src/adsp_current_process1_stub.c - platform/external/fastrpc - Git at Google

 #ifndef _ADSP_CURRENT_PROCESS1_STUB_H
 #define _ADSP_CURRENT_PROCESS1_STUB_H
 /*
  * Copyright (c) 2019, The Linux Foundation. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met:
  *    * Redistributions of source code must retain the above copyright
  *      notice, this list of conditions and the following disclaimer.
  *    * Redistributions in binary form must reproduce the above
  *      copyright notice, this list of conditions and the following
  *      disclaimer in the documentation and/or other materials provided
  *      with the distribution.
  *    * Neither the name of The Linux Foundation nor the names of its
  *      contributors may be used to endorse or promote products derived
  *      from this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
  * ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
  * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
  * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
  * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */
 #include "adsp_current_process1.h"
 #ifndef _QAIC_ENV_H
 #define _QAIC_ENV_H

 #ifdef __GNUC__
 #ifdef __clang__
 #pragma GCC diagnostic ignored "-Wunknown-pragmas"
 #else
 #pragma GCC diagnostic ignored "-Wpragmas"
 #endif
 #pragma GCC diagnostic ignored "-Wuninitialized"
 #pragma GCC diagnostic ignored "-Wunused-parameter"
 #pragma GCC diagnostic ignored "-Wunused-function"
 #endif

 #ifndef _ATTRIBUTE_UNUSED

 #ifdef _WIN32
 #define _ATTRIBUTE_UNUSED
 #else
 #define _ATTRIBUTE_UNUSED __attribute__ ((unused))
 #endif

 #endif // _ATTRIBUTE_UNUSED

 #ifndef __QAIC_REMOTE
 #define __QAIC_REMOTE(ff) ff
 #endif //__QAIC_REMOTE

 #ifndef __QAIC_HEADER
 #define __QAIC_HEADER(ff) ff
 #endif //__QAIC_HEADER

 #ifndef __QAIC_HEADER_EXPORT
 #define __QAIC_HEADER_EXPORT
 #endif // __QAIC_HEADER_EXPORT

 #ifndef __QAIC_HEADER_ATTRIBUTE
 #define __QAIC_HEADER_ATTRIBUTE
 #endif // __QAIC_HEADER_ATTRIBUTE

 #ifndef __QAIC_IMPL
 #define __QAIC_IMPL(ff) ff
 #endif //__QAIC_IMPL

 #ifndef __QAIC_IMPL_EXPORT
 #define __QAIC_IMPL_EXPORT
 #endif // __QAIC_IMPL_EXPORT

 #ifndef __QAIC_IMPL_ATTRIBUTE
 #define __QAIC_IMPL_ATTRIBUTE
 #endif // __QAIC_IMPL_ATTRIBUTE

 #ifndef __QAIC_STUB
 #define __QAIC_STUB(ff) ff
 #endif //__QAIC_STUB

 #ifndef __QAIC_STUB_EXPORT
 #define __QAIC_STUB_EXPORT
 #endif // __QAIC_STUB_EXPORT

 #ifndef __QAIC_STUB_ATTRIBUTE
 #define __QAIC_STUB_ATTRIBUTE
 #endif // __QAIC_STUB_ATTRIBUTE

 #ifndef __QAIC_SKEL
 #define __QAIC_SKEL(ff) ff
 #endif //__QAIC_SKEL__

 #ifndef __QAIC_SKEL_EXPORT
 #define __QAIC_SKEL_EXPORT
 #endif // __QAIC_SKEL_EXPORT

 #ifndef __QAIC_SKEL_ATTRIBUTE
 #define __QAIC_SKEL_ATTRIBUTE
 #endif // __QAIC_SKEL_ATTRIBUTE

 #ifdef __QAIC_DEBUG__
    #ifndef __QAIC_DBG_PRINTF__
    #include <stdio.h>
    #define __QAIC_DBG_PRINTF__( ee ) do { printf ee ; } while(0)
    #endif
 #else
    #define __QAIC_DBG_PRINTF__( ee ) (void)0
 #endif


 #define _OFFSET(src, sof)  ((void*)(((char*)(src)) + (sof)))

 #define _COPY(dst, dof, src, sof, sz)  \
    do {\
          struct __copy { \
             char ar[sz]; \
          };\
          *(struct __copy*)_OFFSET(dst, dof) = *(struct __copy*)_OFFSET(src, sof);\
    } while (0)

 #define _COPYIF(dst, dof, src, sof, sz)  \
    do {\
       if(_OFFSET(dst, dof) != _OFFSET(src, sof)) {\
          _COPY(dst, dof, src, sof, sz); \
       } \
    } while (0)

 _ATTRIBUTE_UNUSED
 static __inline void _qaic_memmove(void* dst, void* src, int size) {
    int i;
    for(i = 0; i < size; ++i) {
       ((char*)dst)[i] = ((char*)src)[i];
    }
 }

 #define _MEMMOVEIF(dst, src, sz)  \
    do {\
       if(dst != src) {\
          _qaic_memmove(dst, src, sz);\
       } \
    } while (0)


 #define _ASSIGN(dst, src, sof)  \
    do {\
       dst = OFFSET(src, sof); \
    } while (0)

 #define _STD_STRLEN_IF(str) (str == 0 ? 0 : strlen(str))

 #include "AEEStdErr.h"

 #define _TRY(ee, func) \
    do { \
       if (AEE_SUCCESS != ((ee) = func)) {\
          __QAIC_DBG_PRINTF__((__FILE__ ":%d:error:%d:%s\n", __LINE__, (int)(ee),#func));\
          goto ee##bail;\
       } \
    } while (0)

 #define _CATCH(exception) exception##bail: if (exception != AEE_SUCCESS)

