/* * 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 2008 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* include implementation structure defs */ #include /* include prototypes */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern pri_t minclsyspri; extern rctl_hndl_t rc_project_locked_mem; extern rctl_hndl_t rc_zone_locked_mem; #ifdef DEBUG static int sunddi_debug = 0; #endif /* DEBUG */ /* ddi_umem_unlock miscellaneous */ static void i_ddi_umem_unlock_thread_start(void); static kmutex_t ddi_umem_unlock_mutex; /* unlock list mutex */ static kcondvar_t ddi_umem_unlock_cv; /* unlock list block/unblock */ static kthread_t *ddi_umem_unlock_thread; /* * The ddi_umem_unlock FIFO list. NULL head pointer indicates empty list. */ static struct ddi_umem_cookie *ddi_umem_unlock_head = NULL; static struct ddi_umem_cookie *ddi_umem_unlock_tail = NULL; /* * DDI(Sun) Function and flag definitions: */ #if defined(__x86) /* * Used to indicate which entries were chosen from a range. */ char *chosen_reg = "chosen-reg"; #endif /* * Function used to ring system console bell */ void (*ddi_console_bell_func)(clock_t duration); /* * Creating register mappings and handling interrupts: */ /* * Generic ddi_map: Call parent to fulfill request... */ int ddi_map(dev_info_t *dp, ddi_map_req_t *mp, off_t offset, off_t len, caddr_t *addrp) { dev_info_t *pdip; ASSERT(dp); pdip = (dev_info_t *)DEVI(dp)->devi_parent; return ((DEVI(pdip)->devi_ops->devo_bus_ops->bus_map)(pdip, dp, mp, offset, len, addrp)); } /* * ddi_apply_range: (Called by nexi only.) * Apply ranges in parent node dp, to child regspec rp... */ int ddi_apply_range(dev_info_t *dp, dev_info_t *rdip, struct regspec *rp) { return (i_ddi_apply_range(dp, rdip, rp)); } int ddi_map_regs(dev_info_t *dip, uint_t rnumber, caddr_t *kaddrp, off_t offset, off_t len) { ddi_map_req_t mr; #if defined(__x86) struct { int bus; int addr; int size; } reg, *reglist; uint_t length; int rc; /* * get the 'registers' or the 'reg' property. * We look up the reg property as an array of * int's. */ rc = ddi_prop_lookup_int_array(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, "registers", (int **)®list, &length); if (rc != DDI_PROP_SUCCESS) rc = ddi_prop_lookup_int_array(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, "reg", (int **)®list, &length); if (rc == DDI_PROP_SUCCESS) { /* * point to the required entry. */ reg = reglist[rnumber]; reg.addr += offset; if (len != 0) reg.size = len; /* * make a new property containing ONLY the required tuple. */ if (ddi_prop_update_int_array(DDI_DEV_T_NONE, dip, chosen_reg, (int *)®, (sizeof (reg)/sizeof (int))) != DDI_PROP_SUCCESS) { cmn_err(CE_WARN, "%s%d: cannot create '%s' " "property", DEVI(dip)->devi_name, DEVI(dip)->devi_instance, chosen_reg); } /* * free the memory allocated by * ddi_prop_lookup_int_array (). */ ddi_prop_free((void *)reglist); } #endif mr.map_op = DDI_MO_MAP_LOCKED; mr.map_type = DDI_MT_RNUMBER; mr.map_obj.rnumber = rnumber; mr.map_prot = PROT_READ | PROT_WRITE; mr.map_flags = DDI_MF_KERNEL_MAPPING; mr.map_handlep = NULL; mr.map_vers = DDI_MAP_VERSION; /* * Call my parent to map in my regs. */ return (ddi_map(dip, &mr, offset, len, kaddrp)); } void ddi_unmap_regs(dev_info_t *dip, uint_t rnumber, caddr_t *kaddrp, off_t offset, off_t len) { ddi_map_req_t mr; mr.map_op = DDI_MO_UNMAP; mr.map_type = DDI_MT_RNUMBER; mr.map_flags = DDI_MF_KERNEL_MAPPING; mr.map_prot = PROT_READ | PROT_WRITE; /* who cares? */ mr.map_obj.rnumber = rnumber; mr.map_handlep = NULL; mr.map_vers = DDI_MAP_VERSION; /* * Call my parent to unmap my regs. */ (void) ddi_map(dip, &mr, offset, len, kaddrp); *kaddrp = (caddr_t)0; #if defined(__x86) (void) ddi_prop_remove(DDI_DEV_T_NONE, dip, chosen_reg); #endif } int ddi_bus_map(dev_info_t *dip, dev_info_t *rdip, ddi_map_req_t *mp, off_t offset, off_t len, caddr_t *vaddrp) { return (i_ddi_bus_map(dip, rdip, mp, offset, len, vaddrp)); } /* * nullbusmap: The/DDI default bus_map entry point for nexi * not conforming to the reg/range paradigm (i.e. scsi, etc.) * with no HAT/MMU layer to be programmed at this level. * * If the call is to map by rnumber, return an error, * otherwise pass anything else up the tree to my parent. */ int nullbusmap(dev_info_t *dip, dev_info_t *rdip, ddi_map_req_t *mp, off_t offset, off_t len, caddr_t *vaddrp) { _NOTE(ARGUNUSED(rdip)) if (mp->map_type == DDI_MT_RNUMBER) return (DDI_ME_UNSUPPORTED); return (ddi_map(dip, mp, offset, len, vaddrp)); } /* * ddi_rnumber_to_regspec: Not for use by leaf drivers. * Only for use by nexi using the reg/range paradigm. */ struct regspec * ddi_rnumber_to_regspec(dev_info_t *dip, int rnumber) { return (i_ddi_rnumber_to_regspec(dip, rnumber)); } /* * Note that we allow the dip to be nil because we may be called * prior even to the instantiation of the devinfo tree itself - all * regular leaf and nexus drivers should always use a non-nil dip! * * We treat peek in a somewhat cavalier fashion .. assuming that we'll * simply get a synchronous fault as soon as we touch a missing address. * * Poke is rather more carefully handled because we might poke to a write * buffer, "succeed", then only find some time later that we got an * asynchronous fault that indicated that the address we were writing to * was not really backed by hardware. */ static int i_ddi_peekpoke(dev_info_t *devi, ddi_ctl_enum_t cmd, size_t size, void *addr, void *value_p) { union { uint64_t u64; uint32_t u32; uint16_t u16; uint8_t u8; } peekpoke_value; peekpoke_ctlops_t peekpoke_args; uint64_t dummy_result; int rval; /* Note: size is assumed to be correct; it is not checked. */ peekpoke_args.size = size; peekpoke_args.dev_addr = (uintptr_t)addr; peekpoke_args.handle = NULL; peekpoke_args.repcount = 1; peekpoke_args.flags = 0; if (cmd == DDI_CTLOPS_POKE) { switch (size) { case sizeof (uint8_t): peekpoke_value.u8 = *(uint8_t *)value_p; break; case sizeof (uint16_t): peekpoke_value.u16 = *(uint16_t *)value_p; break; case sizeof (uint32_t): peekpoke_value.u32 = *(uint32_t *)value_p; break; case sizeof (uint64_t): peekpoke_value.u64 = *(uint64_t *)value_p; break; } } peekpoke_args.host_addr = (uintptr_t)&peekpoke_value.u64; if (devi != NULL) rval = ddi_ctlops(devi, devi, cmd, &peekpoke_args, &dummy_result); else rval = peekpoke_mem(cmd, &peekpoke_args); /* * A NULL value_p is permitted by ddi_peek(9F); discard the result. */ if ((cmd == DDI_CTLOPS_PEEK) & (value_p != NULL)) { switch (size) { case sizeof (uint8_t): *(uint8_t *)value_p = peekpoke_value.u8; break; case sizeof (uint16_t): *(uint16_t *)value_p = peekpoke_value.u16; break; case sizeof (uint32_t): *(uint32_t *)value_p = peekpoke_value.u32; break; case sizeof (uint64_t): *(uint64_t *)value_p = peekpoke_value.u64; break; } } return (rval); } /* * Keep ddi_peek() and ddi_poke() in case 3rd parties are calling this. * they shouldn't be, but the 9f manpage kind of pseudo exposes it. */ int ddi_peek(dev_info_t *devi, size_t size, void *addr, void *value_p) { switch (size) { case sizeof (uint8_t): case sizeof (uint16_t): case sizeof (uint32_t): case sizeof (uint64_t): break; default: return (DDI_FAILURE); } return (i_ddi_peekpoke(devi, DDI_CTLOPS_PEEK, size, addr, value_p)); } int ddi_poke(dev_info_t *devi, size_t size, void *addr, void *value_p) { switch (size) { case sizeof (uint8_t): case sizeof (uint16_t): case sizeof (uint32_t): case sizeof (uint64_t): break; default: return (DDI_FAILURE); } return (i_ddi_peekpoke(devi, DDI_CTLOPS_POKE, size, addr, value_p)); } int ddi_peek8(dev_info_t *dip, int8_t *addr, int8_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peek16(dev_info_t *dip, int16_t *addr, int16_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peek32(dev_info_t *dip, int32_t *addr, int32_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peek64(dev_info_t *dip, int64_t *addr, int64_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } /* * We need to separate the old interfaces from the new ones and leave them * in here for a while. Previous versions of the OS defined the new interfaces * to the old interfaces. This way we can fix things up so that we can * eventually remove these interfaces. * e.g. A 3rd party module/driver using ddi_peek8 and built against S10 * or earlier will actually have a reference to ddi_peekc in the binary. */ #ifdef _ILP32 int ddi_peekc(dev_info_t *dip, int8_t *addr, int8_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peeks(dev_info_t *dip, int16_t *addr, int16_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peekl(dev_info_t *dip, int32_t *addr, int32_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } int ddi_peekd(dev_info_t *dip, int64_t *addr, int64_t *val_p) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_PEEK, sizeof (*val_p), addr, val_p)); } #endif /* _ILP32 */ int ddi_poke8(dev_info_t *dip, int8_t *addr, int8_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_poke16(dev_info_t *dip, int16_t *addr, int16_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_poke32(dev_info_t *dip, int32_t *addr, int32_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_poke64(dev_info_t *dip, int64_t *addr, int64_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } /* * We need to separate the old interfaces from the new ones and leave them * in here for a while. Previous versions of the OS defined the new interfaces * to the old interfaces. This way we can fix things up so that we can * eventually remove these interfaces. * e.g. A 3rd party module/driver using ddi_poke8 and built against S10 * or earlier will actually have a reference to ddi_pokec in the binary. */ #ifdef _ILP32 int ddi_pokec(dev_info_t *dip, int8_t *addr, int8_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_pokes(dev_info_t *dip, int16_t *addr, int16_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_pokel(dev_info_t *dip, int32_t *addr, int32_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } int ddi_poked(dev_info_t *dip, int64_t *addr, int64_t val) { return (i_ddi_peekpoke(dip, DDI_CTLOPS_POKE, sizeof (val), addr, &val)); } #endif /* _ILP32 */ /* * ddi_peekpokeio() is used primarily by the mem drivers for moving * data to and from uio structures via peek and poke. Note that we * use "internal" routines ddi_peek and ddi_poke to make this go * slightly faster, avoiding the call overhead .. */ int ddi_peekpokeio(dev_info_t *devi, struct uio *uio, enum uio_rw rw, caddr_t addr, size_t len, uint_t xfersize) { int64_t ibuffer; int8_t w8; size_t sz; int o; if (xfersize > sizeof (long)) xfersize = sizeof (long); while (len != 0) { if ((len | (uintptr_t)addr) & 1) { sz = sizeof (int8_t); if (rw == UIO_WRITE) { if ((o = uwritec(uio)) == -1) return (DDI_FAILURE); if (ddi_poke8(devi, (int8_t *)addr, (int8_t)o) != DDI_SUCCESS) return (DDI_FAILURE); } else { if (i_ddi_peekpoke(devi, DDI_CTLOPS_PEEK, sz, (int8_t *)addr, &w8) != DDI_SUCCESS) return (DDI_FAILURE); if (ureadc(w8, uio)) return (DDI_FAILURE); } } else { switch (xfersize) { case sizeof (int64_t): if (((len | (uintptr_t)addr) & (sizeof (int64_t) - 1)) == 0) { sz = xfersize; break; } /*FALLTHROUGH*/ case sizeof (int32_t): if (((len | (uintptr_t)addr) & (sizeof (int32_t) - 1)) == 0) { sz = xfersize; break; } /*FALLTHROUGH*/ default: /* * This still assumes that we might have an * I/O bus out there that permits 16-bit * transfers (and that it would be upset by * 32-bit transfers from such locations). */ sz = sizeof (int16_t); break; } if (rw == UIO_READ) { if (i_ddi_peekpoke(devi, DDI_CTLOPS_PEEK, sz, addr, &ibuffer) != DDI_SUCCESS) return (DDI_FAILURE); } if (uiomove(&ibuffer, sz, rw, uio)) return (DDI_FAILURE); if (rw == UIO_WRITE) { if (i_ddi_peekpoke(devi, DDI_CTLOPS_POKE, sz, addr, &ibuffer) != DDI_SUCCESS) return (DDI_FAILURE); } } addr += sz; len -= sz; } return (DDI_SUCCESS); } /* * These routines are used by drivers that do layered ioctls * On sparc, they're implemented in assembler to avoid spilling * register windows in the common (copyin) case .. */ #if !defined(__sparc) int ddi_copyin(const void *buf, void *kernbuf, size_t size, int flags) { if (flags & FKIOCTL) return (kcopy(buf, kernbuf, size) ? -1 : 0); return (copyin(buf, kernbuf, size)); } int ddi_copyout(const void *buf, void *kernbuf, size_t size, int flags) { if (flags & FKIOCTL) return (kcopy(buf, kernbuf, size) ? -1 : 0); return (copyout(buf, kernbuf, size)); } #endif /* !__sparc */ /* * Conversions in nexus pagesize units. We don't duplicate the * 'nil dip' semantics of peek/poke because btopr/btop/ptob are DDI/DKI * routines anyway. */ unsigned long ddi_btop(dev_info_t *dip, unsigned long bytes) { unsigned long pages; (void) ddi_ctlops(dip, dip, DDI_CTLOPS_BTOP, &bytes, &pages); return (pages); } unsigned long ddi_btopr(dev_info_t *dip, unsigned long bytes) { unsigned long pages; (void) ddi_ctlops(dip, dip, DDI_CTLOPS_BTOPR, &bytes, &pages); return (pages); } unsigned long ddi_ptob(dev_info_t *dip, unsigned long pages) { unsigned long bytes; (void) ddi_ctlops(dip, dip, DDI_CTLOPS_PTOB, &pages, &bytes); return (bytes); } unsigned int ddi_enter_critical(void) { return ((uint_t)spl7()); } void ddi_exit_critical(unsigned int spl) { splx((int)spl); } /* * Nexus ctlops punter */ #if !defined(__sparc) /* * Request bus_ctl parent to handle a bus_ctl request * * (The sparc version is in sparc_ddi.s) */ int ddi_ctlops(dev_info_t *d, dev_info_t *r, ddi_ctl_enum_t op, void *a, void *v) { int (*fp)(); if (!d || !r) return (DDI_FAILURE); if ((d = (dev_info_t *)DEVI(d)->devi_bus_ctl) == NULL) return (DDI_FAILURE); fp = DEVI(d)->devi_ops->devo_bus_ops->bus_ctl; return ((*fp)(d, r, op, a, v)); } #endif /* * DMA/DVMA setup */ #if defined(__sparc) static ddi_dma_lim_t standard_limits = { (uint_t)0, /* addr_t dlim_addr_lo */ (uint_t)-1, /* addr_t dlim_addr_hi */ (uint_t)-1, /* uint_t dlim_cntr_max */ (uint_t)1, /* uint_t dlim_burstsizes */ (uint_t)1, /* uint_t dlim_minxfer */ 0 /* uint_t dlim_dmaspeed */ }; #elif defined(__x86) static ddi_dma_lim_t standard_limits = { (uint_t)0, /* addr_t dlim_addr_lo */ (uint_t)0xffffff, /* addr_t dlim_addr_hi */ (uint_t)0, /* uint_t dlim_cntr_max */ (uint_t)0x00000001, /* uint_t dlim_burstsizes */ (uint_t)DMA_UNIT_8, /* uint_t dlim_minxfer */ (uint_t)0, /* uint_t dlim_dmaspeed */ (uint_t)0x86<<24+0, /* uint_t dlim_version */ (uint_t)0xffff, /* uint_t dlim_adreg_max */ (uint_t)0xffff, /* uint_t dlim_ctreg_max */ (uint_t)512, /* uint_t dlim_granular */ (int)1, /* int dlim_sgllen */ (uint_t)0xffffffff /* uint_t dlim_reqsizes */ }; #endif int ddi_dma_setup(dev_info_t *dip, struct ddi_dma_req *dmareqp, ddi_dma_handle_t *handlep) { int (*funcp)() = ddi_dma_map; struct bus_ops *bop; #if defined(__sparc) auto ddi_dma_lim_t dma_lim; if (dmareqp->dmar_limits == (ddi_dma_lim_t *)0) { dma_lim = standard_limits; } else { dma_lim = *dmareqp->dmar_limits; } dmareqp->dmar_limits = &dma_lim; #endif #if defined(__x86) if (dmareqp->dmar_limits == (ddi_dma_lim_t *)0) return (DDI_FAILURE); #endif /* * Handle the case that the requester is both a leaf * and a nexus driver simultaneously by calling the * requester's bus_dma_map function directly instead * of ddi_dma_map. */ bop = DEVI(dip)->devi_ops->devo_bus_ops; if (bop && bop->bus_dma_map) funcp = bop->bus_dma_map; return ((*funcp)(dip, dip, dmareqp, handlep)); } int ddi_dma_addr_setup(dev_info_t *dip, struct as *as, caddr_t addr, size_t len, uint_t flags, int (*waitfp)(), caddr_t arg, ddi_dma_lim_t *limits, ddi_dma_handle_t *handlep) { int (*funcp)() = ddi_dma_map; ddi_dma_lim_t dma_lim; struct ddi_dma_req dmareq; struct bus_ops *bop; if (len == 0) { return (DDI_DMA_NOMAPPING); } if (limits == (ddi_dma_lim_t *)0) { dma_lim = standard_limits; } else { dma_lim = *limits; } dmareq.dmar_limits = &dma_lim; dmareq.dmar_flags = flags; dmareq.dmar_fp = waitfp; dmareq.dmar_arg = arg; dmareq.dmar_object.dmao_size = len; dmareq.dmar_object.dmao_type = DMA_OTYP_VADDR; dmareq.dmar_object.dmao_obj.virt_obj.v_as = as; dmareq.dmar_object.dmao_obj.virt_obj.v_addr = addr; dmareq.dmar_object.dmao_obj.virt_obj.v_priv = NULL; /* * Handle the case that the requester is both a leaf * and a nexus driver simultaneously by calling the * requester's bus_dma_map function directly instead * of ddi_dma_map. */ bop = DEVI(dip)->devi_ops->devo_bus_ops; if (bop && bop->bus_dma_map) funcp = bop->bus_dma_map; return ((*funcp)(dip, dip, &dmareq, handlep)); } int ddi_dma_buf_setup(dev_info_t *dip, struct buf *bp, uint_t flags, int (*waitfp)(), caddr_t arg, ddi_dma_lim_t *limits, ddi_dma_handle_t *handlep) { int (*funcp)() = ddi_dma_map; ddi_dma_lim_t dma_lim; struct ddi_dma_req dmareq; struct bus_ops *bop; if (limits == (ddi_dma_lim_t *)0) { dma_lim = standard_limits; } else { dma_lim = *limits; } dmareq.dmar_limits = &dma_lim; dmareq.dmar_flags = flags; dmareq.dmar_fp = waitfp; dmareq.dmar_arg = arg; dmareq.dmar_object.dmao_size = (uint_t)bp->b_bcount; if (bp->b_flags & B_PAGEIO) { dmareq.dmar_object.dmao_type = DMA_OTYP_PAGES; dmareq.dmar_object.dmao_obj.pp_obj.pp_pp = bp->b_pages; dmareq.dmar_object.dmao_obj.pp_obj.pp_offset = (uint_t)(((uintptr_t)bp->b_un.b_addr) & MMU_PAGEOFFSET); } else { dmareq.dmar_object.dmao_type = DMA_OTYP_BUFVADDR; dmareq.dmar_object.dmao_obj.virt_obj.v_addr = bp->b_un.b_addr; if (bp->b_flags & B_SHADOW) { dmareq.dmar_object.dmao_obj.virt_obj.v_priv = bp->b_shadow; } else { dmareq.dmar_object.dmao_obj.virt_obj.v_priv = NULL; } /* * If the buffer has no proc pointer, or the proc * struct has the kernel address space, or the buffer has * been marked B_REMAPPED (meaning that it is now * mapped into the kernel's address space), then * the address space is kas (kernel address space). */ if ((bp->b_proc == NULL) || (bp->b_proc->p_as == &kas) || (bp->b_flags & B_REMAPPED)) { dmareq.dmar_object.dmao_obj.virt_obj.v_as = 0; } else { dmareq.dmar_object.dmao_obj.virt_obj.v_as = bp->b_proc->p_as; } } /* * Handle the case that the requester is both a leaf * and a nexus driver simultaneously by calling the * requester's bus_dma_map function directly instead * of ddi_dma_map. */ bop = DEVI(dip)->devi_ops->devo_bus_ops; if (bop && bop->bus_dma_map) funcp = bop->bus_dma_map; return ((*funcp)(dip, dip, &dmareq, handlep)); } #if !defined(__sparc) /* * Request bus_dma_ctl parent to fiddle with a dma request. * * (The sparc version is in sparc_subr.s) */ int ddi_dma_mctl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, enum ddi_dma_ctlops request, off_t *offp, size_t *lenp, caddr_t *objp, uint_t flags) { int (*fp)(); dip = (dev_info_t *)DEVI(dip)->devi_bus_dma_ctl; fp = DEVI(dip)->devi_ops->devo_bus_ops->bus_dma_ctl; return ((*fp) (dip, rdip, handle, request, offp, lenp, objp, flags)); } #endif /* * For all DMA control functions, call the DMA control * routine and return status. * * Just plain assume that the parent is to be called. * If a nexus driver or a thread outside the framework * of a nexus driver or a leaf driver calls these functions, * it is up to them to deal with the fact that the parent's * bus_dma_ctl function will be the first one called. */ #define HD ((ddi_dma_impl_t *)h)->dmai_rdip int ddi_dma_kvaddrp(ddi_dma_handle_t h, off_t off, size_t len, caddr_t *kp) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_KVADDR, &off, &len, kp, 0)); } int ddi_dma_htoc(ddi_dma_handle_t h, off_t o, ddi_dma_cookie_t *c) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_HTOC, &o, 0, (caddr_t *)c, 0)); } int ddi_dma_coff(ddi_dma_handle_t h, ddi_dma_cookie_t *c, off_t *o) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_COFF, (off_t *)c, 0, (caddr_t *)o, 0)); } int ddi_dma_movwin(ddi_dma_handle_t h, off_t *o, size_t *l, ddi_dma_cookie_t *c) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_MOVWIN, o, l, (caddr_t *)c, 0)); } int ddi_dma_curwin(ddi_dma_handle_t h, off_t *o, size_t *l) { if ((((ddi_dma_impl_t *)h)->dmai_rflags & DDI_DMA_PARTIAL) == 0) return (DDI_FAILURE); return (ddi_dma_mctl(HD, HD, h, DDI_DMA_REPWIN, o, l, 0, 0)); } int ddi_dma_nextwin(ddi_dma_handle_t h, ddi_dma_win_t win, ddi_dma_win_t *nwin) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_NEXTWIN, (off_t *)&win, 0, (caddr_t *)nwin, 0)); } int ddi_dma_nextseg(ddi_dma_win_t win, ddi_dma_seg_t seg, ddi_dma_seg_t *nseg) { ddi_dma_handle_t h = (ddi_dma_handle_t)win; return (ddi_dma_mctl(HD, HD, h, DDI_DMA_NEXTSEG, (off_t *)&win, (size_t *)&seg, (caddr_t *)nseg, 0)); } #if (defined(__i386) && !defined(__amd64)) || defined(__sparc) /* * This routine is Obsolete and should be removed from ALL architectures * in a future release of Solaris. * * It is deliberately NOT ported to amd64; please fix the code that * depends on this routine to use ddi_dma_nextcookie(9F). * * NOTE: even though we fixed the pointer through a 32-bit param issue (the fix * is a side effect to some other cleanup), we're still not going to support * this interface on x64. */ int ddi_dma_segtocookie(ddi_dma_seg_t seg, off_t *o, off_t *l, ddi_dma_cookie_t *cookiep) { ddi_dma_handle_t h = (ddi_dma_handle_t)seg; return (ddi_dma_mctl(HD, HD, h, DDI_DMA_SEGTOC, o, (size_t *)l, (caddr_t *)cookiep, 0)); } #endif /* (__i386 && !__amd64) || __sparc */ #if !defined(__sparc) /* * The SPARC versions of these routines are done in assembler to * save register windows, so they're in sparc_subr.s. */ int ddi_dma_map(dev_info_t *dip, dev_info_t *rdip, struct ddi_dma_req *dmareqp, ddi_dma_handle_t *handlep) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, struct ddi_dma_req *, ddi_dma_handle_t *); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_map; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_map; return ((*funcp)(hdip, rdip, dmareqp, handlep)); } int ddi_dma_allochdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_attr_t *attr, int (*waitfp)(caddr_t), caddr_t arg, ddi_dma_handle_t *handlep) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_attr_t *, int (*)(caddr_t), caddr_t, ddi_dma_handle_t *); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_allochdl; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_allochdl; return ((*funcp)(hdip, rdip, attr, waitfp, arg, handlep)); } int ddi_dma_freehdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handlep) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_allochdl; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_freehdl; return ((*funcp)(hdip, rdip, handlep)); } int ddi_dma_bindhdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, struct ddi_dma_req *dmareq, ddi_dma_cookie_t *cp, uint_t *ccountp) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t, struct ddi_dma_req *, ddi_dma_cookie_t *, uint_t *); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_bindhdl; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_bindhdl; return ((*funcp)(hdip, rdip, handle, dmareq, cp, ccountp)); } int ddi_dma_unbindhdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_unbindhdl; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_unbindhdl; return ((*funcp)(hdip, rdip, handle)); } int ddi_dma_flush(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, off_t off, size_t len, uint_t cache_flags) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t, off_t, size_t, uint_t); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_flush; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_flush; return ((*funcp)(hdip, rdip, handle, off, len, cache_flags)); } int ddi_dma_win(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, uint_t win, off_t *offp, size_t *lenp, ddi_dma_cookie_t *cookiep, uint_t *ccountp) { dev_info_t *hdip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t, uint_t, off_t *, size_t *, ddi_dma_cookie_t *, uint_t *); hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_win; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_win; return ((*funcp)(hdip, rdip, handle, win, offp, lenp, cookiep, ccountp)); } int ddi_dma_sync(ddi_dma_handle_t h, off_t o, size_t l, uint_t whom) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)h; dev_info_t *hdip, *dip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t, off_t, size_t, uint_t); /* * the DMA nexus driver will set DMP_NOSYNC if the * platform does not require any sync operation. For * example if the memory is uncached or consistent * and without any I/O write buffers involved. */ if ((hp->dmai_rflags & DMP_NOSYNC) == DMP_NOSYNC) return (DDI_SUCCESS); dip = hp->dmai_rdip; hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_flush; funcp = DEVI(hdip)->devi_ops->devo_bus_ops->bus_dma_flush; return ((*funcp)(hdip, dip, h, o, l, whom)); } int ddi_dma_unbind_handle(ddi_dma_handle_t h) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)h; dev_info_t *hdip, *dip; int (*funcp)(dev_info_t *, dev_info_t *, ddi_dma_handle_t); dip = hp->dmai_rdip; hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_unbindhdl; funcp = DEVI(dip)->devi_bus_dma_unbindfunc; return ((*funcp)(hdip, dip, h)); } #endif /* !