/* Copyright (c) 2011-2013, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #define pr_fmt(fmt) "AXI: %s(): " fmt, __func__ #include #include #include #include #include #include #include #include #include "msm_bus_core.h" #define INDEX_MASK 0x0000FFFF #define PNODE_MASK 0xFFFF0000 #define SHIFT_VAL 16 #define CREATE_PNODE_ID(n, i) (((n) << SHIFT_VAL) | (i)) #define GET_INDEX(n) ((n) & INDEX_MASK) #define GET_NODE(n) ((n) >> SHIFT_VAL) #define IS_NODE(n) ((n) % FABRIC_ID_KEY) #define SEL_FAB_CLK 1 #define SEL_SLAVE_CLK 0 #define BW_TO_CLK_FREQ_HZ(width, bw) \ msm_bus_div64(width, bw) #define IS_MASTER_VALID(mas) \ (((mas >= MSM_BUS_MASTER_FIRST) && (mas <= MSM_BUS_MASTER_LAST)) \ ? 1 : 0) #define IS_SLAVE_VALID(slv) \ (((slv >= MSM_BUS_SLAVE_FIRST) && (slv <= MSM_BUS_SLAVE_LAST)) ? 1 : 0) static DEFINE_MUTEX(msm_bus_lock); /* This function uses shift operations to divide 64 bit value for higher * efficiency. The divisor expected are number of ports or bus-width. * These are expected to be 1, 2, 4, 8, 16 and 32 in most cases. * * To account for exception to the above divisor values, the standard * do_div function is used. * */ uint64_t msm_bus_div64(unsigned int w, uint64_t bw) { uint64_t *b = &bw; if ((bw > 0) && (bw < w)) return 1; switch (w) { case 0: WARN(1, "AXI: Divide by 0 attempted\n"); case 1: return bw; case 2: return (bw >> 1); case 4: return (bw >> 2); case 8: return (bw >> 3); case 16: return (bw >> 4); case 32: return (bw >> 5); } do_div(*b, w); return *b; } /** * add_path_node: Adds the path information to the current node * @info: Internal node info structure * @next: Combination of the id and index of the next node * Function returns: Number of pnodes (path_nodes) on success, * error on failure. * * Every node maintains the list of path nodes. A path node is * reached by finding the node-id and index stored at the current * node. This makes updating the paths with requested bw and clock * values efficient, as it avoids lookup for each update-path request. */ static int add_path_node(struct msm_bus_inode_info *info, int next) { struct path_node *pnode; int i; if (ZERO_OR_NULL_PTR(info)) { MSM_BUS_ERR("Cannot find node info!: id :%d\n", info->node_info->priv_id); return -ENXIO; } for (i = 0; i <= info->num_pnodes; i++) { if (info->pnode[i].next == -2) { MSM_BUS_DBG("Reusing pnode for info: %d at index: %d\n", info->node_info->priv_id, i); info->pnode[i].clk[DUAL_CTX] = 0; info->pnode[i].clk[ACTIVE_CTX] = 0; info->pnode[i].bw[DUAL_CTX] = 0; info->pnode[i].bw[ACTIVE_CTX] = 0; info->pnode[i].next = next; MSM_BUS_DBG("%d[%d] : (%d, %d)\n", info->node_info->priv_id, i, GET_NODE(next), GET_INDEX(next)); return i; } } info->num_pnodes++; pnode = krealloc(info->pnode, ((info->num_pnodes + 1) * sizeof(struct path_node)) , GFP_KERNEL); if (ZERO_OR_NULL_PTR(pnode)) { MSM_BUS_ERR("Error creating path node!