dist/compiler/aslanalyze.c

1.1  jruoho
1.1  jruoho /******************************************************************************
1.1  jruoho  *
1.1  jruoho  * Module Name: aslanalyze.c - check for semantic errors
1.1  jruoho  *
1.1  jruoho  *****************************************************************************/
1.1  jruoho
1.1  jruoho /******************************************************************************
1.1  jruoho  *
1.1  jruoho  * 1. Copyright Notice
1.1  jruoho  *
1.1  jruoho  * Some or all of this work - Copyright (c) 1999 - 2010, Intel Corp.
1.1  jruoho  * All rights reserved.
1.1  jruoho  *
1.1  jruoho  * 2. License
1.1  jruoho  *
1.1  jruoho  * 2.1. This is your license from Intel Corp. under its intellectual property
1.1  jruoho  * rights.  You may have additional license terms from the party that provided
1.1  jruoho  * you this software, covering your right to use that party's intellectual
1.1  jruoho  * property rights.
1.1  jruoho  *
1.1  jruoho  * 2.2. Intel grants, free of charge, to any person ("Licensee") obtaining a
1.1  jruoho  * copy of the source code appearing in this file ("Covered Code") an
1.1  jruoho  * irrevocable, perpetual, worldwide license under Intel's copyrights in the
1.1  jruoho  * base code distributed originally by Intel ("Original Intel Code") to copy,
1.1  jruoho  * make derivatives, distribute, use and display any portion of the Covered
1.1  jruoho  * Code in any form, with the right to sublicense such rights; and
1.1  jruoho  *
1.1  jruoho  * 2.3. Intel grants Licensee a non-exclusive and non-transferable patent
1.1  jruoho  * license (with the right to sublicense), under only those claims of Intel
1.1  jruoho  * patents that are infringed by the Original Intel Code, to make, use, sell,
1.1  jruoho  * offer to sell, and import the Covered Code and derivative works thereof
1.1  jruoho  * solely to the minimum extent necessary to exercise the above copyright
1.1  jruoho  * license, and in no event shall the patent license extend to any additions
1.1  jruoho  * to or modifications of the Original Intel Code.  No other license or right
1.1  jruoho  * is granted directly or by implication, estoppel or otherwise;
1.1  jruoho  *
1.1  jruoho  * The above copyright and patent license is granted only if the following
1.1  jruoho  * conditions are met:
1.1  jruoho  *
1.1  jruoho  * 3. Conditions
1.1  jruoho  *
1.1  jruoho  * 3.1. Redistribution of Source with Rights to Further Distribute Source.
1.1  jruoho  * Redistribution of source code of any substantial portion of the Covered
1.1  jruoho  * Code or modification with rights to further distribute source must include
1.1  jruoho  * the above Copyright Notice, the above License, this list of Conditions,
1.1  jruoho  * and the following Disclaimer and Export Compliance provision.  In addition,
1.1  jruoho  * Licensee must cause all Covered Code to which Licensee contributes to
1.1  jruoho  * contain a file documenting the changes Licensee made to create that Covered
1.1  jruoho  * Code and the date of any change.  Licensee must include in that file the
1.1  jruoho  * documentation of any changes made by any predecessor Licensee.  Licensee
1.1  jruoho  * must include a prominent statement that the modification is derived,
1.1  jruoho  * directly or indirectly, from Original Intel Code.
1.1  jruoho  *
1.1  jruoho  * 3.2. Redistribution of Source with no Rights to Further Distribute Source.
1.1  jruoho  * Redistribution of source code of any substantial portion of the Covered
1.1  jruoho  * Code or modification without rights to further distribute source must
1.1  jruoho  * include the following Disclaimer and Export Compliance provision in the
1.1  jruoho  * documentation and/or other materials provided with distribution.  In
1.1  jruoho  * addition, Licensee may not authorize further sublicense of source of any
1.1  jruoho  * portion of the Covered Code, and must include terms to the effect that the
1.1  jruoho  * license from Licensee to its licensee is limited to the intellectual
1.1  jruoho  * property embodied in the software Licensee provides to its licensee, and
1.1  jruoho  * not to intellectual property embodied in modifications its licensee may
1.1  jruoho  * make.
1.1  jruoho  *
1.1  jruoho  * 3.3. Redistribution of Executable. Redistribution in executable form of any
1.1  jruoho  * substantial portion of the Covered Code or modification must reproduce the
1.1  jruoho  * above Copyright Notice, and the following Disclaimer and Export Compliance
1.1  jruoho  * provision in the documentation and/or other materials provided with the
1.1  jruoho  * distribution.
1.1  jruoho  *
1.1  jruoho  * 3.4. Intel retains all right, title, and interest in and to the Original
1.1  jruoho  * Intel Code.
1.1  jruoho  *
1.1  jruoho  * 3.5. Neither the name Intel nor any other trademark owned or controlled by
1.1  jruoho  * Intel shall be used in advertising or otherwise to promote the sale, use or
1.1  jruoho  * other dealings in products derived from or relating to the Covered Code
1.1  jruoho  * without prior written authorization from Intel.
1.1  jruoho  *
1.1  jruoho  * 4. Disclaimer and Export Compliance
1.1  jruoho  *
1.1  jruoho  * 4.1. INTEL MAKES NO WARRANTY OF ANY KIND REGARDING ANY SOFTWARE PROVIDED
1.1  jruoho  * HERE.  ANY SOFTWARE ORIGINATING FROM INTEL OR DERIVED FROM INTEL SOFTWARE
1.1  jruoho  * IS PROVIDED "AS IS," AND INTEL WILL NOT PROVIDE ANY SUPPORT,  ASSISTANCE,
1.1  jruoho  * INSTALLATION, TRAINING OR OTHER SERVICES.  INTEL WILL NOT PROVIDE ANY
1.1  jruoho  * UPDATES, ENHANCEMENTS OR EXTENSIONS.  INTEL SPECIFICALLY DISCLAIMS ANY
1.1  jruoho  * IMPLIED WARRANTIES OF MERCHANTABILITY, NONINFRINGEMENT AND FITNESS FOR A
1.1  jruoho  * PARTICULAR PURPOSE.
1.1  jruoho  *
1.1  jruoho  * 4.2. IN NO EVENT SHALL INTEL HAVE ANY LIABILITY TO LICENSEE, ITS LICENSEES
1.1  jruoho  * OR ANY OTHER THIRD PARTY, FOR ANY LOST PROFITS, LOST DATA, LOSS OF USE OR
1.1  jruoho  * COSTS OF PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES, OR FOR ANY INDIRECT,
1.1  jruoho  * SPECIAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THIS AGREEMENT, UNDER ANY
1.1  jruoho  * CAUSE OF ACTION OR THEORY OF LIABILITY, AND IRRESPECTIVE OF WHETHER INTEL
1.1  jruoho  * HAS ADVANCE NOTICE OF THE POSSIBILITY OF SUCH DAMAGES.  THESE LIMITATIONS
1.1  jruoho  * SHALL APPLY NOTWITHSTANDING THE FAILURE OF THE ESSENTIAL PURPOSE OF ANY
1.1  jruoho  * LIMITED REMEDY.
1.1  jruoho  *
1.1  jruoho  * 4.3. Licensee shall not export, either directly or indirectly, any of this
1.1  jruoho  * software or system incorporating such software without first obtaining any
1.1  jruoho  * required license or other approval from the U. S. Department of Commerce or
1.1  jruoho  * any other agency or department of the United States Government.  In the
1.1  jruoho  * event Licensee exports any such software from the United States or
1.1  jruoho  * re-exports any such software from a foreign destination, Licensee shall
1.1  jruoho  * ensure that the distribution and export/re-export of the software is in
1.1  jruoho  * compliance with all laws, regulations, orders, or other restrictions of the
1.1  jruoho  * U.S. Export Administration Regulations. Licensee agrees that neither it nor
1.1  jruoho  * any of its subsidiaries will export/re-export any technical data, process,
1.1  jruoho  * software, or service, directly or indirectly, to any country for which the
1.1  jruoho  * United States government or any agency thereof requires an export license,
1.1  jruoho  * other governmental approval, or letter of assurance, without first obtaining
1.1  jruoho  * such license, approval or letter.
