dist/parser/psloop.c

1.1  jruoho /******************************************************************************
1.1  jruoho  *
1.1  jruoho  * Module Name: psloop - Main AML parse loop
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 /*
1.1  jruoho  * Parse the AML and build an operation tree as most interpreters, (such as
1.1  jruoho  * Perl) do. Parsing is done by hand rather than with a YACC generated parser
1.1  jruoho  * to tightly constrain stack and dynamic memory usage. Parsing is kept
1.1  jruoho  * flexible and the code fairly compact by parsing based on a list of AML
1.1  jruoho  * opcode templates in AmlOpInfo[].
1.1  jruoho  */
1.1  jruoho
1.1  jruoho #include "acpi.h"
1.1  jruoho #include "accommon.h"
1.1  jruoho #include "acparser.h"
1.1  jruoho #include "acdispat.h"
1.1  jruoho #include "amlcode.h"
1.1  jruoho
1.1  jruoho #define _COMPONENT          ACPI_PARSER
1.1  jruoho         ACPI_MODULE_NAME    ("psloop")
1.1  jruoho
1.1  jruoho static UINT32               AcpiGbl_Depth = 0;
1.1  jruoho
1.1  jruoho
1.1  jruoho /* Local prototypes */
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsGetAmlOpcode (
1.1  jruoho     ACPI_WALK_STATE         *WalkState);
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsBuildNamedOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       *UnnamedOp,
1.1  jruoho     ACPI_PARSE_OBJECT       **Op);
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCreateOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       **NewOp);
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsGetArguments (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       *Op);
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCompleteOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     ACPI_PARSE_OBJECT       **Op,
1.1  jruoho     ACPI_STATUS             Status);
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCompleteFinalOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     ACPI_STATUS             Status);
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AcpiPsLinkModuleCode (
1.1  jruoho     ACPI_PARSE_OBJECT       *ParentOp,
1.1  jruoho     UINT8                   *AmlStart,
1.1  jruoho     UINT32                  AmlLength,
1.1  jruoho     ACPI_OWNER_ID           OwnerId);
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsGetAmlOpcode
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Extract the next AML opcode from the input stream.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsGetAmlOpcode (
1.1  jruoho     ACPI_WALK_STATE         *WalkState)
1.1  jruoho {
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsGetAmlOpcode, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     WalkState->AmlOffset = (UINT32) ACPI_PTR_DIFF (WalkState->ParserState.Aml,
1.1  jruoho                                 WalkState->ParserState.AmlStart);
1.1  jruoho     WalkState->Opcode = AcpiPsPeekOpcode (&(WalkState->ParserState));
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * First cut to determine what we have found:
1.1  jruoho      * 1) A valid AML opcode
1.1  jruoho      * 2) A name string
1.1  jruoho      * 3) An unknown/invalid opcode
1.1  jruoho      */
1.1  jruoho     WalkState->OpInfo = AcpiPsGetOpcodeInfo (WalkState->Opcode);
1.1  jruoho
1.1  jruoho     switch (WalkState->OpInfo->Class)
1.1  jruoho     {
1.1  jruoho     case AML_CLASS_ASCII:
1.1  jruoho     case AML_CLASS_PREFIX:
1.1  jruoho         /*
1.1  jruoho          * Starts with a valid prefix or ASCII char, this is a name
1.1  jruoho          * string. Convert the bare name string to a namepath.
1.1  jruoho          */
1.1  jruoho         WalkState->Opcode = AML_INT_NAMEPATH_OP;
1.1  jruoho         WalkState->ArgTypes = ARGP_NAMESTRING;
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     case AML_CLASS_UNKNOWN:
1.1  jruoho
1.1  jruoho         /* The opcode is unrecognized. Just skip unknown opcodes */
1.1  jruoho
1.1  jruoho         ACPI_ERROR ((AE_INFO,
1.1  jruoho              "Found unknown opcode 0x%X at AML address %p offset 0x%X, ignoring",
1.1  jruoho               WalkState->Opcode, WalkState->ParserState.Aml, WalkState->AmlOffset));
1.1  jruoho
1.1  jruoho         ACPI_DUMP_BUFFER (WalkState->ParserState.Aml, 128);
1.1  jruoho
1.1  jruoho         /* Assume one-byte bad opcode */
1.1  jruoho
1.1  jruoho         WalkState->ParserState.Aml++;
1.1  jruoho         return_ACPI_STATUS (AE_CTRL_PARSE_CONTINUE);
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho
1.1  jruoho         /* Found opcode info, this is a normal opcode */
1.1  jruoho
1.1  jruoho         WalkState->ParserState.Aml += AcpiPsGetOpcodeSize (WalkState->Opcode);
1.1  jruoho         WalkState->ArgTypes = WalkState->OpInfo->ParseArgs;
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (AE_OK);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsBuildNamedOp
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *              AmlOpStart          - Begin of named Op in AML
1.1  jruoho  *              UnnamedOp           - Early Op (not a named Op)
1.1  jruoho  *              Op                  - Returned Op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Parse a named Op
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsBuildNamedOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       *UnnamedOp,
1.1  jruoho     ACPI_PARSE_OBJECT       **Op)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status = AE_OK;
1.1  jruoho     ACPI_PARSE_OBJECT       *Arg = NULL;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsBuildNamedOp, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     UnnamedOp->Common.Value.Arg = NULL;
1.1  jruoho     UnnamedOp->Common.ArgListLength = 0;
1.1  jruoho     UnnamedOp->Common.AmlOpcode = WalkState->Opcode;
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Get and append arguments until we find the node that contains
1.1  jruoho      * the name (the type ARGP_NAME).