\n"); info->num_pnodes--; return -ENOMEM; } info->pnode = pnode; info->pnode[info->num_pnodes].clk[DUAL_CTX] = 0; info->pnode[info->num_pnodes].clk[ACTIVE_CTX] = 0; info->pnode[info->num_pnodes].bw[DUAL_CTX] = 0; info->pnode[info->num_pnodes].bw[ACTIVE_CTX] = 0; info->pnode[info->num_pnodes].next = next; MSM_BUS_DBG("%d[%d] : (%d, %d)\n", info->node_info->priv_id, info->num_pnodes, GET_NODE(next), GET_INDEX(next)); return info->num_pnodes; } static int clearvisitedflag(struct device *dev, void *data) { struct msm_bus_fabric_device *fabdev = to_msm_bus_fabric_device(dev); fabdev->visited = false; return 0; } /** * getpath() - Finds the path from the topology between src and dest * @src: Source. This is the master from which the request originates * @dest: Destination. This is the slave to which we're trying to reach * * Function returns: next_pnode_id. The higher 16 bits of the next_pnode_id * represent the src id of the next node on path. The lower 16 bits of the * next_pnode_id represent the "index", which is the next entry in the array * of pnodes for that node to fill in clk and bw values. This is created using * CREATE_PNODE_ID. The return value is stored in ret_pnode, and this is added * to the list of path nodes. * * This function recursively finds the path by updating the src to the * closest possible node to dest. */ static int getpath(int src, int dest) { int pnode_num = -1, i; struct msm_bus_fabnodeinfo *fabnodeinfo; struct msm_bus_fabric_device *fabdev; int next_pnode_id = -1; struct msm_bus_inode_info *info = NULL; int _src = src/FABRIC_ID_KEY; int _dst = dest/FABRIC_ID_KEY; int ret_pnode = -1; int fabid = GET_FABID(src); /* Find the location of fabric for the src */ MSM_BUS_DBG("%d --> %d\n", src, dest); fabdev = msm_bus_get_fabric_device(fabid); if (!fabdev) { MSM_BUS_WARN("Fabric Not yet registered. Try again\n"); return -ENXIO; } /* Are we there yet? */ if (src == dest) { info = fabdev->algo->find_node(fabdev, src); if (ZERO_OR_NULL_PTR(info)) { MSM_BUS_ERR("Node %d not found\n", dest); return -ENXIO; } for (i = 0; i <= info->num_pnodes; i++) { if (info->pnode[i].next == -2) { MSM_BUS_DBG("src = dst Reusing pnode for" " info: %d at index: %d\n", info->node_info->priv_id, i); next_pnode_id = CREATE_PNODE_ID(src, i); info->pnode[i].clk[DUAL_CTX] = 0; info->pnode[i].bw[DUAL_CTX] = 0; info->pnode[i].next = next_pnode_id; MSM_BUS_DBG("returning: %d, %d\n", GET_NODE (next_pnode_id), GET_INDEX(next_pnode_id)); return next_pnode_id; } } next_pnode_id = CREATE_PNODE_ID(src, (info->num_pnodes + 1)); pnode_num = add_path_node(info, next_pnode_id); if (pnode_num < 0) { MSM_BUS_ERR("Error adding path node\n"); return -ENXIO; } MSM_BUS_DBG("returning: %d, %d\n", GET_NODE(next_pnode_id), GET_INDEX(next_pnode_id)); return next_pnode_id; } else if (_src == _dst) { /* * src and dest belong to same fabric, find the destination * from the radix tree */ info = fabdev->algo->find_node(fabdev, dest); if (ZERO_OR_NULL_PTR(info)) { MSM_BUS_ERR("Node %d not found\n", dest); return -ENXIO; } ret_pnode = getpath(info->node_info->priv_id, dest); next_pnode_id = ret_pnode; } else { /* find the dest fabric */ int trynextgw = true; struct list_head *gateways = fabdev->algo->get_gw_list(fabdev); list_for_each_entry(fabnodeinfo, gateways, list) { /* see