 #define _ASSERT(nErr, ff) _TRY(nErr, 0 == (ff) ? AEE_EBADPARM : AEE_SUCCESS)

 #ifdef __QAIC_DEBUG__
 #define _ALLOCATE(nErr, pal, size, alignment, pv) _TRY(nErr, _allocator_alloc(pal, __FILE_LINE__, size, alignment, (void**)&pv))
 #else
 #define _ALLOCATE(nErr, pal, size, alignment, pv) _TRY(nErr, _allocator_alloc(pal, 0, size, alignment, (void**)&pv))
 #endif


 #endif // _QAIC_ENV_H

 #include "remote.h"
 #include <string.h>
 #ifndef _ALLOCATOR_H
 #define _ALLOCATOR_H

 #include <stdlib.h>
 #include <stdint.h>

 typedef struct _heap _heap;
 struct _heap {
    _heap* pPrev;
    const char* loc;
    uint64_t buf;
 };

 typedef struct _allocator {
    _heap* pheap;
    uint8_t* stack;
    uint8_t* stackEnd;
    int nSize;
 } _allocator;

 _ATTRIBUTE_UNUSED
 static __inline int _heap_alloc(_heap** ppa, const char* loc, int size, void** ppbuf) {
    _heap* pn = 0;
    pn = malloc(size + sizeof(_heap) - sizeof(uint64_t));
    if(pn != 0) {
       pn->pPrev = *ppa;
       pn->loc = loc;
       *ppa = pn;
       *ppbuf = (void*)&(pn->buf);
       return 0;
    } else {
       return -1;
    }
 }
 #define _ALIGN_SIZE(x, y) (((x) + (y-1)) & ~(y-1))

 _ATTRIBUTE_UNUSED
 static __inline int _allocator_alloc(_allocator* me,
                                     const char* loc,
                                     int size,
                                     unsigned int al,
                                     void** ppbuf) {
    if(size < 0) {
       return -1;
    } else if (size == 0) {
       *ppbuf = 0;
       return 0;
    }
    if((_ALIGN_SIZE((uintptr_t)me->stackEnd, al) + size) < (uintptr_t)me->stack + me->nSize) {
       *ppbuf = (uint8_t*)_ALIGN_SIZE((uintptr_t)me->stackEnd, al);
       me->stackEnd = (uint8_t*)_ALIGN_SIZE((uintptr_t)me->stackEnd, al) + size;
       return 0;
    } else {
       return _heap_alloc(&me->pheap, loc, size, ppbuf);
    }
 }

 _ATTRIBUTE_UNUSED
 static __inline void _allocator_deinit(_allocator* me) {
    _heap* pa = me->pheap;
    while(pa != 0) {
       _heap* pn = pa;
       const char* loc = pn->loc;
       (void)loc;
       pa = pn->pPrev;
       free(pn);
    }
 }

 _ATTRIBUTE_UNUSED
 static __inline void _allocator_init(_allocator* me, uint8_t* stack, int stackSize) {
    me->stack =  stack;
    me->stackEnd =  stack + stackSize;
    me->nSize = stackSize;
    me->pheap = 0;
 }


 #endif // _ALLOCATOR_H

 #ifndef SLIM_H
 #define SLIM_H

 #include <stdint.h>

 //a C data structure for the idl types that can be used to implement
 //static and dynamic language bindings fairly efficiently.
 //
 //the goal is to have a minimal ROM and RAM footprint and without
 //doing too many allocations.  A good way to package these things seemed
 //like the module boundary, so all the idls within  one module can share
 //all the type references.


 #define PARAMETER_IN       0x0
 #define PARAMETER_OUT      0x1
 #define PARAMETER_INOUT    0x2
 #define PARAMETER_ROUT     0x3
 #define PARAMETER_INROUT   0x4

 //the types that we get from idl
 #define TYPE_OBJECT             0x0
 #define TYPE_INTERFACE          0x1
 #define TYPE_PRIMITIVE          0x2
 #define TYPE_ENUM               0x3
 #define TYPE_STRING             0x4
 #define TYPE_WSTRING            0x5
 #define TYPE_STRUCTURE          0x6
 #define TYPE_UNION              0x7
 #define TYPE_ARRAY              0x8
 #define TYPE_SEQUENCE           0x9

 //these require the pack/unpack to recurse
 //so it's a hint to those languages that can optimize in cases where
 //recursion isn't necessary.
 #define TYPE_COMPLEX_STRUCTURE  (0x10 | TYPE_STRUCTURE)
 #define TYPE_COMPLEX_UNION      (0x10 | TYPE_UNION)
 #define TYPE_COMPLEX_ARRAY      (0x10 | TYPE_ARRAY)
 #define TYPE_COMPLEX_SEQUENCE   (0x10 | TYPE_SEQUENCE)


 typedef struct Type Type;

 #define INHERIT_TYPE\
    int32_t nativeSize;                /*in the simple case its the same as wire size and alignment*/\
    union {\
       struct {\
          const uintptr_t         p1;\
          const uintptr_t         p2;\
       } _cast;\
       struct {\
          uint32_t  iid;\
          uint32_t  bNotNil;\
       } object;\
       struct {\
          const Type  *arrayType;\
          int32_t      nItems;\
       } array;\
       struct {\
          const Type *seqType;\
          int32_t      nMaxLen;\
       } seqSimple; \
       struct {\
          uint32_t bFloating;\
          uint32_t bSigned;\
       } prim; \
       const SequenceType* seqComplex;\
       const UnionType  *unionType;\
       const StructType *structType;\
       int32_t         stringMaxLen;\
       uint8_t        bInterfaceNotNil;\
    } param;\
    uint8_t    type;\
    uint8_t    nativeAlignment\

 typedef struct UnionType UnionType;
 typedef struct StructType StructType;
 typedef struct SequenceType SequenceType;
 struct Type {
    INHERIT_TYPE;
 };

 struct SequenceType {
    const Type *         seqType;
    uint32_t               nMaxLen;
    uint32_t               inSize;
    uint32_t               routSizePrimIn;
    uint32_t               routSizePrimROut;
 };

