/* $OpenBSD: aml_common.c,v 1.1 2005/06/02 20:09:39 tholo Exp $ */ /*- * Copyright (c) 1999 Takanori Watanabe * Copyright (c) 1999, 2000 Mitsuru IWASAKI * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $Id: aml_common.c,v 1.1 2005/06/02 20:09:39 tholo Exp $ * $FreeBSD: src/usr.sbin/acpi/amldb/aml/aml_common.c,v 1.6 2000/11/09 06:24:45 iwasaki Exp $ */ #include #ifndef _KERNEL #include #include #include #include #include #include #else /* _KERNEL */ #include "opt_acpi.h" #include #include #include #include #include #include #include #ifndef ACPI_NO_OSDFUNC_INLINE #include #endif /* !ACPI_NO_OSDFUNC_INLINE */ #endif /* !_KERNEL */ #include #include #include #include #include #include #include #include /* for debugging */ #ifdef AML_DEBUG int aml_debug = 1; #else /* !AML_DEBUG */ int aml_debug = 0; #endif /* AML_DEBUG */ #ifdef _KERNEL SYSCTL_INT(_debug, OID_AUTO, aml_debug, CTLFLAG_RW, &aml_debug, 1, ""); #endif /* _KERNEL */ static void aml_print_nameseg(u_int8_t *dp); static void aml_print_nameseg(u_int8_t *dp) { if (dp[3] != '_') { AML_DEBUGPRINT("%c%c%c%c", dp[0], dp[1], dp[2], dp[3]); } else if (dp[2] != '_') { AML_DEBUGPRINT("%c%c%c_", dp[0], dp[1], dp[2]); } else if (dp[1] != '_') { AML_DEBUGPRINT("%c%c__", dp[0], dp[1]); } else if (dp[0] != '_') { AML_DEBUGPRINT("%c___", dp[0]); } } void aml_print_namestring(u_int8_t *dp) { int segcount; int i; if (dp[0] == '\\') { AML_DEBUGPRINT("%c", dp[0]); dp++; } else if (dp[0] == '^') { while (dp[0] == '^') { AML_DEBUGPRINT("%c", dp[0]); dp++; } } if (dp[0] == 0x00) { /* NullName */ /* AML_DEBUGPRINT(""); */ dp++; } else if (dp[0] == 0x2e) { /* DualNamePrefix */ aml_print_nameseg(dp + 1); AML_DEBUGPRINT("%c", '.'); aml_print_nameseg(dp + 5); } else if (dp[0] == 0x2f) { /* MultiNamePrefix */ segcount = dp[1]; for (i = 0, dp += 2; i < segcount; i++, dp += 4) { if (i > 0) { AML_DEBUGPRINT("%c", '.'); } aml_print_nameseg(dp); } } else /* NameSeg */ aml_print_nameseg(dp); } int aml_print_curname(struct aml_name *name) { struct aml_name *root; root = aml_get_rootname(); if (name == root) { AML_DEBUGPRINT("\\"); return (0); } else { aml_print_curname(name->parent); } aml_print_nameseg(name->name); AML_DEBUGPRINT("."); return (0); } void aml_print_indent(int indent) { int i; for (i = 0; i < indent; i++) AML_DEBUGPRINT(" "); } void aml_showobject(union aml_object * obj) { int debug; int i; if (obj == NULL) { printf("NO object\n"); return; } debug = aml_debug; aml_debug = 1; switch (obj->type) { case aml_t_num: printf("Num:0x%x\n", obj->num.number); break; case aml_t_processor: printf("Processor:No %d,Port 0x%x length 0x%x\n", obj->proc.id, obj->proc.addr, obj->proc.len); break; case aml_t_mutex: printf("Mutex:Level %d\n", obj->mutex.level); break; case aml_t_powerres: printf("PowerResource:Level %d Order %d\n", obj->pres.level, obj->pres.order); break; case aml_t_opregion: printf("OprationRegion:Busspace%d, Offset 0x%x Length 