1.1  jruoho  *
1.1  jruoho  *****************************************************************************/
1.1  jruoho
1.1  jruoho
1.1  jruoho #include "aslcompiler.h"
1.1  jruoho #include "aslcompiler.y.h"
1.1  jruoho #include "acparser.h"
1.1  jruoho #include "amlcode.h"
1.1  jruoho
1.1  jruoho #define _COMPONENT          ACPI_COMPILER
1.1  jruoho         ACPI_MODULE_NAME    ("aslanalyze")
1.1  jruoho
1.1  jruoho /* Local prototypes */
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapArgTypeToBtype (
1.1  jruoho     UINT32                  ArgType);
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapEtypeToBtype (
1.1  jruoho     UINT32                  Etype);
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AnFormatBtype (
1.1  jruoho     char                    *Buffer,
1.1  jruoho     UINT32                  Btype);
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnGetBtype (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapObjTypeToBtype (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho static BOOLEAN
1.1  jruoho AnLastStatementIsReturn (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AnCheckMethodReturnValue (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo,
1.1  jruoho     ACPI_PARSE_OBJECT       *ArgOp,
1.1  jruoho     UINT32                  RequiredBtypes,
1.1  jruoho     UINT32                  ThisNodeBtype);
1.1  jruoho
1.1  jruoho static BOOLEAN
1.1  jruoho AnIsInternalMethod (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnGetInternalMethodReturnType (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho BOOLEAN
1.1  jruoho AnIsResultUsed (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnIsInternalMethod
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op              - Current op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Boolean
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Check for an internal control method.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static BOOLEAN
1.1  jruoho AnIsInternalMethod (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     if ((!ACPI_STRCMP (Op->Asl.ExternalName, "\\_OSI")) ||
1.1  jruoho         (!ACPI_STRCMP (Op->Asl.ExternalName, "_OSI")))
1.1  jruoho     {
1.1  jruoho         return (TRUE);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (FALSE);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnGetInternalMethodReturnType
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op              - Current op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Btype
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Get the return type of an internal method
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnGetInternalMethodReturnType (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     if ((!ACPI_STRCMP (Op->Asl.ExternalName, "\\_OSI")) ||
1.1  jruoho         (!ACPI_STRCMP (Op->Asl.ExternalName, "_OSI")))
1.1  jruoho     {
1.1  jruoho         return (ACPI_BTYPE_STRING);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (0);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMapArgTypeToBtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ArgType      - The ARGI required type(s) for this argument,
1.1  jruoho  *                             from the opcode info table
1.1  jruoho  *
1.1  jruoho  * RETURN:      The corresponding Bit-encoded types
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Convert an encoded ARGI required argument type code into a
1.1  jruoho  *              bitfield type code. Implements the implicit source conversion
1.1  jruoho  *              rules.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapArgTypeToBtype (
1.1  jruoho     UINT32                  ArgType)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     switch (ArgType)
1.1  jruoho     {
1.1  jruoho
1.1  jruoho     /* Simple types */
1.1  jruoho
1.1  jruoho     case ARGI_ANYTYPE:
1.1  jruoho         return (ACPI_BTYPE_OBJECTS_AND_REFS);
1.1  jruoho
1.1  jruoho     case ARGI_PACKAGE:
1.1  jruoho         return (ACPI_BTYPE_PACKAGE);
1.1  jruoho
1.1  jruoho     case ARGI_EVENT:
1.1  jruoho         return (ACPI_BTYPE_EVENT);
1.1  jruoho
1.1  jruoho     case ARGI_MUTEX:
1.1  jruoho         return (ACPI_BTYPE_MUTEX);
1.1  jruoho
1.1  jruoho     case ARGI_DDBHANDLE:
1.1  jruoho         /*
1.1  jruoho          * DDBHandleObject := SuperName
1.1  jruoho          * ACPI_BTYPE_REFERENCE: Index reference as parameter of Load/Unload
1.1  jruoho          */
1.1  jruoho         return (ACPI_BTYPE_DDB_HANDLE | ACPI_BTYPE_REFERENCE);
1.1  jruoho
1.1  jruoho     /* Interchangeable types */
1.1  jruoho     /*
1.1  jruoho      * Source conversion rules:
1.1  jruoho      * Integer, String, and Buffer are all interchangeable
1.1  jruoho      */
1.1  jruoho     case ARGI_INTEGER:
1.1  jruoho     case ARGI_STRING:
1.1  jruoho     case ARGI_BUFFER:
1.1  jruoho     case ARGI_BUFFER_OR_STRING:
1.1  jruoho     case ARGI_COMPUTEDATA:
1.1  jruoho         return (ACPI_BTYPE_COMPUTE_DATA);
1.1  jruoho
1.1  jruoho     /* References */
1.1  jruoho
1.1  jruoho     case ARGI_INTEGER_REF:
1.1  jruoho         return (ACPI_BTYPE_INTEGER);
1.1  jruoho
1.1  jruoho     case ARGI_OBJECT_REF:
1.1  jruoho         return (ACPI_BTYPE_ALL_OBJECTS);
1.1  jruoho
1.1  jruoho     case ARGI_DEVICE_REF:
1.1  jruoho         return (ACPI_BTYPE_DEVICE_OBJECTS);
1.1  jruoho
1.1  jruoho     case ARGI_REFERENCE:
1.1  jruoho         return (ACPI_BTYPE_REFERENCE);
1.1  jruoho
1.1  jruoho     case ARGI_TARGETREF:
1.1  jruoho     case ARGI_FIXED_TARGET:
1.1  jruoho     case ARGI_SIMPLE_TARGET:
1.1  jruoho         return (ACPI_BTYPE_OBJECTS_AND_REFS);
1.1  jruoho
1.1  jruoho     /* Complex types */
1.1  jruoho
1.1  jruoho     case ARGI_DATAOBJECT:
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Buffer, string, package or reference to a Op -
1.1  jruoho          * Used only by SizeOf operator
1.1  jruoho          */
1.1  jruoho         return (ACPI_BTYPE_STRING | ACPI_BTYPE_BUFFER |
1.1  jruoho             ACPI_BTYPE_PACKAGE | ACPI_BTYPE_REFERENCE);
1.1  jruoho
1.1  jruoho     case ARGI_COMPLEXOBJ:
1.1  jruoho
1.1  jruoho         /* Buffer, String, or package */
1.1  jruoho
1.1  jruoho         return (ACPI_BTYPE_STRING | ACPI_BTYPE_BUFFER | ACPI_BTYPE_PACKAGE);
1.1  jruoho
1.1  jruoho     case ARGI_REF_OR_STRING:
1.1  jruoho         return (ACPI_BTYPE_STRING | ACPI_BTYPE_REFERENCE);
1.1  jruoho
1.1  jruoho     case ARGI_REGION_OR_BUFFER:
1.1  jruoho
1.1  jruoho         /* Used by Load() only. Allow buffers in addition to regions/fields */
1.1  jruoho
1.1  jruoho         return (ACPI_BTYPE_REGION | ACPI_BTYPE_BUFFER | ACPI_BTYPE_FIELD_UNIT);
1.1  jruoho
1.1  jruoho     case ARGI_DATAREFOBJ:
1.1  jruoho         return (ACPI_BTYPE_INTEGER |ACPI_BTYPE_STRING | ACPI_BTYPE_BUFFER |
1.1  jruoho             ACPI_BTYPE_PACKAGE | ACPI_BTYPE_REFERENCE | ACPI_BTYPE_DDB_HANDLE);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (ACPI_BTYPE_OBJECTS_AND_REFS);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMapEtypeToBtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Etype           - Encoded ACPI Type
1.1  jruoho  *
1.1  jruoho  * RETURN:      Btype corresponding to the Etype
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Convert an encoded ACPI type to a bitfield type applying the
1.1  jruoho  *              operand conversion rules. In other words, returns the type(s)
1.1  jruoho  *              this Etype is implicitly converted to during interpretation.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapEtypeToBtype (
1.1  jruoho     UINT32                  Etype)
1.1  jruoho {
1.1  jruoho
1.1  jruoho
1.1  jruoho     if (Etype == ACPI_TYPE_ANY)
1.1  jruoho     {
1.1  jruoho         return ACPI_BTYPE_OBJECTS_AND_REFS;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Try the standard ACPI data types */
1.1  jruoho
1.1  jruoho     if (Etype <= ACPI_TYPE_EXTERNAL_MAX)
1.1  jruoho     {
1.1  jruoho         /*
1.1  jruoho          * This switch statement implements the allowed operand conversion
1.1  jruoho          * rules as per the "ASL Data Types" section of the ACPI
1.1  jruoho          * specification.
1.1  jruoho          */
1.1  jruoho         switch (Etype)
1.1  jruoho         {
1.1  jruoho         case ACPI_TYPE_INTEGER:
1.1  jruoho             return (ACPI_BTYPE_COMPUTE_DATA | ACPI_BTYPE_DDB_HANDLE);
1.1  jruoho
1.1  jruoho         case ACPI_TYPE_STRING:
1.1  jruoho         case ACPI_TYPE_BUFFER:
1.1  jruoho             return (ACPI_BTYPE_COMPUTE_DATA);
1.1  jruoho
1.1  jruoho         case ACPI_TYPE_PACKAGE:
1.1  jruoho             return (ACPI_BTYPE_PACKAGE);
1.1  jruoho
1.1  jruoho         case ACPI_TYPE_FIELD_UNIT:
1.1  jruoho             return (ACPI_BTYPE_COMPUTE_DATA | ACPI_BTYPE_FIELD_UNIT);
1.1  jruoho
1.1  jruoho         case ACPI_TYPE_BUFFER_FIELD:
1.1  jruoho             return (ACPI_BTYPE_COMPUTE_DATA | ACPI_BTYPE_BUFFER_FIELD);
1.1  jruoho
1.1  jruoho         case ACPI_TYPE_DDB_HANDLE:
1.1  jruoho             return (ACPI_BTYPE_INTEGER | ACPI_BTYPE_DDB_HANDLE);
1.1  jruoho
1.1  jruoho         case ACPI_BTYPE_DEBUG_OBJECT:
1.1  jruoho
1.1  jruoho             /* Cannot be used as a source operand */
1.1  jruoho
1.1  jruoho             return (0);
1.1  jruoho
1.1  jruoho         default:
1.1  jruoho             return (1 << (Etype - 1));
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Try the internal data types */
1.1  jruoho
1.1  jruoho     switch (Etype)
1.1  jruoho     {
1.1  jruoho     case ACPI_TYPE_LOCAL_REGION_FIELD:
1.1  jruoho     case ACPI_TYPE_LOCAL_BANK_FIELD:
1.1  jruoho     case ACPI_TYPE_LOCAL_INDEX_FIELD:
1.1  jruoho
1.1  jruoho         /* Named fields can be either Integer/Buffer/String */
1.1  jruoho
1.1  jruoho         return (ACPI_BTYPE_COMPUTE_DATA | ACPI_BTYPE_FIELD_UNIT);
1.1  jruoho
1.1  jruoho     case ACPI_TYPE_LOCAL_ALIAS:
1.1  jruoho
1.1  jruoho         return (ACPI_BTYPE_INTEGER);
1.1  jruoho
1.1  jruoho
1.1  jruoho     case ACPI_TYPE_LOCAL_RESOURCE:
1.1  jruoho     case ACPI_TYPE_LOCAL_RESOURCE_FIELD:
1.1  jruoho
1.1  jruoho         return (ACPI_BTYPE_REFERENCE);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         printf ("Unhandled encoded type: %X\n", Etype);
1.1  jruoho         return (0);
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnFormatBtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Btype               - Bitfield of ACPI types
1.1  jruoho  *              Buffer              - Where to put the ascii string
1.1  jruoho  *
1.1  jruoho  * RETURN:      None.
