/* * 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 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * ACPI Poweroff patchable options in acpi_poweroff_opt for broken BIOS * workarounds. */ #define ACPI_PO_CLRWAK 0x0001 #define ACPI_PO_CLRALL 0x0002 #define ACPI_PO_RSTGPE 0x0004 #define ACPI_PO_DISARB 0x0008 #define ACPI_PO_2NDTRY 0x0010 /* Global configurables */ char *psm_module_name; /* used to store name of psm module */ /* * acpi_irq_check_elcr: when set elcr will also be consulted for building * the reserved irq list. When 0 (false), the existing state of the ELCR * is ignored when selecting a vector during IRQ translation, and the ELCR * is programmed to the proper setting for the type of bus (level-triggered * for PCI, edge-triggered for non-PCI). When non-zero (true), vectors * set to edge-mode will not be used when in PIC-mode. The default value * is 0 (false). Note that ACPI's SCI vector is always set to conform to * ACPI-specification regardless of this. * */ int acpi_irq_check_elcr = 0; /* * acpi_s5_slp_typ: * If >= 0 then override the \_S5 parameter return value. This is useful * for systems with broken \_S5 methods which return the wrong value for * the chipset in use. */ int acpi_s5_slp_typ = -1; int acpi_s5_slp_typ2 = -1; /* second parameter (only patch if different) */ int acpi_poweroff_opt = 0; /* patchable poweroff options */ int psm_verbose = 0; #define PSM_VERBOSE_IRQ(fmt) \ if (psm_verbose & PSM_VERBOSE_IRQ_FLAG) \ cmn_err fmt; #define PSM_VERBOSE_POWEROFF(fmt) \ if (psm_verbose & PSM_VERBOSE_POWEROFF_FLAG || \ psm_verbose & PSM_VERBOSE_POWEROFF_PAUSE_FLAG) \ prom_printf fmt; #define PSM_VERBOSE_POWEROFF_PAUSE(fmt) \ if (psm_verbose & PSM_VERBOSE_POWEROFF_FLAG || \ psm_verbose & PSM_VERBOSE_POWEROFF_PAUSE_FLAG) {\ prom_printf fmt; \ if (psm_verbose & PSM_VERBOSE_POWEROFF_PAUSE_FLAG) \ (void) goany(); \ } /* Local storage */ static ACPI_HANDLE acpi_sbobj = NULL; static kmutex_t acpi_irq_cache_mutex; /* * irq_cache_table is a list that serves a two-key cache. It is used * as a pci busid/devid/ipin <-> irq cache and also as a acpi * interrupt lnk <-> irq cache. */ static irq_cache_t *irq_cache_table; #define IRQ_CACHE_INITLEN 20 static int irq_cache_len = 0; static int irq_cache_valid = 0; static int acpi_get_gsiv(dev_info_t *dip, ACPI_HANDLE pciobj, int devno, int ipin, int *pci_irqp, iflag_t *iflagp, acpi_psm_lnk_t *acpipsmlnkp); static int acpi_eval_lnk(dev_info_t *dip, char *lnkname, int *pci_irqp, iflag_t *intr_flagp, acpi_psm_lnk_t *acpipsmlnkp); static int acpi_get_irq_lnk_cache_ent(ACPI_HANDLE lnkobj, int *pci_irqp, iflag_t *intr_flagp); extern int goany(void); #define NEXT_PRT_ITEM(p) \ (ACPI_PCI_ROUTING_TABLE *)(((char *)(p)) + (p)->Length) static int acpi_get_gsiv(dev_info_t *dip, ACPI_HANDLE pciobj, int devno, int ipin, int *pci_irqp, iflag_t *intr_flagp, acpi_psm_lnk_t *acpipsmlnkp) { ACPI_BUFFER rb; ACPI_PCI_ROUTING_TABLE *prtp; int status; int