0x%x\n", obj->opregion.space, obj->opregion.offset, obj->opregion.length); break; case aml_t_field: printf("Fieldelement:flag 0x%x offset 0x%x len 0x%x {", obj->field.flags, obj->field.bitoffset, obj->field.bitlen); switch (obj->field.f.ftype) { case f_t_field: aml_print_namestring(obj->field.f.fld.regname); break; case f_t_index: aml_print_namestring(obj->field.f.ifld.indexname); printf(" "); aml_print_namestring(obj->field.f.ifld.dataname); break; case f_t_bank: aml_print_namestring(obj->field.f.bfld.regname); printf(" "); aml_print_namestring(obj->field.f.bfld.bankname); printf("0x%x", obj->field.f.bfld.bankvalue); break; } printf("}\n"); break; case aml_t_method: printf("Method: Arg %d From %p To %p\n", obj->meth.argnum, obj->meth.from, obj->meth.to); break; case aml_t_buffer: printf("Buffer: size:0x%x Data %p\n", obj->buffer.size, obj->buffer.data); break; case aml_t_device: printf("Device\n"); break; case aml_t_bufferfield: printf("Bufferfield:offset 0x%x len 0x%x Origin %p\n", obj->bfld.bitoffset, obj->bfld.bitlen, obj->bfld.origin); break; case aml_t_string: printf("String:%s\n", obj->str.string); break; case aml_t_package: printf("Package:elements %d \n", obj->package.elements); for (i = 0; i < obj->package.elements; i++) { if (obj->package.objects[i] == NULL) { break; } if (obj->package.objects[i]->type < 0) { continue; } printf(" "); aml_showobject(obj->package.objects[i]); } break; case aml_t_therm: printf("Thermalzone\n"); break; case aml_t_event: printf("Event\n"); break; case aml_t_ddbhandle: printf("DDBHANDLE\n"); break; case aml_t_objref: if (obj->objref.alias == 1) { printf("Alias"); } else { printf("Object reference"); if (obj->objref.offset >= 0) { printf(" (offset 0x%x)", obj->objref.offset); } } printf(" of "); aml_showobject(obj->objref.ref); break; default: printf("UNK ID=%d\n", obj->type); } aml_debug = debug; } void aml_showtree(struct aml_name * aname, int lev) { int i; struct aml_name *ptr; char name[5]; for (i = 0; i < lev; i++) { printf(" "); } strncpy(name, aname->name, 4); name[4] = 0; printf("%s ", name); if (aname->property != NULL) { aml_showobject(aname->property); } else { printf("\n"); } for (ptr = aname->child; ptr; ptr = ptr->brother) aml_showtree(ptr, lev + 1); } /* * Common Region I/O Stuff */ static __inline u_int64_t aml_adjust_bitmask(u_int32_t flags, u_int32_t bitlen) { u_int64_t bitmask; switch (AML_FIELDFLAGS_ACCESSTYPE(flags)) { case AML_FIELDFLAGS_ACCESS_ANYACC: if (bitlen <= 8) { bitmask = 0x000000ff; break; } if (bitlen <= 16) { bitmask = 0x0000ffff; break; } bitmask = 0xffffffff; break; case AML_FIELDFLAGS_ACCESS_BYTEACC: bitmask = 0x000000ff; break; case AML_FIELDFLAGS_ACCESS_WORDACC: bitmask = 0x0000ffff; break; case AML_FIELDFLAGS_ACCESS_DWORDACC: default: bitmask = 0xffffffff; break; } switch (bitlen) { case 16: bitmask |= 0x0000ffff; break; case 32: bitmask |= 0xffffffff; break; } return (bitmask); } u_int32_t aml_adjust_readvalue(u_int32_t flags, u_int32_t