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Convert a Btype to a string of ACPI types
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AnFormatBtype (
1.1  jruoho     char                    *Buffer,
1.1  jruoho     UINT32                  Btype)
1.1  jruoho {
1.1  jruoho     UINT32                  Type;
1.1  jruoho     BOOLEAN                 First = TRUE;
1.1  jruoho
1.1  jruoho
1.1  jruoho     *Buffer = 0;
1.1  jruoho
1.1  jruoho     if (Btype == 0)
1.1  jruoho     {
1.1  jruoho         strcat (Buffer, "NoReturnValue");
1.1  jruoho         return;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     for (Type = 1; Type <= ACPI_TYPE_EXTERNAL_MAX; Type++)
1.1  jruoho     {
1.1  jruoho         if (Btype & 0x00000001)
1.1  jruoho         {
1.1  jruoho             if (!First)
1.1  jruoho             {
1.1  jruoho                 strcat (Buffer, "|");
1.1  jruoho             }
1.1  jruoho             First = FALSE;
1.1  jruoho             strcat (Buffer, AcpiUtGetTypeName (Type));
1.1  jruoho         }
1.1  jruoho         Btype >>= 1;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     if (Btype & 0x00000001)
1.1  jruoho     {
1.1  jruoho         if (!First)
1.1  jruoho         {
1.1  jruoho             strcat (Buffer, "|");
1.1  jruoho         }
1.1  jruoho         First = FALSE;
1.1  jruoho         strcat (Buffer, "Reference");
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     Btype >>= 1;
1.1  jruoho     if (Btype & 0x00000001)
1.1  jruoho     {
1.1  jruoho         if (!First)
1.1  jruoho         {
1.1  jruoho             strcat (Buffer, "|");
1.1  jruoho         }
1.1  jruoho         First = FALSE;
1.1  jruoho         strcat (Buffer, "Resource");
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnGetBtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op          - Parse node whose type will be returned.
1.1  jruoho  *
1.1  jruoho  * RETURN:      The Btype associated with the Op.
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Get the (bitfield) ACPI type associated with the parse node.
1.1  jruoho  *              Handles the case where the node is a name or method call and
1.1  jruoho  *              the actual type must be obtained from the namespace node.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnGetBtype (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho     ACPI_NAMESPACE_NODE     *Node;
1.1  jruoho     ACPI_PARSE_OBJECT       *ReferencedNode;
1.1  jruoho     UINT32                  ThisNodeBtype = 0;
1.1  jruoho
1.1  jruoho
1.1  jruoho     if ((Op->Asl.ParseOpcode == PARSEOP_NAMESEG)     ||
1.1  jruoho         (Op->Asl.ParseOpcode == PARSEOP_NAMESTRING)  ||
1.1  jruoho         (Op->Asl.ParseOpcode == PARSEOP_METHODCALL))
1.1  jruoho     {
1.1  jruoho         Node = Op->Asl.Node;
1.1  jruoho         if (!Node)
1.1  jruoho         {
1.1  jruoho             DbgPrint (ASL_DEBUG_OUTPUT,
1.1  jruoho                 "No attached Nsnode: [%s] at line %u name [%s], ignoring typecheck\n",
1.1  jruoho                 Op->Asl.ParseOpName, Op->Asl.LineNumber,
1.1  jruoho                 Op->Asl.ExternalName);
1.1  jruoho             return ACPI_UINT32_MAX;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         ThisNodeBtype = AnMapEtypeToBtype (Node->Type);
1.1  jruoho         if (!ThisNodeBtype)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_COMPILER_INTERNAL, Op,
1.1  jruoho                 "could not map type");
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Since it was a named reference, enable the
1.1  jruoho          * reference bit also
1.1  jruoho          */
1.1  jruoho         ThisNodeBtype |= ACPI_BTYPE_REFERENCE;
1.1  jruoho
1.1  jruoho         if (Op->Asl.ParseOpcode == PARSEOP_METHODCALL)
1.1  jruoho         {
1.1  jruoho             ReferencedNode = Node->Op;
1.1  jruoho             if (!ReferencedNode)
1.1  jruoho             {
1.1  jruoho                 /* Check for an internal method */
1.1  jruoho
1.1  jruoho                 if (AnIsInternalMethod (Op))
1.1  jruoho                 {
1.1  jruoho                     return (AnGetInternalMethodReturnType (Op));
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 AslError (ASL_ERROR, ASL_MSG_COMPILER_INTERNAL, Op,
1.1  jruoho                     "null Op pointer");
1.1  jruoho                 return ACPI_UINT32_MAX;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             if (ReferencedNode->Asl.CompileFlags & NODE_METHOD_TYPED)
1.1  jruoho             {
1.1  jruoho                 ThisNodeBtype = ReferencedNode->Asl.AcpiBtype;
1.1  jruoho             }
1.1  jruoho             else
1.1  jruoho             {
1.1  jruoho                 return (ACPI_UINT32_MAX -1);
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho     else
1.1  jruoho     {
1.1  jruoho         ThisNodeBtype = Op->Asl.AcpiBtype;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (ThisNodeBtype);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMapObjTypeToBtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op              - A parse node
1.1  jruoho  *
1.1  jruoho  * RETURN:      A Btype
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Map object to the associated "Btype"
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static UINT32
1.1  jruoho AnMapObjTypeToBtype (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_OBJECTTYPE_BFF:        /* "BuffFieldObj" */
1.1  jruoho         return (ACPI_BTYPE_BUFFER_FIELD);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_BUF:        /* "BuffObj" */
1.1  jruoho         return (ACPI_BTYPE_BUFFER);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_DDB:        /* "DDBHandleObj" */
1.1  jruoho         return (ACPI_BTYPE_DDB_HANDLE);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_DEV:        /* "DeviceObj" */
1.1  jruoho         return (ACPI_BTYPE_DEVICE);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_EVT:        /* "EventObj" */
1.1  jruoho         return (ACPI_BTYPE_EVENT);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_FLD:        /* "FieldUnitObj" */
1.1  jruoho         return (ACPI_BTYPE_FIELD_UNIT);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_INT:        /* "IntObj" */
1.1  jruoho         return (ACPI_BTYPE_INTEGER);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_MTH:        /* "MethodObj" */
1.1  jruoho         return (ACPI_BTYPE_METHOD);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_MTX:        /* "MutexObj" */
1.1  jruoho         return (ACPI_BTYPE_MUTEX);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_OPR:        /* "OpRegionObj" */
1.1  jruoho         return (ACPI_BTYPE_REGION);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_PKG:        /* "PkgObj" */
1.1  jruoho         return (ACPI_BTYPE_PACKAGE);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_POW:        /* "PowerResObj" */
1.1  jruoho         return (ACPI_BTYPE_POWER);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_STR:        /* "StrObj" */
1.1  jruoho         return (ACPI_BTYPE_STRING);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_THZ:        /* "ThermalZoneObj" */
1.1  jruoho         return (ACPI_BTYPE_THERMAL);
1.1  jruoho
1.1  jruoho     case PARSEOP_OBJECTTYPE_UNK:        /* "UnknownObj" */
1.1  jruoho         return (ACPI_BTYPE_OBJECTS_AND_REFS);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         return (0);
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMethodAnalysisWalkBegin
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Descending callback for the analysis walk. Check methods for:
1.1  jruoho  *              1) Initialized local variables
1.1  jruoho  *              2) Valid arguments
1.1  jruoho  *              3) Return types
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnMethodAnalysisWalkBegin (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho     ASL_ANALYSIS_WALK_INFO  *WalkInfo = (ASL_ANALYSIS_WALK_INFO *) Context;
1.1  jruoho     ASL_METHOD_INFO         *MethodInfo = WalkInfo->MethodStack;
1.1  jruoho     ACPI_PARSE_OBJECT       *Next;
1.1  jruoho     UINT32                  RegisterNumber;
1.1  jruoho     UINT32                  i;
1.1  jruoho     char                    LocalName[] = "Local0";
1.1  jruoho     char                    ArgName[] = "Arg0";
1.1  jruoho     ACPI_PARSE_OBJECT       *ArgNode;
1.1  jruoho     ACPI_PARSE_OBJECT       *NextType;
1.1  jruoho     ACPI_PARSE_OBJECT       *NextParamType;
1.1  jruoho     UINT8                   ActualArgs = 0;
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_METHOD:
1.1  jruoho
1.1  jruoho         TotalMethods++;
1.1  jruoho
1.1  jruoho         /* Create and init method info */
1.1  jruoho
1.1  jruoho         MethodInfo       = UtLocalCalloc (sizeof (ASL_METHOD_INFO));
1.1  jruoho         MethodInfo->Next = WalkInfo->MethodStack;
1.1  jruoho         MethodInfo->Op = Op;
1.1  jruoho
1.1  jruoho         WalkInfo->MethodStack = MethodInfo;
1.1  jruoho
1.1  jruoho         /* Get the name node, ignored here */
1.1  jruoho
1.1  jruoho         Next = Op->Asl.Child;
1.1  jruoho
1.1  jruoho         /* Get the NumArguments node */
1.1  jruoho
1.1  jruoho         Next = Next->Asl.Next;
1.1  jruoho         MethodInfo->NumArguments = (UINT8)
1.1  jruoho             (((UINT8) Next->Asl.Value.Integer) & 0x07);
1.1  jruoho