 //byte offset from the start of the case values for
 //this unions case value array.  it MUST be aligned
 //at the alignment requrements for the descriptor
 //
 //if negative it means that the unions cases are
 //simple enumerators, so the value read from the descriptor
 //can be used directly to find the correct case
 typedef union CaseValuePtr CaseValuePtr;
 union CaseValuePtr {
    const uint8_t*   value8s;
    const uint16_t*  value16s;
    const uint32_t*  value32s;
    const uint64_t*  value64s;
 };

 //these are only used in complex cases
 //so I pulled them out of the type definition as references to make
 //the type smaller
 struct UnionType {
    const Type           *descriptor;
    uint32_t               nCases;
    const CaseValuePtr   caseValues;
    const Type * const   *cases;
    int32_t               inSize;
    int32_t               routSizePrimIn;
    int32_t               routSizePrimROut;
    uint8_t                inAlignment;
    uint8_t                routAlignmentPrimIn;
    uint8_t                routAlignmentPrimROut;
    uint8_t                inCaseAlignment;
    uint8_t                routCaseAlignmentPrimIn;
    uint8_t                routCaseAlignmentPrimROut;
    uint8_t                nativeCaseAlignment;
    uint8_t              bDefaultCase;
 };

 struct StructType {
    uint32_t               nMembers;
    const Type * const   *members;
    int32_t               inSize;
    int32_t               routSizePrimIn;
    int32_t               routSizePrimROut;
    uint8_t                inAlignment;
    uint8_t                routAlignmentPrimIn;
    uint8_t                routAlignmentPrimROut;
 };

 typedef struct Parameter Parameter;
 struct Parameter {
    INHERIT_TYPE;
    uint8_t    mode;
    uint8_t  bNotNil;
 };

 #define SLIM_IFPTR32(is32,is64) (sizeof(uintptr_t) == 4 ? (is32) : (is64))
 #define SLIM_SCALARS_IS_DYNAMIC(u) (((u) & 0x00ffffff) == 0x00ffffff)

 typedef struct Method Method;
 struct Method {
    uint32_t                    uScalars;            //no method index
    int32_t                     primInSize;
    int32_t                     primROutSize;
    int                         maxArgs;
    int                         numParams;
    const Parameter * const     *params;
    uint8_t                       primInAlignment;
    uint8_t                       primROutAlignment;
 };

 typedef struct Interface Interface;

 struct Interface {
    int                            nMethods;
    const Method  * const          *methodArray;
    int                            nIIds;
    const uint32_t                   *iids;
    const uint16_t*                  methodStringArray;
    const uint16_t*                  methodStrings;
    const char*                    strings;
 };


 #endif //SLIM_H


 #ifndef _ADSP_CURRENT_PROCESS1_SLIM_H
 #define _ADSP_CURRENT_PROCESS1_SLIM_H
 #include "remote.h"
 #include <stdint.h>

 #ifndef __QAIC_SLIM
 #define __QAIC_SLIM(ff) ff
 #endif
 #ifndef __QAIC_SLIM_EXPORT
 #define __QAIC_SLIM_EXPORT
 #endif