1.1  jruoho      */
1.1  jruoho     while (GET_CURRENT_ARG_TYPE (WalkState->ArgTypes) &&
1.1  jruoho           (GET_CURRENT_ARG_TYPE (WalkState->ArgTypes) != ARGP_NAME))
1.1  jruoho     {
1.1  jruoho         Status = AcpiPsGetNextArg (WalkState, &(WalkState->ParserState),
1.1  jruoho                     GET_CURRENT_ARG_TYPE (WalkState->ArgTypes), &Arg);
1.1  jruoho         if (ACPI_FAILURE (Status))
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (Status);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         AcpiPsAppendArg (UnnamedOp, Arg);
1.1  jruoho         INCREMENT_ARG_LIST (WalkState->ArgTypes);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Make sure that we found a NAME and didn't run out of arguments
1.1  jruoho      */
1.1  jruoho     if (!GET_CURRENT_ARG_TYPE (WalkState->ArgTypes))
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (AE_AML_NO_OPERAND);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* We know that this arg is a name, move to next arg */
1.1  jruoho
1.1  jruoho     INCREMENT_ARG_LIST (WalkState->ArgTypes);
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Find the object. This will either insert the object into
1.1  jruoho      * the namespace or simply look it up
1.1  jruoho      */
1.1  jruoho     WalkState->Op = NULL;
1.1  jruoho
1.1  jruoho     Status = WalkState->DescendingCallback (WalkState, Op);
1.1  jruoho     if (ACPI_FAILURE (Status))
1.1  jruoho     {
1.1  jruoho         ACPI_EXCEPTION ((AE_INFO, Status, "During name lookup/catalog"));
1.1  jruoho         return_ACPI_STATUS (Status);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     if (!*Op)
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (AE_CTRL_PARSE_CONTINUE);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     Status = AcpiPsNextParseState (WalkState, *Op, Status);
1.1  jruoho     if (ACPI_FAILURE (Status))
1.1  jruoho     {
1.1  jruoho         if (Status == AE_CTRL_PENDING)
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (AE_CTRL_PARSE_PENDING);
1.1  jruoho         }
1.1  jruoho         return_ACPI_STATUS (Status);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     AcpiPsAppendArg (*Op, UnnamedOp->Common.Value.Arg);
1.1  jruoho     AcpiGbl_Depth++;
1.1  jruoho
1.1  jruoho     if ((*Op)->Common.AmlOpcode == AML_REGION_OP ||
1.1  jruoho         (*Op)->Common.AmlOpcode == AML_DATA_REGION_OP)
1.1  jruoho     {
1.1  jruoho         /*
1.1  jruoho          * Defer final parsing of an OperationRegion body, because we don't
1.1  jruoho          * have enough info in the first pass to parse it correctly (i.e.,
1.1  jruoho          * there may be method calls within the TermArg elements of the body.)
1.1  jruoho          *
1.1  jruoho          * However, we must continue parsing because the opregion is not a
1.1  jruoho          * standalone package -- we don't know where the end is at this point.
1.1  jruoho          *
1.1  jruoho          * (Length is unknown until parse of the body complete)
1.1  jruoho          */
1.1  jruoho         (*Op)->Named.Data = AmlOpStart;
1.1  jruoho         (*Op)->Named.Length = 0;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (AE_OK);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsCreateOp
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *              AmlOpStart          - Op start in AML
1.1  jruoho  *              NewOp               - Returned Op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Get Op from AML
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCreateOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       **NewOp)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status = AE_OK;
1.1  jruoho     ACPI_PARSE_OBJECT       *Op;
1.1  jruoho     ACPI_PARSE_OBJECT       *NamedOp = NULL;
1.1  jruoho     ACPI_PARSE_OBJECT       *ParentScope;
1.1  jruoho     UINT8                   ArgumentCount;
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsCreateOp, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     Status = AcpiPsGetAmlOpcode (WalkState);
1.1  jruoho     if (Status == AE_CTRL_PARSE_CONTINUE)
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (AE_CTRL_PARSE_CONTINUE);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Create Op structure and append to parent's argument list */
1.1  jruoho
1.1  jruoho     WalkState->OpInfo = AcpiPsGetOpcodeInfo (WalkState->Opcode);
1.1  jruoho     Op = AcpiPsAllocOp (WalkState->Opcode);
1.1  jruoho     if (!Op)
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (AE_NO_MEMORY);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     if (WalkState->OpInfo->Flags & AML_NAMED)
1.1  jruoho     {
1.1  jruoho         Status = AcpiPsBuildNamedOp (WalkState, AmlOpStart, Op, &NamedOp);
1.1  jruoho         AcpiPsFreeOp (Op);
1.1  jruoho         if (ACPI_FAILURE (Status))
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (Status);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         *NewOp = NamedOp;
1.1  jruoho         return_ACPI_STATUS (AE_OK);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* Not a named opcode, just allocate Op and append to parent */
1.1  jruoho
1.1  jruoho     if (WalkState->OpInfo->Flags & AML_CREATE)
1.1  jruoho     {
1.1  jruoho         /*
1.1  jruoho          * Backup to beginning of CreateXXXfield declaration
1.1  jruoho          * BodyLength is unknown until we parse the body
1.1  jruoho          */
1.1  jruoho         Op->Named.Data = AmlOpStart;
1.1  jruoho         Op->Named.Length = 0;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     if (WalkState->Opcode == AML_BANK_FIELD_OP)
1.1  jruoho     {
1.1  jruoho         /*
1.1  jruoho          * Backup to beginning of BankField declaration
1.1  jruoho          * BodyLength is unknown until we parse the body
1.1  jruoho          */
1.1  jruoho         Op->Named.Data = AmlOpStart;
1.1  jruoho         Op->Named.Length = 0;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     ParentScope = AcpiPsGetParentScope (&(WalkState->ParserState));
1.1  jruoho     AcpiPsAppendArg (ParentScope, Op);
1.1  jruoho
1.1  jruoho     if (ParentScope)
1.1  jruoho     {
1.1  jruoho         OpInfo = AcpiPsGetOpcodeInfo (ParentScope->Common.AmlOpcode);
1.1  jruoho         if (OpInfo->Flags & AML_HAS_TARGET)
1.1  jruoho         {
1.1  jruoho             ArgumentCount = AcpiPsGetArgumentCount (OpInfo->Type);
1.1  jruoho             if (ParentScope->Common.ArgListLength > ArgumentCount)
1.1  jruoho             {