1.1  jruoho         /* Get the SerializeRule and SyncLevel nodes, ignored here */
1.1  jruoho
1.1  jruoho         Next = Next->Asl.Next;
1.1  jruoho         Next = Next->Asl.Next;
1.1  jruoho         ArgNode = Next;
1.1  jruoho
1.1  jruoho         /* Get the ReturnType node */
1.1  jruoho
1.1  jruoho         Next = Next->Asl.Next;
1.1  jruoho
1.1  jruoho         NextType = Next->Asl.Child;
1.1  jruoho         while (NextType)
1.1  jruoho         {
1.1  jruoho             /* Get and map each of the ReturnTypes */
1.1  jruoho
1.1  jruoho             MethodInfo->ValidReturnTypes |= AnMapObjTypeToBtype (NextType);
1.1  jruoho             NextType->Asl.ParseOpcode = PARSEOP_DEFAULT_ARG;
1.1  jruoho             NextType = NextType->Asl.Next;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Get the ParameterType node */
1.1  jruoho
1.1  jruoho         Next = Next->Asl.Next;
1.1  jruoho
1.1  jruoho         NextType = Next->Asl.Child;
1.1  jruoho         while (NextType)
1.1  jruoho         {
1.1  jruoho             if (NextType->Asl.ParseOpcode == PARSEOP_DEFAULT_ARG)
1.1  jruoho             {
1.1  jruoho                 NextParamType = NextType->Asl.Child;
1.1  jruoho                 while (NextParamType)
1.1  jruoho                 {
1.1  jruoho                     MethodInfo->ValidArgTypes[ActualArgs] |= AnMapObjTypeToBtype (NextParamType);
1.1  jruoho                     NextParamType->Asl.ParseOpcode = PARSEOP_DEFAULT_ARG;
1.1  jruoho                     NextParamType = NextParamType->Asl.Next;
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho             else
1.1  jruoho             {
1.1  jruoho                 MethodInfo->ValidArgTypes[ActualArgs] =
1.1  jruoho                     AnMapObjTypeToBtype (NextType);
1.1  jruoho                 NextType->Asl.ParseOpcode = PARSEOP_DEFAULT_ARG;
1.1  jruoho                 ActualArgs++;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             NextType = NextType->Asl.Next;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         if ((MethodInfo->NumArguments) &&
1.1  jruoho             (MethodInfo->NumArguments != ActualArgs))
1.1  jruoho         {
1.1  jruoho             /* error: Param list did not match number of args */
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Allow numarguments == 0 for Function() */
1.1  jruoho
1.1  jruoho         if ((!MethodInfo->NumArguments) && (ActualArgs))
1.1  jruoho         {
1.1  jruoho             MethodInfo->NumArguments = ActualArgs;
1.1  jruoho             ArgNode->Asl.Value.Integer |= ActualArgs;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Actual arguments are initialized at method entry.
1.1  jruoho          * All other ArgX "registers" can be used as locals, so we
1.1  jruoho          * track their initialization.
1.1  jruoho          */
1.1  jruoho         for (i = 0; i < MethodInfo->NumArguments; i++)
1.1  jruoho         {
1.1  jruoho             MethodInfo->ArgInitialized[i] = TRUE;
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_METHODCALL:
1.1  jruoho
1.1  jruoho         if (MethodInfo &&
1.1  jruoho            (Op->Asl.Node == MethodInfo->Op->Asl.Node))
1.1  jruoho         {
1.1  jruoho             AslError (ASL_REMARK, ASL_MSG_RECURSION, Op, Op->Asl.ExternalName);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_LOCAL0:
1.1  jruoho     case PARSEOP_LOCAL1:
1.1  jruoho     case PARSEOP_LOCAL2:
1.1  jruoho     case PARSEOP_LOCAL3:
1.1  jruoho     case PARSEOP_LOCAL4:
1.1  jruoho     case PARSEOP_LOCAL5:
1.1  jruoho     case PARSEOP_LOCAL6:
1.1  jruoho     case PARSEOP_LOCAL7:
1.1  jruoho
1.1  jruoho         if (!MethodInfo)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Local was used outside a control method, or there was an error
1.1  jruoho              * in the method declaration.
1.1  jruoho              */
1.1  jruoho             AslError (ASL_REMARK, ASL_MSG_LOCAL_OUTSIDE_METHOD, Op, Op->Asl.ExternalName);
1.1  jruoho             return (AE_ERROR);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         RegisterNumber = (Op->Asl.AmlOpcode & 0x000F);
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * If the local is being used as a target, mark the local
1.1  jruoho          * initialized
1.1  jruoho          */
1.1  jruoho         if (Op->Asl.CompileFlags & NODE_IS_TARGET)
1.1  jruoho         {
1.1  jruoho             MethodInfo->LocalInitialized[RegisterNumber] = TRUE;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Otherwise, this is a reference, check if the local
1.1  jruoho          * has been previously initialized.
1.1  jruoho          *
1.1  jruoho          * The only operator that accepts an uninitialized value is ObjectType()
1.1  jruoho          */
1.1  jruoho         else if ((!MethodInfo->LocalInitialized[RegisterNumber]) &&
1.1  jruoho                  (Op->Asl.Parent->Asl.ParseOpcode != PARSEOP_OBJECTTYPE))
1.1  jruoho         {
1.1  jruoho             LocalName[strlen (LocalName) -1] = (char) (RegisterNumber + 0x30);
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_LOCAL_INIT, Op, LocalName);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_ARG0:
1.1  jruoho     case PARSEOP_ARG1:
1.1  jruoho     case PARSEOP_ARG2:
1.1  jruoho     case PARSEOP_ARG3:
1.1  jruoho     case PARSEOP_ARG4:
1.1  jruoho     case PARSEOP_ARG5:
1.1  jruoho     case PARSEOP_ARG6:
1.1  jruoho
1.1  jruoho         if (!MethodInfo)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Arg was used outside a control method, or there was an error
1.1  jruoho              * in the method declaration.
1.1  jruoho              */
1.1  jruoho             AslError (ASL_REMARK, ASL_MSG_LOCAL_OUTSIDE_METHOD, Op, Op->Asl.ExternalName);
1.1  jruoho             return (AE_ERROR);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         RegisterNumber = (Op->Asl.AmlOpcode & 0x000F) - 8;
1.1  jruoho         ArgName[strlen (ArgName) -1] = (char) (RegisterNumber + 0x30);
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * If the Arg is being used as a target, mark the local
1.1  jruoho          * initialized
1.1  jruoho          */
1.1  jruoho         if (Op->Asl.CompileFlags & NODE_IS_TARGET)
1.1  jruoho         {
1.1  jruoho             MethodInfo->ArgInitialized[RegisterNumber] = TRUE;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Otherwise, this is a reference, check if the Arg
1.1  jruoho          * has been previously initialized.
1.1  jruoho          *
1.1  jruoho          * The only operator that accepts an uninitialized value is ObjectType()
1.1  jruoho          */
1.1  jruoho         else if ((!MethodInfo->ArgInitialized[RegisterNumber]) &&
1.1  jruoho                  (Op->Asl.Parent->Asl.ParseOpcode != PARSEOP_OBJECTTYPE))
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_ARG_INIT, Op, ArgName);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Flag this arg if it is not a "real" argument to the method */
1.1  jruoho
1.1  jruoho         if (RegisterNumber >= MethodInfo->NumArguments)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_REMARK, ASL_MSG_NOT_PARAMETER, Op, ArgName);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_RETURN:
1.1  jruoho
1.1  jruoho         if (!MethodInfo)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Probably was an error in the method declaration,
1.1  jruoho              * no additional error here
1.1  jruoho              */
1.1  jruoho             ACPI_WARNING ((AE_INFO, "%p, No parent method", Op));
1.1  jruoho             return (AE_ERROR);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Child indicates a return value */
1.1  jruoho
1.1  jruoho         if ((Op->Asl.Child) &&
1.1  jruoho             (Op->Asl.Child->Asl.ParseOpcode != PARSEOP_DEFAULT_ARG))
1.1  jruoho         {
1.1  jruoho             MethodInfo->NumReturnWithValue++;
1.1  jruoho         }
1.1  jruoho         else
1.1  jruoho         {
1.1  jruoho             MethodInfo->NumReturnNoValue++;
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_BREAK:
1.1  jruoho     case PARSEOP_CONTINUE:
1.1  jruoho
1.1  jruoho         Next = Op->Asl.Parent;
1.1  jruoho         while (Next)
1.1  jruoho         {
1.1  jruoho             if (Next->Asl.ParseOpcode == PARSEOP_WHILE)
1.1  jruoho             {
1.1  jruoho                 break;
1.1  jruoho             }
1.1  jruoho             Next = Next->Asl.Parent;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         if (!Next)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_NO_WHILE, Op, NULL);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_STALL:
1.1  jruoho
1.1  jruoho         /* We can range check if the argument is an integer */
1.1  jruoho
1.1  jruoho         if ((Op->Asl.Child->Asl.ParseOpcode == PARSEOP_INTEGER) &&
1.1  jruoho             (Op->Asl.Child->Asl.Value.Integer > ACPI_UINT8_MAX))
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_INVALID_TIME, Op, NULL);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_DEVICE:
1.1  jruoho     case PARSEOP_EVENT:
1.1  jruoho     case PARSEOP_MUTEX:
1.1  jruoho     case PARSEOP_OPERATIONREGION:
1.1  jruoho     case PARSEOP_POWERRESOURCE:
1.1  jruoho     case PARSEOP_PROCESSOR:
1.1  jruoho     case PARSEOP_THERMALZONE:
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * The first operand is a name to be created in the namespace.