dev_adr; /* * Get the IRQ routing table */ rb.Pointer = NULL; rb.Length = ACPI_ALLOCATE_BUFFER; if (AcpiGetIrqRoutingTable(pciobj, &rb) != AE_OK) { return (ACPI_PSM_FAILURE); } status = ACPI_PSM_FAILURE; dev_adr = (devno << 16 | 0xffff); for (prtp = rb.Pointer; prtp->Length != 0; prtp = NEXT_PRT_ITEM(prtp)) { /* look until a matching dev/pin is found */ if (dev_adr != prtp->Address || ipin != prtp->Pin) continue; /* NULL Source name means index is GSIV */ if (*prtp->Source == 0) { intr_flagp->intr_el = TRIGGER_LEVEL; intr_flagp->intr_po = POLARITY_ACTIVE_LOW; ASSERT(pci_irqp != NULL); *pci_irqp = prtp->SourceIndex; status = ACPI_PSM_SUCCESS; } else status = acpi_eval_lnk(dip, prtp->Source, pci_irqp, intr_flagp, acpipsmlnkp); break; } AcpiOsFree(rb.Pointer); return (status); } /* * * If the interrupt link device is already configured, * stores polarity and sensitivity in the structure pointed to by * intr_flagp, and irqno in the value pointed to by pci_irqp. * * Returns: * ACPI_PSM_SUCCESS if the interrupt link device is already configured. * ACPI_PSM_PARTIAL if configuration is needed. * ACPI_PSM_FAILURE in case of error. * * When two devices share the same interrupt link device, and the * link device is already configured (i.e. found in the irq cache) * we need to use the already configured irq instead of reconfiguring * the link device. */ static int acpi_eval_lnk(dev_info_t *dip, char *lnkname, int *pci_irqp, iflag_t *intr_flagp, acpi_psm_lnk_t *acpipsmlnkp) { ACPI_HANDLE tmpobj; ACPI_HANDLE lnkobj; int status; /* * Convert the passed-in link device name to a handle */ if (AcpiGetHandle(NULL, lnkname, &lnkobj) != AE_OK) { return (ACPI_PSM_FAILURE); } /* * Assume that the link device is invalid if no _CRS method * exists, since _CRS method is a required method */ if (AcpiGetHandle(lnkobj, "_CRS", &tmpobj) != AE_OK) { return (ACPI_PSM_FAILURE); } ASSERT(acpipsmlnkp != NULL); acpipsmlnkp->lnkobj = lnkobj; if ((acpi_get_irq_lnk_cache_ent(lnkobj, pci_irqp, intr_flagp)) == ACPI_PSM_SUCCESS) { PSM_VERBOSE_IRQ((CE_CONT, "!psm: link object found from cache " " for device %s, instance #%d, irq no %d\n", ddi_get_name(dip), ddi_get_instance(dip), *pci_irqp)); return (ACPI_PSM_SUCCESS); } else { if (acpica_eval_int(lnkobj, "_STA", &status) == AE_OK) { acpipsmlnkp->device_status = (uchar_t)status; } return (ACPI_PSM_PARTIAL); } } int acpi_psm_init(char *module_name, int verbose_flags) { psm_module_name = module_name; psm_verbose = verbose_flags; if (AcpiGetHandle(NULL, "\\_SB", &acpi_sbobj) != AE_OK) { cmn_err(CE_WARN, "!psm: get _SB failed"); return (ACPI_PSM_FAILURE); } mutex_init(&acpi_irq_cache_mutex, NULL, MUTEX_DEFAULT, NULL); return (ACPI_PSM_SUCCESS); } /* * Return bus/dev/fn for PCI dip (note: not the parent "pci" node). */ int get_bdf(dev_info_t *dip, int *bus, int *device, int *func) { pci_regspec_t *pci_rp; int len; if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, "reg", (int **)&pci_rp, (uint_t *)&len) != DDI_SUCCESS) return (-1); if (len < (sizeof (pci_regspec_t) / sizeof (int))) { ddi_prop_free(pci_rp); return (-1); } if (bus != NULL) *bus = (int)PCI_REG_BUS_G(pci_rp->pci_phys_hi); if (device != NULL) *device = (int)PCI_REG_DEV_G(pci_rp->pci_phys_hi); if (func != NULL) *func = (int)PCI_REG_FUNC_G(pci_rp->pci_phys_hi); ddi_prop_free(pci_rp); return (0); } /* * Build the reserved ISA irq list, and store it in the table pointed to by * reserved_irqs_table. The caller is responsible for allocating this table * with a minimum of MAX_ISA_IRQ + 1 entries. * * The routine looks in the device tree at the subtree rooted at /isa * for each of the devices under that node, if an interrupts property * is present, its values are used to "reserve" irqs so that later ACPI * configuration won't choose those irqs. * * In addition, if acpi_irq_check_elcr is set, will use ELCR register * to identify reserved IRQs. */ void build_reserved_irqlist(uchar_t *reserved_irqs_table) { dev_info_t *isanode = ddi_find_devinfo("isa", -1, 0); dev_info_t *isa_child = 0; int i; uint_t elcrval; /* Initialize the reserved ISA IRQs: */ for (i = 0; i <= MAX_ISA_IRQ; i++) reserved_irqs_table[i] = 0; if (acpi_irq_check_elcr) { elcrval = (inb(ELCR_PORT2) << 8) | (inb(ELCR_PORT1)); if (ELCR_EDGE(elcrval, 0) && ELCR_EDGE(elcrval, 1) && ELCR_EDGE(elcrval, 2) && ELCR_EDGE(elcrval, 8) && ELCR_EDGE(elcrval, 13)) { /* valid ELCR */ for (i = 0; i <= MAX_ISA_IRQ; i++) if (!ELCR_LEVEL(elcrval, i)) reserved_irqs_table[i] = 1; } } /* always check the isa devinfo nodes */ if (isanode != 0) { /* Found ISA */ uint_t intcnt; /* Interrupt count */ int *intrs; /* Interrupt values */ /* Load first child: */ isa_child = ddi_get_child(isanode); while (isa_child != 0) { /* Iterate over /isa children */ /* if child has any interrupts, save them */ if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, isa_child, DDI_PROP_DONTPASS, "interrupts", &intrs, &intcnt) == DDI_PROP_SUCCESS) { /* * iterate over child interrupt list, adding * them to the reserved irq list */ while (intcnt-- > 0) { /* * Each value MUST be <= MAX_ISA_IRQ */ if ((intrs[intcnt] > MAX_ISA_IRQ) || (intrs[intcnt] < 0)) continue; reserved_irqs_table[intrs[intcnt]] = 1; } ddi_prop_free(intrs); } isa_child = ddi_get_next_sibling(isa_child); } /* The isa node was held by ddi_find_devinfo, so release it */ ndi_rele_devi(isanode); } /* * Reserve IRQ14 & IRQ15 for IDE. It shouldn't be hard-coded * here but there's no other way to find the irqs for * legacy-mode ata (since it's hard-coded in pci-ide also). */ reserved_irqs_table[14] = 1; reserved_irqs_table[15] = 1; } /* * Examine devinfo node to determine if it is a PCI-PCI bridge * * Returns: * 0 if not a bridge or error * 1 if a bridge */ static int psm_is_pci_bridge(dev_info_t *dip) { ddi_acc_handle_t cfg_handle; int rv = 0; if (pci_config_setup(dip, &cfg_handle) == DDI_SUCCESS) { rv = ((pci_config_get8(cfg_handle, PCI_CONF_BASCLASS) == PCI_CLASS_BRIDGE) && (pci_config_get8(cfg_handle, PCI_CONF_SUBCLASS) == PCI_BRIDGE_PCI)); pci_config_teardown(&cfg_handle); } return (rv); } /* * Examines ACPI node for presence of _PRT object * * Returns: * 0 if no _PRT or error * 1 if _PRT is present */ static int psm_node_has_prt(ACPI_HANDLE *ah) { ACPI_HANDLE rh; return (AcpiGetHandle(ah, "_PRT", &rh) == AE_OK); } /* * Look first for an ACPI PCI bus node matching busid, then for a _PRT on the * parent node; then drop into the bridge-chasing code (which will also * look for _PRTs on the way up the tree of bridges) * * Stores polarity and sensitivity in the structure pointed to by * intr_flagp, and irqno in the value pointed to by pci_irqp. * * Returns: * ACPI_PSM_SUCCESS on success. * ACPI_PSM_PARTIAL to indicate need to configure the interrupt * link device. * ACPI_PSM_FAILURE if an error prevented the system from * obtaining irq information for dip. */ int acpi_translate_pci_irq(dev_info_t *dip, int ipin, int *pci_irqp, iflag_t *intr_flagp, acpi_psm_lnk_t *acpipsmlnkp) { ACPI_HANDLE pciobj; int status = AE_ERROR; dev_info_t *curdip, *parentdip; int curpin, curbus, curdev; curpin = ipin; curdip = dip; while (curdip != ddi_root_node()) { parentdip = ddi_get_parent(curdip); ASSERT(parentdip != NULL); if (get_bdf(curdip, &curbus, &curdev, NULL) != 0) { break; } status = acpica_find_pciobj(parentdip, &pciobj); if ((status == AE_OK) && psm_node_has_prt(pciobj)) { return (acpi_get_gsiv(curdip, pciobj, curdev, curpin, pci_irqp, intr_flagp, acpipsmlnkp)); } /* if we got here, we need to traverse a bridge upwards */ if (!psm_is_pci_bridge(parentdip)) break; /* * This is the rotating scheme that Compaq is using * and documented in the PCI-PCI spec. Also, if the * PCI-PCI bridge is behind another PCI-PCI bridge, * then it needs to keep ascending until an interrupt * entry is found or the top is reached */ curpin = (curdev + curpin) % PCI_INTD; curdip = parentdip; } /* * We should never, ever get here; didn't find a _PRT */ return (ACPI_PSM_FAILURE); } /* * Sets the irq resource of the lnk object to the requested irq value. * * Returns ACPI_PSM_SUCCESS on success, ACPI_PSM_FAILURE upon failure. */ int acpi_set_irq_resource(acpi_psm_lnk_t *acpipsmlnkp, int irq) { ACPI_BUFFER rsb; ACPI_RESOURCE *resp; ACPI_RESOURCE *srsp; ACPI_HANDLE lnkobj; int srs_len, status; ASSERT(acpipsmlnkp != NULL); lnkobj = acpipsmlnkp->lnkobj; /* * Fetch the possible resources for the link */ rsb.Pointer = NULL; rsb.Length = ACPI_ALLOCATE_BUFFER; status = AcpiGetPossibleResources(lnkobj, &rsb); if (status != AE_OK) { cmn_err(CE_WARN, "!psm: set_irq: _PRS failed"); return (ACPI_PSM_FAILURE); } /* * Find an IRQ resource descriptor to use as template */ srsp = NULL; for (resp = rsb.Pointer; resp->Type != ACPI_RESOURCE_TYPE_END_TAG; resp = ACPI_NEXT_RESOURCE(resp)) { if ((resp->Type == ACPI_RESOURCE_TYPE_IRQ) || (resp->Type == ACPI_RESOURCE_TYPE_EXTENDED_IRQ)) { ACPI_RESOURCE *endtag; /* * Allocate enough room for this resource entry * and one end tag following it */ srs_len = resp->Length + sizeof (*endtag); srsp = kmem_zalloc(srs_len, KM_SLEEP); bcopy(resp, srsp, resp->Length); endtag = ACPI_NEXT_RESOURCE(srsp); endtag->Type = ACPI_RESOURCE_TYPE_END_TAG; endtag->Length = 0; break; /* drop out of the loop */ } } /* * We're done with the PRS values, toss 'em lest we forget */ AcpiOsFree(rsb.Pointer); if (srsp == NULL) return (ACPI_PSM_FAILURE); /* * The Interrupts[] array is always at least one entry * long; see the definition of ACPI_RESOURCE. */ switch (srsp->Type) { case ACPI_RESOURCE_TYPE_IRQ: srsp->Data.Irq.InterruptCount = 1; srsp->Data.Irq.Interrupts[0] = irq; break; case ACPI_RESOURCE_TYPE_EXTENDED_IRQ: srsp->Data.ExtendedIrq.InterruptCount = 1; srsp->Data.ExtendedIrq.Interrupts[0] = irq; break; } rsb.Pointer = srsp; rsb.Length = srs_len; status = AcpiSetCurrentResources(lnkobj, &rsb); kmem_free(srsp, srs_len); if (status != AE_OK) { cmn_err(CE_WARN, "!psm: set_irq: _SRS failed"); return (ACPI_PSM_FAILURE); } if (acpica_eval_int(lnkobj, "_STA", &status) == AE_OK) { acpipsmlnkp->device_status = (uchar_t)status; return (ACPI_PSM_SUCCESS); } else return (ACPI_PSM_FAILURE); } /* * */ static int psm_acpi_edgelevel(UINT32 el) { switch (el) { case ACPI_EDGE_SENSITIVE: return (INTR_EL_EDGE); case ACPI_LEVEL_SENSITIVE: return (INTR_EL_LEVEL); default: /* el is a single bit; should never reach here */ return (INTR_EL_CONFORM); } } /* * */ static int psm_acpi_po(UINT32 po) { switch (po) { case ACPI_ACTIVE_HIGH: return (INTR_PO_ACTIVE_HIGH); case ACPI_ACTIVE_LOW: return (INTR_PO_ACTIVE_LOW); default: /* po is a single bit; should never reach here */ return (INTR_PO_CONFORM); } } /* * Retrieves the current irq setting for the interrrupt link device. * * Stores polarity and sensitivity in the structure pointed to by * intr_flagp, and irqno in the value pointed to by pci_irqp. * * Returns ACPI_PSM_SUCCESS on success, ACPI_PSM_FAILURE upon failure. */ int acpi_get_current_irq_resource(acpi_psm_lnk_t *acpipsmlnkp, int *pci_irqp, iflag_t *intr_flagp) { ACPI_HANDLE lnkobj; ACPI_BUFFER rb; ACPI_RESOURCE *rp; int irq; int status = ACPI_PSM_FAILURE; ASSERT(acpipsmlnkp != NULL); lnkobj = acpipsmlnkp->lnkobj; if (!(acpipsmlnkp->device_status & STA_PRESENT) || !(acpipsmlnkp->device_status & STA_ENABLE)) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: crs device either not " "present or disabled, status 0x%x", acpipsmlnkp->device_status)); return (ACPI_PSM_FAILURE); } rb.Pointer = NULL; rb.Length = ACPI_ALLOCATE_BUFFER; if (AcpiGetCurrentResources(lnkobj, &rb) != AE_OK) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: no crs object found or" " evaluation failed")); return (ACPI_PSM_FAILURE); } irq = -1; for (rp = rb.Pointer; rp->Type != ACPI_RESOURCE_TYPE_END_TAG; rp = ACPI_NEXT_RESOURCE(rp)) { if (rp->Type == ACPI_RESOURCE_TYPE_IRQ) { if (irq > 0) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: multiple IRQ" " from _CRS ")); status = ACPI_PSM_FAILURE; break; } if (rp->Data.Irq.InterruptCount != 1) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: <>1 interrupt" " from _CRS ")); status = ACPI_PSM_FAILURE; break; } intr_flagp->intr_el = psm_acpi_edgelevel( rp->Data.Irq.Triggering); intr_flagp->intr_po = psm_acpi_po( rp->Data.Irq.Polarity); irq = rp->Data.Irq.Interrupts[0]; status = ACPI_PSM_SUCCESS; } else if (rp->Type == ACPI_RESOURCE_TYPE_EXTENDED_IRQ) { if (irq > 0) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: multiple IRQ" " from _CRS ")); status = ACPI_PSM_FAILURE; break; } if (rp->Data.ExtendedIrq.InterruptCount != 1) { PSM_VERBOSE_IRQ((CE_WARN, "!psm: <>1 interrupt" " from _CRS ")); status = ACPI_PSM_FAILURE; break; } intr_flagp->intr_el = psm_acpi_edgelevel( rp->Data.ExtendedIrq.Triggering); intr_flagp->intr_po = psm_acpi_po( rp->Data.ExtendedIrq.Polarity); irq = rp->Data.ExtendedIrq.Interrupts[0]; status = ACPI_PSM_SUCCESS; } } AcpiOsFree(rb.Pointer); if (status == ACPI_PSM_SUCCESS) { *pci_irqp = irq; } return (status); } /* * Searches for the given IRQ in the irqlist passed in. * * If multiple matches exist, this returns true on the first match. * Returns the interrupt flags, if a match was found, in `intr_flagp' if * it's passed in non-NULL */ int acpi_irqlist_find_irq(acpi_irqlist_t *irqlistp, int irq, iflag_t *intr_flagp) { int found = 0; int i; while (irqlistp != NULL && !found) { for (i = 0; i < irqlistp->num_irqs; i++) { if (irqlistp->irqs[i] == irq) { if (intr_flagp) *intr_flagp = irqlistp->intr_flags; found = 1; break; /* out of for() */ } } } return (found ? ACPI_PSM_SUCCESS : ACPI_PSM_FAILURE); } /* * Frees the irqlist allocated by acpi_get_possible_irq_resource. * It takes a count of number of entries in the list. */ void acpi_free_irqlist(acpi_irqlist_t *irqlistp) { acpi_irqlist_t *freednode; while (irqlistp != NULL) { /* Free the irq list */ kmem_free(irqlistp->irqs, irqlistp->num_irqs * sizeof (int32_t)); freednode = irqlistp; irqlistp = irqlistp->next; kmem_free(freednode, sizeof (acpi_irqlist_t)); } } /* * Creates a new entry in the given irqlist with the information passed in. */ static void acpi_add_irqlist_entry(acpi_irqlist_t **irqlistp, uint32_t *irqlist, int irqlist_len, iflag_t *intr_flagp) { acpi_irqlist_t *newent; ASSERT(irqlist != NULL); ASSERT(intr_flagp != NULL); newent = kmem_alloc(sizeof (acpi_irqlist_t), KM_SLEEP); newent->intr_flags = *intr_flagp; newent->irqs = irqlist; newent->num_irqs = irqlist_len; newent->next = *irqlistp; *irqlistp = newent; } /* * Retrieves a list of possible interrupt settings for the interrupt link * device. * * Stores polarity and sensitivity in the structure pointed to by intr_flagp. * Updates value pointed to by irqlistp with the address of a table it * allocates. where interrupt numbers are stored. Stores the number of entries * in this table in the value pointed to by