/* * mgr.c * * DSP-BIOS Bridge driver support functions for TI OMAP processors. * * Implementation of Manager interface to the device object at the * driver level. This queries the NDB data base and retrieves the * data about Node and Processor. * * Copyright (C) 2005-2006 Texas Instruments, Inc. * * This package is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * THIS PACKAGE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED * WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE. */ #include <linux/types.h> /* ----------------------------------- Host OS */ #include <dspbridge/host_os.h> /* ----------------------------------- DSP/BIOS Bridge */ #include <dspbridge/dbdefs.h> /* ----------------------------------- OS Adaptation Layer */ #include <dspbridge/sync.h> /* ----------------------------------- Others */ #include <dspbridge/dbdcd.h> #include <dspbridge/drv.h> #include <dspbridge/dev.h> /* ----------------------------------- This */ #include <dspbridge/mgr.h> /* ----------------------------------- Defines, Data Structures, Typedefs */ #define ZLDLLNAME "" struct mgr_object { struct dcd_manager *dcd_mgr; /* Proc/Node data manager */ }; /* ----------------------------------- Globals */ static u32 refs; /* * ========= mgr_create ========= * Purpose: * MGR Object gets created only once during driver Loading. */ int mgr_create(struct mgr_object **mgr_obj, struct cfg_devnode *dev_node_obj) { int status = 0; struct mgr_object *pmgr_obj = NULL; struct drv_data *drv_datap = dev_get_drvdata(bridge); pmgr_obj = kzalloc(sizeof(struct mgr_object), GFP_KERNEL); if (pmgr_obj) { status = dcd_create_manager(ZLDLLNAME, &pmgr_obj->dcd_mgr); if (!status) { /* If succeeded store the handle in the MGR Object */ if (drv_datap) { drv_datap->mgr_object = (void *)pmgr_obj; } else { status = -EPERM; pr_err("%s: Failed to store MGR object\n", __func__); } if (!status) { *mgr_obj = pmgr_obj; } else { dcd_destroy_manager(pmgr_obj->dcd_mgr); kfree(pmgr_obj); } } else { /* failed to Create DCD Manager */ kfree(pmgr_obj); } } else { status = -ENOMEM; } return status; } /* * ========= mgr_destroy ========= * This function is invoked during bridge driver unloading.Frees MGR object. */ int mgr_destroy(struct mgr_object *hmgr_obj) { int status = 0; struct mgr_object *pmgr_obj = (struct mgr_object *)hmgr_obj; struct drv_data *drv_datap = dev_get_drvdata(bridge); /* Free resources */ if (hmgr_obj->dcd_mgr) dcd_destroy_manager(hmgr_obj->dcd_mgr); kfree(pmgr_obj); /* Update the driver data with NULL for MGR Object */ if (drv_datap) { drv_datap->mgr_object = NULL; } else { status = -EPERM; pr_err("%s: Failed to store MGR object\n", __func__); } return status; } /* * ======== mgr_enum_node_info ======== * Enumerate and get configuration information about nodes configured * in the node database. */ int mgr_enum_node_info(u32 node_id, struct dsp_ndbprops *pndb_props, u32 undb_props_size, u32 *pu_num_nodes) { int status = 0; struct dsp_uuid node_uuid; u32 node_index = 0; struct dcd_genericobj gen_obj; struct mgr_object *pmgr_obj = NULL; struct drv_data *drv_datap = dev_get_drvdata(bridge); *pu_num_nodes = 0; /* Get the Manager Object from the driver data */ if (!drv_datap || !drv_datap->mgr_object) { pr_err("%s: Failed to retrieve the object handle\n", __func__); return -ENODATA; } pmgr_obj = drv_datap->mgr_object; /* Forever loop till we hit failed or no more items in the * Enumeration. We will exit the loop other than 0; */ while (!status) { status = dcd_enumerate_object(node_index++, DSP_DCDNODETYPE, &node_uuid); if (status) break; *pu_num_nodes = node_index; if (node_id == (node_index - 1)) { status = dcd_get_object_def(pmgr_obj->dcd_mgr, &node_uuid, DSP_DCDNODETYPE, &gen_obj); if (status) break; /* Get the Obj def */ *pndb_props = gen_obj.obj_data.node_obj.ndb_props; } } /* the last status is not 0, but neither an error */ if (status > 0) status = 0; return status; } /* * ======== mgr_enum_processor_info ======== * Enumerate and get configuration information about available * DSP processors. */ int