1.1  jruoho          * Check against the reserved list.
1.1  jruoho          */
1.1  jruoho         i = ApCheckForPredefinedName (Op, Op->Asl.NameSeg);
1.1  jruoho         if (i < ACPI_VALID_RESERVED_NAME_MAX)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_RESERVED_USE, Op, Op->Asl.ExternalName);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_NAME:
1.1  jruoho
1.1  jruoho         /* Typecheck any predefined names statically defined with Name() */
1.1  jruoho
1.1  jruoho         ApCheckForPredefinedObject (Op, Op->Asl.NameSeg);
1.1  jruoho
1.1  jruoho         /* Special typechecking for _HID */
1.1  jruoho
1.1  jruoho         if (!ACPI_STRCMP (METHOD_NAME__HID, Op->Asl.NameSeg))
1.1  jruoho         {
1.1  jruoho             Next = Op->Asl.Child->Asl.Next;
1.1  jruoho             if (Next->Asl.ParseOpcode == PARSEOP_STRING_LITERAL)
1.1  jruoho             {
1.1  jruoho                 /*
1.1  jruoho                  * _HID is a string, all characters must be alphanumeric.
1.1  jruoho                  * One of the things we want to catch here is the use of
1.1  jruoho                  * a leading asterisk in the string.
1.1  jruoho                  */
1.1  jruoho                 for (i = 0; Next->Asl.Value.String[i]; i++)
1.1  jruoho                 {
1.1  jruoho                     if (!isalnum ((int) Next->Asl.Value.String[i]))
1.1  jruoho                     {
1.1  jruoho                         AslError (ASL_ERROR, ASL_MSG_ALPHANUMERIC_STRING,
1.1  jruoho                             Next, Next->Asl.Value.String);
1.1  jruoho                         break;
1.1  jruoho                     }
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnLastStatementIsReturn
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op            - A method parse node
1.1  jruoho  *
1.1  jruoho  * RETURN:      TRUE if last statement is an ASL RETURN. False otherwise
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Walk down the list of top level statements within a method
1.1  jruoho  *              to find the last one. Check if that last statement is in
1.1  jruoho  *              fact a RETURN statement.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static BOOLEAN
1.1  jruoho AnLastStatementIsReturn (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho     ACPI_PARSE_OBJECT       *Next;
1.1  jruoho
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Check if last statement is a return
1.1  jruoho      */
1.1  jruoho     Next = ASL_GET_CHILD_NODE (Op);
1.1  jruoho     while (Next)
1.1  jruoho     {
1.1  jruoho         if ((!Next->Asl.Next) &&
1.1  jruoho             (Next->Asl.ParseOpcode == PARSEOP_RETURN))
1.1  jruoho         {
1.1  jruoho             return TRUE;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         Next = ASL_GET_PEER_NODE (Next);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return FALSE;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMethodAnalysisWalkEnd
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Ascending callback for analysis walk. Complete method
1.1  jruoho  *              return analysis.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnMethodAnalysisWalkEnd (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho     ASL_ANALYSIS_WALK_INFO  *WalkInfo = (ASL_ANALYSIS_WALK_INFO *) Context;
1.1  jruoho     ASL_METHOD_INFO         *MethodInfo = WalkInfo->MethodStack;
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_METHOD:
1.1  jruoho     case PARSEOP_RETURN:
1.1  jruoho         if (!MethodInfo)
1.1  jruoho         {
1.1  jruoho             printf ("No method info for method! [%s]\n", Op->Asl.Namepath);
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_COMPILER_INTERNAL, Op,
1.1  jruoho                 "No method info for this method");
1.1  jruoho             CmCleanupAndExit ();
1.1  jruoho             return (AE_AML_INTERNAL);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_METHOD:
1.1  jruoho
1.1  jruoho         WalkInfo->MethodStack = MethodInfo->Next;
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Check if there is no return statement at the end of the
1.1  jruoho          * method AND we can actually get there -- i.e., the execution
1.1  jruoho          * of the method can possibly terminate without a return statement.
1.1  jruoho          */
1.1  jruoho         if ((!AnLastStatementIsReturn (Op)) &&
1.1  jruoho             (!(Op->Asl.CompileFlags & NODE_HAS_NO_EXIT)))
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * No return statement, and execution can possibly exit
1.1  jruoho              * via this path. This is equivalent to Return ()
1.1  jruoho              */
1.1  jruoho             MethodInfo->NumReturnNoValue++;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Check for case where some return statements have a return value
1.1  jruoho          * and some do not. Exit without a return statement is a return with
1.1  jruoho          * no value
1.1  jruoho          */
1.1  jruoho         if (MethodInfo->NumReturnNoValue &&
1.1  jruoho             MethodInfo->NumReturnWithValue)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_WARNING, ASL_MSG_RETURN_TYPES, Op,
1.1  jruoho                 Op->Asl.ExternalName);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * If there are any RETURN() statements with no value, or there is a
1.1  jruoho          * control path that allows the method to exit without a return value,
1.1  jruoho          * we mark the method as a method that does not return a value. This
1.1  jruoho          * knowledge can be used to check method invocations that expect a
1.1  jruoho          * returned value.
1.1  jruoho          */
1.1  jruoho         if (MethodInfo->NumReturnNoValue)
1.1  jruoho         {
1.1  jruoho             if (MethodInfo->NumReturnWithValue)
1.1  jruoho             {
1.1  jruoho                 Op->Asl.CompileFlags |= NODE_METHOD_SOME_NO_RETVAL;
1.1  jruoho             }
1.1  jruoho             else
1.1  jruoho             {
1.1  jruoho                 Op->Asl.CompileFlags |= NODE_METHOD_NO_RETVAL;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Check predefined method names for correct return behavior
1.1  jruoho          * and correct number of arguments
1.1  jruoho          */
1.1  jruoho         ApCheckForPredefinedMethod (Op, MethodInfo);
1.1  jruoho         ACPI_FREE (MethodInfo);
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_RETURN:
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * If the parent is a predefined method name, attempt to typecheck
1.1  jruoho          * the return value. Only static types can be validated.
1.1  jruoho          */
1.1  jruoho         ApCheckPredefinedReturnValue (Op, MethodInfo);
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * The parent block does not "exit" and continue execution -- the
1.1  jruoho          * method is terminated here with the Return() statement.
1.1  jruoho          */
1.1  jruoho         Op->Asl.Parent->Asl.CompileFlags |= NODE_HAS_NO_EXIT;
1.1  jruoho
1.1  jruoho         /* Used in the "typing" pass later */
1.1  jruoho
1.1  jruoho         Op->Asl.ParentMethod = MethodInfo->Op;
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * If there is a peer node after the return statement, then this
1.1  jruoho          * node is unreachable code -- i.e., it won't be executed because of
1.1  jruoho          * the preceeding Return() statement.
1.1  jruoho          */
1.1  jruoho         if (Op->Asl.Next)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_WARNING, ASL_MSG_UNREACHABLE_CODE, Op->Asl.Next, NULL);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_IF:
1.1  jruoho
1.1  jruoho         if ((Op->Asl.CompileFlags & NODE_HAS_NO_EXIT) &&
1.1  jruoho             (Op->Asl.Next) &&
1.1  jruoho             (Op->Asl.Next->Asl.ParseOpcode == PARSEOP_ELSE))
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * This IF has a corresponding ELSE. The IF block has no exit,
1.1  jruoho              * (it contains an unconditional Return)
1.1  jruoho              * mark the ELSE block to remember this fact.
1.1  jruoho              */
1.1  jruoho             Op->Asl.Next->Asl.CompileFlags |= NODE_IF_HAS_NO_EXIT;
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case PARSEOP_ELSE:
1.1  jruoho
1.1  jruoho         if ((Op->Asl.CompileFlags & NODE_HAS_NO_EXIT) &&
1.1  jruoho             (Op->Asl.CompileFlags & NODE_IF_HAS_NO_EXIT))
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * This ELSE block has no exit and the corresponding IF block
1.1  jruoho              * has no exit either. Therefore, the parent node has no exit.