1.1  jruoho                 Op->Common.Flags |= ACPI_PARSEOP_TARGET;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho         else if (ParentScope->Common.AmlOpcode == AML_INCREMENT_OP)
1.1  jruoho         {
1.1  jruoho             Op->Common.Flags |= ACPI_PARSEOP_TARGET;
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     if (WalkState->DescendingCallback != NULL)
1.1  jruoho     {
1.1  jruoho         /*
1.1  jruoho          * Find the object. This will either insert the object into
1.1  jruoho          * the namespace or simply look it up
1.1  jruoho          */
1.1  jruoho         WalkState->Op = *NewOp = Op;
1.1  jruoho
1.1  jruoho         Status = WalkState->DescendingCallback (WalkState, &Op);
1.1  jruoho         Status = AcpiPsNextParseState (WalkState, Op, Status);
1.1  jruoho         if (Status == AE_CTRL_PENDING)
1.1  jruoho         {
1.1  jruoho             Status = AE_CTRL_PARSE_PENDING;
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (Status);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsGetArguments
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *              AmlOpStart          - Op start in AML
1.1  jruoho  *              Op                  - Current Op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Get arguments for passed Op.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsGetArguments (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     UINT8                   *AmlOpStart,
1.1  jruoho     ACPI_PARSE_OBJECT       *Op)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status = AE_OK;
1.1  jruoho     ACPI_PARSE_OBJECT       *Arg = NULL;
1.1  jruoho     const ACPI_OPCODE_INFO  *OpInfo;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsGetArguments, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     switch (Op->Common.AmlOpcode)
1.1  jruoho     {
1.1  jruoho     case AML_BYTE_OP:       /* AML_BYTEDATA_ARG */
1.1  jruoho     case AML_WORD_OP:       /* AML_WORDDATA_ARG */
1.1  jruoho     case AML_DWORD_OP:      /* AML_DWORDATA_ARG */
1.1  jruoho     case AML_QWORD_OP:      /* AML_QWORDATA_ARG */
1.1  jruoho     case AML_STRING_OP:     /* AML_ASCIICHARLIST_ARG */
1.1  jruoho
1.1  jruoho         /* Fill in constant or string argument directly */
1.1  jruoho
1.1  jruoho         AcpiPsGetNextSimpleArg (&(WalkState->ParserState),
1.1  jruoho             GET_CURRENT_ARG_TYPE (WalkState->ArgTypes), Op);
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     case AML_INT_NAMEPATH_OP:   /* AML_NAMESTRING_ARG */
1.1  jruoho
1.1  jruoho         Status = AcpiPsGetNextNamepath (WalkState, &(WalkState->ParserState), Op, 1);
1.1  jruoho         if (ACPI_FAILURE (Status))
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (Status);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         WalkState->ArgTypes = 0;
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho     default:
1.1  jruoho         /*
1.1  jruoho          * Op is not a constant or string, append each argument to the Op
1.1  jruoho          */
1.1  jruoho         while (GET_CURRENT_ARG_TYPE (WalkState->ArgTypes) && !WalkState->ArgCount)
1.1  jruoho         {
1.1  jruoho             WalkState->AmlOffset = (UINT32) ACPI_PTR_DIFF (WalkState->ParserState.Aml,
1.1  jruoho                 WalkState->ParserState.AmlStart);
1.1  jruoho
1.1  jruoho             Status = AcpiPsGetNextArg (WalkState, &(WalkState->ParserState),
1.1  jruoho                         GET_CURRENT_ARG_TYPE (WalkState->ArgTypes), &Arg);
1.1  jruoho             if (ACPI_FAILURE (Status))
1.1  jruoho             {
1.1  jruoho                 return_ACPI_STATUS (Status);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             if (Arg)
1.1  jruoho             {
1.1  jruoho                 Arg->Common.AmlOffset = WalkState->AmlOffset;
1.1  jruoho                 AcpiPsAppendArg (Op, Arg);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             INCREMENT_ARG_LIST (WalkState->ArgTypes);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Handle executable code at "module-level". This refers to
1.1  jruoho          * executable opcodes that appear outside of any control method.
1.1  jruoho          */
1.1  jruoho         if ((WalkState->PassNumber <= ACPI_IMODE_LOAD_PASS2) &&
1.1  jruoho             ((WalkState->ParseFlags & ACPI_PARSE_DISASSEMBLE) == 0))
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * We want to skip If/Else/While constructs during Pass1 because we
1.1  jruoho              * want to actually conditionally execute the code during Pass2.
1.1  jruoho              *
1.1  jruoho              * Except for disassembly, where we always want to walk the
1.1  jruoho              * If/Else/While packages
1.1  jruoho              */
1.1  jruoho             switch (Op->Common.AmlOpcode)
1.1  jruoho             {
1.1  jruoho             case AML_IF_OP:
1.1  jruoho             case AML_ELSE_OP:
1.1  jruoho             case AML_WHILE_OP:
1.1  jruoho
1.1  jruoho                 /*
1.1  jruoho                  * Currently supported module-level opcodes are:
1.1  jruoho                  * IF/ELSE/WHILE. These appear to be the most common,
1.1  jruoho                  * and easiest to support since they open an AML
1.1  jruoho                  * package.
1.1  jruoho                  */
1.1  jruoho                 if (WalkState->PassNumber == ACPI_IMODE_LOAD_PASS1)
1.1  jruoho                 {
1.1  jruoho                     AcpiPsLinkModuleCode (Op->Common.Parent, AmlOpStart,
1.1  jruoho                         (UINT32) (WalkState->ParserState.PkgEnd - AmlOpStart),
1.1  jruoho                         WalkState->OwnerId);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 ACPI_DEBUG_PRINT ((ACPI_DB_PARSE,
1.1  jruoho                     "Pass1: Skipping an If/Else/While body\n"));
1.1  jruoho
1.1  jruoho                 /* Skip body of if/else/while in pass 1 */
1.1  jruoho
1.1  jruoho                 WalkState->ParserState.Aml = WalkState->ParserState.PkgEnd;
1.1  jruoho                 WalkState->ArgCount = 0;
1.1  jruoho                 break;
1.1  jruoho
1.1  jruoho             default:
1.1  jruoho                 /*
1.1  jruoho                  * Check for an unsupported executable opcode at module
1.1  jruoho                  * level. We must be in PASS1, the parent must be a SCOPE,
1.1  jruoho                  * The opcode class must be EXECUTE, and the opcode must
1.1  jruoho                  * not be an argument to another opcode.