 static const Type types[1];
 static const SequenceType sequenceTypes[1] = {{&(types[0]),0x0,0x4,0x4,0x0}};
 static const Type types[1] = {{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8)}};
 static const Parameter parameters[6] = {{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8),0,0},{SLIM_IFPTR32(0x4,0x8),{{(const uintptr_t)0xdeadc0de,(const uintptr_t)0}}, 0,SLIM_IFPTR32(0x4,0x8),3,0},{SLIM_IFPTR32(0x4,0x8),{{(const uintptr_t)0xdeadc0de,(const uintptr_t)0}}, 0,SLIM_IFPTR32(0x4,0x8),0,0},{0x2,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x2,0,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)&(sequenceTypes[0]),0}}, 25,SLIM_IFPTR32(0x4,0x8),0,0},{0x4,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x4,3,0}};
 static const Parameter* const parameterArrays[6] = {(&(parameters[3])),(&(parameters[4])),(&(parameters[0])),(&(parameters[1])),(&(parameters[5])),(&(parameters[2]))};
 static const Method methods[5] = {{REMOTE_SCALARS_MAKEX(0,0,0x2,0x0,0x0,0x1),0x4,0x0,2,2,(&(parameterArrays[2])),0x4,0x1},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x0,0x1,0x0),0x0,0x0,1,1,(&(parameterArrays[5])),0x1,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x0,0x0,0x0),0x0,0x0,0,0,0,0x0,0x0},{REMOTE_SCALARS_MAKEX(0,0,255,255,15,15),0x8,0x0,3,2,(&(parameterArrays[0])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x1,0x0,0x0),0x0,0x4,1,1,(&(parameterArrays[4])),0x1,0x4}};
 static const Method* const methodArrays[6] = {&(methods[0]),&(methods[1]),&(methods[2]),&(methods[2]),&(methods[3]),&(methods[4])};
 static const char strings[77] = "set_logging_params\0thread_exit\0filesToLog\0getASID\0close\0asid\0mask\0open\0uri\0h\0";
 static const uint16_t methodStrings[12] = {0,61,31,66,71,75,42,56,50,75,19,26};
 static const uint16_t methodStringsArrays[6] = {3,8,11,10,0,6};
 __QAIC_SLIM_EXPORT const Interface __QAIC_SLIM(adsp_current_process1_slim) = {6,&(methodArrays[0]),0,0,&(methodStringsArrays [0]),methodStrings,strings};
 #endif //_ADSP_CURRENT_PROCESS1_SLIM_H
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_skel_handle_invoke)(remote_handle64 _h, uint32_t _sc, remote_arg* _pra) __QAIC_STUB_ATTRIBUTE {
    return __QAIC_REMOTE(remote_handle64_invoke)(_h, _sc, _pra);
 }
 #ifdef __cplusplus
 extern "C" {
 #endif
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_open)(const char* uri, remote_handle64* h) __QAIC_STUB_ATTRIBUTE {
    return __QAIC_REMOTE(remote_handle64_open)(uri, h);
 }
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_close)(remote_handle64 h) __QAIC_STUB_ATTRIBUTE {
    return __QAIC_REMOTE(remote_handle64_close)(h);
 }
 static __inline int _stub_method(remote_handle64 _handle, uint32_t _mid) {
    remote_arg* _pra = 0;
    int _nErr = 0;
    _TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, 0, 0, 0, 0), _pra));
    _CATCH(_nErr) {}
    return _nErr;
 }
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_exit)(remote_handle64 _handle) __QAIC_STUB_ATTRIBUTE {
    uint32_t _mid = 2;
    return _stub_method(_handle, _mid);
 }
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_thread_exit)(remote_handle64 _handle) __QAIC_STUB_ATTRIBUTE {
    uint32_t _mid = 3;
    return _stub_method(_handle, _mid);
 }
 static __inline int _stub_unpack(remote_arg* _praROutPost, remote_arg* _ppraROutPost[1], void* _primROut, char* _in0[1], uint32_t _in0Len[1]) {
    int _nErr = 0;
    remote_arg* _praROutPostStart = _praROutPost;
    remote_arg** _ppraROutPostStart = _ppraROutPost;
    _ppraROutPost = &_praROutPost;
    _ppraROutPostStart[0] += (_praROutPost - _praROutPostStart) +0;
    return _nErr;
 }
 static __inline int _stub_pack(_allocator* _al, remote_arg* _praIn, remote_arg* _ppraIn[1], remote_arg* _praROut, remote_arg* _ppraROut[1], void* _primIn, void* _primROut, char* _in0[1], uint32_t _in0Len[1]) {
    int _nErr = 0;
    remote_arg* _praInStart = _praIn;
    remote_arg** _ppraInStart = _ppraIn;
    remote_arg* _praROutStart = _praROut;
    remote_arg** _ppraROutStart = _ppraROut;
    _ppraIn = &_praIn;
    _ppraROut = &_praROut;
    _in0Len[0] = (1 + strlen(_in0[0]));
    _COPY(_primIn, 0, _in0Len, 0, 4);
    _praIn[0].buf.pv = _in0[0];
    _praIn[0].buf.nLen = (1 * _in0Len[0]);
    _ppraInStart[0] += (_praIn - _praInStart) + 1;
    _ppraROutStart[0] += (_praROut - _praROutStart) +0;
    return _nErr;
 }
 static __inline void _count(int _numIn[1], int _numROut[1], char* _in0[1], uint32_t _in0Len[1]) {
    _numIn[0] += 1;
    _numROut[0] += 0;
 }
 static __inline int _stub_method_1(remote_handle64 _handle, uint32_t _mid, uint16_t _in0[1], void* _in1[1], uint32_t _in1Len[1]) {
    remote_arg* _pra;
    int _numIn[1];
    int _numROut[1];
    char* _seq_nat1;
    int _ii;
    _allocator _al[1] = {{0}};
    uint32_t _primIn[2];
    remote_arg* _praIn;
    remote_arg** _ppraIn = &_praIn;
    remote_arg* _praROut;
    remote_arg** _ppraROut = &_praROut;
    char* _seq_primIn1;
    int _nErr = 0;
    remote_arg* _praROutPost;
    remote_arg** _ppraROutPost = &_praROutPost;
    _numIn[0] = 1;
    _numROut[0] = 0;
    for(_ii = 0, _seq_nat1 = (char*)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
    {
       _count(_numIn, _numROut, SLIM_IFPTR32((char**)&(((uint32_t*)_seq_nat1)[0]), (char**)&(((uint64_t*)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t*)&(((uint32_t*)_seq_nat1)[1]), (uint32_t*)&(((uint32_t*)_seq_nat1)[2])));
    }
    _allocator_init(_al, 0, 0);
    _ALLOCATE(_nErr, _al, ((((_numIn[0] + _numROut[0]) + 1) + 0) * sizeof(_pra[0])), 4, _pra);
    _pra[0].buf.pv = (void*)_primIn;
    _pra[0].buf.nLen = sizeof(_primIn);
    _COPY(_primIn, 0, _in0, 0, 2);
    _COPY(_primIn, 4, _in1Len, 0, 4);
    _praIn = (_pra + 1);
    _praROut = (_praIn + _numIn[0] + 0);
    _ALLOCATE(_nErr, _al, (_in1Len[0] * 4), 4, _praIn[0].buf.pv);
    _praIn[0].buf.nLen = (4 * _in1Len[0]);
    for(_ii = 0, _seq_primIn1 = (char*)_praIn[0].buf.pv, _seq_nat1 = (char*)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_primIn1 = (_seq_primIn1 + 4), _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
    {
       _TRY(_nErr, _stub_pack(_al, (_praIn + 1), _ppraIn, (_praROut + 0), _ppraROut, _seq_primIn1, 0, SLIM_IFPTR32((char**)&(((uint32_t*)_seq_nat1)[0]), (char**)&(((uint64_t*)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t*)&(((uint32_t*)_seq_nat1)[1]), (uint32_t*)&(((uint32_t*)_seq_nat1)[2]))));
    }
    _TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, (_numIn[0] + 1), (_numROut[0] + 0), 0, 0), _pra));
    _praROutPost = _praROut;
    for(_ii = 0, _seq_nat1 = (char*)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
    {
       _TRY(_nErr, _stub_unpack((_praROutPost + 0), _ppraROutPost, 0, SLIM_IFPTR32((char**)&(((uint32_t*)_seq_nat1)[0]), (char**)&(((uint64_t*)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t*)&(((uint32_t*)_seq_nat1)[1]), (uint32_t*)&(((uint32_t*)_seq_nat1)[2]))));
    }
    _CATCH(_nErr) {}
    _allocator_deinit(_al);
    return _nErr;
 }
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_set_logging_params)(remote_handle64 _handle, unsigned short mask, const _cstring1_t* filesToLog, int filesToLogLen) __QAIC_STUB_ATTRIBUTE {
    uint32_t _mid = 4;
    return _stub_method_1(_handle, _mid, (uint16_t*)&mask, (void**)&filesToLog, (uint32_t*)&filesToLogLen);
 }
 static __inline int _stub_method_2(remote_handle64 _handle, uint32_t _mid, uint32_t _rout0[1]) {
    int _numIn[1];
    remote_arg _pra[1];
    uint32_t _primROut[1];
    int _nErr = 0;
    _numIn[0] = 0;
    _pra[(_numIn[0] + 0)].buf.pv = (void*)_primROut;
    _pra[(_numIn[0] + 0)].buf.nLen = sizeof(_primROut);
    _TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, 0, 1, 0, 0), _pra));
    _COPY(_rout0, 0, _primROut, 0, 4);
    _CATCH(_nErr) {}
    return _nErr;
 }
 __QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_getASID)(remote_handle64 _handle, unsigned int* asid) __QAIC_STUB_ATTRIBUTE {
    uint32_t _mid = 5;
    return _stub_method_2(_handle, _mid, (uint32_t*)asid);
 }
 #ifdef __cplusplus
 }
 #endif
 #endif //_ADSP_CURRENT_PROCESS1_STUB_H
	#ifndef _ADSP_CURRENT_PROCESS1_STUB_H
	#define _ADSP_CURRENT_PROCESS1_STUB_H
	/*
	* Copyright (c) 2019, The Linux Foundation. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the following
	* disclaimer in the documentation and/or other materials provided
	* with the distribution.
	* * Neither the name of The Linux Foundation nor the names of its
	* contributors may be used to endorse or promote products derived
	* from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
	* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
	* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
	* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
	* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/
	#include "adsp_current_process1.h"
	#ifndef _QAIC_ENV_H
	#define _QAIC_ENV_H