bitoffset, u_int32_t bitlen, u_int32_t orgval) { u_int32_t offset, retval; u_int64_t bitmask; offset = bitoffset; /* XXX bitoffset may change in this function! */ bitmask = aml_adjust_bitmask(flags, bitlen); retval = (orgval >> offset) & (~(bitmask << bitlen)) & bitmask; return (retval); } u_int32_t aml_adjust_updatevalue(u_int32_t flags, u_int32_t bitoffset, u_int32_t bitlen, u_int32_t orgval, u_int32_t value) { u_int32_t offset, retval; u_int64_t bitmask; offset = bitoffset; /* XXX bitoffset may change in this function! */ bitmask = aml_adjust_bitmask(flags, bitlen); retval = orgval; switch (AML_FIELDFLAGS_UPDATERULE(flags)) { case AML_FIELDFLAGS_UPDATE_PRESERVE: retval &= (~(((u_int64_t)1 << bitlen) - 1) << offset) | (~(bitmask << offset)); break; case AML_FIELDFLAGS_UPDATE_WRITEASONES: retval = (~(((u_int64_t)1 << bitlen) - 1) << offset) | (~(bitmask << offset)); retval &= bitmask; /* trim the upper bits */ break; case AML_FIELDFLAGS_UPDATE_WRITEASZEROS: retval = 0; break; default: printf("illegal update rule: %d\n", flags); return (orgval); } retval |= (value << (offset & bitmask)); return (retval); } /* * BufferField I/O */ #define AML_BUFFER_INPUT 0 #define AML_BUFFER_OUTPUT 1 static int aml_bufferfield_io(int io, u_int32_t *valuep, u_int8_t *origin, u_int32_t bitoffset, u_int32_t bitlen); static int aml_bufferfield_io(int io, u_int32_t *valuep, u_int8_t *origin, u_int32_t bitoffset, u_int32_t bitlen) { u_int8_t val, tmp, masklow, maskhigh; u_int8_t offsetlow, offsethigh; u_int8_t *addr; int i; u_int32_t value, readval; u_int32_t byteoffset, bytelen; masklow = maskhigh = 0xff; val = readval = 0; value = *valuep; byteoffset = bitoffset / 8; bytelen = bitlen / 8 + ((bitlen % 8) ? 1 : 0); addr = origin + byteoffset; /* simple I/O ? */ if (bitlen <= 8 || bitlen == 16 || bitlen == 32) { bcopy(addr, &readval, bytelen); AML_DEBUGPRINT("\n\t[bufferfield:0x%x@%p:%d,%d]", readval, addr, bitoffset % 8, bitlen); switch (io) { case AML_BUFFER_INPUT: value = aml_adjust_readvalue(AML_FIELDFLAGS_ACCESS_BYTEACC, bitoffset % 8, bitlen, readval); *valuep = value; AML_DEBUGPRINT("\n[read(bufferfield, %p)&mask:0x%x]\n", addr, value); break; case AML_BUFFER_OUTPUT: value = aml_adjust_updatevalue(AML_FIELDFLAGS_ACCESS_BYTEACC, bitoffset % 8, bitlen, readval, value); bcopy(&value, addr, bytelen); AML_DEBUGPRINT("->[bufferfield:0x%x@%p:%d,%d]", value, addr, bitoffset % 8, bitlen); break; } goto out; } offsetlow = bitoffset % 8; if (bytelen > 1) { offsethigh = (bitlen - (8 - offsetlow)) % 8; } else { offsethigh = 0; } if (offsetlow) { masklow = (~((1 << bitlen) - 1) << offsetlow) | ~(0xff << offsetlow); AML_DEBUGPRINT("\t[offsetlow = 0x%x, masklow = 0x%x, ~masklow = 0x%x]\n", offsetlow, masklow, ~masklow & 0xff); } if (offsethigh) { maskhigh = 0xff << offsethigh; AML_DEBUGPRINT("\t[offsethigh = 0x%x, maskhigh = 0x%x, ~maskhigh = 0x%x]\n", offsethigh, maskhigh, ~maskhigh & 0xff); } for (i = bytelen; i > 