1.1  jruoho                  */
1.1  jruoho                 if ((WalkState->PassNumber == ACPI_IMODE_LOAD_PASS1) &&
1.1  jruoho                     (Op->Common.Parent->Common.AmlOpcode == AML_SCOPE_OP))
1.1  jruoho                 {
1.1  jruoho                     OpInfo = AcpiPsGetOpcodeInfo (Op->Common.AmlOpcode);
1.1  jruoho                     if ((OpInfo->Class == AML_CLASS_EXECUTE) &&
1.1  jruoho                         (!Arg))
1.1  jruoho                     {
1.1  jruoho                         ACPI_WARNING ((AE_INFO,
1.1  jruoho                             "Detected an unsupported executable opcode "
1.1  jruoho                             "at module-level: [0x%.4X] at table offset 0x%.4X",
1.1  jruoho                             Op->Common.AmlOpcode,
1.1  jruoho                             (UINT32) (ACPI_PTR_DIFF (AmlOpStart,
1.1  jruoho                                 WalkState->ParserState.AmlStart) +
1.1  jruoho                                 sizeof (ACPI_TABLE_HEADER))));
1.1  jruoho                     }
1.1  jruoho                 }
1.1  jruoho                 break;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Special processing for certain opcodes */
1.1  jruoho
1.1  jruoho         switch (Op->Common.AmlOpcode)
1.1  jruoho         {
1.1  jruoho         case AML_METHOD_OP:
1.1  jruoho             /*
1.1  jruoho              * Skip parsing of control method because we don't have enough
1.1  jruoho              * info in the first pass to parse it correctly.
1.1  jruoho              *
1.1  jruoho              * Save the length and address of the body
1.1  jruoho              */
1.1  jruoho             Op->Named.Data = WalkState->ParserState.Aml;
1.1  jruoho             Op->Named.Length = (UINT32)
1.1  jruoho                 (WalkState->ParserState.PkgEnd - WalkState->ParserState.Aml);
1.1  jruoho
1.1  jruoho             /* Skip body of method */
1.1  jruoho
1.1  jruoho             WalkState->ParserState.Aml = WalkState->ParserState.PkgEnd;
1.1  jruoho             WalkState->ArgCount = 0;
1.1  jruoho             break;
1.1  jruoho
1.1  jruoho         case AML_BUFFER_OP:
1.1  jruoho         case AML_PACKAGE_OP:
1.1  jruoho         case AML_VAR_PACKAGE_OP:
1.1  jruoho
1.1  jruoho             if ((Op->Common.Parent) &&
1.1  jruoho                 (Op->Common.Parent->Common.AmlOpcode == AML_NAME_OP) &&
1.1  jruoho                 (WalkState->PassNumber <= ACPI_IMODE_LOAD_PASS2))
1.1  jruoho             {
1.1  jruoho                 /*
1.1  jruoho                  * Skip parsing of Buffers and Packages because we don't have
1.1  jruoho                  * enough info in the first pass to parse them correctly.
1.1  jruoho                  */
1.1  jruoho                 Op->Named.Data = AmlOpStart;
1.1  jruoho                 Op->Named.Length = (UINT32)
1.1  jruoho                     (WalkState->ParserState.PkgEnd - AmlOpStart);
1.1  jruoho
1.1  jruoho                 /* Skip body */
1.1  jruoho
1.1  jruoho                 WalkState->ParserState.Aml = WalkState->ParserState.PkgEnd;
1.1  jruoho                 WalkState->ArgCount = 0;
1.1  jruoho             }
1.1  jruoho             break;
1.1  jruoho
1.1  jruoho         case AML_WHILE_OP:
1.1  jruoho
1.1  jruoho             if (WalkState->ControlState)
1.1  jruoho             {
1.1  jruoho                 WalkState->ControlState->Control.PackageEnd =
1.1  jruoho                     WalkState->ParserState.PkgEnd;
1.1  jruoho             }
1.1  jruoho             break;
1.1  jruoho
1.1  jruoho         default:
1.1  jruoho
1.1  jruoho             /* No action for all other opcodes */
1.1  jruoho             break;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         break;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (AE_OK);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsLinkModuleCode
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  ParentOp            - Parent parser op
1.1  jruoho  *              AmlStart            - Pointer to the AML
1.1  jruoho  *              AmlLength           - Length of executable AML
1.1  jruoho  *              OwnerId             - OwnerId of module level code
1.1  jruoho  *
1.1  jruoho  * RETURN:      None.
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Wrap the module-level code with a method object and link the
1.1  jruoho  *              object to the global list. Note, the mutex field of the method
1.1  jruoho  *              object is used to link multiple module-level code objects.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static void
1.1  jruoho AcpiPsLinkModuleCode (
1.1  jruoho     ACPI_PARSE_OBJECT       *ParentOp,
1.1  jruoho     UINT8                   *AmlStart,
1.1  jruoho     UINT32                  AmlLength,
1.1  jruoho     ACPI_OWNER_ID           OwnerId)
1.1  jruoho {
1.1  jruoho     ACPI_OPERAND_OBJECT     *Prev;
1.1  jruoho     ACPI_OPERAND_OBJECT     *Next;
1.1  jruoho     ACPI_OPERAND_OBJECT     *MethodObj;
1.1  jruoho     ACPI_NAMESPACE_NODE     *ParentNode;
1.1  jruoho
1.1  jruoho
1.1  jruoho     /* Get the tail of the list */
1.1  jruoho
1.1  jruoho     Prev = Next = AcpiGbl_ModuleCodeList;
1.1  jruoho     while (Next)
1.1  jruoho     {
1.1  jruoho         Prev = Next;
1.1  jruoho         Next = Next->Method.Mutex;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Insert the module level code into the list. Merge it if it is
1.1  jruoho      * adjacent to the previous element.
