIST;
ctx->state = DEMUX_PV_STATE_STARTING;
/* have QP0 only if link layer is IB */
if (rdma_port_get_link_layer(ibdev, ctx->port) ==
IB_LINK_LAYER_INFINIBAND)
ctx->has_smi = 1;
if (ctx->has_smi) {
ret = mlx4_ib_alloc_pv_bufs(ctx, IB_QPT_SMI, create_tun);
if (ret) {
pr_err("Failed allocating qp0 tunnel bufs (%d)\n", ret);
goto err_out;
}
}
ret = mlx4_ib_alloc_pv_bufs(ctx, IB_QPT_GSI, create_tun);
if (ret) {
pr_err("Failed allocating qp1 tunnel bufs (%d)\n", ret);
goto err_out_qp0;
}
cq_size = 2 * MLX4_NUM_TUNNEL_BUFS;
if (ctx->has_smi)
cq_size *= 2;
cq_attr.cqe = cq_size;
ctx->cq = ib_create_cq(ctx->ib_dev, mlx4_ib_tunnel_comp_handler,
NULL, ctx, &cq_attr);
if (IS_ERR(ctx->cq)) {
ret = PTR_ERR(ctx->cq);
pr_err("Couldn't create tunnel CQ (%d)\n", ret);
goto err_buf;
}
ctx->pd = ib_alloc_pd(ctx->ib_dev, 0);
if (IS_ERR(ctx->pd)) {
ret = PTR_ERR(ctx->pd);
pr_err("Couldn't create tunnel PD (%d)\n", ret);
goto err_cq;
}
if (ctx->has_smi) {
ret = create_pv_sqp(ctx, IB_QPT_SMI, create_tun);
if (ret) {
pr_err("Couldn't create %s QP0 (%d)\n",
create_tun ? "tunnel for" : "", ret);
goto err_pd;
}
}
ret = create_pv_sqp(ctx, IB_QPT_GSI, create_tun);
if (ret) {
pr_err("Couldn't create %s QP1 (%d)\n",
create_tun ? "tunnel for" : "", ret);
goto err_qp0;
}
if (create_tun)
INIT_WORK(&ctx->work, mlx4_ib_tunnel_comp_worker);
else
INIT_WORK(&ctx->work, mlx4_ib_sqp_comp_worker);
ctx->wq = to_mdev(ibdev)->sriov.demux[port - 1].wq;
ret = ib_req_notify_cq(ctx->cq, IB_CQ_NEXT_COMP);
if (ret) {
pr_err("Couldn't arm tunnel cq (%d)\n", ret);
goto err_wq;
}
ctx->state = DEMUX_PV_STATE_ACTIVE;
return 0;
err_wq:
ctx->wq = NULL;
ib_destroy_qp(ctx->qp[1].qp);
ctx->qp[1].qp = NULL;
err_qp0:
if (ctx->has_smi)
ib_destroy_qp(ctx->qp[0].qp);
ctx->qp[0].qp = NULL;
err_pd:
ib_dealloc_pd(ctx->pd);
ctx->pd = NULL;
err_cq:
ib_destroy_cq(ctx->cq);
ctx->cq = NULL;
err_buf:
mlx4_ib_free_pv_qp_bufs(ctx, IB_QPT_GSI, create_tun);
err_out_qp0:
if (ctx->has_smi)
mlx4_ib_free_pv_qp_bufs(ctx, IB_QPT_SMI, create_tun);
err_out:
ctx->state = DEMUX_PV_STATE_DOWN;
return ret;
}
static void destroy_pv_resources(struct mlx4_ib_dev *dev, int slave, int port,
struct mlx4_ib_demux_pv_ctx *ctx, int flush)
{
if (!ctx)
return;
if (ctx->state > DEMUX_PV_STATE_DOWN) {
ctx->state = DEMUX_PV_STATE_DOWNING;
if (flush)
flush_workqueue(ctx->wq);
if (ctx->has_smi) {
ib_destroy_qp(ctx->qp[0].qp);
ctx->qp[0].qp = NULL;
mlx4_ib_free_pv_qp_bufs(ctx, IB_QPT_SMI, 1);
}
ib_destroy_qp(ctx->qp[1].qp);
ctx->qp[1].qp = NULL;
mlx4_ib_free_pv_qp_bufs(ctx, IB_QPT_GSI, 1);
ib_dealloc_pd(ctx->pd);
ctx->pd = NULL;
ib_destroy_cq(ctx->cq);
ctx->cq = NULL;
ctx->state = DEMUX_PV_STATE_DOWN;
}
}
static int mlx4_ib_tunnels_update(struct mlx4_ib_dev *dev, int slave,
int port, int do_init)
{
int ret = 0;
if (!do_init) {