0; i--, addr++) { val = *addr; AML_DEBUGPRINT("\t[bufferfield:0x%02x@%p]", val, addr); switch (io) { case AML_BUFFER_INPUT: tmp = val; /* the lowest byte? */ if (i == bytelen) { if (offsetlow) { readval = tmp & ~masklow; } else { readval = tmp; } } else { if (i == 1 && offsethigh) { tmp = tmp & ~maskhigh; } readval = (tmp << (8 * (bytelen - i))) | readval; } AML_DEBUGPRINT("\n"); /* goto to next byte... */ if (i > 1) { continue; } /* final adjustment before finishing region access */ if (offsetlow) { readval = readval >> offsetlow; } AML_DEBUGPRINT("[read(bufferfield, %p)&mask:0x%x]\n", addr, readval); *valuep = readval; break; case AML_BUFFER_OUTPUT: tmp = value & 0xff; /* the lowest byte? */ if (i == bytelen) { if (offsetlow) { tmp = (val & masklow) | tmp << offsetlow; } value = value >> (8 - offsetlow); } else { if (i == 1 && offsethigh) { tmp = (val & maskhigh) | tmp; } value = value >> 8; } AML_DEBUGPRINT("->[bufferfield:0x%02x@%p]\n", tmp, addr); *addr = tmp; } } out: return (0); } u_int32_t aml_bufferfield_read(u_int8_t *origin, u_int32_t bitoffset, u_int32_t bitlen) { int value; value = 0; aml_bufferfield_io(AML_BUFFER_INPUT, &value, origin, bitoffset, bitlen); return (value); } int aml_bufferfield_write(u_int32_t value, u_int8_t *origin, u_int32_t bitoffset, u_int32_t bitlen) { int status; status = aml_bufferfield_io(AML_BUFFER_OUTPUT, &value, origin, bitoffset, bitlen); return (status); } int aml_region_handle_alloc(struct aml_environ *env, int regtype, u_int32_t flags, u_int32_t baseaddr, u_int32_t bitoffset, u_int32_t bitlen, struct aml_region_handle *h) { int state; struct aml_name *pci_info; state = 0; pci_info = NULL; bzero(h, sizeof(struct aml_region_handle)); h->env = env; h->regtype = regtype; h->flags = flags; h->baseaddr = baseaddr; h->bitoffset = bitoffset; h->bitlen = bitlen; switch (AML_FIELDFLAGS_ACCESSTYPE(flags)) { case AML_FIELDFLAGS_ACCESS_ANYACC: if (bitlen <= 8) { h->unit = 1; break; } if (bitlen <= 16) { h->unit = 2; break; } h->unit = 4; break; case AML_FIELDFLAGS_ACCESS_BYTEACC: h->unit = 1; break; case AML_FIELDFLAGS_ACCESS_WORDACC: h->unit = 2; break; case AML_FIELDFLAGS_ACCESS_DWORDACC: h->unit = 4; break; default: h->unit = 1; break; } h->addr = baseaddr + h->unit * ((bitoffset / 8) / h->unit); h->bytelen = baseaddr + ((bitoffset + bitlen) / 8) - h->addr + ((bitlen % 8) ? 1 : 0); #ifdef _KERNEL switch (h->regtype) { case AML_REGION_SYSMEM: OsdMapMemory((void *)h->addr, h->bytelen, (void **)&h->vaddr); break; case AML_REGION_PCICFG: /* Obtain PCI bus number */ pci_info = aml_search_name(env, "_BBN"); if (pci_info == NULL || pci_info->property->type != aml_t_num) { AML_DEBUGPRINT("Cannot locate _BBN. Using default 0\n"); h->pci_bus = 0; } else { AML_DEBUGPRINT("found _BBN: %d\n", pci_info->property->num.number); h->pci_bus = pci_info->property->num.number & 0xff; } /* Obtain device & function number */ pci_info = aml_search_name(env, "_ADR"); if (pci_info == NULL || pci_info->property->type != aml_t_num) { printf("Cannot locate: _ADR\n"); state = -1; goto out; } h->pci_devfunc = pci_info->property->num.number; AML_DEBUGPRINT("[pci%d.