1.1  jruoho      */
1.1  jruoho     if (!Prev ||
1.1  jruoho        ((Prev->Method.AmlStart + Prev->Method.AmlLength) != AmlStart))
1.1  jruoho     {
1.1  jruoho         /* Create, initialize, and link a new temporary method object */
1.1  jruoho
1.1  jruoho         MethodObj = AcpiUtCreateInternalObject (ACPI_TYPE_METHOD);
1.1  jruoho         if (!MethodObj)
1.1  jruoho         {
1.1  jruoho             return;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         if (ParentOp->Common.Node)
1.1  jruoho         {
1.1  jruoho             ParentNode = ParentOp->Common.Node;
1.1  jruoho         }
1.1  jruoho         else
1.1  jruoho         {
1.1  jruoho             ParentNode = AcpiGbl_RootNode;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         MethodObj->Method.AmlStart = AmlStart;
1.1  jruoho         MethodObj->Method.AmlLength = AmlLength;
1.1  jruoho         MethodObj->Method.OwnerId = OwnerId;
1.1  jruoho         MethodObj->Method.Flags |= AOPOBJ_MODULE_LEVEL;
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Save the parent node in NextObject. This is cheating, but we
1.1  jruoho          * don't want to expand the method object.
1.1  jruoho          */
1.1  jruoho         MethodObj->Method.NextObject =
1.1  jruoho             ACPI_CAST_PTR (ACPI_OPERAND_OBJECT, ParentNode);
1.1  jruoho
1.1  jruoho         if (!Prev)
1.1  jruoho         {
1.1  jruoho             AcpiGbl_ModuleCodeList = MethodObj;
1.1  jruoho         }
1.1  jruoho         else
1.1  jruoho         {
1.1  jruoho             Prev->Method.Mutex = MethodObj;
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho     else
1.1  jruoho     {
1.1  jruoho         Prev->Method.AmlLength += AmlLength;
1.1  jruoho     }
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsCompleteOp
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *              Op                  - Returned Op
1.1  jruoho  *              Status              - Parse status before complete Op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Complete Op
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCompleteOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     ACPI_PARSE_OBJECT       **Op,
1.1  jruoho     ACPI_STATUS             Status)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status2;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsCompleteOp, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Finished one argument of the containing scope
1.1  jruoho      */
1.1  jruoho     WalkState->ParserState.Scope->ParseScope.ArgCount--;
1.1  jruoho
1.1  jruoho     /* Close this Op (will result in parse subtree deletion) */
1.1  jruoho
1.1  jruoho     Status2 = AcpiPsCompleteThisOp (WalkState, *Op);
1.1  jruoho     if (ACPI_FAILURE (Status2))
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (Status2);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     *Op = NULL;
1.1  jruoho
1.1  jruoho     switch (Status)
1.1  jruoho     {
1.1  jruoho     case AE_OK:
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case AE_CTRL_TRANSFER:
1.1  jruoho
1.1  jruoho         /* We are about to transfer to a called method */
1.1  jruoho
1.1  jruoho         WalkState->PrevOp = NULL;
1.1  jruoho         WalkState->PrevArgTypes = WalkState->ArgTypes;
1.1  jruoho         return_ACPI_STATUS (Status);
1.1  jruoho
1.1  jruoho
1.1  jruoho     case AE_CTRL_END:
1.1  jruoho
1.1  jruoho         AcpiPsPopScope (&(WalkState->ParserState), Op,
1.1  jruoho             &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho
1.1  jruoho         if (*Op)
1.1  jruoho         {
1.1  jruoho             WalkState->Op = *Op;
1.1  jruoho             WalkState->OpInfo = AcpiPsGetOpcodeInfo ((*Op)->Common.AmlOpcode);
1.1  jruoho             WalkState->Opcode = (*Op)->Common.AmlOpcode;
1.1  jruoho
1.1  jruoho             Status = WalkState->AscendingCallback (WalkState);
1.1  jruoho             Status = AcpiPsNextParseState (WalkState, *Op, Status);
1.1  jruoho
1.1  jruoho             Status2 = AcpiPsCompleteThisOp (WalkState, *Op);
1.1  jruoho             if (ACPI_FAILURE (Status2))
1.1  jruoho             {
1.1  jruoho                 return_ACPI_STATUS (Status2);
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         Status = AE_OK;
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case AE_CTRL_BREAK:
1.1  jruoho     case AE_CTRL_CONTINUE:
1.1  jruoho
1.1  jruoho         /* Pop off scopes until we find the While */
1.1  jruoho
1.1  jruoho         while (!(*Op) || ((*Op)->Common.AmlOpcode != AML_WHILE_OP))
1.1  jruoho         {
1.1  jruoho             AcpiPsPopScope (&(WalkState->ParserState), Op,
1.1  jruoho                 &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Close this iteration of the While loop */
1.1  jruoho
1.1  jruoho         WalkState->Op = *Op;
1.1  jruoho         WalkState->OpInfo = AcpiPsGetOpcodeInfo ((*Op)->Common.AmlOpcode);
1.1  jruoho         WalkState->Opcode = (*Op)->Common.AmlOpcode;
1.1  jruoho
1.1  jruoho         Status = WalkState->AscendingCallback (WalkState);
1.1  jruoho         Status = AcpiPsNextParseState (WalkState, *Op, Status);
1.1  jruoho
1.1  jruoho         Status2 = AcpiPsCompleteThisOp (WalkState, *Op);
1.1  jruoho         if (ACPI_FAILURE (Status2))
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (Status2);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         Status = AE_OK;
1.1  jruoho         break;
1.1  jruoho
1.1  jruoho
1.1  jruoho     case AE_CTRL_TERMINATE:
1.1  jruoho
1.1  jruoho         /* Clean up */
1.1  jruoho         do
1.1  jruoho         {
1.1  jruoho             if (*Op)
1.1  jruoho             {
1.1  jruoho                 Status2 = AcpiPsCompleteThisOp (WalkState, *Op);
1.1  jruoho                 if (ACPI_FAILURE (Status2))
1.1  jruoho                 {
1.1  jruoho                     return_ACPI_STATUS (Status2);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 AcpiUtDeleteGenericState (
1.1  jruoho                     AcpiUtPopGenericState (&WalkState->ControlState));
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             AcpiPsPopScope (&(WalkState->ParserState), Op,
1.1  jruoho                 &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho
1.1  jruoho         } while (*Op);
1.1  jruoho
