/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * hermon_srq.c * Hermon Shared Receive Queue Processing Routines * * Implements all the routines necessary for allocating, freeing, querying, * modifying and posting shared receive queues. */ #include #include #include #include #include #include #include #include static void hermon_srq_sgl_to_logwqesz(hermon_state_t *state, uint_t num_sgl, hermon_qp_wq_type_t wq_type, uint_t *logwqesz, uint_t *max_sgl); /* * hermon_srq_alloc() * Context: Can be called only from user or kernel context. */ int hermon_srq_alloc(hermon_state_t *state, hermon_srq_info_t *srqinfo, uint_t sleepflag) { ibt_srq_hdl_t ibt_srqhdl; hermon_pdhdl_t pd; ibt_srq_sizes_t *sizes; ibt_srq_sizes_t *real_sizes; hermon_srqhdl_t *srqhdl; ibt_srq_flags_t flags; hermon_rsrc_t *srqc, *rsrc; hermon_hw_srqc_t srqc_entry; uint32_t *buf; hermon_srqhdl_t srq; hermon_umap_db_entry_t *umapdb; ibt_mr_attr_t mr_attr; hermon_mr_options_t mr_op; hermon_mrhdl_t mr; uint64_t value, srq_desc_off; uint32_t log_srq_size; uint32_t uarpg; uint_t srq_is_umap; int flag, status; uint_t max_sgl; uint_t wqesz; uint_t srq_wr_sz; _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*sizes)) /* * options-->wq_location used to be for location, now explicitly * LOCATION_NORMAL */ /* * Extract the necessary info from the hermon_srq_info_t structure */ real_sizes = srqinfo->srqi_real_sizes; sizes = srqinfo->srqi_sizes; pd = srqinfo->srqi_pd; ibt_srqhdl = srqinfo->srqi_ibt_srqhdl; flags = srqinfo->srqi_flags; srqhdl = srqinfo->srqi_srqhdl; /* * Determine whether SRQ is being allocated for userland access or * whether it is being allocated for kernel access. If the SRQ is * being allocated for userland access, then lookup the UAR doorbell * page number for the current process. Note: If this is not found * (e.g. if the process has not previously open()'d the Hermon driver), * then an error is returned. */ srq_is_umap = (flags & IBT_SRQ_USER_MAP) ? 1 : 0; if (srq_is_umap) { status = hermon_umap_db_find(state->hs_instance, ddi_get_pid(), MLNX_UMAP_UARPG_RSRC, &value, 0, NULL); if (status != DDI_SUCCESS) { status = IBT_INVALID_PARAM; goto srqalloc_fail3; } uarpg = ((hermon_rsrc_t *)(uintptr_t)value)->hr_indx; } else { uarpg = state->hs_kernel_uar_index; } /* Increase PD refcnt */ hermon_pd_refcnt_inc(pd); /* Allocate an SRQ context entry */ status = hermon_rsrc_alloc(state, HERMON_SRQC, 1, sleepflag, &srqc); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail1; } /* Allocate the SRQ Handle entry */ status = hermon_rsrc_alloc(state, HERMON_SRQHDL, 1, sleepflag, &rsrc); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail2; } srq = (hermon_srqhdl_t)rsrc->hr_addr; _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*srq)) bzero(srq, sizeof (struct hermon_sw_srq_s)); /* Calculate the SRQ number */ /* just use the index, implicit in Hermon */ srq->srq_srqnum = srqc->hr_indx; /* * If this will be a user-mappable SRQ, then allocate an entry for * the "userland resources database". This will later be added to * the database (after all further SRQ operations are successful). * If we fail here, we must undo the reference counts and the * previous resource allocation. */ if (srq_is_umap) { umapdb = hermon_umap_db_alloc(state->hs_instance, srq->srq_srqnum, MLNX_UMAP_SRQMEM_RSRC, (uint64_t)(uintptr_t)rsrc); if (umapdb == NULL) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail3; } } /* * Allocate the doorbell record. Hermon just needs one for the * SRQ, and use uarpg (above) as the uar index */ status = hermon_dbr_alloc(state, uarpg, &srq->srq_wq_dbr_acchdl, &srq->srq_wq_vdbr, &srq->srq_wq_pdbr, &srq->srq_rdbr_mapoffset); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail4; } /* * Calculate