	#ifdef __GNUC__
	#ifdef __clang__
	#pragma GCC diagnostic ignored "-Wunknown-pragmas"
	#else
	#pragma GCC diagnostic ignored "-Wpragmas"
	#endif
	#pragma GCC diagnostic ignored "-Wuninitialized"
	#pragma GCC diagnostic ignored "-Wunused-parameter"
	#pragma GCC diagnostic ignored "-Wunused-function"
	#endif

	#ifndef _ATTRIBUTE_UNUSED

	#ifdef _WIN32
	#define _ATTRIBUTE_UNUSED
	#else
	#define _ATTRIBUTE_UNUSED __attribute__ ((unused))
	#endif

	#endif // _ATTRIBUTE_UNUSED

	#ifndef __QAIC_REMOTE
	#define __QAIC_REMOTE(ff) ff
	#endif //__QAIC_REMOTE

	#ifndef __QAIC_HEADER
	#define __QAIC_HEADER(ff) ff
	#endif //__QAIC_HEADER

	#ifndef __QAIC_HEADER_EXPORT
	#define __QAIC_HEADER_EXPORT
	#endif // __QAIC_HEADER_EXPORT

	#ifndef __QAIC_HEADER_ATTRIBUTE
	#define __QAIC_HEADER_ATTRIBUTE
	#endif // __QAIC_HEADER_ATTRIBUTE

	#ifndef __QAIC_IMPL
	#define __QAIC_IMPL(ff) ff
	#endif //__QAIC_IMPL

	#ifndef __QAIC_IMPL_EXPORT
	#define __QAIC_IMPL_EXPORT
	#endif // __QAIC_IMPL_EXPORT

	#ifndef __QAIC_IMPL_ATTRIBUTE
	#define __QAIC_IMPL_ATTRIBUTE
	#endif // __QAIC_IMPL_ATTRIBUTE

	#ifndef __QAIC_STUB
	#define __QAIC_STUB(ff) ff
	#endif //__QAIC_STUB

	#ifndef __QAIC_STUB_EXPORT
	#define __QAIC_STUB_EXPORT
	#endif // __QAIC_STUB_EXPORT

	#ifndef __QAIC_STUB_ATTRIBUTE
	#define __QAIC_STUB_ATTRIBUTE
	#endif // __QAIC_STUB_ATTRIBUTE

	#ifndef __QAIC_SKEL
	#define __QAIC_SKEL(ff) ff
	#endif //__QAIC_SKEL__

	#ifndef __QAIC_SKEL_EXPORT
	#define __QAIC_SKEL_EXPORT
	#endif // __QAIC_SKEL_EXPORT

	#ifndef __QAIC_SKEL_ATTRIBUTE
	#define __QAIC_SKEL_ATTRIBUTE
	#endif // __QAIC_SKEL_ATTRIBUTE

	#ifdef __QAIC_DEBUG__
	#ifndef __QAIC_DBG_PRINTF__
	#include <stdio.h>
	#define __QAIC_DBG_PRINTF__( ee ) do { printf ee ; } while(0)
	#endif
	#else
	#define __QAIC_DBG_PRINTF__( ee ) (void)0
	#endif