1.1  jruoho         return_ACPI_STATUS (AE_OK);
1.1  jruoho
1.1  jruoho
1.1  jruoho     default:  /* All other non-AE_OK status */
1.1  jruoho
1.1  jruoho         do
1.1  jruoho         {
1.1  jruoho             if (*Op)
1.1  jruoho             {
1.1  jruoho                 Status2 = AcpiPsCompleteThisOp (WalkState, *Op);
1.1  jruoho                 if (ACPI_FAILURE (Status2))
1.1  jruoho                 {
1.1  jruoho                     return_ACPI_STATUS (Status2);
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             AcpiPsPopScope (&(WalkState->ParserState), Op,
1.1  jruoho                 &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho
1.1  jruoho         } while (*Op);
1.1  jruoho
1.1  jruoho
1.1  jruoho #if 0
1.1  jruoho         /*
1.1  jruoho          * TBD: Cleanup parse ops on error
1.1  jruoho          */
1.1  jruoho         if (*Op == NULL)
1.1  jruoho         {
1.1  jruoho             AcpiPsPopScope (ParserState, Op,
1.1  jruoho                 &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho         }
1.1  jruoho #endif
1.1  jruoho         WalkState->PrevOp = NULL;
1.1  jruoho         WalkState->PrevArgTypes = WalkState->ArgTypes;
1.1  jruoho         return_ACPI_STATUS (Status);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     /* This scope complete? */
1.1  jruoho
1.1  jruoho     if (AcpiPsHasCompletedScope (&(WalkState->ParserState)))
1.1  jruoho     {
1.1  jruoho         AcpiPsPopScope (&(WalkState->ParserState), Op,
1.1  jruoho             &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho         ACPI_DEBUG_PRINT ((ACPI_DB_PARSE, "Popped scope, Op=%p\n", *Op));
1.1  jruoho     }
1.1  jruoho     else
1.1  jruoho     {
1.1  jruoho         *Op = NULL;
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (AE_OK);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsCompleteFinalOp
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *              Op                  - Current Op
1.1  jruoho  *              Status              - Current parse status before complete last
1.1  jruoho  *                                    Op
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Complete last Op.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho static ACPI_STATUS
1.1  jruoho AcpiPsCompleteFinalOp (
1.1  jruoho     ACPI_WALK_STATE         *WalkState,
1.1  jruoho     ACPI_PARSE_OBJECT       *Op,
1.1  jruoho     ACPI_STATUS             Status)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status2;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsCompleteFinalOp, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     /*
1.1  jruoho      * Complete the last Op (if not completed), and clear the scope stack.
1.1  jruoho      * It is easily possible to end an AML "package" with an unbounded number
1.1  jruoho      * of open scopes (such as when several ASL blocks are closed with
1.1  jruoho      * sequential closing braces). We want to terminate each one cleanly.
1.1  jruoho      */
1.1  jruoho     ACPI_DEBUG_PRINT ((ACPI_DB_PARSE, "AML package complete at Op %p\n", Op));
1.1  jruoho     do
1.1  jruoho     {
1.1  jruoho         if (Op)
1.1  jruoho         {
1.1  jruoho             if (WalkState->AscendingCallback != NULL)
1.1  jruoho             {
1.1  jruoho                 WalkState->Op = Op;
1.1  jruoho                 WalkState->OpInfo = AcpiPsGetOpcodeInfo (Op->Common.AmlOpcode);
1.1  jruoho                 WalkState->Opcode = Op->Common.AmlOpcode;
1.1  jruoho
1.1  jruoho                 Status = WalkState->AscendingCallback (WalkState);
1.1  jruoho                 Status = AcpiPsNextParseState (WalkState, Op, Status);
1.1  jruoho                 if (Status == AE_CTRL_PENDING)
1.1  jruoho                 {
1.1  jruoho                     Status = AcpiPsCompleteOp (WalkState, &Op, AE_OK);
1.1  jruoho                     if (ACPI_FAILURE (Status))
1.1  jruoho                     {
1.1  jruoho                         return_ACPI_STATUS (Status);
1.1  jruoho                     }
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 if (Status == AE_CTRL_TERMINATE)
1.1  jruoho                 {
1.1  jruoho                     Status = AE_OK;
1.1  jruoho
1.1  jruoho                     /* Clean up */
1.1  jruoho                     do
1.1  jruoho                     {
1.1  jruoho                         if (Op)
1.1  jruoho                         {
1.1  jruoho                             Status2 = AcpiPsCompleteThisOp (WalkState, Op);
1.1  jruoho                             if (ACPI_FAILURE (Status2))
1.1  jruoho                             {
1.1  jruoho                                 return_ACPI_STATUS (Status2);
1.1  jruoho                             }
1.1  jruoho                         }
1.1  jruoho
1.1  jruoho                         AcpiPsPopScope (&(WalkState->ParserState), &Op,
1.1  jruoho                             &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho
1.1  jruoho                     } while (Op);
1.1  jruoho
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 else if (ACPI_FAILURE (Status))
1.1  jruoho                 {
1.1  jruoho                     /* First error is most important */
1.1  jruoho
1.1  jruoho                     (void) AcpiPsCompleteThisOp (WalkState, Op);
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             Status2 = AcpiPsCompleteThisOp (WalkState, Op);
1.1  jruoho             if (ACPI_FAILURE (Status2))
1.1  jruoho             {
1.1  jruoho                 return_ACPI_STATUS (Status2);
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         AcpiPsPopScope (&(WalkState->ParserState), &Op, &WalkState->ArgTypes,
1.1  jruoho             &WalkState->ArgCount);
1.1  jruoho
1.1  jruoho     } while (Op);
1.1  jruoho
1.1  jruoho     return_ACPI_STATUS (Status);
1.1  jruoho }
1.1  jruoho
1.1  jruoho
1.1  jruoho /*******************************************************************************
1.1  jruoho  *
1.1  jruoho  * FUNCTION:    AcpiPsParseLoop
1.1  jruoho  *
1.1  jruoho  * PARAMETERS:  WalkState           - Current state
1.1  jruoho  *
1.1  jruoho  * RETURN:      Status
1.1  jruoho  *
1.1  jruoho  * DESCRIPTION: Parse AML (pointed to by the current parser state) and return
1.1  jruoho  *              a tree of ops.