the appropriate size for the SRQ. * Note: All Hermon SRQs must be a power-of-2 in size. Also * they may not be any smaller than HERMON_SRQ_MIN_SIZE. This step * is to round the requested size up to the next highest power-of-2 */ srq_wr_sz = max(sizes->srq_wr_sz + 1, HERMON_SRQ_MIN_SIZE); log_srq_size = highbit(srq_wr_sz); if (ISP2(srq_wr_sz)) { log_srq_size = log_srq_size - 1; } /* * Next we verify that the rounded-up size is valid (i.e. consistent * with the device limits and/or software-configured limits). If not, * then obviously we have a lot of cleanup to do before returning. */ if (log_srq_size > state->hs_cfg_profile->cp_log_max_srq_sz) { status = IBT_HCA_WR_EXCEEDED; goto srqalloc_fail4a; } /* * Next we verify that the requested number of SGL is valid (i.e. * consistent with the device limits and/or software-configured * limits). If not, then obviously the same cleanup needs to be done. */ max_sgl = state->hs_ibtfinfo.hca_attr->hca_max_srq_sgl; if (sizes->srq_sgl_sz > max_sgl) { status = IBT_HCA_SGL_EXCEEDED; goto srqalloc_fail4a; } /* * Determine the SRQ's WQE sizes. This depends on the requested * number of SGLs. Note: This also has the side-effect of * calculating the real number of SGLs (for the calculated WQE size) */ hermon_srq_sgl_to_logwqesz(state, sizes->srq_sgl_sz, HERMON_QP_WQ_TYPE_RECVQ, &srq->srq_wq_log_wqesz, &srq->srq_wq_sgl); /* * Allocate the memory for SRQ work queues. Note: The location from * which we will allocate these work queues is always * QUEUE_LOCATION_NORMAL. Since Hermon work queues are not * allowed to cross a 32-bit (4GB) boundary, the alignment of the work * queue memory is very important. We used to allocate work queues * (the combined receive and send queues) so that they would be aligned * on their combined size. That alignment guaranteed that they would * never cross the 4GB boundary (Hermon work queues are on the order of * MBs at maximum). Now we are able to relax this alignment constraint * by ensuring that the IB address assigned to the queue memory (as a * result of the hermon_mr_register() call) is offset from zero. * Previously, we had wanted to use the ddi_dma_mem_alloc() routine to * guarantee the alignment, but when attempting to use IOMMU bypass * mode we found that we were not allowed to specify any alignment that * was more restrictive than the system page size. So we avoided this * constraint by passing two alignment values, one for the memory * allocation itself and the other for the DMA handle (for later bind). * This used to cause more memory than necessary to be allocated (in * order to guarantee the more restrictive alignment contraint). But * be guaranteeing the zero-based IB virtual address for the queue, we * are able to conserve this memory. * * Note: If SRQ is not user-mappable, then it may come from either * kernel system memory or from HCA-attached local DDR memory. * * Note2: We align this queue on a pagesize boundary. This is required * to make sure that all the resulting IB addresses will start at 0, for * a zero-based queue. By making sure we are aligned on at least a * page, any offset we use into our queue will be the same as when we * perform hermon_srq_modify() operations later. */ wqesz = (1 << srq->srq_wq_log_wqesz); srq->srq_wqinfo.qa_size = (1 << log_srq_size) * wqesz; srq->srq_wqinfo.qa_alloc_align = PAGESIZE; srq->srq_wqinfo.qa_bind_align = PAGESIZE; if (srq_is_umap) { srq->srq_wqinfo.qa_location = HERMON_QUEUE_LOCATION_USERLAND; } else { srq->srq_wqinfo.qa_location = HERMON_QUEUE_LOCATION_NORMAL; } status = hermon_queue_alloc(state, &srq->srq_wqinfo, sleepflag); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail4a; } buf = (uint32_t *)srq->srq_wqinfo.qa_buf_aligned; _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*buf)) /* * Register the memory for the SRQ work queues. The memory for the SRQ * must be registered in the Hermon cMPT tables. This gives us the LKey * to specify in the SRQ context later. Note: If the work queue is to * be allocated from DDR memory, then only a "bypass" mapping is * appropriate. And if the SRQ memory is user-mappable, then we force * DDI_DMA_CONSISTENT mapping. Also, in order to meet the alignment * restriction, we pass the "mro_bind_override_addr" flag in the call * to hermon_mr_register(). This guarantees that the resulting IB vaddr * will be zero-based (modulo the offset into the first page). If we * fail here, we still have the bunch of resource and reference count * cleanup to do. */ flag = (sleepflag == HERMON_SLEEP) ? IBT_MR_SLEEP : IBT_MR_NOSLEEP; mr_attr.mr_vaddr = (uint64_t)(uintptr_t)buf; mr_attr.mr_len = srq->srq_wqinfo.qa_size; mr_attr.mr_as = NULL; mr_attr.mr_flags = flag | IBT_MR_ENABLE_LOCAL_WRITE; mr_op.mro_bind_type = state->hs_cfg_profile->cp_iommu_bypass; mr_op.mro_bind_dmahdl = srq->srq_wqinfo.qa_dmahdl; mr_op.mro_bind_override_addr = 1; status = hermon_mr_register(state, pd, &mr_attr, &mr, &mr_op, HERMON_SRQ_CMPT); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqalloc_fail5; } _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*mr)) /* * Calculate the offset between the kernel virtual address space * and the IB virtual address space. This will be used when * posting work requests to properly initialize each WQE. */ srq_desc_off = (uint64_t)(uintptr_t)srq->srq_wqinfo.qa_buf_aligned - (uint64_t)mr->mr_bindinfo.bi_addr; srq->srq_wq_wqhdr = hermon_wrid_wqhdr_create(1 << log_srq_size); /* * Fill in all the return arguments (if necessary). This includes * real queue size and real SGLs. */ if (real_sizes != NULL) { real_sizes->srq_wr_sz = (1 << log_srq_size) - 1; real_sizes->srq_sgl_sz = srq->srq_wq_sgl; } /* * Fill in the SRQC entry. This is the final step before passing * ownership of the SRQC entry to the Hermon hardware. We use all of * the information collected/calculated above to fill in the * requisite portions of the SRQC. Note: If this SRQ is going to be * used for userland access, then we need to set the UAR page number * appropriately (otherwise it's a "don't care") */ bzero(&srqc_entry, sizeof (hermon_hw_srqc_t)); srqc_entry.state = HERMON_SRQ_STATE_HW_OWNER; srqc_entry.log_srq_size = log_srq_size; srqc_entry.srqn = srq->srq_srqnum; srqc_entry.log_rq_stride = srq->srq_wq_log_wqesz - 4; /* 16-byte chunks */ srqc_entry.page_offs = srq->srq_wqinfo.qa_pgoffs >> 6; srqc_entry.log2_pgsz = mr->mr_log2_pgsz; srqc_entry.mtt_base_addrh = (uint32_t)((mr->mr_mttaddr >> 32) & 0xFF); srqc_entry.mtt_base_addrl = mr->mr_mttaddr >> 3; srqc_entry.pd = pd->pd_pdnum; srqc_entry.dbr_addrh = (uint32_t)((uint64_t)srq->srq_wq_pdbr >> 32); srqc_entry.dbr_addrl = (uint32_t)((uint64_t)srq->srq_wq_pdbr >> 2); /* * all others - specifically, xrcd, cqn_xrc, lwm, wqe_cnt, and wqe_cntr * are zero thanks to the bzero of the structure */ /* * Write the SRQC entry to hardware. Lastly, we pass ownership of * the entry to the hardware (using the Hermon SW2HW_SRQ firmware * command). Note: In general, this operation shouldn't fail. But * if it does, we have to undo everything we've done above before * returning error. */ status = hermon_cmn_ownership_cmd_post(state, SW2HW_SRQ, &srqc_entry, sizeof (hermon_hw_srqc_t), srq->srq_srqnum, sleepflag); if (status != HERMON_CMD_SUCCESS) { cmn_err(CE_CONT, "Hermon: SW2HW_SRQ command failed: %08x\n", status); if (status == HERMON_CMD_INVALID_STATUS) { hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_SRV_LOST); } status = ibc_get_ci_failure(0); goto srqalloc_fail8; } /* * Fill in the rest of the Hermon SRQ handle. We can update * the following fields for use in further operations on the SRQ. */ srq->srq_srqcrsrcp = srqc; srq->srq_rsrcp = rsrc; srq->srq_mrhdl = mr; srq->srq_refcnt = 0; srq->srq_is_umap = srq_is_umap; srq->srq_uarpg = uarpg; srq->srq_umap_dhp = (devmap_cookie_t)NULL; srq->srq_pdhdl = pd; srq->srq_wq_bufsz = (1 << log_srq_size); srq->srq_wq_buf = buf; srq->srq_desc_off = srq_desc_off; srq->srq_hdlrarg = (void *)ibt_srqhdl; srq->srq_state = 0; srq->srq_real_sizes.srq_wr_sz = (1 << log_srq_size); srq->srq_real_sizes.srq_sgl_sz = srq->srq_wq_sgl; /* * Put SRQ handle in Hermon SRQNum-to-SRQhdl list. Then fill in the * "srqhdl" and return success */ hermon_icm_set_num_to_hdl(state, HERMON_SRQC, srqc->hr_indx, srq); /* * If this is a user-mappable SRQ, then we need to insert the * previously allocated entry into the "userland resources database". * This will allow for later lookup during devmap() (i.e. mmap()) * calls. */ if (srq->srq_is_umap) { hermon_umap_db_add(umapdb); } else { /* initialize work queue for kernel SRQs */ int i, len, last; uint16_t *desc; desc = (uint16_t *)buf; len = wqesz / sizeof (*desc); last = srq->srq_wq_bufsz - 1; for (i = 0; i < last; i++) { desc[1] = htons(i + 1); desc += len; } srq->srq_wq_wqhdr->wq_tail = last; srq->srq_wq_wqhdr->wq_head = 0; } *srqhdl = srq; return (status); /* * The following is cleanup for all possible failure cases in this routine */ srqalloc_fail8: hermon_wrid_wqhdr_destroy(srq->srq_wq_wqhdr); srqalloc_fail7: if (hermon_mr_deregister(state, &mr, HERMON_MR_DEREG_ALL, HERMON_SLEEPFLAG_FOR_CONTEXT()) != DDI_SUCCESS) { HERMON_WARNING(state, "failed to deregister SRQ memory"); } srqalloc_fail5: hermon_queue_free(&srq->srq_wqinfo); srqalloc_fail4a: hermon_dbr_free(state, uarpg, srq->srq_wq_vdbr); srqalloc_fail4: if (srq_is_umap) { hermon_umap_db_free(umapdb); } srqalloc_fail3: hermon_rsrc_free(state, &rsrc); srqalloc_fail2: hermon_rsrc_free(state, &srqc); srqalloc_fail1: hermon_pd_refcnt_dec(pd); srqalloc_fail: return (status); } /* * hermon_srq_free() * Context: Can be called only from user or kernel context. */ /* ARGSUSED */ int hermon_srq_free(hermon_state_t *state, hermon_srqhdl_t *srqhdl, uint_t sleepflag) { hermon_rsrc_t *srqc, *rsrc; hermon_umap_db_entry_t *umapdb; uint64_t value; hermon_srqhdl_t srq; hermon_mrhdl_t mr; hermon_pdhdl_t pd; hermon_hw_srqc_t srqc_entry; uint32_t srqnum; uint_t maxprot; int status; /* * Pull all the necessary information from the Hermon Shared Receive * Queue handle. This is necessary here because the resource for the * SRQ handle is going to be freed up as part of this operation. */ srq = *srqhdl; mutex_enter(&srq->srq_lock); srqc = srq->srq_srqcrsrcp; rsrc = srq->srq_rsrcp; pd = srq->srq_pdhdl; mr = srq->srq_mrhdl; srqnum = srq->srq_srqnum; /* * If there are work queues still associated with the SRQ, then return * an error. Otherwise, we will be holding the SRQ lock. */ if (srq->srq_refcnt != 0) { mutex_exit(&srq->srq_lock); return (IBT_SRQ_IN_USE); } /* * If this was a user-mappable SRQ, then we need to remove its entry * from the "userland resources database". If it is also currently * mmap()'d out to a user process, then we need to call * devmap_devmem_remap() to remap the SRQ memory to an invalid mapping. * We also need to invalidate the SRQ tracking information for the * user mapping. */ if (srq->srq_is_umap) { status = hermon_umap_db_find(state->hs_instance, srq->srq_srqnum, MLNX_UMAP_SRQMEM_RSRC, &value, HERMON_UMAP_DB_REMOVE, &umapdb); if (status != DDI_SUCCESS) { mutex_exit(&srq->srq_lock); HERMON_WARNING(state, "failed to