if the destination is at a connected fabric */ if (_dst == (fabnodeinfo->info->node_info->priv_id / FABRIC_ID_KEY)) { /* Found the fab on which the device exists */ info = fabnodeinfo->info; trynextgw = false; ret_pnode = getpath(info->node_info->priv_id, dest); pnode_num = add_path_node(info, ret_pnode); if (pnode_num < 0) { MSM_BUS_ERR("Error adding path node\n"); return -ENXIO; } next_pnode_id = CREATE_PNODE_ID( info->node_info->priv_id, pnode_num); break; } } /* find the gateway */ if (trynextgw) { gateways = fabdev->algo->get_gw_list(fabdev); list_for_each_entry(fabnodeinfo, gateways, list) { struct msm_bus_fabric_device *gwfab = msm_bus_get_fabric_device(fabnodeinfo-> info->node_info->priv_id); if (!gwfab) { MSM_BUS_ERR("Err: No gateway found\n"); return -ENXIO; } if (!gwfab->visited) { MSM_BUS_DBG("VISITED ID: %d\n", gwfab->id); gwfab->visited = true; info = fabnodeinfo->info; ret_pnode = getpath(info-> node_info->priv_id, dest); pnode_num = add_path_node(info, ret_pnode); if (pnode_num < 0) { MSM_BUS_ERR("Malloc failure in" " adding path node\n"); return -ENXIO; } next_pnode_id = CREATE_PNODE_ID( info->node_info->priv_id, pnode_num); break; } } if (next_pnode_id < 0) return -ENXIO; } } if (!IS_NODE(src)) { MSM_BUS_DBG("Returning next_pnode_id:%d[%d]\n", GET_NODE( next_pnode_id), GET_INDEX(next_pnode_id)); return next_pnode_id; } info = fabdev->algo->find_node(fabdev, src); if (!info) { MSM_BUS_ERR("Node info not found.\n"); return -ENXIO; } pnode_num = add_path_node(info, next_pnode_id); MSM_BUS_DBG(" Last: %d[%d] = (%d, %d)\n", src, info->num_pnodes, GET_NODE(next_pnode_id), GET_INDEX(next_pnode_id)); MSM_BUS_DBG("returning: %d, %d\n", src, pnode_num); return CREATE_PNODE_ID(src, pnode_num); } /** * update_path() - Update the path with the bandwidth and clock values, as * requested by the client. * * @curr: Current source node, as specified in the client vector (master) * @pnode: The first-hop node on the path, stored in the internal client struct * @req_clk: Requested clock value from the vector * @req_bw: Requested bandwidth value from the vector * @curr_clk: Current clock frequency * @curr_bw: Currently allocated bandwidth * * This function updates the nodes on the path calculated using getpath(), with * clock and bandwidth values. The sum of bandwidths, and the max of clock * frequencies is calculated at each node on the path. Commit data to be sent * to RPM for each master and slave is also calculated here. */ static int update_path(int curr, int pnode, uint64_t req_clk, uint64_t req_bw, uint64_t curr_clk, uint64_t curr_bw, unsigned int ctx, unsigned int cl_active_flag) { int index, ret = 0; struct msm_bus_inode_info *info; int next_pnode; int64_t add_bw = req_bw - curr_bw; uint64_t bwsum = 0; uint64_t req_clk_hz, curr_clk_hz, bwsum_hz; int *master_tiers; struct msm_bus_fabric_device *fabdev = msm_bus_get_fabric_device (GET_FABID(curr)); if (!fabdev) { MSM_BUS_ERR("Bus device for bus ID: %d not found!