__sparc */ int ddi_dma_free(ddi_dma_handle_t h) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_FREE, 0, 0, 0, 0)); } int ddi_iopb_alloc(dev_info_t *dip, ddi_dma_lim_t *limp, uint_t len, caddr_t *iopbp) { ddi_dma_lim_t defalt; size_t size = len; if (!limp) { defalt = standard_limits; limp = &defalt; } return (i_ddi_mem_alloc_lim(dip, limp, size, 0, 0, 0, iopbp, NULL, NULL)); } void ddi_iopb_free(caddr_t iopb) { i_ddi_mem_free(iopb, NULL); } int ddi_mem_alloc(dev_info_t *dip, ddi_dma_lim_t *limits, uint_t length, uint_t flags, caddr_t *kaddrp, uint_t *real_length) { ddi_dma_lim_t defalt; size_t size = length; if (!limits) { defalt = standard_limits; limits = &defalt; } return (i_ddi_mem_alloc_lim(dip, limits, size, flags & 0x1, 1, 0, kaddrp, real_length, NULL)); } void ddi_mem_free(caddr_t kaddr) { i_ddi_mem_free(kaddr, NULL); } /* * DMA attributes, alignment, burst sizes, and transfer minimums */ int ddi_dma_get_attr(ddi_dma_handle_t handle, ddi_dma_attr_t *attrp) { ddi_dma_impl_t *dimp = (ddi_dma_impl_t *)handle; if (attrp == NULL) return (DDI_FAILURE); *attrp = dimp->dmai_attr; return (DDI_SUCCESS); } int ddi_dma_burstsizes(ddi_dma_handle_t handle) { ddi_dma_impl_t *dimp = (ddi_dma_impl_t *)handle; if (!dimp) return (0); else return (dimp->dmai_burstsizes); } int ddi_dma_devalign(ddi_dma_handle_t handle, uint_t *alignment, uint_t *mineffect) { ddi_dma_impl_t *dimp = (ddi_dma_impl_t *)handle; if (!dimp || !alignment || !mineffect) return (DDI_FAILURE); if (!(dimp->dmai_rflags & DDI_DMA_SBUS_64BIT)) { *alignment = 1 << ddi_ffs(dimp->dmai_burstsizes); } else { if (dimp->dmai_burstsizes & 0xff0000) { *alignment = 1 << ddi_ffs(dimp->dmai_burstsizes >> 16); } else { *alignment = 1 << ddi_ffs(dimp->dmai_burstsizes); } } *mineffect = dimp->dmai_minxfer; return (DDI_SUCCESS); } int ddi_iomin(dev_info_t *a, int i, int stream) { int r; /* * Make sure that the initial value is sane */ if (i & (i - 1)) return (0); if (i == 0) i = (stream) ? 4 : 1; r = ddi_ctlops(a, a, DDI_CTLOPS_IOMIN, (void *)(uintptr_t)stream, (void *)&i); if (r != DDI_SUCCESS || (i & (i - 1))) return (0); return (i); } /* * Given two DMA attribute structures, apply the attributes * of one to the other, following the rules of attributes * and the wishes of the caller. * * The rules of DMA attribute structures are that you cannot * make things *less* restrictive as you apply one set * of attributes to another. * */ void ddi_dma_attr_merge(ddi_dma_attr_t *attr, ddi_dma_attr_t *mod) { attr->dma_attr_addr_lo = MAX(attr->dma_attr_addr_lo, mod->dma_attr_addr_lo); attr->dma_attr_addr_hi = MIN(attr->dma_attr_addr_hi, mod->dma_attr_addr_hi); attr->dma_attr_count_max = MIN(attr->dma_attr_count_max, mod->dma_attr_count_max); attr->dma_attr_align = MAX(attr->dma_attr_align, mod->dma_attr_align); attr->dma_attr_burstsizes = (uint_t)(attr->dma_attr_burstsizes & mod->dma_attr_burstsizes); attr->dma_attr_minxfer = maxbit(attr->dma_attr_minxfer, mod->dma_attr_minxfer); attr->dma_attr_maxxfer = MIN(attr->dma_attr_maxxfer, mod->dma_attr_maxxfer); attr->dma_attr_seg = MIN(attr->dma_attr_seg, mod->dma_attr_seg); attr->dma_attr_sgllen = MIN((uint_t)attr->dma_attr_sgllen, (uint_t)mod->dma_attr_sgllen); attr->dma_attr_granular = MAX(attr->dma_attr_granular, mod->dma_attr_granular); } /* * mmap/segmap interface: */ /* * ddi_segmap: setup the default segment driver. Calls the drivers * XXmmap routine to validate the range to be mapped. * Return ENXIO of the range is not valid. Create * a seg_dev segment that contains all of the * necessary information and will reference the * default segment driver routines. It returns zero * on success or non-zero on failure. */ int ddi_segmap(dev_t dev, off_t offset, struct as *asp, caddr_t *addrp, off_t len, uint_t prot, uint_t maxprot, uint_t flags, cred_t *credp) { extern int spec_segmap(dev_t, off_t, struct as *, caddr_t *, off_t, uint_t, uint_t, uint_t, struct cred *); return (spec_segmap(dev, offset, asp, addrp, len, prot, maxprot, flags, credp)); } /* * ddi_map_fault: Resolve mappings at fault time. Used by segment * drivers. Allows each successive parent to resolve * address translations and add its mappings to the * mapping list supplied in the page structure. It * returns zero on success or non-zero on failure. */ int ddi_map_fault(dev_info_t *dip, struct hat *hat, struct seg *seg, caddr_t addr, struct devpage *dp, pfn_t pfn, uint_t prot, uint_t lock) { return (i_ddi_map_fault(dip, dip, hat, seg, addr, dp, pfn, prot, lock)); } /* * ddi_device_mapping_check: Called from ddi_segmap_setup. * Invokes platform specific DDI to determine whether attributes specified * in attr(9s) are valid for the region of memory that will be made * available for direct access to user process via the mmap(2) system call. */ int ddi_device_mapping_check(dev_t dev, ddi_device_acc_attr_t *accattrp, uint_t rnumber, uint_t *hat_flags) { ddi_acc_handle_t handle; ddi_map_req_t mr; ddi_acc_hdl_t *hp; int result; dev_info_t *dip; /* * we use e_ddi_hold_devi_by_dev to search for the devi. We * release it immediately since it should already be held by * a devfs vnode. */ if ((dip = e_ddi_hold_devi_by_dev(dev, E_DDI_HOLD_DEVI_NOATTACH)) == NULL) return (-1); ddi_release_devi(dip); /* for e_ddi_hold_devi_by_dev() */ /* * Allocate and initialize the common elements of data * access handle. */ handle = impl_acc_hdl_alloc(KM_SLEEP, NULL); if (handle == NULL) return (-1); hp = impl_acc_hdl_get(handle); hp->ah_vers = VERS_ACCHDL; hp->ah_dip = dip; hp->ah_rnumber = rnumber; hp->ah_offset = 0; hp->ah_len = 0; hp->ah_acc = *accattrp; /* * Set up the mapping request and call to parent. */ mr.map_op = DDI_MO_MAP_HANDLE; mr.map_type = DDI_MT_RNUMBER; mr.map_obj.rnumber = rnumber; mr.map_prot = PROT_READ | PROT_WRITE; mr.map_flags = DDI_MF_KERNEL_MAPPING; mr.map_handlep = hp; mr.map_vers = DDI_MAP_VERSION; result = ddi_map(dip, &mr, 0, 0, NULL); /* * Region must be mappable, pick up flags from the framework. */ *hat_flags = hp->ah_hat_flags; impl_acc_hdl_free(handle); /* * check for end result. */ if (result != DDI_SUCCESS) return (-1); return (0); } /* * Property functions: See also, ddipropdefs.h. * * These functions are the framework for the property functions, * i.e. they support software defined properties. All implementation * specific property handling (i.e.: self-identifying devices and * PROM defined properties are handled in the implementation specific * functions (defined in ddi_implfuncs.h). */ /* * nopropop: Shouldn't be called, right? */ int nopropop(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp) { _NOTE(ARGUNUSED(dev, dip, prop_op, mod_flags, name, valuep, lengthp)) return (DDI_PROP_NOT_FOUND); } #ifdef DDI_PROP_DEBUG int ddi_prop_debug_flag = 0; int ddi_prop_debug(int enable) { int prev = ddi_prop_debug_flag; if ((enable != 0) || (prev != 0)) printf("ddi_prop_debug: debugging %s\n", enable ? "enabled" : "disabled"); ddi_prop_debug_flag = enable; return (prev); } #endif /* DDI_PROP_DEBUG */ /* * Search a property list for a match, if found return pointer * to matching prop struct, else return NULL. */ ddi_prop_t * i_ddi_prop_search(dev_t dev, char *name, uint_t flags, ddi_prop_t **list_head) { ddi_prop_t *propp; /* * find the property in child's devinfo: * Search order defined by this search function is first matching * property with input dev == DDI_DEV_T_ANY matching any dev or * dev == propp->prop_dev, name == propp->name, and the correct * data type as specified in the flags. If a DDI_DEV_T_NONE dev * value made it this far then it implies a DDI_DEV_T_ANY search. */ if (dev == DDI_DEV_T_NONE) dev = DDI_DEV_T_ANY; for (propp = *list_head; propp != NULL; propp = propp->prop_next) { if (!DDI_STRSAME(propp->prop_name, name)) continue; if ((dev != DDI_DEV_T_ANY) && (propp->prop_dev != dev)) continue; if (((propp->prop_flags & flags) & DDI_PROP_TYPE_MASK) == 0) continue; return (propp); } return ((ddi_prop_t *)0); } /* * Search for property within devnames structures */ ddi_prop_t * i_ddi_search_global_prop(dev_t dev, char *name, uint_t flags) { major_t major; struct devnames *dnp; ddi_prop_t *propp; /* * Valid dev_t value is needed to index into the * correct devnames entry, therefore a dev_t * value of DDI_DEV_T_ANY is not appropriate. */ ASSERT(dev != DDI_DEV_T_ANY); if (dev == DDI_DEV_T_ANY) { return ((ddi_prop_t *)0); } major = getmajor(dev); dnp = &(devnamesp[major]); if (dnp->dn_global_prop_ptr == NULL) return ((ddi_prop_t *)0); LOCK_DEV_OPS(&dnp->dn_lock); for (propp = dnp->dn_global_prop_ptr->prop_list; propp != NULL; propp = (ddi_prop_t *)propp->prop_next) { if (!DDI_STRSAME(propp->prop_name, name)) continue; if ((!(flags & LDI_DEV_T_ANY)) && (propp->prop_dev != dev)) continue; if (((propp->prop_flags & flags) & DDI_PROP_TYPE_MASK) == 0) continue; /* Property found, return it */ UNLOCK_DEV_OPS(&dnp->dn_lock); return (propp); } UNLOCK_DEV_OPS(&dnp->dn_lock); return ((ddi_prop_t *)0); } static char prop_no_mem_msg[] = "can't allocate memory for ddi property <%s>"; /* * ddi_prop_search_global: * Search the global property list within devnames * for the named property. Return the encoded value. */ static int i_ddi_prop_search_global(dev_t dev, uint_t flags, char *name, void *valuep, uint_t *lengthp) { ddi_prop_t *propp; caddr_t buffer; propp = i_ddi_search_global_prop(dev, name, flags); /* Property NOT found, bail */ if (propp == (ddi_prop_t *)0) return (DDI_PROP_NOT_FOUND); if (propp->prop_flags & DDI_PROP_UNDEF_IT) return (DDI_PROP_UNDEFINED); if ((buffer = kmem_alloc(propp->prop_len, (flags & DDI_PROP_CANSLEEP) ? KM_SLEEP : KM_NOSLEEP)) == NULL) { cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } /* * Return the encoded data */ *(caddr_t *)valuep = buffer; *lengthp = propp->prop_len; bcopy(propp->prop_val, buffer, propp->prop_len); return (DDI_PROP_SUCCESS); } /* * ddi_prop_search_common: Lookup and return the encoded value */ int ddi_prop_search_common(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, uint_t flags, char *name, void *valuep, uint_t *lengthp) { ddi_prop_t *propp; int i; caddr_t buffer; caddr_t prealloc = NULL; int plength = 0; dev_info_t *pdip; int (*bop)(); /*CONSTANTCONDITION*/ while (1) { mutex_enter(&(DEVI(dip)->devi_lock)); /* * find the property in child's devinfo: * Search order is: * 1. driver defined properties * 2. system defined properties * 3. driver global properties * 4. boot defined properties */ propp = i_ddi_prop_search(dev, name, flags, &(DEVI(dip)->devi_drv_prop_ptr)); if (propp == NULL) { propp = i_ddi_prop_search(dev, name, flags, &(DEVI(dip)->devi_sys_prop_ptr)); } if ((propp == NULL) && DEVI(dip)->devi_global_prop_list) { propp = i_ddi_prop_search(dev, name, flags, &DEVI(dip)->devi_global_prop_list->prop_list); } if (propp == NULL) { propp = i_ddi_prop_search(dev, name, flags, &(DEVI(dip)->devi_hw_prop_ptr)); } /* * Software property found? */ if (propp != (ddi_prop_t *)0) { /* * If explicit undefine, return now. */ if (propp->prop_flags & DDI_PROP_UNDEF_IT) { mutex_exit(&(DEVI(dip)->devi_lock)); if (prealloc) kmem_free(prealloc, plength); return (DDI_PROP_UNDEFINED); } /* * If we only want to know if it exists, return now */ if (prop_op == PROP_EXISTS) { mutex_exit(&(DEVI(dip)->devi_lock)); ASSERT(prealloc == NULL); return (DDI_PROP_SUCCESS); } /* * If length only request or prop length == 0, * service request and return now. */ if ((prop_op == PROP_LEN) ||(propp->prop_len == 0)) { *lengthp = propp->prop_len; /* * if prop_op is PROP_LEN_AND_VAL_ALLOC * that means prop_len is 0, so set valuep * also to NULL */ if (prop_op == PROP_LEN_AND_VAL_ALLOC) *(caddr_t *)valuep = NULL; mutex_exit(&(DEVI(dip)->devi_lock)); if (prealloc) kmem_free(prealloc, plength); return (DDI_PROP_SUCCESS); } /* * If LEN_AND_VAL_ALLOC and the request can sleep, * drop the mutex, allocate the buffer, and go * through the loop again. If we already allocated * the buffer, and the size of the property changed, * keep trying... */ if ((prop_op == PROP_LEN_AND_VAL_ALLOC) && (flags & DDI_PROP_CANSLEEP)) { if (prealloc && (propp->prop_len != plength)) { kmem_free(prealloc, plength); prealloc = NULL; } if (prealloc == NULL) { plength = propp->prop_len; mutex_exit(&(DEVI(dip)->devi_lock)); prealloc = kmem_alloc(plength, KM_SLEEP); continue; } } /* * Allocate buffer, if required. Either way, * set `buffer' variable. */ i = *lengthp; /* Get callers length */ *lengthp = propp->prop_len; /* Set callers length */ switch (prop_op) { case PROP_LEN_AND_VAL_ALLOC: if (prealloc == NULL) { buffer = kmem_alloc(propp->prop_len, KM_NOSLEEP); } else { buffer = prealloc; } if (buffer == NULL) { mutex_exit(&(DEVI(dip)->devi_lock)); cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } /* Set callers buf ptr */ *(caddr_t *)valuep = buffer; break; case PROP_LEN_AND_VAL_BUF: if (propp->prop_len > (i)) { mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_PROP_BUF_TOO_SMALL); } buffer = valuep; /* Get callers buf ptr */ break; default: break; } /* * Do the copy. */ bcopy(propp->prop_val, buffer, propp->prop_len); mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_PROP_SUCCESS); } mutex_exit(&(DEVI(dip)->devi_lock)); if (prealloc) kmem_free(prealloc, plength); prealloc = NULL; /* * Prop not found, call parent bus_ops to deal with possible * h/w layer (possible PROM defined props, etc.) and to * possibly ascend the hierarchy, if allowed by flags. */ pdip = (dev_info_t *)DEVI(dip)->devi_parent; /* * One last call for the root driver PROM props? */ if (dip == ddi_root_node()) { return (ddi_bus_prop_op(dev, dip, dip, prop_op, flags, name, valuep, (int *)lengthp)); } /* * We may have been called to check for properties * within a single devinfo node that has no parent - * see make_prop() */ if (pdip == NULL) { ASSERT((flags & (DDI_PROP_DONTPASS | DDI_PROP_NOTPROM)) == (DDI_PROP_DONTPASS | DDI_PROP_NOTPROM)); return (DDI_PROP_NOT_FOUND); } /* * Instead of recursing, we do iterative calls up the tree. * As a bit of optimization, skip the bus_op level if the * node is a s/w node and if the parent's bus_prop_op function * is `ddi_bus_prop_op', because we know that in this case, * this function does nothing. * * 4225415: If the parent isn't attached, or the child * hasn't been named by the parent yet, use the default * ddi_bus_prop_op as a proxy for the parent. This * allows property lookups in any child/parent state to * include 'prom' and inherited properties, even when * there are no drivers attached to the child or parent. */ bop = ddi_bus_prop_op; if (i_ddi_devi_attached(pdip) && (i_ddi_node_state(dip) >= DS_INITIALIZED)) bop = DEVI(pdip)->devi_ops->devo_bus_ops->bus_prop_op; i = DDI_PROP_NOT_FOUND; if ((bop != ddi_bus_prop_op) || ndi_dev_is_prom_node(dip)) { i = (*bop)(dev, pdip, dip, prop_op, flags | DDI_PROP_DONTPASS, name, valuep, lengthp); } if ((flags & DDI_PROP_DONTPASS) || (i != DDI_PROP_NOT_FOUND)) return (i); dip = pdip; } /*NOTREACHED*/ } /* * ddi_prop_op: The basic property operator for drivers. * * In ddi_prop_op, the type of valuep is interpreted based on prop_op: * * prop_op valuep * ------ ------ * * PROP_LEN * * PROP_LEN_AND_VAL_BUF Pointer to callers buffer * * PROP_LEN_AND_VAL_ALLOC Address of callers pointer (will be set to * address of allocated buffer, if successful) */ int ddi_prop_op(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp) { int i; ASSERT((mod_flags & DDI_PROP_TYPE_MASK) == 0); /* * If this was originally an LDI prop lookup then we bail here. * The reason is that the LDI property lookup interfaces first call * a drivers prop_op() entry point to allow it to override * properties. But if we've made it here, then the driver hasn't * overriden any properties. We don't want to continue with the * property search here because we don't have any type inforamtion. * When we return failure, the LDI interfaces will then proceed to * call the typed property interfaces to look up the property. */ if (mod_flags & DDI_PROP_DYNAMIC) return (DDI_PROP_NOT_FOUND); /* * check for pre-typed property consumer asking for typed property: * see e_ddi_getprop_int64. */ if (mod_flags & DDI_PROP_CONSUMER_TYPED) mod_flags |= DDI_PROP_TYPE_INT64; mod_flags |= DDI_PROP_TYPE_ANY; i = ddi_prop_search_common(dev, dip, prop_op, mod_flags, name, valuep, (uint_t *)lengthp); if (i == DDI_PROP_FOUND_1275) return (DDI_PROP_SUCCESS); return (i); } /* * ddi_prop_op_nblocks_blksize: The basic property operator for drivers that * maintain size in number of blksize blocks. Provides a dynamic property * implementation for size oriented properties based on nblocks64 and blksize * values passed in by the driver. Fallback to ddi_prop_op if the nblocks64 * is too large. This interface should not be used with a nblocks64 that * represents the driver's idea of how to represent unknown, if nblocks is * unknown use ddi_prop_op. */ int ddi_prop_op_nblocks_blksize(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp, uint64_t nblocks64, uint_t blksize) { uint64_t size64; int blkshift; /* convert block size to shift value */ ASSERT(BIT_ONLYONESET(blksize)); blkshift = highbit(blksize) - 1; /* * There is no point in supporting nblocks64 values that don't have * an accurate uint64_t byte count representation. */ if (nblocks64 >= (UINT64_MAX >> blkshift)) return (ddi_prop_op(dev, dip, prop_op, mod_flags, name, valuep, lengthp)); size64 = nblocks64 << blkshift; return (ddi_prop_op_size_blksize(dev, dip, prop_op, mod_flags, name, valuep, lengthp, size64, blksize)); } /* * ddi_prop_op_nblocks: ddi_prop_op_nblocks_blksize with DEV_BSIZE blksize. */ int ddi_prop_op_nblocks(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp, uint64_t nblocks64) { return (ddi_prop_op_nblocks_blksize(dev, dip, prop_op, mod_flags, name, valuep, lengthp, nblocks64, DEV_BSIZE)); } /* * ddi_prop_op_size_blksize: The basic property operator for block drivers that * maintain size in bytes. Provides a of dynamic property implementation for * size oriented properties based on size64 value and blksize passed in by the * driver. Fallback to ddi_prop_op if the size64 is too large. This interface * should not be used with a size64 that represents the driver's idea of how * to represent unknown, if size is unknown use ddi_prop_op. * * NOTE: the legacy "nblocks"/"size" properties are treated as 32-bit unsigned * integers. While the most likely interface to request them ([bc]devi_size) * is declared int (signed) there is no enforcement of this, which means we * can't enforce limitations here without risking regression. */ int ddi_prop_op_size_blksize(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp, uint64_t size64, uint_t blksize) { uint64_t nblocks64; int callers_length; caddr_t buffer; int blkshift; /* convert block size to shift value */ ASSERT(BIT_ONLYONESET(blksize)); blkshift = highbit(blksize) - 1; /* compute DEV_BSIZE nblocks value */ nblocks64 = size64 >> blkshift; /* get callers length, establish length of our dynamic properties */ callers_length = *lengthp; if (strcmp(name, "Nblocks") == 0) *lengthp = sizeof (uint64_t); else if (strcmp(name, "Size") == 0) *lengthp = sizeof (uint64_t); else if ((strcmp(name, "nblocks") == 0) && (nblocks64 < UINT_MAX)) *lengthp = sizeof (uint32_t); else if ((strcmp(name, "size") == 0) && (size64 < UINT_MAX)) *lengthp = sizeof (uint32_t); else if ((strcmp(name, "blksize") == 0) && (blksize < UINT_MAX)) *lengthp = sizeof (uint32_t); else { /* fallback to ddi_prop_op */ return (ddi_prop_op(dev, dip, prop_op, mod_flags, name, valuep, lengthp)); } /* service request for the length of the property */ if (prop_op == PROP_LEN) return (DDI_PROP_SUCCESS); /* the length of the property and the request must match */ if (callers_length != *lengthp) return (DDI_PROP_INVAL_ARG); switch (prop_op) { case PROP_LEN_AND_VAL_ALLOC: if ((buffer = kmem_alloc(*lengthp, (mod_flags & DDI_PROP_CANSLEEP) ? KM_SLEEP : KM_NOSLEEP)) == NULL) return (DDI_PROP_NO_MEMORY); *(caddr_t *)valuep = buffer; /* set callers buf ptr */ break; case PROP_LEN_AND_VAL_BUF: buffer = valuep; /* get callers buf ptr */ break; default: return (DDI_PROP_INVAL_ARG); } /* transfer the value into the buffer */ if (strcmp(name, "Nblocks") == 0) *((uint64_t *)buffer) = nblocks64; else if (strcmp(name, "Size") == 0) *((uint64_t *)buffer) = size64; else if (strcmp(name, "nblocks") == 0) *((uint32_t *)buffer) = (uint32_t)nblocks64; else if (strcmp(name, "size") == 0) *((uint32_t *)buffer) = (uint32_t)size64; else if (strcmp(name, "blksize") == 0) *((uint32_t *)buffer) = (uint32_t)blksize; return (DDI_PROP_SUCCESS); } /* * ddi_prop_op_size: ddi_prop_op_size_blksize with DEV_BSIZE block size. */ int ddi_prop_op_size(dev_t dev, dev_info_t *dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp, uint64_t size64) { return (ddi_prop_op_size_blksize(dev, dip, prop_op, mod_flags, name, valuep, lengthp, size64, DEV_BSIZE)); } /* * Variable length props... */ /* * ddi_getlongprop: Get variable length property len+val into a buffer * allocated by property provider via kmem_alloc. Requester * is responsible for freeing returned property via kmem_free. * * Arguments: * * dev_t: Input: dev_t of property. * dip: Input: dev_info_t pointer of child. * flags: Input: Possible flag modifiers are: * DDI_PROP_DONTPASS: Don't pass to parent if prop not found. * DDI_PROP_CANSLEEP: Memory allocation may sleep. * name: Input: name of property. * valuep: Output: Addr of callers buffer pointer. * lengthp:Output: *lengthp will contain prop length on exit. * * Possible Returns: * * DDI_PROP_SUCCESS: Prop found and returned. * DDI_PROP_NOT_FOUND: Prop not found * DDI_PROP_UNDEFINED: Prop explicitly undefined. * DDI_PROP_NO_MEMORY: Prop found, but unable to alloc mem. */ int ddi_getlongprop(dev_t dev, dev_info_t *dip, int flags, char *name, caddr_t valuep, int *lengthp) { return (ddi_prop_op(dev, dip, PROP_LEN_AND_VAL_ALLOC, flags, name, valuep, lengthp)); } /* * * ddi_getlongprop_buf: Get long prop into pre-allocated callers * buffer. (no memory allocation by provider). * * dev_t: Input: dev_t of property. * dip: Input: dev_info_t pointer of child. * flags: Input: DDI_PROP_DONTPASS or NULL * name: Input: name of property * valuep: Input: ptr to callers buffer. * lengthp:I/O: ptr to length of callers buffer on entry, * actual length of property on exit. * * Possible returns: * * DDI_PROP_SUCCESS Prop found and returned * DDI_PROP_NOT_FOUND Prop not found * DDI_PROP_UNDEFINED Prop explicitly undefined. * DDI_PROP_BUF_TOO_SMALL Prop found, callers buf too small, * no value returned, but actual prop * length returned in *lengthp * */ int ddi_getlongprop_buf(dev_t dev, dev_info_t *dip, int flags, char *name, caddr_t valuep, int *lengthp) { return (ddi_prop_op(dev, dip, PROP_LEN_AND_VAL_BUF, flags, name, valuep, lengthp)); } /* * Integer/boolean sized props. * * Call is value only... returns found boolean or int sized prop value or * defvalue if prop not found or is wrong length or is explicitly undefined. * Only flag is DDI_PROP_DONTPASS... * * By convention, this interface returns boolean (0) sized properties * as value (int)1. * * This never returns an error, if property not found or specifically * undefined, the input `defvalue' is returned. */ int ddi_getprop(dev_t dev, dev_info_t *dip, int flags, char *name, int defvalue) { int propvalue = defvalue; int proplength = sizeof (int); int error; error = ddi_prop_op(dev, dip, PROP_LEN_AND_VAL_BUF, flags, name, (caddr_t)&propvalue, &proplength); if ((error == DDI_PROP_SUCCESS) && (proplength == 0)) propvalue = 1; return (propvalue); } /* * Get prop length interface: flags are 0 or DDI_PROP_DONTPASS * if returns DDI_PROP_SUCCESS, length returned in *lengthp. */ int ddi_getproplen(dev_t dev, dev_info_t *dip, int flags, char *name, int *lengthp) { return (ddi_prop_op(dev, dip, PROP_LEN, flags, name, NULL, lengthp)); } /* * Allocate a struct prop_driver_data, along with 'size' bytes * for decoded property data. This structure is freed by * calling ddi_prop_free(9F). */ static void * ddi_prop_decode_alloc(size_t size, void (*prop_free)(struct prop_driver_data *)) { struct prop_driver_data *pdd; /* * Allocate a structure with enough memory to store the decoded data. */ pdd = kmem_zalloc(sizeof (struct prop_driver_data) + size, KM_SLEEP); pdd->pdd_size = (sizeof (struct prop_driver_data) + size); pdd->pdd_prop_free = prop_free; /* * Return a pointer to the location to put the decoded data. */ return ((void *)((caddr_t)pdd + sizeof (struct prop_driver_data))); } /* * Allocated the memory needed to store the encoded data in the property * handle. */ static int ddi_prop_encode_alloc(prop_handle_t *ph, size_t size) { /* * If size is zero, then set data to NULL and size to 0. This * is a boolean property. */ if (size == 0) { ph->ph_size = 0; ph->ph_data = NULL; ph->ph_cur_pos = NULL; ph->ph_save_pos = NULL; } else { if (ph->ph_flags == DDI_PROP_DONTSLEEP) { ph->ph_data = kmem_zalloc(size, KM_NOSLEEP); if (ph->ph_data == NULL) return (DDI_PROP_NO_MEMORY); } else ph->ph_data = kmem_zalloc(size, KM_SLEEP); ph->ph_size = size; ph->ph_cur_pos = ph->ph_data; ph->ph_save_pos = ph->ph_data; } return (DDI_PROP_SUCCESS); } /* * Free the space allocated by the lookup routines. Each lookup routine * returns a pointer to the decoded data to the driver. The driver then * passes this pointer back to us. This data actually lives in a struct * prop_driver_data. We use negative indexing to find the beginning of * the structure and then free the entire structure using the size and * the free routine stored in the structure. */ void ddi_prop_free(void *datap) { struct prop_driver_data *pdd; /* * Get the structure */ pdd = (struct prop_driver_data *) ((caddr_t)datap - sizeof (struct prop_driver_data)); /* * Call the free routine to free it */ (*pdd->pdd_prop_free)(pdd); } /* * Free the data associated with an array of ints, * allocated with ddi_prop_decode_alloc(). */ static void ddi_prop_free_ints(struct prop_driver_data *pdd) { kmem_free(pdd, pdd->pdd_size); } /* * Free a single string property or a single string contained within * the argv style return value of an array of strings. */ static void ddi_prop_free_string(struct prop_driver_data *pdd) { kmem_free(pdd, pdd->pdd_size); } /* * Free an array of strings. */ static void ddi_prop_free_strings(struct prop_driver_data *pdd) { kmem_free(pdd, pdd->pdd_size); } /* * Free the data associated with an array of bytes. */ static void ddi_prop_free_bytes(struct prop_driver_data *pdd) { kmem_free(pdd, pdd->pdd_size); } /* * Reset the current location pointer in the property handle to the * beginning of the data. */ void ddi_prop_reset_pos(prop_handle_t *ph) { ph->ph_cur_pos = ph->ph_data; ph->ph_save_pos = ph->ph_data; } /* * Restore the current location pointer in the property handle to the * saved position. */ void ddi_prop_save_pos(prop_handle_t *ph) { ph->ph_save_pos = ph->ph_cur_pos; } /* * Save the location that the current location pointer is pointing to.. */ void ddi_prop_restore_pos(prop_handle_t *ph) { ph->ph_cur_pos = ph->ph_save_pos; } /* * Property encode/decode functions */ /* * Decode a single integer property */ static int ddi_prop_fm_decode_int(prop_handle_t *ph, void *data, uint_t *nelements) { int i; int tmp; /* * If there is nothing to decode return an error */ if (ph->ph_size == 0) return (DDI_PROP_END_OF_DATA); /* * Decode the property as a single integer and return it * in data if we were able to decode it. */ i = DDI_PROP_INT(ph, DDI_PROP_CMD_DECODE, &tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } *(int *)data = tmp; *nelements = 1; return (DDI_PROP_SUCCESS); } /* * Decode a single 64 bit integer property */ static int ddi_prop_fm_decode_int64(prop_handle_t *ph, void *data, uint_t *nelements) { int i; int64_t tmp; /* * If there is nothing to decode return an error */ if (ph->ph_size == 0) return (DDI_PROP_END_OF_DATA); /* * Decode the property as a single integer and return it * in data if we were able to decode it. */ i = DDI_PROP_INT64(ph, DDI_PROP_CMD_DECODE, &tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } *(int64_t *)data = tmp; *nelements = 1; return (DDI_PROP_SUCCESS); } /* * Decode an array of integers property */ static int ddi_prop_fm_decode_ints(prop_handle_t *ph, void *data, uint_t *nelements) { int i; int cnt = 0; int *tmp; int *intp; int n; /* * Figure out how many array elements there are by going through the * data without decoding it first and counting. */ for (;;) { i = DDI_PROP_INT(ph, DDI_PROP_CMD_SKIP, NULL); if (i < 0) break; cnt++; } /* * If there are no elements return an error */ if (cnt == 0) return (DDI_PROP_END_OF_DATA); /* * If we cannot skip through the data, we cannot decode it */ if (i == DDI_PROP_RESULT_ERROR) return (DDI_PROP_CANNOT_DECODE); /* * Reset the data pointer to the beginning of the encoded data */ ddi_prop_reset_pos(ph); /* * Allocated memory to store the decoded value in. */ intp = ddi_prop_decode_alloc((cnt * sizeof (int)), ddi_prop_free_ints); /* * Decode each element and place it in the space we just allocated */ tmp = intp; for (n = 0; n < cnt; n++, tmp++) { i = DDI_PROP_INT(ph, DDI_PROP_CMD_DECODE, tmp); if (i < DDI_PROP_RESULT_OK) { /* * Free the space we just allocated * and return an error. */ ddi_prop_free(intp); switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } } *nelements = cnt; *(int **)data = intp; return (DDI_PROP_SUCCESS); } /* * Decode a 64 bit integer array property */ static int ddi_prop_fm_decode_int64_array(prop_handle_t *ph, void *data, uint_t *nelements) { int i; int n; int cnt = 0; int64_t *tmp; int64_t *intp; /* * Count the number of array elements by going * through the data without decoding it. */ for (;;) { i = DDI_PROP_INT64(ph, DDI_PROP_CMD_SKIP, NULL); if (i < 0) break; cnt++; } /* * If there are no elements return an error */ if (cnt == 0) return (DDI_PROP_END_OF_DATA); /* * If we cannot skip through the data, we cannot decode it */ if (i == DDI_PROP_RESULT_ERROR) return (DDI_PROP_CANNOT_DECODE); /* * Reset the data pointer to the beginning of the encoded data */ ddi_prop_reset_pos(ph); /* * Allocate memory to store the decoded value. */ intp = ddi_prop_decode_alloc((cnt * sizeof (int64_t)), ddi_prop_free_ints); /* * Decode each element and place it in the space allocated */ tmp = intp; for (n = 0; n < cnt; n++, tmp++) { i = DDI_PROP_INT64(ph, DDI_PROP_CMD_DECODE, tmp); if (i < DDI_PROP_RESULT_OK) { /* * Free the space we just allocated * and return an error. */ ddi_prop_free(intp); switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } } *nelements = cnt; *(int64_t **)data = intp; return (DDI_PROP_SUCCESS); } /* * Encode an array of integers property (Can be one element) */ int ddi_prop_fm_encode_ints(prop_handle_t *ph, void *data, uint_t nelements) { int i; int *tmp; int cnt; int size; /* * If there is no data, we cannot do anything */ if (nelements == 0) return (DDI_PROP_CANNOT_ENCODE); /* * Get the size of an encoded int. */ size = DDI_PROP_INT(ph, DDI_PROP_CMD_GET_ESIZE, NULL); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } /* * Allocate space in the handle to store the encoded int. */ if (ddi_prop_encode_alloc(ph, size * nelements) != DDI_PROP_SUCCESS) return (DDI_PROP_NO_MEMORY); /* * Encode the array of ints. */ tmp = (int *)data; for (cnt = 0; cnt < nelements; cnt++, tmp++) { i = DDI_PROP_INT(ph, DDI_PROP_CMD_ENCODE, tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } } return (DDI_PROP_SUCCESS); } /* * Encode a 64 bit integer array property */ int ddi_prop_fm_encode_int64(prop_handle_t *ph, void *data, uint_t nelements) { int i; int cnt; int size; int64_t *tmp; /* * If there is no data, we cannot do anything */ if (nelements == 0) return (DDI_PROP_CANNOT_ENCODE); /* * Get the size of an encoded 64 bit int. */ size = DDI_PROP_INT64(ph, DDI_PROP_CMD_GET_ESIZE, NULL); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } /* * Allocate space in the handle to store the encoded int. */ if (ddi_prop_encode_alloc(ph, size * nelements) != DDI_PROP_SUCCESS) return (DDI_PROP_NO_MEMORY); /* * Encode the array of ints. */ tmp = (int64_t *)data; for (cnt = 0; cnt < nelements; cnt++, tmp++) { i = DDI_PROP_INT64(ph, DDI_PROP_CMD_ENCODE, tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } } return (DDI_PROP_SUCCESS); } /* * Decode a single string property */ static int ddi_prop_fm_decode_string(prop_handle_t *ph, void *data, uint_t *nelements) { char *tmp; char *str; int i; int size; /* * If there is nothing to decode return an error */ if (ph->ph_size == 0) return (DDI_PROP_END_OF_DATA); /* * Get the decoded size of the encoded string. */ size = DDI_PROP_STR(ph, DDI_PROP_CMD_GET_DSIZE, NULL); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } /* * Allocated memory to store the decoded value in. */ str = ddi_prop_decode_alloc((size_t)size, ddi_prop_free_string); ddi_prop_reset_pos(ph); /* * Decode the str and place it in the space we just allocated */ tmp = str; i = DDI_PROP_STR(ph, DDI_PROP_CMD_DECODE, tmp); if (i < DDI_PROP_RESULT_OK) { /* * Free the space we just allocated * and return an error. */ ddi_prop_free(str); switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } *(char **)data = str; *nelements = 1; return (DDI_PROP_SUCCESS); } /* * Decode an array of strings. */ int ddi_prop_fm_decode_strings(prop_handle_t *ph, void *data, uint_t *nelements) { int cnt = 0; char **strs; char **tmp; char *ptr; int i; int n; int size; size_t nbytes; /* * Figure out how many array elements there are by going through the * data without decoding it first and counting. */ for (;;) { i = DDI_PROP_STR(ph, DDI_PROP_CMD_SKIP, NULL); if (i < 0) break; cnt++; } /* * If there are no elements return an error */ if (cnt == 0) return (DDI_PROP_END_OF_DATA); /* * If we cannot skip through the data, we cannot decode it */ if (i == DDI_PROP_RESULT_ERROR) return (DDI_PROP_CANNOT_DECODE); /* * Reset the data pointer to the beginning of the encoded data */ ddi_prop_reset_pos(ph); /* * Figure out how much memory we need for the sum total */ nbytes = (cnt + 1) * sizeof (char *); for (n = 0; n < cnt; n++) { /* * Get the decoded size of the current encoded string. */ size = DDI_PROP_STR(ph, DDI_PROP_CMD_GET_DSIZE, NULL); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } nbytes += size; } /* * Allocate memory in which to store the decoded strings. */ strs = ddi_prop_decode_alloc(nbytes, ddi_prop_free_strings); /* * Set up pointers for each string by figuring out yet * again how long each string is. */ ddi_prop_reset_pos(ph); ptr = (caddr_t)strs + ((cnt + 1) * sizeof (char *)); for (tmp = strs, n = 0; n < cnt; n++, tmp++) { /* * Get the decoded size of the current encoded string. */ size = DDI_PROP_STR(ph, DDI_PROP_CMD_GET_DSIZE, NULL); if (size < DDI_PROP_RESULT_OK) { ddi_prop_free(strs); switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } *tmp = ptr; ptr += size; } /* * String array is terminated by a NULL */ *tmp = NULL; /* * Finally, we can decode each string */ ddi_prop_reset_pos(ph); for (tmp = strs, n = 0; n < cnt; n++, tmp++) { i = DDI_PROP_STR(ph, DDI_PROP_CMD_DECODE, *tmp); if (i < DDI_PROP_RESULT_OK) { /* * Free the space we just allocated * and return an error */ ddi_prop_free(strs); switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } } *(char ***)data = strs; *nelements = cnt; return (DDI_PROP_SUCCESS); } /* * Encode a string. */ int ddi_prop_fm_encode_string(prop_handle_t *ph, void *data, uint_t nelements) { char **tmp; int size; int i; /* * If there is no data, we cannot do anything */ if (nelements == 0) return (DDI_PROP_CANNOT_ENCODE); /* * Get the size of the encoded string. */ tmp = (char **)data; size = DDI_PROP_STR(ph, DDI_PROP_CMD_GET_ESIZE, *tmp); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } /* * Allocate space in the handle to store the encoded string. */ if (ddi_prop_encode_alloc(ph, size) != DDI_PROP_SUCCESS) return (DDI_PROP_NO_MEMORY); ddi_prop_reset_pos(ph); /* * Encode the string. */ tmp = (char **)data; i = DDI_PROP_STR(ph, DDI_PROP_CMD_ENCODE, *tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } return (DDI_PROP_SUCCESS); } /* * Encode an array of strings. */ int ddi_prop_fm_encode_strings(prop_handle_t *ph, void *data, uint_t nelements) { int cnt = 0; char **tmp; int size; uint_t total_size; int i; /* * If there is no data, we cannot do anything */ if (nelements == 0) return (DDI_PROP_CANNOT_ENCODE); /* * Get the total size required to encode all the strings. */ total_size = 0; tmp = (char **)data; for (cnt = 0; cnt < nelements; cnt++, tmp++) { size = DDI_PROP_STR(ph, DDI_PROP_CMD_GET_ESIZE, *tmp); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } total_size += (uint_t)size; } /* * Allocate space in the handle to store the encoded strings. */ if (ddi_prop_encode_alloc(ph, total_size) != DDI_PROP_SUCCESS) return (DDI_PROP_NO_MEMORY); ddi_prop_reset_pos(ph); /* * Encode the array of strings. */ tmp = (char **)data; for (cnt = 0; cnt < nelements; cnt++, tmp++) { i = DDI_PROP_STR(ph, DDI_PROP_CMD_ENCODE, *tmp); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } } return (DDI_PROP_SUCCESS); } /* * Decode an array of bytes. */ static int ddi_prop_fm_decode_bytes(prop_handle_t *ph, void *data, uint_t *nelements) { uchar_t *tmp; int nbytes; int i; /* * If there are no elements return an error */ if (ph->ph_size == 0) return (DDI_PROP_END_OF_DATA); /* * Get the size of the encoded array of bytes. */ nbytes = DDI_PROP_BYTES(ph, DDI_PROP_CMD_GET_DSIZE, data, ph->ph_size); if (nbytes < DDI_PROP_RESULT_OK) { switch (nbytes) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } /* * Allocated memory to store the decoded value in. */ tmp = ddi_prop_decode_alloc(nbytes, ddi_prop_free_bytes); /* * Decode each element and place it in the space we just allocated */ i = DDI_PROP_BYTES(ph, DDI_PROP_CMD_DECODE, tmp, nbytes); if (i < DDI_PROP_RESULT_OK) { /* * Free the space we just allocated * and return an error */ ddi_prop_free(tmp); switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } *(uchar_t **)data = tmp; *nelements = nbytes; return (DDI_PROP_SUCCESS); } /* * Encode an array of bytes. */ int ddi_prop_fm_encode_bytes(prop_handle_t *ph, void *data, uint_t nelements) { int size; int i; /* * If there are no elements, then this is a boolean property, * so just create a property handle with no data and return. */ if (nelements == 0) { (void) ddi_prop_encode_alloc(ph, 0); return (DDI_PROP_SUCCESS); } /* * Get the size of the encoded array of bytes. */ size = DDI_PROP_BYTES(ph, DDI_PROP_CMD_GET_ESIZE, (uchar_t *)data, nelements); if (size < DDI_PROP_RESULT_OK) { switch (size) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_DECODE); } } /* * Allocate space in the handle to store the encoded bytes. */ if (ddi_prop_encode_alloc(ph, (uint_t)size) != DDI_PROP_SUCCESS) return (DDI_PROP_NO_MEMORY); /* * Encode the array of bytes. */ i = DDI_PROP_BYTES(ph, DDI_PROP_CMD_ENCODE, (uchar_t *)data, nelements); if (i < DDI_PROP_RESULT_OK) { switch (i) { case DDI_PROP_RESULT_EOF: return (DDI_PROP_END_OF_DATA); case DDI_PROP_RESULT_ERROR: return (DDI_PROP_CANNOT_ENCODE); } } return (DDI_PROP_SUCCESS); } /* * OBP 1275 integer, string and byte operators. * * DDI_PROP_CMD_DECODE: * * DDI_PROP_RESULT_ERROR: cannot decode the data * DDI_PROP_RESULT_EOF: end of data * DDI_PROP_OK: data was decoded * * DDI_PROP_CMD_ENCODE: * * DDI_PROP_RESULT_ERROR: cannot encode the data * DDI_PROP_RESULT_EOF: end of data * DDI_PROP_OK: data was encoded * * DDI_PROP_CMD_SKIP: * * DDI_PROP_RESULT_ERROR: cannot skip the data * DDI_PROP_RESULT_EOF: end of data * DDI_PROP_OK: data was skipped * * DDI_PROP_CMD_GET_ESIZE: * * DDI_PROP_RESULT_ERROR: cannot get encoded size * DDI_PROP_RESULT_EOF: end of data * > 0: the encoded size * * DDI_PROP_CMD_GET_DSIZE: * * DDI_PROP_RESULT_ERROR: cannot get decoded size * DDI_PROP_RESULT_EOF: end of data * > 0: the decoded size */ /* * OBP 1275 integer operator * * OBP properties are a byte stream of data, so integers may not be * properly aligned. Therefore we need to copy them one byte at a time. */ int ddi_prop_1275_int(prop_handle_t *ph, uint_t cmd, int *data) { int i; switch (cmd) { case DDI_PROP_CMD_DECODE: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0) return (DDI_PROP_RESULT_ERROR); if (ph->ph_flags & PH_FROM_PROM) { i = MIN(ph->ph_size, PROP_1275_INT_SIZE); if ((int *)ph->ph_cur_pos > ((int *)ph->ph_data + ph->ph_size - i)) return (DDI_PROP_RESULT_ERROR); } else { if (ph->ph_size < sizeof (int) || ((int *)ph->ph_cur_pos > ((int *)ph->ph_data + ph->ph_size - sizeof (int)))) return (DDI_PROP_RESULT_ERROR); } /* * Copy the integer, using the implementation-specific * copy function if the property is coming from the PROM. */ if (ph->ph_flags & PH_FROM_PROM) { *data = impl_ddi_prop_int_from_prom( (uchar_t *)ph->ph_cur_pos, (ph->ph_size < PROP_1275_INT_SIZE) ? ph->ph_size : PROP_1275_INT_SIZE); } else { bcopy(ph->ph_cur_pos, data, sizeof (int)); } /* * Move the current location to the start of the next * bit of undecoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + PROP_1275_INT_SIZE; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_ENCODE: /* * Check that there is room to encoded the data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < PROP_1275_INT_SIZE || ((int *)ph->ph_cur_pos > ((int *)ph->ph_data + ph->ph_size - sizeof (int)))) return (DDI_PROP_RESULT_ERROR); /* * Encode the integer into the byte stream one byte at a * time. */ bcopy(data, ph->ph_cur_pos, sizeof (int)); /* * Move the current location to the start of the next bit of * space where we can store encoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + PROP_1275_INT_SIZE; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_SKIP: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < PROP_1275_INT_SIZE) return (DDI_PROP_RESULT_ERROR); if ((caddr_t)ph->ph_cur_pos == (caddr_t)ph->ph_data + ph->ph_size) { return (DDI_PROP_RESULT_EOF); } else if ((caddr_t)ph->ph_cur_pos > (caddr_t)ph->ph_data + ph->ph_size) { return (DDI_PROP_RESULT_EOF); } /* * Move the current location to the start of the next bit of * undecoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + PROP_1275_INT_SIZE; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_GET_ESIZE: /* * Return the size of an encoded integer on OBP */ return (PROP_1275_INT_SIZE); case DDI_PROP_CMD_GET_DSIZE: /* * Return the size of a decoded integer on the system. */ return (sizeof (int)); default: #ifdef DEBUG panic("ddi_prop_1275_int: %x impossible", cmd); /*NOTREACHED*/ #else return (DDI_PROP_RESULT_ERROR); #endif /* DEBUG */ } } /* * 64 bit integer operator. * * This is an extension, defined by Sun, to the 1275 integer * operator. This routine handles the encoding/decoding of * 64 bit integer properties. */ int ddi_prop_int64_op(prop_handle_t *ph, uint_t cmd, int64_t *data) { switch (cmd) { case DDI_PROP_CMD_DECODE: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0) return (DDI_PROP_RESULT_ERROR); if (ph->ph_flags & PH_FROM_PROM) { return (DDI_PROP_RESULT_ERROR); } else { if (ph->ph_size < sizeof (int64_t) || ((int64_t *)ph->ph_cur_pos > ((int64_t *)ph->ph_data + ph->ph_size - sizeof (int64_t)))) return (DDI_PROP_RESULT_ERROR); } /* * Copy the integer, using the implementation-specific * copy function if the property is coming from the PROM. */ if (ph->ph_flags & PH_FROM_PROM) { return (DDI_PROP_RESULT_ERROR); } else { bcopy(ph->ph_cur_pos, data, sizeof (int64_t)); } /* * Move the current location to the start of the next * bit of undecoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + sizeof (int64_t); return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_ENCODE: /* * Check that there is room to encoded the data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < sizeof (int64_t) || ((int64_t *)ph->ph_cur_pos > ((int64_t *)ph->ph_data + ph->ph_size - sizeof (int64_t)))) return (DDI_PROP_RESULT_ERROR); /* * Encode the integer into the byte stream one byte at a * time. */ bcopy(data, ph->ph_cur_pos, sizeof (int64_t)); /* * Move the current location to the start of the next bit of * space where we can store encoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + sizeof (int64_t); return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_SKIP: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < sizeof (int64_t)) return (DDI_PROP_RESULT_ERROR); if ((caddr_t)ph->ph_cur_pos == (caddr_t)ph->ph_data + ph->ph_size) { return (DDI_PROP_RESULT_EOF); } else if ((caddr_t)ph->ph_cur_pos > (caddr_t)ph->ph_data + ph->ph_size) { return (DDI_PROP_RESULT_EOF); } /* * Move the current location to the start of * the next bit of undecoded data. */ ph->ph_cur_pos = (uchar_t *)ph->ph_cur_pos + sizeof (int64_t); return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_GET_ESIZE: /* * Return the size of an encoded integer on OBP */ return (sizeof (int64_t)); case DDI_PROP_CMD_GET_DSIZE: /* * Return the size of a decoded integer on the system. */ return (sizeof (int64_t)); default: #ifdef DEBUG panic("ddi_prop_int64_op: %x impossible", cmd); /*NOTREACHED*/ #else return (DDI_PROP_RESULT_ERROR); #endif /* DEBUG */ } } /* * OBP 1275 string operator. * * OBP strings are NULL terminated. */ int ddi_prop_1275_string(prop_handle_t *ph, uint_t cmd, char *data) { int n; char *p; char *end; switch (cmd) { case DDI_PROP_CMD_DECODE: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0) { return (DDI_PROP_RESULT_ERROR); } /* * Match DDI_PROP_CMD_GET_DSIZE logic for when to stop and * how to NULL terminate result. */ p = (char *)ph->ph_cur_pos; end = (char *)ph->ph_data + ph->ph_size; if (p >= end) return (DDI_PROP_RESULT_EOF); while (p < end) { *data++ = *p; if (*p++ == 0) { /* NULL from OBP */ ph->ph_cur_pos = p; return (DDI_PROP_RESULT_OK); } } /* * If OBP did not NULL terminate string, which happens * (at least) for 'true'/'false' boolean values, account for * the space and store null termination on decode. */ ph->ph_cur_pos = p; *data = 0; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_ENCODE: /* * Check that there is room to encoded the data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0) { return (DDI_PROP_RESULT_ERROR); } n = strlen(data) + 1; if ((char *)ph->ph_cur_pos > ((char *)ph->ph_data + ph->ph_size - n)) { return (DDI_PROP_RESULT_ERROR); } /* * Copy the NULL terminated string */ bcopy(data, ph->ph_cur_pos, n); /* * Move the current location to the start of the next bit of * space where we can store encoded data. */ ph->ph_cur_pos = (char *)ph->ph_cur_pos + n; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_SKIP: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0) { return (DDI_PROP_RESULT_ERROR); } /* * Return the string length plus one for the NULL * We know the size of the property, we need to * ensure that the string is properly formatted, * since we may be looking up random OBP data. */ p = (char *)ph->ph_cur_pos; end = (char *)ph->ph_data + ph->ph_size; if (p >= end) return (DDI_PROP_RESULT_EOF); while (p < end) { if (*p++ == 0) { /* NULL from OBP */ ph->ph_cur_pos = p; return (DDI_PROP_RESULT_OK); } } /* * Accommodate the fact that OBP does not always NULL * terminate strings. */ ph->ph_cur_pos = p; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_GET_ESIZE: /* * Return the size of the encoded string on OBP. */ return (strlen(data) + 1); case DDI_PROP_CMD_GET_DSIZE: /* * Return the string length plus one for the NULL. * We know the size of the property, we need to * ensure that the string is properly formatted, * since we may be looking up random OBP data. */ p = (char *)ph->ph_cur_pos; end = (char *)ph->ph_data + ph->ph_size; if (p >= end) return (DDI_PROP_RESULT_EOF); for (n = 0; p < end; n++) { if (*p++ == 0) { /* NULL from OBP */ ph->ph_cur_pos = p; return (n + 1); } } /* * If OBP did not NULL terminate string, which happens for * 'true'/'false' boolean values, account for the space * to store null termination here. */ ph->ph_cur_pos = p; return (n + 1); default: #ifdef DEBUG panic("ddi_prop_1275_string: %x impossible", cmd); /*NOTREACHED*/ #else return (DDI_PROP_RESULT_ERROR); #endif /* DEBUG */ } } /* * OBP 1275 byte operator * * Caller must specify the number of bytes to get. OBP encodes bytes * as a byte so there is a 1-to-1 translation. */ int ddi_prop_1275_bytes(prop_handle_t *ph, uint_t cmd, uchar_t *data, uint_t nelements) { switch (cmd) { case DDI_PROP_CMD_DECODE: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < nelements || ((char *)ph->ph_cur_pos > ((char *)ph->ph_data + ph->ph_size - nelements))) return (DDI_PROP_RESULT_ERROR); /* * Copy out the bytes */ bcopy(ph->ph_cur_pos, data, nelements); /* * Move the current location */ ph->ph_cur_pos = (char *)ph->ph_cur_pos + nelements; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_ENCODE: /* * Check that there is room to encode the data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < nelements || ((char *)ph->ph_cur_pos > ((char *)ph->ph_data + ph->ph_size - nelements))) return (DDI_PROP_RESULT_ERROR); /* * Copy in the bytes */ bcopy(data, ph->ph_cur_pos, nelements); /* * Move the current location to the start of the next bit of * space where we can store encoded data. */ ph->ph_cur_pos = (char *)ph->ph_cur_pos + nelements; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_SKIP: /* * Check that there is encoded data */ if (ph->ph_cur_pos == NULL || ph->ph_size == 0 || ph->ph_size < nelements) return (DDI_PROP_RESULT_ERROR); if ((char *)ph->ph_cur_pos > ((char *)ph->ph_data + ph->ph_size - nelements)) return (DDI_PROP_RESULT_EOF); /* * Move the current location */ ph->ph_cur_pos = (char *)ph->ph_cur_pos + nelements; return (DDI_PROP_RESULT_OK); case DDI_PROP_CMD_GET_ESIZE: /* * The size in bytes of the encoded size is the * same as the decoded size provided by the caller. */ return (nelements); case DDI_PROP_CMD_GET_DSIZE: /* * Just return the number of bytes specified by the caller. */ return (nelements); default: #ifdef DEBUG panic("ddi_prop_1275_bytes: %x impossible", cmd); /*NOTREACHED*/ #else return (DDI_PROP_RESULT_ERROR); #endif /* DEBUG */ } } /* * Used for properties that come from the OBP, hardware configuration files, * or that are created by calls to ddi_prop_update(9F). */ static struct prop_handle_ops prop_1275_ops = { ddi_prop_1275_int, ddi_prop_1275_string, ddi_prop_1275_bytes, ddi_prop_int64_op }; /* * Interface to create/modify a managed property on child's behalf... * Flags interpreted are: * DDI_PROP_CANSLEEP: Allow memory allocation to sleep. * DDI_PROP_SYSTEM_DEF: Manipulate system list rather than driver list. * * Use same dev_t when modifying or undefining a property. * Search for properties with DDI_DEV_T_ANY to match first named * property on the list. * * Properties are stored LIFO and subsequently will match the first * `matching' instance. */ /* * ddi_prop_add: Add a software defined property */ /* * define to get a new ddi_prop_t. * km_flags are KM_SLEEP or KM_NOSLEEP. */ #define DDI_NEW_PROP_T(km_flags) \ (kmem_zalloc(sizeof (ddi_prop_t), km_flags)) static int ddi_prop_add(dev_t dev, dev_info_t *dip, int flags, char *name, caddr_t value, int length) { ddi_prop_t *new_propp, *propp; ddi_prop_t **list_head = &(DEVI(dip)->devi_drv_prop_ptr); int km_flags = KM_NOSLEEP; int name_buf_len; /* * If dev_t is DDI_DEV_T_ANY or name's length is zero return error. */ if (dev == DDI_DEV_T_ANY || name == (char *)0 || strlen(name) == 0) return (DDI_PROP_INVAL_ARG); if (flags & DDI_PROP_CANSLEEP) km_flags = KM_SLEEP; if (flags & DDI_PROP_SYSTEM_DEF) list_head = &(DEVI(dip)->devi_sys_prop_ptr); else if (flags & DDI_PROP_HW_DEF) list_head = &(DEVI(dip)->devi_hw_prop_ptr); if ((new_propp = DDI_NEW_PROP_T(km_flags)) == NULL) { cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } /* * If dev is major number 0, then we need to do a ddi_name_to_major * to get the real major number for the device. This needs to be * done because some drivers need to call ddi_prop_create in their * attach routines but they don't have a dev. By creating the dev * ourself if the major number is 0, drivers will not have to know what * their major number. They can just create a dev with major number * 0 and pass it in. For device 0, we will be doing a little extra * work by recreating the same dev that we already have, but its the * price you pay :-). * * This fixes bug #1098060. */ if (getmajor(dev) == DDI_MAJOR_T_UNKNOWN) { new_propp->prop_dev = makedevice(ddi_name_to_major(DEVI(dip)->devi_binding_name), getminor(dev)); } else new_propp->prop_dev = dev; /* * Allocate space for property name and copy it in... */ name_buf_len = strlen(name) + 1; new_propp->prop_name = kmem_alloc(name_buf_len, km_flags); if (new_propp->prop_name == 0) { kmem_free(new_propp, sizeof (ddi_prop_t)); cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } bcopy(name, new_propp->prop_name, name_buf_len); /* * Set the property type */ new_propp->prop_flags = flags & DDI_PROP_TYPE_MASK; /* * Set length and value ONLY if not an explicit property undefine: * NOTE: value and length are zero for explicit undefines. */ if (flags & DDI_PROP_UNDEF_IT) { new_propp->prop_flags |= DDI_PROP_UNDEF_IT; } else { if ((new_propp->prop_len = length) != 0) { new_propp->prop_val = kmem_alloc(length, km_flags); if (new_propp->prop_val == 0) { kmem_free(new_propp->prop_name, name_buf_len); kmem_free(new_propp, sizeof (ddi_prop_t)); cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } bcopy(value, new_propp->prop_val, length); } } /* * Link property into beginning of list. (Properties are LIFO order.) */ mutex_enter(&(DEVI(dip)->devi_lock)); propp = *list_head; new_propp->prop_next = propp; *list_head = new_propp; mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_PROP_SUCCESS); } /* * ddi_prop_change: Modify a software managed property value * * Set new length and value if found. * returns DDI_PROP_INVAL_ARG if dev is DDI_DEV_T_ANY or * input name is the NULL string. * returns DDI_PROP_NO_MEMORY if unable to allocate memory * * Note: an undef can be modified to be a define, * (you can't go the other way.) */ static int ddi_prop_change(dev_t dev, dev_info_t *dip, int flags, char *name, caddr_t value, int length) { ddi_prop_t *propp; ddi_prop_t **ppropp; caddr_t p = NULL; if ((dev == DDI_DEV_T_ANY) || (name == NULL) || (strlen(name) == 0)) return (DDI_PROP_INVAL_ARG); /* * Preallocate buffer, even if we don't need it... */ if (length != 0) { p = kmem_alloc(length, (flags & DDI_PROP_CANSLEEP) ? KM_SLEEP : KM_NOSLEEP); if (p == NULL) { cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } } /* * If the dev_t value contains DDI_MAJOR_T_UNKNOWN for the major * number, a real dev_t value should be created based upon the dip's * binding driver. See ddi_prop_add... */ if (getmajor(dev) == DDI_MAJOR_T_UNKNOWN) dev = makedevice( ddi_name_to_major(DEVI(dip)->devi_binding_name), getminor(dev)); /* * Check to see if the property exists. If so we modify it. * Else we create it by calling ddi_prop_add(). */ mutex_enter(&(DEVI(dip)->devi_lock)); ppropp = &DEVI(dip)->devi_drv_prop_ptr; if (flags & DDI_PROP_SYSTEM_DEF) ppropp = &DEVI(dip)->devi_sys_prop_ptr; else if (flags & DDI_PROP_HW_DEF) ppropp = &DEVI(dip)->devi_hw_prop_ptr; if ((propp = i_ddi_prop_search(dev, name, flags, ppropp)) != NULL) { /* * Need to reallocate buffer? If so, do it * carefully (reuse same space if new prop * is same size and non-NULL sized). */ if (length != 0) bcopy(value, p, length); if (propp->prop_len != 0) kmem_free(propp->prop_val, propp->prop_len); propp->prop_len = length; propp->prop_val = p; propp->prop_flags &= ~DDI_PROP_UNDEF_IT; mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_PROP_SUCCESS); } mutex_exit(&(DEVI(dip)->devi_lock)); if (length != 0) kmem_free(p, length); return (ddi_prop_add(dev, dip, flags, name, value, length)); } /* * Common update routine used to update and encode a property. Creates * a property handle, calls the property encode routine, figures out if * the property already exists and updates if it does. Otherwise it * creates if it does not exist. */ int ddi_prop_update_common(dev_t match_dev, dev_info_t *dip, int flags, char *name, void *data, uint_t nelements, int (*prop_create)(prop_handle_t *, void *data, uint_t nelements)) { prop_handle_t ph; int rval; uint_t ourflags; /* * If dev_t is DDI_DEV_T_ANY or name's length is zero, * return error. */ if (match_dev == DDI_DEV_T_ANY || name == NULL || strlen(name) == 0) return (DDI_PROP_INVAL_ARG); /* * Create the handle */ ph.ph_data = NULL; ph.ph_cur_pos = NULL; ph.ph_save_pos = NULL; ph.ph_size = 0; ph.ph_ops = &prop_1275_ops; /* * ourflags: * For compatibility with the old interfaces. The old interfaces * didn't sleep by default and slept when the flag was set. These * interfaces to the opposite. So the old interfaces now set the * DDI_PROP_DONTSLEEP flag by default which tells us not to sleep. * * ph.ph_flags: * Blocked data or unblocked data allocation * for ph.ph_data in ddi_prop_encode_alloc() */ if (flags & DDI_PROP_DONTSLEEP) { ourflags = flags; ph.ph_flags = DDI_PROP_DONTSLEEP; } else { ourflags = flags | DDI_PROP_CANSLEEP; ph.ph_flags = DDI_PROP_CANSLEEP; } /* * Encode the data and store it in the property handle by * calling the prop_encode routine. */ if ((rval = (*prop_create)(&ph, data, nelements)) != DDI_PROP_SUCCESS) { if (rval == DDI_PROP_NO_MEMORY) cmn_err(CE_CONT, prop_no_mem_msg, name); if (ph.ph_size != 0) kmem_free(ph.ph_data, ph.ph_size); return (rval); } /* * The old interfaces use a stacking approach to creating * properties. If we are being called from the old interfaces, * the DDI_PROP_STACK_CREATE flag will be set, so we just do a * create without checking. */ if (flags & DDI_PROP_STACK_CREATE) { rval = ddi_prop_add(match_dev, dip, ourflags, name, ph.ph_data, ph.ph_size); } else { rval = ddi_prop_change(match_dev, dip, ourflags, name, ph.ph_data, ph.ph_size); } /* * Free the encoded data allocated in the prop_encode routine. */ if (ph.ph_size != 0) kmem_free(ph.ph_data, ph.ph_size); return (rval); } /* * ddi_prop_create: Define a managed property: * See above for details. */ int ddi_prop_create(dev_t dev, dev_info_t *dip, int flag, char *name, caddr_t value, int length) { if (!(flag & DDI_PROP_CANSLEEP)) { flag |= DDI_PROP_DONTSLEEP; #ifdef DDI_PROP_DEBUG if (length != 0) cmn_err(CE_NOTE, "!ddi_prop_create: interface obsolete," "use ddi_prop_update (prop = %s, node = %s%d)", name, ddi_driver_name(dip), ddi_get_instance(dip)); #endif /* DDI_PROP_DEBUG */ } flag &= ~DDI_PROP_SYSTEM_DEF; return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_STACK_CREATE | DDI_PROP_TYPE_ANY), name, value, length, ddi_prop_fm_encode_bytes)); } int e_ddi_prop_create(dev_t dev, dev_info_t *dip, int flag, char *name, caddr_t value, int length) { if (!(flag & DDI_PROP_CANSLEEP)) flag |= DDI_PROP_DONTSLEEP; return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_SYSTEM_DEF | DDI_PROP_STACK_CREATE | DDI_PROP_TYPE_ANY), name, value, length, ddi_prop_fm_encode_bytes)); } int ddi_prop_modify(dev_t dev, dev_info_t *dip, int flag, char *name, caddr_t value, int length) { ASSERT((flag & DDI_PROP_TYPE_MASK) == 0); /* * If dev_t is DDI_DEV_T_ANY or name's length is zero, * return error. */ if (dev == DDI_DEV_T_ANY || name == NULL || strlen(name) == 0) return (DDI_PROP_INVAL_ARG); if (!(flag & DDI_PROP_CANSLEEP)) flag |= DDI_PROP_DONTSLEEP; flag &= ~DDI_PROP_SYSTEM_DEF; if (ddi_prop_exists(dev, dip, (flag | DDI_PROP_NOTPROM), name) == 0) return (DDI_PROP_NOT_FOUND); return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_TYPE_BYTE), name, value, length, ddi_prop_fm_encode_bytes)); } int e_ddi_prop_modify(dev_t dev, dev_info_t *dip, int flag, char *name, caddr_t value, int length) { ASSERT((flag & DDI_PROP_TYPE_MASK) == 0); /* * If dev_t is DDI_DEV_T_ANY or name's length is zero, * return error. */ if (dev == DDI_DEV_T_ANY || name == NULL || strlen(name) == 0) return (DDI_PROP_INVAL_ARG); if (ddi_prop_exists(dev, dip, (flag | DDI_PROP_SYSTEM_DEF), name) == 0) return (DDI_PROP_NOT_FOUND); if (!(flag & DDI_PROP_CANSLEEP)) flag |= DDI_PROP_DONTSLEEP; return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_BYTE), name, value, length, ddi_prop_fm_encode_bytes)); } /* * Common lookup routine used to lookup and decode a property. * Creates a property handle, searches for the raw encoded data, * fills in the handle, and calls the property decode functions * passed in. * * This routine is not static because ddi_bus_prop_op() which lives in * ddi_impl.c calls it. No driver should be calling this routine. */ int ddi_prop_lookup_common(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, void *data, uint_t *nelements, int (*prop_decoder)(prop_handle_t *, void *data, uint_t *nelements)) { int rval; uint_t ourflags; prop_handle_t ph; if ((match_dev == DDI_DEV_T_NONE) || (name == NULL) || (strlen(name) == 0)) return (DDI_PROP_INVAL_ARG); ourflags = (flags & DDI_PROP_DONTSLEEP) ? flags : flags | DDI_PROP_CANSLEEP; /* * Get the encoded data */ bzero(&ph, sizeof (prop_handle_t)); if (flags & DDI_UNBND_DLPI2) { /* * For unbound dlpi style-2 devices, index into * the devnames' array and search the global * property list. */ ourflags &= ~DDI_UNBND_DLPI2; rval = i_ddi_prop_search_global(match_dev, ourflags, name, &ph.ph_data, &ph.ph_size); } else { rval = ddi_prop_search_common(match_dev, dip, PROP_LEN_AND_VAL_ALLOC, ourflags, name, &ph.ph_data, &ph.ph_size); } if (rval != DDI_PROP_SUCCESS && rval != DDI_PROP_FOUND_1275) { ASSERT(ph.ph_data == NULL); ASSERT(ph.ph_size == 0); return (rval); } /* * If the encoded data came from a OBP or software * use the 1275 OBP decode/encode routines. */ ph.ph_cur_pos = ph.ph_data; ph.ph_save_pos = ph.ph_data; ph.ph_ops = &prop_1275_ops; ph.ph_flags = (rval == DDI_PROP_FOUND_1275) ? PH_FROM_PROM : 0; rval = (*prop_decoder)(&ph, data, nelements); /* * Free the encoded data */ if (ph.ph_size != 0) kmem_free(ph.ph_data, ph.ph_size); return (rval); } /* * Lookup and return an array of composite properties. The driver must * provide the decode routine. */ int ddi_prop_lookup(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, void *data, uint_t *nelements, int (*prop_decoder)(prop_handle_t *, void *data, uint_t *nelements)) { return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_COMPOSITE), name, data, nelements, prop_decoder)); } /* * Return 1 if a property exists (no type checking done). * Return 0 if it does not exist. */ int ddi_prop_exists(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name) { int i; uint_t x = 0; i = ddi_prop_search_common(match_dev, dip, PROP_EXISTS, flags | DDI_PROP_TYPE_MASK, name, NULL, &x); return (i == DDI_PROP_SUCCESS || i == DDI_PROP_FOUND_1275); } /* * Update an array of composite properties. The driver must * provide the encode routine. */ int ddi_prop_update(dev_t match_dev, dev_info_t *dip, char *name, void *data, uint_t nelements, int (*prop_create)(prop_handle_t *, void *data, uint_t nelements)) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_COMPOSITE, name, data, nelements, prop_create)); } /* * Get a single integer or boolean property and return it. * If the property does not exists, or cannot be decoded, * then return the defvalue passed in. * * This routine always succeeds. */ int ddi_prop_get_int(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, int defvalue) { int data; uint_t nelements; int rval; if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_get_int: invalid flag" " 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ flags &= DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2; } if ((rval = ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_INT), name, &data, &nelements, ddi_prop_fm_decode_int)) != DDI_PROP_SUCCESS) { if (rval == DDI_PROP_END_OF_DATA) data = 1; else data = defvalue; } return (data); } /* * Get a single 64 bit integer or boolean property and return it. * If the property does not exists, or cannot be decoded, * then return the defvalue passed in. * * This routine always succeeds. */ int64_t ddi_prop_get_int64(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, int64_t defvalue) { int64_t data; uint_t nelements; int rval; if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_get_int64: invalid flag" " 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ return (DDI_PROP_INVAL_ARG); } if ((rval = ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_INT64 | DDI_PROP_NOTPROM), name, &data, &nelements, ddi_prop_fm_decode_int64)) != DDI_PROP_SUCCESS) { if (rval == DDI_PROP_END_OF_DATA) data = 1; else data = defvalue; } return (data); } /* * Get an array of integer property */ int ddi_prop_lookup_int_array(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, int **data, uint_t *nelements) { if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_lookup_int_array: " "invalid flag 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ flags &= DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2; } return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_INT), name, data, nelements, ddi_prop_fm_decode_ints)); } /* * Get an array of 64 bit integer properties */ int ddi_prop_lookup_int64_array(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, int64_t **data, uint_t *nelements) { if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_lookup_int64_array: " "invalid flag 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ return (DDI_PROP_INVAL_ARG); } return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_INT64 | DDI_PROP_NOTPROM), name, data, nelements, ddi_prop_fm_decode_int64_array)); } /* * Update a single integer property. If the property exists on the drivers * property list it updates, else it creates it. */ int ddi_prop_update_int(dev_t match_dev, dev_info_t *dip, char *name, int data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_INT, name, &data, 1, ddi_prop_fm_encode_ints)); } /* * Update a single 64 bit integer property. * Update the driver property list if it exists, else create it. */ int ddi_prop_update_int64(dev_t match_dev, dev_info_t *dip, char *name, int64_t data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_INT64, name, &data, 1, ddi_prop_fm_encode_int64)); } int e_ddi_prop_update_int(dev_t match_dev, dev_info_t *dip, char *name, int data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_INT, name, &data, 1, ddi_prop_fm_encode_ints)); } int e_ddi_prop_update_int64(dev_t match_dev, dev_info_t *dip, char *name, int64_t data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_INT64, name, &data, 1, ddi_prop_fm_encode_int64)); } /* * Update an array of integer property. If the property exists on the drivers * property list it updates, else it creates it. */ int ddi_prop_update_int_array(dev_t match_dev, dev_info_t *dip, char *name, int *data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_INT, name, data, nelements, ddi_prop_fm_encode_ints)); } /* * Update an array of 64 bit integer properties. * Update the driver property list if it exists, else create it. */ int ddi_prop_update_int64_array(dev_t match_dev, dev_info_t *dip, char *name, int64_t *data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_INT64, name, data, nelements, ddi_prop_fm_encode_int64)); } int e_ddi_prop_update_int64_array(dev_t match_dev, dev_info_t *dip, char *name, int64_t *data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_INT64, name, data, nelements, ddi_prop_fm_encode_int64)); } int e_ddi_prop_update_int_array(dev_t match_dev, dev_info_t *dip, char *name, int *data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_INT, name, data, nelements, ddi_prop_fm_encode_ints)); } /* * Get a single string property. */ int ddi_prop_lookup_string(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, char **data) { uint_t x; if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "%s: invalid flag 0x%x " "(prop = %s, node = %s%d); invalid bits ignored", "ddi_prop_lookup_string", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ flags &= DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2; } return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_STRING), name, data, &x, ddi_prop_fm_decode_string)); } /* * Get an array of strings property. */ int ddi_prop_lookup_string_array(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, char ***data, uint_t *nelements) { if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_lookup_string_array: " "invalid flag 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ flags &= DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2; } return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_STRING), name, data, nelements, ddi_prop_fm_decode_strings)); } /* * Update a single string property. */ int ddi_prop_update_string(dev_t match_dev, dev_info_t *dip, char *name, char *data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_STRING, name, &data, 1, ddi_prop_fm_encode_string)); } int e_ddi_prop_update_string(dev_t match_dev, dev_info_t *dip, char *name, char *data) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_STRING, name, &data, 1, ddi_prop_fm_encode_string)); } /* * Update an array of strings property. */ int ddi_prop_update_string_array(dev_t match_dev, dev_info_t *dip, char *name, char **data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_STRING, name, data, nelements, ddi_prop_fm_encode_strings)); } int e_ddi_prop_update_string_array(dev_t match_dev, dev_info_t *dip, char *name, char **data, uint_t nelements) { return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_STRING, name, data, nelements, ddi_prop_fm_encode_strings)); } /* * Get an array of bytes property. */ int ddi_prop_lookup_byte_array(dev_t match_dev, dev_info_t *dip, uint_t flags, char *name, uchar_t **data, uint_t *nelements) { if (flags & ~(DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2)) { #ifdef DEBUG if (dip != NULL) { cmn_err(CE_WARN, "ddi_prop_lookup_byte_array: " " invalid flag 0x%x (prop = %s, node = %s%d)", flags, name, ddi_driver_name(dip), ddi_get_instance(dip)); } #endif /* DEBUG */ flags &= DDI_PROP_DONTPASS | DDI_PROP_NOTPROM | LDI_DEV_T_ANY | DDI_UNBND_DLPI2; } return (ddi_prop_lookup_common(match_dev, dip, (flags | DDI_PROP_TYPE_BYTE), name, data, nelements, ddi_prop_fm_decode_bytes)); } /* * Update an array of bytes property. */ int ddi_prop_update_byte_array(dev_t match_dev, dev_info_t *dip, char *name, uchar_t *data, uint_t nelements) { if (nelements == 0) return (DDI_PROP_INVAL_ARG); return (ddi_prop_update_common(match_dev, dip, DDI_PROP_TYPE_BYTE, name, data, nelements, ddi_prop_fm_encode_bytes)); } int e_ddi_prop_update_byte_array(dev_t match_dev, dev_info_t *dip, char *name, uchar_t *data, uint_t nelements) { if (nelements == 0) return (DDI_PROP_INVAL_ARG); return (ddi_prop_update_common(match_dev, dip, DDI_PROP_SYSTEM_DEF | DDI_PROP_TYPE_BYTE, name, data, nelements, ddi_prop_fm_encode_bytes)); } /* * ddi_prop_remove_common: Undefine a managed property: * Input dev_t must match dev_t when defined. * Returns DDI_PROP_NOT_FOUND, possibly. * DDI_PROP_INVAL_ARG is also possible if dev is * DDI_DEV_T_ANY or incoming name is the NULL string. */ int ddi_prop_remove_common(dev_t dev, dev_info_t *dip, char *name, int flag) { ddi_prop_t **list_head = &(DEVI(dip)->devi_drv_prop_ptr); ddi_prop_t *propp; ddi_prop_t *lastpropp = NULL; if ((dev == DDI_DEV_T_ANY) || (name == (char *)0) || (strlen(name) == 0)) { return (DDI_PROP_INVAL_ARG); } if (flag & DDI_PROP_SYSTEM_DEF) list_head = &(DEVI(dip)->devi_sys_prop_ptr); else if (flag & DDI_PROP_HW_DEF) list_head = &(DEVI(dip)->devi_hw_prop_ptr); mutex_enter(&(DEVI(dip)->devi_lock)); for (propp = *list_head; propp != NULL; propp = propp->prop_next) { if (DDI_STRSAME(propp->prop_name, name) && (dev == propp->prop_dev)) { /* * Unlink this propp allowing for it to * be first in the list: */ if (lastpropp == NULL) *list_head = propp->prop_next; else lastpropp->prop_next = propp->prop_next; mutex_exit(&(DEVI(dip)->devi_lock)); /* * Free memory and return... */ kmem_free(propp->prop_name, strlen(propp->prop_name) + 1); if (propp->prop_len != 0) kmem_free(propp->prop_val, propp->prop_len); kmem_free(propp, sizeof (ddi_prop_t)); return (DDI_PROP_SUCCESS); } lastpropp = propp; } mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_PROP_NOT_FOUND); } int ddi_prop_remove(dev_t dev, dev_info_t *dip, char *name) { return (ddi_prop_remove_common(dev, dip, name, 0)); } int e_ddi_prop_remove(dev_t dev, dev_info_t *dip, char *name) { return (ddi_prop_remove_common(dev, dip, name, DDI_PROP_SYSTEM_DEF)); } /* * e_ddi_prop_list_delete: remove a list of properties * Note that the caller needs to provide the required protection * (eg. devi_lock if these properties are still attached to a devi) */ void e_ddi_prop_list_delete(ddi_prop_t *props) { i_ddi_prop_list_delete(props); } /* * ddi_prop_remove_all_common: * Used before unloading a driver to remove * all properties. (undefines all dev_t's props.) * Also removes `explicitly undefined' props. * No errors possible. */ void ddi_prop_remove_all_common(dev_info_t *dip, int flag) { ddi_prop_t **list_head; mutex_enter(&(DEVI(dip)->devi_lock)); if (flag & DDI_PROP_SYSTEM_DEF) { list_head = &(DEVI(dip)->devi_sys_prop_ptr); } else if (flag & DDI_PROP_HW_DEF) { list_head = &(DEVI(dip)->devi_hw_prop_ptr); } else { list_head = &(DEVI(dip)->devi_drv_prop_ptr); } i_ddi_prop_list_delete(*list_head); *list_head = NULL; mutex_exit(&(DEVI(dip)->devi_lock)); } /* * ddi_prop_remove_all: Remove all driver prop definitions. */ void ddi_prop_remove_all(dev_info_t *dip) { ddi_prop_remove_all_common(dip, 0); } /* * e_ddi_prop_remove_all: Remove all system prop definitions. */ void e_ddi_prop_remove_all(dev_info_t *dip) { ddi_prop_remove_all_common(dip, (int)DDI_PROP_SYSTEM_DEF); } /* * ddi_prop_undefine: Explicitly undefine a property. Property * searches which match this property return * the error code DDI_PROP_UNDEFINED. * * Use ddi_prop_remove to negate effect of * ddi_prop_undefine * * See above for error returns. */ int ddi_prop_undefine(dev_t dev, dev_info_t *dip, int flag, char *name) { if (!(flag & DDI_PROP_CANSLEEP)) flag |= DDI_PROP_DONTSLEEP; return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_STACK_CREATE | DDI_PROP_UNDEF_IT | DDI_PROP_TYPE_ANY), name, NULL, 0, ddi_prop_fm_encode_bytes)); } int e_ddi_prop_undefine(dev_t dev, dev_info_t *dip, int flag, char *name) { if (!