find in database"); return (ibc_get_ci_failure(0)); } hermon_umap_db_free(umapdb); if (srq->srq_umap_dhp != NULL) { maxprot = (PROT_READ | PROT_WRITE | PROT_USER); status = devmap_devmem_remap(srq->srq_umap_dhp, state->hs_dip, 0, 0, srq->srq_wqinfo.qa_size, maxprot, DEVMAP_MAPPING_INVALID, NULL); if (status != DDI_SUCCESS) { mutex_exit(&srq->srq_lock); HERMON_WARNING(state, "failed in SRQ memory " "devmap_devmem_remap()"); return (ibc_get_ci_failure(0)); } srq->srq_umap_dhp = (devmap_cookie_t)NULL; } } /* * Put NULL into the Hermon SRQNum-to-SRQHdl list. This will allow any * in-progress events to detect that the SRQ corresponding to this * number has been freed. */ hermon_icm_set_num_to_hdl(state, HERMON_SRQC, srqc->hr_indx, NULL); mutex_exit(&srq->srq_lock); _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*srq)); /* * Reclaim SRQC entry from hardware (using the Hermon HW2SW_SRQ * firmware command). If the ownership transfer fails for any reason, * then it is an indication that something (either in HW or SW) has * gone seriously wrong. */ status = hermon_cmn_ownership_cmd_post(state, HW2SW_SRQ, &srqc_entry, sizeof (hermon_hw_srqc_t), srqnum, sleepflag); if (status != HERMON_CMD_SUCCESS) { HERMON_WARNING(state, "failed to reclaim SRQC ownership"); cmn_err(CE_CONT, "Hermon: HW2SW_SRQ command failed: %08x\n", status); if (status == HERMON_CMD_INVALID_STATUS) { hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_SRV_LOST); } return (ibc_get_ci_failure(0)); } /* * Deregister the memory for the Shared Receive Queue. If this fails * for any reason, then it is an indication that something (either * in HW or SW) has gone seriously wrong. So we print a warning * message and return. */ status = hermon_mr_deregister(state, &mr, HERMON_MR_DEREG_ALL, sleepflag); if (status != DDI_SUCCESS) { HERMON_WARNING(state, "failed to deregister SRQ memory"); return (IBT_FAILURE); } hermon_wrid_wqhdr_destroy(srq->srq_wq_wqhdr); /* Free the memory for the SRQ */ hermon_queue_free(&srq->srq_wqinfo); /* Free the dbr */ hermon_dbr_free(state, srq->srq_uarpg, srq->srq_wq_vdbr); /* Free the Hermon SRQ Handle */ hermon_rsrc_free(state, &rsrc); /* Free the SRQC entry resource */ hermon_rsrc_free(state, &srqc); /* Decrement the reference count on the protection domain (PD) */ hermon_pd_refcnt_dec(pd); /* Set the srqhdl pointer to NULL and return success */ *srqhdl = NULL; return (DDI_SUCCESS); } /* * hermon_srq_modify() * Context: Can be called only from user or kernel context. */ int hermon_srq_modify(hermon_state_t *state, hermon_srqhdl_t srq, uint_t size, uint_t *real_size, uint_t sleepflag) { hermon_qalloc_info_t new_srqinfo, old_srqinfo; hermon_rsrc_t *mtt, *old_mtt; hermon_bind_info_t bind; hermon_bind_info_t old_bind; hermon_mrhdl_t mr; hermon_hw_srqc_t srqc_entry; hermon_hw_dmpt_t mpt_entry; uint64_t *wre_new, *wre_old; uint64_t mtt_addr; uint64_t srq_pgoffs; uint64_t srq_desc_off; uint32_t *buf, srq_old_bufsz; uint32_t wqesz; uint_t max_srq_size; uint_t mtt_pgsize_bits; uint_t log_srq_size, maxprot; int status; if ((state->hs_devlim.mod_wr_srq == 0) || (state->hs_cfg_profile->cp_srq_resize_enabled == 0)) return (IBT_NOT_SUPPORTED); /* * If size requested is larger than device capability, return * Insufficient Resources */ max_srq_size = (1 << state->hs_cfg_profile->cp_log_max_srq_sz); if (size > max_srq_size) { return (IBT_HCA_WR_EXCEEDED); } /* * Calculate the appropriate size for the SRQ. * Note: All Hermon SRQs must be a power-of-2 in size. Also * they may not be any smaller than HERMON_SRQ_MIN_SIZE. This step * is to round the requested size up to the next highest power-of-2 */ size = max(size, HERMON_SRQ_MIN_SIZE); log_srq_size = highbit(size); if (ISP2(size)) { log_srq_size = log_srq_size - 1; } /* * Next we verify that the rounded-up size is valid (i.e. consistent * with the device limits and/or software-configured limits). */ if (log_srq_size > state->hs_cfg_profile->cp_log_max_srq_sz) { status = IBT_HCA_WR_EXCEEDED; goto srqmodify_fail; } /* * Allocate the memory for newly resized Shared Receive Queue. * * Note: If SRQ is not user-mappable, then it may come from either * kernel system memory or from HCA-attached local DDR memory. * * Note2: We align this queue on a pagesize boundary. This is required * to make sure that all the resulting IB addresses will start at 0, * for a zero-based queue. By making sure we are aligned on at least a * page, any offset we use into our queue will be the same as it was * when we allocated it at hermon_srq_alloc() time. */ wqesz = (1 << srq->srq_wq_log_wqesz); new_srqinfo.qa_size = (1 << log_srq_size) * wqesz; new_srqinfo.qa_alloc_align = PAGESIZE; new_srqinfo.qa_bind_align = PAGESIZE; if (srq->srq_is_umap) { new_srqinfo.qa_location = HERMON_QUEUE_LOCATION_USERLAND; } else { new_srqinfo.qa_location = HERMON_QUEUE_LOCATION_NORMAL; } status = hermon_queue_alloc(state, &new_srqinfo, sleepflag); if (status != DDI_SUCCESS) { status = IBT_INSUFF_RESOURCE; goto srqmodify_fail; } buf = (uint32_t *)new_srqinfo.qa_buf_aligned; _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(*buf)) /* * Allocate the memory for the new WRE list. This will be used later * when we resize the wridlist based on the new SRQ size. */ wre_new = kmem_zalloc((1 << log_srq_size) * sizeof (uint64_t), sleepflag); if (wre_new == NULL) { status = IBT_INSUFF_RESOURCE; goto srqmodify_fail; } /* * Fill in the "bind" struct. This struct provides the majority * of the information that will be used to distinguish between an * "addr" binding (as is the case here) and a "buf" binding (see * below). The "bind" struct is later passed to hermon_mr_mem_bind() * which does most of the "heavy lifting" for the Hermon memory * registration routines. */ _NOTE(NOW_INVISIBLE_TO_OTHER_THREADS(bind)) bzero(&bind, sizeof (hermon_bind_info_t)); bind.bi_type = HERMON_BINDHDL_VADDR; bind.bi_addr = (uint64_t)(uintptr_t)buf; bind.bi_len = new_srqinfo.qa_size; bind.bi_as = NULL; bind.bi_flags = sleepflag == HERMON_SLEEP ? IBT_MR_SLEEP : IBT_MR_NOSLEEP | IBT_MR_ENABLE_LOCAL_WRITE; bind.bi_bypass = state->hs_cfg_profile->cp_iommu_bypass; status = hermon_mr_mtt_bind(state, &bind, new_srqinfo.qa_dmahdl, &mtt, &mtt_pgsize_bits, 0); /* no relaxed ordering */ if (status != DDI_SUCCESS) { status = status; kmem_free(wre_new, (1 << log_srq_size) * sizeof (uint64_t)); hermon_queue_free(&new_srqinfo); goto srqmodify_fail; } /* * Calculate the offset between the kernel virtual address space * and the IB virtual address space. This will be used when * posting work requests to properly initialize each WQE. * * Note: bind addr is zero-based (from alloc) so we calculate the * correct new offset here. */ bind.bi_addr = bind.bi_addr & ((1 << mtt_pgsize_bits) - 1); srq_desc_off = (uint64_t)(uintptr_t)new_srqinfo.qa_buf_aligned - (uint64_t)bind.bi_addr; srq_pgoffs = (uint_t) ((uintptr_t)new_srqinfo.qa_buf_aligned & HERMON_PAGEOFFSET); /* * Fill in the MPT entry. This is the final step before passing * ownership of the MPT entry to the Hermon hardware. We use all of * the information collected/calculated above to fill in the * requisite portions of the MPT. */ bzero(&mpt_entry, sizeof (hermon_hw_dmpt_t)); mpt_entry.reg_win_len = bind.bi_len; mtt_addr = (mtt->hr_indx << HERMON_MTT_SIZE_SHIFT); mpt_entry.mtt_addr_h = mtt_addr >> 32; mpt_entry.mtt_addr_l = mtt_addr >> 3; /* * for hermon we build up a new srqc and pass that (partially filled * to resize SRQ instead of modifying the (d)mpt directly */ /* * Now we grab the SRQ lock. Since we will be updating the actual * SRQ location and the producer/consumer indexes, we should hold * the lock. * * We do a HERMON_NOSLEEP here (and below), though, because we are * holding the "srq_lock" and if we got raised to interrupt level * by priority inversion, we would not want to block in this routine * waiting for success. */ mutex_enter(&srq->srq_lock); /* * Copy old entries to new buffer */ srq_old_bufsz = srq->srq_wq_bufsz; bcopy(srq->srq_wq_buf, buf, srq_old_bufsz * wqesz); /* * Setup MPT information for use in the MODIFY_MPT command */ mr = srq->srq_mrhdl; mutex_enter(&mr->mr_lock); /* * now, setup the srqc information needed for resize - limit the * values, but use the same structure as the srqc */ srqc_entry.log_srq_size = log_srq_size; srqc_entry.page_offs = srq_pgoffs >> 6; srqc_entry.log2_pgsz = mr->mr_log2_pgsz; srqc_entry.mtt_base_addrl = (uint64_t)mtt_addr >> 32; srqc_entry.mtt_base_addrh = mtt_addr >> 3; /* * RESIZE_SRQ * * If this fails for any reason, then it is an indication that * something (either in HW or SW) has gone seriously wrong. So we * print a warning message and return. */ status = hermon_resize_srq_cmd_post(state, &srqc_entry, srq->srq_srqnum, sleepflag); if (status != HERMON_CMD_SUCCESS) { cmn_err(CE_CONT, "Hermon: RESIZE_SRQ command failed: %08x\n", status); if (status == HERMON_CMD_INVALID_STATUS) { hermon_fm_ereport(state, HCA_SYS_ERR, HCA_ERR_SRV_LOST); } (void) hermon_mr_mtt_unbind(state, &bind, mtt); kmem_free(wre_new, (1 << log_srq_size) * sizeof (uint64_t)); hermon_queue_free(&new_srqinfo); mutex_exit(&mr->mr_lock); mutex_exit(&srq->srq_lock); return (ibc_get_ci_failure(0)); } /* * Update the Hermon Shared Receive Queue handle with all the new * information. At the same time, save away all the necessary * information for freeing up the old resources */ old_srqinfo = srq->srq_wqinfo; old_mtt = srq->srq_mrhdl->mr_mttrsrcp; bcopy(&srq->srq_mrhdl->mr_bindinfo, &old_bind, sizeof (hermon_bind_info_t)); /* Now set the new info */ srq->srq_wqinfo = new_srqinfo; srq->srq_wq_buf = buf; srq->srq_wq_bufsz = (1 << log_srq_size); bcopy(&bind, &srq->srq_mrhdl->mr_bindinfo, sizeof (hermon_bind_info_t)); srq->srq_mrhdl->mr_mttrsrcp = mtt; srq->srq_desc_off = srq_desc_off; srq->srq_real_sizes.srq_wr_sz = (1 << log_srq_size); /* Update MR mtt pagesize */ mr->mr_logmttpgsz = mtt_pgsize_bits; mutex_exit(&mr->mr_lock); /* * Initialize new wridlist, if needed. * * If a wridlist already is setup on an SRQ (the QP associated with an * SRQ has moved "from_reset") then we must update this wridlist based * on the new SRQ size. We allocate the new size of Work Request ID * Entries, copy over the old entries to the new list, and * re-initialize the srq wridlist in non-umap case */ wre_old = srq->srq_wq_wqhdr->wq_wrid; bcopy(wre_old, wre_new, srq_old_bufsz * sizeof (uint64_t)); /* Setup new sizes in wre */ srq->srq_wq_wqhdr->wq_wrid = wre_new; /* * If "old" SRQ was a user-mappable SRQ that is currently mmap()'d out * to a user process, then we need to call devmap_devmem_remap() to * invalidate the mapping to the SRQ memory. We also need to * invalidate the SRQ tracking information for the user mapping. * * Note: On failure, the remap really shouldn't ever happen. So, if it * does, it is an indication that something has gone seriously wrong. * So we print a warning message and return error (knowing, of course, * that the "old" SRQ memory will be leaked) */ if ((srq->srq_is_umap) && (srq->srq_umap_dhp != NULL)) { maxprot = (PROT_READ | PROT_WRITE | PROT_USER); status = devmap_devmem_remap(srq->srq_umap_dhp, state->hs_dip, 0, 