num_entriesp; * * Each element in this table is of type int32_t. The table should be later * freed by caller via acpi_free_irq_list(). * * Returns ACPI_PSM_SUCCESS on success and ACPI_PSM_FAILURE upon failure */ int acpi_get_possible_irq_resources(acpi_psm_lnk_t *acpipsmlnkp, acpi_irqlist_t **irqlistp) { ACPI_HANDLE lnkobj; ACPI_BUFFER rsb; ACPI_RESOURCE *resp; int status; int i, el, po, irqlist_len; uint32_t *irqlist; void *tmplist; iflag_t intr_flags; ASSERT(acpipsmlnkp != NULL); lnkobj = acpipsmlnkp->lnkobj; rsb.Pointer = NULL; rsb.Length = ACPI_ALLOCATE_BUFFER; status = AcpiGetPossibleResources(lnkobj, &rsb); if (status != AE_OK) { cmn_err(CE_WARN, "!psm: get_irq: _PRS failed"); return (ACPI_PSM_FAILURE); } /* * Scan the resources looking for an interrupt resource */ *irqlistp = 0; for (resp = rsb.Pointer; resp->Type != ACPI_RESOURCE_TYPE_END_TAG; resp = ACPI_NEXT_RESOURCE(resp)) { switch (resp->Type) { case ACPI_RESOURCE_TYPE_IRQ: irqlist_len = resp->Data.Irq.InterruptCount; tmplist = resp->Data.Irq.Interrupts; el = resp->Data.Irq.Triggering; po = resp->Data.Irq.Polarity; break; case ACPI_RESOURCE_TYPE_EXTENDED_IRQ: irqlist_len = resp->Data.ExtendedIrq.InterruptCount; tmplist = resp->Data.ExtendedIrq.Interrupts; el = resp->Data.ExtendedIrq.Triggering; po = resp->Data.ExtendedIrq.Polarity; break; default: continue; } if (resp->Type != ACPI_RESOURCE_TYPE_IRQ && resp->Type != ACPI_RESOURCE_TYPE_EXTENDED_IRQ) { cmn_err(CE_WARN, "!psm: get_irq: no IRQ resource"); return (ACPI_PSM_FAILURE); } /* NEEDSWORK: move this into add_irqlist_entry someday */ irqlist = kmem_zalloc(irqlist_len * sizeof (*irqlist), KM_SLEEP); for (i = 0; i < irqlist_len; i++) if (resp->Type == ACPI_RESOURCE_TYPE_IRQ) irqlist[i] = ((uint8_t *)tmplist)[i]; else irqlist[i] = ((uint32_t *)tmplist)[i]; intr_flags.intr_el = psm_acpi_edgelevel(el); intr_flags.intr_po = psm_acpi_po(po); acpi_add_irqlist_entry(irqlistp, irqlist, irqlist_len, &intr_flags); } AcpiOsFree(rsb.Pointer); return (irqlistp == NULL ? ACPI_PSM_FAILURE : ACPI_PSM_SUCCESS); } /* * Adds a new cache entry to the irq cache which maps an irq and * its attributes to PCI bus/dev/ipin and optionally to its associated ACPI * interrupt link device object. */ void acpi_new_irq_cache_ent(int bus, int dev, int ipin, int pci_irq, iflag_t *intr_flagp, acpi_psm_lnk_t *acpipsmlnkp) { int newsize; irq_cache_t *new_arr, *ep; mutex_enter(&acpi_irq_cache_mutex); if (irq_cache_valid >= irq_cache_len) { /* initially, or re-, allocate array */ newsize = (irq_cache_len ? irq_cache_len * 2 : IRQ_CACHE_INITLEN); new_arr = kmem_zalloc(newsize * sizeof (irq_cache_t), KM_SLEEP); if (irq_cache_len != 0) { /* realloc: copy data, free old */ bcopy(irq_cache_table, new_arr, irq_cache_len * sizeof (irq_cache_t)); kmem_free(irq_cache_table, irq_cache_len * sizeof (irq_cache_t)); } irq_cache_len = newsize; irq_cache_table = new_arr; } ep = &irq_cache_table[irq_cache_valid++]; ep->bus = (uchar_t)bus; ep->dev = (uchar_t)dev; ep->ipin = (uchar_t)ipin; ep->flags = *intr_flagp; ep->irq = pci_irq; ASSERT(acpipsmlnkp != NULL); ep->lnkobj = acpipsmlnkp->lnkobj; mutex_exit(&acpi_irq_cache_mutex); } /* * Searches the irq caches for the given bus/dev/ipin. * * If info is found, stores polarity and sensitivity in the structure * pointed to by intr_flagp, and irqno in the value pointed to by pci_irqp, * and returns ACPI_PSM_SUCCESS. * Otherwise, ACPI_PSM_FAILURE is returned. */ int acpi_get_irq_cache_ent(uchar_t bus, uchar_t dev, int ipin, int *pci_irqp, iflag_t *intr_flagp) { irq_cache_t *irqcachep; int i; int ret = ACPI_PSM_FAILURE; mutex_enter(&acpi_irq_cache_mutex); for (irqcachep = irq_cache_table, i = 0; i < irq_cache_valid; irqcachep++, i++) if ((irqcachep->bus == bus) && (irqcachep->dev == dev) && (irqcachep->ipin == ipin)) { ASSERT(pci_irqp != NULL && intr_flagp != NULL); *pci_irqp = irqcachep->irq; *intr_flagp = irqcachep->flags; ret = ACPI_PSM_SUCCESS; break; } mutex_exit(&acpi_irq_cache_mutex); return (ret); } /* * Searches the irq caches for the given interrupt lnk device object. * * If info is found, stores polarity and sensitivity in the structure * pointed to by intr_flagp, and irqno in the value pointed to by pci_irqp, * and returns ACPI_PSM_SUCCESS. * Otherwise, ACPI_PSM_FAILURE is returned. */ int acpi_get_irq_lnk_cache_ent(ACPI_HANDLE lnkobj, int *pci_irqp, iflag_t *intr_flagp) { irq_cache_t *irqcachep; int i; int ret = ACPI_PSM_FAILURE; if (lnkobj == NULL) return (ACPI_PSM_FAILURE); mutex_enter(&acpi_irq_cache_mutex); for (irqcachep = irq_cache_table, i = 0; i < irq_cache_valid; irqcachep++, i++) if (irqcachep->lnkobj == lnkobj) { ASSERT(pci_irqp != NULL); *pci_irqp = irqcachep->irq; ASSERT(intr_flagp != NULL); *intr_flagp = irqcachep->flags; ret = ACPI_PSM_SUCCESS; break; } mutex_exit(&acpi_irq_cache_mutex); return (ret); } int acpi_poweroff(void) { PSM_VERBOSE_POWEROFF(("acpi_poweroff: starting poweroff\n")); if (AcpiEnterSleepStatePrep(5) != AE_OK) return (1); ACPI_DISABLE_IRQS(); if (AcpiEnterSleepState(5) != AE_OK) { ACPI_ENABLE_IRQS(); return (1); } ACPI_ENABLE_IRQS(); /* we should be off; if we get here it's an error */ PSM_VERBOSE_POWEROFF(("acpi_poweroff: failed to actually power off\n")); return (1); } /* * psm_set_elcr() sets ELCR bit for specified vector */ void psm_set_elcr(int vecno, int val) { int elcr_port = ELCR_PORT1 + (vecno >> 3); int elcr_bit = 1 << (vecno & 0x07); ASSERT((vecno >= 0) && (vecno < 16)); if (val) { /* set bit to force level-triggered mode */ outb(elcr_port, inb(elcr_port) | elcr_bit); } else { /* clear bit to force edge-triggered mode */ outb(elcr_port, inb(elcr_port) & ~elcr_bit); } } /* * psm_get_elcr() returns status of ELCR bit for specific vector */ int psm_get_elcr(int vecno) { int elcr_port = ELCR_PORT1 + (vecno >> 3); int elcr_bit = 1 << (vecno & 0x07); ASSERT((vecno >= 0) && (vecno < 16)); return ((inb(elcr_port) & elcr_bit) ? 1 : 0); }