\n", GET_FABID(curr)); return -ENXIO; } MSM_BUS_DBG("args: %d %d %d %llu %llu %llu %llu %u\n", curr, GET_NODE(pnode), GET_INDEX(pnode), req_clk, req_bw, curr_clk, curr_bw, ctx); index = GET_INDEX(pnode); MSM_BUS_DBG("Client passed index :%d\n", index); info = fabdev->algo->find_node(fabdev, curr); if (!info) { MSM_BUS_ERR("Cannot find node info!\n"); return -ENXIO; } /** * If master supports dual configuration, check if * the configuration needs to be changed based on * incoming requests */ if (info->node_info->dual_conf) fabdev->algo->config_master(fabdev, info, req_clk, req_bw); info->link_info.sel_bw = &info->link_info.bw[ctx]; info->link_info.sel_clk = &info->link_info.clk[ctx]; *info->link_info.sel_bw += add_bw; info->pnode[index].sel_bw = &info->pnode[index].bw[ctx]; /** * To select the right clock, AND the context with * client active flag. */ info->pnode[index].sel_clk = &info->pnode[index].clk[ctx & cl_active_flag]; *info->pnode[index].sel_bw += add_bw; info->link_info.num_tiers = info->node_info->num_tiers; info->link_info.tier = info->node_info->tier; master_tiers = info->node_info->tier; do { struct msm_bus_inode_info *hop; fabdev = msm_bus_get_fabric_device(GET_FABID(curr)); if (!fabdev) { MSM_BUS_ERR("Fabric not found\n"); return -ENXIO; } MSM_BUS_DBG("id: %d\n", info->node_info->priv_id); /* find next node and index */ next_pnode = info->pnode[index].next; curr = GET_NODE(next_pnode); index = GET_INDEX(next_pnode); MSM_BUS_DBG("id:%d, next: %d\n", info-> node_info->priv_id, curr); /* Get hop */ /* check if we are here as gateway, or does the hop belong to * this fabric */ if (IS_NODE(curr)) hop = fabdev->algo->find_node(fabdev, curr); else hop = fabdev->algo->find_gw_node(fabdev, curr); if (!hop) { MSM_BUS_ERR("Null Info found for hop\n"); return -ENXIO; } hop->link_info.sel_bw = &hop->link_info.bw[ctx]; hop->link_info.sel_clk = &hop->link_info.clk[ctx]; *hop->link_info.sel_bw += add_bw; hop->pnode[index].sel_bw = &hop->pnode[index].bw[ctx]; hop->pnode[index].sel_clk = &hop->pnode[index].clk[ctx & cl_active_flag]; if (!hop->node_info->buswidth) { MSM_BUS_WARN("No bus width found. Using default\n"); hop->node_info->buswidth = 8; } *hop->pnode[index].sel_clk = BW_TO_CLK_FREQ_HZ(hop->node_info-> buswidth, req_clk); *hop->pnode[index].sel_bw += add_bw; MSM_BUS_DBG("fabric: %d slave: %d, slave-width: %d info: %d\n", fabdev->id, hop->node_info->priv_id, hop->node_info-> buswidth, info->node_info->priv_id); /* Update Bandwidth */ fabdev->algo->update_bw(fabdev, hop, info, add_bw, master_tiers, ctx); bwsum = *hop->link_info.sel_bw; /* Update Fabric clocks */ curr_clk_hz = BW_TO_CLK_FREQ_HZ(hop->node_info->buswidth, curr_clk); req_clk_hz = BW_TO_CLK_FREQ_HZ(hop->node_info->buswidth, req_clk); bwsum_hz = BW_TO_CLK_FREQ_HZ(hop->node_info->buswidth, bwsum); /* Account for multiple channels if any */ if (hop->node_info->num_sports > 1) bwsum_hz = msm_bus_div64(hop->node_info->num_sports, bwsum_hz); MSM_BUS_DBG("AXI: Hop: %d, ports: %d, bwsum_hz: %llu\n", hop->node_info->id, hop->node_info->num_sports, bwsum_hz); MSM_BUS_DBG("up-clk: curr_hz: %llu, req_hz: %llu, bw_hz %llu\n", curr_clk, req_clk, bwsum_hz); ret = fabdev->algo->update_clks(fabdev, hop, index, curr_clk_hz, req_clk_hz, bwsum_hz, SEL_FAB_CLK, ctx, cl_active_flag); if (ret) MSM_BUS_WARN("Failed to update clk\n"); info = hop; } while (GET_NODE(info->pnode[index].next) != info->node_info->priv_id); /* Update BW, clk after exiting the loop for the last one */ if (!info) { MSM_BUS_ERR("Cannot find node info!