clean_vf_mcast(&dev->sriov.demux[port - 1], slave);
/* for master, destroy real sqp resources */
if (slave == mlx4_master_func_num(dev->dev))
destroy_pv_resources(dev, slave, port,
dev->sriov.sqps[port - 1], 1);
/* destroy the tunnel qp resources */
destroy_pv_resources(dev, slave, port,
dev->sriov.demux[port - 1].tun[slave], 1);
return 0;
}
/* create the tunnel qp resources */
ret = create_pv_resources(&dev->ib_dev, slave, port, 1,
dev->sriov.demux[port - 1].tun[slave]);
/* for master, create the real sqp resources */
if (!ret && slave == mlx4_master_func_num(dev->dev))
ret = create_pv_resources(&dev->ib_dev, slave, port, 0,
dev->sriov.sqps[port - 1]);
return ret;
}
void mlx4_ib_tunnels_update_work(struct work_struct *work)
{
struct mlx4_ib_demux_work *dmxw;
dmxw = container_of(work, struct mlx4_ib_demux_work, work);
mlx4_ib_tunnels_update(dmxw->dev, dmxw->slave, (int) dmxw->port,
dmxw->do_init);
kfree(dmxw);
return;
}
static int mlx4_ib_alloc_demux_ctx(struct mlx4_ib_dev *dev,
struct mlx4_ib_demux_ctx *ctx,
int port)
{
char name[12];
int ret = 0;
int i;
ctx->tun = kcalloc(dev->dev->caps.sqp_demux,
sizeof (struct mlx4_ib_demux_pv_ctx *), GFP_KERNEL);
if (!ctx->tun)
return -ENOMEM;
ctx->dev = dev;
ctx->port = port;
ctx->ib_dev = &dev->ib_dev;
for (i = 0;
i < min(dev->dev->caps.sqp_demux,
(u16)(dev->dev->persist->num_vfs + 1));
i++) {
struct mlx4_active_ports actv_ports =
mlx4_get_active_ports(dev->dev, i);
if (!test_bit(port - 1, actv_ports.ports))
continue;
ret = alloc_pv_object(dev, i, port, &ctx->tun[i]);
if (ret) {
ret = -ENOMEM;
goto err_mcg;
}
}
ret = mlx4_ib_mcg_port_init(ctx);
if (ret) {
pr_err("Failed initializing mcg para-virt (%d)\n", ret);
goto err_mcg;
}
snprintf(name, sizeof name, "mlx4_ibt%d", port);
ctx->wq = alloc_ordered_workqueue(name, WQ_MEM_RECLAIM);
if (!ctx->wq) {
pr_err("Failed to create tunnelling WQ for port %d\n", port);
ret = -ENOMEM;
goto err_wq;
}
snprintf(name, sizeof name, "mlx4_ibud%d", port);
ctx->ud_wq = alloc_ordered_workqueue(name, WQ_MEM_RECLAIM);
if (!ctx->ud_wq) {
pr_err("Failed to create up/down WQ for port %d\n", port);
ret = -ENOMEM;
goto err_udwq;
}
return 0;
err_udwq:
destroy_workqueue(ctx->wq);
ctx->wq = NULL;
err_wq:
mlx4_ib_mcg_port_cleanup(ctx, 1);
err_mcg:
for (i = 0; i < dev->dev->caps.sqp_demux; i++)
free_pv_object(dev, i, port);
kfree(ctx->tun);
ctx->tun = NULL;
return ret;
}
static void mlx4_ib_free_sqp_ctx(struct mlx4_ib_demux_pv_ctx *sqp_ctx)
{
if (sqp_ctx->state > DEMUX_PV_STATE_DOWN) {
sqp_ctx->state = DEMUX_PV_STATE_DOWNING;
flush_workqueue(sqp_ctx->wq);
if (sqp_ctx->has_smi) {
ib_destroy_qp(sqp_ctx->qp[0].qp);
sqp_ctx->qp[0].qp = NULL;
mlx4_ib_free_pv_qp_bufs(sqp_ctx, IB_QPT_SMI, 0);
}
ib_destroy_qp(sqp_ctx->qp[1].qp);
sqp_ctx->qp[1].qp = NULL;
mlx4_ib_free_pv_qp_bufs(sqp_ctx, IB_QPT_GSI, 0);