mgr_enum_processor_info(u32 processor_id, struct dsp_processorinfo * processor_info, u32 processor_info_size, u8 *pu_num_procs) { int status = 0; int status1 = 0; int status2 = 0; struct dsp_uuid temp_uuid; u32 temp_index = 0; u32 proc_index = 0; struct dcd_genericobj gen_obj; struct mgr_object *pmgr_obj = NULL; struct mgr_processorextinfo *ext_info; struct dev_object *hdev_obj; struct drv_object *hdrv_obj; u8 dev_type; struct cfg_devnode *dev_node; struct drv_data *drv_datap = dev_get_drvdata(bridge); bool proc_detect = false; *pu_num_procs = 0; /* Retrieve the Object handle from the driver data */ if (!drv_datap || !drv_datap->drv_object) { status = -ENODATA; pr_err("%s: Failed to retrieve the object handle\n", __func__); } else { hdrv_obj = drv_datap->drv_object; } if (!status) { status = drv_get_dev_object(processor_id, hdrv_obj, &hdev_obj); if (!status) { status = dev_get_dev_type(hdev_obj, (u8 *) &dev_type); status = dev_get_dev_node(hdev_obj, &dev_node); if (dev_type != DSP_UNIT) status = -EPERM; if (!status) processor_info->processor_type = DSPTYPE64; } } if (status) goto func_end; /* Get The Manager Object from the driver data */ if (drv_datap && drv_datap->mgr_object) { pmgr_obj = drv_datap->mgr_object; } else { dev_dbg(bridge, "%s: Failed to get MGR Object\n", __func__); goto func_end; } /* Forever loop till we hit no more items in the * Enumeration. We will exit the loop other than 0; */ while (status1 == 0) { status1 = dcd_enumerate_object(temp_index++, DSP_DCDPROCESSORTYPE, &temp_uuid); if (status1 != 0) break; proc_index++; /* Get the Object properties to find the Device/Processor * Type */ if (proc_detect != false) continue; status2 = dcd_get_object_def(pmgr_obj->dcd_mgr, (struct dsp_uuid *)&temp_uuid, DSP_DCDPROCESSORTYPE, &gen_obj); if (!status2) { /* Get the Obj def */ if (processor_info_size < sizeof(struct mgr_processorextinfo)) { *processor_info = gen_obj.obj_data.proc_info; } else { /* extended info */ ext_info = (struct mgr_processorextinfo *) processor_info; *ext_info = gen_obj.obj_data.ext_proc_obj; } dev_dbg(bridge, "%s: Got proctype from DCD %x\n", __func__, processor_info->processor_type); /* See if we got the needed processor */ if (dev_type == DSP_UNIT) { if (processor_info->processor_type == DSPPROCTYPE_C64) proc_detect = true; } else if (dev_type == IVA_UNIT) { if (processor_info->processor_type == IVAPROCTYPE_ARM7) proc_detect = true; } /* User applications only check for chip type, so * this is a clumsy overwrite */ processor_info->processor_type = DSPTYPE64; } else { dev_dbg(bridge, "%s: Failed to get DCD processor info " "%x\n", __func__, status2); status = -EPERM; } } *pu_num_procs = proc_index; if (proc_detect == false) { dev_dbg(bridge, "%s: Failed to get proc info from DCD, so use " "CFG registry\n", __func__); processor_info->processor_type = DSPTYPE64; } func_end: return status; } /* * ======== mgr_exit ======== * Decrement reference count, and free resources when reference count is * 0. */ void mgr_exit(void) { refs--; if (refs == 0) dcd_exit(); } /* * ======== mgr_get_dcd_handle ======== * Retrieves the MGR handle. Accessor Function. */ int mgr_get_dcd_handle(struct mgr_object *mgr_handle, u32 *dcd_handle) { int status = -EPERM; struct mgr_object *pmgr_obj = (struct mgr_object *)mgr_handle; *dcd_handle = (u32) NULL; if (pmgr_obj) { *dcd_handle = (u32) pmgr_obj->dcd_mgr; status = 0; } return status; } /* * ======== mgr_init ======== * Initialize MGR's private state, keeping a reference count on each call. */ bool mgr_init(void) { bool ret = true; if (refs == 0) ret = dcd_init(); /* DCD Module */ if (ret) refs++; return ret; } /* * ======== mgr_wait_for_bridge_events ======== * Block on any Bridge event(s) */ int mgr_wait_for_bridge_events(struct dsp_notification **anotifications, u32 count, u32 *pu_index, u32 utimeout) { int status; struct sync_object *sync_events[MAX_EVENTS]; u32 i; for (i = 0; i < count; i++) sync_events[i] = anotifications[i]->handle; status = sync_wait_on_multiple_events(sync_events, count, utimeout, pu_index); return status; }