/* $Id: shub_intr.c,v 1.1 2002/02/28 17:31:25 marcelo Exp $ * * This file is subject to the terms and conditions of the GNU General Public * License. See the file "COPYING" in the main directory of this archive * for more details. * * Copyright (C) 1992-1997, 2000-2003 Silicon Graphics, Inc. All Rights Reserved. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* ARGSUSED */ void hub_intr_init(vertex_hdl_t hubv) { } xwidgetnum_t hub_widget_id(nasid_t nasid) { hubii_wcr_t ii_wcr; /* the control status register */ ii_wcr.wcr_reg_value = REMOTE_HUB_L(nasid,IIO_WCR); return ii_wcr.wcr_fields_s.wcr_widget_id; } static hub_intr_t do_hub_intr_alloc(vertex_hdl_t dev, device_desc_t dev_desc, vertex_hdl_t owner_dev, int uncond_nothread) { cpuid_t cpu = 0; int vector; hub_intr_t intr_hdl; cnodeid_t cnode; int cpuphys, slice; int nasid; iopaddr_t xtalk_addr; struct xtalk_intr_s *xtalk_info; xwidget_info_t xwidget_info; ilvl_t intr_swlevel = 0; cpu = intr_heuristic(dev, dev_desc, -1, 0, owner_dev, NULL, &vector); if (cpu == CPU_NONE) { printk("Unable to allocate interrupt for 0x%p\n", (void *)owner_dev); return(0); } cpuphys = cpu_physical_id(cpu); slice = cpu_physical_id_to_slice(cpuphys); nasid = cpu_physical_id_to_nasid(cpuphys); cnode = cpuid_to_cnodeid(cpu); if (slice) { xtalk_addr = SH_II_INT1 | ((unsigned long)nasid << 36) | (1UL << 47); } else { xtalk_addr = SH_II_INT0 | ((unsigned long)nasid << 36) | (1UL << 47); } intr_hdl = snia_kmem_alloc_node(sizeof(struct hub_intr_s), KM_NOSLEEP, cnode); ASSERT_ALWAYS(intr_hdl); xtalk_info = &intr_hdl->i_xtalk_info; xtalk_info->xi_dev = dev; xtalk_info->xi_vector = vector; xtalk_info->xi_addr = xtalk_addr; xwidget_info = xwidget_info_get(dev); if (xwidget_info) { xtalk_info->xi_target = xwidget_info_masterid_get(xwidget_info); } intr_hdl->i_swlevel = intr_swlevel; intr_hdl->i_cpuid = cpu; intr_hdl->i_bit = vector; intr_hdl->i_flags |= HUB_INTR_IS_ALLOCED; return(intr_hdl); } hub_intr_t hub_intr_alloc(vertex_hdl_t dev, device_desc_t dev_desc, vertex_hdl_t owner_dev) { return(do_hub_intr_alloc(dev, dev_desc, owner_dev, 0)); } hub_intr_t hub_intr_alloc_nothd(vertex_hdl_t dev, device_desc_t dev_desc, vertex_hdl_t owner_dev) { return(do_hub_intr_alloc(dev, dev_desc, owner_dev, 1)); } void hub_intr_free(hub_intr_t intr_hdl) { cpuid_t cpu = intr_hdl->i_cpuid; int vector = intr_hdl->i_bit; xtalk_intr_t xtalk_info; if (intr_hdl->i_flags & HUB_INTR_IS_CONNECTED) { xtalk_info = &intr_hdl->i_xtalk_info; xtalk_info->xi_dev = 0; xtalk_info->xi_vector = 0; xtalk_info->xi_addr = 0; hub_intr_disconnect(intr_hdl); } if (intr_hdl->i_flags & HUB_INTR_IS_ALLOCED) { kfree(intr_hdl); } intr_unreserve_level(cpu, vector); } int hub_intr_connect(hub_intr_t intr_hdl, intr_func_t intr_func, /* xtalk intr handler */ void *intr_arg, /* arg to intr handler */ xtalk_intr_setfunc_t setfunc, void *setfunc_arg) { int rv; cpuid_t cpu = intr_hdl->i_cpuid; int vector = intr_hdl->i_bit; ASSERT(intr_hdl->i_flags & HUB_INTR_IS_ALLOCED); rv = intr_connect_level(cpu, vector, intr_hdl->i_swlevel, NULL); if (rv < 0) { return rv; } intr_hdl->i_xtalk_info.xi_setfunc = setfunc; intr_hdl->i_xtalk_info.xi_sfarg = setfunc_arg; if (setfunc) { (*setfunc)((xtalk_intr_t)intr_hdl); } intr_hdl->i_flags |= HUB_INTR_IS_CONNECTED; return 0; } /* * Disassociate handler with the specified interrupt. */ void hub_intr_disconnect(hub_intr_t intr_hdl) { /*REFERENCED*/ int rv; cpuid_t cpu = intr_hdl->i_cpuid; int bit = intr_hdl->i_bit; xtalk_intr_setfunc_t setfunc; setfunc = intr_hdl->i_xtalk_info.xi_setfunc; /* TBD: send disconnected interrupts somewhere harmless */ if (setfunc) (*setfunc)((xtalk_intr_t)intr_hdl); rv = intr_disconnect_level(cpu, bit); ASSERT(rv == 0); intr_hdl->i_flags &= ~HUB_INTR_IS_CONNECTED; }