/* * @file Broadcom Dongle Host Driver (DHD), Flow ring specific code at top level * * Flow rings are transmit traffic (=propagating towards antenna) related entities * * * Copyright (C) 2021, Broadcom. * * Unless you and Broadcom execute a separate written software license * agreement governing use of this software, this software is licensed to you * under the terms of the GNU General Public License version 2 (the "GPL"), * available at http://www.broadcom.com/licenses/GPLv2.php, with the * following added to such license: * * As a special exception, the copyright holders of this software give you * permission to link this software with independent modules, and to copy and * distribute the resulting executable under terms of your choice, provided that * you also meet, for each linked independent module, the terms and conditions of * the license of that module. An independent module is a module which is not * derived from this software. The special exception does not apply to any * modifications of the software. * * * <> * * $Id$ */ /** XXX Twiki: [PCIeFullDongleArchitecture] */ #include #include #include #include #include #include #include #include #include #include #include #include #include <802.1d.h> #include #include #include static INLINE int dhd_flow_queue_throttle(flow_queue_t *queue); static INLINE uint16 dhd_flowid_find(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da); static INLINE uint16 dhd_flowid_alloc(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da); static INLINE int dhd_flowid_lookup(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da, uint16 *flowid); int dhd_flow_queue_overflow(flow_queue_t *queue, void *pkt); #define FLOW_QUEUE_PKT_NEXT(p) PKTLINK(p) #define FLOW_QUEUE_PKT_SETNEXT(p, x) PKTSETLINK((p), (x)) const uint8 prio2ac[8] = { 0, 1, 1, 0, 2, 2, 3, 3 }; const uint8 prio2tid[8] = { 0, 1, 2, 3, 4, 5, 6, 7 }; /** Queue overflow throttle. Return value: TRUE if throttle needs to be applied */ static INLINE int dhd_flow_queue_throttle(flow_queue_t *queue) { #if defined(BCM_ROUTER_DHD) /* Two tests * 1) Test whether overall level 2 (grandparent) cummulative threshold crossed. * 2) Or test whether queue's budget and overall cummulative threshold crossed. */ void *gp_clen_ptr = DHD_FLOW_QUEUE_L2CLEN_PTR(queue); void *parent_clen_ptr = DHD_FLOW_QUEUE_CLEN_PTR(queue); int gp_cumm_threshold = DHD_FLOW_QUEUE_L2THRESHOLD(queue); int cumm_threshold = DHD_FLOW_QUEUE_THRESHOLD(queue); int ret = ((DHD_CUMM_CTR_READ(gp_clen_ptr) > gp_cumm_threshold) || ((DHD_FLOW_QUEUE_OVFL(queue, DHD_FLOW_QUEUE_MAX(queue))) && (DHD_CUMM_CTR_READ(parent_clen_ptr) > cumm_threshold))); return ret; #else return DHD_FLOW_QUEUE_FULL(queue); #endif /* ! BCM_ROUTER_DHD */ } int BCMFASTPATH(dhd_flow_queue_overflow)(flow_queue_t *queue, void *pkt) { return BCME_NORESOURCE; } /** Returns flow ring given a flowid */ flow_ring_node_t * dhd_flow_ring_node(dhd_pub_t *dhdp, uint16 flowid) { flow_ring_node_t * flow_ring_node; ASSERT(dhdp != (dhd_pub_t*)NULL); ASSERT(flowid <= dhdp->max_tx_flowid); if (flowid > dhdp->max_tx_flowid) { return NULL; } flow_ring_node = &(((flow_ring_node_t*)(dhdp->flow_ring_table))[flowid]); ASSERT(flow_ring_node->flowid == flowid); return flow_ring_node; } /** Returns 'backup' queue given a flowid */ flow_queue_t * dhd_flow_queue(dhd_pub_t *dhdp, uint16 flowid) { flow_ring_node_t * flow_ring_node = NULL; flow_ring_node = dhd_flow_ring_node(dhdp, flowid); if (flow_ring_node) return &flow_ring_node->queue; else return NULL; } /* Flow ring's queue management functions */ /** Reinitialize a flow ring's queue. */ void dhd_flow_queue_reinit(dhd_pub_t *dhdp, flow_queue_t *queue, int max) { ASSERT((queue != NULL) && (max > 0)); queue->head = queue->tail = NULL; queue->len = 0; /* Set queue's threshold and queue's parent cummulative length counter */ ASSERT(max > 1); DHD_FLOW_QUEUE_SET_MAX(queue, max); DHD_FLOW_QUEUE_SET_THRESHOLD(queue, max); DHD_FLOW_QUEUE_SET_CLEN(queue, &dhdp->cumm_ctr); DHD_FLOW_QUEUE_SET_L2CLEN(queue, &dhdp->l2cumm_ctr); queue->failures = 0U; queue->cb = &dhd_flow_queue_overflow; } /** Initialize a flow ring's queue, called on driver initialization. */ void dhd_flow_queue_init(dhd_pub_t *dhdp, flow_queue_t *queue, int max) { ASSERT((queue != NULL) && (max > 0)); dll_init(&queue->list); dhd_flow_queue_reinit(dhdp, queue, max); } /** Register an enqueue overflow callback handler */ void dhd_flow_queue_register(flow_queue_t *queue, flow_queue_cb_t cb) { ASSERT(queue != NULL); queue->cb = cb; } /** * Enqueue an 802.3 packet at the back of a flow ring's queue. From there, it will travel later on * to the flow ring itself. */ int BCMFASTPATH(dhd_flow_queue_enqueue)(dhd_pub_t *dhdp, flow_queue_t *queue, void *pkt) { int ret = BCME_OK; ASSERT(queue != NULL); if (dhd_flow_queue_throttle(queue)) { queue->failures++; ret = (*queue->cb)(queue, pkt); goto done; } if (queue->head) { FLOW_QUEUE_PKT_SETNEXT(queue->tail, pkt); } else { queue->head = pkt; } FLOW_QUEUE_PKT_SETNEXT(pkt, NULL); queue->tail = pkt; /* at tail */ queue->len++; /* increment parent's cummulative length */ DHD_CUMM_CTR_INCR(DHD_FLOW_QUEUE_CLEN_PTR(queue)); /* increment grandparent's cummulative length */ DHD_CUMM_CTR_INCR(DHD_FLOW_QUEUE_L2CLEN_PTR(queue)); done: return ret; } /** Dequeue an 802.3 packet from a flow ring's queue, from head (FIFO) */ void * BCMFASTPATH(dhd_flow_queue_dequeue)(dhd_pub_t *dhdp, flow_queue_t *queue) { void * pkt; ASSERT(queue != NULL); pkt = queue->head; /* from head */ if (pkt == NULL) { goto done; } queue->head = FLOW_QUEUE_PKT_NEXT(pkt); if (queue->head == NULL) queue->tail = NULL; queue->len--; /* decrement parent's cummulative length */ DHD_CUMM_CTR_DECR(DHD_FLOW_QUEUE_CLEN_PTR(queue)); /* decrement grandparent's cummulative length */ DHD_CUMM_CTR_DECR(DHD_FLOW_QUEUE_L2CLEN_PTR(queue)); FLOW_QUEUE_PKT_SETNEXT(pkt, NULL); /* dettach packet from queue */ done: return pkt; } /** Reinsert a dequeued 802.3 packet back at the head */ void BCMFASTPATH(dhd_flow_queue_reinsert)(dhd_pub_t *dhdp, flow_queue_t *queue, void *pkt) { if (queue->head == NULL) { queue->tail = pkt; } FLOW_QUEUE_PKT_SETNEXT(pkt, queue->head); queue->head = pkt; queue->len++; /* increment parent's cummulative length */ DHD_CUMM_CTR_INCR(DHD_FLOW_QUEUE_CLEN_PTR(queue)); /* increment grandparent's cummulative length */ DHD_CUMM_CTR_INCR(DHD_FLOW_QUEUE_L2CLEN_PTR(queue)); } /** Fetch the backup queue for a flowring, and assign flow control thresholds */ void dhd_flow_ring_config_thresholds(dhd_pub_t *dhdp, uint16 flowid, int queue_budget, int cumm_threshold, void *cumm_ctr, int l2cumm_threshold, void *l2cumm_ctr) { flow_queue_t * queue = NULL; ASSERT(dhdp != (dhd_pub_t*)NULL); ASSERT(queue_budget > 1); ASSERT(cumm_threshold > 1); ASSERT(cumm_ctr != (void*)NULL); ASSERT(l2cumm_threshold > 1); ASSERT(l2cumm_ctr != (void*)NULL); queue = dhd_flow_queue(dhdp, flowid); if (queue) { DHD_FLOW_QUEUE_SET_MAX(queue, queue_budget); /* Max queue length */ /* Set the queue's parent threshold and cummulative counter */ DHD_FLOW_QUEUE_SET_THRESHOLD(queue, cumm_threshold); DHD_FLOW_QUEUE_SET_CLEN(queue, cumm_ctr); /* Set the queue's grandparent threshold and cummulative counter */ DHD_FLOW_QUEUE_SET_L2THRESHOLD(queue, l2cumm_threshold); DHD_FLOW_QUEUE_SET_L2CLEN(queue, l2cumm_ctr); } } /* * This function returns total number of flowrings that can be created for a INFRA STA. * For prio2ac mapping, it will return 4, prio2ac[8] = { 0, 1, 1, 0, 2, 2, 3, 3 } * For prio2tid mapping, it will return 8, prio2tid[8] = { 0, 1, 2, 3, 4, 5, 6, 7 } */ uint8 dhd_num_prio_supported_per_flow_ring(dhd_pub_t *dhdp) { uint8 prio_count = 0; int i; /* Pick all elements one by one */ for (i = 0; i < NUMPRIO; i++) { /* Check if the picked element is already counted */ int j; for (j = 0; j < i; j++) { if (dhdp->flow_prio_map[i] == dhdp->flow_prio_map[j]) { break; } } /* If not counted earlier, then count it */ if (i == j) { prio_count++; } } return prio_count; } uint8 dhd_get_max_multi_client_flow_rings(dhd_pub_t *dhdp) { uint8 reserved_infra_sta_flow_rings = dhd_num_prio_supported_per_flow_ring(dhdp); uint8 total_tx_flow_rings = (uint8)dhd_get_max_flow_rings(dhdp); uint8 max_multi_client_flow_rings = total_tx_flow_rings - reserved_infra_sta_flow_rings; return max_multi_client_flow_rings; } int dhd_flowid_map_init(dhd_pub_t *dhdp, uint16 max_tx_flow_rings) { uint16 max_normal_tx_flow_rings = max_tx_flow_rings; if (dhdp->htput_support) { max_normal_tx_flow_rings = max_tx_flow_rings - HTPUT_TOTAL_FLOW_RINGS; } /* Construct a normal flowid allocator from FLOWID_RESERVED to * (max_normal_tx_flow_rings - 1) */ dhdp->flowid_allocator = id16_map_init(dhdp->osh, max_normal_tx_flow_rings, FLOWID_RESERVED); if (dhdp->flowid_allocator == NULL) { DHD_ERROR(("%s: flowid allocator init failure\n", __FUNCTION__)); return BCME_NOMEM; } dhdp->htput_flowid_allocator = NULL; if (dhdp->htput_support) { if (HTPUT_TOTAL_FLOW_RINGS > 0) { dhdp->htput_flow_ring_start = max_normal_tx_flow_rings + FLOWID_RESERVED; /* Construct a htput flowid allocator from htput_flow_ring_start to * (htput_flow_ring_start + HTPUT_TOTAL_FLOW_RINGS - 1) */ dhdp->htput_flowid_allocator = id16_map_init(dhdp->osh, HTPUT_TOTAL_FLOW_RINGS, dhdp->htput_flow_ring_start); if (dhdp->htput_flowid_allocator == NULL) { DHD_ERROR(("%s: htput flowid allocator init failure\n", __FUNCTION__)); return BCME_NOMEM; } dhdp->htput_client_flow_rings = 0u; } } return BCME_OK; } void dhd_flowid_map_deinit(dhd_pub_t *dhdp) { if (dhdp->flowid_allocator) { dhdp->flowid_allocator = id16_map_fini(dhdp->osh, dhdp->flowid_allocator); } ASSERT(dhdp->flowid_allocator == NULL); if (dhdp->htput_flowid_allocator) { dhdp->htput_flowid_allocator = id16_map_fini(dhdp->osh, dhdp->htput_flowid_allocator); ASSERT(dhdp->htput_flowid_allocator == NULL); } dhdp->htput_client_flow_rings = 0u; return; } /** Initializes data structures of multiple flow rings * num_h2d_rings - max_h2d_rings including static and dynamic rings */ int dhd_flow_rings_init(dhd_pub_t *dhdp, uint32 num_h2d_rings) { uint32 idx; uint32 flow_ring_table_sz = 0; uint32 if_flow_lkup_sz = 0; flow_ring_table_t *flow_ring_table = NULL; if_flow_lkup_t *if_flow_lkup = NULL; void *lock = NULL; void *list_lock = NULL; unsigned long flags; uint16 max_tx_flow_rings; DHD_INFO(("%s\n", __FUNCTION__)); /* * Only 16-bit flowid map will be allocated for actual number of Tx flowrings * excluding common rings. * Rest all flowring data structure will be allocated for all num_h2d_rings. */ max_tx_flow_rings = dhd_get_max_flow_rings(dhdp); if (dhd_flowid_map_init(dhdp, max_tx_flow_rings) != BCME_OK) { DHD_ERROR(("%s: dhd_flowid_map_init failure\n", __FUNCTION__)); goto fail; } /* Any Tx flow id should not be > max_tx_flowid */ dhdp->max_tx_flowid = max_tx_flow_rings + FLOWID_RESERVED - 1; /* Allocate a flow ring table, comprising of requested number of rings */ flow_ring_table_sz = (num_h2d_rings * sizeof(flow_ring_node_t)); flow_ring_table = (flow_ring_table_t *)MALLOCZ(dhdp->osh, flow_ring_table_sz); if (flow_ring_table == NULL) { DHD_ERROR(("%s: flow ring table alloc failure\n", __FUNCTION__)); goto fail; } /* Initialize flow ring table state */ DHD_CUMM_CTR_INIT(&dhdp->cumm_ctr); DHD_CUMM_CTR_INIT(&dhdp->l2cumm_ctr); bzero((uchar *)flow_ring_table, flow_ring_table_sz); for (idx = 0; idx < num_h2d_rings; idx++) { flow_ring_table[idx].status = FLOW_RING_STATUS_CLOSED; flow_ring_table[idx].flowid = (uint16)idx; flow_ring_table[idx].lock = osl_spin_lock_init(dhdp->osh); #ifdef IDLE_TX_FLOW_MGMT flow_ring_table[idx].last_active_ts = OSL_SYSUPTIME(); #endif /* IDLE_TX_FLOW_MGMT */ if (flow_ring_table[idx].lock == NULL) { DHD_ERROR(("%s: Failed to init spinlock for queue!\n", __FUNCTION__)); goto fail; } dll_init(&flow_ring_table[idx].list); /* Initialize the per flow ring backup queue */ dhd_flow_queue_init(dhdp, &flow_ring_table[idx].queue, FLOW_RING_QUEUE_THRESHOLD); } /* Allocate per interface hash table (for fast lookup from interface to flow ring) */ if_flow_lkup_sz = sizeof(if_flow_lkup_t) * DHD_MAX_IFS; if_flow_lkup = (if_flow_lkup_t *)DHD_OS_PREALLOC(dhdp, DHD_PREALLOC_IF_FLOW_LKUP, if_flow_lkup_sz); if (if_flow_lkup == NULL) { DHD_ERROR(("%s: if flow lkup alloc failure\n", __FUNCTION__)); goto fail; } /* Initialize per interface hash table */ for (idx = 0; idx < DHD_MAX_IFS; idx++) { int hash_ix; if_flow_lkup[idx].status = 0; if_flow_lkup[idx].role = 0; for (hash_ix = 0; hash_ix < DHD_FLOWRING_HASH_SIZE; hash_ix++) if_flow_lkup[idx].fl_hash[hash_ix] = NULL; } lock = osl_spin_lock_init(dhdp->osh); if (lock == NULL) goto fail; list_lock = osl_spin_lock_init(dhdp->osh); if (list_lock == NULL) goto lock_fail; dhdp->flow_prio_map_type = DHD_FLOW_PRIO_AC_MAP; bcopy(prio2ac, dhdp->flow_prio_map, sizeof(uint8) * NUMPRIO); dhdp->max_multi_client_flow_rings = dhd_get_max_multi_client_flow_rings(dhdp); OSL_ATOMIC_INIT(dhdp->osh, &dhdp->multi_client_flow_rings); #ifdef DHD_LOSSLESS_ROAMING dhdp->dequeue_prec_map = ALLPRIO; #endif /* Now populate into dhd pub */ DHD_FLOWID_LOCK(lock, flags); dhdp->num_h2d_rings = num_h2d_rings; dhdp->flow_ring_table = (void *)flow_ring_table; dhdp->if_flow_lkup = (void *)if_flow_lkup; dhdp->flowid_lock = lock; dhdp->flow_rings_inited = TRUE; dhdp->flowring_list_lock = list_lock; DHD_FLOWID_UNLOCK(lock, flags); DHD_INFO(("%s done\n", __FUNCTION__)); return BCME_OK; lock_fail: /* deinit the spinlock */ osl_spin_lock_deinit(dhdp->osh, lock); fail: /* Destruct the per interface flow lkup table */ if (if_flow_lkup != NULL) { DHD_OS_PREFREE(dhdp, if_flow_lkup, if_flow_lkup_sz); } if (flow_ring_table != NULL) { for (idx = 0; idx < num_h2d_rings; idx++) { if (flow_ring_table[idx].lock != NULL) osl_spin_lock_deinit(dhdp->osh, flow_ring_table[idx].lock); } MFREE(dhdp->osh, flow_ring_table, flow_ring_table_sz); } dhd_flowid_map_deinit(dhdp); return BCME_NOMEM; } /** Deinit Flow Ring specific data structures */ void dhd_flow_rings_deinit(dhd_pub_t *dhdp) { uint16 idx; uint32 flow_ring_table_sz; uint32 if_flow_lkup_sz; flow_ring_table_t *flow_ring_table; unsigned long flags; void *lock; DHD_INFO(("dhd_flow_rings_deinit\n")); if (!(dhdp->flow_rings_inited)) { DHD_ERROR(("dhd_flow_rings not initialized!\n")); return; } if (dhdp->flow_ring_table != NULL) { ASSERT(dhdp->num_h2d_rings > 0); DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; dhdp->flow_ring_table = NULL; DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); for (idx = 0; idx < dhdp->num_h2d_rings; idx++) { if (flow_ring_table[idx].active) { dhd_bus_clean_flow_ring(dhdp->bus, &flow_ring_table[idx]); } ASSERT(DHD_FLOW_QUEUE_EMPTY(&flow_ring_table[idx].queue)); /* Deinit flow ring queue locks before destroying flow ring table */ if (flow_ring_table[idx].lock != NULL) { osl_spin_lock_deinit(dhdp->osh, flow_ring_table[idx].lock); } flow_ring_table[idx].lock = NULL; } /* Destruct the flow ring table */ flow_ring_table_sz = dhdp->num_h2d_rings * sizeof(flow_ring_table_t); MFREE(dhdp->osh, flow_ring_table, flow_ring_table_sz); } DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); /* Destruct the per interface flow lkup table */ if (dhdp->if_flow_lkup != NULL) { if_flow_lkup_sz = sizeof(if_flow_lkup_t) * DHD_MAX_IFS; bzero((uchar *)dhdp->if_flow_lkup, if_flow_lkup_sz); DHD_OS_PREFREE(dhdp, dhdp->if_flow_lkup, if_flow_lkup_sz); dhdp->if_flow_lkup = NULL; } /* Destruct the flowid allocator */ dhd_flowid_map_deinit(dhdp); dhdp->num_h2d_rings = 0U; bzero(dhdp->flow_prio_map, sizeof(uint8) * NUMPRIO); dhdp->max_multi_client_flow_rings = 0U; OSL_ATOMIC_INIT(dhdp->osh, &dhdp->multi_client_flow_rings); lock = dhdp->flowid_lock; dhdp->flowid_lock = NULL; if (lock) { DHD_FLOWID_UNLOCK(lock, flags); osl_spin_lock_deinit(dhdp->osh, lock); } osl_spin_lock_deinit(dhdp->osh, dhdp->flowring_list_lock); dhdp->flowring_list_lock = NULL; ASSERT(dhdp->if_flow_lkup == NULL); ASSERT(dhdp->flow_ring_table == NULL); dhdp->flow_rings_inited = FALSE; } /** Uses hash table to quickly map from ifindex to a flow ring 'role' (STA/AP) */ uint8 dhd_flow_rings_ifindex2role(dhd_pub_t *dhdp, uint8 ifindex) { if_flow_lkup_t *if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; ASSERT(if_flow_lkup); return if_flow_lkup[ifindex].role; } #ifdef WLTDLS bool is_tdls_destination(dhd_pub_t *dhdp, uint8 *da) { unsigned long flags; tdls_peer_node_t *cur = NULL; DHD_TDLS_LOCK(&dhdp->tdls_lock, flags); /* Check only if tdls peer is added */ if (dhdp->peer_tbl.tdls_peer_count && !(ETHER_ISMULTI(da))) { cur = dhdp->peer_tbl.node; while (cur != NULL) { if (!memcmp(da, cur->addr, ETHER_ADDR_LEN)) { DHD_TDLS_UNLOCK(&dhdp->tdls_lock, flags); return TRUE; } cur = cur->next; } } DHD_TDLS_UNLOCK(&dhdp->tdls_lock, flags); return FALSE; } #endif /* WLTDLS */ /** Uses hash table to quickly map from ifindex+prio+da to a flow ring id */ static INLINE uint16 dhd_flowid_find(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da) { int hash; bool ismcast = FALSE; flow_hash_info_t *cur; if_flow_lkup_t *if_flow_lkup; unsigned long flags; ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return FLOWID_INVALID; DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; ASSERT(if_flow_lkup); if (DHD_IF_ROLE_GENERIC_STA(dhdp, ifindex)) { #ifdef WLTDLS if (is_tdls_destination(dhdp, da)) { hash = DHD_FLOWRING_HASHINDEX(da, prio); cur = if_flow_lkup[ifindex].fl_hash[hash]; while (cur != NULL) { if (!memcmp(cur->flow_info.da, da, ETHER_ADDR_LEN)) { DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return cur->flowid; } cur = cur->next; } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return FLOWID_INVALID; } #endif /* WLTDLS */ /* For STA non TDLS dest and WDS dest flow ring id is mapped based on prio only */ cur = if_flow_lkup[ifindex].fl_hash[prio]; if (cur) { DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return cur->flowid; } } else { if (ETHER_ISMULTI(da) && TRUE) { ismcast = TRUE; hash = 0; } else { hash = DHD_FLOWRING_HASHINDEX(da, prio); } cur = if_flow_lkup[ifindex].fl_hash[hash]; while (cur) { if ((ismcast && ETHER_ISMULTI(cur->flow_info.da)) || (!memcmp(cur->flow_info.da, da, ETHER_ADDR_LEN) && (cur->flow_info.tid == prio))) { DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return cur->flowid; } cur = cur->next; } } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); #ifdef DHD_EFI DHD_TRACE(("%s: cannot find flowid\n", __FUNCTION__)); #else DHD_INFO(("%s: cannot find flowid\n", __FUNCTION__)); #endif return FLOWID_INVALID; } /* dhd_flowid_find */ static uint16 dhd_flowid_map_alloc(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *da) { uint16 flowid = FLOWID_INVALID; ASSERT(dhdp->flowid_allocator != NULL); /* P2P Connections are always 80Mhz */ if (DHD_IF_ROLE_P2PGC(dhdp, ifindex) || DHD_IF_ROLE_P2PGO(dhdp, ifindex)) { flowid = id16_map_alloc(dhdp->flowid_allocator); return flowid; } if (dhdp->htput_flowid_allocator) { if (prio == HTPUT_FLOW_RING_PRIO) { if (DHD_IF_ROLE_GENERIC_STA(dhdp, ifindex)) { /* For STA case, only one flowring per PRIO is created, * so no need to have a HTPUT counter variable for STA case. * If already HTPUT flowring is allocated for given HTPUT_PRIO, * then this function will not even get called as dhd_flowid_find * will take care assigning same for those HTPUT_PRIO packets. */ flowid = id16_map_alloc(dhdp->htput_flowid_allocator); } else if (DHD_IF_ROLE_MULTI_CLIENT(dhdp, ifindex) && !ETHER_ISMULTI(da) && dhd_is_sta_htput(dhdp, ifindex, (uint8 *)da)) { /* Use HTPUT flowrings for only HTPUT_NUM_CLIENT_FLOW_RINGS */ if (dhdp->htput_client_flow_rings < HTPUT_NUM_CLIENT_FLOW_RINGS) { flowid = id16_map_alloc(dhdp->htput_flowid_allocator); /* increment htput client counter */ if (flowid != FLOWID_INVALID) { dhdp->htput_client_flow_rings++; } } } } } BCM_REFERENCE(flowid); /* * For HTPUT case, if the high throughput flowrings are already allocated * for the given role, the control comes here. */ if (flowid == FLOWID_INVALID) { flowid = id16_map_alloc(dhdp->flowid_allocator); } return flowid; } /** Create unique Flow ID, called when a flow ring is created. */ static INLINE uint16 dhd_flowid_alloc(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da) { flow_hash_info_t *fl_hash_node, *cur; if_flow_lkup_t *if_flow_lkup; int hash; uint16 flowid; unsigned long flags; fl_hash_node = (flow_hash_info_t *) MALLOCZ(dhdp->osh, sizeof(flow_hash_info_t)); if (fl_hash_node == NULL) { DHD_ERROR(("%s: flow_hash_info_t memory allocation failed \n", __FUNCTION__)); return FLOWID_INVALID; } memcpy(fl_hash_node->flow_info.da, da, sizeof(fl_hash_node->flow_info.da)); DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); flowid = dhd_flowid_map_alloc(dhdp, ifindex, prio, da); DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); if (flowid == FLOWID_INVALID) { MFREE(dhdp->osh, fl_hash_node, sizeof(flow_hash_info_t)); DHD_ERROR_RLMT(("%s: cannot get free flowid \n", __FUNCTION__)); return FLOWID_INVALID; } fl_hash_node->flowid = flowid; fl_hash_node->flow_info.tid = prio; fl_hash_node->flow_info.ifindex = ifindex; fl_hash_node->next = NULL; DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; if (DHD_IF_ROLE_GENERIC_STA(dhdp, ifindex)) { /* For STA/GC non TDLS dest and WDS dest we allocate entry based on prio only */ #ifdef WLTDLS if (is_tdls_destination(dhdp, da)) { hash = DHD_FLOWRING_HASHINDEX(da, prio); cur = if_flow_lkup[ifindex].fl_hash[hash]; if (cur) { while (cur->next) { cur = cur->next; } cur->next = fl_hash_node; } else { if_flow_lkup[ifindex].fl_hash[hash] = fl_hash_node; } } else #endif /* WLTDLS */ if_flow_lkup[ifindex].fl_hash[prio] = fl_hash_node; } else { /* For bcast/mcast assign first slot in in interface */ hash = (ETHER_ISMULTI(da) && TRUE) ? 0 : DHD_FLOWRING_HASHINDEX(da, prio); cur = if_flow_lkup[ifindex].fl_hash[hash]; if (cur) { while (cur->next) { cur = cur->next; } cur->next = fl_hash_node; } else if_flow_lkup[ifindex].fl_hash[hash] = fl_hash_node; } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); DHD_INFO(("%s: allocated flowid %d\n", __FUNCTION__, fl_hash_node->flowid)); if (fl_hash_node->flowid > dhdp->max_tx_flowid) { DHD_ERROR(("%s: flowid=%d max_tx_flowid=%d ifindex=%d prio=%d role=%d\n", __FUNCTION__, fl_hash_node->flowid, dhdp->max_tx_flowid, ifindex, prio, if_flow_lkup[ifindex].role)); dhd_prhex("da", (uchar *)da, ETHER_ADDR_LEN, DHD_ERROR_VAL); dhd_prhex("sa", (uchar *)sa, ETHER_ADDR_LEN, DHD_ERROR_VAL); return FLOWID_INVALID; } return fl_hash_node->flowid; } /* dhd_flowid_alloc */ /** Get flow ring ID, if not present try to create one */ static INLINE int dhd_flowid_lookup(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da, uint16 *flowid) { uint16 id; flow_ring_node_t *flow_ring_node; flow_ring_table_t *flow_ring_table; unsigned long flags; int ret; DHD_TRACE(("%s\n", __FUNCTION__)); if (!dhdp->flow_ring_table) { return BCME_ERROR; } ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return BCME_BADARG; flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; id = dhd_flowid_find(dhdp, ifindex, prio, sa, da); if (id == FLOWID_INVALID || (id > dhdp->max_tx_flowid)) { bool if_role_multi_client; if_flow_lkup_t *if_flow_lkup; if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; if (!if_flow_lkup[ifindex].status) return BCME_ERROR; /* check role for multi client case */ if_role_multi_client = DHD_IF_ROLE_MULTI_CLIENT(dhdp, ifindex); /* Abort Flowring creation if multi client flowrings crossed the threshold */ #ifdef DHD_LIMIT_MULTI_CLIENT_FLOWRINGS if (if_role_multi_client && (OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings) >= dhdp->max_multi_client_flow_rings)) { DHD_ERROR_RLMT(("%s: Max multi client flow rings reached: %d:%d\n", __FUNCTION__, OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings), dhdp->max_multi_client_flow_rings)); return BCME_ERROR; } #endif /* DHD_LIMIT_MULTI_CLIENT_FLOWRINGS */ /* Do not create Flowring if peer is not associated */ #if (defined(linux) || defined(LINUX)) && defined(PCIE_FULL_DONGLE) if (if_role_multi_client && !ETHER_ISMULTI(da) && !dhd_sta_associated(dhdp, ifindex, (uint8 *)da)) { DHD_ERROR_RLMT(("%s: Skip send pkt without peer addition\n", __FUNCTION__)); return BCME_ERROR; } #endif /* (linux || LINUX) && PCIE_FULL_DONGLE */ id = dhd_flowid_alloc(dhdp, ifindex, prio, sa, da); if (id == FLOWID_INVALID) { DHD_ERROR_RLMT(("%s: alloc flowid ifindex %u status %u\n", __FUNCTION__, ifindex, if_flow_lkup[ifindex].status)); return BCME_ERROR; } ASSERT(id <= dhdp->max_tx_flowid); /* Only after flowid alloc, increment multi_client_flow_rings */ if (if_role_multi_client) { OSL_ATOMIC_INC(dhdp->osh, &dhdp->multi_client_flow_rings); } /* register this flowid in dhd_pub */ dhd_add_flowid(dhdp, ifindex, prio, da, id); flow_ring_node = (flow_ring_node_t *) &flow_ring_table[id]; DHD_FLOWRING_LOCK(flow_ring_node->lock, flags); /* Init Flow info */ memcpy(flow_ring_node->flow_info.sa, sa, sizeof(flow_ring_node->flow_info.sa)); memcpy(flow_ring_node->flow_info.da, da, sizeof(flow_ring_node->flow_info.da)); flow_ring_node->flow_info.tid = prio; flow_ring_node->flow_info.ifindex = ifindex; flow_ring_node->active = TRUE; flow_ring_node->status = FLOW_RING_STATUS_CREATE_PENDING; #ifdef DEVICE_TX_STUCK_DETECT flow_ring_node->tx_cmpl = flow_ring_node->tx_cmpl_prev = OSL_SYSUPTIME(); flow_ring_node->stuck_count = 0; #endif /* DEVICE_TX_STUCK_DETECT */ #ifdef TX_STATUS_LATENCY_STATS flow_ring_node->flow_info.num_tx_status = 0; flow_ring_node->flow_info.cum_tx_status_latency = 0; flow_ring_node->flow_info.num_tx_pkts = 0; #endif /* TX_STATUS_LATENCY_STATS */ #ifdef BCMDBG bzero(&flow_ring_node->flow_info.tx_status[0], sizeof(uint32) * DHD_MAX_TX_STATUS_MSGS); #endif DHD_FLOWRING_UNLOCK(flow_ring_node->lock, flags); /* Create and inform device about the new flow */ if (dhd_bus_flow_ring_create_request(dhdp->bus, (void *)flow_ring_node) != BCME_OK) { DHD_FLOWRING_LOCK(flow_ring_node->lock, flags); flow_ring_node->status = FLOW_RING_STATUS_CLOSED; flow_ring_node->active = FALSE; DHD_FLOWRING_UNLOCK(flow_ring_node->lock, flags); DHD_ERROR(("%s: create error %d\n", __FUNCTION__, id)); return BCME_ERROR; } *flowid = id; return BCME_OK; } else { /* if the Flow id was found in the hash */ if (id > dhdp->max_tx_flowid) { DHD_ERROR(("%s: Invalid flow id : %u, max_tx_flowid : %u\n", __FUNCTION__, id, dhdp->max_tx_flowid)); *flowid = FLOWID_INVALID; ASSERT(0); return BCME_ERROR; } flow_ring_node = (flow_ring_node_t *) &flow_ring_table[id]; DHD_FLOWRING_LOCK(flow_ring_node->lock, flags); /* * If the flow_ring_node is in Open State or Status pending state then * we can return the Flow id to the caller.If the flow_ring_node is in * FLOW_RING_STATUS_PENDING this means the creation is in progress and * hence the packets should be queued. * * If the flow_ring_node is in FLOW_RING_STATUS_DELETE_PENDING Or * FLOW_RING_STATUS_CLOSED, then we should return Error. * Note that if the flowing is being deleted we would mark it as * FLOW_RING_STATUS_DELETE_PENDING. Now before Dongle could respond and * before we mark it as FLOW_RING_STATUS_CLOSED we could get tx packets. * We should drop the packets in that case. * The decission to return OK should NOT be based on 'active' variable, beause * active is made TRUE when a flow_ring_node gets allocated and is made * FALSE when the flow ring gets removed and does not reflect the True state * of the Flow ring. * In case if IDLE_TX_FLOW_MGMT is defined, we have to handle two more flowring * states. If the flow_ring_node's status is FLOW_RING_STATUS_SUSPENDED, the flowid * is to be returned and from dhd_bus_txdata, the flowring would be resumed again. * The status FLOW_RING_STATUS_RESUME_PENDING, is equivalent to * FLOW_RING_STATUS_CREATE_PENDING. */ if (flow_ring_node->status == FLOW_RING_STATUS_DELETE_PENDING || flow_ring_node->status == FLOW_RING_STATUS_CLOSED) { *flowid = FLOWID_INVALID; ret = BCME_ERROR; } else { *flowid = id; ret = BCME_OK; } DHD_FLOWRING_UNLOCK(flow_ring_node->lock, flags); return ret; } /* Flow Id found in the hash */ } /* dhd_flowid_lookup */ int dhd_flowid_find_by_ifidx(dhd_pub_t *dhdp, uint8 ifindex, uint16 flowid) { int hashidx = 0; bool found = FALSE; flow_hash_info_t *cur; if_flow_lkup_t *if_flow_lkup; unsigned long flags; if (!dhdp->flow_ring_table) { DHD_ERROR(("%s : dhd->flow_ring_table is NULL\n", __FUNCTION__)); return BCME_ERROR; } DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; for (hashidx = 0; hashidx < DHD_FLOWRING_HASH_SIZE; hashidx++) { cur = if_flow_lkup[ifindex].fl_hash[hashidx]; if (cur) { if (cur->flowid == flowid) { found = TRUE; } while (!found && cur) { if (cur->flowid == flowid) { found = TRUE; break; } cur = cur->next; } if (found) { DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return BCME_OK; } } } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return BCME_ERROR; } int dhd_flowid_debug_create(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, char *sa, char *da, uint16 *flowid) { return dhd_flowid_lookup(dhdp, ifindex, prio, sa, da, flowid); } /** * Assign existing or newly created flowid to an 802.3 packet. This flowid is later on used to * select the flowring to send the packet to the dongle. */ int BCMFASTPATH(dhd_flowid_update)(dhd_pub_t *dhdp, uint8 ifindex, uint8 prio, void *pktbuf) { uint8 *pktdata = (uint8 *)PKTDATA(dhdp->osh, pktbuf); struct ether_header *eh = (struct ether_header *)pktdata; uint16 flowid = 0; ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) { return BCME_BADARG; } if (!dhdp->flowid_allocator) { DHD_ERROR(("%s: Flow ring not intited yet \n", __FUNCTION__)); return BCME_ERROR; } if (dhd_flowid_lookup(dhdp, ifindex, prio, (char *)eh->ether_shost, (char *)eh->ether_dhost, &flowid) != BCME_OK) { return BCME_ERROR; } DHD_INFO(("%s: prio %d flowid %d\n", __FUNCTION__, prio, flowid)); /* Tag the packet with flowid */ DHD_PKT_SET_FLOWID(pktbuf, flowid); return BCME_OK; } static void dhd_flowid_map_free(dhd_pub_t *dhdp, uint8 ifindex, uint16 flowid) { if (dhdp->htput_flowid_allocator) { if (DHD_IS_FLOWID_HTPUT(dhdp, flowid)) { id16_map_free(dhdp->htput_flowid_allocator, flowid); /* decrement htput client counter */ if (DHD_IF_ROLE_MULTI_CLIENT(dhdp, ifindex)) { dhdp->htput_client_flow_rings--; } return; } } id16_map_free(dhdp->flowid_allocator, flowid); return; } void