\n"); return -ENXIO; } /* Update slave clocks */ ret = fabdev->algo->update_clks(fabdev, info, index, curr_clk_hz, req_clk_hz, bwsum_hz, SEL_SLAVE_CLK, ctx, cl_active_flag); if (ret) MSM_BUS_ERR("Failed to update clk\n"); return ret; } /** * msm_bus_commit_fn() - Commits the data for fabric to rpm * @dev: fabric device * @data: NULL */ static int msm_bus_commit_fn(struct device *dev, void *data) { int ret = 0; struct msm_bus_fabric_device *fabdev = to_msm_bus_fabric_device(dev); MSM_BUS_DBG("Committing: fabid: %d\n", fabdev->id); ret = fabdev->algo->commit(fabdev); return ret; } /** * msm_bus_scale_register_client() - Register the clients with the msm bus * driver * @pdata: Platform data of the client, containing src, dest, ab, ib * * Client data contains the vectors specifying arbitrated bandwidth (ab) * and instantaneous bandwidth (ib) requested between a particular * src and dest. */ uint32_t msm_bus_scale_register_client(struct msm_bus_scale_pdata *pdata) { struct msm_bus_client *client = NULL; int i; int src, dest, nfab; struct msm_bus_fabric_device *deffab; deffab = msm_bus_get_fabric_device(MSM_BUS_FAB_DEFAULT); if (!deffab) { MSM_BUS_ERR("Error finding default fabric\n"); return -ENXIO; } nfab = msm_bus_get_num_fab(); if (nfab < deffab->board_algo->board_nfab) { MSM_BUS_ERR("Can't register client!\n" "Num of fabrics up: %d\n", nfab); return 0; } if ((!pdata) || (pdata->usecase->num_paths == 0) || IS_ERR(pdata)) { MSM_BUS_ERR("Cannot register client with null data\n"); return 0; } client = kzalloc(sizeof(struct msm_bus_client), GFP_KERNEL); if (!client) { MSM_BUS_ERR("Error allocating client\n"); return 0; } mutex_lock(&msm_bus_lock); client->pdata = pdata; client->curr = -1; for (i = 0; i < pdata->usecase->num_paths; i++) { int *pnode; struct msm_bus_fabric_device *srcfab; pnode = krealloc(client->src_pnode, ((i + 1) * sizeof(int)), GFP_KERNEL); if (ZERO_OR_NULL_PTR(pnode)) { MSM_BUS_ERR("Invalid Pnode ptr!\n"); continue; } else client->src_pnode = pnode; if (!IS_MASTER_VALID(pdata->usecase->vectors[i].src)) { MSM_BUS_ERR("Invalid Master ID %d in request!\n", pdata->usecase->vectors[i].src); goto err; } if (!IS_SLAVE_VALID(pdata->usecase->vectors[i].dst)) { MSM_BUS_ERR("Invalid Slave ID %d in request!\n", pdata->usecase->vectors[i].dst); goto err; } src = msm_bus_board_get_iid(pdata->usecase->vectors[i].src); if (src == -ENXIO) { MSM_BUS_ERR("Master %d not supported. Client cannot be" " registered\n", pdata->usecase->vectors[i].src); goto err; } dest = msm_bus_board_get_iid(pdata->usecase->vectors[i].dst); if (dest == -ENXIO) { MSM_BUS_ERR("Slave %d not supported. Client cannot be" " registered\n", pdata->usecase->vectors[i].dst); goto err; } srcfab = msm_bus_get_fabric_device(GET_FABID(src)); if (!srcfab) { MSM_BUS_ERR("Fabric not found\n"); goto err; } srcfab->visited = true; pnode[i] = getpath(src, dest); bus_for_each_dev(&msm_bus_type, NULL, NULL, clearvisitedflag); if (pnode[i] == -ENXIO) { MSM_BUS_ERR("Cannot register client now! Try again!