	#define _OFFSET(src, sof) ((void)(((char)(src)) + (sof)))

	#define _COPY(dst, dof, src, sof, sz) \
	do {\
	struct __copy { \
	char ar[sz]; \
	};\
	(struct __copy)_OFFSET(dst, dof) = (struct __copy)_OFFSET(src, sof);\
	} while (0)

	#define _COPYIF(dst, dof, src, sof, sz) \
	do {\
	if(_OFFSET(dst, dof) != _OFFSET(src, sof)) {\
	_COPY(dst, dof, src, sof, sz); \
	} \
	} while (0)

	_ATTRIBUTE_UNUSED
	static __inline void _qaic_memmove(void* dst, void* src, int size) {
	int i;
	for(i = 0; i < size; ++i) {
	((char)dst)[i] = ((char)src)[i];
	}
	}

	#define _MEMMOVEIF(dst, src, sz) \
	do {\
	if(dst != src) {\
	_qaic_memmove(dst, src, sz);\
	} \
	} while (0)


	#define _ASSIGN(dst, src, sof) \
	do {\
	dst = OFFSET(src, sof); \
	} while (0)

	#define _STD_STRLEN_IF(str) (str == 0 ? 0 : strlen(str))

	#include "AEEStdErr.h"

	#define _TRY(ee, func) \
	do { \
	if (AEE_SUCCESS != ((ee) = func)) {\
	__QAIC_DBG_PRINTF__((__FILE__ ":%d:error:%d:%s\n", __LINE__, (int)(ee),#func));\
	goto ee##bail;\
	} \
	} while (0)

	#define _CATCH(exception) exception##bail: if (exception != AEE_SUCCESS)

	#define _ASSERT(nErr, ff) _TRY(nErr, 0 == (ff) ? AEE_EBADPARM : AEE_SUCCESS)

	#ifdef __QAIC_DEBUG__
	#define _ALLOCATE(nErr, pal, size, alignment, pv) _TRY(nErr, _allocator_alloc(pal, __FILE_LINE__, size, alignment, (void**)&pv))
	#else
	#define _ALLOCATE(nErr, pal, size, alignment, pv) _TRY(nErr, _allocator_alloc(pal, 0, size, alignment, (void**)&pv))
	#endif


	#endif // _QAIC_ENV_H

	#include "remote.h"
	#include <string.h>
	#ifndef _ALLOCATOR_H
	#define _ALLOCATOR_H

	#include <stdlib.h>
	#include <stdint.h>

	typedef struct _heap _heap;
	struct _heap {
	_heap* pPrev;
	const char* loc;
	uint64_t buf;
	};

	typedef struct _allocator {
	_heap* pheap;
	uint8_t* stack;
	uint8_t* stackEnd;
	int nSize;
	} _allocator;

	_ATTRIBUTE_UNUSED
	static __inline int _heap_alloc(_heap** ppa, const char* loc, int size, void** ppbuf) {
	_heap* pn = 0;
	pn = malloc(size + sizeof(_heap) - sizeof(uint64_t));
	if(pn != 0) {
	pn->pPrev = *ppa;
	pn->loc = loc;
	*ppa = pn;
	ppbuf = (void)&(pn->buf);
	return 0;
	} else {
	return -1;
	}
	}
	#define _ALIGN_SIZE(x, y) (((x) + (y-1)) & ~(y-1))

	_ATTRIBUTE_UNUSED
	static __inline int _allocator_alloc(_allocator* me,
	const char* loc,
	int size,
	unsigned int al,
	void** ppbuf) {
	if(size < 0) {
	return -1;
	} else if (size == 0) {
	*ppbuf = 0;
	return 0;
	}
	if((_ALIGN_SIZE((uintptr_t)me->stackEnd, al) + size) < (uintptr_t)me->stack + me->nSize) {
	ppbuf = (uint8_t)_ALIGN_SIZE((uintptr_t)me->stackEnd, al);
	me->stackEnd = (uint8_t*)_ALIGN_SIZE((uintptr_t)me->stackEnd, al) + size;
	return 0;
	} else {
	return _heap_alloc(&me->pheap, loc, size, ppbuf);
	}
	}

	_ATTRIBUTE_UNUSED
	static __inline void _allocator_deinit(_allocator* me) {
	_heap* pa = me->pheap;
	while(pa != 0) {
	_heap* pn = pa;
	const char* loc = pn->loc;
	(void)loc;
	pa = pn->pPrev;
	free(pn);
	}
	}

	_ATTRIBUTE_UNUSED
	static __inline void _allocator_init(_allocator* me, uint8_t* stack, int stackSize) {
	me->stack = stack;
	me->stackEnd = stack + stackSize;
	me->nSize = stackSize;
	me->pheap = 0;
	}


	#endif // _ALLOCATOR_H

	#ifndef SLIM_H
	#define SLIM_H

	#include <stdint.h>

	//a C data structure for the idl types that can be used to implement
	//static and dynamic language bindings fairly efficiently.
	//
	//the goal is to have a minimal ROM and RAM footprint and without
	//doing too many allocations. A good way to package these things seemed
	//like the module boundary, so all the idls within one module can share
	//all the type references.