dhd_flowid_free(dhd_pub_t *dhdp, uint8 ifindex, uint16 flowid) { int hashix; bool found = FALSE; flow_hash_info_t *cur, *prev; if_flow_lkup_t *if_flow_lkup; unsigned long flags; bool if_role_multi_client; ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; if_role_multi_client = DHD_IF_ROLE_MULTI_CLIENT(dhdp, ifindex); for (hashix = 0; hashix < DHD_FLOWRING_HASH_SIZE; hashix++) { cur = if_flow_lkup[ifindex].fl_hash[hashix]; if (cur) { if (cur->flowid == flowid) { found = TRUE; } prev = NULL; while (!found && cur) { if (cur->flowid == flowid) { found = TRUE; break; } prev = cur; cur = cur->next; } if (found) { if (!prev) { if_flow_lkup[ifindex].fl_hash[hashix] = cur->next; } else { prev->next = cur->next; } /* Decrement multi_client_flow_rings */ if (if_role_multi_client) { if (OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings)) { OSL_ATOMIC_DEC(dhdp->osh, &dhdp->multi_client_flow_rings); } } /* deregister flowid from dhd_pub. */ dhd_del_flowid(dhdp, ifindex, flowid); dhd_flowid_map_free(dhdp, ifindex, flowid); DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); MFREE(dhdp->osh, cur, sizeof(flow_hash_info_t)); return; } } } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); DHD_ERROR(("%s: could not free flow ring hash entry flowid %d\n", __FUNCTION__, flowid)); } /* dhd_flowid_free */ /** * Delete all Flow rings associated with the given interface. Is called when eg the dongle * indicates that a wireless link has gone down. */ void dhd_flow_rings_delete(dhd_pub_t *dhdp, uint8 ifindex) { uint32 id; flow_ring_table_t *flow_ring_table; DHD_ERROR(("%s: ifindex %u\n", __FUNCTION__, ifindex)); ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; if (!dhdp->flow_ring_table) return; flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; for (id = 0; id < dhdp->num_h2d_rings; id++) { if (flow_ring_table[id].active && (flow_ring_table[id].flow_info.ifindex == ifindex) && (flow_ring_table[id].status == FLOW_RING_STATUS_OPEN)) { dhd_bus_flow_ring_delete_request(dhdp->bus, (void *) &flow_ring_table[id]); } } } void dhd_update_multicilent_flow_rings(dhd_pub_t *dhdp, uint8 ifindex, bool increment) { uint32 id; flow_ring_table_t *flow_ring_table; DHD_ERROR(("%s: ifindex %u\n", __FUNCTION__, ifindex)); ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; if (!dhdp->flow_ring_table) return; flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; for (id = 0; id < dhdp->num_h2d_rings; id++) { if (flow_ring_table[id].active && (flow_ring_table[id].flow_info.ifindex == ifindex) && (flow_ring_table[id].status == FLOW_RING_STATUS_OPEN)) { if (increment) { if (OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings) < dhdp->max_multi_client_flow_rings) { OSL_ATOMIC_INC(dhdp->osh, &dhdp->multi_client_flow_rings); } else { DHD_ERROR(("%s: multi_client_flow_rings:%u" " reached max:%d\n", __FUNCTION__, OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings), dhdp->max_multi_client_flow_rings)); } } else { if (OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings)) { OSL_ATOMIC_DEC(dhdp->osh, &dhdp->multi_client_flow_rings); } else { DHD_ERROR(("%s: multi_client_flow_rings:%u" " reached ZERO\n", __FUNCTION__, OSL_ATOMIC_READ(dhdp->osh, &dhdp->multi_client_flow_rings))); } } } } } void dhd_flow_rings_flush(dhd_pub_t *dhdp, uint8 ifindex) { uint32 id; flow_ring_table_t *flow_ring_table; DHD_INFO(("%s: ifindex %u\n", __FUNCTION__, ifindex)); ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; if (!dhdp->flow_ring_table) return; flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; for (id = 0; id < dhdp->num_h2d_rings; id++) { if (flow_ring_table[id].active && (flow_ring_table[id].flow_info.ifindex == ifindex) && (flow_ring_table[id].status == FLOW_RING_STATUS_OPEN)) { dhd_bus_flow_ring_flush_request(dhdp->bus, (void *) &flow_ring_table[id]); } } } /** Delete flow ring(s) for given peer address. */ void dhd_flow_rings_delete_for_peer(dhd_pub_t *dhdp, uint8 ifindex, char *addr) { uint32 id; flow_ring_table_t *flow_ring_table; DHD_INFO(("%s: ifindex %u\n", __FUNCTION__, ifindex)); ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; if (!dhdp->flow_ring_table) return; flow_ring_table = (flow_ring_table_t *)dhdp->flow_ring_table; for (id = 0; id < dhdp->num_h2d_rings; id++) { /* * Send flowring delete request even if flowring status is * FLOW_RING_STATUS_CREATE_PENDING, to handle cases where DISASSOC_IND * event comes ahead of flowring create response. * Otherwise the flowring will not be deleted later as there will not be any * DISASSOC_IND event. With this change, when create response event comes to DHD, * it will change the status to FLOW_RING_STATUS_OPEN and soon delete response * event will come, upon which DHD will delete the flowring. */ if (flow_ring_table[id].active && (flow_ring_table[id].flow_info.ifindex == ifindex) && (!memcmp(flow_ring_table[id].flow_info.da, addr, ETHER_ADDR_LEN)) && ((flow_ring_table[id].status == FLOW_RING_STATUS_OPEN) || (flow_ring_table[id].status == FLOW_RING_STATUS_CREATE_PENDING))) { DHD_INFO(("%s: deleting flowid %d\n", __FUNCTION__, flow_ring_table[id].flowid)); dhd_bus_flow_ring_delete_request(dhdp->bus, (void *) &flow_ring_table[id]); } } } /** Handles interface ADD, CHANGE, DEL indications from the dongle */ void dhd_update_interface_flow_info(dhd_pub_t *dhdp, uint8 ifindex, uint8 op, uint8 role) { if_flow_lkup_t *if_flow_lkup; unsigned long flags; ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return; DHD_INFO(("%s: ifindex %u op %u role is %u \n", __FUNCTION__, ifindex, op, role)); if (!dhdp->flowid_allocator) { DHD_ERROR(("%s: Flow ring not intited yet \n", __FUNCTION__)); return; } DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; if (op == WLC_E_IF_ADD || op == WLC_E_IF_CHANGE) { DHD_ERROR(("%s: ifindex:%d previous role:%d new role:%d\n", __FUNCTION__, ifindex, if_flow_lkup[ifindex].role, role)); if_flow_lkup[ifindex].role = role; #ifdef PCIE_FULL_DONGLE if (op == WLC_E_IF_CHANGE) { bool increment = DHD_IF_ROLE_MULTI_CLIENT(dhdp, ifindex); dhd_update_multicilent_flow_rings(dhdp, ifindex, increment); } #endif /* PCIE_FULL_DONGLE */ if (role == WLC_E_IF_ROLE_WDS) { /** * WDS role does not send WLC_E_LINK event after interface is up. * So to create flowrings for WDS, make status as TRUE in WLC_E_IF itself. * same is true while making the status as FALSE. * TODO: Fix FW to send WLC_E_LINK for WDS role aswell. So that all the * interfaces are handled uniformly. */ if_flow_lkup[ifindex].status = TRUE; DHD_INFO(("%s: Mcast Flow ring for ifindex %d role is %d \n", __FUNCTION__, ifindex, role)); } } else if ((op == WLC_E_IF_DEL) && (role == WLC_E_IF_ROLE_WDS)) { if_flow_lkup[ifindex].status = FALSE; DHD_INFO(("%s: cleanup all Flow rings for ifindex %d role is %d \n", __FUNCTION__, ifindex, role)); } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); } /** Handles a STA 'link' indication from the dongle */ int dhd_update_interface_link_status(dhd_pub_t *dhdp, uint8 ifindex, uint8 status) { if_flow_lkup_t *if_flow_lkup; unsigned long flags; ASSERT(ifindex < DHD_MAX_IFS); if (ifindex >= DHD_MAX_IFS) return BCME_BADARG; DHD_INFO(("%s: ifindex %d status %d\n", __FUNCTION__, ifindex, status)); DHD_FLOWID_LOCK(dhdp->flowid_lock, flags); if_flow_lkup = (if_flow_lkup_t *)dhdp->if_flow_lkup; if (status) { if_flow_lkup[ifindex].status = TRUE; } else { if_flow_lkup[ifindex].status = FALSE; } DHD_FLOWID_UNLOCK(dhdp->flowid_lock, flags); return BCME_OK; } /** Update flow priority mapping, called on IOVAR */ int dhd_update_flow_prio_map(dhd_pub_t *dhdp, uint8 map) { uint16 flowid; flow_ring_node_t *flow_ring_node; if (map > DHD_FLOW_PRIO_LLR_MAP) return BCME_BADOPTION; /* Check if we need to change prio map */ if (map == dhdp->flow_prio_map_type) return BCME_OK; /* If any ring is active we cannot change priority mapping for flow rings */ for (flowid = 0; flowid < dhdp->num_h2d_rings; flowid++) { flow_ring_node = DHD_FLOW_RING(dhdp, flowid); if (flow_ring_node->active) return BCME_EPERM; } /* Inform firmware about new mapping type */ if (BCME_OK != dhd_flow_prio_map(dhdp, &map, TRUE)) return BCME_ERROR; /* update internal structures */ dhdp->flow_prio_map_type = map; if (dhdp->flow_prio_map_type == DHD_FLOW_PRIO_TID_MAP) bcopy(prio2tid, dhdp->flow_prio_map, sizeof(uint8) * NUMPRIO); else bcopy(prio2ac, dhdp->flow_prio_map, sizeof(uint8) * NUMPRIO); dhdp->max_multi_client_flow_rings = dhd_get_max_multi_client_flow_rings(dhdp); return BCME_OK; } /** Inform firmware on updated flow priority mapping, called on IOVAR */ int dhd_flow_prio_map(dhd_pub_t *dhd, uint8 *map, bool set) { uint8 iovbuf[WLC_IOCTL_SMLEN]; int len; uint32 val; if (!set) { bzero(&iovbuf, sizeof(iovbuf)); len = bcm_mkiovar("bus:fl_prio_map", NULL, 0, (char*)iovbuf, sizeof(iovbuf)); if (len == 0) { return BCME_BUFTOOSHORT; } if (dhd_wl_ioctl_cmd(dhd, WLC_GET_VAR, iovbuf, sizeof(iovbuf), FALSE, 0) < 0) { DHD_ERROR(("%s: failed to get fl_prio_map\n", __FUNCTION__)); return BCME_ERROR; } *map = iovbuf[0]; return BCME_OK; } val = (uint32)map[0]; len = bcm_mkiovar("bus:fl_prio_map", (char *)&val, sizeof(val), (char*)iovbuf, sizeof(iovbuf)); if (len == 0) { return BCME_BUFTOOSHORT; } if (dhd_wl_ioctl_cmd(dhd, WLC_SET_VAR, iovbuf, len, TRUE, 0) < 0) { DHD_ERROR(("%s: failed to set fl_prio_map \n", __FUNCTION__)); return BCME_ERROR; } return BCME_OK; } uint32 dhd_active_tx_flowring_bkpq_len(dhd_pub_t *dhd) { unsigned long list_lock_flags; dll_t *item, *prev; flow_ring_node_t *flow_ring_node; dhd_bus_t *bus = dhd->bus; uint32 active_tx_flowring_qlen = 0; DHD_FLOWRING_LIST_LOCK(bus->dhd->flowring_list_lock, list_lock_flags); for (item = dll_tail_p(&bus->flowring_active_list); !dll_end(&bus->flowring_active_list, item); item = prev) { prev = dll_prev_p(item); flow_ring_node = dhd_constlist_to_flowring(item); if (flow_ring_node->active) { DHD_INFO(("%s :%d\n", __FUNCTION__, flow_ring_node->queue.len)); active_tx_flowring_qlen += flow_ring_node->queue.len; } } DHD_FLOWRING_LIST_UNLOCK(bus->dhd->flowring_list_lock, list_lock_flags); return active_tx_flowring_qlen; }