1.1  jruoho              */
1.1  jruoho             Op->Asl.Parent->Asl.CompileFlags |= NODE_HAS_NO_EXIT;
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho
1.1  jruoho         if ((Op->Asl.CompileFlags & NODE_HAS_NO_EXIT) &&
1.1  jruoho             (Op->Asl.Parent))
1.1  jruoho         {
1.1  jruoho             /* If this node has no exit, then the parent has no exit either */
1.1  jruoho
1.1  jruoho             Op->Asl.Parent->Asl.CompileFlags |= NODE_HAS_NO_EXIT;
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMethodTypingWalkBegin
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Descending callback for the typing walk.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnMethodTypingWalkBegin (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMethodTypingWalkEnd
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Ascending callback for typing walk. Complete the method
1.1  jruoho  *              return analysis. Check methods for:
1.1  jruoho  *              1) Initialized local variables
1.1  jruoho  *              2) Valid arguments
1.1  jruoho  *              3) Return types
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnMethodTypingWalkEnd (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho     UINT32                  ThisNodeBtype;
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_METHOD:
1.1  jruoho
1.1  jruoho         Op->Asl.CompileFlags |= NODE_METHOD_TYPED;
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     case PARSEOP_RETURN:
1.1  jruoho
1.1  jruoho         if ((Op->Asl.Child) &&
1.1  jruoho             (Op->Asl.Child->Asl.ParseOpcode != PARSEOP_DEFAULT_ARG))
1.1  jruoho         {
1.1  jruoho             ThisNodeBtype = AnGetBtype (Op->Asl.Child);
1.1  jruoho
1.1  jruoho             if ((Op->Asl.Child->Asl.ParseOpcode == PARSEOP_METHODCALL) &&
1.1  jruoho                 (ThisNodeBtype == (ACPI_UINT32_MAX -1)))
1.1  jruoho             {
1.1  jruoho                 /*
1.1  jruoho                  * The called method is untyped at this time (typically a
1.1  jruoho                  * forward reference).
1.1  jruoho                  *
1.1  jruoho                  * Check for a recursive method call first.
1.1  jruoho                  */
1.1  jruoho                 if (Op->Asl.ParentMethod != Op->Asl.Child->Asl.Node->Op)
1.1  jruoho                 {
1.1  jruoho                     /* We must type the method here */
1.1  jruoho
1.1  jruoho                     TrWalkParseTree (Op->Asl.Child->Asl.Node->Op,
1.1  jruoho                         ASL_WALK_VISIT_TWICE, AnMethodTypingWalkBegin,
1.1  jruoho                         AnMethodTypingWalkEnd, NULL);
1.1  jruoho
1.1  jruoho                     ThisNodeBtype = AnGetBtype (Op->Asl.Child);
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             /* Returns a value, save the value type */
1.1  jruoho
1.1  jruoho             if (Op->Asl.ParentMethod)
1.1  jruoho             {
1.1  jruoho                 Op->Asl.ParentMethod->Asl.AcpiBtype |= ThisNodeBtype;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnCheckMethodReturnValue
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op                  - Parent
1.1  jruoho  *              OpInfo              - Parent info
1.1  jruoho  *              ArgOp               - Method invocation op
1.1  jruoho  *              RequiredBtypes      - What caller requires
1.1  jruoho  *              ThisNodeBtype       - What this node returns (if anything)
1.1  jruoho  *
1.1  jruoho  * RETURN:      None
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Check a method invocation for 1) A return value and if it does
1.1  jruoho  *              in fact return a value, 2) check the type of the return value.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AnCheckMethodReturnValue (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo,
1.1  jruoho     ACPI_PARSE_OBJECT       *ArgOp,
1.1  jruoho     UINT32                  RequiredBtypes,
1.1  jruoho     UINT32                  ThisNodeBtype)
1.1  jruoho {
1.1  jruoho     ACPI_PARSE_OBJECT       *OwningOp;
1.1  jruoho     ACPI_NAMESPACE_NODE     *Node;
1.1  jruoho
1.1  jruoho
1.1  jruoho     Node = ArgOp->Asl.Node;
1.1  jruoho
1.1  jruoho
1.1  jruoho     /* Examine the parent op of this method */
1.1  jruoho
1.1  jruoho     OwningOp = Node->Op;
1.1  jruoho     if (OwningOp->Asl.CompileFlags & NODE_METHOD_NO_RETVAL)
1.1  jruoho     {
1.1  jruoho         /* Method NEVER returns a value */
1.1  jruoho
1.1  jruoho         AslError (ASL_ERROR, ASL_MSG_NO_RETVAL, Op, Op->Asl.ExternalName);
1.1  jruoho     }
1.1  jruoho     else if (OwningOp->Asl.CompileFlags & NODE_METHOD_SOME_NO_RETVAL)
1.1  jruoho     {
1.1  jruoho         /* Method SOMETIMES returns a value, SOMETIMES not */
1.1  jruoho
1.1  jruoho         AslError (ASL_WARNING, ASL_MSG_SOME_NO_RETVAL, Op, Op->Asl.ExternalName);
1.1  jruoho     }
1.1  jruoho     else if (!(ThisNodeBtype & RequiredBtypes))
1.1  jruoho     {
1.1  jruoho         /* Method returns a value, but the type is wrong */
1.1  jruoho
1.1  jruoho         AnFormatBtype (StringBuffer, ThisNodeBtype);
1.1  jruoho         AnFormatBtype (StringBuffer2, RequiredBtypes);
1.1  jruoho
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * The case where the method does not return any value at all
1.1  jruoho          * was already handled in the namespace cross reference
1.1  jruoho          * -- Only issue an error if the method in fact returns a value,
1.1  jruoho          * but it is of the wrong type
1.1  jruoho          */
1.1  jruoho         if (ThisNodeBtype != 0)
1.1  jruoho         {
1.1  jruoho             sprintf (MsgBuffer,
1.1  jruoho                 "Method returns [%s], %s operator requires [%s]",
1.1  jruoho                 StringBuffer, OpInfo->Name, StringBuffer2);
1.1  jruoho
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_INVALID_TYPE, ArgOp, MsgBuffer);
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnOperandTypecheckWalkBegin
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Descending callback for the analysis walk. Check methods for:
1.1  jruoho  *              1) Initialized local variables
1.1  jruoho  *              2) Valid arguments
1.1  jruoho  *              3) Return types
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnOperandTypecheckWalkBegin (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnOperandTypecheckWalkEnd
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Ascending callback for analysis walk. Complete method
1.1  jruoho  *              return analysis.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnOperandTypecheckWalkEnd (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo;
1.1  jruoho     UINT32                  RuntimeArgTypes;
1.1  jruoho     UINT32                  RuntimeArgTypes2;
1.1  jruoho     UINT32                  RequiredBtypes;
1.1  jruoho     UINT32                  ThisNodeBtype;
1.1  jruoho     UINT32                  CommonBtypes;
1.1  jruoho     UINT32                  OpcodeClass;
1.1  jruoho     ACPI_PARSE_OBJECT       *ArgOp;
1.1  jruoho     UINT32                  ArgType;
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Asl.AmlOpcode)
1.1  jruoho     {
1.1  jruoho     case AML_RAW_DATA_BYTE:
1.1  jruoho     case AML_RAW_DATA_WORD:
1.1  jruoho     case AML_RAW_DATA_DWORD:
1.1  jruoho     case AML_RAW_DATA_QWORD:
1.1  jruoho     case AML_RAW_DATA_BUFFER:
1.1  jruoho     case AML_RAW_DATA_CHAIN:
1.1  jruoho     case AML_PACKAGE_LENGTH:
1.1  jruoho     case AML_UNASSIGNED_OPCODE:
1.1  jruoho     case AML_DEFAULT_ARG_OP:
1.1  jruoho
1.1  jruoho         /* Ignore the internal (compiler-only) AML opcodes */
1.1  jruoho
1.1  jruoho         return (AE_OK);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     OpInfo = AcpiPsGetOpcodeInfo (Op->Asl.AmlOpcode);
1.1  jruoho     if (!OpInfo)
1.1  jruoho     {
1.1  jruoho         return (AE_OK);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     ArgOp           = Op->Asl.Child;
1.1  jruoho     RuntimeArgTypes = OpInfo->RuntimeArgs;
1.1  jruoho     OpcodeClass     = OpInfo->Class;
1.1  jruoho
1.1  jruoho #ifdef ASL_ERROR_NAMED_OBJECT_IN_WHILE
1.1  jruoho     /*
1.1  jruoho      * Update 11/2008: In practice, we can't perform this check. A simple
1.1  jruoho      * analysis is not sufficient. Also, it can cause errors when compiling
1.1  jruoho      * disassembled code because of the way Switch operators are implemented
1.1  jruoho      * (a While(One) loop with a named temp variable created within.)
1.1  jruoho      */
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * If we are creating a named object, check if we are within a while loop
1.1  jruoho      * by checking if the parent is a WHILE op. This is a simple analysis, but
1.1  jruoho      * probably sufficient for many cases.
1.1  jruoho      *
1.1  jruoho      * Allow Scope(), Buffer(), and Package().