(flag & DDI_PROP_CANSLEEP)) flag |= DDI_PROP_DONTSLEEP; return (ddi_prop_update_common(dev, dip, (flag | DDI_PROP_SYSTEM_DEF | DDI_PROP_STACK_CREATE | DDI_PROP_UNDEF_IT | DDI_PROP_TYPE_ANY), name, NULL, 0, ddi_prop_fm_encode_bytes)); } /* * Code to search hardware layer (PROM), if it exists, on behalf of child. * * if input dip != child_dip, then call is on behalf of child * to search PROM, do it via ddi_prop_search_common() and ascend only * if allowed. * * if input dip == ch_dip (child_dip), call is on behalf of root driver, * to search for PROM defined props only. * * Note that the PROM search is done only if the requested dev * is either DDI_DEV_T_ANY or DDI_DEV_T_NONE. PROM properties * have no associated dev, thus are automatically associated with * DDI_DEV_T_NONE. * * Modifying flag DDI_PROP_NOTPROM inhibits the search in the h/w layer. * * Returns DDI_PROP_FOUND_1275 if found to indicate to framework * that the property resides in the prom. */ int impl_ddi_bus_prop_op(dev_t dev, dev_info_t *dip, dev_info_t *ch_dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp) { int len; caddr_t buffer; /* * If requested dev is DDI_DEV_T_NONE or DDI_DEV_T_ANY, then * look in caller's PROM if it's a self identifying device... * * Note that this is very similar to ddi_prop_op, but we * search the PROM instead of the s/w defined properties, * and we are called on by the parent driver to do this for * the child. */ if (((dev == DDI_DEV_T_NONE) || (dev == DDI_DEV_T_ANY)) && ndi_dev_is_prom_node(ch_dip) && ((mod_flags & DDI_PROP_NOTPROM) == 0)) { len = prom_getproplen((pnode_t)DEVI(ch_dip)->devi_nodeid, name); if (len == -1) { return (DDI_PROP_NOT_FOUND); } /* * If exists only request, we're done */ if (prop_op == PROP_EXISTS) { return (DDI_PROP_FOUND_1275); } /* * If length only request or prop length == 0, get out */ if ((prop_op == PROP_LEN) || (len == 0)) { *lengthp = len; return (DDI_PROP_FOUND_1275); } /* * Allocate buffer if required... (either way `buffer' * is receiving address). */ switch (prop_op) { case PROP_LEN_AND_VAL_ALLOC: buffer = kmem_alloc((size_t)len, mod_flags & DDI_PROP_CANSLEEP ? KM_SLEEP : KM_NOSLEEP); if (buffer == NULL) { return (DDI_PROP_NO_MEMORY); } *(caddr_t *)valuep = buffer; break; case PROP_LEN_AND_VAL_BUF: if (len > (*lengthp)) { *lengthp = len; return (DDI_PROP_BUF_TOO_SMALL); } buffer = valuep; break; default: break; } /* * Call the PROM function to do the copy. */ (void) prom_getprop((pnode_t)DEVI(ch_dip)->devi_nodeid, name, buffer); *lengthp = len; /* return the actual length to the caller */ (void) impl_fix_props(dip, ch_dip, name, len, buffer); return (DDI_PROP_FOUND_1275); } return (DDI_PROP_NOT_FOUND); } /* * The ddi_bus_prop_op default bus nexus prop op function. * * Code to search hardware layer (PROM), if it exists, * on behalf of child, then, if appropriate, ascend and check * my own software defined properties... */ int ddi_bus_prop_op(dev_t dev, dev_info_t *dip, dev_info_t *ch_dip, ddi_prop_op_t prop_op, int mod_flags, char *name, caddr_t valuep, int *lengthp) { int error; error = impl_ddi_bus_prop_op(dev, dip, ch_dip, prop_op, mod_flags, name, valuep, lengthp); if (error == DDI_PROP_SUCCESS || error == DDI_PROP_FOUND_1275 || error == DDI_PROP_BUF_TOO_SMALL) return (error); if (error == DDI_PROP_NO_MEMORY) { cmn_err(CE_CONT, prop_no_mem_msg, name); return (DDI_PROP_NO_MEMORY); } /* * Check the 'options' node as a last resort */ if ((mod_flags & DDI_PROP_DONTPASS) != 0) return (DDI_PROP_NOT_FOUND); if (ch_dip == ddi_root_node()) { /* * As a last resort, when we've reached * the top and still haven't found the * property, see if the desired property * is attached to the options node. * * The options dip is attached right after boot. */ ASSERT(options_dip != NULL); /* * Force the "don't pass" flag to *just* see * what the options node has to offer. */ return (ddi_prop_search_common(dev, options_dip, prop_op, mod_flags|DDI_PROP_DONTPASS, name, valuep, (uint_t *)lengthp)); } /* * Otherwise, continue search with parent's s/w defined properties... * NOTE: Using `dip' in following call increments the level. */ return (ddi_prop_search_common(dev, dip, prop_op, mod_flags, name, valuep, (uint_t *)lengthp)); } /* * External property functions used by other parts of the kernel... */ /* * e_ddi_getlongprop: See comments for ddi_get_longprop. */ int e_ddi_getlongprop(dev_t dev, vtype_t type, char *name, int flags, caddr_t valuep, int *lengthp) { _NOTE(ARGUNUSED(type)) dev_info_t *devi; ddi_prop_op_t prop_op = PROP_LEN_AND_VAL_ALLOC; int error; if ((devi = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (DDI_PROP_NOT_FOUND); error = cdev_prop_op(dev, devi, prop_op, flags, name, valuep, lengthp); ddi_release_devi(devi); return (error); } /* * e_ddi_getlongprop_buf: See comments for ddi_getlongprop_buf. */ int e_ddi_getlongprop_buf(dev_t dev, vtype_t type, char *name, int flags, caddr_t valuep, int *lengthp) { _NOTE(ARGUNUSED(type)) dev_info_t *devi; ddi_prop_op_t prop_op = PROP_LEN_AND_VAL_BUF; int error; if ((devi = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (DDI_PROP_NOT_FOUND); error = cdev_prop_op(dev, devi, prop_op, flags, name, valuep, lengthp); ddi_release_devi(devi); return (error); } /* * e_ddi_getprop: See comments for ddi_getprop. */ int e_ddi_getprop(dev_t dev, vtype_t type, char *name, int flags, int defvalue) { _NOTE(ARGUNUSED(type)) dev_info_t *devi; ddi_prop_op_t prop_op = PROP_LEN_AND_VAL_BUF; int propvalue = defvalue; int proplength = sizeof (int); int error; if ((devi = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (defvalue); error = cdev_prop_op(dev, devi, prop_op, flags, name, (caddr_t)&propvalue, &proplength); ddi_release_devi(devi); if ((error == DDI_PROP_SUCCESS) && (proplength == 0)) propvalue = 1; return (propvalue); } /* * e_ddi_getprop_int64: * * This is a typed interfaces, but predates typed properties. With the * introduction of typed properties the framework tries to ensure * consistent use of typed interfaces. This is why TYPE_INT64 is not * part of TYPE_ANY. E_ddi_getprop_int64 is a special case where a * typed interface invokes legacy (non-typed) interfaces: * cdev_prop_op(), prop_op(9E), ddi_prop_op(9F)). In this case the * fact that TYPE_INT64 is not part of TYPE_ANY matters. To support * this type of lookup as a single operation we invoke the legacy * non-typed interfaces with the special CONSUMER_TYPED bit set. The * framework ddi_prop_op(9F) implementation is expected to check for * CONSUMER_TYPED and, if set, expand type bits beyond TYPE_ANY * (currently TYPE_INT64). */ int64_t e_ddi_getprop_int64(dev_t dev, vtype_t type, char *name, int flags, int64_t defvalue) { _NOTE(ARGUNUSED(type)) dev_info_t *devi; ddi_prop_op_t prop_op = PROP_LEN_AND_VAL_BUF; int64_t propvalue = defvalue; int proplength = sizeof (propvalue); int error; if ((devi = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (defvalue); error = cdev_prop_op(dev, devi, prop_op, flags | DDI_PROP_CONSUMER_TYPED, name, (caddr_t)&propvalue, &proplength); ddi_release_devi(devi); if ((error == DDI_PROP_SUCCESS) && (proplength == 0)) propvalue = 1; return (propvalue); } /* * e_ddi_getproplen: See comments for ddi_getproplen. */ int e_ddi_getproplen(dev_t dev, vtype_t type, char *name, int flags, int *lengthp) { _NOTE(ARGUNUSED(type)) dev_info_t *devi; ddi_prop_op_t prop_op = PROP_LEN; int error; if ((devi = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (DDI_PROP_NOT_FOUND); error = cdev_prop_op(dev, devi, prop_op, flags, name, NULL, lengthp); ddi_release_devi(devi); return (error); } /* * Routines to get at elements of the dev_info structure */ /* * ddi_binding_name: Return the driver binding name of the devinfo node * This is the name the OS used to bind the node to a driver. */ char * ddi_binding_name(dev_info_t *dip) { return (DEVI(dip)->devi_binding_name); } /* * ddi_driver_major: Return the major number of the driver that * the supplied devinfo is bound to (-1 if none) */ major_t ddi_driver_major(dev_info_t *devi) { return (DEVI(devi)->devi_major); } /* * ddi_driver_name: Return the normalized driver name. this is the * actual driver name */ const char * ddi_driver_name(dev_info_t *devi) { major_t major; if ((major = ddi_driver_major(devi)) != DDI_MAJOR_T_NONE) return (ddi_major_to_name(major)); return (ddi_node_name(devi)); } /* * i_ddi_set_binding_name: Set binding name. * * Set the binding name to the given name. * This routine is for use by the ddi implementation, not by drivers. */ void i_ddi_set_binding_name(dev_info_t *dip, char *name) { DEVI(dip)->devi_binding_name = name; } /* * ddi_get_name: A synonym of ddi_binding_name() ... returns a name * the implementation has used to bind the node to a driver. */ char * ddi_get_name(dev_info_t *dip) { return (DEVI(dip)->devi_binding_name); } /* * ddi_node_name: Return the name property of the devinfo node * This may differ from ddi_binding_name if the node name * does not define a binding to a driver (i.e. generic names). */ char * ddi_node_name(dev_info_t *dip) { return (DEVI(dip)->devi_node_name); } /* * ddi_get_nodeid: Get nodeid stored in dev_info structure. */ int ddi_get_nodeid(dev_info_t *dip) { return (DEVI(dip)->devi_nodeid); } int ddi_get_instance(dev_info_t *dip) { return (DEVI(dip)->devi_instance); } struct dev_ops * ddi_get_driver(dev_info_t *dip) { return (DEVI(dip)->devi_ops); } void ddi_set_driver(dev_info_t *dip, struct dev_ops *devo) { DEVI(dip)->devi_ops = devo; } /* * ddi_set_driver_private/ddi_get_driver_private: * Get/set device driver private data in devinfo. */ void ddi_set_driver_private(dev_info_t *dip, void *data) { DEVI(dip)->devi_driver_data = data; } void * ddi_get_driver_private(dev_info_t *dip) { return (DEVI(dip)->devi_driver_data); } /* * ddi_get_parent, ddi_get_child, ddi_get_next_sibling */ dev_info_t * ddi_get_parent(dev_info_t *dip) { return ((dev_info_t *)DEVI(dip)->devi_parent); } dev_info_t * ddi_get_child(dev_info_t *dip) { return ((dev_info_t *)DEVI(dip)->devi_child); } dev_info_t * ddi_get_next_sibling(dev_info_t *dip) { return ((dev_info_t *)DEVI(dip)->devi_sibling); } dev_info_t * ddi_get_next(dev_info_t *dip) { return ((dev_info_t *)DEVI(dip)->devi_next); } void ddi_set_next(dev_info_t *dip, dev_info_t *nextdip) { DEVI(dip)->devi_next = DEVI(nextdip); } /* * ddi_root_node: Return root node of devinfo tree */ dev_info_t * ddi_root_node(void) { extern dev_info_t *top_devinfo; return (top_devinfo); } /* * Miscellaneous functions: */ /* * Implementation specific hooks */ void ddi_report_dev(dev_info_t *d) { char *b; (void) ddi_ctlops(d, d, DDI_CTLOPS_REPORTDEV, (void *)0, (void *)0); /* * If this devinfo node has cb_ops, it's implicitly accessible from * userland, so we print its full name together with the instance * number 'abbreviation' that the driver may use internally. */ if (DEVI(d)->devi_ops->devo_cb_ops != (struct cb_ops *)0 && (b = kmem_zalloc(MAXPATHLEN, KM_NOSLEEP))) { cmn_err(CE_CONT, "?%s%d is %s\n", ddi_driver_name(d), ddi_get_instance(d), ddi_pathname(d, b)); kmem_free(b, MAXPATHLEN); } } /* * ddi_ctlops() is described in the assembler not to buy a new register * window when it's called and can reduce cost in climbing the device tree * without using the tail call optimization. */ int ddi_dev_regsize(dev_info_t *dev, uint_t rnumber, off_t *result) { int ret; ret = ddi_ctlops(dev, dev, DDI_CTLOPS_REGSIZE, (void *)&rnumber, (void *)result); return (ret == DDI_SUCCESS ? DDI_SUCCESS : DDI_FAILURE); } int ddi_dev_nregs(dev_info_t *dev, int *result) { return (ddi_ctlops(dev, dev, DDI_CTLOPS_NREGS, 0, (void *)result)); } int ddi_dev_is_sid(dev_info_t *d) { return (ddi_ctlops(d, d, DDI_CTLOPS_SIDDEV, (void *)0, (void *)0)); } int ddi_slaveonly(dev_info_t *d) { return (ddi_ctlops(d, d, DDI_CTLOPS_SLAVEONLY, (void *)0, (void *)0)); } int ddi_dev_affinity(dev_info_t *a, dev_info_t *b) { return (ddi_ctlops(a, a, DDI_CTLOPS_AFFINITY, (void *)b, (void *)0)); } int ddi_streams_driver(dev_info_t *dip) { if (i_ddi_devi_attached(dip) && (DEVI(dip)->devi_ops->devo_cb_ops != NULL) && (DEVI(dip)->devi_ops->devo_cb_ops->cb_str != NULL)) return (DDI_SUCCESS); return (DDI_FAILURE); } /* * callback free list */ static int ncallbacks; static int nc_low = 170; static int nc_med = 512; static int nc_high = 2048; static struct ddi_callback *callbackq; static struct ddi_callback *callbackqfree; /* * set/run callback lists */ struct cbstats { kstat_named_t cb_asked; kstat_named_t cb_new; kstat_named_t cb_run; kstat_named_t cb_delete; kstat_named_t cb_maxreq; kstat_named_t cb_maxlist; kstat_named_t cb_alloc; kstat_named_t cb_runouts; kstat_named_t cb_L2; kstat_named_t cb_grow; } cbstats = { {"asked", KSTAT_DATA_UINT32}, {"new", KSTAT_DATA_UINT32}, {"run", KSTAT_DATA_UINT32}, {"delete", KSTAT_DATA_UINT32}, {"maxreq", KSTAT_DATA_UINT32}, {"maxlist", KSTAT_DATA_UINT32}, {"alloc", KSTAT_DATA_UINT32}, {"runouts", KSTAT_DATA_UINT32}, {"L2", KSTAT_DATA_UINT32}, {"grow", KSTAT_DATA_UINT32}, }; #define nc_asked cb_asked.value.ui32 #define nc_new cb_new.value.ui32 #define nc_run cb_run.value.ui32 #define nc_delete cb_delete.value.ui32 #define nc_maxreq cb_maxreq.value.ui32 #define nc_maxlist cb_maxlist.value.ui32 #define nc_alloc cb_alloc.value.ui32 #define nc_runouts cb_runouts.value.ui32 #define nc_L2 cb_L2.value.ui32 #define nc_grow cb_grow.value.ui32 static kmutex_t ddi_callback_mutex; /* * callbacks are handled using a L1/L2 cache. The L1 cache * comes out of kmem_cache_alloc and can expand/shrink dynamically. If * we can't get callbacks from the L1 cache [because pageout is doing * I/O at the time freemem is 0], we allocate callbacks out of the * L2 cache. The L2 cache is static and depends on the memory size. * [We might also count the number of devices at probe time and * allocate one structure per device and adjust for deferred attach] */ void impl_ddi_callback_init(void) { int i; uint_t physmegs; kstat_t *ksp; physmegs = physmem >> (20 - PAGESHIFT); if (physmegs < 48) { ncallbacks = nc_low; } else if (physmegs < 128) { ncallbacks = nc_med; } else { ncallbacks = nc_high; } /* * init free list */ callbackq = kmem_zalloc( ncallbacks * sizeof (struct ddi_callback), KM_SLEEP); for (i = 0; i < ncallbacks-1; i++) callbackq[i].c_nfree = &callbackq[i+1]; callbackqfree = callbackq; /* init kstats */ if (ksp = kstat_create("unix", 0, "cbstats", "misc", KSTAT_TYPE_NAMED, sizeof (cbstats) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL)) { ksp->ks_data = (void *) &cbstats; kstat_install(ksp); } } static void callback_insert(int (*funcp)(caddr_t), caddr_t arg, uintptr_t *listid, int count) { struct ddi_callback *list, *marker, *new; size_t size = sizeof (struct ddi_callback); list = marker = (struct ddi_callback *)*listid; while (list != NULL) { if (list->c_call == funcp && list->c_arg == arg) { list->c_count += count; return; } marker = list; list = list->c_nlist; } new = kmem_alloc(size, KM_NOSLEEP); if (new == NULL) { new = callbackqfree; if (new == NULL) { new = kmem_alloc_tryhard(sizeof (struct ddi_callback), &size, KM_NOSLEEP | KM_PANIC); cbstats.nc_grow++; } else { callbackqfree = new->c_nfree; cbstats.nc_L2++; } } if (marker != NULL) { marker->c_nlist = new; } else { *listid = (uintptr_t)new; } new->c_size = size; new->c_nlist = NULL; new->c_call = funcp; new->c_arg = arg; new->c_count = count; cbstats.nc_new++; cbstats.nc_alloc++; if (cbstats.nc_alloc > cbstats.nc_maxlist) cbstats.nc_maxlist = cbstats.nc_alloc; } void ddi_set_callback(int (*funcp)(caddr_t), caddr_t arg, uintptr_t *listid) { mutex_enter(&ddi_callback_mutex); cbstats.nc_asked++; if ((cbstats.nc_asked - cbstats.nc_run) > cbstats.nc_maxreq) cbstats.nc_maxreq = (cbstats.nc_asked - cbstats.nc_run); (void) callback_insert(funcp, arg, listid, 1); mutex_exit(&ddi_callback_mutex); } static void real_callback_run(void *Queue) { int (*funcp)(caddr_t); caddr_t arg; int count, rval; uintptr_t *listid; struct ddi_callback *list, *marker; int check_pending = 1; int pending = 0; do { mutex_enter(&ddi_callback_mutex); listid = Queue; list = (struct ddi_callback *)*listid; if (list == NULL) { mutex_exit(&ddi_callback_mutex); return; } if (check_pending) { marker = list; while (marker != NULL) { pending += marker->c_count; marker = marker->c_nlist; } check_pending = 0; } ASSERT(pending > 0); ASSERT(list->c_count > 0); funcp = list->c_call; arg = list->c_arg; count = list->c_count; *(uintptr_t *)Queue = (uintptr_t)list->c_nlist; if (list >= &callbackq[0] && list <= &callbackq[ncallbacks-1]) { list->c_nfree = callbackqfree; callbackqfree = list; } else kmem_free(list, list->c_size); cbstats.nc_delete++; cbstats.nc_alloc--; mutex_exit(&ddi_callback_mutex); do { if ((rval = (*funcp)(arg)) == 0) { pending -= count; mutex_enter(&ddi_callback_mutex); (void) callback_insert(funcp, arg, listid, count); cbstats.nc_runouts++; } else { pending--; mutex_enter(&ddi_callback_mutex); cbstats.nc_run++; } mutex_exit(&ddi_callback_mutex); } while (rval != 0 && (--count > 0)); } while (pending > 0); } void ddi_run_callback(uintptr_t *listid) { softcall(real_callback_run, listid); } /* * ddi_periodic_t * ddi_periodic_add(void (*func)(void *), void *arg, hrtime_t interval, * int level) * * INTERFACE LEVEL * Solaris DDI specific (Solaris DDI) * * PARAMETERS * func: the callback function * * The callback function will be invoked. The function is invoked * in kernel context if the argument level passed is the zero. * Otherwise it's invoked in interrupt context at the specified * level. * * arg: the argument passed to the callback function * * interval: interval time * * level : callback interrupt level * * If the value is the zero, the callback function is invoked * in kernel context. If the value is more than the zero, but * less than or equal to ten, the callback function is invoked in * interrupt context at the specified interrupt level, which may * be used for real time applications. * * This value must be in range of 0-10, which can be a numeric * number or a pre-defined macro (DDI_IPL_0, ... , DDI_IPL_10). * * DESCRIPTION * ddi_periodic_add(9F) schedules the specified function to be * periodically invoked in the interval time. * * As well as timeout(9F), the exact time interval over which the function * takes effect cannot be guaranteed, but the value given is a close * approximation. * * Drivers waiting on behalf of processes with real-time constraints must * pass non-zero value with the level argument to ddi_periodic_add(9F). * * RETURN VALUES * ddi_periodic_add(9F) returns a non-zero opaque value (ddi_periodic_t), * which must be used for ddi_periodic_delete(9F) to specify the request. * * CONTEXT * ddi_periodic_add(9F) can be called in user or kernel context, but * it cannot be called in interrupt context, which is different from * timeout(9F). */ ddi_periodic_t ddi_periodic_add(void (*func)(void *), void *arg, hrtime_t interval, int level) { /* * Sanity check of the argument level. */ if (level < DDI_IPL_0 || level > DDI_IPL_10) cmn_err(CE_PANIC, "ddi_periodic_add: invalid interrupt level (%d).", level); /* * Sanity check of the context. ddi_periodic_add() cannot be * called in either interrupt context or high interrupt context. */ if (servicing_interrupt()) cmn_err(CE_PANIC, "ddi_periodic_add: called in (high) interrupt context."); return ((ddi_periodic_t)i_timeout(func, arg, interval, level)); } /* * void * ddi_periodic_delete(ddi_periodic_t req) * * INTERFACE LEVEL * Solaris DDI specific (Solaris DDI) * * PARAMETERS * req: ddi_periodic_t opaque value ddi_periodic_add(9F) returned * previously. * * DESCRIPTION * ddi_periodic_delete(9F) cancels the ddi_periodic_add(9F) request * previously requested. * * ddi_periodic_delete(9F) will not return until the pending request * is canceled or executed. * * As well as untimeout(9F), calling ddi_periodic_delete(9F) for a * timeout which is either running on another CPU, or has already * completed causes no problems. However, unlike untimeout(9F), there is * no restrictions on the lock which might be held across the call to * ddi_periodic_delete(9F). * * Drivers should be structured with the understanding that the arrival of * both an interrupt and a timeout for that interrupt can occasionally * occur, in either order. * * CONTEXT * ddi_periodic_delete(9F) can be called in user or kernel context, but * it cannot be called in interrupt context, which is different from * untimeout(9F). */ void ddi_periodic_delete(ddi_periodic_t req) { /* * Sanity check of the context. ddi_periodic_delete() cannot be * called in either interrupt context or high interrupt context. */ if (servicing_interrupt()) cmn_err(CE_PANIC, "ddi_periodic_delete: called in (high) interrupt context."); i_untimeout((timeout_t)req); } dev_info_t * nodevinfo(dev_t dev, int otyp) { _NOTE(ARGUNUSED(dev, otyp)) return ((dev_info_t *)0); } /* * A driver should support its own getinfo(9E) entry point. This function * is provided as a convenience for ON drivers that don't expect their * getinfo(9E) entry point to be called. A driver that uses this must not * call ddi_create_minor_node. */ int ddi_no_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { _NOTE(ARGUNUSED(dip, infocmd, arg, result)) return (DDI_FAILURE); } /* * A driver should support its own getinfo(9E) entry point. This function * is provided as a convenience for ON drivers that where the minor number * is the instance. Drivers that do not have 1:1 mapping must implement * their own getinfo(9E) function. */ int ddi_getinfo_1to1(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { _NOTE(ARGUNUSED(dip)) int instance; if (infocmd != DDI_INFO_DEVT2INSTANCE) return (DDI_FAILURE); instance = getminor((dev_t)(uintptr_t)arg); *result = (void *)(uintptr_t)instance; return (DDI_SUCCESS); } int ddifail(dev_info_t *devi, ddi_attach_cmd_t cmd) { _NOTE(ARGUNUSED(devi, cmd)) return (DDI_FAILURE); } int ddi_no_dma_map(dev_info_t *dip, dev_info_t *rdip, struct ddi_dma_req *dmareqp, ddi_dma_handle_t *handlep) { _NOTE(ARGUNUSED(dip, rdip, dmareqp, handlep)) return (DDI_DMA_NOMAPPING); } int ddi_no_dma_allochdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_attr_t *attr, int (*waitfp)(caddr_t), caddr_t arg, ddi_dma_handle_t *handlep) { _NOTE(ARGUNUSED(dip, rdip, attr, waitfp, arg, handlep)) return (DDI_DMA_BADATTR); } int ddi_no_dma_freehdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle) { _NOTE(ARGUNUSED(dip, rdip, handle)) return (DDI_FAILURE); } int ddi_no_dma_bindhdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, struct ddi_dma_req *dmareq, ddi_dma_cookie_t *cp, uint_t *ccountp) { _NOTE(ARGUNUSED(dip, rdip, handle, dmareq, cp, ccountp)) return (DDI_DMA_NOMAPPING); } int ddi_no_dma_unbindhdl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle) { _NOTE(ARGUNUSED(dip, rdip, handle)) return (DDI_FAILURE); } int ddi_no_dma_flush(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, off_t off, size_t len, uint_t cache_flags) { _NOTE(ARGUNUSED(dip, rdip, handle, off, len, cache_flags)) return (DDI_FAILURE); } int ddi_no_dma_win(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, uint_t win, off_t *offp, size_t *lenp, ddi_dma_cookie_t *cookiep, uint_t *ccountp) { _NOTE(ARGUNUSED(dip, rdip, handle, win, offp, lenp, cookiep, ccountp)) return (DDI_FAILURE); } int ddi_no_dma_mctl(dev_info_t *dip, dev_info_t *rdip, ddi_dma_handle_t handle, enum ddi_dma_ctlops request, off_t *offp, size_t *lenp, caddr_t *objp, uint_t flags) { _NOTE(ARGUNUSED(dip, rdip, handle, request, offp, lenp, objp, flags)) return (DDI_FAILURE); } void ddivoid(void) {} int nochpoll(dev_t dev, short events, int anyyet, short *reventsp, struct pollhead **pollhdrp) { _NOTE(ARGUNUSED(dev, events, anyyet, reventsp, pollhdrp)) return (ENXIO); } cred_t * ddi_get_cred(void) { return (CRED()); } clock_t ddi_get_lbolt(void) { return (lbolt); } time_t ddi_get_time(void) { time_t now; if ((now = gethrestime_sec()) == 0) { timestruc_t ts; mutex_enter(&tod_lock); ts = tod_get(); mutex_exit(&tod_lock); return (ts.tv_sec); } else { return (now); } } pid_t ddi_get_pid(void) { return (ttoproc(curthread)->p_pid); } kt_did_t ddi_get_kt_did(void) { return (curthread->t_did); } /* * This function returns B_TRUE if the caller can reasonably expect that a call * to cv_wait_sig(9F), cv_timedwait_sig(9F), or qwait_sig(9F) could be awakened * by user-level signal. If it returns B_FALSE, then the caller should use * other means to make certain that the wait will not hang "forever." * * It does not check the signal mask, nor for reception of any particular * signal. * * Currently, a thread can receive a signal if it's not a kernel thread and it * is not in the middle of exit(2) tear-down. Threads that are in that * tear-down effectively convert cv_wait_sig to cv_wait, cv_timedwait_sig to * cv_timedwait, and qwait_sig to qwait. */ boolean_t ddi_can_receive_sig(void) { proc_t *pp; if (curthread->t_proc_flag & TP_LWPEXIT) return (B_FALSE); if ((pp = ttoproc(curthread)) == NULL) return (B_FALSE); return (pp->p_as != &kas); } /* * Swap bytes in 16-bit [half-]words */ void swab(void *src, void *dst, size_t nbytes) { uchar_t *pf = (uchar_t *)src; uchar_t *pt = (uchar_t *)dst; uchar_t tmp; int nshorts; nshorts = nbytes >> 1; while (--nshorts >= 0) { tmp = *pf++; *pt++ = *pf++; *pt++ = tmp; } } static void ddi_append_minor_node(dev_info_t *ddip, struct ddi_minor_data *dmdp) { struct ddi_minor_data *dp; mutex_enter(&(DEVI(ddip)->devi_lock)); i_devi_enter(ddip, DEVI_S_MD_UPDATE, DEVI_S_MD_UPDATE, 1); if ((dp = DEVI(ddip)->devi_minor) == (struct ddi_minor_data *)NULL) { DEVI(ddip)->devi_minor = dmdp; } else { while (dp->next != (struct ddi_minor_data *)NULL) dp = dp->next; dp->next = dmdp; } i_devi_exit(ddip, DEVI_S_MD_UPDATE, 1); mutex_exit(&(DEVI(ddip)->devi_lock)); } /* * Part of the obsolete SunCluster DDI Hooks. * Keep for binary compatibility */ minor_t ddi_getiminor(dev_t dev) { return (getminor(dev)); } static int i_log_devfs_minor_create(dev_info_t *dip, char *minor_name) { int se_flag; int kmem_flag; int se_err; char *pathname, *class_name; sysevent_t *ev = NULL; sysevent_id_t eid; sysevent_value_t se_val; sysevent_attr_list_t *ev_attr_list = NULL; /* determine interrupt context */ se_flag = (servicing_interrupt()) ? SE_NOSLEEP : SE_SLEEP; kmem_flag = (se_flag == SE_SLEEP) ? KM_SLEEP : KM_NOSLEEP; i_ddi_di_cache_invalidate(kmem_flag); #ifdef DEBUG if ((se_flag == SE_NOSLEEP) && sunddi_debug) { cmn_err(CE_CONT, "ddi_create_minor_node: called from " "interrupt level by driver %s", ddi_driver_name(dip)); } #endif /* DEBUG */ ev = sysevent_alloc(EC_DEVFS, ESC_DEVFS_MINOR_CREATE, EP_DDI, se_flag); if (ev == NULL) { goto fail; } pathname = kmem_alloc(MAXPATHLEN, kmem_flag); if (pathname == NULL) { sysevent_free(ev); goto fail; } (void) ddi_pathname(dip, pathname); ASSERT(strlen(pathname)); se_val.value_type = SE_DATA_TYPE_STRING; se_val.value.sv_string = pathname; if (sysevent_add_attr(&ev_attr_list, DEVFS_PATHNAME, &se_val, se_flag) != 0) { kmem_free(pathname, MAXPATHLEN); sysevent_free(ev); goto fail; } kmem_free(pathname, MAXPATHLEN); /* add the device class attribute */ if ((class_name = i_ddi_devi_class(dip)) != NULL) { se_val.value_type = SE_DATA_TYPE_STRING; se_val.value.sv_string = class_name; if (sysevent_add_attr(&ev_attr_list, DEVFS_DEVI_CLASS, &se_val, SE_SLEEP) != 0) { sysevent_free_attr(ev_attr_list); goto fail; } } /* * allow for NULL minor names */ if (minor_name != NULL) { se_val.value.sv_string = minor_name; if (sysevent_add_attr(&ev_attr_list, DEVFS_MINOR_NAME, &se_val, se_flag) != 0) { sysevent_free_attr(ev_attr_list); sysevent_free(ev); goto fail; } } if (sysevent_attach_attributes(ev, ev_attr_list) != 0) { sysevent_free_attr(ev_attr_list); sysevent_free(ev); goto fail; } if ((se_err = log_sysevent(ev, se_flag, &eid)) != 0) { if (se_err == SE_NO_TRANSPORT) { cmn_err(CE_WARN, "/devices or /dev may not be current " "for driver %s (%s). Run devfsadm -i %s", ddi_driver_name(dip), "syseventd not responding", ddi_driver_name(dip)); } else { sysevent_free(ev); goto fail; } } sysevent_free(ev); return (DDI_SUCCESS); fail: cmn_err(CE_WARN, "/devices or /dev may not be current " "for driver %s. Run devfsadm -i %s", ddi_driver_name(dip), ddi_driver_name(dip)); return (DDI_SUCCESS); } /* * failing to remove a minor node is not of interest * therefore we do not generate an error message */ static int i_log_devfs_minor_remove(dev_info_t *dip, char *minor_name) { char *pathname, *class_name; sysevent_t *ev; sysevent_id_t eid; sysevent_value_t se_val; sysevent_attr_list_t *ev_attr_list = NULL; /* * only log ddi_remove_minor_node() calls outside the scope * of attach/detach reconfigurations and when the dip is * still initialized. */ if (DEVI_IS_ATTACHING(dip) || DEVI_IS_DETACHING(dip) || (i_ddi_node_state(dip) < DS_INITIALIZED)) { return (DDI_SUCCESS); } i_ddi_di_cache_invalidate(KM_SLEEP); ev = sysevent_alloc(EC_DEVFS, ESC_DEVFS_MINOR_REMOVE, EP_DDI, SE_SLEEP); if (ev == NULL) { return (DDI_SUCCESS); } pathname = kmem_alloc(MAXPATHLEN, KM_SLEEP); if (pathname == NULL) { sysevent_free(ev); return (DDI_SUCCESS); } (void) ddi_pathname(dip, pathname); ASSERT(strlen(pathname)); se_val.value_type = SE_DATA_TYPE_STRING; se_val.value.sv_string = pathname; if (sysevent_add_attr(&ev_attr_list, DEVFS_PATHNAME, &se_val, SE_SLEEP) != 0) { kmem_free(pathname, MAXPATHLEN); sysevent_free(ev); return (DDI_SUCCESS); } kmem_free(pathname, MAXPATHLEN); /* * allow for NULL minor names */ if (minor_name != NULL) { se_val.value.sv_string = minor_name; if (sysevent_add_attr(&ev_attr_list, DEVFS_MINOR_NAME, &se_val, SE_SLEEP) != 0) { sysevent_free_attr(ev_attr_list); goto fail; } } if ((class_name = i_ddi_devi_class(dip)) != NULL) { /* add the device class, driver name and instance attributes */ se_val.value_type = SE_DATA_TYPE_STRING; se_val.value.sv_string = class_name; if (sysevent_add_attr(&ev_attr_list, DEVFS_DEVI_CLASS, &se_val, SE_SLEEP) != 0) { sysevent_free_attr(ev_attr_list); goto fail; } se_val.value_type = SE_DATA_TYPE_STRING; se_val.value.sv_string = (char *)ddi_driver_name(dip); if (sysevent_add_attr(&ev_attr_list, DEVFS_DRIVER_NAME, &se_val, SE_SLEEP) != 0) { sysevent_free_attr(ev_attr_list); goto fail; } se_val.value_type = SE_DATA_TYPE_INT32; se_val.value.sv_int32 = ddi_get_instance(dip); if (sysevent_add_attr(&ev_attr_list, DEVFS_INSTANCE, &se_val, SE_SLEEP) != 0) { sysevent_free_attr(ev_attr_list); goto fail; } } if (sysevent_attach_attributes(ev, ev_attr_list) != 0) { sysevent_free_attr(ev_attr_list); } else { (void) log_sysevent(ev, SE_SLEEP, &eid); } fail: sysevent_free(ev); return (DDI_SUCCESS); } /* * Derive the device class of the node. * Device class names aren't defined yet. Until this is done we use * devfs event subclass names as device class names. */ static int derive_devi_class(dev_info_t *dip, char *node_type, int flag) { int rv = DDI_SUCCESS; if (i_ddi_devi_class(dip) == NULL) { if (strncmp(node_type, DDI_NT_BLOCK, sizeof (DDI_NT_BLOCK) - 1) == 0 && (node_type[sizeof (DDI_NT_BLOCK) - 1] == '\0' || node_type[sizeof (DDI_NT_BLOCK) - 1] == ':') && strcmp(node_type, DDI_NT_FD) != 0) { rv = i_ddi_set_devi_class(dip, ESC_DISK, flag); } else if (strncmp(node_type, DDI_NT_NET, sizeof (DDI_NT_NET) - 1) == 0 && (node_type[sizeof (DDI_NT_NET) - 1] == '\0' || node_type[sizeof (DDI_NT_NET) - 1] == ':')) { rv = i_ddi_set_devi_class(dip, ESC_NETWORK, flag); } else if (strncmp(node_type, DDI_NT_PRINTER, sizeof (DDI_NT_PRINTER) - 1) == 0 && (node_type[sizeof (DDI_NT_PRINTER) - 1] == '\0' || node_type[sizeof (DDI_NT_PRINTER) - 1] == ':')) { rv = i_ddi_set_devi_class(dip, ESC_PRINTER, flag); } else if (strncmp(node_type, DDI_PSEUDO, sizeof (DDI_PSEUDO) -1) == 0 && (strncmp(ESC_LOFI, ddi_node_name(dip), sizeof (ESC_LOFI) -1) == 0)) { rv = i_ddi_set_devi_class(dip, ESC_LOFI, flag); } } return (rv); } /* * Check compliance with PSARC 2003/375: * * The name must contain only characters a-z, A-Z, 0-9 or _ and it must not * exceed IFNAMSIZ (16) characters in length. */ static boolean_t verify_name(char *name) { size_t len = strlen(name); char *cp; if (len == 0 || len > IFNAMSIZ) return (B_FALSE); for (cp = name; *cp != '\0'; cp++) { if (!isalnum(*cp) && *cp != '_') return (B_FALSE); } return (B_TRUE); } /* * ddi_create_minor_common: Create a ddi_minor_data structure and * attach it to the given devinfo node. */ int ddi_create_minor_common(dev_info_t *dip, char *name, int spec_type, minor_t minor_num, char *node_type, int flag, ddi_minor_type mtype, const char *read_priv, const char *write_priv, mode_t priv_mode) { struct ddi_minor_data *dmdp; major_t major; if (spec_type != S_IFCHR && spec_type != S_IFBLK) return (DDI_FAILURE); if (name == NULL) return (DDI_FAILURE); /* * Log a message if the minor number the driver is creating * is not expressible on the on-disk filesystem (currently * this is limited to 18 bits both by UFS). The device can * be opened via devfs, but not by device special files created * via mknod(). */ if (minor_num > L_MAXMIN32) { cmn_err(CE_WARN, "%s%d:%s minor 0x%x too big for 32-bit applications", ddi_driver_name(dip), ddi_get_instance(dip), name, minor_num); return (DDI_FAILURE); } /* dip must be bound and attached */ major = ddi_driver_major(dip); ASSERT(major != DDI_MAJOR_T_NONE); /* * Default node_type to DDI_PSEUDO and issue notice in debug mode */ if (node_type == NULL) { node_type = DDI_PSEUDO; NDI_CONFIG_DEBUG((CE_NOTE, "!illegal node_type NULL for %s%d " " minor node %s; default to DDI_PSEUDO", ddi_driver_name(dip), ddi_get_instance(dip), name)); } /* * If the driver is a network driver, ensure that the name falls within * the interface naming constraints specified by PSARC/2003/375. */ if (strcmp(node_type, DDI_NT_NET) == 0) { if (!verify_name(name)) return (DDI_FAILURE); if (mtype == DDM_MINOR) { struct devnames *dnp = &devnamesp[major]; /* Mark driver as a network driver */ LOCK_DEV_OPS(&dnp->dn_lock); dnp->dn_flags |= DN_NETWORK_DRIVER; UNLOCK_DEV_OPS(&dnp->dn_lock); } } if (mtype == DDM_MINOR) { if (derive_devi_class(dip, node_type, KM_NOSLEEP) != DDI_SUCCESS) return (DDI_FAILURE); } /* * Take care of minor number information for the node. */ if ((dmdp = kmem_zalloc(sizeof (struct ddi_minor_data), KM_NOSLEEP)) == NULL) { return (DDI_FAILURE); } if ((dmdp->ddm_name = i_ddi_strdup(name, KM_NOSLEEP)) == NULL) { kmem_free(dmdp, sizeof (struct ddi_minor_data)); return (DDI_FAILURE); } dmdp->dip = dip; dmdp->ddm_dev = makedevice(major, minor_num); dmdp->ddm_spec_type = spec_type; dmdp->ddm_node_type = node_type; dmdp->type = mtype; if (flag & CLONE_DEV) { dmdp->type = DDM_ALIAS; dmdp->ddm_dev = makedevice(ddi_driver_major(clone_dip), major); } if (flag & PRIVONLY_DEV) { dmdp->ddm_flags |= DM_NO_FSPERM; } if (read_priv || write_priv) { dmdp->ddm_node_priv = devpolicy_priv_by_name(read_priv, write_priv); } dmdp->ddm_priv_mode = priv_mode; ddi_append_minor_node(dip, dmdp); /* * only log ddi_create_minor_node() calls which occur * outside the scope of attach(9e)/detach(9e) reconfigurations */ if (!(DEVI_IS_ATTACHING(dip) || DEVI_IS_DETACHING(dip)) && mtype != DDM_INTERNAL_PATH) { (void) i_log_devfs_minor_create(dip, name); } /* * Check if any dacf rules match the creation of this minor node */ dacfc_match_create_minor(name, node_type, dip, dmdp, flag); return (DDI_SUCCESS); } int ddi_create_minor_node(dev_info_t *dip, char *name, int spec_type, minor_t minor_num, char *node_type, int flag) { return (ddi_create_minor_common(dip, name, spec_type, minor_num, node_type, flag, DDM_MINOR, NULL, NULL, 0)); } int ddi_create_priv_minor_node(dev_info_t *dip, char *name, int spec_type, minor_t minor_num, char *node_type, int flag, const char *rdpriv, const char *wrpriv, mode_t priv_mode) { return (ddi_create_minor_common(dip, name, spec_type, minor_num, node_type, flag, DDM_MINOR, rdpriv, wrpriv, priv_mode)); } int ddi_create_default_minor_node(dev_info_t *dip, char *name, int spec_type, minor_t minor_num, char *node_type, int flag) { return (ddi_create_minor_common(dip, name, spec_type, minor_num, node_type, flag, DDM_DEFAULT, NULL, NULL, 0)); } /* * Internal (non-ddi) routine for drivers to export names known * to the kernel (especially ddi_pathname_to_dev_t and friends) * but not exported externally to /dev */ int ddi_create_internal_pathname(dev_info_t *dip, char *name, int spec_type, minor_t minor_num) { return (ddi_create_minor_common(dip, name, spec_type, minor_num, "internal", 0, DDM_INTERNAL_PATH, NULL, NULL, 0)); } void ddi_remove_minor_node(dev_info_t *dip, char *name) { struct ddi_minor_data *dmdp, *dmdp1; struct ddi_minor_data **dmdp_prev; mutex_enter(&(DEVI(dip)->devi_lock)); i_devi_enter(dip, DEVI_S_MD_UPDATE, DEVI_S_MD_UPDATE, 1); dmdp_prev = &DEVI(dip)->devi_minor; dmdp = DEVI(dip)->devi_minor; while (dmdp != NULL) { dmdp1 = dmdp->next; if ((name == NULL || (dmdp->ddm_name != NULL && strcmp(name, dmdp->ddm_name) == 0))) { if (dmdp->ddm_name != NULL) { if (dmdp->type != DDM_INTERNAL_PATH) (void) i_log_devfs_minor_remove(dip, dmdp->ddm_name); kmem_free(dmdp->ddm_name, strlen(dmdp->ddm_name) + 1); } /* * Release device privilege, if any. * Release dacf client data associated with this minor * node by storing NULL. */ if (dmdp->ddm_node_priv) dpfree(dmdp->ddm_node_priv); dacf_store_info((dacf_infohdl_t)dmdp, NULL); kmem_free(dmdp, sizeof (struct ddi_minor_data)); *dmdp_prev = dmdp1; /* * OK, we found it, so get out now -- if we drive on, * we will strcmp against garbage. See 1139209. */ if (name != NULL) break; } else { dmdp_prev = &dmdp->next; } dmdp = dmdp1; } i_devi_exit(dip, DEVI_S_MD_UPDATE, 1); mutex_exit(&(DEVI(dip)->devi_lock)); } int ddi_in_panic() { return (panicstr != NULL); } /* * Find first bit set in a mask (returned counting from 1 up) */ int ddi_ffs(long mask) { return (ffs(mask)); } /* * Find last bit set. Take mask and clear * all but the most significant bit, and * then let ffs do the rest of the work. * * Algorithm courtesy of Steve Chessin. */ int ddi_fls(long mask) { while (mask) { long nx; if ((nx = (mask & (mask - 1))) == 0) break; mask = nx; } return (ffs(mask)); } /* * The next five routines comprise generic storage management utilities * for driver soft state structures (in "the old days," this was done * with a statically sized array - big systems and dynamic loading * and unloading make heap allocation more attractive) */ /* * Allocate a set of pointers to 'n_items' objects of size 'size' * bytes. Each pointer is initialized to nil. * * The 'size' and 'n_items' values are stashed in the opaque * handle returned to the caller. * * This implementation interprets 'set of pointers' to mean 'array * of pointers' but note that nothing in the interface definition * precludes an implementation that uses, for example, a linked list. * However there should be a small efficiency gain from using an array * at lookup time. * * NOTE As an optimization, we make our growable array allocations in * powers of two (bytes), since that's how much kmem_alloc (currently) * gives us anyway. It should save us some free/realloc's .. * * As a further optimization, we make the growable array start out * with MIN_N_ITEMS in it. */ #define MIN_N_ITEMS 8 /* 8 void *'s == 32 bytes */ int ddi_soft_state_init(void **state_p, size_t size, size_t n_items) { struct i_ddi_soft_state *ss; if (state_p == NULL || *state_p != NULL || size == 0) return (EINVAL); ss = kmem_zalloc(sizeof (*ss), KM_SLEEP); mutex_init(&ss->lock, NULL, MUTEX_DRIVER, NULL); ss->size = size; if (n_items < MIN_N_ITEMS) ss->n_items = MIN_N_ITEMS; else { int bitlog; if ((bitlog = ddi_fls(n_items)) == ddi_ffs(n_items)) bitlog--; ss->n_items = 1 << bitlog; } ASSERT(ss->n_items >= n_items); ss->array = kmem_zalloc(ss->n_items * sizeof (void *), KM_SLEEP); *state_p = ss; return (0); } /* * Allocate a state structure of size 'size' to be associated * with item 'item'. * * In this implementation, the array is extended to * allow the requested offset, if needed. */ int ddi_soft_state_zalloc(void *state, int item) { struct i_ddi_soft_state *ss; void **array; void *new_element; if ((ss = state) == NULL || item < 0) return (DDI_FAILURE); mutex_enter(&ss->lock); if (ss->size == 0) { mutex_exit(&ss->lock); cmn_err(CE_WARN, "ddi_soft_state_zalloc: bad handle: %s", mod_containing_pc(caller())); return (DDI_FAILURE); } array = ss->array; /* NULL if ss->n_items == 0 */ ASSERT(ss->n_items != 0 && array != NULL); /* * refuse to tread on an existing element */ if (item < ss->n_items && array[item] != NULL) { mutex_exit(&ss->lock); return (DDI_FAILURE); } /* * Allocate a new element to plug in */ new_element = kmem_zalloc(ss->size, KM_SLEEP); /* * Check if the array is big enough, if not, grow it. */ if (item >= ss->n_items) { void **new_array; size_t new_n_items; struct i_ddi_soft_state *dirty; /* * Allocate a new array of the right length, copy * all the old pointers to the new array, then * if it exists at all, put the old array on the * dirty list. * * Note that we can't kmem_free() the old array. * * Why -- well the 'get' operation is 'mutex-free', so we * can't easily catch a suspended thread that is just about * to dereference the array we just grew out of. So we * cons up a header and put it on a list of 'dirty' * pointer arrays. (Dirty in the sense that there may * be suspended threads somewhere that are in the middle * of referencing them). Fortunately, we -can- garbage * collect it all at ddi_soft_state_fini time. */ new_n_items = ss->n_items; while (new_n_items < (1 + item)) new_n_items <<= 1; /* double array size .. */ ASSERT(new_n_items >= (1 + item)); /* sanity check! */ new_array = kmem_zalloc(new_n_items * sizeof (void *), KM_SLEEP); /* * Copy the pointers into the new array */ bcopy(array, new_array, ss->n_items * sizeof (void *)); /* * Save the old array on the dirty list */ dirty = kmem_zalloc(sizeof (*dirty), KM_SLEEP); dirty->array = ss->array; dirty->n_items = ss->n_items; dirty->next = ss->next; ss->next = dirty; ss->array = (array = new_array); ss->n_items = new_n_items; } ASSERT(array != NULL && item < ss->n_items && array[item] == NULL); array[item] = new_element; mutex_exit(&ss->lock); return (DDI_SUCCESS); } /* * Fetch a pointer to the allocated soft state structure. * * This is designed to be cheap. * * There's an argument that there should be more checking for * nil pointers and out of bounds on the array.. but we do a lot * of that in the alloc/free routines. * * An array has the convenience that we don't need to lock read-access * to it c.f. a linked list. However our "expanding array" strategy * means that we should hold a readers lock on the i_ddi_soft_state * structure. * * However, from a performance viewpoint, we need to do it without * any locks at all -- this also makes it a leaf routine. The algorithm * is 'lock-free' because we only discard the pointer arrays at * ddi_soft_state_fini() time. */ void * ddi_get_soft_state(void *state, int item) { struct i_ddi_soft_state *ss = state; ASSERT(ss != NULL && item >= 0); if (item < ss->n_items && ss->array != NULL) return (ss->array[item]); return (NULL); } /* * Free the state structure corresponding to 'item.' Freeing an * element that has either gone or was never allocated is not * considered an error. Note that we free the state structure, but * we don't shrink our pointer array, or discard 'dirty' arrays, * since even a few pointers don't really waste too much memory. * * Passing an item number that is out of bounds, or a null pointer will * provoke an error message. */ void ddi_soft_state_free(void *state, int item) { struct i_ddi_soft_state *ss; void **array; void *element; static char msg[] = "ddi_soft_state_free:"; if ((ss = state) == NULL) { cmn_err(CE_WARN, "%s null handle: %s", msg, mod_containing_pc(caller())); return; } element = NULL; mutex_enter(&ss->lock); if ((array = ss->array) == NULL || ss->size == 0) { cmn_err(CE_WARN, "%s bad handle: %s", msg, mod_containing_pc(caller())); } else if (item < 0 || item >= ss->n_items) { cmn_err(CE_WARN, "%s item %d not in range [0..%lu]: %s", msg, item, ss->n_items - 1, mod_containing_pc(caller())); } else if (array[item] != NULL) { element = array[item]; array[item] = NULL; } mutex_exit(&ss->lock); if (element) kmem_free(element, ss->size); } /* * Free the entire set of pointers, and any * soft state structures contained therein. * * Note that we don't grab the ss->lock mutex, even though * we're inspecting the various fields of the data structure. * * There is an implicit assumption that this routine will * never run concurrently with any of the above on this * particular state structure i.e. by the time the driver * calls this routine, there should be no other threads * running in the driver. */ void ddi_soft_state_fini(void **state_p) { struct i_ddi_soft_state *ss, *dirty; int item; static char msg[] = "ddi_soft_state_fini:"; if (state_p == NULL || (ss = *state_p) == NULL) { cmn_err(CE_WARN, "%s null handle: %s", msg, mod_containing_pc(caller())); return; } if (ss->size == 0) { cmn_err(CE_WARN, "%s bad handle: %s", msg, mod_containing_pc(caller())); return; } if (ss->n_items > 0) { for (item = 0; item < ss->n_items; item++) ddi_soft_state_free(ss, item); kmem_free(ss->array, ss->n_items * sizeof (void *)); } /* * Now delete any dirty arrays from previous 'grow' operations */ for (dirty = ss->next; dirty; dirty = ss->next) { ss->next = dirty->next; kmem_free(dirty->array, dirty->n_items * sizeof (void *)); kmem_free(dirty, sizeof (*dirty)); } mutex_destroy(&ss->lock); kmem_free(ss, sizeof (*ss)); *state_p = NULL; } /* * This sets the devi_addr entry in the dev_info structure 'dip' to 'name'. * Storage is double buffered to prevent updates during devi_addr use - * double buffering is adaquate for reliable ddi_deviname() consumption. * The double buffer is not freed until dev_info structure destruction * (by i_ddi_free_node). */ void ddi_set_name_addr(dev_info_t *dip, char *name) { char *buf = DEVI(dip)->devi_addr_buf; char *newaddr; if (buf == NULL) { buf = kmem_zalloc(2 * MAXNAMELEN, KM_SLEEP); DEVI(dip)->devi_addr_buf = buf; } if (name) { ASSERT(strlen(name) < MAXNAMELEN); newaddr = (DEVI(dip)->devi_addr == buf) ? (buf + MAXNAMELEN) : buf; (void) strlcpy(newaddr, name, MAXNAMELEN); } else newaddr = NULL; DEVI(dip)->devi_addr = newaddr; } char * ddi_get_name_addr(dev_info_t *dip) { return (DEVI(dip)->devi_addr); } void ddi_set_parent_data(dev_info_t *dip, void *pd) { DEVI(dip)->devi_parent_data = pd; } void * ddi_get_parent_data(dev_info_t *dip) { return (DEVI(dip)->devi_parent_data); } /* * ddi_name_to_major: Returns the major number of a module given its name. */ major_t ddi_name_to_major(char *name) { return (mod_name_to_major(name)); } /* * ddi_major_to_name: Returns the module name bound to a major number. */ char * ddi_major_to_name(major_t major) { return (mod_major_to_name(major)); } /* * Return the name of the devinfo node pointed at by 'dip' in the buffer * pointed at by 'name.' A devinfo node is named as a result of calling * ddi_initchild(). * * Note: the driver must be held before calling this function! */ char * ddi_deviname(dev_info_t *dip, char *name) { char *addrname; char none = '\0'; if (dip == ddi_root_node()) { *name = '\0'; return (name); } if (i_ddi_node_state(dip) < DS_BOUND) { addrname = &none; } else { /* * Use ddi_get_name_addr() without checking state so we get * a unit-address if we are called after ddi_set_name_addr() * by nexus DDI_CTL_INITCHILD code, but before completing * node promotion to DS_INITIALIZED. We currently have * two situations where we are called in this state: * o For framework processing of a path-oriented alias. * o If a SCSA nexus driver calls ddi_devid_register() * from it's tran_tgt_init(9E) implementation. */ addrname = ddi_get_name_addr(dip); if (addrname == NULL) addrname = &none; } if (*addrname == '\0') { (void) sprintf(name, "/%s", ddi_node_name(dip)); } else { (void) sprintf(name, "/%s@%s", ddi_node_name(dip), addrname); } return (name); } /* * Spits out the name of device node, typically name@addr, for a given node, * using the driver name, not the nodename. * * Used by match_parent. Not to be used elsewhere. */ char * i_ddi_parname(dev_info_t *dip, char *name) { char *addrname; if (dip == ddi_root_node()) { *name = '\0'; return (name); } ASSERT(i_ddi_node_state(dip) >= DS_INITIALIZED); if (*(addrname = ddi_get_name_addr(dip)) == '\0') (void) sprintf(name, "%s", ddi_binding_name(dip)); else (void) sprintf(name, "%s@%s", ddi_binding_name(dip), addrname); return (name); } static char * pathname_work(dev_info_t *dip, char *path) { char *bp; if (dip == ddi_root_node()) { *path = '\0'; return (path); } (void) pathname_work(ddi_get_parent(dip), path); bp = path + strlen(path); (void) ddi_deviname(dip, bp); return (path); } char * ddi_pathname(dev_info_t *dip, char *path) { return (pathname_work(dip, path)); } /* * Given a dev_t, return the pathname of the corresponding device in the * buffer pointed at by "path." The buffer is assumed to be large enough * to hold the pathname of the device (MAXPATHLEN). * * The pathname of a device is the pathname of the devinfo node to which * the device "belongs," concatenated with the character ':' and the name * of the minor node corresponding to the dev_t. If spec_type is 0 then * just the pathname of the devinfo node is returned without driving attach * of that node. For a non-zero spec_type, an attach is performed and a * search of the minor list occurs. * * It is possible that the path associated with the dev_t is not * currently available in the devinfo tree. In order to have a * dev_t, a device must have been discovered before, which means * that the path is always in the instance tree. The one exception * to this is if the dev_t is associated with a pseudo driver, in * which case the device must exist on the pseudo branch of the * devinfo tree as a result of parsing .conf files. */ int ddi_dev_pathname(dev_t devt, int spec_type, char *path) { major_t major = getmajor(devt); int instance; dev_info_t *dip; char *minorname; char *drvname; if (major >= devcnt) goto fail; if (major == clone_major) { /* clone has no minor nodes, manufacture the path here */ if ((drvname = ddi_major_to_name(getminor(devt))) == NULL) goto fail; (void) snprintf(path, MAXPATHLEN, "%s:%s", CLONE_PATH, drvname); return (DDI_SUCCESS); } /* extract instance from devt (getinfo(9E) DDI_INFO_DEVT2INSTANCE). */ if ((instance = dev_to_instance(devt)) == -1) goto fail; /* reconstruct the path given the major/instance */ if (e_ddi_majorinstance_to_path(major, instance, path) != DDI_SUCCESS) goto fail; /* if spec_type given we must drive attach and search minor nodes */ if ((spec_type == S_IFCHR) || (spec_type == S_IFBLK)) { /* attach the path so we can search minors */ if ((dip = e_ddi_hold_devi_by_path(path, 0)) == NULL) goto fail; /* Add minorname to path. */ mutex_enter(&(DEVI(dip)->devi_lock)); minorname = i_ddi_devtspectype_to_minorname(dip, devt, spec_type); if (minorname) { (void) strcat(path, ":"); (void) strcat(path, minorname); } mutex_exit(&(DEVI(dip)->devi_lock)); ddi_release_devi(dip); if (minorname == NULL) goto fail; } ASSERT(strlen(path) < MAXPATHLEN); return (DDI_SUCCESS); fail: *path = 0; return (DDI_FAILURE); } /* * Given a major number and an instance, return the path. * This interface does NOT drive attach. */ int e_ddi_majorinstance_to_path(major_t major, int instance, char *path) { struct devnames *dnp; dev_info_t *dip; if ((major >= devcnt) || (instance == -1)) { *path = 0; return (DDI_FAILURE); } /* look for the major/instance in the instance tree */ if (e_ddi_instance_majorinstance_to_path(major, instance, path) == DDI_SUCCESS) { ASSERT(strlen(path) < MAXPATHLEN); return (DDI_SUCCESS); } /* * Not in instance tree, find the instance on the per driver list and * construct path to instance via ddi_pathname(). This is how paths * down the 'pseudo' branch are constructed. */ dnp = &(devnamesp[major]); LOCK_DEV_OPS(&(dnp->dn_lock)); for (dip = dnp->dn_head; dip; dip = (dev_info_t *)DEVI(dip)->devi_next) { /* Skip if instance does not match. */ if (DEVI(dip)->devi_instance != instance) continue; /* * An ndi_hold_devi() does not prevent DS_INITIALIZED->DS_BOUND * node demotion, so it is not an effective way of ensuring * that the ddi_pathname result has a unit-address. Instead, * we reverify the node state after calling ddi_pathname(). */ if (i_ddi_node_state(dip) >= DS_INITIALIZED) { (void) ddi_pathname(dip, path); if (i_ddi_node_state(dip) < DS_INITIALIZED) continue; UNLOCK_DEV_OPS(&(dnp->dn_lock)); ASSERT(strlen(path) < MAXPATHLEN); return (DDI_SUCCESS); } } UNLOCK_DEV_OPS(&(dnp->dn_lock)); /* can't reconstruct the path */ *path = 0; return (DDI_FAILURE); } #define GLD_DRIVER_PPA "SUNW,gld_v0_ppa" /* * Given the dip for a network interface return the ppa for that interface. * * In all cases except GLD v0 drivers, the ppa == instance. * In the case of GLD v0 drivers, the ppa is equal to the attach order. * So for these drivers when the attach routine calls gld_register(), * the GLD framework creates an integer property called "gld_driver_ppa" * that can be queried here. * * The only time this function is used is when a system is booting over nfs. * In this case the system has to resolve the pathname of the boot device * to it's ppa. */ int i_ddi_devi_get_ppa(dev_info_t *dip) { return (ddi_prop_get_int(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS | DDI_PROP_NOTPROM, GLD_DRIVER_PPA, ddi_get_instance(dip))); } /* * i_ddi_devi_set_ppa() should only be called from gld_register() * and only for GLD v0 drivers */ void i_ddi_devi_set_ppa(dev_info_t *dip, int ppa) { (void) e_ddi_prop_update_int(DDI_DEV_T_NONE, dip, GLD_DRIVER_PPA, ppa); } /* * Private DDI Console bell functions. */ void ddi_ring_console_bell(clock_t duration) { if (ddi_console_bell_func != NULL) (*ddi_console_bell_func)(duration); } void ddi_set_console_bell(void (*bellfunc)(clock_t duration)) { ddi_console_bell_func = bellfunc; } int ddi_dma_alloc_handle(dev_info_t *dip, ddi_dma_attr_t *attr, int (*waitfp)(caddr_t), caddr_t arg, ddi_dma_handle_t *handlep) { int (*funcp)() = ddi_dma_allochdl; ddi_dma_attr_t dma_attr; struct bus_ops *bop; if (attr == (ddi_dma_attr_t *)0) return (DDI_DMA_BADATTR); dma_attr = *attr; bop = DEVI(dip)->devi_ops->devo_bus_ops; if (bop && bop->bus_dma_allochdl) funcp = bop->bus_dma_allochdl; return ((*funcp)(dip, dip, &dma_attr, waitfp, arg, handlep)); } void ddi_dma_free_handle(ddi_dma_handle_t *handlep) { ddi_dma_handle_t h = *handlep; (void) ddi_dma_freehdl(HD, HD, h); } static uintptr_t dma_mem_list_id = 0; int ddi_dma_mem_alloc(ddi_dma_handle_t handle, size_t length, ddi_device_acc_attr_t *accattrp, uint_t flags, int (*waitfp)(caddr_t), caddr_t arg, caddr_t *kaddrp, size_t *real_length, ddi_acc_handle_t *handlep) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; dev_info_t *dip = hp->dmai_rdip; ddi_acc_hdl_t *ap; ddi_dma_attr_t *attrp = &hp->dmai_attr; uint_t sleepflag, xfermodes; int (*fp)(caddr_t); int rval; if (waitfp == DDI_DMA_SLEEP) fp = (int (*)())KM_SLEEP; else if (waitfp == DDI_DMA_DONTWAIT) fp = (int (*)())KM_NOSLEEP; else fp = waitfp; *handlep = impl_acc_hdl_alloc(fp, arg); if (*handlep == NULL) return (DDI_FAILURE); /* check if the cache attributes are supported */ if (i_ddi_check_cache_attr(flags) == B_FALSE) return (DDI_FAILURE); /* * Transfer the meaningful bits to xfermodes. * Double-check if the 3rd party driver correctly sets the bits. * If not, set DDI_DMA_STREAMING to keep compatibility. */ xfermodes = flags & (DDI_DMA_CONSISTENT | DDI_DMA_STREAMING); if (xfermodes == 0) { xfermodes = DDI_DMA_STREAMING; } /* * initialize the common elements of data access handle */ ap = impl_acc_hdl_get(*handlep); ap->ah_vers = VERS_ACCHDL; ap->ah_dip = dip; ap->ah_offset = 0; ap->ah_len = 0; ap->ah_xfermodes = flags; ap->ah_acc = *accattrp; sleepflag = ((waitfp == DDI_DMA_SLEEP) ? 