ib_dealloc_pd(sqp_ctx->pd);
sqp_ctx->pd = NULL;
ib_destroy_cq(sqp_ctx->cq);
sqp_ctx->cq = NULL;
sqp_ctx->state = DEMUX_PV_STATE_DOWN;
}
}
static void mlx4_ib_free_demux_ctx(struct mlx4_ib_demux_ctx *ctx)
{
int i;
if (ctx) {
struct mlx4_ib_dev *dev = to_mdev(ctx->ib_dev);
mlx4_ib_mcg_port_cleanup(ctx, 1);
for (i = 0; i < dev->dev->caps.sqp_demux; i++) {
if (!ctx->tun[i])
continue;
if (ctx->tun[i]->state > DEMUX_PV_STATE_DOWN)
ctx->tun[i]->state = DEMUX_PV_STATE_DOWNING;
}
flush_workqueue(ctx->wq);
for (i = 0; i < dev->dev->caps.sqp_demux; i++) {
destroy_pv_resources(dev, i, ctx->port, ctx->tun[i], 0);
free_pv_object(dev, i, ctx->port);
}
kfree(ctx->tun);
destroy_workqueue(ctx->ud_wq);
destroy_workqueue(ctx->wq);
}
}
static void mlx4_ib_master_tunnels(struct mlx4_ib_dev *dev, int do_init)
{
int i;
if (!mlx4_is_master(dev->dev))
return;
/* initialize or tear down tunnel QPs for the master */
for (i = 0; i < dev->dev->caps.num_ports; i++)
mlx4_ib_tunnels_update(dev, mlx4_master_func_num(dev->dev), i + 1, do_init);
return;
}
int mlx4_ib_init_sriov(struct mlx4_ib_dev *dev)
{
int i = 0;
int err;
if (!mlx4_is_mfunc(dev->dev))
return 0;
dev->sriov.is_going_down = 0;
spin_lock_init(&dev->sriov.going_down_lock);
mlx4_ib_cm_paravirt_init(dev);
mlx4_ib_warn(&dev->ib_dev, "multi-function enabled\n");
if (mlx4_is_slave(dev->dev)) {
mlx4_ib_warn(&dev->ib_dev, "operating in qp1 tunnel mode\n");
return 0;
}
for (i = 0; i < dev->dev->caps.sqp_demux; i++) {
if (i == mlx4_master_func_num(dev->dev))
mlx4_put_slave_node_guid(dev->dev, i, dev->ib_dev.node_guid);
else
mlx4_put_slave_node_guid(dev->dev, i, mlx4_ib_gen_node_guid());
}
err = mlx4_ib_init_alias_guid_service(dev);
if (err) {
mlx4_ib_warn(&dev->ib_dev, "Failed init alias guid process.\n");
goto paravirt_err;
}
err = mlx4_ib_device_register_sysfs(dev);
if (err) {
mlx4_ib_warn(&dev->ib_dev, "Failed to register sysfs\n");
goto sysfs_err;
}
mlx4_ib_warn(&dev->ib_dev, "initializing demux service for %d qp1 clients\n",
dev->dev->caps.sqp_demux);
for (i = 0; i < dev->num_ports; i++) {
union ib_gid gid;
err = __mlx4_ib_query_gid(&dev->ib_dev, i + 1, 0, &gid, 1);
if (err)
goto demux_err;
dev->sriov.demux[i].guid_cache[0] = gid.global.interface_id;
IB/mlx4: Use correct subnet-prefix in QP1 mads under SR-IOV When sending QP1 MAD packets which use a GRH, the source GID (which consists of the 64-bit subnet prefix, and the 64 bit port GUID) must be included in the packet GRH. For SR-IOV, a GID cache is used, since the source GID needs to be the slave's source GID, and not the Hypervisor's GID. This cache also included a subnet_prefix. Unfortunately, the subnet_prefix field in the cache was never initialized (to the default subnet prefix 0xfe80::0). As a result, this field remained all zeroes. Therefore, when