\n"); goto err; } } msm_bus_dbg_client_data(client->pdata, MSM_BUS_DBG_REGISTER, (uint32_t)client); mutex_unlock(&msm_bus_lock); MSM_BUS_DBG("ret: %u num_paths: %d\n", (uint32_t)client, pdata->usecase->num_paths); return (uint32_t)(client); err: kfree(client->src_pnode); kfree(client); mutex_unlock(&msm_bus_lock); return 0; } EXPORT_SYMBOL(msm_bus_scale_register_client); /** * msm_bus_scale_client_update_request() - Update the request for bandwidth * from a particular client * * cl: Handle to the client * index: Index into the vector, to which the bw and clock values need to be * updated */ int msm_bus_scale_client_update_request(uint32_t cl, unsigned index) { int i, ret = 0; struct msm_bus_scale_pdata *pdata; int pnode, src, curr, ctx; uint64_t req_clk, req_bw, curr_clk, curr_bw; struct msm_bus_client *client = (struct msm_bus_client *)cl; if (IS_ERR_OR_NULL(client)) { MSM_BUS_ERR("msm_bus_scale_client update req error %d\n", (uint32_t)client); return -ENXIO; } mutex_lock(&msm_bus_lock); if (client->curr == index) goto err; curr = client->curr; pdata = client->pdata; if (!pdata) { MSM_BUS_ERR("Null pdata passed to update-request\n"); return -ENXIO; } if (index >= pdata->num_usecases) { MSM_BUS_ERR("Client %u passed invalid index: %d\n", (uint32_t)client, index); ret = -ENXIO; goto err; } MSM_BUS_DBG("cl: %u index: %d curr: %d num_paths: %d\n", cl, index, client->curr, client->pdata->usecase->num_paths); for (i = 0; i < pdata->usecase->num_paths; i++) { src = msm_bus_board_get_iid(client->pdata->usecase[index]. vectors[i].src); if (src == -ENXIO) { MSM_BUS_ERR("Master %d not supported. Request cannot" " be updated\n", client->pdata->usecase-> vectors[i].src); goto err; } if (msm_bus_board_get_iid(client->pdata->usecase[index]. vectors[i].dst) == -ENXIO) { MSM_BUS_ERR("Slave %d not supported. Request cannot" " be updated\n", client->pdata->usecase-> vectors[i].dst); } pnode = client->src_pnode[i]; req_clk = client->pdata->usecase[index].vectors[i].ib; req_bw = client->pdata->usecase[index].vectors[i].ab; if (curr < 0) { curr_clk = 0; curr_bw = 0; } else { curr_clk = client->pdata->usecase[curr].vectors[i].ib; curr_bw = client->pdata->usecase[curr].vectors[i].ab; MSM_BUS_DBG("ab: %llu ib: %llu\n", curr_bw, curr_clk); } if (index == 0) { /* This check protects the bus driver from clients * that can leave non-zero requests after * unregistering. * */ req_clk = 0; req_bw = 0; } if (!pdata->active_only) { ret = update_path(src, pnode, req_clk, req_bw, curr_clk, curr_bw, 0, pdata->active_only); if (ret) { MSM_BUS_ERR("Update path failed! %d\n", ret); goto err; } } ret = update_path(src, pnode, req_clk, req_bw, curr_clk, curr_bw, ACTIVE_CTX, pdata->active_only); if (ret) { MSM_BUS_ERR("Update Path