1.1  jruoho  *
1.1  jruoho  ******************************************************************************/
1.1  jruoho
1.1  jruoho ACPI_STATUS
1.1  jruoho AcpiPsParseLoop (
1.1  jruoho     ACPI_WALK_STATE         *WalkState)
1.1  jruoho {
1.1  jruoho     ACPI_STATUS             Status = AE_OK;
1.1  jruoho     ACPI_PARSE_OBJECT       *Op = NULL;     /* current op */
1.1  jruoho     ACPI_PARSE_STATE        *ParserState;
1.1  jruoho     UINT8                   *AmlOpStart = NULL;
1.1  jruoho
1.1  jruoho
1.1  jruoho     ACPI_FUNCTION_TRACE_PTR (PsParseLoop, WalkState);
1.1  jruoho
1.1  jruoho
1.1  jruoho     if (WalkState->DescendingCallback == NULL)
1.1  jruoho     {
1.1  jruoho         return_ACPI_STATUS (AE_BAD_PARAMETER);
1.1  jruoho     }
1.1  jruoho
1.1  jruoho     ParserState = &WalkState->ParserState;
1.1  jruoho     WalkState->ArgTypes = 0;
1.1  jruoho
1.1  jruoho #if (!defined (ACPI_NO_METHOD_EXECUTION) && !defined (ACPI_CONSTANT_EVAL_ONLY))
1.1  jruoho
1.1  jruoho     if (WalkState->WalkType & ACPI_WALK_METHOD_RESTART)
1.1  jruoho     {
1.1  jruoho         /* We are restarting a preempted control method */
1.1  jruoho
1.1  jruoho         if (AcpiPsHasCompletedScope (ParserState))
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * We must check if a predicate to an IF or WHILE statement
1.1  jruoho              * was just completed
1.1  jruoho              */
1.1  jruoho             if ((ParserState->Scope->ParseScope.Op) &&
1.1  jruoho                ((ParserState->Scope->ParseScope.Op->Common.AmlOpcode == AML_IF_OP) ||
1.1  jruoho                 (ParserState->Scope->ParseScope.Op->Common.AmlOpcode == AML_WHILE_OP)) &&
1.1  jruoho                 (WalkState->ControlState) &&
1.1  jruoho                 (WalkState->ControlState->Common.State ==
1.1  jruoho                     ACPI_CONTROL_PREDICATE_EXECUTING))
1.1  jruoho             {
1.1  jruoho                 /*
1.1  jruoho                  * A predicate was just completed, get the value of the
1.1  jruoho                  * predicate and branch based on that value
1.1  jruoho                  */
1.1  jruoho                 WalkState->Op = NULL;
1.1  jruoho                 Status = AcpiDsGetPredicateValue (WalkState, ACPI_TO_POINTER (TRUE));
1.1  jruoho                 if (ACPI_FAILURE (Status) &&
1.1  jruoho                     ((Status & AE_CODE_MASK) != AE_CODE_CONTROL))
1.1  jruoho                 {
1.1  jruoho                     if (Status == AE_AML_NO_RETURN_VALUE)
1.1  jruoho                     {
1.1  jruoho                         ACPI_EXCEPTION ((AE_INFO, Status,
1.1  jruoho                             "Invoked method did not return a value"));
1.1  jruoho                     }
1.1  jruoho
1.1  jruoho                     ACPI_EXCEPTION ((AE_INFO, Status, "GetPredicate Failed"));
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 Status = AcpiPsNextParseState (WalkState, Op, Status);
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             AcpiPsPopScope (ParserState, &Op,
1.1  jruoho                 &WalkState->ArgTypes, &WalkState->ArgCount);
1.1  jruoho             ACPI_DEBUG_PRINT ((ACPI_DB_PARSE, "Popped scope, Op=%p\n", Op));
1.1  jruoho         }
1.1  jruoho         else if (WalkState->PrevOp)
1.1  jruoho         {
1.1  jruoho             /* We were in the middle of an op */
1.1  jruoho
1.1  jruoho             Op = WalkState->PrevOp;
1.1  jruoho             WalkState->ArgTypes = WalkState->PrevArgTypes;
1.1  jruoho         }
1.1  jruoho     }
1.1  jruoho #endif
1.1  jruoho
1.1  jruoho     /* Iterative parsing loop, while there is more AML to process: */
1.1  jruoho
1.1  jruoho     while ((ParserState->Aml < ParserState->AmlEnd) || (Op))
1.1  jruoho     {
1.1  jruoho         AmlOpStart = ParserState->Aml;
1.1  jruoho         if (!Op)
1.1  jruoho         {
1.1  jruoho             Status = AcpiPsCreateOp (WalkState, AmlOpStart, &Op);
1.1  jruoho             if (ACPI_FAILURE (Status))
1.1  jruoho             {
1.1  jruoho                 if (Status == AE_CTRL_PARSE_CONTINUE)
1.1  jruoho                 {
1.1  jruoho                     continue;
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 if (Status == AE_CTRL_PARSE_PENDING)
1.1  jruoho                 {
1.1  jruoho                     Status = AE_OK;
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 Status = AcpiPsCompleteOp (WalkState, &Op, Status);
1.1  jruoho                 if (ACPI_FAILURE (Status))
1.1  jruoho                 {
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 continue;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             Op->Common.AmlOffset = WalkState->AmlOffset;
1.1  jruoho
1.1  jruoho             if (WalkState->OpInfo)
1.1  jruoho             {
1.1  jruoho                 ACPI_DEBUG_PRINT ((ACPI_DB_PARSE,
1.1  jruoho                     "Opcode %4.4X [%s] Op %p Aml %p AmlOffset %5.5X\n",
1.1  jruoho                      (UINT32) Op->Common.AmlOpcode, WalkState->OpInfo->Name,
1.1  jruoho                      Op, ParserState->Aml, Op->Common.AmlOffset));