1 : 0); if (xfermodes == DDI_DMA_CONSISTENT) { rval = i_ddi_mem_alloc(dip, attrp, length, sleepflag, flags, accattrp, kaddrp, NULL, ap); *real_length = length; } else { rval = i_ddi_mem_alloc(dip, attrp, length, sleepflag, flags, accattrp, kaddrp, real_length, ap); } if (rval == DDI_SUCCESS) { ap->ah_len = (off_t)(*real_length); ap->ah_addr = *kaddrp; } else { impl_acc_hdl_free(*handlep); *handlep = (ddi_acc_handle_t)NULL; if (waitfp != DDI_DMA_SLEEP && waitfp != DDI_DMA_DONTWAIT) { ddi_set_callback(waitfp, arg, &dma_mem_list_id); } rval = DDI_FAILURE; } return (rval); } void ddi_dma_mem_free(ddi_acc_handle_t *handlep) { ddi_acc_hdl_t *ap; ap = impl_acc_hdl_get(*handlep); ASSERT(ap); i_ddi_mem_free((caddr_t)ap->ah_addr, ap); /* * free the handle */ impl_acc_hdl_free(*handlep); *handlep = (ddi_acc_handle_t)NULL; if (dma_mem_list_id != 0) { ddi_run_callback(&dma_mem_list_id); } } int ddi_dma_buf_bind_handle(ddi_dma_handle_t handle, struct buf *bp, uint_t flags, int (*waitfp)(caddr_t), caddr_t arg, ddi_dma_cookie_t *cookiep, uint_t *ccountp) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; dev_info_t *hdip, *dip; struct ddi_dma_req dmareq; int (*funcp)(); dmareq.dmar_flags = flags; dmareq.dmar_fp = waitfp; dmareq.dmar_arg = arg; dmareq.dmar_object.dmao_size = (uint_t)bp->b_bcount; if (bp->b_flags & B_PAGEIO) { dmareq.dmar_object.dmao_type = DMA_OTYP_PAGES; dmareq.dmar_object.dmao_obj.pp_obj.pp_pp = bp->b_pages; dmareq.dmar_object.dmao_obj.pp_obj.pp_offset = (uint_t)(((uintptr_t)bp->b_un.b_addr) & MMU_PAGEOFFSET); } else { dmareq.dmar_object.dmao_obj.virt_obj.v_addr = bp->b_un.b_addr; if (bp->b_flags & B_SHADOW) { dmareq.dmar_object.dmao_obj.virt_obj.v_priv = bp->b_shadow; dmareq.dmar_object.dmao_type = DMA_OTYP_BUFVADDR; } else { dmareq.dmar_object.dmao_type = (bp->b_flags & (B_PHYS | B_REMAPPED)) ? DMA_OTYP_BUFVADDR : DMA_OTYP_VADDR; dmareq.dmar_object.dmao_obj.virt_obj.v_priv = NULL; } /* * If the buffer has no proc pointer, or the proc * struct has the kernel address space, or the buffer has * been marked B_REMAPPED (meaning that it is now * mapped into the kernel's address space), then * the address space is kas (kernel address space). */ if ((bp->b_proc == NULL) || (bp->b_proc->p_as == &kas) || (bp->b_flags & B_REMAPPED)) { dmareq.dmar_object.dmao_obj.virt_obj.v_as = 0; } else { dmareq.dmar_object.dmao_obj.virt_obj.v_as = bp->b_proc->p_as; } } dip = hp->dmai_rdip; hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_bindhdl; funcp = DEVI(dip)->devi_bus_dma_bindfunc; return ((*funcp)(hdip, dip, handle, &dmareq, cookiep, ccountp)); } int ddi_dma_addr_bind_handle(ddi_dma_handle_t handle, struct as *as, caddr_t addr, size_t len, uint_t flags, int (*waitfp)(caddr_t), caddr_t arg, ddi_dma_cookie_t *cookiep, uint_t *ccountp) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; dev_info_t *hdip, *dip; struct ddi_dma_req dmareq; int (*funcp)(); if (len == (uint_t)0) { return (DDI_DMA_NOMAPPING); } dmareq.dmar_flags = flags; dmareq.dmar_fp = waitfp; dmareq.dmar_arg = arg; dmareq.dmar_object.dmao_size = len; dmareq.dmar_object.dmao_type = DMA_OTYP_VADDR; dmareq.dmar_object.dmao_obj.virt_obj.v_as = as; dmareq.dmar_object.dmao_obj.virt_obj.v_addr = addr; dmareq.dmar_object.dmao_obj.virt_obj.v_priv = NULL; dip = hp->dmai_rdip; hdip = (dev_info_t *)DEVI(dip)->devi_bus_dma_bindhdl; funcp = DEVI(dip)->devi_bus_dma_bindfunc; return ((*funcp)(hdip, dip, handle, &dmareq, cookiep, ccountp)); } void ddi_dma_nextcookie(ddi_dma_handle_t handle, ddi_dma_cookie_t *cookiep) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; ddi_dma_cookie_t *cp; cp = hp->dmai_cookie; ASSERT(cp); cookiep->dmac_notused = cp->dmac_notused; cookiep->dmac_type = cp->dmac_type; cookiep->dmac_address = cp->dmac_address; cookiep->dmac_size = cp->dmac_size; hp->dmai_cookie++; } int ddi_dma_numwin(ddi_dma_handle_t handle, uint_t *nwinp) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; if ((hp->dmai_rflags & DDI_DMA_PARTIAL) == 0) { return (DDI_FAILURE); } else { *nwinp = hp->dmai_nwin; return (DDI_SUCCESS); } } int ddi_dma_getwin(ddi_dma_handle_t h, uint_t win, off_t *offp, size_t *lenp, ddi_dma_cookie_t *cookiep, uint_t *ccountp) { int (*funcp)() = ddi_dma_win; struct bus_ops *bop; bop = DEVI(HD)->devi_ops->devo_bus_ops; if (bop && bop->bus_dma_win) funcp = bop->bus_dma_win; return ((*funcp)(HD, HD, h, win, offp, lenp, cookiep, ccountp)); } int ddi_dma_set_sbus64(ddi_dma_handle_t h, ulong_t burstsizes) { return (ddi_dma_mctl(HD, HD, h, DDI_DMA_SET_SBUS64, 0, &burstsizes, 0, 0)); } int i_ddi_dma_fault_check(ddi_dma_impl_t *hp) { return (hp->dmai_fault); } int ddi_check_dma_handle(ddi_dma_handle_t handle) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; int (*check)(ddi_dma_impl_t *); if ((check = hp->dmai_fault_check) == NULL) check = i_ddi_dma_fault_check; return (((*check)(hp) == DDI_SUCCESS) ? DDI_SUCCESS : DDI_FAILURE); } void i_ddi_dma_set_fault(ddi_dma_handle_t handle) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; void (*notify)(ddi_dma_impl_t *); if (!hp->dmai_fault) { hp->dmai_fault = 1; if ((notify = hp->dmai_fault_notify) != NULL) (*notify)(hp); } } void i_ddi_dma_clr_fault(ddi_dma_handle_t handle) { ddi_dma_impl_t *hp = (ddi_dma_impl_t *)handle; void (*notify)(ddi_dma_impl_t *); if (hp->dmai_fault) { hp->dmai_fault = 0; if ((notify = hp->dmai_fault_notify) != NULL) (*notify)(hp); } } /* * register mapping routines. */ int ddi_regs_map_setup(dev_info_t *dip, uint_t rnumber, caddr_t *addrp, offset_t offset, offset_t len, ddi_device_acc_attr_t *accattrp, ddi_acc_handle_t *handle) { ddi_map_req_t mr; ddi_acc_hdl_t *hp; int result; /* * Allocate and initialize the common elements of data access handle. */ *handle = impl_acc_hdl_alloc(KM_SLEEP, NULL); hp = impl_acc_hdl_get(*handle); hp->ah_vers = VERS_ACCHDL; hp->ah_dip = dip; hp->ah_rnumber = rnumber; hp->ah_offset = offset; hp->ah_len = len; hp->ah_acc = *accattrp; /* * Set up the mapping request and call to parent. */ mr.map_op = DDI_MO_MAP_LOCKED; mr.map_type = DDI_MT_RNUMBER; mr.map_obj.rnumber = rnumber; mr.map_prot = PROT_READ | PROT_WRITE; mr.map_flags = DDI_MF_KERNEL_MAPPING; mr.map_handlep = hp; mr.map_vers = DDI_MAP_VERSION; result = ddi_map(dip, &mr, offset, len, addrp); /* * check for end result */ if (result != DDI_SUCCESS) { impl_acc_hdl_free(*handle); *handle = (ddi_acc_handle_t)NULL; } else { hp->ah_addr = *addrp; } return (result); } void ddi_regs_map_free(ddi_acc_handle_t *handlep) { ddi_map_req_t mr; ddi_acc_hdl_t *hp; hp = impl_acc_hdl_get(*handlep); ASSERT(hp); mr.map_op = DDI_MO_UNMAP; mr.map_type = DDI_MT_RNUMBER; mr.map_obj.rnumber = hp->ah_rnumber; mr.map_prot = PROT_READ | PROT_WRITE; mr.map_flags = DDI_MF_KERNEL_MAPPING; mr.map_handlep = hp; mr.map_vers = DDI_MAP_VERSION; /* * Call my parent to unmap my regs. */ (void) ddi_map(hp->ah_dip, &mr, hp->ah_offset, hp->ah_len, &hp->ah_addr); /* * free the handle */ impl_acc_hdl_free(*handlep); *handlep = (ddi_acc_handle_t)NULL; } int ddi_device_zero(ddi_acc_handle_t handle, caddr_t dev_addr, size_t bytecount, ssize_t dev_advcnt, uint_t dev_datasz) { uint8_t *b; uint16_t *w; uint32_t *l; uint64_t *ll; /* check for total byte count is multiple of data transfer size */ if (bytecount != ((bytecount / dev_datasz) * dev_datasz)) return (DDI_FAILURE); switch (dev_datasz) { case DDI_DATA_SZ01_ACC: for (b = (uint8_t *)dev_addr; bytecount != 0; bytecount -= 1, b += dev_advcnt) ddi_put8(handle, b, 0); break; case DDI_DATA_SZ02_ACC: for (w = (uint16_t *)dev_addr; bytecount != 0; bytecount -= 2, w += dev_advcnt) ddi_put16(handle, w, 0); break; case DDI_DATA_SZ04_ACC: for (l = (uint32_t *)dev_addr; bytecount != 0; bytecount -= 4, l += dev_advcnt) ddi_put32(handle, l, 0); break; case DDI_DATA_SZ08_ACC: for (ll = (uint64_t *)dev_addr; bytecount != 0; bytecount -= 8, ll += dev_advcnt) ddi_put64(handle, ll, 0x0ll); break; default: return (DDI_FAILURE); } return (DDI_SUCCESS); } int ddi_device_copy( ddi_acc_handle_t src_handle, caddr_t src_addr, ssize_t src_advcnt, ddi_acc_handle_t dest_handle, caddr_t dest_addr, ssize_t dest_advcnt, size_t bytecount, uint_t dev_datasz) { uint8_t *b_src, *b_dst; uint16_t *w_src, *w_dst; uint32_t *l_src, *l_dst; uint64_t *ll_src, *ll_dst; /* check for total byte count is multiple of data transfer size */ if (bytecount != ((bytecount / dev_datasz) * dev_datasz)) return (DDI_FAILURE); switch (dev_datasz) { case DDI_DATA_SZ01_ACC: b_src = (uint8_t *)src_addr; b_dst = (uint8_t *)dest_addr; for (; bytecount != 0; bytecount -= 1) { ddi_put8(dest_handle, b_dst, ddi_get8(src_handle, b_src)); b_dst += dest_advcnt; b_src += src_advcnt; } break; case DDI_DATA_SZ02_ACC: w_src = (uint16_t *)src_addr; w_dst = (uint16_t *)dest_addr; for (; bytecount != 0; bytecount -= 2) { ddi_put16(dest_handle, w_dst, ddi_get16(src_handle, w_src)); w_dst += dest_advcnt; w_src += src_advcnt; } break; case DDI_DATA_SZ04_ACC: l_src = (uint32_t *)src_addr; l_dst = (uint32_t *)dest_addr; for (; bytecount != 0; bytecount -= 4) { ddi_put32(dest_handle, l_dst, ddi_get32(src_handle, l_src)); l_dst += dest_advcnt; l_src += src_advcnt; } break; case DDI_DATA_SZ08_ACC: ll_src = (uint64_t *)src_addr; ll_dst = (uint64_t *)dest_addr; for (; bytecount != 0; bytecount -= 8) { ddi_put64(dest_handle, ll_dst, ddi_get64(src_handle, ll_src)); ll_dst += dest_advcnt; ll_src += src_advcnt; } break; default: return (DDI_FAILURE); } return (DDI_SUCCESS); } #define swap16(value) \ ((((value) & 0xff) << 8) | ((value) >> 8)) #define swap32(value) \ (((uint32_t)swap16((uint16_t)((value) & 0xffff)) << 16) | \ (uint32_t)swap16((uint16_t)((value) >> 16))) #define swap64(value) \ (((uint64_t)swap32((uint32_t)((value) & 0xffffffff)) \ << 32) | \ (uint64_t)swap32((uint32_t)((value) >> 32))) uint16_t ddi_swap16(uint16_t value) { return (swap16(value)); } uint32_t ddi_swap32(uint32_t value) { return (swap32(value)); } uint64_t ddi_swap64(uint64_t value) { return (swap64(value)); } /* * Convert a binding name to a driver name. * A binding name is the name used to determine the driver for a * device - it may be either an alias for the driver or the name * of the driver itself. */ char * i_binding_to_drv_name(char *bname) { major_t major_no; ASSERT(bname != NULL); if ((major_no = ddi_name_to_major(bname)) == -1) return (NULL); return (ddi_major_to_name(major_no)); } /* * Search for minor name that has specified dev_t and spec_type. * If spec_type is zero then any dev_t match works. Since we * are returning a pointer to the minor name string, we require the * caller to do the locking. */ char * i_ddi_devtspectype_to_minorname(dev_info_t *dip, dev_t dev, int spec_type) { struct ddi_minor_data *dmdp; /* * The did layered driver currently intentionally returns a * devinfo ptr for an underlying sd instance based on a did * dev_t. In this case it is not an error. * * The did layered driver is associated with Sun Cluster. */ ASSERT((ddi_driver_major(dip) == getmajor(dev)) || (strcmp(ddi_major_to_name(getmajor(dev)), "did") == 0)); ASSERT(MUTEX_HELD(&(DEVI(dip)->devi_lock))); for (dmdp = DEVI(dip)->devi_minor; dmdp; dmdp = dmdp->next) { if (((dmdp->type == DDM_MINOR) || (dmdp->type == DDM_INTERNAL_PATH) || (dmdp->type == DDM_DEFAULT)) && (dmdp->ddm_dev == dev) && ((((spec_type & (S_IFCHR|S_IFBLK))) == 0) || (dmdp->ddm_spec_type == spec_type))) return (dmdp->ddm_name); } return (NULL); } /* * Find the devt and spectype of the specified minor_name. * Return DDI_FAILURE if minor_name not found. Since we are * returning everything via arguments we can do the locking. */ int i_ddi_minorname_to_devtspectype(dev_info_t *dip, char *minor_name, dev_t *devtp, int *spectypep) { struct ddi_minor_data *dmdp; /* deal with clone minor nodes */ if (dip == clone_dip) { major_t major; /* * Make sure minor_name is a STREAMS driver. * We load the driver but don't attach to any instances. */ major = ddi_name_to_major(minor_name); if (major == DDI_MAJOR_T_NONE) return (DDI_FAILURE); if (ddi_hold_driver(major) == NULL) return (DDI_FAILURE); if (STREAMSTAB(major) == NULL) { ddi_rele_driver(major); return (DDI_FAILURE); } ddi_rele_driver(major); if (devtp) *devtp = makedevice(clone_major, (minor_t)major); if (spectypep) *spectypep = S_IFCHR; return (DDI_SUCCESS); } ASSERT(!MUTEX_HELD(&(DEVI(dip)->devi_lock))); mutex_enter(&(DEVI(dip)->devi_lock)); for (dmdp = DEVI(dip)->devi_minor; dmdp; dmdp = dmdp->next) { if (((dmdp->type != DDM_MINOR) && (dmdp->type != DDM_INTERNAL_PATH) && (dmdp->type != DDM_DEFAULT)) || strcmp(minor_name, dmdp->ddm_name)) continue; if (devtp) *devtp = dmdp->ddm_dev; if (spectypep) *spectypep = dmdp->ddm_spec_type; mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_SUCCESS); } mutex_exit(&(DEVI(dip)->devi_lock)); return (DDI_FAILURE); } extern char hw_serial[]; static kmutex_t devid_gen_mutex; static short devid_gen_number; #ifdef DEBUG static int devid_register_corrupt = 0; static int devid_register_corrupt_major = 0; static int devid_register_corrupt_hint = 0; static int devid_register_corrupt_hint_major = 0; static int devid_lyr_debug = 0; #define DDI_DEBUG_DEVID_DEVTS(msg, ndevs, devs) \ if (devid_lyr_debug) \ ddi_debug_devid_devts(msg, ndevs, devs) #else #define DDI_DEBUG_DEVID_DEVTS(msg, ndevs, devs) #endif /* DEBUG */ #ifdef DEBUG static void ddi_debug_devid_devts(char *msg, int ndevs, dev_t *devs) { int i; cmn_err(CE_CONT, "%s:\n", msg); for (i = 0; i < ndevs; i++) { cmn_err(CE_CONT, " 0x%lx\n", devs[i]); } } static void ddi_debug_devid_paths(char *msg, int npaths, char **paths) { int i; cmn_err(CE_CONT, "%s:\n", msg); for (i = 0; i < npaths; i++) { cmn_err(CE_CONT, " %s\n", paths[i]); } } static void ddi_debug_devid_devts_per_path(char *path, int ndevs, dev_t *devs) { int i; cmn_err(CE_CONT, "dev_ts per path %s\n", path); for (i = 0; i < ndevs; i++) { cmn_err(CE_CONT, " 0x%lx\n", devs[i]); } } #endif /* DEBUG */ /* * Register device id into DDI framework. * Must be called when device is attached. */ static int i_ddi_devid_register(dev_info_t *dip, ddi_devid_t devid) { impl_devid_t *i_devid = (impl_devid_t *)devid; size_t driver_len; const char *driver_name; char *devid_str; major_t major; if ((dip == NULL) || ((major = ddi_driver_major(dip)) == DDI_MAJOR_T_NONE)) return (DDI_FAILURE); /* verify that the devid is valid */ if (ddi_devid_valid(devid) != DDI_SUCCESS) return (DDI_FAILURE); /* Updating driver name hint in devid */ driver_name = ddi_driver_name(dip); driver_len = strlen(driver_name); if (driver_len > DEVID_HINT_SIZE) { /* Pick up last four characters of driver name */ driver_name += driver_len - DEVID_HINT_SIZE; driver_len = DEVID_HINT_SIZE; } bzero(i_devid->did_driver, DEVID_HINT_SIZE); bcopy(driver_name, i_devid->did_driver, driver_len); #ifdef DEBUG /* Corrupt the devid for testing. */ if (devid_register_corrupt) i_devid->did_id[0] += devid_register_corrupt; if (devid_register_corrupt_major && (major == devid_register_corrupt_major)) i_devid->did_id[0] += 1; if (devid_register_corrupt_hint) i_devid->did_driver[0] += devid_register_corrupt_hint; if (devid_register_corrupt_hint_major && (major == devid_register_corrupt_hint_major)) i_devid->did_driver[0] += 1; #endif /* DEBUG */ /* encode the devid as a string */ if ((devid_str = ddi_devid_str_encode(devid, NULL)) == NULL) return (DDI_FAILURE); /* add string as a string property */ if (ndi_prop_update_string(DDI_DEV_T_NONE, dip, DEVID_PROP_NAME, devid_str) != DDI_SUCCESS) { cmn_err(CE_WARN, "%s%d: devid property update failed", ddi_driver_name(dip), ddi_get_instance(dip)); ddi_devid_str_free(devid_str); return (DDI_FAILURE); } /* keep pointer to devid string for interrupt context fma code */ if (DEVI(dip)->devi_devid_str) ddi_devid_str_free(DEVI(dip)->devi_devid_str); DEVI(dip)->devi_devid_str = devid_str; return (DDI_SUCCESS); } int ddi_devid_register(dev_info_t *dip, ddi_devid_t devid) { int rval; rval = i_ddi_devid_register(dip, devid); if (rval == DDI_SUCCESS) { /* * Register devid in devid-to-path cache */ if (e_devid_cache_register(dip, devid) == DDI_SUCCESS) { mutex_enter(&DEVI(dip)->devi_lock); DEVI(dip)->devi_flags |= DEVI_REGISTERED_DEVID; mutex_exit(&DEVI(dip)->devi_lock); } else { cmn_err(CE_WARN, "%s%d: failed to cache devid", ddi_driver_name(dip), ddi_get_instance(dip)); } } else { cmn_err(CE_WARN, "%s%d: failed to register devid", ddi_driver_name(dip), ddi_get_instance(dip)); } return (rval); } /* * Remove (unregister) device id from DDI framework. * Must be called when device is detached. */ static void i_ddi_devid_unregister(dev_info_t *dip) { if (DEVI(dip)->devi_devid_str) { ddi_devid_str_free(DEVI(dip)->devi_devid_str); DEVI(dip)->devi_devid_str = NULL; } /* remove the devid property */ (void) ndi_prop_remove(DDI_DEV_T_NONE, dip, DEVID_PROP_NAME); } void ddi_devid_unregister(dev_info_t *dip) { mutex_enter(&DEVI(dip)->devi_lock); DEVI(dip)->devi_flags &= ~DEVI_REGISTERED_DEVID; mutex_exit(&DEVI(dip)->devi_lock); e_devid_cache_unregister(dip); i_ddi_devid_unregister(dip); } /* * Allocate and initialize a device id. */ int ddi_devid_init( dev_info_t *dip, ushort_t devid_type, ushort_t nbytes, void *id, ddi_devid_t *ret_devid) { impl_devid_t *i_devid; int sz = sizeof (*i_devid) + nbytes - sizeof (char); int driver_len; const char *driver_name; switch (devid_type) { case DEVID_SCSI3_WWN: /*FALLTHRU*/ case DEVID_SCSI_SERIAL: /*FALLTHRU*/ case DEVID_ATA_SERIAL: /*FALLTHRU*/ case DEVID_ENCAP: if (nbytes == 0) return (DDI_FAILURE); if (id == NULL) return (DDI_FAILURE); break; case DEVID_FAB: if (nbytes != 0) return (DDI_FAILURE); if (id != NULL) return (DDI_FAILURE); nbytes = sizeof (int) + sizeof (struct timeval32) + sizeof (short); sz += nbytes; break; default: return (DDI_FAILURE); } if ((i_devid = kmem_zalloc(sz, KM_SLEEP)) == NULL) return (DDI_FAILURE); i_devid->did_magic_hi = DEVID_MAGIC_MSB; i_devid->did_magic_lo = DEVID_MAGIC_LSB; i_devid->did_rev_hi = DEVID_REV_MSB; i_devid->did_rev_lo = DEVID_REV_LSB; DEVID_FORMTYPE(i_devid, devid_type); DEVID_FORMLEN(i_devid, nbytes); /* Fill in driver name hint */ driver_name = ddi_driver_name(dip); driver_len = strlen(driver_name); if (driver_len > DEVID_HINT_SIZE) { /* Pick up last four characters of driver name */ driver_name += driver_len - DEVID_HINT_SIZE; driver_len = DEVID_HINT_SIZE; } bcopy(driver_name, i_devid->did_driver, driver_len); /* Fill in id field */ if (devid_type == DEVID_FAB) { char *cp; int hostid; char *hostid_cp = &hw_serial[0]; struct timeval32 timestamp32; int i; int *ip; short gen; /* increase the generation number */ mutex_enter(&devid_gen_mutex); gen = devid_gen_number++; mutex_exit(&devid_gen_mutex); cp = i_devid->did_id; /* Fill in host id (big-endian byte ordering) */ hostid = stoi(&hostid_cp); *cp++ = hibyte(hiword(hostid)); *cp++ = lobyte(hiword(hostid)); *cp++ = hibyte(loword(hostid)); *cp++ = lobyte(loword(hostid)); /* * Fill in timestamp (big-endian byte ordering) * * (Note that the format may have to be changed * before 2038 comes around, though it's arguably * unique enough as it is..) */ uniqtime32(×tamp32); ip = (int *)×tamp32; for (i = 0; i < sizeof (timestamp32) / sizeof (int); i++, ip++) { int val; val = *ip; *cp++ = hibyte(hiword(val)); *cp++ = lobyte(hiword(val)); *cp++ = hibyte(loword(val)); *cp++ = lobyte(loword(val)); } /* fill in the generation number */ *cp++ = hibyte(gen); *cp++ = lobyte(gen); } else bcopy(id, i_devid->did_id, nbytes); /* return device id */ *ret_devid = (ddi_devid_t)i_devid; return (DDI_SUCCESS); } int ddi_devid_get(dev_info_t *dip, ddi_devid_t *ret_devid) { return (i_ddi_devi_get_devid(DDI_DEV_T_ANY, dip, ret_devid)); } int i_ddi_devi_get_devid(dev_t dev, dev_info_t *dip, ddi_devid_t *ret_devid) { char *devidstr; ASSERT(dev != DDI_DEV_T_NONE); /* look up the property, devt specific first */ if (ddi_prop_lookup_string(dev, dip, DDI_PROP_DONTPASS, DEVID_PROP_NAME, &devidstr) != DDI_PROP_SUCCESS) { if ((dev == DDI_DEV_T_ANY) || (ddi_prop_lookup_string(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, DEVID_PROP_NAME, &devidstr) != DDI_PROP_SUCCESS)) { return (DDI_FAILURE); } } /* convert to binary form */ if (ddi_devid_str_decode(devidstr, ret_devid, NULL) == -1) { ddi_prop_free(devidstr); return (DDI_FAILURE); } ddi_prop_free(devidstr); return (DDI_SUCCESS); } /* * Return a copy of the device id for dev_t */ int ddi_lyr_get_devid(dev_t dev, ddi_devid_t *ret_devid) { dev_info_t *dip; int rval; /* get the dip */ if ((dip = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (DDI_FAILURE); rval = i_ddi_devi_get_devid(dev, dip, ret_devid); ddi_release_devi(dip); /* e_ddi_hold_devi_by_dev() */ return (rval); } /* * Return a copy of the minor name for dev_t and spec_type */ int ddi_lyr_get_minor_name(dev_t dev, int spec_type, char **minor_name) { dev_info_t *dip; char *nm; size_t alloc_sz, sz; if ((dip = e_ddi_hold_devi_by_dev(dev, 0)) == NULL) return (DDI_FAILURE); mutex_enter(&(DEVI(dip)->devi_lock)); if ((nm = i_ddi_devtspectype_to_minorname(dip, dev, spec_type)) == NULL) { mutex_exit(&(DEVI(dip)->devi_lock)); ddi_release_devi(dip); /* e_ddi_hold_devi_by_dev() */ return (DDI_FAILURE); } /* make a copy */ alloc_sz = strlen(nm) + 1; retry: /* drop lock to allocate memory */ mutex_exit(&(DEVI(dip)->devi_lock)); *minor_name = kmem_alloc(alloc_sz, KM_SLEEP); mutex_enter(&(DEVI(dip)->devi_lock)); /* re-check things, since we dropped the lock */ if ((nm = i_ddi_devtspectype_to_minorname(dip, dev, spec_type)) == NULL) { mutex_exit(&(DEVI(dip)->devi_lock)); kmem_free(*minor_name, alloc_sz); *minor_name = NULL; ddi_release_devi(dip); /* e_ddi_hold_devi_by_dev() */ return (DDI_FAILURE); } /* verify size is the same */ sz = strlen(nm) + 1; if (alloc_sz != sz) { kmem_free(*minor_name, alloc_sz); alloc_sz = sz; goto retry; } /* sz == alloc_sz - make a copy */ (void) strcpy(*minor_name, nm); mutex_exit(&(DEVI(dip)->devi_lock)); ddi_release_devi(dip); /* e_ddi_hold_devi_by_dev() */ return (DDI_SUCCESS); } int ddi_lyr_devid_to_devlist( ddi_devid_t devid, char *minor_name, int *retndevs, dev_t **retdevs) { ASSERT(ddi_devid_valid(devid) == DDI_SUCCESS); if (e_devid_cache_to_devt_list(devid, minor_name, retndevs, retdevs) == DDI_SUCCESS) { ASSERT(*retndevs > 0); DDI_DEBUG_DEVID_DEVTS("ddi_lyr_devid_to_devlist", *retndevs, *retdevs); return (DDI_SUCCESS); } if (e_ddi_devid_discovery(devid) == DDI_FAILURE) { return (DDI_FAILURE); } if (e_devid_cache_to_devt_list(devid, minor_name, retndevs, retdevs) == DDI_SUCCESS) { ASSERT(*retndevs > 0); DDI_DEBUG_DEVID_DEVTS("ddi_lyr_devid_to_devlist", *retndevs, *retdevs); return (DDI_SUCCESS); } return (DDI_FAILURE); } void ddi_lyr_free_devlist(dev_t *devlist, int ndevs) { kmem_free(devlist, sizeof (dev_t) * ndevs); } /* * Note: This will need to be fixed if we ever allow processes to * have more than one data model per exec. */ model_t ddi_mmap_get_model(void) { return (get_udatamodel()); } model_t ddi_model_convert_from(model_t model) { return ((model & DDI_MODEL_MASK) & ~DDI_MODEL_NATIVE); } /* * ddi interfaces managing storage and retrieval of eventcookies. */ /* * Invoke bus nexus driver's implementation of the * (*bus_remove_eventcall)() interface to remove a registered * callback handler for "event". */ int ddi_remove_event_handler(ddi_callback_id_t id) { ndi_event_callbacks_t *cb = (ndi_event_callbacks_t *)id; dev_info_t *ddip; ASSERT(cb); if (!cb) { return (DDI_FAILURE); } ddip = NDI_EVENT_DDIP(cb->ndi_evtcb_cookie); return (ndi_busop_remove_eventcall(ddip, id)); } /* * Invoke bus nexus driver's implementation of the * (*bus_add_eventcall)() interface to register a callback handler * for "event". */ int ddi_add_event_handler(dev_info_t *dip, ddi_eventcookie_t event, void (*handler)(dev_info_t *, ddi_eventcookie_t, void *, void *), void *arg, ddi_callback_id_t *id) { return (ndi_busop_add_eventcall(dip, dip, event, handler, arg, id)); } /* * Return a handle for event "name" by calling up the device tree * hierarchy via (*bus_get_eventcookie)() interface until claimed * by a bus nexus or top of dev_info tree is reached. */ int ddi_get_eventcookie(dev_info_t *dip, char *name, ddi_eventcookie_t *event_cookiep) { return (ndi_busop_get_eventcookie(dip, dip, name, event_cookiep)); } /* * single thread access to dev_info node and set state */ void i_devi_enter(dev_info_t *dip, uint_t s_mask, uint_t w_mask, int has_lock) { if (!has_lock) mutex_enter(&(DEVI(dip)->devi_lock)); ASSERT(mutex_owned(&(DEVI(dip)->devi_lock))); /* * wait until state(s) have been changed */ while ((DEVI(dip)->devi_state & w_mask) != 0) { cv_wait(&(DEVI(dip)->devi_cv), &(DEVI(dip)->devi_lock)); } DEVI(dip)->devi_state |= s_mask; if (!has_lock) mutex_exit(&(DEVI(dip)->devi_lock)); } void i_devi_exit(dev_info_t *dip, uint_t c_mask, int has_lock) { if (!has_lock) mutex_enter(&(DEVI(dip)->devi_lock)); ASSERT(mutex_owned(&(DEVI(dip)->devi_lock))); /* * clear the state(s) and wakeup any threads waiting * for state change */ DEVI(dip)->devi_state &= ~c_mask; cv_broadcast(&(DEVI(dip)->devi_cv)); if (!has_lock) mutex_exit(&(DEVI(dip)->devi_lock)); } /* * This procedure is provided as the general callback function when * umem_lockmemory calls as_add_callback for long term memory locking. * When as_unmap, as_setprot, or as_free encounter segments which have * locked memory, this callback will be invoked. */ void umem_lock_undo(struct as *as, void *arg, uint_t event) { _NOTE(ARGUNUSED(as, event)) struct ddi_umem_cookie *cp = (struct ddi_umem_cookie *)arg; /* * Call the cleanup function. Decrement the cookie reference * count, if it goes to zero, return the memory for the cookie. * The i_ddi_umem_unlock for this cookie may or may not have been * called already. It is the responsibility of the caller of * umem_lockmemory to handle the case of the cleanup routine * being called after a ddi_umem_unlock for the cookie * was called. */ (*cp->callbacks.cbo_umem_lock_cleanup)((ddi_umem_cookie_t)cp); /* remove the cookie if reference goes to zero */ if (atomic_add_long_nv((ulong_t *)(&(cp->cook_refcnt)), -1) == 0) { kmem_free(cp, sizeof (struct ddi_umem_cookie)); } } /* * The following two Consolidation Private routines provide generic * interfaces to increase/decrease the amount of device-locked memory. * * To keep project_rele and project_hold consistent, i_ddi_decr_locked_memory() * must be called every time i_ddi_incr_locked_memory() is called. */ int /* ARGSUSED */ i_ddi_incr_locked_memory(proc_t *procp, rctl_qty_t inc) { ASSERT(procp != NULL); mutex_enter(&procp->p_lock); if (rctl_incr_locked_mem(procp, NULL, inc, 1)) { mutex_exit(&procp->p_lock); return (ENOMEM); } mutex_exit(&procp->p_lock); return (0); } /* * To keep project_rele and project_hold consistent, i_ddi_incr_locked_memory() * must be called every time i_ddi_decr_locked_memory() is called. */ /* ARGSUSED */ void i_ddi_decr_locked_memory(proc_t *procp, rctl_qty_t dec) { ASSERT(procp != NULL); mutex_enter(&procp->p_lock); rctl_decr_locked_mem(procp, NULL, dec, 1); mutex_exit(&procp->p_lock); } /* * This routine checks if the max-locked-memory resource ctl is * exceeded, if not increments it, grabs a hold on the project. * Returns 0 if successful otherwise returns error code */ static int umem_incr_devlockmem(struct ddi_umem_cookie *cookie) { proc_t *procp; int ret; ASSERT(cookie); procp = cookie->procp; ASSERT(procp); if ((ret = i_ddi_incr_locked_memory(procp, cookie->size)) != 0) { return (ret); } return (0); } /* * Decrements the max-locked-memory resource ctl and releases * the hold on the project that was acquired during umem_incr_devlockmem */ static void umem_decr_devlockmem(struct ddi_umem_cookie *cookie) { proc_t *proc; proc = (proc_t *)cookie->procp; if (!proc) return; i_ddi_decr_locked_memory(proc, cookie->size); } /* * A consolidation private function which is essentially equivalent to * ddi_umem_lock but with the addition of arguments ops_vector and procp. * A call to as_add_callback is done if DDI_UMEMLOCK_LONGTERM is set, and * the ops_vector is valid. * * Lock the virtual address range in the current process and create a * ddi_umem_cookie (of type UMEM_LOCKED). This can be used to pass to * ddi_umem_iosetup to create a buf or do devmap_umem_setup/remap to export * to user space. * * Note: The resource control accounting currently uses a full charge model * in other words attempts to lock the same/overlapping areas of memory * will deduct the full size of the buffer from the projects running * counter for the device locked memory. * * addr, size should be PAGESIZE aligned * * flags - DDI_UMEMLOCK_READ, DDI_UMEMLOCK_WRITE or both * identifies whether the locked memory will be read or written or both * DDI_UMEMLOCK_LONGTERM must be set when the locking will * be maintained for an indefinitely long period (essentially permanent), * rather than for what would be required for a typical I/O completion. * When DDI_UMEMLOCK_LONGTERM is set, umem_lockmemory will return EFAULT * if the memory pertains to a regular file which is mapped MAP_SHARED. * This is to prevent a deadlock if a file truncation is attempted after * after the locking is done. * * Returns 0 on success * EINVAL - for invalid parameters * EPERM, ENOMEM and other error codes returned by as_pagelock * ENOMEM - is returned if the current request to lock memory exceeds * *.max-locked-memory resource control value. * EFAULT - memory pertains to a regular file mapped shared and * and DDI_UMEMLOCK_LONGTERM flag is set * EAGAIN - could not start the ddi_umem_unlock list processing thread */ int umem_lockmemory(caddr_t addr, size_t len, int flags, ddi_umem_cookie_t *cookie, struct umem_callback_ops *ops_vector, proc_t *procp) { int error; struct ddi_umem_cookie *p; void (*driver_callback)() = NULL; struct as *as = procp->p_as; struct seg *seg; vnode_t *vp; *cookie = NULL; /* in case of any error return */ /* These are the only three valid flags */ if ((flags & ~(DDI_UMEMLOCK_READ | DDI_UMEMLOCK_WRITE | DDI_UMEMLOCK_LONGTERM)) != 0) return (EINVAL); /* At least one (can be both) of the two access flags must be set */ if ((flags & (DDI_UMEMLOCK_READ | DDI_UMEMLOCK_WRITE)) == 0) return (EINVAL); /* addr and len must be page-aligned */ if (((uintptr_t)addr & PAGEOFFSET) != 0) return (EINVAL); if ((len & PAGEOFFSET) != 0) return (EINVAL); /* * For longterm locking a driver callback must be specified; if * not longterm then a callback is optional. */ if (ops_vector != NULL) { if (ops_vector->cbo_umem_callback_version != UMEM_CALLBACK_VERSION) return (EINVAL); else driver_callback = ops_vector->cbo_umem_lock_cleanup; } if ((driver_callback == NULL) && (flags & DDI_UMEMLOCK_LONGTERM)) return (EINVAL); /* * Call i_ddi_umem_unlock_thread_start if necessary. It will * be called on first ddi_umem_lock or umem_lockmemory call. */ if (ddi_umem_unlock_thread == NULL) i_ddi_umem_unlock_thread_start(); /* Allocate memory for the cookie */ p = kmem_zalloc(sizeof (struct ddi_umem_cookie), KM_SLEEP); /* Convert the flags to seg_rw type */ if (flags & DDI_UMEMLOCK_WRITE) { p->s_flags = S_WRITE; } else { p->s_flags = S_READ; } /* Store procp in cookie for later iosetup/unlock */ p->procp = (void *)procp; /* * Store the struct as pointer in cookie for later use by * ddi_umem_unlock. The proc->p_as will be stale if ddi_umem_unlock * is called after relvm is called. */ p->asp = as; /* * The size field is needed for lockmem accounting. */ p->size = len; if (umem_incr_devlockmem(p) != 0) { /* * The requested memory cannot be locked */ kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; return (ENOMEM); } /* Lock the pages corresponding to addr, len in memory */ error = as_pagelock(as, &(p->pparray), addr, len, p->s_flags); if (error != 0) { umem_decr_devlockmem(p); kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; return (error); } /* * For longterm locking the addr must pertain to a seg_vn segment or * or a seg_spt segment. * If the segment pertains to a regular file, it cannot be * mapped MAP_SHARED. * This is to prevent a deadlock if a file truncation is attempted * after the locking is done. * Doing this after as_pagelock guarantees persistence of the as; if * an unacceptable segment is found, the cleanup includes calling * as_pageunlock before returning EFAULT. */ if (flags & DDI_UMEMLOCK_LONGTERM) { extern struct seg_ops segspt_shmops; AS_LOCK_ENTER(as, &as->a_lock, RW_READER); for (seg = as_segat(as, addr); ; seg = AS_SEGNEXT(as, seg)) { if (seg == NULL || seg->s_base > addr + len) break; if (((seg->s_ops != &segvn_ops) && (seg->s_ops != &segspt_shmops)) || ((SEGOP_GETVP(seg, addr, &vp) == 0 && vp != NULL && vp->v_type == VREG) && (SEGOP_GETTYPE(seg, addr) & MAP_SHARED))) { as_pageunlock(as, p->pparray, addr, len, p->s_flags); AS_LOCK_EXIT(as, &as->a_lock); umem_decr_devlockmem(p); kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; return (EFAULT); } } AS_LOCK_EXIT(as, &as->a_lock); } /* Initialize the fields in the ddi_umem_cookie */ p->cvaddr = addr; p->type = UMEM_LOCKED; if (driver_callback != NULL) { /* i_ddi_umem_unlock and umem_lock_undo may need the cookie */ p->cook_refcnt = 2; p->callbacks = *ops_vector; } else { /* only i_ddi_umme_unlock needs the cookie */ p->cook_refcnt = 1; } *cookie = (ddi_umem_cookie_t)p; /* * If a driver callback was specified, add an entry to the * as struct callback list. The as_pagelock above guarantees * the persistence of as. */ if (driver_callback) { error = as_add_callback(as, umem_lock_undo, p, AS_ALL_EVENT, addr, len, KM_SLEEP); if (error != 0) { as_pageunlock(as, p->pparray, addr, len, p->s_flags); umem_decr_devlockmem(p); kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; } } return (error); } /* * Unlock the pages locked by ddi_umem_lock or umem_lockmemory and free * the cookie. Called from i_ddi_umem_unlock_thread. */ static void i_ddi_umem_unlock(struct ddi_umem_cookie *p) { uint_t rc; /* * There is no way to determine whether a callback to * umem_lock_undo was registered via as_add_callback. * (i.e. umem_lockmemory was called with DDI_MEMLOCK_LONGTERM and * a valid callback function structure.) as_delete_callback * is called to delete a possible registered callback. If the * return from as_delete_callbacks is AS_CALLBACK_DELETED, it * indicates that there was a callback registered, and that is was * successfully deleted. Thus, the cookie reference count * will never be decremented by umem_lock_undo. Just return the * memory for the cookie, since both users of the cookie are done. * A return of AS_CALLBACK_NOTFOUND indicates a callback was * never registered. A return of AS_CALLBACK_DELETE_DEFERRED * indicates that callback processing is taking place and, and * umem_lock_undo is, or will be, executing, and thus decrementing * the cookie reference count when it is complete. * * This needs to be done before as_pageunlock so that the * persistence of as is guaranteed because of the locked pages. * */ rc = as_delete_callback(p->asp, p); /* * The proc->p_as will be stale if i_ddi_umem_unlock is called * after relvm is called so use p->asp. */ as_pageunlock(p->asp, p->pparray, p->cvaddr, p->size, p->s_flags); /* * Now that we have unlocked the memory decrement the * *.max-locked-memory rctl */ umem_decr_devlockmem(p); if (rc == AS_CALLBACK_DELETED) { /* umem_lock_undo will not happen, return the cookie memory */ ASSERT(p->cook_refcnt == 2); kmem_free(p, sizeof (struct ddi_umem_cookie)); } else { /* * umem_undo_lock may happen if as_delete_callback returned * AS_CALLBACK_DELETE_DEFERRED. In that case, decrement the * reference count, atomically, and return the cookie * memory if the reference count goes to zero. The only * other value for rc is AS_CALLBACK_NOTFOUND. In that * case, just return the cookie memory. */ if ((rc != AS_CALLBACK_DELETE_DEFERRED) || (atomic_add_long_nv((ulong_t *)(&(p->cook_refcnt)), -1) == 0)) { kmem_free(p, sizeof (struct ddi_umem_cookie)); } } } /* * i_ddi_umem_unlock_thread - deferred ddi_umem_unlock list handler. * * Call i_ddi_umem_unlock for entries in the ddi_umem_unlock list * until it is empty. Then, wait for more to be added. This thread is awoken * via calls to ddi_umem_unlock. */ static void i_ddi_umem_unlock_thread(void) { struct ddi_umem_cookie *ret_cookie; callb_cpr_t cprinfo; /* process the ddi_umem_unlock list */ CALLB_CPR_INIT(&cprinfo, &ddi_umem_unlock_mutex, callb_generic_cpr, "unlock_thread"); for (;;) { mutex_enter(&ddi_umem_unlock_mutex); if (ddi_umem_unlock_head != NULL) { /* list not empty */ ret_cookie = ddi_umem_unlock_head; /* take if off the list */ if ((ddi_umem_unlock_head = ddi_umem_unlock_head->unl_forw) == NULL) { ddi_umem_unlock_tail = NULL; } mutex_exit(&ddi_umem_unlock_mutex); /* unlock the pages in this cookie */ (void) i_ddi_umem_unlock(ret_cookie); } else { /* list is empty, wait for next ddi_umem_unlock */ CALLB_CPR_SAFE_BEGIN(&cprinfo); cv_wait(&ddi_umem_unlock_cv, &ddi_umem_unlock_mutex); CALLB_CPR_SAFE_END(&cprinfo, &ddi_umem_unlock_mutex); mutex_exit(&ddi_umem_unlock_mutex); } } /* ddi_umem_unlock_thread does not exit */ /* NOTREACHED */ } /* * Start the thread that will process the ddi_umem_unlock list if it is * not already started (i_ddi_umem_unlock_thread). */ static void i_ddi_umem_unlock_thread_start(void) { mutex_enter(&ddi_umem_unlock_mutex); if (ddi_umem_unlock_thread == NULL) { ddi_umem_unlock_thread = thread_create(NULL, 0, i_ddi_umem_unlock_thread, NULL, 0, &p0, TS_RUN, minclsyspri); } mutex_exit(&ddi_umem_unlock_mutex); } /* * Lock the virtual address range in the current process and create a * ddi_umem_cookie (of type UMEM_LOCKED). This can be used to pass to * ddi_umem_iosetup to create a buf or do devmap_umem_setup/remap to export * to user space. * * Note: The resource control accounting currently uses a full charge model * in other words attempts to lock the same/overlapping areas of memory * will deduct the full size of the buffer from the projects running * counter for the device locked memory. This applies to umem_lockmemory too. * * addr, size should be PAGESIZE aligned * flags - DDI_UMEMLOCK_READ, DDI_UMEMLOCK_WRITE or both * identifies whether the locked memory will be read or written or both * * Returns 0 on success * EINVAL - for invalid parameters * EPERM, ENOMEM and other error codes returned by as_pagelock * ENOMEM - is returned if the current request to lock memory exceeds * *.max-locked-memory resource control value. * EAGAIN - could not start the ddi_umem_unlock list processing thread */ int ddi_umem_lock(caddr_t addr, size_t len, int flags, ddi_umem_cookie_t *cookie) { int error; struct ddi_umem_cookie *p; *cookie = NULL; /* in case of any error return */ /* These are the only two valid flags */ if ((flags & ~(DDI_UMEMLOCK_READ | DDI_UMEMLOCK_WRITE)) != 0) { return (EINVAL); } /* At least one of the two flags (or both) must be set */ if ((flags & (DDI_UMEMLOCK_READ | DDI_UMEMLOCK_WRITE)) == 0) { return (EINVAL); } /* addr and len must be page-aligned */ if (((uintptr_t)addr & PAGEOFFSET) != 0) { return (EINVAL); } if ((len & PAGEOFFSET) != 0) { return (EINVAL); } /* * Call i_ddi_umem_unlock_thread_start if necessary. It will * be called on first ddi_umem_lock or umem_lockmemory call. */ if (ddi_umem_unlock_thread == NULL) i_ddi_umem_unlock_thread_start(); /* Allocate memory for the cookie */ p = kmem_zalloc(sizeof (struct ddi_umem_cookie), KM_SLEEP); /* Convert the flags to seg_rw type */ if (flags & DDI_UMEMLOCK_WRITE) { p->s_flags = S_WRITE; } else { p->s_flags = S_READ; } /* Store curproc in cookie for later iosetup/unlock */ p->procp = (void *)curproc; /* * Store the struct as pointer in cookie for later use by * ddi_umem_unlock. The proc->p_as will be stale if ddi_umem_unlock * is called after relvm is called. */ p->asp = curproc->p_as; /* * The size field is needed for lockmem accounting. */ p->size = len; if (umem_incr_devlockmem(p) != 0) { /* * The requested memory cannot be locked */ kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; return (ENOMEM); } /* Lock the pages corresponding to addr, len in memory */ error = as_pagelock(((proc_t *)p->procp)->p_as, &(p->pparray), addr, len, p->s_flags); if (error != 0) { umem_decr_devlockmem(p); kmem_free(p, sizeof (struct ddi_umem_cookie)); *cookie = (ddi_umem_cookie_t)NULL; return (error); } /* Initialize the fields in the ddi_umem_cookie */ p->cvaddr = addr; p->type = UMEM_LOCKED; p->cook_refcnt = 1; *cookie = (ddi_umem_cookie_t)p; return (error); } /* * Add the cookie to the ddi_umem_unlock list. Pages will be * unlocked by i_ddi_umem_unlock_thread. */ void ddi_umem_unlock(ddi_umem_cookie_t cookie) { struct ddi_umem_cookie *p = (struct ddi_umem_cookie *)cookie; ASSERT(p->type == UMEM_LOCKED); ASSERT(CPU_ON_INTR(CPU) == 0); /* cannot be high level */ ASSERT(ddi_umem_unlock_thread != NULL); p->unl_forw = (struct ddi_umem_cookie *)NULL; /* end of list */ /* * Queue the unlock request and notify i_ddi_umem_unlock thread * if it's called in the interrupt context. Otherwise, unlock pages * immediately. */ if (servicing_interrupt()) { /* queue the unlock request and notify the thread */ mutex_enter(&ddi_umem_unlock_mutex); if (ddi_umem_unlock_head == NULL) { ddi_umem_unlock_head = ddi_umem_unlock_tail = p; cv_broadcast(&ddi_umem_unlock_cv); } else { ddi_umem_unlock_tail->unl_forw = p; ddi_umem_unlock_tail = p; } mutex_exit(&ddi_umem_unlock_mutex); } else { /* unlock the pages right away */ (void) i_ddi_umem_unlock(p); } } /* * Create a buf structure from a ddi_umem_cookie * cookie - is a ddi_umem_cookie for from ddi_umem_lock and ddi_umem_alloc * (only UMEM_LOCKED & KMEM_NON_PAGEABLE types supported) * off, len - identifies the portion of the memory represented by the cookie * that the buf points to. * NOTE: off, len need to follow the alignment/size restrictions of the * device (dev) that this buf will be passed to. Some devices * will accept unrestricted alignment/size, whereas others (such as * st) require some block-size alignment/size. It is the caller's * responsibility to ensure that the alignment/size restrictions * are met (we cannot assert as we do not know the restrictions) * * direction - is one of B_READ or B_WRITE and needs to be compatible with * the flags used in ddi_umem_lock * * The following three arguments are used to initialize fields in the * buf structure and are uninterpreted by this routine. * * dev * blkno * iodone * * sleepflag - is one of DDI_UMEM_SLEEP or DDI_UMEM_NOSLEEP * * Returns a buf structure pointer on success (to be freed by freerbuf) * NULL on any parameter error or memory alloc failure * */ struct buf * ddi_umem_iosetup(ddi_umem_cookie_t cookie, off_t off, size_t len, int direction, dev_t dev, daddr_t blkno, int (*iodone)(struct buf *), int sleepflag) { struct ddi_umem_cookie *p = (struct ddi_umem_cookie *)cookie; struct buf *bp; /* * check for valid cookie offset, len */ if ((off + len) > p->size) { return (NULL); } if (len > p->size) { return (NULL); } /* direction has to be one of B_READ or B_WRITE */ if ((direction != B_READ) && (direction != B_WRITE)) { return (NULL); } /* These are the only two valid sleepflags */ if ((sleepflag != DDI_UMEM_SLEEP) && (sleepflag != DDI_UMEM_NOSLEEP)) { return (NULL); } /* * Only cookies of type UMEM_LOCKED and KMEM_NON_PAGEABLE are supported */ if ((p->type != UMEM_LOCKED) && (p->type != KMEM_NON_PAGEABLE)) { return (NULL); } /* If type is KMEM_NON_PAGEABLE procp is NULL */ ASSERT((p->type == KMEM_NON_PAGEABLE) ? (p->procp == NULL) : (p->procp != NULL)); bp = kmem_alloc(sizeof (struct buf), sleepflag); if (bp == NULL) { return (NULL); } bioinit(bp); bp->b_flags = B_BUSY | B_PHYS | direction; bp->b_edev = dev; bp->b_lblkno = blkno; bp->b_iodone = iodone; bp->b_bcount = len; bp->b_proc = (proc_t *)p->procp; ASSERT(((uintptr_t)(p->cvaddr) & PAGEOFFSET) == 0); bp->b_un.b_addr = (caddr_t)((uintptr_t)(p->cvaddr) + off); if (p->pparray != NULL) { bp->b_flags |= B_SHADOW; ASSERT(((uintptr_t)(p->cvaddr) & PAGEOFFSET) == 0); bp->b_shadow = p->pparray + btop(off); } return (bp); } /* * Fault-handling and related routines */ ddi_devstate_t ddi_get_devstate(dev_info_t *dip) { if (DEVI_IS_DEVICE_OFFLINE(dip)) return (DDI_DEVSTATE_OFFLINE); else if (DEVI_IS_DEVICE_DOWN(dip) || DEVI_IS_BUS_DOWN(dip)) return (DDI_DEVSTATE_DOWN); else if (DEVI_IS_BUS_QUIESCED(dip)) return (DDI_DEVSTATE_QUIESCED); else if (DEVI_IS_DEVICE_DEGRADED(dip)) return (DDI_DEVSTATE_DEGRADED); else return (DDI_DEVSTATE_UP); } void ddi_dev_report_fault(dev_info_t *dip, ddi_fault_impact_t impact, ddi_fault_location_t location, const char *message) { struct ddi_fault_event_data fd; ddi_eventcookie_t ec; /* * Assemble all the information into a fault-event-data structure */ fd.f_dip = dip; fd.f_impact = impact; fd.f_location = location; fd.f_message = message; fd.f_oldstate = ddi_get_devstate(dip); /* * Get eventcookie from defining parent. */ if (ddi_get_eventcookie(dip, DDI_DEVI_FAULT_EVENT, &ec) != DDI_SUCCESS) return; (void) ndi_post_event(dip, dip, ec, &fd); } char * i_ddi_devi_class(dev_info_t *dip) { return (DEVI(dip)->devi_device_class); } int i_ddi_set_devi_class(dev_info_t *dip, char *devi_class, int flag) { struct dev_info *devi = DEVI(dip); mutex_enter(&devi->devi_lock); if (devi->devi_device_class) kmem_free(devi->devi_device_class, strlen(devi->devi_device_class) + 1); if ((devi->devi_device_class = i_ddi_strdup(devi_class, flag)) != NULL) { mutex_exit(&devi->devi_lock); return (DDI_SUCCESS); } mutex_exit(&devi->devi_lock); return (DDI_FAILURE); } /* * Task Queues DDI interfaces. */ /* ARGSUSED */ ddi_taskq_t * ddi_taskq_create(dev_info_t *dip, const char *name, int nthreads, pri_t pri, uint_t cflags) { char full_name[TASKQ_NAMELEN]; const char *tq_name; int nodeid = 0; if (dip == NULL) tq_name = name; else { nodeid = ddi_get_instance(dip); if (name == NULL) name = "tq"; (void) snprintf(full_name, sizeof (full_name), "%s_%s", ddi_driver_name(dip), name); tq_name = full_name; } return ((ddi_taskq_t *)taskq_create_instance(tq_name, nodeid, nthreads, pri == TASKQ_DEFAULTPRI ? minclsyspri : pri, nthreads, INT_MAX, TASKQ_PREPOPULATE)); } void ddi_taskq_destroy(ddi_taskq_t *tq) { taskq_destroy((taskq_t *)tq); } int ddi_taskq_dispatch(ddi_taskq_t *tq, void (* func)(void *), void *arg, uint_t dflags) { taskqid_t id = taskq_dispatch((taskq_t *)tq, func, arg, dflags == DDI_SLEEP ? TQ_SLEEP : TQ_NOSLEEP); return (id != 0 ? DDI_SUCCESS : DDI_FAILURE); } void ddi_taskq_wait(ddi_taskq_t *tq) { taskq_wait((taskq_t *)tq); } void ddi_taskq_suspend(ddi_taskq_t *tq) { taskq_suspend((taskq_t *)tq); } boolean_t ddi_taskq_suspended(ddi_taskq_t *tq) { return (taskq_suspended((taskq_t *)tq)); } void ddi_taskq_resume(ddi_taskq_t *tq) { taskq_resume((taskq_t *)tq); } int ddi_parse( const char *ifname, char *alnum, uint_t *nump) { const char *p; int l; ulong_t num; boolean_t nonum = B_TRUE; char c; l = strlen(ifname); for (p = ifname + l; p != ifname; l--) { c = *--p; if (!isdigit(c)) { (void) strlcpy(alnum, ifname, l + 1); if (ddi_strtoul(p + 1, NULL, 10, &num) != 0) return (DDI_FAILURE); break; } nonum = B_FALSE; } if (l == 0 || nonum) return (DDI_FAILURE); *nump = num; return (DDI_SUCCESS); }