/* $OpenBSD: dsdt.c,v 1.156 2009/11/13 11:39:56 jordan Exp $ */ /* * Copyright (c) 2005 Jordan Hargrave * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #ifdef DDB #include #include #endif #include #include #include #include #ifdef SMALL_KERNEL #undef ACPI_DEBUG #endif #define opsize(opcode) (((opcode) & 0xFF00) ? 2 : 1) #define AML_FIELD_RESERVED 0x00 #define AML_FIELD_ATTRIB 0x01 #define AML_REVISION 0x01 #define AML_INTSTRLEN 16 #define AML_NAMESEG_LEN 4 void aml_copyvalue(struct aml_value *, struct aml_value *); void aml_setvalue(struct aml_scope *, struct aml_value *, struct aml_value *, int64_t); void aml_freevalue(struct aml_value *); struct aml_value *aml_allocvalue(int, int64_t, const void *); struct aml_value *_aml_setvalue(struct aml_value *, int, int64_t, const void *); u_int64_t aml_convradix(u_int64_t, int, int); int64_t aml_evalexpr(int64_t, int64_t, int); int aml_lsb(u_int64_t); int aml_msb(u_int64_t); int aml_tstbit(const u_int8_t *, int); void aml_setbit(u_int8_t *, int, int); void aml_xaddref(struct aml_value *, const char *); void aml_xdelref(struct aml_value **, const char *); void aml_bufcpy(void *, int, const void *, int, int); int aml_pc(uint8_t *); struct aml_value *aml_parseop(struct aml_scope *, struct aml_value *,int); struct aml_value *aml_parsetarget(struct aml_scope *, struct aml_value *, struct aml_value **); struct aml_value *aml_parseterm(struct aml_scope *, struct aml_value *); struct aml_value *aml_evaltarget(struct aml_scope *scope, struct aml_value *res); int aml_evalterm(struct aml_scope *scope, struct aml_value *raw, struct aml_value *dst); struct aml_opcode *aml_findopcode(int); #define acpi_os_malloc(sz) _acpi_os_malloc(sz, __FUNCTION__, __LINE__) #define acpi_os_free(ptr) _acpi_os_free(ptr, __FUNCTION__, __LINE__) void *_acpi_os_malloc(size_t, const char *, int); void _acpi_os_free(void *, const char *, int); void acpi_sleep(int); void acpi_stall(int); uint8_t *aml_xparsename(uint8_t *pos, struct aml_node *node, void (*fn)(struct aml_node *, int, uint8_t *, void *), void *arg); void ns_xcreate(struct aml_node *node, int n, uint8_t *pos, void *arg); void ns_xdis(struct aml_node *node, int n, uint8_t *pos, void *arg); void ns_xsearch(struct aml_node *node, int n, uint8_t *pos, void *arg); struct aml_value *aml_callosi(struct aml_scope *, struct aml_value *); const char *aml_getname(const char *); int64_t aml_hextoint(const char *); void aml_dump(int, u_int8_t *); void _aml_die(const char *fn, int line, const char *fmt, ...); #define aml_die(x...) _aml_die(__FUNCTION__, __LINE__, x) /* * @@@: Global variables */ int aml_intlen = 64; struct aml_node aml_root; struct aml_value *aml_global_lock; struct acpi_softc *dsdt_softc; /* Perfect Hash key */ #define HASH_OFF 6904 #define HASH_SIZE 179 #define HASH_KEY(k) (((k) ^ HASH_OFF) % HASH_SIZE) /* * XXX this array should be sorted, and then aml_findopcode() should * do a binary search */ struct aml_opcode **aml_ophash; struct aml_opcode aml_table[] = { /* Simple types */ { AMLOP_ZERO, "Zero", "c", }, { AMLOP_ONE, "One", "c", }, { AMLOP_ONES, "Ones", "c", }, { AMLOP_REVISION, "Revision", "R", }, { AMLOP_BYTEPREFIX, ".Byte", "b", }, { AMLOP_WORDPREFIX, ".Word", "w", }, { AMLOP_DWORDPREFIX, ".DWord", "d", }, { AMLOP_QWORDPREFIX, ".QWord", "q", }, { AMLOP_STRINGPREFIX, ".String", "a", }, { AMLOP_DEBUG, "DebugOp", "D", }, { AMLOP_BUFFER, "Buffer", "piB", }, { AMLOP_PACKAGE, "Package", "pbT", }, { AMLOP_VARPACKAGE, "VarPackage", "piT", }, /* Simple objects */ { AMLOP_LOCAL0, "Local0", "L", }, { AMLOP_LOCAL1, "Local1", "L", }, { AMLOP_LOCAL2, "Local2", "L", }, { AMLOP_LOCAL3, "Local3", "L", }, { AMLOP_LOCAL4, "Local4", "L", }, { AMLOP_LOCAL5, "Local5", "L", }, { AMLOP_LOCAL6, "Local6", "L", }, { AMLOP_LOCAL7, "Local7", "L", }, { AMLOP_ARG0, "Arg0", "A", }, { AMLOP_ARG1, "Arg1", "A", }, { AMLOP_ARG2, "Arg2", "A", }, { AMLOP_ARG3, "Arg3", "A", }, { AMLOP_ARG4, "Arg4", "A", }, { AMLOP_ARG5, "Arg5", "A", }, { AMLOP_ARG6, "Arg6", "A", }, /* Control flow */ { AMLOP_IF, "If", "piI", }, { AMLOP_ELSE, "Else", "pT" }, { AMLOP_WHILE, "While", "piT", }, { AMLOP_BREAK, "Break", "" }, { AMLOP_CONTINUE, "Continue", "" }, { AMLOP_RETURN, "Return", "t", }, { AMLOP_FATAL, "Fatal", "bdi", }, { AMLOP_NOP, "Nop", "", }, { AMLOP_BREAKPOINT, "BreakPoint", "", }, /* Arithmetic operations */ { AMLOP_INCREMENT, "Increment", "S", }, { AMLOP_DECREMENT, "Decrement", "S", }, { AMLOP_ADD, "Add", "iir", }, { AMLOP_SUBTRACT, "Subtract", "iir", }, { AMLOP_MULTIPLY, "Multiply", "iir", }, { AMLOP_DIVIDE, "Divide", "iirr", }, { AMLOP_SHL, "ShiftLeft", "iir", }, { AMLOP_SHR, "ShiftRight", "iir", }, { AMLOP_AND, "And", "iir", }, { AMLOP_NAND, "Nand", "iir", }, { AMLOP_OR, "Or", "iir", }, { AMLOP_NOR, "Nor", "iir", }, { AMLOP_XOR, "Xor", "iir", }, { AMLOP_NOT, "Not", "ir", }, { AMLOP_MOD, "Mod", "iir", }, { AMLOP_FINDSETLEFTBIT, "FindSetLeftBit", "ir", }, { AMLOP_FINDSETRIGHTBIT,"FindSetRightBit", "ir",}, /* Logical test operations */ { AMLOP_LAND, "LAnd", "ii", }, { AMLOP_LOR, "LOr", "ii", }, { AMLOP_LNOT, "LNot", "i", }, { AMLOP_LNOTEQUAL, "LNotEqual", "tt", }, { AMLOP_LLESSEQUAL, "LLessEqual", "tt", }, { AMLOP_LGREATEREQUAL, "LGreaterEqual", "tt", }, { AMLOP_LEQUAL, "LEqual", "tt", }, { AMLOP_LGREATER, "LGreater", "tt", }, { AMLOP_LLESS, "LLess", "tt", }, /* Named objects */ { AMLOP_NAMECHAR, ".NameRef", "n", }, { AMLOP_ALIAS, "Alias", "nN", }, { AMLOP_NAME, "Name", "Nt", }, { AMLOP_EVENT, "Event", "N", }, { AMLOP_MUTEX, "Mutex", "Nb", }, { AMLOP_DATAREGION, "DataRegion", "Nttt", }, { AMLOP_OPREGION, "OpRegion", "Nbii", }, { AMLOP_SCOPE, "Scope", "pnT", }, { AMLOP_DEVICE, "Device", "pNT", }, { AMLOP_POWERRSRC, "Power Resource", "pNbwT",}, { AMLOP_THERMALZONE, "ThermalZone", "pNT", }, { AMLOP_PROCESSOR, "Processor", "pNbdbT", }, { AMLOP_METHOD, "Method", "pNbM", }, /* Field operations */ { AMLOP_FIELD, "Field", "pnbF", }, { AMLOP_INDEXFIELD, "IndexField", "pnnbF",}, { AMLOP_BANKFIELD, "BankField", "pnnibF",}, { AMLOP_CREATEFIELD, "CreateField", "tiiN", }, { AMLOP_CREATEQWORDFIELD, "CreateQWordField","tiN",}, { AMLOP_CREATEDWORDFIELD, "CreateDWordField","tiN",}, { AMLOP_CREATEWORDFIELD, "CreateWordField", "tiN",}, { AMLOP_CREATEBYTEFIELD, "CreateByteField", "tiN",}, { AMLOP_CREATEBITFIELD, "CreateBitField", "tiN", }, /* Conversion operations */ { AMLOP_TOINTEGER, "ToInteger", "tr", }, { AMLOP_TOBUFFER, "ToBuffer", "tr", }, { AMLOP_TODECSTRING, "ToDecString", "ir", }, { AMLOP_TOHEXSTRING, "ToHexString", "ir", }, { AMLOP_TOSTRING, "ToString", "tir", }, { AMLOP_MID, "Mid", "tiir", }, { AMLOP_FROMBCD, "FromBCD", "ir", }, { AMLOP_TOBCD, "ToBCD", "ir", }, /* Mutex/Signal operations */ { AMLOP_ACQUIRE, "Acquire", "Sw", }, { AMLOP_RELEASE, "Release", "S", }, { AMLOP_SIGNAL, "Signal", "S", }, { AMLOP_WAIT, "Wait", "Si", }, { AMLOP_RESET, "Reset", "S", }, { AMLOP_INDEX, "Index", "tir", }, { AMLOP_DEREFOF, "DerefOf", "t", }, { AMLOP_REFOF, "RefOf", "S", }, { AMLOP_CONDREFOF, "CondRef", "SS", }, { AMLOP_LOADTABLE, "LoadTable", "tttttt" }, { AMLOP_STALL, "Stall", "i", }, { AMLOP_SLEEP, "Sleep", "i", }, { AMLOP_LOAD, "Load", "nS", }, { AMLOP_UNLOAD, "Unload", "t" }, { AMLOP_STORE, "Store", "tS", }, { AMLOP_CONCAT, "Concat", "ttr", }, { AMLOP_CONCATRES, "ConcatRes", "ttt" }, { AMLOP_NOTIFY, "Notify", "Si", }, { AMLOP_SIZEOF, "Sizeof", "S", }, { AMLOP_MATCH, "Match", "tbibii", }, { AMLOP_OBJECTTYPE, "ObjectType", "S", }, { AMLOP_COPYOBJECT, "CopyObject", "tS", }, }; int aml_pc(uint8_t *src) { return src - aml_root.start; } struct aml_scope *aml_lastscope; void _aml_die(const char *fn, int line, const char *fmt, ...) { #ifndef SMALL_KERNEL struct aml_scope *root; struct aml_value *sp; int idx; #endif /* SMALL_KERNEL */ va_list ap; va_start(ap, fmt); vprintf(fmt, ap); printf("\n"); va_end(ap); #ifndef SMALL_KERNEL for (root = aml_lastscope; root && root->pos; root = root->parent) { printf("%.4x Called: %s\n", aml_pc(root->pos), aml_nodename(root->node)); for (idx = 0; idx < AML_MAX_ARG; idx++) { sp = aml_getstack(root, AMLOP_ARG0+idx); if (sp && sp->type) { printf(" arg%d: ", idx); aml_showvalue(sp, 0); } } for (idx = 0; idx < AML_MAX_LOCAL; idx++) { sp = aml_getstack(root, AMLOP_LOCAL0+idx); if (sp && sp->type) { printf(" local%d: ", idx); aml_showvalue(sp, 0); } } } #endif /* SMALL_KERNEL */ /* XXX: don't panic */ panic("aml_die %s:%d", fn, line); } void aml_hashopcodes(void) { int i; /* Dynamically allocate hash table */ aml_ophash = (struct aml_opcode **)acpi_os_malloc(HASH_SIZE*sizeof(struct aml_opcode *)); for (i = 0; i < sizeof(aml_table) / sizeof(aml_table[0]); i++) aml_ophash[HASH_KEY(aml_table[i].opcode)] = &aml_table[i]; } struct aml_opcode * aml_findopcode(int opcode) { struct aml_opcode *hop; hop = aml_ophash[HASH_KEY(opcode)]; if (hop && hop->opcode == opcode) return hop; return NULL; } #ifndef SMALL_KERNEL const char * aml_mnem(int opcode, uint8_t *pos) { struct aml_opcode *tab; static char mnemstr[32]; if ((tab = aml_findopcode(opcode)) != NULL) { strlcpy(mnemstr, tab->mnem, sizeof(mnemstr)); if (pos != NULL) { switch (opcode) { case AMLOP_STRINGPREFIX: snprintf(mnemstr, sizeof(mnemstr), "\"%s\"", pos); break; case AMLOP_BYTEPREFIX: snprintf(mnemstr, sizeof(mnemstr), "0x%.2x", *(uint8_t *)pos); break; case AMLOP_WORDPREFIX: snprintf(mnemstr, sizeof(mnemstr), "0x%.4x", *(uint16_t *)pos); break; case AMLOP_DWORDPREFIX: snprintf(mnemstr, sizeof(mnemstr), "0x%.4x", *(uint16_t *)pos); break; case AMLOP_NAMECHAR: strlcpy(mnemstr, aml_getname(pos), sizeof(mnemstr)); break; } } return mnemstr; } return ("xxx"); } #endif /* SMALL_KERNEL */ struct aml_notify_data { struct aml_node *node; char pnpid[20]; void *cbarg; int (*cbproc)(struct aml_node *, int, void *); int poll; SLIST_ENTRY(aml_notify_data) link; }; SLIST_HEAD(aml_notify_head, aml_notify_data); struct aml_notify_head aml_notify_list = LIST_HEAD_INITIALIZER(&aml_notify_list); /* * @@@: Memory management functions */ long acpi_nalloc; struct acpi_memblock { size_t size; #ifdef ACPI_MEMDEBUG const char *fn; int line; int sig; LIST_ENTRY(acpi_memblock) link; #endif }; #ifdef ACPI_MEMDEBUG LIST_HEAD(, acpi_memblock) acpi_memhead; #endif int acpi_memsig; void * _acpi_os_malloc(size_t size, const char *fn, int line) { struct acpi_memblock *sptr; sptr = malloc(size+sizeof(*sptr), M_ACPI, M_WAITOK | M_ZERO); dnprintf(99, "alloc: %x %s:%d\n", sptr, fn, line); acpi_nalloc += size; sptr->size = size; #ifdef ACPI_MEMDEBUG sptr->line = line; sptr->fn = fn; sptr->sig = ++acpi_memsig; LIST_INSERT_HEAD(&acpi_memhead, sptr, link); #endif return &sptr[1]; } void _acpi_os_free(void *ptr, const char *fn, int line) { struct acpi_memblock *sptr; if (ptr != NULL) { sptr = &(((struct acpi_memblock *)ptr)[-1]); acpi_nalloc -= sptr->size; #ifdef ACPI_MEMDEBUG LIST_REMOVE(sptr, link); #endif dnprintf(99, "free: %x %s:%d\n", sptr, fn, line); free(sptr, M_ACPI); } } int acpi_walkmem(int sig, const char *lbl) { #ifdef ACPI_MEMDEBUG struct acpi_memblock *sptr; printf("--- walkmem:%s %x --- %x bytes alloced\n", lbl, sig, acpi_nalloc); LIST_FOREACH(sptr, &acpi_memhead, link) { if (sptr->sig < sig) break; printf("%.4x Alloc %.8lx bytes @ %s:%d\n", sptr->sig, sptr->size, sptr->fn, sptr->line); } #endif return acpi_memsig; } void acpi_sleep(int ms) { int to = ms * hz / 1000; if (cold) delay(ms * 1000); else { if (to <= 0) to = 1; while (tsleep(dsdt_softc, PWAIT, "asleep", to) != EWOULDBLOCK); } } void acpi_stall(int us) { delay(us); } /* * @@@: Misc utility functions */ #ifdef ACPI_DEBUG void aml_dump(int len, u_int8_t *buf) { int idx; dnprintf(50, "{ "); for (idx = 0; idx < len; idx++) { dnprintf(50, "%s0x%.2x", idx ? ", " : "", buf[idx]); } dnprintf(50, " }\n"); } #endif /* Bit mangling code */ int aml_tstbit(const u_int8_t *pb, int bit) { pb += aml_bytepos(bit); return (*pb & aml_bitmask(bit)); } void aml_setbit(u_int8_t *pb, int bit, int val) { pb += aml_bytepos(bit); if (val) *pb |= aml_bitmask(bit); else *pb &= ~aml_bitmask(bit); } /* * @@@: Notify functions */ void acpi_poll(void *arg) { dsdt_softc->sc_poll = 1; dsdt_softc->sc_wakeup = 0; wakeup(dsdt_softc); timeout_add_sec(&dsdt_softc->sc_dev_timeout, 10); } void aml_register_notify(struct aml_node *node, const char *pnpid, int (*proc)(struct aml_node *, int, void *), void *arg, int poll) { struct aml_notify_data *pdata; extern int acpi_poll_enabled; dnprintf(10, "aml_register_notify: %s %s %x\n", node->name, pnpid ? pnpid : "", proc); pdata = acpi_os_malloc(sizeof(struct aml_notify_data)); pdata->node = node; pdata->cbarg = arg; pdata->cbproc = proc; pdata->poll = poll; if (pnpid) strlcpy(pdata->pnpid, pnpid, sizeof(pdata->pnpid)); SLIST_INSERT_HEAD(&aml_notify_list, pdata, link); if (poll && !acpi_poll_enabled) timeout_add_sec(&dsdt_softc->sc_dev_timeout, 10); } void aml_notify(struct aml_node *node, int notify_value) { struct aml_notify_data *pdata = NULL; if (node == NULL) return; SLIST_FOREACH(pdata, &aml_notify_list, link) if (pdata->node == node) pdata->cbproc(pdata->node, notify_value, pdata->cbarg); } void aml_notify_dev(const char *pnpid, int notify_value) { struct aml_notify_data *pdata = NULL; if (pnpid == NULL) return; SLIST_FOREACH(pdata, &aml_notify_list, link) if (pdata->pnpid && !strcmp(pdata->pnpid, pnpid)) pdata->cbproc(pdata->node, notify_value, pdata->cbarg); } void acpi_poll_notify(void) { struct aml_notify_data *pdata = NULL; SLIST_FOREACH(pdata, &aml_notify_list, link) if (pdata->cbproc && pdata->poll) pdata->cbproc(pdata->node, 0, pdata->cbarg); } /* * @@@: Namespace functions */ struct aml_node *__aml_search(struct aml_node *, uint8_t *, int); void aml_delchildren(struct aml_node *); /* Search for a name in children nodes */ struct aml_node * __aml_search(struct aml_node *root, uint8_t *nameseg, int create) { struct aml_node **sp, *node; /* XXX: Replace with SLIST/SIMPLEQ routines */ if (root == NULL) return NULL; //rw_enter_read(&aml_nslock); for (sp = &root->child; *sp; sp = &(*sp)->sibling) { if (!strncmp((*sp)->name, nameseg, AML_NAMESEG_LEN)) { //rw_exit_read(&aml_nslock); return *sp; } } //rw_exit_read(&aml_nslock); if (create) { node = acpi_os_malloc(sizeof(struct aml_node)); memcpy((void *)node->name, nameseg, AML_NAMESEG_LEN); node->value = aml_allocvalue(0,0,NULL); node->value->node = node; node->parent = root; node->sibling = NULL; //rw_enter_write(&aml_nslock); *sp = node; //rw_exit_write(&aml_nslock); } return *sp; } /* Get absolute pathname of AML node */ const char * aml_nodename(struct aml_node *node) { static char namebuf[128]; namebuf[0] = 0; if (node) { aml_nodename(node->parent); if (node->parent != &aml_root) strlcat(namebuf, ".", sizeof(namebuf)); strlcat(namebuf, node->name, sizeof(namebuf)); return namebuf+1; } return namebuf; } const char * aml_getname(const char *name) { static char namebuf[128], *p; int count; p = namebuf; while (*name == AMLOP_ROOTCHAR || *name == AMLOP_PARENTPREFIX) *(p++) = *(name++); switch (*name) { case 0x00: count = 0; break; case AMLOP_MULTINAMEPREFIX: count = name[1]; name += 2; break; case AMLOP_DUALNAMEPREFIX: count = 2; name += 1; break; default: count = 1; } while (count--) { memcpy(p, name, 4); p[4] = '.'; p += 5; name += 4; if (*name == '.') name++; } *(--p) = 0; return namebuf; } /* Free all children nodes/values */ void aml_delchildren(struct aml_node *node) { struct aml_node *onode; if (node == NULL) return; while ((onode = node->child) != NULL) { node->child = onode->sibling; aml_delchildren(onode); /* Decrease reference count */ aml_xdelref(&onode->value, ""); /* Delete node */ acpi_os_free(onode); } } /* * @@@: Value functions */ /* * Field I/O code */ void aml_unlockfield(struct aml_scope *, struct aml_value *); void aml_lockfield(struct aml_scope *, struct aml_value *); long acpi_acquire_global_lock(void*); long acpi_release_global_lock(void*); static long global_lock_count = 0; #define acpi_acquire_global_lock(x) 1 #define acpi_release_global_lock(x) 0 void aml_lockfield(struct aml_scope *scope, struct aml_value *field) { int st = 0; if (AML_FIELD_LOCK(field->v_field.flags) != AML_FIELD_LOCK_ON) return; /* If lock is already ours, just continue */ if (global_lock_count++) return; /* Spin to acquire lock */ while (!st) { st = acpi_acquire_global_lock(&dsdt_softc->sc_facs->global_lock); /* XXX - yield/delay? */ } return; } void aml_unlockfield(struct aml_scope *scope, struct aml_value *field) { int st, x; if (AML_FIELD_LOCK(field->v_field.flags) != AML_FIELD_LOCK_ON) return; /* If we are the last ones, turn out the lights */ if (--global_lock_count) return; /* Release lock */ st = acpi_release_global_lock(&dsdt_softc->sc_facs->global_lock); if (!st) return; /* Signal others if someone waiting */ x = acpi_read_pmreg(dsdt_softc, ACPIREG_PM1_CNT, 0); x |= ACPI_PM1_GBL_RLS; acpi_write_pmreg(dsdt_softc, ACPIREG_PM1_CNT, 0, x); return; } /* * @@@: Value set/compare/alloc/free routines */ #ifndef SMALL_KERNEL void aml_showvalue(struct aml_value *val, int lvl) { int idx; if (val == NULL) return; if (val->node) printf(" [%s]", aml_nodename(val->node)); printf(" %p cnt:%.2x stk:%.2x", val, val->refcnt, val->stack); switch (val->type) { case AML_OBJTYPE_INTEGER: printf(" integer: %llx\n", val->v_integer); break; case AML_OBJTYPE_STRING: printf(" string: %s\n", val->v_string); break; case AML_OBJTYPE_METHOD: printf(" method: %.2x\n", val->v_method.flags); break; case AML_OBJTYPE_PACKAGE: printf(" package: %.2x\n", val->length); for (idx = 0; idx < val->length; idx++) aml_showvalue(val->v_package[idx], lvl); break; case AML_OBJTYPE_BUFFER: printf(" buffer: %.2x {", val->length); for (idx = 0; idx < val->length; idx++) printf("%s%.2x", idx ? ", " : "", val->v_buffer[idx]); printf("}\n"); break; case AML_OBJTYPE_FIELDUNIT: case AML_OBJTYPE_BUFFERFIELD: printf(" field: bitpos=%.4x bitlen=%.4x ref1:%x ref2:%x [%s]\n", val->v_field.bitpos, val->v_field.bitlen, val->v_field.ref1, val->v_field.ref2, aml_mnem(val->v_field.type, NULL)); if (val->v_field.ref1) printf(" ref1: %s\n", aml_nodename(val->v_field.ref1->node)); if (val->v_field.ref2) printf(" ref2: %s\n", aml_nodename(val->v_field.ref2->node)); break; case AML_OBJTYPE_MUTEX: printf(" mutex: %s ref: %d\n", val->v_mutex ? val->v_mutex->amt_name : "", val->v_mutex ? val->v_mutex->amt_ref_count : 0); break; case AML_OBJTYPE_EVENT: printf(" event:\n"); break; case AML_OBJTYPE_OPREGION: printf(" opregion: %.2x,%.8llx,%x\n", val->v_opregion.iospace, val->v_opregion.iobase, val->v_opregion.iolen); break; case AML_OBJTYPE_NAMEREF: printf(" nameref: %s\n", aml_getname(val->v_nameref)); break; case AML_OBJTYPE_DEVICE: printf(" device:\n"); break; case AML_OBJTYPE_PROCESSOR: printf(" cpu: %.2x,%.4x,%.2x\n", val->v_processor.proc_id, val->v_processor.proc_addr, val->v_processor.proc_len); break; case AML_OBJTYPE_THERMZONE: printf(" thermzone:\n"); break; case AML_OBJTYPE_POWERRSRC: printf(" pwrrsrc: %.2x,%.2x\n", val->v_powerrsrc.pwr_level, val->v_powerrsrc.pwr_order); break; case AML_OBJTYPE_OBJREF: printf(" objref: %p index:%x opcode:%s\n", val->v_objref.ref, val->v_objref.index, aml_mnem(val->v_objref.type, 0)); aml_showvalue(val->v_objref.ref, lvl); break; default: printf(" !!type: %x\n", val->type); } } #endif /* SMALL_KERNEL */ int64_t aml_val2int(struct aml_value *rval) { int64_t ival = 0; if (rval == NULL) { dnprintf(50, "null val2int\n"); return (0); } switch (rval->type) { case AML_OBJTYPE_INTEGER: ival = rval->v_integer; break; case AML_OBJTYPE_BUFFER: aml_bufcpy(&ival, 0, rval->v_buffer, 0, min(aml_intlen, rval->length*8)); break; case AML_OBJTYPE_STRING: ival = aml_hextoint(rval->v_string); break; } return (ival); } /* Sets value into LHS: lhs must already be cleared */ struct aml_value * _aml_setvalue(struct aml_value *lhs, int type, int64_t ival, const void *bval) { memset(&lhs->_, 0x0, sizeof(lhs->_)); lhs->type = type; switch (lhs->type) { case AML_OBJTYPE_INTEGER: lhs->length = aml_intlen>>3; lhs->v_integer = ival; break; case AML_OBJTYPE_METHOD: lhs->v_method.flags = ival; lhs->v_method.fneval = bval; break; case AML_OBJTYPE_NAMEREF: lhs->v_nameref = (uint8_t *)bval; break; case AML_OBJTYPE_OBJREF: lhs->v_objref.type = ival; lhs->v_objref.ref = (struct aml_value *)bval; break; case AML_OBJTYPE_BUFFER: lhs->length = ival; lhs->v_buffer = (uint8_t *)acpi_os_malloc(ival); if (bval) memcpy(lhs->v_buffer, bval, ival); break; case AML_OBJTYPE_STRING: if (ival == -1) ival = strlen((const char *)bval); lhs->length = ival; lhs->v_string = (char *)acpi_os_malloc(ival+1); if (bval) strncpy(lhs->v_string, (const char *)bval, ival); break; case AML_OBJTYPE_PACKAGE: lhs->length = ival; lhs->v_package = (struct aml_value **)acpi_os_malloc(ival * sizeof(struct aml_value *)); for (ival = 0; ival < lhs->length; ival++) lhs->v_package[ival] = aml_allocvalue( AML_OBJTYPE_UNINITIALIZED, 0, NULL); break; } return lhs; } /* Copy object to another value: lhs must already be cleared */ void aml_copyvalue(struct aml_value *lhs, struct aml_value *rhs) { int idx; lhs->type = rhs->type; switch (lhs->type) { case AML_OBJTYPE_UNINITIALIZED: break; case AML_OBJTYPE_INTEGER: lhs->length = aml_intlen>>3; lhs->v_integer = rhs->v_integer; break; case AML_OBJTYPE_MUTEX: lhs->v_mutex = rhs->v_mutex; break; case AML_OBJTYPE_POWERRSRC: lhs->v_powerrsrc = rhs->v_powerrsrc; break; case AML_OBJTYPE_METHOD: lhs->v_method = rhs->v_method; break; case AML_OBJTYPE_BUFFER: _aml_setvalue(lhs, rhs->type, rhs->length, rhs->v_buffer); break; case AML_OBJTYPE_STRING: _aml_setvalue(lhs, rhs->type, rhs->length, rhs->v_string); break; case AML_OBJTYPE_OPREGION: lhs->v_opregion = rhs->v_opregion; break; case AML_OBJTYPE_PROCESSOR: lhs->v_processor = rhs->v_processor; break; case AML_OBJTYPE_NAMEREF: lhs->v_nameref = rhs->v_nameref; break; case AML_OBJTYPE_PACKAGE: _aml_setvalue(lhs, rhs->type, rhs->length, NULL); for (idx = 0; idx < rhs->length; idx++) aml_copyvalue(lhs->v_package[idx], rhs->v_package[idx]); break; case AML_OBJTYPE_OBJREF: lhs->v_objref = rhs->v_objref; break; default: printf("copyvalue: %x", rhs->type); break; } } /* Allocate dynamic AML value * type : Type of object to allocate (AML_OBJTYPE_XXXX) * ival : Integer value (action depends on type) * bval : Buffer value (action depends on type) */ struct aml_value * aml_allocvalue(int type, int64_t ival, const void *bval) { struct aml_value *rv; rv = (struct aml_value *)acpi_os_malloc(sizeof(struct aml_value)); if (rv != NULL) { aml_xaddref(rv, ""); return _aml_setvalue(rv, type, ival, bval); } return NULL; } void aml_freevalue(struct aml_value *val) { int idx; if (val == NULL) return; switch (val->type) { case AML_OBJTYPE_STRING: acpi_os_free(val->v_string); break; case AML_OBJTYPE_BUFFER: acpi_os_free(val->v_buffer); break; case AML_OBJTYPE_PACKAGE: for (idx = 0; idx < val->length; idx++) { aml_freevalue(val->v_package[idx]); acpi_os_free(val->v_package[idx]); } acpi_os_free(val->v_package); break; case AML_OBJTYPE_OBJREF: aml_xdelref(&val->v_objref.ref, ""); break; case AML_OBJTYPE_BUFFERFIELD: case AML_OBJTYPE_FIELDUNIT: aml_xdelref(&val->v_field.ref1, ""); aml_xdelref(&val->v_field.ref2, ""); break; } val->type = 0; memset(&val->_, 0, sizeof(val->_)); } /* * @@@: Math eval routines */ /* Convert number from one radix to another * Used in BCD conversion routines */ u_int64_t aml_convradix(u_int64_t val, int iradix, int oradix) { u_int64_t rv = 0, pwr; rv = 0; pwr = 1; while (val) { rv += (val % iradix) * pwr; val /= iradix; pwr *= oradix; } return rv; } /* Calculate LSB */ int aml_lsb(u_int64_t val) { int lsb; if (val == 0) return (0); for (lsb = 1; !