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * Start ArgCount at zero because we don't know if there are
1.1  jruoho          * any args yet
1.1  jruoho          */
1.1  jruoho         WalkState->ArgCount  = 0;
1.1  jruoho
1.1  jruoho         /* Are there any arguments that must be processed? */
1.1  jruoho
1.1  jruoho         if (WalkState->ArgTypes)
1.1  jruoho         {
1.1  jruoho             /* Get arguments */
1.1  jruoho
1.1  jruoho             Status = AcpiPsGetArguments (WalkState, AmlOpStart, Op);
1.1  jruoho             if (ACPI_FAILURE (Status))
1.1  jruoho             {
1.1  jruoho                 Status = AcpiPsCompleteOp (WalkState, &Op, Status);
1.1  jruoho                 if (ACPI_FAILURE (Status))
1.1  jruoho                 {
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 continue;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* Check for arguments that need to be processed */
1.1  jruoho
1.1  jruoho         if (WalkState->ArgCount)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * There are arguments (complex ones), push Op and
1.1  jruoho              * prepare for argument
1.1  jruoho              */
1.1  jruoho             Status = AcpiPsPushScope (ParserState, Op,
1.1  jruoho                         WalkState->ArgTypes, WalkState->ArgCount);
1.1  jruoho             if (ACPI_FAILURE (Status))
1.1  jruoho             {
1.1  jruoho                 Status = AcpiPsCompleteOp (WalkState, &Op, Status);
1.1  jruoho                 if (ACPI_FAILURE (Status))
1.1  jruoho                 {
1.1  jruoho                     return_ACPI_STATUS (Status);
1.1  jruoho                 }
1.1  jruoho
1.1  jruoho                 continue;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             Op = NULL;
1.1  jruoho             continue;
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /*
1.1  jruoho          * All arguments have been processed -- Op is complete,
1.1  jruoho          * prepare for next
1.1  jruoho          */
1.1  jruoho         WalkState->OpInfo = AcpiPsGetOpcodeInfo (Op->Common.AmlOpcode);
1.1  jruoho         if (WalkState->OpInfo->Flags & AML_NAMED)
1.1  jruoho         {
1.1  jruoho             if (AcpiGbl_Depth)
1.1  jruoho             {
1.1  jruoho                 AcpiGbl_Depth--;
1.1  jruoho             }
1.1  jruoho
1.1  jruoho             if (Op->Common.AmlOpcode == AML_REGION_OP ||
1.1  jruoho                 Op->Common.AmlOpcode == AML_DATA_REGION_OP)
1.1  jruoho             {
1.1  jruoho                 /*
1.1  jruoho                  * Skip parsing of control method or opregion body,
1.1  jruoho                  * because we don't have enough info in the first pass
1.1  jruoho                  * to parse them correctly.
1.1  jruoho                  *
1.1  jruoho                  * Completed parsing an OpRegion declaration, we now
1.1  jruoho                  * know the length.
1.1  jruoho                  */
1.1  jruoho                 Op->Named.Length = (UINT32) (ParserState->Aml - Op->Named.Data);
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         if (WalkState->OpInfo->Flags & AML_CREATE)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Backup to beginning of CreateXXXfield declaration (1 for
1.1  jruoho              * Opcode)
1.1  jruoho              *
1.1  jruoho              * BodyLength is unknown until we parse the body
1.1  jruoho              */
1.1  jruoho             Op->Named.Length = (UINT32) (ParserState->Aml - Op->Named.Data);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         if (Op->Common.AmlOpcode == AML_BANK_FIELD_OP)
1.1  jruoho         {
1.1  jruoho             /*
1.1  jruoho              * Backup to beginning of BankField declaration
1.1  jruoho              *
1.1  jruoho              * BodyLength is unknown until we parse the body
1.1  jruoho              */
1.1  jruoho             Op->Named.Length = (UINT32) (ParserState->Aml - Op->Named.Data);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         /* This op complete, notify the dispatcher */
1.1  jruoho
1.1  jruoho         if (WalkState->AscendingCallback != NULL)
1.1  jruoho         {
1.1  jruoho             WalkState->Op = Op;
1.1  jruoho             WalkState->Opcode = Op->Common.AmlOpcode;
1.1  jruoho
1.1  jruoho             Status = WalkState->AscendingCallback (WalkState);
1.1  jruoho             Status = AcpiPsNextParseState (WalkState, Op, Status);
1.1  jruoho             if (Status == AE_CTRL_PENDING)
1.1  jruoho             {
1.1  jruoho                 Status = AE_OK;
1.1  jruoho             }
1.1  jruoho         }
1.1  jruoho
1.1  jruoho         Status = AcpiPsCompleteOp (WalkState, &Op, Status);
1.1  jruoho         if (ACPI_FAILURE (Status))
1.1  jruoho         {
1.1  jruoho             return_ACPI_STATUS (Status);
1.1  jruoho         }
1.1  jruoho
1.1  jruoho     } /* while ParserState->Aml */
1.1  jruoho
1.1  jruoho     Status = AcpiPsCompleteFinalOp (WalkState, Op, Status);
1.1  jruoho     return_ACPI_STATUS (Status);
1.1  jruoho }
1.1  jruoho