failed! %d\n", ret); goto err; } } client->curr = index; ctx = ACTIVE_CTX; msm_bus_dbg_client_data(client->pdata, index, cl); bus_for_each_dev(&msm_bus_type, NULL, NULL, msm_bus_commit_fn); err: mutex_unlock(&msm_bus_lock); return ret; } EXPORT_SYMBOL(msm_bus_scale_client_update_request); int reset_pnodes(int curr, int pnode) { struct msm_bus_inode_info *info; struct msm_bus_fabric_device *fabdev; int index, next_pnode; fabdev = msm_bus_get_fabric_device(GET_FABID(curr)); if (!fabdev) { MSM_BUS_ERR("Fabric not found for: %d\n", (GET_FABID(curr))); return -ENXIO; } index = GET_INDEX(pnode); info = fabdev->algo->find_node(fabdev, curr); if (!info) { MSM_BUS_ERR("Cannot find node info!\n"); return -ENXIO; } MSM_BUS_DBG("Starting the loop--remove\n"); do { struct msm_bus_inode_info *hop; fabdev = msm_bus_get_fabric_device(GET_FABID(curr)); if (!fabdev) { MSM_BUS_ERR("Fabric not found\n"); return -ENXIO; } next_pnode = info->pnode[index].next; info->pnode[index].next = -2; curr = GET_NODE(next_pnode); index = GET_INDEX(next_pnode); if (IS_NODE(curr)) hop = fabdev->algo->find_node(fabdev, curr); else hop = fabdev->algo->find_gw_node(fabdev, curr); if (!hop) { MSM_BUS_ERR("Null Info found for hop\n"); return -ENXIO; } MSM_BUS_DBG("%d[%d] = %d\n", info->node_info->priv_id, index, info->pnode[index].next); MSM_BUS_DBG("num_pnodes: %d: %d\n", info->node_info->priv_id, info->num_pnodes); info = hop; } while (GET_NODE(info->pnode[index].next) != info->node_info->priv_id); info->pnode[index].next = -2; MSM_BUS_DBG("%d[%d] = %d\n", info->node_info->priv_id, index, info->pnode[index].next); MSM_BUS_DBG("num_pnodes: %d: %d\n", info->node_info->priv_id, info->num_pnodes); return 0; } int msm_bus_board_get_iid(int id) { struct msm_bus_fabric_device *deffab; deffab = msm_bus_get_fabric_device(MSM_BUS_FAB_DEFAULT); if (!deffab) { MSM_BUS_ERR("Error finding default fabric\n"); return -ENXIO; } return deffab->board_algo->get_iid(id); } void msm_bus_scale_client_reset_pnodes(uint32_t cl) { int i, src, pnode, index; struct msm_bus_client *client = (struct msm_bus_client *)(cl); if (IS_ERR_OR_NULL(client)) { MSM_BUS_ERR("msm_bus_scale_reset_pnodes error\n"); return; } index = 0; for (i = 0; i < client->pdata->usecase->num_paths; i++) { src = msm_bus_board_get_iid( client->pdata->usecase[index].vectors[i].src); pnode = client->src_pnode[i]; MSM_BUS_DBG("(%d, %d)\n", GET_NODE(pnode), GET_INDEX(pnode)); reset_pnodes(src, pnode); } } /** * msm_bus_scale_unregister_client() - Unregister the client from the bus driver * @cl: Handle to the client */ void msm_bus_scale_unregister_client(uint32_t cl) { struct msm_bus_client *client = (struct msm_bus_client *)(cl); if (IS_ERR_OR_NULL(client)) return; if (client->curr != 0) msm_bus_scale_client_update_request(cl, 0); MSM_BUS_DBG("Unregistering client %d\n", cl); mutex_lock(&msm_bus_lock); msm_bus_scale_client_reset_pnodes(cl); msm_bus_dbg_client_data(client->pdata, MSM_BUS_DBG_UNREGISTER, cl); mutex_unlock(&msm_bus_lock); kfree(client->src_pnode); kfree(client); } EXPORT_SYMBOL(msm_bus_scale_unregister_client);