(val & 0x1); lsb++) val >>= 1; return (lsb); } /* Calculate MSB */ int aml_msb(u_int64_t val) { int msb; if (val == 0) return (0); for (msb = 1; val != 0x1; msb++) val >>= 1; return (msb); } /* Evaluate Math operands */ int64_t aml_evalexpr(int64_t lhs, int64_t rhs, int opcode) { int64_t res; switch (opcode) { /* Math operations */ case AMLOP_INCREMENT: case AMLOP_ADD: res = (lhs + rhs); break; case AMLOP_DECREMENT: case AMLOP_SUBTRACT: res = (lhs - rhs); break; case AMLOP_MULTIPLY: res = (lhs * rhs); break; case AMLOP_DIVIDE: res = (lhs / rhs); break; case AMLOP_MOD: res = (lhs % rhs); break; case AMLOP_SHL: res = (lhs << rhs); break; case AMLOP_SHR: res = (lhs >> rhs); break; case AMLOP_AND: res = (lhs & rhs); break; case AMLOP_NAND: res = ~(lhs & rhs); break; case AMLOP_OR: res = (lhs | rhs); break; case AMLOP_NOR: res = ~(lhs | rhs); break; case AMLOP_XOR: res = (lhs ^ rhs); break; case AMLOP_NOT: res = ~(lhs); break; /* Conversion/misc */ case AMLOP_FINDSETLEFTBIT: res = aml_msb(lhs); break; case AMLOP_FINDSETRIGHTBIT: res = aml_lsb(lhs); break; case AMLOP_TOINTEGER: res = (lhs); break; case AMLOP_FROMBCD: res = aml_convradix(lhs, 16, 10); break; case AMLOP_TOBCD: res = aml_convradix(lhs, 10, 16); break; /* Logical/Comparison */ case AMLOP_LAND: res = (lhs && rhs); break; case AMLOP_LOR: res = (lhs || rhs); break; case AMLOP_LNOT: res = (!lhs); break; case AMLOP_LNOTEQUAL: res = (lhs != rhs); break; case AMLOP_LLESSEQUAL: res = (lhs <= rhs); break; case AMLOP_LGREATEREQUAL: res = (lhs >= rhs); break; case AMLOP_LEQUAL: res = (lhs == rhs); break; case AMLOP_LGREATER: res = (lhs > rhs); break; case AMLOP_LLESS: res = (lhs < rhs); break; } dnprintf(15,"aml_evalexpr: %s %llx %llx = %llx\n", aml_mnem(opcode, NULL), lhs, rhs, res); return res; } /* * aml_bufcpy copies/shifts buffer data, special case for aligned transfers * dstPos/srcPos are bit positions within destination/source buffers */ void aml_bufcpy(void *pvDst, int dstPos, const void *pvSrc, int srcPos, int len) { const u_int8_t *pSrc = pvSrc; u_int8_t *pDst = pvDst; int idx; if (aml_bytealigned(dstPos|srcPos|len)) { /* Aligned transfer: use memcpy */ memcpy(pDst+aml_bytepos(dstPos), pSrc+aml_bytepos(srcPos), aml_bytelen(len)); return; } /* Misaligned transfer: perform bitwise copy (slow) */ for (idx = 0; idx < len; idx++) aml_setbit(pDst, idx + dstPos, aml_tstbit(pSrc, idx + srcPos)); } /* * @@@: External API * * evaluate an AML node * Returns a copy of the value in res (must be freed by user) */ void aml_walknodes(struct aml_node *node, int mode, int (*nodecb)(struct aml_node *, void *), void *arg) { struct aml_node *child; if (node == NULL) return; if (mode == AML_WALK_PRE) nodecb(node, arg); for (child = node->child; child; child = child->sibling) aml_walknodes(child, mode, nodecb, arg); if (mode == AML_WALK_POST) nodecb(node, arg); } int aml_find_node(struct aml_node *node, const char *name, int (*cbproc)(struct aml_node *, void *arg), void *arg) { const char *nn; int st = 0; while (node) { if ((nn = node->name) != NULL) { if (*nn == AMLOP_ROOTCHAR) nn++; while (*nn == AMLOP_PARENTPREFIX) nn++; if (!strcmp(name, nn)) st = cbproc(node, arg); } /* Only recurse if cbproc() wants us to */ if (!st) aml_find_node(node->child, name, cbproc, arg); node = node->sibling; } return st; } /* * @@@: Parser functions */ uint8_t *aml_parsename(struct aml_scope *); uint8_t *aml_parseend(struct aml_scope *scope); int aml_parselength(struct aml_scope *); int aml_parseopcode(struct aml_scope *); /* Get AML Opcode */ int aml_parseopcode(struct aml_scope *scope) { int opcode = (scope->pos[0]); int twocode = (scope->pos[0]<<8) + scope->pos[1]; /* Check if this is an embedded name */ switch (opcode) { case AMLOP_ROOTCHAR: case AMLOP_PARENTPREFIX: case AMLOP_MULTINAMEPREFIX: case AMLOP_DUALNAMEPREFIX: case AMLOP_NAMECHAR: return AMLOP_NAMECHAR; } if (opcode >= 'A' && opcode <= 'Z') return AMLOP_NAMECHAR; if (twocode == AMLOP_LNOTEQUAL || twocode == AMLOP_LLESSEQUAL || twocode == AMLOP_LGREATEREQUAL || opcode == AMLOP_EXTPREFIX) { scope->pos += 2; return twocode; } scope->pos += 1; return opcode; } /* Decode embedded AML Namestring */ uint8_t * aml_parsename(struct aml_scope *scope) { uint8_t *name = scope->pos; while (*scope->pos == AMLOP_ROOTCHAR || *scope->pos == AMLOP_PARENTPREFIX) scope->pos++; switch (*scope->pos) { case 0x00: break; case AMLOP_MULTINAMEPREFIX: scope->pos += 2+AML_NAMESEG_LEN*scope->pos[1]; break; case AMLOP_DUALNAMEPREFIX: scope->pos += 1+AML_NAMESEG_LEN*2; break; default: scope->pos += AML_NAMESEG_LEN; break; } return name; } /* Decode AML Length field * AML Length field is encoded: * byte0 byte1 byte2 byte3 * 00xxxxxx : if upper bits == 00, length = xxxxxx * 01--xxxx yyyyyyyy : if upper bits == 01, length = yyyyyyyyxxxx * 10--xxxx yyyyyyyy zzzzzzzz : if upper bits == 10, length = zzzzzzzzyyyyyyyyxxxx * 11--xxxx yyyyyyyy zzzzzzzz wwwwwwww : if upper bits == 11, length = wwwwwwwwzzzzzzzzyyyyyyyyxxxx */ int aml_parselength(struct aml_scope *scope) { int len; uint8_t lcode; lcode = *(scope->pos++); if (lcode <= 0x3F) return lcode; /* lcode >= 0x40, multibyte length, get first byte of extended length */ len = lcode & 0xF; len += *(scope->pos++) << 4L; if (lcode >= 0x80) len += *(scope->pos++) << 12L; if (lcode >= 0xC0) len += *(scope->pos++) << 20L; return len; } /* Get address of end of scope; based on current address */ uint8_t * aml_parseend(struct aml_scope *scope) { uint8_t *pos = scope->pos; int len; len = aml_parselength(scope); if (pos+len > scope->end) { dnprintf(10, "Bad scope... runover pos:%.4x new end:%.4x scope " "end:%.4x\n", aml_pc(pos), aml_pc(pos+len), aml_pc(scope->end)); pos = scope->end; } return pos+len; } /* * @@@: Opcode utility functions */ int amlop_delay; u_int64_t aml_getpciaddr(struct acpi_softc *sc, struct aml_node *root) { int64_t tmpres; u_int64_t pciaddr; /* PCI */ pciaddr = 0; if (!aml_evalinteger(dsdt_softc, root, "_ADR", 0, NULL, &tmpres)) { /* Device:Function are bits 16-31,32-47 */ pciaddr += (tmpres << 16L); dnprintf(20, "got _adr [%s]\n", aml_nodename(root)); } else { /* Mark invalid */ pciaddr += (0xFFFF << 16L); return pciaddr; } if (!aml_evalinteger(dsdt_softc, root, "_BBN", 0, NULL, &tmpres)) { /* PCI bus is in bits 48-63 */ pciaddr += (tmpres << 48L); dnprintf(20, "got _bbn [%s]\n", aml_nodename(root)); } dnprintf(20, "got pciaddr: %s:%llx\n", aml_nodename(root), pciaddr); return pciaddr; } /* * @@@: Opcode functions */ int odp; const char hext[] = "0123456789ABCDEF"; const char * aml_eisaid(u_int32_t pid) { static char id[8]; id[0] = '@' + ((pid >> 2) & 0x1F); id[1] = '@' + ((pid << 3) & 0x18) + ((pid >> 13) & 0x7); id[2] = '@' + ((pid >> 8) & 0x1F); id[3] = hext[(pid >> 20) & 0xF]; id[4] = hext[(pid >> 16) & 0xF]; id[5] = hext[(pid >> 28) & 0xF]; id[6] = hext[(pid >> 24) & 0xF]; id[7] = 0; return id; } /* * @@@: Default Object creation */ static char osstring[] = "Macrosift Windogs MT"; struct aml_defval { const char *name; int type; int64_t ival; const void *bval; struct aml_value **gval; } aml_defobj[] = { { "_OS_", AML_OBJTYPE_STRING, -1, osstring }, { "_REV", AML_OBJTYPE_INTEGER, 2, NULL }, { "_GL", AML_OBJTYPE_MUTEX, 1, NULL, &aml_global_lock }, { "_OSI", AML_OBJTYPE_METHOD, 1, aml_callosi }, /* Create default scopes */ { "_GPE" }, { "_PR_" }, { "_SB_" }, { "_TZ_" }, { "_SI_" }, { NULL } }; /* _OSI Default Method: * Returns True if string argument matches list of known OS strings * We return True for Windows to fake out nasty bad AML */ char *aml_valid_osi[] = { "Windows 2000", "Windows 2001", "Windows 2001.1", "Windows 2001 SP0", "Windows 2001 SP1", "Windows 2001 SP2", "Windows 2001 SP3", "Windows 2001 SP4", "Windows 2006", NULL }; struct aml_value * aml_callosi(struct aml_scope *scope, struct aml_value *val) { int idx, result=0; struct aml_value *fa; fa = aml_getstack(scope, AMLOP_ARG0); for (idx=0; !result && aml_valid_osi[idx] != NULL; idx++) { dnprintf(10,"osi: %s,%s\n", fa->v_string, aml_valid_osi[idx]); result = !strcmp(fa->v_string, aml_valid_osi[idx]); } dnprintf(10,"@@ OSI found: %x\n", result); return aml_allocvalue(AML_OBJTYPE_INTEGER, result, NULL); } void aml_create_defaultobjects() { struct aml_value *tmp; struct aml_defval *def; #ifdef ACPI_MEMDEBUG LIST_INIT(&acpi_memhead); #endif osstring[1] = 'i'; osstring[6] = 'o'; osstring[15] = 'w'; osstring[18] = 'N'; strlcpy(aml_root.name, "\\", sizeof(aml_root.name)); aml_root.value = aml_allocvalue(0, 0, NULL); aml_root.value->node = &aml_root; for (def = aml_defobj; def->name; def++) { /* Allocate object value + add to namespace */ aml_xparsename((uint8_t *)def->name, &aml_root, ns_xcreate, &tmp); _aml_setvalue(tmp, def->type, def->ival, def->bval); if (def->gval) { /* Set root object pointer */ *def->gval = tmp; } } } #ifdef ACPI_DEBUG int aml_print_resource(union acpi_resource *crs, void *arg) { int typ = AML_CRSTYPE(crs); switch (typ) { case LR_EXTIRQ: printf("extirq\tflags:%.2x len:%.2x irq:%.4x\n", crs->lr_extirq.flags, crs->lr_extirq.irq_count, aml_letohost32(crs->lr_extirq.irq[0])); break; case SR_IRQ: printf("irq\t%.4x %.2x\n", aml_letohost16(crs->sr_irq.irq_mask), crs->sr_irq.irq_flags); break; case SR_DMA: printf("dma\t%.2x %.2x\n", crs->sr_dma.channel, crs->sr_dma.flags); break; case SR_IOPORT: printf("ioport\tflags:%.2x _min:%.4x _max:%.4x _aln:%.2x _len:%.2x\n", crs->sr_ioport.flags, crs->sr_ioport._min, crs->sr_ioport._max, crs->sr_ioport._aln, crs->sr_ioport._len); break; case SR_STARTDEP: printf("startdep\n"); break; case SR_ENDDEP: printf("enddep\n"); break; case LR_WORD: printf("word\ttype:%.2x flags:%.2x tflag:%.2x gra:%.4x min:%.4x max:%.4x tra:%.4x len:%.4x\n", crs->lr_word.type, crs->lr_word.flags, crs->lr_word.tflags, crs->lr_word._gra, crs->lr_word._min, crs->lr_word._max, crs->lr_word._tra, crs->lr_word._len); break; case LR_DWORD: printf("dword\ttype:%.2x flags:%.2x tflag:%.2x gra:%.8x min:%.8x max:%.8x tra:%.8x len:%.8x\n", crs->lr_dword.type, crs->lr_dword.flags, crs->lr_dword.tflags, crs->lr_dword._gra, crs->lr_dword._min, crs->lr_dword._max, crs->lr_dword._tra, crs->lr_dword._len); break; case LR_QWORD: printf("dword\ttype:%.2x flags:%.2x tflag:%.2x gra:%.16llx min:%.16llx max:%.16llx tra:%.16llx len:%.16llx\n", crs->lr_qword.type, crs->lr_qword.flags, crs->lr_qword.tflags, crs->lr_qword._gra, crs->lr_qword._min, crs->lr_qword._max, crs->lr_qword._tra, crs->lr_qword._len); break; default: printf("unknown type: %x\n", typ); break; } return (0); } #endif /* ACPI_DEBUG */ union acpi_resource *aml_mapresource(union acpi_resource *); union acpi_resource * aml_mapresource(union acpi_resource *crs) { static union acpi_resource map; int rlen; rlen = AML_CRSLEN(crs); if (rlen >= sizeof(map)) return crs; memset(&map, 0, sizeof(map)); memcpy(&map, crs, rlen); return ↦ } int aml_parse_resource(int length, uint8_t *buffer, int (*crs_enum)(union acpi_resource *, void *), void *arg) { int off, rlen; union acpi_resource *crs; for (off = 0; off < length; off += rlen) { crs = (union acpi_resource *)(buffer+off); rlen = AML_CRSLEN(crs); if (crs->hdr.typecode == 0x79 || rlen <= 3) break; crs = aml_mapresource(crs); #ifdef ACPI_DEBUG aml_print_resource(crs, NULL); #endif crs_enum(crs, arg); } return (0); } void aml_foreachpkg(struct aml_value *pkg, int start, void (*fn)(struct aml_value *, void *), void *arg) { int idx; if (pkg->type != AML_OBJTYPE_PACKAGE) return; for (idx=start; idxlength; idx++) fn(pkg->v_package[idx], arg); } /* * Walk nodes and perform fixups for nameref */ int aml_fixup_node(struct aml_node *, void *); int aml_fixup_node(struct aml_node *node, void *arg) { struct aml_value *val = arg; int i; if (node->value == NULL) return (0); if (arg == NULL) aml_fixup_node(node, node->value); else if (val->type == AML_OBJTYPE_NAMEREF) { node = aml_searchname(node, val->v_nameref); if (node && node->value) { _aml_setvalue(val, AML_OBJTYPE_OBJREF, AMLOP_NAMECHAR, node->value); } } else if (val->type == AML_OBJTYPE_PACKAGE) { for (i = 0; i < val->length; i++) aml_fixup_node(node, val->v_package[i]); } else if (val->type == AML_OBJTYPE_OPREGION) { if (val->v_opregion.iospace != GAS_PCI_CFG_SPACE) return (0); if (ACPI_PCI_FN(val->v_opregion.iobase) != 0xFFFF) return (0); val->v_opregion.iobase = ACPI_PCI_REG(val->v_opregion.iobase) + aml_getpciaddr(dsdt_softc, node); dnprintf(20, "late ioaddr : %s:%llx\n", aml_nodename(node), val->v_opregion.iobase); } return (0); } void aml_postparse() { aml_walknodes(&aml_root, AML_WALK_PRE, aml_fixup_node, NULL); } const char * aml_val_to_string(const struct aml_value *val) { static char buffer[256]; int len; switch (val->type) { case AML_OBJTYPE_BUFFER: len = val->length; if (len >= sizeof(buffer)) len = sizeof(buffer) - 1; memcpy(buffer, val->v_buffer, len); buffer[len] = 0; break; case AML_OBJTYPE_STRING: strlcpy(buffer, val->v_string, sizeof(buffer)); break; case AML_OBJTYPE_INTEGER: snprintf(buffer, sizeof(buffer), "%llx", val->v_integer); break; default: snprintf(buffer, sizeof(buffer), "Failed to convert type %d to string!", val->type); }; return (buffer); } /* * XXX: NEW PARSER CODE GOES HERE */ int aml_error; struct aml_value *aml_gettgt(struct aml_value *, int); struct aml_value *aml_xeval(struct aml_scope *, struct aml_value *, int, int, struct aml_value *); struct aml_value *aml_xparsesimple(struct aml_scope *, char, struct aml_value *); struct aml_value *aml_xparse(struct aml_scope *, int, const char *); struct aml_value *aml_seterror(struct aml_scope *, const char *, ...); struct aml_scope *aml_xfindscope(struct aml_scope *, int, int); struct aml_scope *aml_xpushscope(struct aml_scope *, struct aml_value *, struct aml_node *, int); struct aml_scope *aml_xpopscope(struct aml_scope *); void aml_showstack(struct aml_scope *); struct aml_value *aml_xconvert(struct aml_value *, int, int); int aml_xmatchtest(int64_t, int64_t, int); int aml_xmatch(struct aml_value *, int, int, int, int, int); int aml_xcompare(struct aml_value *, struct aml_value *, int); struct aml_value *aml_xconcat(struct aml_value *, struct aml_value *); struct aml_value *aml_xconcatres(struct aml_value *, struct aml_value *); struct aml_value *aml_xmid(struct aml_value *, int, int); int aml_ccrlen(union acpi_resource *, void *); void aml_xstore(struct aml_scope *, struct aml_value *, int64_t, struct aml_value *); int valid_acpihdr(void *buf, int len, const char *sig) { struct acpi_table_header *hdr = buf; if (sig && strncmp(hdr->signature, sig, 4)) return (0); if (len < hdr->length) return (0); if (acpi_checksum(hdr, hdr->length) != 0) return (0); return (1); } /* * Reference Count functions */ void aml_xaddref(struct aml_value *val, const char *lbl) { if (val == NULL) return; dnprintf(50, "XAddRef: %p %s:[%s] %d\n", val, lbl, val->node ? aml_nodename(val->node) : "INTERNAL", val->refcnt); val->refcnt++; } /* Decrease reference counter */ void aml_xdelref(struct aml_value **pv, const char *lbl) { struct aml_value *val; if (pv == NULL || *pv == NULL) return; val = *pv; val->refcnt--; if (val->refcnt == 0) { dnprintf(50, "XDelRef: %p %s %2d [%s] %s\n", val, lbl, val->refcnt, val->node ? aml_nodename(val->node) : "INTERNAL", val->refcnt ? "" : "---------------- FREEING"); aml_freevalue(val); acpi_os_free(val); *pv = NULL; } } /* Walk list of parent scopes until we find one of 'type' * If endscope is set, mark all intermediate scopes as invalid (used for Method/While) */ struct aml_scope * aml_xfindscope(struct aml_scope *scope, int type, int endscope) { while (scope) { switch (endscope) { case AMLOP_RETURN: scope->pos = scope->end; if (scope->type == AMLOP_WHILE) scope->pos = NULL; break; case AMLOP_CONTINUE: scope->pos = scope->end; break; case AMLOP_BREAK: scope->pos = scope->end; if (scope->type == type) scope->parent->pos = scope->end; break; } if (scope->type == type) break; scope = scope->parent; } return scope; } struct aml_value * aml_getstack(struct aml_scope *scope, int opcode) { struct aml_value *sp; sp = NULL; scope = aml_xfindscope(scope, AMLOP_METHOD, 0); if (scope == NULL) return NULL; if (opcode >= AMLOP_LOCAL0 && opcode <= AMLOP_LOCAL7) { if (scope->locals == NULL) scope->locals = aml_allocvalue(AML_OBJTYPE_PACKAGE, 8, NULL); sp = scope->locals->v_package[opcode - AMLOP_LOCAL0]; sp->stack = opcode; } else if (opcode >= AMLOP_ARG0 && opcode <= AMLOP_ARG6) { if (scope->args == NULL) scope->args = aml_allocvalue(AML_OBJTYPE_PACKAGE, 7, NULL); sp = scope->args->v_package[opcode - AMLOP_ARG0]; if (sp->type == AML_OBJTYPE_OBJREF) sp = sp->v_objref.ref; } return sp; } #ifdef ACPI_DEBUG /* Dump AML Stack */ void aml_showstack(struct aml_scope *scope) { struct aml_value *sp; int idx; dnprintf(10, "===== Stack %s:%s\n", aml_nodename(scope->node), aml_mnem(scope->type, 0)); for (idx=0; scope->args && idx<7; idx++) { sp = aml_getstack(scope, AMLOP_ARG0+idx); if (sp && sp->type) { dnprintf(10," Arg%d: ", idx); aml_showvalue(sp, 10); } } for (idx=0; scope->locals && idx<8; idx++) { sp = aml_getstack(scope, AMLOP_LOCAL0+idx); if (sp && sp->type) { dnprintf(10," Local%d: ", idx); aml_showvalue(sp, 10); } } } #endif /* Create a new scope object */ struct aml_scope * aml_xpushscope(struct aml_scope *parent, struct aml_value *range, struct aml_node *node, int type) { struct aml_scope *scope; uint8_t *start, *end; if (range->type == AML_OBJTYPE_METHOD) { start = range->v_method.start; end = range->v_method.end; } else { start = range->v_buffer; end = start + range->length; if (start == end) return NULL; } scope = acpi_os_malloc(sizeof(struct aml_scope)); if (scope == NULL) return NULL; scope->node = node; scope->start = start; scope->end = end; scope->pos = scope->start; scope->parent = parent; scope->type = type; scope->sc = dsdt_softc; aml_lastscope = scope; return scope; } /* Free a scope object and any children */ struct aml_scope * aml_xpopscope(struct aml_scope *scope) { struct aml_scope *nscope; if (scope == NULL) return NULL; nscope = scope->parent; if (scope->type == AMLOP_METHOD) aml_delchildren(scope->node); if (scope->locals) { aml_freevalue(scope->locals); acpi_os_free(scope->locals); scope->locals = NULL; } if (scope->args) { aml_freevalue(scope->args); acpi_os_free(scope->args); scope->args = NULL; } acpi_os_free(scope); aml_lastscope = nscope; return nscope; } /* Test AMLOP_MATCH codes */ int aml_xmatchtest(int64_t a, int64_t b, int op) { switch (op) { case AML_MATCH_TR: return (1); case AML_MATCH_EQ: return (a == b); case AML_MATCH_LT: return (a < b); case AML_MATCH_LE: return (a <= b); case AML_MATCH_GE: return (a >= b); case AML_MATCH_GT: return (a > b); } return (0); } /* Search a package for a matching value */ int aml_xmatch(struct aml_value *pkg, int index, int op1, int v1, int op2, int v2) { struct aml_value *tmp; int flag; while (index < pkg->length) { /* Convert package value to integer */ tmp = aml_xconvert(pkg->v_package[index], AML_OBJTYPE_INTEGER, -1); /* Perform test */ flag = aml_xmatchtest(tmp->v_integer, v1, op1) && aml_xmatchtest(tmp->v_integer, v2, op2); aml_xdelref(&tmp, "xmatch"); if (flag) return index; index++; } return -1; } /* * Namespace functions */ /* Search for name in namespace */ void ns_xsearch(struct aml_node *node, int n, uint8_t *pos, void *arg) { struct aml_value **rv = arg; struct aml_node *rnode; /* If name search is relative, check up parent nodes */ for (rnode=node; n == 1 && rnode; rnode=rnode->parent) { if (__aml_search(rnode, pos, 0) != NULL) break; } while (n--) { rnode = __aml_search(rnode, pos, 0); pos += 4; } if (rnode != NULL) { *rv = rnode->value; return; } *rv = NULL; } /* Create name in namespace */ void ns_xcreate(struct aml_node *node, int n, uint8_t *pos, void *arg) { struct aml_value **rv = arg; while (n--) { node = __aml_search(node, pos, 1); pos += 4; } *rv = node->value; } void ns_xdis(struct aml_node *node, int n, uint8_t *pos, void *arg) { printf(aml_nodename(node)); while (n--) { printf("%s%c%c%c%c", n ? "." : "", pos[0], pos[1], pos[2], pos[3]); pos+=4; } } uint8_t * aml_xparsename(uint8_t *pos, struct aml_node *node, void (*fn)(struct aml_node *, int, uint8_t *, void *), void *arg) { uint8_t *rpos = pos; struct aml_value **rv = arg; if (*pos == AMLOP_ROOTCHAR) { node = &aml_root; pos++; } while (*pos == AMLOP_PARENTPREFIX) { node = node ? node->parent : &aml_root; pos++; } if (*pos == 0) { fn(node, 0, pos, arg); pos++; } else if (*pos == AMLOP_MULTINAMEPREFIX) { fn(node, pos[1], pos+2, arg); pos += 2 + 4 * pos[1]; } else if (*pos == AMLOP_DUALNAMEPREFIX) { fn(node, 2, pos+1, arg); pos += 9; } else if (*pos == '_' || (*pos >= 'A' && *pos <= 'Z')) { fn(node, 1, pos, arg); pos += 4; } else { printf("Invalid name!!!\n"); } if (rv && *rv == NULL) *rv = aml_allocvalue(AML_OBJTYPE_NAMEREF, 0, rpos); return pos; } /* * Conversion routines */ int64_t aml_hextoint(const char *str) { int64_t v = 0; char c; while (*str) { if (*str >= '0' && *str <= '9') c = *(str++) - '0'; else if (*str >= 'a' && *str <= 'f') c = *(str++) - 'a' + 10; else if (*str >= 'A' && *str <= 'F') c = *(str++) - 'A' + 10; else break; v = (v << 4) + c; } return v; } struct aml_value * aml_xconvert(struct aml_value *a, int ctype, int clen) { struct aml_value *c = NULL; /* Object is already this type */ if (clen == -1) clen = a->length; if (a->type == ctype) { aml_xaddref(a, "XConvert"); return a; } switch (ctype) { case AML_OBJTYPE_BUFFER: dnprintf(10,"convert to buffer\n"); switch (a->type) { case AML_OBJTYPE_INTEGER: c = aml_allocvalue(AML_OBJTYPE_BUFFER, a->length, &a->v_integer); break; case AML_OBJTYPE_STRING: c = aml_allocvalue(AML_OBJTYPE_BUFFER, a->length, a->v_string); break; } break; case AML_OBJTYPE_INTEGER: dnprintf(10,"convert to integer : %x\n", a->type); switch (a->type) { case AML_OBJTYPE_BUFFER: c = aml_allocvalue(AML_OBJTYPE_INTEGER, 0, NULL); memcpy(&c->v_integer, a->v_buffer, min(a->length, c->length)); break; case AML_OBJTYPE_STRING: c = aml_allocvalue(AML_OBJTYPE_INTEGER, 0, NULL); c->v_integer = aml_hextoint(a->v_string); break; case AML_OBJTYPE_UNINITIALIZED: c = aml_allocvalue(AML_OBJTYPE_INTEGER, 0, NULL); break; } break; case AML_OBJTYPE_STRING: case AML_OBJTYPE_HEXSTRING: case AML_OBJTYPE_DECSTRING: dnprintf(10,"convert to string\n"); switch (a->type) { case AML_OBJTYPE_INTEGER: c = aml_allocvalue(AML_OBJTYPE_STRING, 20, NULL); snprintf(c->v_string, c->length, (ctype == AML_OBJTYPE_HEXSTRING) ? "0x%llx" : "%lld", a->v_integer); break; case AML_OBJTYPE_BUFFER: c = aml_allocvalue(AML_OBJTYPE_STRING, a->length, a->v_buffer); break; case AML_OBJTYPE_STRING: aml_xaddref(a, "XConvert"); return a; } break; } if (c == NULL) { #ifndef SMALL_KERNEL aml_showvalue(a, 0); #endif aml_die("Could not convert %x to %x\n", a->type, ctype); } return c; } int aml_xcompare(struct aml_value *a1, struct aml_value *a2, int opcode) { int rc = 0; /* Convert A2 to type of A1 */ a2 = aml_xconvert(a2, a1->type, -1); if (a1->type == AML_OBJTYPE_INTEGER) rc = aml_evalexpr(a1->v_integer, a2->v_integer, opcode); else { /* Perform String/Buffer comparison */ rc = memcmp(a1->v_buffer, a2->v_buffer, min(a1->length, a2->length)); if (rc == 0) { /* If buffers match, which one is longer */ rc = a1->length - a2->length; } /* Perform comparison against zero */ rc = aml_evalexpr(rc, 0, opcode); } /* Either deletes temp buffer, or decrease refcnt on original A2 */ aml_xdelref(&a2, "xcompare"); return rc; } /* Concatenate two objects, returning pointer to new object */ struct aml_value * aml_xconcat(struct aml_value *a1, struct aml_value *a2) { struct aml_value *c; /* Convert arg2 to type of arg1 */ a2 = aml_xconvert(a2, a1->type, -1); switch (a1->type) { case AML_OBJTYPE_INTEGER: c = aml_allocvalue(AML_OBJTYPE_BUFFER, a1->length + a2->length, NULL); memcpy(c->v_buffer, &a1->v_integer, a1->length); memcpy(c->v_buffer+a1->length, &a2->v_integer, a2->length); break; case AML_OBJTYPE_BUFFER: c = aml_allocvalue(AML_OBJTYPE_BUFFER, a1->length + a2->length, NULL); memcpy(c->v_buffer, a1->v_buffer, a1->length); memcpy(c->v_buffer+a1->length, a2->v_buffer, a2->length); break; case AML_OBJTYPE_STRING: c = aml_allocvalue(AML_OBJTYPE_STRING, a1->length + a2->length, NULL); memcpy(c->v_string, a1->v_string, a1->length); memcpy(c->v_string+a1->length, a2->v_string, a2->length); break; default: aml_die("concat type mismatch %d != %d\n", a1->type, a2->type); break; } /* Either deletes temp buffer, or decrease refcnt on original A2 */ aml_xdelref(&a2, "xconcat"); return c; } /* Calculate length of Resource Template */ int aml_ccrlen(union acpi_resource *rs, void *arg) { int *plen = arg; *plen += AML_CRSLEN(rs); return (0); } /* Concatenate resource templates, returning pointer to new object */ struct aml_value * aml_xconcatres(struct aml_value *a1, struct aml_value *a2) { struct aml_value *c; int l1 = 0, l2 = 0, l3 = 2; uint8_t a3[] = { 0x79, 0x00 }; if (a1->type != AML_OBJTYPE_BUFFER || a2->type != AML_OBJTYPE_BUFFER) aml_die("concatres: not buffers\n"); /* Walk a1, a2, get length minus end tags, concatenate buffers, add end tag */ aml_parse_resource(a1->length, a1->v_buffer, aml_ccrlen, &l1); aml_parse_resource(a2->length, a2->v_buffer, aml_ccrlen, &l2); /* Concatenate buffers, add end tag */ c = aml_allocvalue(AML_OBJTYPE_BUFFER, l1+l2+l3, NULL); memcpy(c->v_buffer, a1->v_buffer, l1); memcpy(c->v_buffer+l1, a2->v_buffer, l2); memcpy(c->v_buffer+l1+l2, a3, l3); return c; } /* Extract substring from string or buffer */ struct aml_value * aml_xmid(struct aml_value *src, int index, int length) { if (index > src->length) index = 0; if ((index + length) > src->length) length = src->length - index; return aml_allocvalue(src->type, length, src->v_buffer + index); } /* * Field I/O utility functions */ void aml_xgasio(int, uint64_t, int, void *, int, int, const char *); void aml_xcreatefield(struct aml_value *, int, struct aml_value *, int, int, struct aml_value *, int, int); void aml_xparsefieldlist(struct aml_scope *, int, int, struct aml_value *, struct aml_value *, int); #define GAS_PCI_CFG_SPACE_UNEVAL 0xCC int aml_evalhid(struct aml_node *node, struct aml_value *val) { if (aml_evalname(dsdt_softc, node, "_HID", 0, NULL, val)) return (-1); /* Integer _HID: convert to EISA ID */ if (val->type == AML_OBJTYPE_INTEGER) _aml_setvalue(val, AML_OBJTYPE_STRING, -1, aml_eisaid(val->v_integer)); return (0); } void aml_rwfield(struct aml_value *, int, int, struct aml_value *, int); void aml_rwgas(struct aml_value *, int, int, struct aml_value *, int, int); /* Get PCI address for opregion objects */ int aml_rdpciaddr(struct aml_node *pcidev, union amlpci_t *addr) { int64_t res; if (aml_evalinteger(dsdt_softc, pcidev, "_ADR", 0, NULL, &res) == 0) { addr->fun = res & 0xFFFF; addr->dev = res >> 16; } while (pcidev != NULL) { /* HID device (PCI or PCIE root): eval _BBN */ if (__aml_search(pcidev, "_HID", 0)) { if (aml_evalinteger(dsdt_softc, pcidev, "_BBN", 0, NULL, &res) == 0) { addr->bus = res; break; } } pcidev = pcidev->parent; } return (0); } /* Read/Write from opregion object */ void aml_rwgas(struct aml_value *rgn, int bpos, int blen, struct aml_value *val, int mode, int flag) { struct aml_value tmp; union amlpci_t pi; void *tbit, *vbit; int slen, type, sz; dnprintf(10," %5s %.2x %.8llx %.4x [%s]\n", mode == ACPI_IOREAD ? "read" : "write", rgn->v_opregion.iospace, rgn->v_opregion.iobase + (bpos >> 3), blen, aml_nodename(rgn->node)); memset(&tmp, 0, sizeof(tmp)); pi.addr = rgn->v_opregion.iobase + (bpos >> 3); if (rgn->v_opregion.iospace == GAS_PCI_CFG_SPACE) { /* Get PCI Root Address for this opregion */ aml_rdpciaddr(rgn->node->parent, &pi); } /* Get field access size */ switch (AML_FIELD_ACCESS(flag)) { case AML_FIELD_WORDACC: sz = 2; break; case AML_FIELD_DWORDACC: sz = 4; break; case AML_FIELD_QWORDACC: sz = 8; break; default: sz = 1; break; } tbit = &tmp.v_integer; vbit = &val->v_integer; slen = (blen + 7) >> 3; type = rgn->v_opregion.iospace; /* Allocate temporary storage */ if (blen > aml_intlen) { if (mode == ACPI_IOREAD) { /* Read from a large field: create buffer */ _aml_setvalue(val, AML_OBJTYPE_BUFFER, slen, 0); } else { /* Write to a large field.. create or convert buffer */ val = aml_xconvert(val, AML_OBJTYPE_BUFFER, -1); } _aml_setvalue(&tmp, AML_OBJTYPE_BUFFER, slen, 0); tbit = tmp.v_buffer; vbit = val->v_buffer; } else if (mode == ACPI_IOREAD) { /* Read from a short field.. initialize integer */ _aml_setvalue(val, AML_OBJTYPE_INTEGER, 0, 0); } else { /* Write to a short field.. convert to integer */ val = aml_xconvert(val, AML_OBJTYPE_INTEGER, -1); } if (mode == ACPI_IOREAD) { /* Read bits from opregion */ acpi_gasio(dsdt_softc, ACPI_IOREAD, type, pi.addr, sz, slen, tbit); aml_bufcpy(vbit, 0, tbit, bpos & 7, blen); } else { /* Write bits to opregion */ if (val->length < slen) { dnprintf(0,"writetooshort: %d %d %s\n", val->length, slen, aml_nodename(rgn->node)); slen = val->length; } if (AML_FIELD_UPDATE(flag) == AML_FIELD_PRESERVE && ((bpos|blen) & 7)) { /* If not aligned and preserve, read existing value */ acpi_gasio(dsdt_softc, ACPI_IOREAD, type, pi.addr, sz, slen, tbit); } else if (AML_FIELD_UPDATE(flag) == AML_FIELD_WRITEASONES) { memset(tbit, 0xFF, tmp.length); } /* Copy target bits, then write to region */ aml_bufcpy(tbit, bpos & 7, vbit, 0, blen); acpi_gasio(dsdt_softc, ACPI_IOWRITE, type, pi.addr, sz, slen, tbit); aml_xdelref(&val, "fld.write"); } aml_freevalue(&tmp); } void aml_rwfield(struct aml_value *fld, int bpos, int blen, struct aml_value *val, int mode) { struct aml_value tmp, *ref1, *ref2; ref2 = fld->v_field.ref2; ref1 = fld->v_field.ref1; if (blen > fld->v_field.bitlen) blen = fld->v_field.bitlen; aml_lockfield(NULL, fld); memset(&tmp, 0, sizeof(tmp)); aml_xaddref(&tmp, "fld.write"); if (fld->v_field.type == AMLOP_INDEXFIELD) { _aml_setvalue(&tmp, AML_OBJTYPE_INTEGER, fld->v_field.ref3, 0); aml_rwfield(ref2, 0, aml_intlen, &tmp, ACPI_IOWRITE); aml_rwfield(ref1, fld->v_field.bitpos, fld->v_field.bitlen, val, mode); } else if (fld->v_field.type == AMLOP_BANKFIELD) { _aml_setvalue(&tmp, AML_OBJTYPE_INTEGER, fld->v_field.ref3, 0); aml_rwfield(ref2, 0, aml_intlen, &tmp, ACPI_IOWRITE); aml_rwgas(ref1, fld->v_field.bitpos, fld->v_field.bitlen, val, mode, fld->v_field.flags); } else if (fld->v_field.type == AMLOP_FIELD) { aml_rwgas(ref1, fld->v_field.bitpos+bpos, blen, val, mode, fld->v_field.flags); } else if (mode == ACPI_IOREAD) { /* bufferfield:read */ _aml_setvalue(val, AML_OBJTYPE_INTEGER, 0, 0); aml_bufcpy(&val->v_integer, 0, ref1->v_buffer, fld->v_field.bitpos, fld->v_field.bitlen); } else { /* bufferfield:write */ val = aml_xconvert(val, AML_OBJTYPE_INTEGER, -1); aml_bufcpy(ref1->v_buffer, fld->v_field.bitpos, &val->v_integer, 0, fld->v_field.bitlen); aml_xdelref(&val, "wrbuffld"); } aml_unlockfield(NULL, fld); } /* Perform IO to address space * type = GAS_XXXX * base = base address * rlen = length in bytes to read/write * buf = buffer * mode = ACPI_IOREAD/ACPI_IOWRITE * sz = access_size (bits) */ void aml_xgasio(int type, uint64_t base, int rlen, void *buf, int mode, int sz, const char *lbl) { sz >>= 3; acpi_gasio(dsdt_softc, mode, type, base, sz, rlen, buf); #ifdef ACPI_DEBUG { int idx; printf("%sio: [%s] ty:%x bs=%.8llx sz=%.4x rlen=%.4x ", mode == ACPI_IOREAD ? "rd" : "wr", lbl, type, base, sz, rlen); for (idx=0; idx aml_intlen ? "BUF" : "INT", aml_nodename(field->node), bpos, blen); if (index) { dnprintf(10, " index:%s:%.2x\n", aml_nodename(index->node), indexval); } dnprintf(10, " data:%s\n", aml_nodename(data->node)); field->type = (opcode == AMLOP_FIELD || opcode == AMLOP_INDEXFIELD || opcode == AMLOP_BANKFIELD) ? AML_OBJTYPE_FIELDUNIT : AML_OBJTYPE_BUFFERFIELD; if (opcode == AMLOP_INDEXFIELD) { indexval = bpos >> 3; bpos &= 7; } if (field->type == AML_OBJTYPE_BUFFERFIELD && data->type != AML_OBJTYPE_BUFFER) { printf("WARN: %s not buffer\n", aml_nodename(data->node)); data = aml_xconvert(data, AML_OBJTYPE_BUFFER, -1); } field->v_field.type = opcode; field->v_field.bitpos = bpos; field->v_field.bitlen = blen; field->v_field.ref3 = indexval; field->v_field.ref2 = index; field->v_field.ref1 = data; field->v_field.flags = flags; /* Increase reference count */ aml_xaddref(data, "Field.Data"); aml_xaddref(index, "Field.Index"); } /* Parse Field/IndexField/BankField scope */ void aml_xparsefieldlist(struct aml_scope *mscope, int opcode, int flags, struct aml_value *data, struct aml_value *index, int indexval) { struct aml_value *rv; int bpos, blen; if (mscope == NULL) return; bpos = 0; while (mscope->pos < mscope->end) { switch (*mscope->pos) { case 0x00: // reserved, length mscope->pos++; blen = aml_parselength(mscope); break; case 0x01: // flags mscope->pos += 3; blen = 0; break; default: // 4-byte name, length mscope->pos = aml_xparsename(mscope->pos, mscope->node, ns_xcreate, &rv); blen = aml_parselength(mscope); aml_xcreatefield(rv, opcode, data, bpos, blen, index, indexval, flags); break; } bpos += blen; } aml_xpopscope(mscope); } /* * Mutex/Event utility functions */ int acpi_xmutex_acquire(struct aml_scope *, struct aml_value *, int); void acpi_xmutex_release(struct aml_scope *, struct aml_value *); int acpi_xevent_wait(struct aml_scope *, struct aml_value *, int); void acpi_xevent_signal(struct aml_scope *, struct aml_value *); void acpi_xevent_reset(struct aml_scope *, struct aml_value *); int acpi_xmutex_acquire(struct aml_scope *scope, struct aml_value *mtx, int timeout) { int err; if (mtx->v_mtx.owner == NULL || scope == mtx->v_mtx.owner) { /* We are now the owner */ mtx->v_mtx.owner = scope; if (mtx == aml_global_lock) { dnprintf(10,"LOCKING GLOBAL\n"); err = acpi_acquire_global_lock(&dsdt_softc->sc_facs->global_lock); } dnprintf(5,"%s acquires mutex %s\n", scope->node->name, mtx->node->name); return (0); } else if (timeout == 0) { return (1); } /* Wait for mutex */ return (0); } void acpi_xmutex_release(struct aml_scope *scope, struct aml_value *mtx) { int err; if (mtx == aml_global_lock) { dnprintf(10,"UNLOCKING GLOBAL\n"); err=acpi_release_global_lock(&dsdt_softc->sc_facs->global_lock); } dnprintf(5, "%s releases mutex %s\n", scope->node->name, mtx->node->name); mtx->v_mtx.owner = NULL; /* Wakeup waiters */ } int acpi_xevent_wait(struct aml_scope *scope, struct aml_value *evt, int timeout) { if (evt->v_evt.state == 1) { /* Object is signaled */ return (0); } else if (timeout == 0) { /* Zero timeout */ return (1); } /* Wait for timeout or signal */ return (0); } void acpi_xevent_signal(struct aml_scope *scope, struct aml_value *evt) { evt->v_evt.state = 1; /* Wakeup waiters */ } void acpi_xevent_reset(struct aml_scope *scope, struct aml_value *evt) { evt->v_evt.state = 0; } /* Store result value into an object */ void aml_xstore(struct aml_scope *scope, struct aml_value *lhs , int64_t ival, struct aml_value *rhs) { struct aml_value tmp; int mlen; /* Already set */ if (lhs == rhs || lhs == NULL || lhs->type == AML_OBJTYPE_NOTARGET) { return; } memset(&tmp, 0, sizeof(tmp)); tmp.refcnt=99; if (rhs == NULL) { rhs = _aml_setvalue(&tmp, AML_OBJTYPE_INTEGER, ival, NULL); } if (rhs->type == AML_OBJTYPE_BUFFERFIELD || rhs->type == AML_OBJTYPE_FIELDUNIT) { aml_rwfield(rhs, 0, rhs->v_field.bitlen, &tmp, ACPI_IOREAD); rhs = &tmp; } /* Store to LocalX: free value */ if (lhs->stack >= AMLOP_LOCAL0 && lhs->stack <= AMLOP_LOCAL7) aml_freevalue(lhs); lhs = aml_gettgt(lhs, AMLOP_STORE); switch (lhs->type) { case AML_OBJTYPE_UNINITIALIZED: aml_copyvalue(lhs, rhs); break; case AML_OBJTYPE_BUFFERFIELD: case AML_OBJTYPE_FIELDUNIT: aml_rwfield(lhs, 0, lhs->v_field.bitlen, rhs, ACPI_IOWRITE); break; case AML_OBJTYPE_DEBUGOBJ: break; case AML_OBJTYPE_INTEGER: rhs = aml_xconvert(rhs, lhs->type, -1); lhs->v_integer = rhs->v_integer; aml_xdelref(&rhs, "store.int"); break; case AML_OBJTYPE_BUFFER: case AML_OBJTYPE_STRING: rhs = aml_xconvert(rhs, lhs->type, -1); if (lhs->length < rhs->length) { dnprintf(10,"Overrun! %d,%d\n", lhs->length, rhs->length); aml_freevalue(lhs); _aml_setvalue(lhs, rhs->type, rhs->length, NULL); } mlen = min(lhs->length, rhs->length); memset(lhs->v_buffer, 0x00, lhs->length); memcpy(lhs->v_buffer, rhs->v_buffer, mlen); aml_xdelref(&rhs, "store.bufstr"); break; case AML_OBJTYPE_PACKAGE: /* Convert to LHS type, copy into LHS */ if (rhs->type != AML_OBJTYPE_PACKAGE) { aml_die("Copy non-package into package?"); } aml_freevalue(lhs); aml_copyvalue(lhs, rhs); break; default: aml_die("Store to default type! %x\n", lhs->type); break; } aml_freevalue(&tmp); } #ifndef SMALL_KERNEL /* Disassembler routines */ void aml_disprintf(void *arg, const char *fmt, ...); void aml_disprintf(void *arg, const char *fmt, ...) { va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); } void aml_disasm(struct aml_scope *scope, int lvl, void (*dbprintf)(void *, const char *, ...), void *arg) { int pc, opcode; struct aml_opcode *htab; uint64_t ival; struct aml_value *rv, tmp; uint8_t *end; struct aml_scope *ms; char *ch; char mch[64]; if (dbprintf == NULL) dbprintf = aml_disprintf; pc = aml_pc(scope->pos); opcode = aml_parseopcode(scope); htab = aml_findopcode(opcode); /* Display address + indent */ if (lvl <= 0x7FFF) { dbprintf(arg, "%.4x ", pc); for (pc=0; pcpos = aml_xparsename(scope->pos, scope->node, ns_xsearch, &rv); if (rv->type == AML_OBJTYPE_NAMEREF) { ch = "@@@"; aml_xdelref(&rv, "disasm"); break; } /* if this is a method, get arguments */ strlcpy(mch, aml_nodename(rv->node), sizeof(mch)); if (rv->type == AML_OBJTYPE_METHOD) { strlcat(mch, "(", sizeof(mch)); for (ival=0; ivalv_method.flags); ival++) { strlcat(mch, ival ? ", %z" : "%z", sizeof(mch)); } strlcat(mch, ")", sizeof(mch)); } ch = mch; break; case AMLOP_ZERO: case AMLOP_ONE: case AMLOP_ONES: case AMLOP_LOCAL0: case AMLOP_LOCAL1: case AMLOP_LOCAL2: case AMLOP_LOCAL3: case AMLOP_LOCAL4: case AMLOP_LOCAL5: case AMLOP_LOCAL6: case AMLOP_LOCAL7: case AMLOP_ARG0: case AMLOP_ARG1: case AMLOP_ARG2: case AMLOP_ARG3: case AMLOP_ARG4: case AMLOP_ARG5: case AMLOP_ARG6: case AMLOP_NOP: case AMLOP_REVISION: case AMLOP_DEBUG: case AMLOP_CONTINUE: case AMLOP_BREAKPOINT: case AMLOP_BREAK: ch="%m"; break; case AMLOP_BYTEPREFIX: ch="%b"; break; case AMLOP_WORDPREFIX: ch="%w"; break; case AMLOP_DWORDPREFIX: ch="%d"; break; case AMLOP_QWORDPREFIX: ch="%q"; break; case AMLOP_STRINGPREFIX: ch="%a"; break; case AMLOP_INCREMENT: case AMLOP_DECREMENT: case AMLOP_LNOT: case AMLOP_SIZEOF: case AMLOP_DEREFOF: case AMLOP_REFOF: case AMLOP_OBJECTTYPE: case AMLOP_UNLOAD: case AMLOP_RELEASE: case AMLOP_SIGNAL: case AMLOP_RESET: case AMLOP_STALL: case AMLOP_SLEEP: case AMLOP_RETURN: ch="%m(%n)"; break; case AMLOP_OR: case AMLOP_ADD: case AMLOP_AND: case AMLOP_NAND: case AMLOP_XOR: case AMLOP_SHL: case AMLOP_SHR: case AMLOP_NOR: case AMLOP_MOD: case AMLOP_SUBTRACT: case AMLOP_MULTIPLY: case AMLOP_INDEX: case AMLOP_CONCAT: case AMLOP_CONCATRES: case AMLOP_TOSTRING: ch="%m(%n, %n, %n)"; break; case AMLOP_CREATEBYTEFIELD: case AMLOP_CREATEWORDFIELD: case AMLOP_CREATEDWORDFIELD: case AMLOP_CREATEQWORDFIELD: case AMLOP_CREATEBITFIELD: ch="%m(%n, %n, %N)"; break; case AMLOP_CREATEFIELD: ch="%m(%n, %n, %n, %N)"; break; case AMLOP_DIVIDE: case AMLOP_MID: ch="%m(%n, %n, %n, %n)"; break; case AMLOP_LAND: case AMLOP_LOR: case AMLOP_LNOTEQUAL: case AMLOP_LLESSEQUAL: case AMLOP_LLESS: case AMLOP_LEQUAL: case AMLOP_LGREATEREQUAL: case AMLOP_LGREATER: case AMLOP_NOT: case AMLOP_FINDSETLEFTBIT: case AMLOP_FINDSETRIGHTBIT: case AMLOP_TOINTEGER: case AMLOP_TOBUFFER: case AMLOP_TOHEXSTRING: case AMLOP_TODECSTRING: case AMLOP_FROMBCD: case AMLOP_TOBCD: case AMLOP_WAIT: case AMLOP_LOAD: case AMLOP_STORE: case AMLOP_NOTIFY: case AMLOP_COPYOBJECT: ch="%m(%n, %n)"; break; case AMLOP_ACQUIRE: ch = "%m(%n, %w)"; break; case AMLOP_CONDREFOF: ch="%m(%R, %n)"; break; case AMLOP_ALIAS: ch="%m(%n, %N)"; break; case AMLOP_NAME: ch="%m(%N, %n)"; break; case AMLOP_EVENT: ch="%m(%N)"; break; case AMLOP_MUTEX: ch = "%m(%N, %b)"; break; case AMLOP_OPREGION: ch = "%m(%N, %b, %n, %n)"; break; case AMLOP_DATAREGION: ch="%m(%N, %n, %n, %n)"; break; case AMLOP_FATAL: ch = "%m(%b, %d, %n)"; break; case AMLOP_IF: case AMLOP_WHILE: case AMLOP_SCOPE: case AMLOP_THERMALZONE: case AMLOP_VARPACKAGE: end = aml_parseend(scope); ch = "%m(%n) {\n%T}"; break; case AMLOP_DEVICE: end = aml_parseend(scope); ch = "%m(%N) {\n%T}"; break; case AMLOP_POWERRSRC: end = aml_parseend(scope); ch = "%m(%N, %b, %w) {\n%T}"; break; case AMLOP_PROCESSOR: end = aml_parseend(scope); ch = "%m(%N, %b, %d, %b) {\n%T}"; break; case AMLOP_METHOD: end = aml_parseend(scope); ch = "%m(%N, %b) {\n%T}"; break; case AMLOP_PACKAGE: end = aml_parseend(scope); ch = "%m(%b) {\n%T}"; break; case AMLOP_ELSE: end = aml_parseend(scope); ch = "%m {\n%T}"; break; case AMLOP_BUFFER: end = aml_parseend(scope); ch = "%m(%n) { %B }"; break; case AMLOP_INDEXFIELD: end = aml_parseend(scope); ch = "%m(%n, %n, %b) {\n%F}"; break; case AMLOP_BANKFIELD: end = aml_parseend(scope); ch = "%m(%n, %n, %n, %b) {\n%F}"; break; case AMLOP_FIELD: end = aml_parseend(scope); ch = "%m(%n, %b) {\n%F}"; break; case AMLOP_MATCH: ch = "%m(%n, %b, %n, %b, %n, %n)"; break; case AMLOP_LOADTABLE: ch = "%m(%n, %n, %n, %n, %n, %n)"; break; default: aml_die("opcode = %x\n", opcode); break; } /* Parse printable buffer args */ while (ch && *ch) { char c; if (*ch != '%') { dbprintf(arg,"%c", *(ch++)); continue; } c = *(++ch); switch (c) { case 'b': case 'w': case 'd': case 'q': /* Parse simple object: don't allocate */ aml_xparsesimple(scope, c, &tmp); dbprintf(arg,"0x%llx", tmp.v_integer); break; case 'a': dbprintf(arg, "\'%s\'", scope->pos); scope->pos += strlen(scope->pos)+1; break; case 'N': /* Create Name */ rv = aml_xparsesimple(scope, c, NULL); dbprintf(arg,aml_nodename(rv->node)); break; case 'm': /* display mnemonic */ dbprintf(arg,htab->mnem); break; case 'R': /* Search name */ scope->pos = aml_xparsename(scope->pos, scope->node, ns_xdis, &rv); break; case 'z': case 'n': /* generic arg: recurse */ aml_disasm(scope, lvl | 0x8000, dbprintf, arg); break; case 'B': /* Buffer */ scope->pos = end; break; case 'F': /* Field List */ tmp.v_buffer = scope->pos; tmp.length = end - scope->pos; ms = aml_xpushscope(scope, &tmp, scope->node, 0); while (ms && ms->pos < ms->end) { if (*ms->pos == 0x00) { ms->pos++; aml_parselength(ms); } else if (*ms->pos == 0x01) { ms->pos+=3; } else { ms->pos = aml_xparsename(ms->pos, ms->node, ns_xcreate, &rv); aml_parselength(ms); dbprintf(arg," %s\n", aml_nodename(rv->node)); } } aml_xpopscope(ms); /* Display address and closing bracket */ dbprintf(arg,"%.4x ", aml_pc(scope->pos)); for (pc=0; pc<(lvl & 0x7FFF); pc++) { dbprintf(arg," "); } scope->pos = end; break; case 'T': /* Scope: Termlist */ tmp.v_buffer = scope->pos; tmp.length = end - scope->pos; ms = aml_xpushscope(scope, &tmp, scope->node, 0); while (ms && ms->pos < ms->end) { aml_disasm(ms, (lvl + 1) & 0x7FFF, dbprintf, arg); } aml_xpopscope(ms); /* Display address and closing bracket */ dbprintf(arg,"%.4x ", aml_pc(scope->pos)); for (pc=0; pc<(lvl & 0x7FFF); pc++) { dbprintf(arg," "); } scope->pos = end; break; } ch++; } if (lvl <= 0x7FFF) { dbprintf(arg,"\n"); } } #endif /* SMALL_KERNEL */ int aml_busy; /* Evaluate method or buffervalue objects */ struct aml_value * aml_xeval(struct aml_scope *scope, struct aml_value *my_ret, int ret_type, int argc, struct aml_value *argv) { struct aml_value *tmp = my_ret; struct aml_scope *ms; int idx; switch (tmp->type) { case AML_OBJTYPE_NAMEREF: my_ret = aml_seterror(scope, "Undefined name: %s", aml_getname(my_ret->v_nameref)); break; case AML_OBJTYPE_METHOD: dnprintf(10,"\n--== Eval Method [%s, %d args] to %c ==--\n", aml_nodename(tmp->node), AML_METHOD_ARGCOUNT(tmp->v_method.flags), ret_type); ms = aml_xpushscope(scope, tmp, tmp->node, AMLOP_METHOD); /* Parse method arguments */ for (idx=0; idxv_method.flags); idx++) { struct aml_value *sp; sp = aml_getstack(ms, AMLOP_ARG0+idx); if (argv) { aml_copyvalue(sp, &argv[idx]); } else { _aml_setvalue(sp, AML_OBJTYPE_OBJREF, AMLOP_ARG0 + idx, 0); sp->v_objref.ref = aml_xparse(scope, 't', "ARGX"); } } #ifdef ACPI_DEBUG aml_showstack(ms); #endif /* Evaluate method scope */ aml_root.start = tmp->v_method.base; if (tmp->v_method.fneval != NULL) { my_ret = tmp->v_method.fneval(ms, NULL); } else { aml_xparse(ms, 'T', "METHEVAL"); my_ret = ms->retv; } dnprintf(10,"\n--==Finished evaluating method: %s %c\n", aml_nodename(tmp->node), ret_type); #ifdef ACPI_DEBUG aml_showvalue(my_ret, 0); aml_showstack(ms); #endif aml_xpopscope(ms); break; case AML_OBJTYPE_BUFFERFIELD: case AML_OBJTYPE_FIELDUNIT: my_ret = aml_allocvalue(0,0,NULL); dnprintf(20,"quick: Convert Bufferfield to %c 0x%x\n", ret_type, my_ret); aml_rwfield(tmp, 0, tmp->v_field.bitlen, my_ret, ACPI_IOREAD); break; } if (ret_type == 'i' && my_ret && my_ret->type != AML_OBJTYPE_INTEGER) { #ifndef SMALL_KERNEL aml_showvalue(my_ret, 8-100); #endif aml_die("Not Integer"); } return my_ret; } /* * The following opcodes produce return values * TOSTRING -> Str * TOHEXSTR -> Str * TODECSTR -> Str * STRINGPFX -> Str * BUFFER -> Buf * CONCATRES -> Buf * TOBUFFER -> Buf * MID -> Buf|Str * CONCAT -> Buf|Str * PACKAGE -> Pkg * VARPACKAGE -> Pkg * LOCALx -> Obj * ARGx -> Obj * NAMECHAR -> Obj * REFOF -> ObjRef * INDEX -> ObjRef * DEREFOF -> DataRefObj * COPYOBJECT -> DataRefObj * STORE -> DataRefObj * ZERO -> Int * ONE -> Int * ONES -> Int * REVISION -> Int * B/W/D/Q -> Int * OR -> Int * AND -> Int * ADD -> Int * NAND -> Int * XOR -> Int * SHL -> Int * SHR -> Int * NOR -> Int * MOD -> Int * SUBTRACT -> Int * MULTIPLY -> Int * DIVIDE -> Int * NOT -> Int * TOBCD -> Int * FROMBCD -> Int * FSLEFTBIT -> Int * FSRIGHTBIT -> Int * INCREMENT -> Int * DECREMENT -> Int * TOINTEGER -> Int * MATCH -> Int * SIZEOF -> Int * OBJECTTYPE -> Int * TIMER -> Int * CONDREFOF -> Bool * ACQUIRE -> Bool * WAIT -> Bool * LNOT -> Bool * LAND -> Bool * LOR -> Bool * LLESS -> Bool * LEQUAL -> Bool * LGREATER -> Bool * LNOTEQUAL -> Bool * LLESSEQUAL -> Bool * LGREATEREQ -> Bool * LOADTABLE -> DDB * DEBUG -> Debug * The following opcodes do not generate a return value: * NOP * BREAKPOINT * RELEASE * RESET * SIGNAL * NAME * ALIAS * OPREGION * DATAREGION * EVENT * MUTEX * SCOPE * DEVICE * THERMALZONE * POWERRSRC * PROCESSOR * METHOD * CREATEFIELD * CREATEBITFIELD * CREATEBYTEFIELD * CREATEWORDFIELD * CREATEDWORDFIELD * CREATEQWORDFIELD * FIELD * INDEXFIELD * BANKFIELD * STALL * SLEEP * NOTIFY * FATAL * LOAD * UNLOAD * IF * ELSE * WHILE * BREAK * CONTINUE */ /* Parse a simple object from AML Bytestream */ struct aml_value * aml_xparsesimple(struct aml_scope *scope, char ch, struct aml_value *rv) { if (ch == AML_ARG_CREATENAME) { scope->pos = aml_xparsename(scope->pos, scope->node, ns_xcreate, &rv); return rv; } else if (ch == AML_ARG_SEARCHNAME) { scope->pos = aml_xparsename(scope->pos, scope->node, ns_xsearch, &rv); return rv; } if (rv == NULL) rv = aml_allocvalue(0,0,NULL); switch (ch) { case AML_ARG_REVISION: _aml_setvalue(rv, AML_OBJTYPE_INTEGER, AML_REVISION, NULL); break; case AML_ARG_DEBUG: _aml_setvalue(rv, AML_OBJTYPE_DEBUGOBJ, 0, NULL); break; case AML_ARG_BYTE: _aml_setvalue(rv, AML_OBJTYPE_INTEGER, aml_get8(scope->pos), NULL); scope->pos += 1; break; case AML_ARG_WORD: _aml_setvalue(rv, AML_OBJTYPE_INTEGER, aml_get16(scope->pos), NULL); scope->pos += 2; break; case AML_ARG_DWORD: _aml_setvalue(rv, AML_OBJTYPE_INTEGER, aml_get32(scope->pos), NULL); scope->pos += 4; break; case AML_ARG_QWORD: _aml_setvalue(rv, AML_OBJTYPE_INTEGER, aml_get64(scope->pos), NULL); scope->pos += 8; break; case AML_ARG_STRING: _aml_setvalue(rv, AML_OBJTYPE_STRING, -1, scope->pos); scope->pos += rv->length+1; break; } return rv; } /* * Main Opcode Parser/Evaluator * * ret_type is expected type for return value * 'o' = Data Object (Int/Str/Buf/Pkg/Name) * 'i' = Integer * 't' = TermArg (Int/Str/Buf/Pkg) * 'r' = Target (NamedObj/Local/Arg/Null) * 'S' = SuperName (NamedObj/Local/Arg) * 'T' = TermList */ #define aml_debugger(x) int maxdp; struct aml_value * aml_gettgt(struct aml_value *val, int opcode) { while (val && val->type == AML_OBJTYPE_OBJREF) { val = val->v_objref.ref; } return val; } struct aml_value * aml_seterror(struct aml_scope *scope, const char *fmt, ...) { va_list ap; va_start(ap, fmt); printf("### AML PARSE ERROR (0x%x): ", aml_pc(scope->pos)); vprintf(fmt, ap); printf("\n"); va_end(ap); while (scope) { scope->pos = scope->end; scope = scope->parent; } aml_error++; return aml_allocvalue(AML_OBJTYPE_INTEGER, 0, 0); } struct aml_value * aml_xparse(struct aml_scope *scope, int ret_type, const char *stype) { int opcode, idx, pc; struct aml_opcode *htab; struct aml_value *opargs[8], *my_ret, *rv; struct aml_scope *mscope, *iscope; uint8_t *start, *end; const char *ch; int64_t ival; my_ret = NULL; if (scope == NULL || scope->pos >= scope->end) { return NULL; } if (odp++ > 125) panic("depth"); if (odp > maxdp) { maxdp = odp; dnprintf(10, "max depth: %d\n", maxdp); } end = NULL; iscope = scope; start: /* --== Stage 0: Get Opcode ==-- */ start = scope->pos; pc = aml_pc(scope->pos); aml_debugger(scope); opcode = aml_parseopcode(scope); htab = aml_findopcode(opcode); if (htab == NULL) { /* No opcode handler */ aml_die("Unknown opcode: %.4x @ %.4x", opcode, pc); } dnprintf(18,"%.4x %s\n", pc, aml_mnem(opcode, scope->pos)); /* --== Stage 1: Process opcode arguments ==-- */ memset(opargs, 0, sizeof(opargs)); idx = 0; for (ch = htab->args; *ch; ch++) { rv = NULL; switch (*ch) { case AML_ARG_OBJLEN: end = aml_parseend(scope); break; case AML_ARG_IFELSE: /* Special Case: IF-ELSE:piTbpT or IF:piT */ ch = (*end == AMLOP_ELSE && end < scope->end) ? "-TbpT" : "-T"; break; /* Complex arguments */ case 's': case 'S': case AML_ARG_TARGET: case AML_ARG_TERMOBJ: case AML_ARG_INTEGER: if (*ch == 'r' && *scope->pos == AMLOP_ZERO) { /* Special case: NULL Target */ rv = aml_allocvalue(AML_OBJTYPE_NOTARGET, 0, NULL); scope->pos++; } else { rv = aml_xparse(scope, *ch, htab->mnem); if (rv == NULL || aml_error) goto parse_error; } break; /* Simple arguments */ case AML_ARG_BUFFER: case AML_ARG_METHOD: case AML_ARG_FIELDLIST: case AML_ARG_TERMOBJLIST: rv = aml_allocvalue(AML_OBJTYPE_SCOPE, 0, NULL); rv->v_buffer = scope->pos; rv->length = end - scope->pos; scope->pos = end; break; case AML_ARG_CONST: rv = aml_allocvalue(AML_OBJTYPE_INTEGER, (char)opcode, NULL); break; case AML_ARG_CREATENAME: rv = aml_xparsesimple(scope, *ch, NULL); if (rv->type != 0 && opcode != AMLOP_SCOPE) dnprintf(10, "%s value already exists %s\n", aml_nodename(rv->node), htab->mnem); aml_xaddref(rv, "Create Name"); break; case AML_ARG_SEARCHNAME: rv = aml_xparsesimple(scope, *ch, NULL); if (rv->type != AML_OBJTYPE_NAMEREF) aml_xaddref(rv, "Search Name"); break; case AML_ARG_BYTE: case AML_ARG_WORD: case AML_ARG_DWORD: case AML_ARG_QWORD: case AML_ARG_DEBUG: case AML_ARG_STRING: case AML_ARG_REVISION: rv = aml_xparsesimple(scope, *ch, NULL); break; case AML_ARG_STKLOCAL: case AML_ARG_STKARG: rv = aml_getstack(scope, opcode); break; default: aml_die("Unknown arg type: %c\n", *ch); break; } if (rv != NULL) opargs[idx++] = rv; } /* --== Stage 2: Process opcode ==-- */ ival = 0; my_ret = NULL; mscope = NULL; switch (opcode) { case AMLOP_NOP: case AMLOP_BREAKPOINT: break; case AMLOP_LOCAL0: case AMLOP_LOCAL1: case AMLOP_LOCAL2: case AMLOP_LOCAL3: case AMLOP_LOCAL4: case AMLOP_LOCAL5: case AMLOP_LOCAL6: case AMLOP_LOCAL7: case AMLOP_ARG0: case AMLOP_ARG1: case AMLOP_ARG2: case AMLOP_ARG3: case AMLOP_ARG4: case AMLOP_ARG5: case AMLOP_ARG6: my_ret = opargs[0]; aml_xaddref(my_ret, htab->mnem); break; case AMLOP_NAMECHAR: /* opargs[0] = named object (node != NULL), or nameref */ my_ret = opargs[0]; if (scope->type == AMLOP_PACKAGE) { /* Special case for package */ if (my_ret->type == AML_OBJTYPE_NAMEREF) my_ret = aml_allocvalue(AML_OBJTYPE_STRING, -1, aml_getname(my_ret->v_nameref)); else if (my_ret->node) my_ret = aml_allocvalue(AML_OBJTYPE_STRING, -1, aml_nodename(my_ret->node)); break; } if (my_ret->type == AML_OBJTYPE_OBJREF) { my_ret = my_ret->v_objref.ref; aml_xaddref(my_ret, "de-alias"); } if (ret_type == 'i' || ret_type == 't' || ret_type == 'T') { /* Return TermArg or Integer: Evaluate object */ my_ret = aml_xeval(scope, my_ret, ret_type, 0, NULL); } else if (my_ret->type == AML_OBJTYPE_METHOD) { /* This should only happen with CondRef */ dnprintf(12,"non-termarg method : %s\n", stype); aml_xaddref(my_ret, "zoom"); } break; case AMLOP_ZERO: case AMLOP_ONE: case AMLOP_ONES: case AMLOP_DEBUG: case AMLOP_REVISION: case AMLOP_BYTEPREFIX: case AMLOP_WORDPREFIX: case AMLOP_DWORDPREFIX: case AMLOP_QWORDPREFIX: case AMLOP_STRINGPREFIX: my_ret = opargs[0]; break; case AMLOP_BUFFER: /* Buffer: iB => Buffer */ my_ret = aml_allocvalue(AML_OBJTYPE_BUFFER, opargs[0]->v_integer, NULL); memcpy(my_ret->v_buffer, opargs[1]->v_buffer, opargs[1]->length); break; case AMLOP_PACKAGE: case AMLOP_VARPACKAGE: /* Package/VarPackage: bT/iT => Package */ my_ret = aml_allocvalue(AML_OBJTYPE_PACKAGE, opargs[0]->v_integer, 0); mscope = aml_xpushscope(scope, opargs[1], scope->node, AMLOP_PACKAGE); /* Recursively parse package contents */ for (idx=0; idxlength; idx++) { rv = aml_xparse(mscope, 'o', "Package"); if (rv != NULL) { aml_xdelref(&my_ret->v_package[idx], "pkginit"); my_ret->v_package[idx] = rv; } } aml_xpopscope(mscope); mscope = NULL; break; /* Math/Logical operations */ case AMLOP_OR: case AMLOP_ADD: case AMLOP_AND: case AMLOP_NAND: case AMLOP_XOR: case AMLOP_SHL: case AMLOP_SHR: case AMLOP_NOR: case AMLOP_MOD: case AMLOP_SUBTRACT: case AMLOP_MULTIPLY: /* XXX: iir => I */ ival = aml_evalexpr(opargs[0]->v_integer, opargs[1]->v_integer, opcode); aml_xstore(scope, opargs[2], ival, NULL); break; case AMLOP_DIVIDE: /* Divide: iirr => I */ if (opargs[1]->v_integer == 0) { my_ret = aml_seterror(scope, "Divide by Zero!"); break; } ival = aml_evalexpr(opargs[0]->v_integer, opargs[1]->v_integer, AMLOP_MOD); aml_xstore(scope, opargs[2], ival, NULL); ival = aml_evalexpr(opargs[0]->v_integer, opargs[1]->v_integer, AMLOP_DIVIDE); aml_xstore(scope, opargs[3], ival, NULL); break; case AMLOP_NOT: case AMLOP_TOBCD: case AMLOP_FROMBCD: case AMLOP_FINDSETLEFTBIT: case AMLOP_FINDSETRIGHTBIT: /* XXX: ir => I */ ival = aml_evalexpr(opargs[0]->v_integer, 0, opcode); aml_xstore(scope, opargs[1], ival, NULL); break; case AMLOP_INCREMENT: case AMLOP_DECREMENT: /* Inc/Dec: S => I */ my_ret = aml_xeval(scope, opargs[0], AML_ARG_INTEGER, 0, NULL); ival = aml_evalexpr(my_ret->v_integer, 1, opcode); aml_xstore(scope, opargs[0], ival, NULL); break; case AMLOP_LNOT: /* LNot: i => Bool */ ival = aml_evalexpr(opargs[0]->v_integer, 0, opcode); break; case AMLOP_LOR: case AMLOP_LAND: /* XXX: ii => Bool */ ival = aml_evalexpr(opargs[0]->v_integer, opargs[1]->v_integer, opcode); break; case AMLOP_LLESS: case AMLOP_LEQUAL: case AMLOP_LGREATER: case AMLOP_LNOTEQUAL: case AMLOP_LLESSEQUAL: case AMLOP_LGREATEREQUAL: /* XXX: tt => Bool */ ival = aml_xcompare(opargs[0], opargs[1], opcode); break; /* Reference/Store operations */ case AMLOP_CONDREFOF: /* CondRef: rr => I */ ival = 0; if (opargs[0]->node != NULL) { aml_freevalue(opargs[1]); /* Create Object Reference */ _aml_setvalue(opargs[1], AML_OBJTYPE_OBJREF, opcode, opargs[0]); aml_xaddref(opargs[1], "CondRef"); /* Mark that we found it */ ival = -1; } break; case AMLOP_REFOF: /* RefOf: r => ObjRef */ my_ret = aml_allocvalue(AML_OBJTYPE_OBJREF, opcode, opargs[0]); aml_xaddref(my_ret->v_objref.ref, "RefOf"); break; case AMLOP_INDEX: /* Index: tir => ObjRef */ idx = opargs[1]->v_integer; if (idx >= opargs[0]->length || idx < 0) { #ifndef SMALL_KERNEL aml_showvalue(opargs[0], 0); #endif aml_die("Index out of bounds %d/%d\n", idx, opargs[0]->length); } switch (opargs[0]->type) { case AML_OBJTYPE_PACKAGE: /* Don't set opargs[0] to NULL */ if (ret_type == 't' || ret_type == 'i' || ret_type == 'T') { my_ret = opargs[0]->v_package[idx]; aml_xaddref(my_ret, "Index.Package"); } else { my_ret = aml_allocvalue(AML_OBJTYPE_OBJREF, AMLOP_PACKAGE, opargs[0]->v_package[idx]); aml_xaddref(my_ret->v_objref.ref, "Index.Package"); } break; case AML_OBJTYPE_BUFFER: case AML_OBJTYPE_STRING: case AML_OBJTYPE_INTEGER: rv = aml_xconvert(opargs[0], AML_OBJTYPE_BUFFER, -1); if (ret_type == 't' || ret_type == 'i' || ret_type == 'T') { dnprintf(12,"Index.Buf Term: %d = %x\n", idx, rv->v_buffer[idx]); ival = rv->v_buffer[idx]; } else { dnprintf(12, "Index.Buf Targ\n"); my_ret = aml_allocvalue(0,0,NULL); aml_xcreatefield(my_ret, AMLOP_INDEX, rv, 8 * idx, 8, NULL, 0, AML_FIELD_BYTEACC); } aml_xdelref(&rv, "Index.BufStr"); break; default: aml_die("Unknown index : %x\n", opargs[0]->type); break; } aml_xstore(scope, opargs[2], ival, my_ret); break; case AMLOP_DEREFOF: /* DerefOf: t:ObjRef => DataRefObj */ if (opargs[0]->type == AML_OBJTYPE_OBJREF) { my_ret = opargs[0]->v_objref.ref; aml_xaddref(my_ret, "DerefOf"); } else { my_ret = opargs[0]; //aml_xaddref(my_ret, "DerefOf"); } break; case AMLOP_COPYOBJECT: /* CopyObject: t:DataRefObj, s:implename => DataRefObj */ my_ret = opargs[0]; aml_freevalue(opargs[1]); aml_copyvalue(opargs[1], opargs[0]); break; case AMLOP_STORE: /* Store: t:DataRefObj, S:upername => DataRefObj */ my_ret = opargs[0]; aml_xstore(scope, opargs[1], 0, opargs[0]); break; /* Conversion */ case AMLOP_TOINTEGER: /* Source:CData, Result => Integer */ my_ret = aml_xconvert(opargs[0], AML_OBJTYPE_INTEGER, -1); aml_xstore(scope, opargs[1], 0, my_ret); break; case AMLOP_TOBUFFER: /* Source:CData, Result => Buffer */ my_ret = aml_xconvert(opargs[0], AML_OBJTYPE_BUFFER, -1); aml_xstore(scope, opargs[1], 0, my_ret); break; case AMLOP_TOHEXSTRING: /* Source:CData, Result => String */ my_ret = aml_xconvert(opargs[0], AML_OBJTYPE_HEXSTRING, -1); aml_xstore(scope, opargs[1], 0, my_ret); break; case AMLOP_TODECSTRING: /* Source:CData, Result => String */ my_ret = aml_xconvert(opargs[0], AML_OBJTYPE_DECSTRING, -1); aml_xstore(scope, opargs[1], 0, my_ret); break; case AMLOP_TOSTRING: /* Source:B, Length:I, Result => String */ my_ret = aml_xconvert(opargs[0], AML_OBJTYPE_STRING, opargs[1]->v_integer); aml_xstore(scope, opargs[2], 0, my_ret); break; case AMLOP_CONCAT: /* Source1:CData, Source2:CData, Result => CData */ my_ret = aml_xconcat(opargs[0], opargs[1]); aml_xstore(scope, opargs[2], 0, my_ret); break; case AMLOP_CONCATRES: /* Concat two resource buffers: buf1, buf2, result => Buffer */ my_ret = aml_xconcatres(opargs[0], opargs[1]); aml_xstore(scope, opargs[2], 0, my_ret); break; case AMLOP_MID: /* Source:BS, Index:I, Length:I, Result => BS */ my_ret = aml_xmid(opargs[0], opargs[1]->v_integer, opargs[2]->v_integer); aml_xstore(scope, opargs[3], 0, my_ret); break; case AMLOP_MATCH: /* Match: Pkg, Op1, Val1, Op2, Val2, Index */ ival = aml_xmatch(opargs[0], opargs[5]->v_integer, opargs[1]->v_integer, opargs[2]->v_integer, opargs[3]->v_integer, opargs[4]->v_integer); break; case AMLOP_SIZEOF: /* Sizeof: S => i */ rv = aml_gettgt(opargs[0], opcode); ival = rv->length; break; case AMLOP_OBJECTTYPE: /* ObjectType: S => i */ rv = aml_gettgt(opargs[0], opcode); ival = rv->type; break; /* Mutex/Event handlers */ case AMLOP_ACQUIRE: /* Acquire: Sw => Bool */ rv = aml_gettgt(opargs[0], opcode); ival = acpi_xmutex_acquire(scope, rv, opargs[1]->v_integer); break; case AMLOP_RELEASE: /* Release: S */ rv = aml_gettgt(opargs[0], opcode); acpi_xmutex_release(scope, rv); break; case AMLOP_WAIT: /* Wait: Si => Bool */ rv = aml_gettgt(opargs[0], opcode); ival = acpi_xevent_wait(scope, rv, opargs[1]->v_integer); break; case AMLOP_RESET: /* Reset: S */ rv = aml_gettgt(opargs[0], opcode); acpi_xevent_reset(scope, rv); break; case AMLOP_SIGNAL: /* Signal: S */ rv = aml_gettgt(opargs[0], opcode); acpi_xevent_signal(scope, rv); break; /* Named objects */ case AMLOP_NAME: /* Name: Nt */ rv = opargs[0]; aml_freevalue(rv); if (!strcmp(rv->node->name, "_HID") && opargs[1]->type == AML_OBJTYPE_INTEGER) { /* Shortcut for _HID: autoconvert to string */ _aml_setvalue(rv, AML_OBJTYPE_STRING, -1, aml_eisaid(opargs[1]->v_integer)); } else { aml_copyvalue(rv, opargs[1]); } break; case AMLOP_ALIAS: /* Alias: nN */ rv = _aml_setvalue(opargs[1], AML_OBJTYPE_OBJREF, opcode, 0); rv->v_objref.ref = aml_gettgt(opargs[0], opcode); aml_xaddref(rv->v_objref.ref, "Alias"); break; case AMLOP_OPREGION: /* OpRegion: Nbii */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_OPREGION, 0, 0); rv->v_opregion.iospace = opargs[1]->v_integer; rv->v_opregion.iobase = opargs[2]->v_integer; rv->v_opregion.iolen = opargs[3]->v_integer; rv->v_opregion.flag = 0; break; case AMLOP_DATAREGION: /* DataTableRegion: N,t:SigStr,t:OemIDStr,t:OemTableIDStr */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_OPREGION, 0, 0); rv->v_opregion.iospace = GAS_SYSTEM_MEMORY; rv->v_opregion.iobase = 0; rv->v_opregion.iolen = 0; aml_die("AML-DataTableRegion\n"); break; case AMLOP_EVENT: /* Event: N */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_EVENT, 0, 0); rv->v_integer = 0; break; case AMLOP_MUTEX: /* Mutex: Nw */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_MUTEX, 0, 0); rv->v_mtx.synclvl = opargs[1]->v_integer; break; case AMLOP_SCOPE: /* Scope: NT */ rv = opargs[0]; if (rv->type == AML_OBJTYPE_NAMEREF) { printf("Undefined scope: %s\n", aml_getname(rv->v_nameref)); break; } mscope = aml_xpushscope(scope, opargs[1], rv->node, opcode); break; case AMLOP_DEVICE: /* Device: NT */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_DEVICE, 0, 0); mscope = aml_xpushscope(scope, opargs[1], rv->node, opcode); break; case AMLOP_THERMALZONE: /* ThermalZone: NT */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_THERMZONE, 0, 0); mscope = aml_xpushscope(scope, opargs[1], rv->node, opcode); break; case AMLOP_POWERRSRC: /* PowerRsrc: NbwT */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_POWERRSRC, 0, 0); rv->v_powerrsrc.pwr_level = opargs[1]->v_integer; rv->v_powerrsrc.pwr_order = opargs[2]->v_integer; mscope = aml_xpushscope(scope, opargs[3], rv->node, opcode); break; case AMLOP_PROCESSOR: /* Processor: NbdbT */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_PROCESSOR, 0, 0); rv->v_processor.proc_id = opargs[1]->v_integer; rv->v_processor.proc_addr = opargs[2]->v_integer; rv->v_processor.proc_len = opargs[3]->v_integer; mscope = aml_xpushscope(scope, opargs[4], rv->node, opcode); break; case AMLOP_METHOD: /* Method: NbM */ rv = _aml_setvalue(opargs[0], AML_OBJTYPE_METHOD, 0, 0); rv->v_method.flags = opargs[1]->v_integer; rv->v_method.start = opargs[2]->v_buffer; rv->v_method.end = rv->v_method.start + opargs[2]->length; rv->v_method.base = aml_root.start; break; /* Field objects */ case AMLOP_CREATEFIELD: /* Source:B, BitIndex:I, NumBits:I, FieldName */ rv = _aml_setvalue(opargs[3], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer, opargs[2]->v_integer, NULL, 0, 0); break; case AMLOP_CREATEBITFIELD: /* Source:B, BitIndex:I, FieldName */ rv = _aml_setvalue(opargs[2], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer, 1, NULL, 0, 0); break; case AMLOP_CREATEBYTEFIELD: /* Source:B, ByteIndex:I, FieldName */ rv = _aml_setvalue(opargs[2], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer*8, 8, NULL, 0, AML_FIELD_BYTEACC); break; case AMLOP_CREATEWORDFIELD: /* Source:B, ByteIndex:I, FieldName */ rv = _aml_setvalue(opargs[2], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer*8, 16, NULL, 0, AML_FIELD_WORDACC); break; case AMLOP_CREATEDWORDFIELD: /* Source:B, ByteIndex:I, FieldName */ rv = _aml_setvalue(opargs[2], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer*8, 32, NULL, 0, AML_FIELD_DWORDACC); break; case AMLOP_CREATEQWORDFIELD: /* Source:B, ByteIndex:I, FieldName */ rv = _aml_setvalue(opargs[2], AML_OBJTYPE_BUFFERFIELD, 0, 0); aml_xcreatefield(rv, opcode, opargs[0], opargs[1]->v_integer*8, 64, NULL, 0, AML_FIELD_QWORDACC); break; case AMLOP_FIELD: /* Field: n:OpRegion, b:Flags, F:ieldlist */ mscope = aml_xpushscope(scope, opargs[2], scope->node, opcode); aml_xparsefieldlist(mscope, opcode, opargs[1]->v_integer, opargs[0], NULL, 0); mscope = NULL; break; case AMLOP_INDEXFIELD: /* IndexField: n:Index, n:Data, b:Flags, F:ieldlist */ mscope = aml_xpushscope(scope, opargs[3], scope->node, opcode); aml_xparsefieldlist(mscope, opcode, opargs[2]->v_integer, opargs[1], opargs[0], 0); mscope = NULL; break; case AMLOP_BANKFIELD: /* BankField: n:OpRegion, n:Field, i:Bank, b:Flags, F:ieldlist */ mscope = aml_xpushscope(scope, opargs[4], scope->node, opcode); aml_xparsefieldlist(mscope, opcode, opargs[3]->v_integer, opargs[0], opargs[1], opargs[2]->v_integer); mscope = NULL; break; /* Misc functions */ case AMLOP_STALL: /* Stall: i */ acpi_stall(opargs[0]->v_integer); break; case AMLOP_SLEEP: /* Sleep: i */ acpi_sleep(opargs[0]->v_integer); break; case AMLOP_NOTIFY: /* Notify: Si */ rv = aml_gettgt(opargs[0], opcode); dnprintf(50,"Notifying: %s %x\n", aml_nodename(rv->node), opargs[1]->v_integer); aml_notify(rv->node, opargs[1]->v_integer); break; case AMLOP_TIMER: /* Timer: => i */ ival = 0xDEADBEEF; break; case AMLOP_FATAL: /* Fatal: bdi */ aml_die("AML FATAL ERROR: %x,%x,%x\n", opargs[0]->v_integer, opargs[1]->v_integer, opargs[2]->v_integer); break; case AMLOP_LOADTABLE: /* LoadTable(Sig:Str, OEMID:Str, OEMTable:Str, [RootPath:Str], [ParmPath:Str], [ParmData:DataRefObj]) => DDBHandle */ aml_die("LoadTable"); break; case AMLOP_LOAD: /* Load(Object:NameString, DDBHandle:SuperName) */ rv = opargs[0]; if (rv->type != AML_OBJTYPE_OPREGION || rv->v_opregion.iospace != GAS_SYSTEM_MEMORY) { aml_die("LOAD: not a memory region!\n"); } /* Create buffer and read from memory */ _aml_setvalue(opargs[1], AML_OBJTYPE_BUFFER, rv->v_opregion.iolen, NULL); aml_xgasio(rv->v_opregion.iospace, rv->v_opregion.iobase, rv->v_opregion.iolen, opargs[1]->v_buffer, ACPI_IOREAD, 8, ""); /* Validate that this is a SSDT */ if (!valid_acpihdr(opargs[1]->v_buffer, opargs[1]->length, "SSDT")) { aml_die("LOAD: Not a SSDT!\n"); } /* Parse block: set header bytes to NOP */ memset(opargs[1]->v_buffer, AMLOP_NOP, sizeof(struct acpi_table_header)); mscope = aml_xpushscope(scope, opargs[1], scope->node, AMLOP_SCOPE); break; case AMLOP_UNLOAD: /* DDBHandle */ aml_die("Unload"); break; /* Control Flow */ case AMLOP_IF: /* Arguments: iT or iTbT */ if (opargs[0]->v_integer) { dnprintf(10,"parse-if @ %.4x\n", pc); mscope = aml_xpushscope(scope, opargs[1], scope->node, AMLOP_IF); } else if (opargs[3] != NULL) { dnprintf(10,"parse-else @ %.4x\n", pc); mscope = aml_xpushscope(scope, opargs[3], scope->node, AMLOP_ELSE); } break; case AMLOP_WHILE: if (opargs[0]->v_integer) { /* Set parent position to start of WHILE */ scope->pos = start; mscope = aml_xpushscope(scope, opargs[1], scope->node, AMLOP_WHILE); } break; case AMLOP_BREAK: /* Break: Find While Scope parent, mark type as null */ aml_xfindscope(scope, AMLOP_WHILE, AMLOP_BREAK); break; case AMLOP_CONTINUE: /* Find Scope.. mark all objects as invalid on way to root */ aml_xfindscope(scope, AMLOP_WHILE, AMLOP_CONTINUE); break; case AMLOP_RETURN: mscope = aml_xfindscope(scope, AMLOP_METHOD, AMLOP_RETURN); if (mscope->retv) { aml_die("already allocated\n"); } mscope->retv = aml_allocvalue(0,0,NULL); aml_copyvalue(mscope->retv, opargs[0]); mscope = NULL; break; default: /* may be set direct result */ aml_die("Unknown opcode: %x:%s\n", opcode, htab->mnem); break; } if (mscope != NULL) { /* Change our scope to new scope */ scope = mscope; } if ((ret_type == 'i' || ret_type == 't') && my_ret == NULL) { dnprintf(10,"quick: %.4x [%s] alloc return integer = 0x%llx\n", pc, htab->mnem, ival); my_ret = aml_allocvalue(AML_OBJTYPE_INTEGER, ival, NULL); } if (ret_type == 'i' && my_ret && my_ret->type != AML_OBJTYPE_INTEGER) { dnprintf(10,"quick: %.4x convert to integer %s -> %s\n", pc, htab->mnem, stype); my_ret = aml_xconvert(my_ret, AML_OBJTYPE_INTEGER, -1); } if (my_ret != NULL) { /* Display result */ dnprintf(20,"quick: %.4x %18s %c %.4x\n", pc, stype, ret_type, my_ret->stack); } /* End opcode: display/free arguments */ parse_error: for (idx=0; idx<8; idx++) { if (opargs[idx] == my_ret) opargs[idx] = NULL; aml_xdelref(&opargs[idx], "oparg"); } /* If parsing whole scope and not done, start again */ if (ret_type == 'T') { aml_xdelref(&my_ret, "scope.loop"); while (scope->pos >= scope->end && scope != iscope) { /* Pop intermediate scope */ scope = aml_xpopscope(scope); } if (scope->pos && scope->pos < scope->end) goto start; } odp--; dnprintf(50, ">>return [%s] %s %c %p\n", aml_nodename(scope->node), stype, ret_type, my_ret); return my_ret; } int acpi_parse_aml(struct acpi_softc *sc, u_int8_t *start, u_int32_t length) { struct aml_scope *scope; struct aml_value res; dsdt_softc = sc; aml_root.start = start; memset(&res, 0, sizeof(res)); res.type = AML_OBJTYPE_SCOPE; res.length = length; res.v_buffer = start; /* Push toplevel scope, parse AML */ aml_error = 0; scope = aml_xpushscope(NULL, &res, &aml_root, AMLOP_SCOPE); aml_busy++; aml_xparse(scope, 'T', "TopLevel"); aml_busy--; aml_xpopscope(scope); if (aml_error) { printf("error in acpi_parse_aml\n"); return -1; } return (0); } /* * @@@: External API * * evaluate an AML node * Returns a copy of the value in res (must be freed by user) */ int aml_evalnode(struct acpi_softc *sc, struct aml_node *node, int argc, struct aml_value *argv, struct aml_value *res) { struct aml_value *xres; if (res) memset(res, 0, sizeof(*res)); if (node == NULL || node->value == NULL) return (ACPI_E_BADVALUE); dnprintf(12,"EVALNODE: %s %d\n", aml_nodename(node), acpi_nalloc); aml_error = 0; xres = aml_xeval(NULL, node->value, 't', argc, argv); if (xres) { if (res) aml_copyvalue(res, xres); if (xres != node->value) aml_xdelref(&xres, "evalnode"); } if (aml_error) { printf("error evaluating: %s\n", aml_nodename(node)); return (-1); } return (0); } /* * evaluate an AML name * Returns a copy of the value in res (must be freed by user) */ int aml_evalname(struct acpi_softc *sc, struct aml_node *parent, const char *name, int argc, struct aml_value *argv, struct aml_value *res) { parent = aml_searchname(parent, name); return aml_evalnode(sc, parent, argc, argv, res); } /* * evaluate an AML integer object */ int aml_evalinteger(struct acpi_softc *sc, struct aml_node *parent, const char *name, int argc, struct aml_value *argv, int64_t *ival) { struct aml_value res; int rc; parent = aml_searchname(parent, name); rc = aml_evalnode(sc, parent, argc, argv, &res); if (rc == 0) { *ival = aml_val2int(&res); aml_freevalue(&res); } return rc; } /* * Search for an AML name in namespace.. root only */ struct aml_node * aml_searchname(struct aml_node *root, const void *vname) { char *name = (char *)vname; dnprintf(25,"Searchname: %s:%s = ", aml_nodename(root), vname); if (*name == AMLOP_ROOTCHAR) { root = &aml_root; name++; } while (*name != 0) { root = __aml_search(root, name, 0); name += (name[4] == '.') ? 5 : 4; } dnprintf(25,"%p %s\n", root, aml_nodename(root)); return root; } /* * Search for relative name */ struct aml_node * aml_searchrel(struct aml_node *root, const void *vname) { struct aml_node *res; while (root) { res = aml_searchname(root, vname); if (res != NULL) return res; root = root->parent; } return NULL; } void acpi_getdevlist(struct acpi_devlist_head *list, struct aml_node *root, struct aml_value *pkg, int off) { struct acpi_devlist *dl; struct aml_node *node; int idx; for (idx=off; idxlength; idx++) { node = aml_searchname(root, pkg->v_package[idx]->v_string); if (node) { dl = acpi_os_malloc(sizeof(*dl)); if (dl) { dl->dev_node = node; TAILQ_INSERT_TAIL(list, dl, dev_link); } } } } void acpi_freedevlist(struct acpi_devlist_head *list) { struct acpi_devlist *dl; while ((dl = TAILQ_FIRST(list)) != NULL) { TAILQ_REMOVE(list, dl, dev_link); acpi_os_free(dl); } }