1.1  jruoho      */
1.1  jruoho     if (((OpcodeClass == AML_CLASS_NAMED_OBJECT) && (Op->Asl.AmlOpcode != AML_SCOPE_OP)) ||
1.1  jruoho         ((OpcodeClass == AML_CLASS_CREATE) && (OpInfo->Flags & AML_NSNODE)))
1.1  jruoho     {
1.1  jruoho         if (Op->Asl.Parent->Asl.AmlOpcode == AML_WHILE_OP)
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_NAMED_OBJECT_IN_WHILE, Op, NULL);
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho #endif
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Special case for control opcodes IF/RETURN/WHILE since they
1.1  jruoho      * have no runtime arg list (at this time)
1.1  jruoho      */
1.1  jruoho     switch (Op->Asl.AmlOpcode)
1.1  jruoho     {
1.1  jruoho     case AML_IF_OP:
1.1  jruoho     case AML_WHILE_OP:
1.1  jruoho     case AML_RETURN_OP:
1.1  jruoho
1.1  jruoho         if (ArgOp->Asl.ParseOpcode == PARSEOP_METHODCALL)
1.1  jruoho         {
1.1  jruoho             /* Check for an internal method */
1.1  jruoho
1.1  jruoho             if (AnIsInternalMethod (ArgOp))
1.1  jruoho             {
1.1  jruoho                 return (AE_OK);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             /* The lone arg is a method call, check it */
1.1  jruoho
1.1  jruoho             RequiredBtypes = AnMapArgTypeToBtype (ARGI_INTEGER);
1.1  jruoho             if (Op->Asl.AmlOpcode == AML_RETURN_OP)
1.1  jruoho             {
1.1  jruoho                 RequiredBtypes = 0xFFFFFFFF;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             ThisNodeBtype = AnGetBtype (ArgOp);
1.1  jruoho             if (ThisNodeBtype == ACPI_UINT32_MAX)
1.1  jruoho             {
1.1  jruoho                 return (AE_OK);
1.1  jruoho             }
1.1  jruoho             AnCheckMethodReturnValue (Op, OpInfo, ArgOp,
1.1  jruoho                 RequiredBtypes, ThisNodeBtype);
1.1  jruoho         }
1.1  jruoho         return (AE_OK);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Ignore the non-executable opcodes */
1.1  jruoho
1.1  jruoho     if (RuntimeArgTypes == ARGI_INVALID_OPCODE)
1.1  jruoho     {
1.1  jruoho         return (AE_OK);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     switch (OpcodeClass)
1.1  jruoho     {
1.1  jruoho     case AML_CLASS_EXECUTE:
1.1  jruoho     case AML_CLASS_CREATE:
1.1  jruoho     case AML_CLASS_CONTROL:
1.1  jruoho     case AML_CLASS_RETURN_VALUE:
1.1  jruoho
1.1  jruoho         /* TBD: Change class or fix typechecking for these */
1.1  jruoho
1.1  jruoho         if ((Op->Asl.AmlOpcode == AML_BUFFER_OP)        ||
1.1  jruoho             (Op->Asl.AmlOpcode == AML_PACKAGE_OP)       ||
1.1  jruoho             (Op->Asl.AmlOpcode == AML_VAR_PACKAGE_OP))
1.1  jruoho         {
1.1  jruoho             break;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Reverse the runtime argument list */
1.1  jruoho
1.1  jruoho         RuntimeArgTypes2 = 0;
1.1  jruoho         while ((ArgType = GET_CURRENT_ARG_TYPE (RuntimeArgTypes)))
1.1  jruoho         {
1.1  jruoho             RuntimeArgTypes2 <<= ARG_TYPE_WIDTH;
1.1  jruoho             RuntimeArgTypes2 |= ArgType;
1.1  jruoho             INCREMENT_ARG_LIST (RuntimeArgTypes);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         while ((ArgType = GET_CURRENT_ARG_TYPE (RuntimeArgTypes2)))
1.1  jruoho         {
1.1  jruoho             RequiredBtypes = AnMapArgTypeToBtype (ArgType);
1.1  jruoho
1.1  jruoho             ThisNodeBtype = AnGetBtype (ArgOp);
1.1  jruoho             if (ThisNodeBtype == ACPI_UINT32_MAX)
1.1  jruoho             {
1.1  jruoho                 goto NextArgument;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             /* Examine the arg based on the required type of the arg */
1.1  jruoho
1.1  jruoho             switch (ArgType)
1.1  jruoho             {
1.1  jruoho             case ARGI_TARGETREF:
1.1  jruoho
1.1  jruoho                 if (ArgOp->Asl.ParseOpcode == PARSEOP_ZERO)
1.1  jruoho                 {
1.1  jruoho                     /* ZERO is the placeholder for "don't store result" */
1.1  jruoho
1.1  jruoho                     ThisNodeBtype = RequiredBtypes;
1.1  jruoho                     break;
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 if (ArgOp->Asl.ParseOpcode == PARSEOP_INTEGER)
1.1  jruoho                 {
1.1  jruoho                     /*
1.1  jruoho                      * This is the case where an original reference to a resource
1.1  jruoho                      * descriptor field has been replaced by an (Integer) offset.
1.1  jruoho                      * These named fields are supported at compile-time only;
1.1  jruoho                      * the names are not passed to the interpreter (via the AML).
1.1  jruoho                      */
1.1  jruoho                     if ((ArgOp->Asl.Node->Type == ACPI_TYPE_LOCAL_RESOURCE_FIELD) ||
1.1  jruoho                         (ArgOp->Asl.Node->Type == ACPI_TYPE_LOCAL_RESOURCE))
1.1  jruoho                     {
1.1  jruoho                         AslError (ASL_ERROR, ASL_MSG_RESOURCE_FIELD, ArgOp, NULL);
1.1  jruoho                     }
1.1  jruoho                     else
1.1  jruoho                     {
1.1  jruoho                         AslError (ASL_ERROR, ASL_MSG_INVALID_TYPE, ArgOp, NULL);
1.1  jruoho                     }
1.1  jruoho                     break;
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 if ((ArgOp->Asl.ParseOpcode == PARSEOP_METHODCALL) ||
1.1  jruoho                     (ArgOp->Asl.ParseOpcode == PARSEOP_DEREFOF))
1.1  jruoho                 {
1.1  jruoho                     break;
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 ThisNodeBtype = RequiredBtypes;
1.1  jruoho                 break;
1.1  jruoho
1.1  jruoho
1.1  jruoho             case ARGI_REFERENCE:            /* References */
1.1  jruoho             case ARGI_INTEGER_REF:
1.1  jruoho             case ARGI_OBJECT_REF:
1.1  jruoho             case ARGI_DEVICE_REF:
1.1  jruoho
1.1  jruoho                 switch (ArgOp->Asl.ParseOpcode)
1.1  jruoho                 {
1.1  jruoho                 case PARSEOP_LOCAL0:
1.1  jruoho                 case PARSEOP_LOCAL1:
1.1  jruoho                 case PARSEOP_LOCAL2:
1.1  jruoho                 case PARSEOP_LOCAL3:
1.1  jruoho                 case PARSEOP_LOCAL4:
1.1  jruoho                 case PARSEOP_LOCAL5:
1.1  jruoho                 case PARSEOP_LOCAL6:
1.1  jruoho                 case PARSEOP_LOCAL7:
1.1  jruoho
1.1  jruoho                     /* TBD: implement analysis of current value (type) of the local */
1.1  jruoho                     /* For now, just treat any local as a typematch */
1.1  jruoho
1.1  jruoho                     /*ThisNodeBtype = RequiredBtypes;*/
1.1  jruoho                     break;
1.1  jruoho
1.1  jruoho                 case PARSEOP_ARG0:
1.1  jruoho                 case PARSEOP_ARG1:
1.1  jruoho                 case PARSEOP_ARG2:
1.1  jruoho                 case PARSEOP_ARG3:
1.1  jruoho                 case PARSEOP_ARG4:
1.1  jruoho                 case PARSEOP_ARG5:
1.1  jruoho                 case PARSEOP_ARG6:
1.1  jruoho
1.1  jruoho                     /* Hard to analyze argument types, sow we won't */
1.1  jruoho                     /* For now, just treat any arg as a typematch */
1.1  jruoho
1.1  jruoho                     /* ThisNodeBtype = RequiredBtypes; */
1.1  jruoho                     break;
1.1  jruoho
1.1  jruoho                 case PARSEOP_DEBUG:
1.1  jruoho                     break;
1.1  jruoho
1.1  jruoho                 case PARSEOP_REFOF:
1.1  jruoho                 case PARSEOP_INDEX:
1.1  jruoho                 default:
1.1  jruoho                     break;
1.1  jruoho
1.1  jruoho                 }
1.1  jruoho                 break;
1.1  jruoho
1.1  jruoho             case ARGI_INTEGER:
1.1  jruoho             default:
1.1  jruoho                 break;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho
1.1  jruoho             CommonBtypes = ThisNodeBtype & RequiredBtypes;
1.1  jruoho
1.1  jruoho             if (ArgOp->Asl.ParseOpcode == PARSEOP_METHODCALL)
1.1  jruoho             {
1.1  jruoho                 if (AnIsInternalMethod (ArgOp))
1.1  jruoho                 {
1.1  jruoho                     return (AE_OK);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 /* Check a method call for a valid return value */
1.1  jruoho
1.1  jruoho                 AnCheckMethodReturnValue (Op, OpInfo, ArgOp,
1.1  jruoho                     RequiredBtypes, ThisNodeBtype);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             /*
1.1  jruoho              * Now check if the actual type(s) match at least one
1.1  jruoho              * bit to the required type
1.1  jruoho              */
1.1  jruoho             else if (!CommonBtypes)
1.1  jruoho             {
1.1  jruoho                 /* No match -- this is a type mismatch error */
1.1  jruoho
1.1  jruoho                 AnFormatBtype (StringBuffer, ThisNodeBtype);
1.1  jruoho                 AnFormatBtype (StringBuffer2, RequiredBtypes);
1.1  jruoho
1.1  jruoho                 sprintf (MsgBuffer, "[%s] found, %s operator requires [%s]",
1.1  jruoho                             StringBuffer, OpInfo->Name, StringBuffer2);
1.1  jruoho
1.1  jruoho                 AslError (ASL_ERROR, ASL_MSG_INVALID_TYPE, ArgOp, MsgBuffer);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho         NextArgument:
1.1  jruoho             ArgOp = ArgOp->Asl.Next;
1.1  jruoho             INCREMENT_ARG_LIST (RuntimeArgTypes2);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (AE_OK);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnIsResultUsed
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Op              - Parent op for the operator
1.1  jruoho  *
1.1  jruoho  * RETURN:      TRUE if result from this operation is actually consumed
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Determine if the function result value from an operator is
1.1  jruoho  *              used.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho BOOLEAN
1.1  jruoho AnIsResultUsed (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho     ACPI_PARSE_OBJECT       *Parent;
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_INCREMENT:
1.1  jruoho     case PARSEOP_DECREMENT:
1.1  jruoho
1.1  jruoho         /* These are standalone operators, no return value */
1.1  jruoho
1.1  jruoho         return (TRUE);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Examine parent to determine if the return value is used */
1.1  jruoho
1.1  jruoho     Parent = Op->Asl.Parent;
1.1  jruoho     switch (Parent->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     /* If/While - check if the operator is the predicate */
1.1  jruoho
1.1  jruoho     case PARSEOP_IF:
1.1  jruoho     case PARSEOP_WHILE:
1.1  jruoho
1.1  jruoho         /* First child is the predicate */
1.1  jruoho
1.1  jruoho         if (Parent->Asl.Child == Op)
1.1  jruoho         {
1.1  jruoho             return (TRUE);
1.1  jruoho         }
1.1  jruoho         return (FALSE);
1.1  jruoho
1.1  jruoho     /* Not used if one of these is the parent */
1.1  jruoho
1.1  jruoho     case PARSEOP_METHOD:
1.1  jruoho     case PARSEOP_DEFINITIONBLOCK:
1.1  jruoho     case PARSEOP_ELSE:
1.1  jruoho
1.1  jruoho         return (FALSE);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         /* Any other type of parent means that the result is used */
1.1  jruoho
1.1  jruoho         return (TRUE);
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnOtherSemanticAnalysisWalkBegin
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Descending callback for the analysis walk. Checks for
1.1  jruoho  *              miscellaneous issues in the code.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnOtherSemanticAnalysisWalkBegin (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho     ACPI_PARSE_OBJECT       *ArgNode;
1.1  jruoho     ACPI_PARSE_OBJECT       *PrevArgNode = NULL;
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo;
1.1  jruoho
1.1  jruoho
1.1  jruoho     OpInfo = AcpiPsGetOpcodeInfo (Op->Asl.AmlOpcode);
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Determine if an execution class operator actually does something by
1.1  jruoho      * checking if it has a target and/or the function return value is used.
1.1  jruoho      * (Target is optional, so a standalone statement can actually do nothing.)
1.1  jruoho      */
1.1  jruoho     if ((OpInfo->Class == AML_CLASS_EXECUTE) &&
1.1  jruoho         (OpInfo->Flags & AML_HAS_RETVAL) &&
1.1  jruoho         (!AnIsResultUsed (Op)))
1.1  jruoho     {
1.1  jruoho         if (OpInfo->Flags & AML_HAS_TARGET)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Find the target node, it is always the last child. If the traget
1.1  jruoho              * is not specified in the ASL, a default node of type Zero was
1.1  jruoho              * created by the parser.
1.1  jruoho              */
1.1  jruoho             ArgNode = Op->Asl.Child;
1.1  jruoho             while (ArgNode->Asl.Next)
1.1  jruoho             {
1.1  jruoho                 PrevArgNode = ArgNode;
1.1  jruoho                 ArgNode = ArgNode->Asl.Next;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             /* Divide() is the only weird case, it has two targets */
1.1  jruoho
1.1  jruoho             if (Op->Asl.AmlOpcode == AML_DIVIDE_OP)
1.1  jruoho             {
1.1  jruoho                 if ((ArgNode->Asl.ParseOpcode == PARSEOP_ZERO) &&
1.1  jruoho                     (PrevArgNode->Asl.ParseOpcode == PARSEOP_ZERO))
1.1  jruoho                 {
1.1  jruoho                     AslError (ASL_WARNING, ASL_MSG_RESULT_NOT_USED, Op, Op->Asl.ExternalName);
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho             else if (ArgNode->Asl.ParseOpcode == PARSEOP_ZERO)
1.1  jruoho             {
1.1  jruoho                 AslError (ASL_WARNING, ASL_MSG_RESULT_NOT_USED, Op, Op->Asl.ExternalName);
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho         else
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Has no target and the result is not used. Only a couple opcodes
1.1  jruoho              * can have this combination.
1.1  jruoho              */
1.1  jruoho             switch (Op->Asl.ParseOpcode)
1.1  jruoho             {
1.1  jruoho             case PARSEOP_ACQUIRE:
1.1  jruoho             case PARSEOP_WAIT:
1.1  jruoho             case PARSEOP_LOADTABLE:
1.1  jruoho                 break;
1.1  jruoho
1.1  jruoho             default:
1.1  jruoho                 AslError (ASL_WARNING, ASL_MSG_RESULT_NOT_USED, Op, Op->Asl.ExternalName);
1.1  jruoho                 break;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Semantic checks for individual ASL operators
1.1  jruoho      */
1.1  jruoho     switch (Op->Asl.ParseOpcode)
1.1  jruoho     {
1.1  jruoho     case PARSEOP_ACQUIRE:
1.1  jruoho     case PARSEOP_WAIT:
1.1  jruoho         /*
1.1  jruoho          * Emit a warning if the timeout parameter for these operators is not
1.1  jruoho          * ACPI_WAIT_FOREVER, and the result value from the operator is not
1.1  jruoho          * checked, meaning that a timeout could happen, but the code
1.1  jruoho          * would not know about it.
1.1  jruoho          */
1.1  jruoho
1.1  jruoho         /* First child is the namepath, 2nd child is timeout */
1.1  jruoho
1.1  jruoho         ArgNode = Op->Asl.Child;
1.1  jruoho         ArgNode = ArgNode->Asl.Next;
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Check for the WAIT_FOREVER case - defined by the ACPI spec to be
1.1  jruoho          * 0xFFFF or greater
1.1  jruoho          */
1.1  jruoho         if (((ArgNode->Asl.ParseOpcode == PARSEOP_WORDCONST) ||
1.1  jruoho              (ArgNode->Asl.ParseOpcode == PARSEOP_INTEGER))  &&
1.1  jruoho              (ArgNode->Asl.Value.Integer >= (UINT64) ACPI_WAIT_FOREVER))
1.1  jruoho         {
1.1  jruoho             break;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * The operation could timeout. If the return value is not used
1.1  jruoho          * (indicates timeout occurred), issue a warning
1.1  jruoho          */
1.1  jruoho         if (!AnIsResultUsed (Op))
1.1  jruoho         {
1.1  jruoho             AslError (ASL_WARNING, ASL_MSG_TIMEOUT, ArgNode, Op->Asl.ExternalName);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     case PARSEOP_CREATEFIELD:
1.1  jruoho         /*
1.1  jruoho          * Check for a zero Length (NumBits) operand. NumBits is the 3rd operand
1.1  jruoho          */
1.1  jruoho         ArgNode = Op->Asl.Child;
1.1  jruoho         ArgNode = ArgNode->Asl.Next;
1.1  jruoho         ArgNode = ArgNode->Asl.Next;
1.1  jruoho
1.1  jruoho         if ((ArgNode->Asl.ParseOpcode == PARSEOP_ZERO) ||
1.1  jruoho            ((ArgNode->Asl.ParseOpcode == PARSEOP_INTEGER) &&
1.1  jruoho             (ArgNode->Asl.Value.Integer == 0)))
1.1  jruoho         {
1.1  jruoho             AslError (ASL_ERROR, ASL_MSG_NON_ZERO, ArgNode, NULL);
1.1  jruoho         }
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnOtherSemanticAnalysisWalkEnd
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ASL_WALK_CALLBACK
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Ascending callback for analysis walk. Complete method
1.1  jruoho  *              return analysis.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AnOtherSemanticAnalysisWalkEnd (
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     UINT32                  Level,
1.1  jruoho     void                    *Context)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     return AE_OK;
1.1  jruoho
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho #ifdef ACPI_OBSOLETE_FUNCTIONS
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AnMapBtypeToEtype
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  Btype               - Bitfield of ACPI types
1.1  jruoho  *
1.1  jruoho  * RETURN:      The Etype corresponding the the Btype
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Convert a bitfield type to an encoded type
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho UINT32
1.1  jruoho AnMapBtypeToEtype (
1.1  jruoho     UINT32              Btype)
1.1  jruoho {
1.1  jruoho     UINT32              i;
1.1  jruoho     UINT32              Etype;
1.1  jruoho
1.1  jruoho
1.1  jruoho     if (Btype == 0)
1.1  jruoho     {
1.1  jruoho         return 0;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     Etype = 1;
1.1  jruoho     for (i = 1; i < Btype; i *= 2)
1.1  jruoho     {
1.1  jruoho         Etype++;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return (Etype);
1.1  jruoho }
1.1  jruoho #endif
1.1  jruoho