%d]", h->pci_bus, h->pci_devfunc); break; default: break; } out: #endif /* _KERNEL */ return (state); } void aml_region_handle_free(struct aml_region_handle *h) { #ifdef _KERNEL switch (h->regtype) { case AML_REGION_SYSMEM: OsdUnMapMemory((void *)h->vaddr, h->bytelen); break; default: break; } #endif /* _KERNEL */ } static int aml_region_io_simple(struct aml_environ *env, int io, int regtype, u_int32_t flags, u_int32_t *valuep, u_int32_t baseaddr, u_int32_t bitoffset, u_int32_t bitlen) { int i, state; u_int32_t readval, value, offset, bytelen; struct aml_region_handle handle; state = aml_region_handle_alloc(env, regtype, flags, baseaddr, bitoffset, bitlen, &handle); if (state == -1) { goto out; } readval = 0; offset = bitoffset % (handle.unit * 8); /* limitation of 32 bits alignment */ bytelen = (handle.bytelen > 4) ? 4 : handle.bytelen; if (io == AML_REGION_INPUT || AML_FIELDFLAGS_UPDATERULE(flags) == AML_FIELDFLAGS_UPDATE_PRESERVE) { for (i = 0; i < bytelen; i += handle.unit) { state = aml_region_read_simple(&handle, i, &value); if (state == -1) { goto out; } readval |= (value << (i * 8)); } AML_DEBUGPRINT("\t[%d:0x%x@0x%x:%d,%d]", regtype, readval, handle.addr, offset, bitlen); } switch (io) { case AML_REGION_INPUT: AML_DEBUGPRINT("\n"); readval = aml_adjust_readvalue(flags, offset, bitlen, readval); value = readval; value = aml_region_prompt_read(&handle, value); state = aml_region_prompt_update_value(readval, value, &handle); if (state == -1) { goto out; } *valuep = value; break; case AML_REGION_OUTPUT: value = *valuep; value = aml_adjust_updatevalue(flags, offset, bitlen, readval, value); value = aml_region_prompt_write(&handle, value); AML_DEBUGPRINT("\t->[%d:0x%x@0x%x:%d,%d]\n", regtype, value, handle.addr, offset, bitlen); for (i = 0; i < bytelen; i += handle.unit) { state = aml_region_write_simple(&handle, i, value); if (state == -1) { goto out; } value = value >> (handle.unit * 8); } break; } aml_region_handle_free(&handle); out: return (state); } int aml_region_io(struct aml_environ *env, int io, int regtype, u_int32_t flags, u_int32_t *valuep, u_int32_t baseaddr, u_int32_t bitoffset, u_int32_t bitlen) { u_int32_t unit, offset; u_int32_t offadj, bitadj; u_int32_t value, readval; int state, i; readval = 0; state = 0; unit = 4; /* limitation of 32 bits alignment */ offset = bitoffset % (unit * 8); offadj = 0; bitadj = 0; if (offset + bitlen > unit * 8) { bitadj = bitlen - (unit * 8 - offset); } for (i = 0; i < offset + bitlen; i += unit * 8) { value = (*valuep) >> offadj; state = aml_region_io_simple(env, io, regtype, flags, &value, baseaddr, bitoffset + offadj, bitlen - bitadj); if (state == -1) { goto out; } readval |= value << offadj; bitadj = offadj = bitlen - bitadj; } *valuep = readval; out: return (state); }