	#define PARAMETER_IN 0x0
	#define PARAMETER_OUT 0x1
	#define PARAMETER_INOUT 0x2
	#define PARAMETER_ROUT 0x3
	#define PARAMETER_INROUT 0x4

	//the types that we get from idl
	#define TYPE_OBJECT 0x0
	#define TYPE_INTERFACE 0x1
	#define TYPE_PRIMITIVE 0x2
	#define TYPE_ENUM 0x3
	#define TYPE_STRING 0x4
	#define TYPE_WSTRING 0x5
	#define TYPE_STRUCTURE 0x6
	#define TYPE_UNION 0x7
	#define TYPE_ARRAY 0x8
	#define TYPE_SEQUENCE 0x9

	//these require the pack/unpack to recurse
	//so it's a hint to those languages that can optimize in cases where
	//recursion isn't necessary.
	#define TYPE_COMPLEX_STRUCTURE (0x10 \| TYPE_STRUCTURE)
	#define TYPE_COMPLEX_UNION (0x10 \| TYPE_UNION)
	#define TYPE_COMPLEX_ARRAY (0x10 \| TYPE_ARRAY)
	#define TYPE_COMPLEX_SEQUENCE (0x10 \| TYPE_SEQUENCE)


	typedef struct Type Type;

	#define INHERIT_TYPE\
	int32_t nativeSize; /in the simple case its the same as wire size and alignment/\
	union {\
	struct {\
	const uintptr_t p1;\
	const uintptr_t p2;\
	} _cast;\
	struct {\
	uint32_t iid;\
	uint32_t bNotNil;\
	} object;\
	struct {\
	const Type *arrayType;\
	int32_t nItems;\
	} array;\
	struct {\
	const Type *seqType;\
	int32_t nMaxLen;\
	} seqSimple; \
	struct {\
	uint32_t bFloating;\
	uint32_t bSigned;\
	} prim; \
	const SequenceType* seqComplex;\
	const UnionType *unionType;\
	const StructType *structType;\
	int32_t stringMaxLen;\
	uint8_t bInterfaceNotNil;\
	} param;\
	uint8_t type;\
	uint8_t nativeAlignment\

	typedef struct UnionType UnionType;
	typedef struct StructType StructType;
	typedef struct SequenceType SequenceType;
	struct Type {
	INHERIT_TYPE;
	};

	struct SequenceType {
	const Type * seqType;
	uint32_t nMaxLen;
	uint32_t inSize;
	uint32_t routSizePrimIn;
	uint32_t routSizePrimROut;
	};

	//byte offset from the start of the case values for
	//this unions case value array. it MUST be aligned
	//at the alignment requrements for the descriptor
	//
	//if negative it means that the unions cases are
	//simple enumerators, so the value read from the descriptor
	//can be used directly to find the correct case
	typedef union CaseValuePtr CaseValuePtr;
	union CaseValuePtr {
	const uint8_t* value8s;
	const uint16_t* value16s;
	const uint32_t* value32s;
	const uint64_t* value64s;
	};

	//these are only used in complex cases
	//so I pulled them out of the type definition as references to make
	//the type smaller
	struct UnionType {
	const Type *descriptor;
	uint32_t nCases;
	const CaseValuePtr caseValues;
	const Type * const *cases;
	int32_t inSize;
	int32_t routSizePrimIn;
	int32_t routSizePrimROut;
	uint8_t inAlignment;
	uint8_t routAlignmentPrimIn;
	uint8_t routAlignmentPrimROut;
	uint8_t inCaseAlignment;
	uint8_t routCaseAlignmentPrimIn;
	uint8_t routCaseAlignmentPrimROut;
	uint8_t nativeCaseAlignment;
	uint8_t bDefaultCase;
	};

	struct StructType {
	uint32_t nMembers;
	const Type * const *members;
	int32_t inSize;
	int32_t routSizePrimIn;
	int32_t routSizePrimROut;
	uint8_t inAlignment;
	uint8_t routAlignmentPrimIn;
	uint8_t routAlignmentPrimROut;
	};

	typedef struct Parameter Parameter;
	struct Parameter {
	INHERIT_TYPE;
	uint8_t mode;
	uint8_t bNotNil;
	};

	#define SLIM_IFPTR32(is32,is64) (sizeof(uintptr_t) == 4 ? (is32) : (is64))
	#define SLIM_SCALARS_IS_DYNAMIC(u) (((u) & 0x00ffffff) == 0x00ffffff)

	typedef struct Method Method;
	struct Method {
	uint32_t uScalars; //no method index
	int32_t primInSize;
	int32_t primROutSize;
	int maxArgs;
	int numParams;
	const Parameter * const *params;
	uint8_t primInAlignment;
	uint8_t primROutAlignment;
	};

	typedef struct Interface Interface;

	struct Interface {
	int nMethods;
	const Method * const *methodArray;
	int nIIds;
	const uint32_t *iids;
	const uint16_t* methodStringArray;
	const uint16_t* methodStrings;
	const char* strings;
	};


	#endif //SLIM_H


	#ifndef _ADSP_CURRENT_PROCESS1_SLIM_H
	#define _ADSP_CURRENT_PROCESS1_SLIM_H
	#include "remote.h"
	#include <stdint.h>

	#ifndef __QAIC_SLIM
	#define __QAIC_SLIM(ff) ff
	#endif
	#ifndef __QAIC_SLIM_EXPORT
	#define __QAIC_SLIM_EXPORT
	#endif