0, srq->srq_wqinfo.qa_size, maxprot, DEVMAP_MAPPING_INVALID, NULL); if (status != DDI_SUCCESS) { mutex_exit(&srq->srq_lock); HERMON_WARNING(state, "failed in SRQ memory " "devmap_devmem_remap()"); /* We can, however, free the memory for old wre */ kmem_free(wre_old, srq_old_bufsz * sizeof (uint64_t)); return (ibc_get_ci_failure(0)); } srq->srq_umap_dhp = (devmap_cookie_t)NULL; } /* * Drop the SRQ lock now. The only thing left to do is to free up * the old resources. */ mutex_exit(&srq->srq_lock); /* * Unbind the MTT entries. */ status = hermon_mr_mtt_unbind(state, &old_bind, old_mtt); if (status != DDI_SUCCESS) { HERMON_WARNING(state, "failed to unbind old SRQ memory"); status = ibc_get_ci_failure(0); goto srqmodify_fail; } /* Free the memory for old wre */ kmem_free(wre_old, srq_old_bufsz * sizeof (uint64_t)); /* Free the memory for the old SRQ */ hermon_queue_free(&old_srqinfo); /* * Fill in the return arguments (if necessary). This includes the * real new completion queue size. */ if (real_size != NULL) { *real_size = (1 << log_srq_size); } return (DDI_SUCCESS); srqmodify_fail: return (status); } /* * hermon_srq_refcnt_inc() * Context: Can be called from interrupt or base context. */ void hermon_srq_refcnt_inc(hermon_srqhdl_t srq) { mutex_enter(&srq->srq_lock); srq->srq_refcnt++; mutex_exit(&srq->srq_lock); } /* * hermon_srq_refcnt_dec() * Context: Can be called from interrupt or base context. */ void hermon_srq_refcnt_dec(hermon_srqhdl_t srq) { mutex_enter(&srq->srq_lock); srq->srq_refcnt--; mutex_exit(&srq->srq_lock); } /* * hermon_srqhdl_from_srqnum() * Context: Can be called from interrupt or base context. * * This routine is important because changing the unconstrained * portion of the SRQ number is critical to the detection of a * potential race condition in the SRQ handler code (i.e. the case * where a SRQ is freed and alloc'd again before an event for the * "old" SRQ can be handled). * * While this is not a perfect solution (not sure that one exists) * it does help to mitigate the chance that this race condition will * cause us to deliver a "stale" event to the new SRQ owner. Note: * this solution does not scale well because the number of constrained * bits increases (and, hence, the number of unconstrained bits * decreases) as the number of supported SRQ grows. For small and * intermediate values, it should hopefully provide sufficient * protection. */ hermon_srqhdl_t hermon_srqhdl_from_srqnum(hermon_state_t *state, uint_t srqnum) { uint_t srqindx, srqmask; /* Calculate the SRQ table index from the srqnum */ srqmask = (1 << state->hs_cfg_profile->cp_log_num_srq) - 1; srqindx = srqnum & srqmask; return (hermon_icm_num_to_hdl(state, HERMON_SRQC, srqindx)); } /* * hermon_srq_sgl_to_logwqesz() * Context: Can be called from interrupt or base context. */ static void hermon_srq_sgl_to_logwqesz(hermon_state_t *state, uint_t num_sgl, hermon_qp_wq_type_t wq_type, uint_t *logwqesz, uint_t *max_sgl) { uint_t max_size, log2, actual_sgl; switch (wq_type) { case HERMON_QP_WQ_TYPE_RECVQ: /* * Use requested maximum SGL to calculate max descriptor size * (while guaranteeing that the descriptor size is a * power-of-2 cachelines). */ max_size = (HERMON_QP_WQE_MLX_SRQ_HDRS + (num_sgl << 4)); log2 = highbit(max_size); if (ISP2(max_size)) { log2 = log2 - 1; } /* Make sure descriptor is at least the minimum size */ log2 = max(log2, HERMON_QP_WQE_LOG_MINIMUM); /* Calculate actual number of SGL (given WQE size) */ actual_sgl = ((1 << log2) - HERMON_QP_WQE_MLX_SRQ_HDRS) >> 4; break; default: HERMON_WARNING(state, "unexpected work queue type"); break; } /* Fill in the return values */ *logwqesz = log2; *max_sgl = min(state->hs_cfg_profile->cp_srq_max_sgl, actual_sgl); }