SR-IOV was active, all QP1 packets which included a GRH had a source GID subnet prefix of all-zeroes. However, the subnet-prefix should initially be 0xfe80::0 (the default subnet prefix). In addition, if OpenSM modifies a port's subnet prefix, the new subnet prefix must be used in the GRH when sending QP1 packets. To fix this we now initialize the subnet prefix in the SR-IOV GID cache to the default subnet prefix. We update the cached value if/when OpenSM modifies the port's subnet prefix. We take this cached value when sending QP1 packets when SR-IOV is active. Note that the value is stored as an atomic64. This eliminates any need for locking when the subnet prefix is being updated. Note also that we depend on the FW generating the "port management change" event for tracking subnet-prefix changes performed by OpenSM. If running early FW (before 2.9.4630), subnet prefix changes will not be tracked (but the default subnet prefix still will be stored in the cache; therefore users who do not modify the subnet prefix will not have a problem). IF there is a need for such tracking also for early FW, we will add that capability in a subsequent patch. Fixes: 1ffeb2eb8be9 ("IB/mlx4: SR-IOV IB context objects and proxy/tunnel SQP support") Signed-off-by: Jack Morgenstein <jackm@dev.mellanox.co.il> Signed-off-by: Leon Romanovsky <leon@kernel.org> Signed-off-by: Doug Ledford <dledford@redhat.com>
2016-09-13 00:16:20 +08:00
atomic64_set(&dev->sriov.demux[i].subnet_prefix,
be64_to_cpu(gid.global.subnet_prefix));
err = alloc_pv_object(dev, mlx4_master_func_num(dev->dev), i + 1,
&dev->sriov.sqps[i]);
if (err)
goto demux_err;
err = mlx4_ib_alloc_demux_ctx(dev, &dev->sriov.demux[i], i + 1);
if (err)
goto free_pv;
}
mlx4_ib_master_tunnels(dev, 1);
return 0;
free_pv:
free_pv_object(dev, mlx4_master_func_num(dev->dev), i + 1);
demux_err:
while (--i >= 0) {
free_pv_object(dev, mlx4_master_func_num(dev->dev), i + 1);
mlx4_ib_free_demux_ctx(&dev->sriov.demux[i]);
}
mlx4_ib_device_unregister_sysfs(dev);
sysfs_err:
mlx4_ib_destroy_alias_guid_service(dev);
paravirt_err:
mlx4_ib_cm_paravirt_clean(dev, -1);
return err;
}
void mlx4_ib_close_sriov(struct mlx4_ib_dev *dev)
{
int i;
unsigned long flags;
if (!mlx4_is_mfunc(dev->dev))
return;
spin_lock_irqsave(&dev->sriov.going_down_lock, flags);
dev->sriov.is_going_down = 1;
spin_unlock_irqrestore(&dev->sriov.going_down_lock, flags);
if (mlx4_is_master(dev->dev)) {
for (i = 0; i < dev->num_ports; i++) {
flush_workqueue(dev->sriov.demux[i].ud_wq);
mlx4_ib_free_sqp_ctx(dev->sriov.sqps[i]);
kfree(dev->sriov.sqps[i]);
dev->sriov.sqps[i] = NULL;
mlx4_ib_free_demux_ctx(&dev->sriov.demux[i]);
}
mlx4_ib_cm_paravirt_clean(dev, -1);
mlx4_ib_destroy_alias_guid_service(dev);
mlx4_ib_device_unregister_sysfs(dev);
}
}