	static const Type types[1];
	static const SequenceType sequenceTypes[1] = {{&(types[0]),0x0,0x4,0x4,0x0}};
	static const Type types[1] = {{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8)}};
	static const Parameter parameters[6] = {{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8),0,0},{SLIM_IFPTR32(0x4,0x8),{{(const uintptr_t)0xdeadc0de,(const uintptr_t)0}}, 0,SLIM_IFPTR32(0x4,0x8),3,0},{SLIM_IFPTR32(0x4,0x8),{{(const uintptr_t)0xdeadc0de,(const uintptr_t)0}}, 0,SLIM_IFPTR32(0x4,0x8),0,0},{0x2,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x2,0,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)&(sequenceTypes[0]),0}}, 25,SLIM_IFPTR32(0x4,0x8),0,0},{0x4,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x4,3,0}};
	static const Parameter* const parameterArrays[6] = {(&(parameters[3])),(&(parameters[4])),(&(parameters[0])),(&(parameters[1])),(&(parameters[5])),(&(parameters[2]))};
	static const Method methods[5] = {{REMOTE_SCALARS_MAKEX(0,0,0x2,0x0,0x0,0x1),0x4,0x0,2,2,(&(parameterArrays[2])),0x4,0x1},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x0,0x1,0x0),0x0,0x0,1,1,(&(parameterArrays[5])),0x1,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x0,0x0,0x0),0x0,0x0,0,0,0,0x0,0x0},{REMOTE_SCALARS_MAKEX(0,0,255,255,15,15),0x8,0x0,3,2,(&(parameterArrays[0])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x0,0x1,0x0,0x0),0x0,0x4,1,1,(&(parameterArrays[4])),0x1,0x4}};
	static const Method* const methodArrays[6] = {&(methods[0]),&(methods[1]),&(methods[2]),&(methods[2]),&(methods[3]),&(methods[4])};
	static const char strings[77] = "set_logging_params\0thread_exit\0filesToLog\0getASID\0close\0asid\0mask\0open\0uri\0h\0";
	static const uint16_t methodStrings[12] = {0,61,31,66,71,75,42,56,50,75,19,26};
	static const uint16_t methodStringsArrays[6] = {3,8,11,10,0,6};
	__QAIC_SLIM_EXPORT const Interface __QAIC_SLIM(adsp_current_process1_slim) = {6,&(methodArrays[0]),0,0,&(methodStringsArrays [0]),methodStrings,strings};
	#endif //_ADSP_CURRENT_PROCESS1_SLIM_H
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_skel_handle_invoke)(remote_handle64 _h, uint32_t _sc, remote_arg* _pra) __QAIC_STUB_ATTRIBUTE {
	return __QAIC_REMOTE(remote_handle64_invoke)(_h, _sc, _pra);
	}
	#ifdef __cplusplus
	extern "C" {
	#endif
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_open)(const char* uri, remote_handle64* h) __QAIC_STUB_ATTRIBUTE {
	return __QAIC_REMOTE(remote_handle64_open)(uri, h);
	}
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_close)(remote_handle64 h) __QAIC_STUB_ATTRIBUTE {
	return __QAIC_REMOTE(remote_handle64_close)(h);
	}
	static __inline int _stub_method(remote_handle64 _handle, uint32_t _mid) {
	remote_arg* _pra = 0;
	int _nErr = 0;
	_TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, 0, 0, 0, 0), _pra));
	_CATCH(_nErr) {}
	return _nErr;
	}
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_exit)(remote_handle64 _handle) __QAIC_STUB_ATTRIBUTE {
	uint32_t _mid = 2;
	return _stub_method(_handle, _mid);
	}
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_thread_exit)(remote_handle64 _handle) __QAIC_STUB_ATTRIBUTE {
	uint32_t _mid = 3;
	return _stub_method(_handle, _mid);
	}
	static __inline int _stub_unpack(remote_arg* _praROutPost, remote_arg* _ppraROutPost[1], void* _primROut, char* _in0[1], uint32_t _in0Len[1]) {
	int _nErr = 0;
	remote_arg* _praROutPostStart = _praROutPost;
	remote_arg** _ppraROutPostStart = _ppraROutPost;
	_ppraROutPost = &_praROutPost;
	_ppraROutPostStart[0] += (_praROutPost - _praROutPostStart) +0;
	return _nErr;
	}
	static __inline int _stub_pack(_allocator* _al, remote_arg* _praIn, remote_arg* _ppraIn[1], remote_arg* _praROut, remote_arg* _ppraROut[1], void* _primIn, void* _primROut, char* _in0[1], uint32_t _in0Len[1]) {
	int _nErr = 0;
	remote_arg* _praInStart = _praIn;
	remote_arg** _ppraInStart = _ppraIn;
	remote_arg* _praROutStart = _praROut;
	remote_arg** _ppraROutStart = _ppraROut;
	_ppraIn = &_praIn;
	_ppraROut = &_praROut;
	_in0Len[0] = (1 + strlen(_in0[0]));
	_COPY(_primIn, 0, _in0Len, 0, 4);
	_praIn[0].buf.pv = _in0[0];
	_praIn[0].buf.nLen = (1 * _in0Len[0]);
	_ppraInStart[0] += (_praIn - _praInStart) + 1;
	_ppraROutStart[0] += (_praROut - _praROutStart) +0;
	return _nErr;
	}
	static __inline void _count(int _numIn[1], int _numROut[1], char* _in0[1], uint32_t _in0Len[1]) {
	_numIn[0] += 1;
	_numROut[0] += 0;
	}
	static __inline int _stub_method_1(remote_handle64 _handle, uint32_t _mid, uint16_t _in0[1], void* _in1[1], uint32_t _in1Len[1]) {
	remote_arg* _pra;
	int _numIn[1];
	int _numROut[1];
	char* _seq_nat1;
	int _ii;
	_allocator _al[1] = {{0}};
	uint32_t _primIn[2];
	remote_arg* _praIn;
	remote_arg** _ppraIn = &_praIn;
	remote_arg* _praROut;
	remote_arg** _ppraROut = &_praROut;
	char* _seq_primIn1;
	int _nErr = 0;
	remote_arg* _praROutPost;
	remote_arg** _ppraROutPost = &_praROutPost;
	_numIn[0] = 1;
	_numROut[0] = 0;
	for(_ii = 0, _seq_nat1 = (char*)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
	{
	_count(_numIn, _numROut, SLIM_IFPTR32((char*)&(((uint32_t)_seq_nat1)[0]), (char*)&(((uint64_t)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t)&(((uint32_t)_seq_nat1)[1]), (uint32_t)&(((uint32_t)_seq_nat1)[2])));
	}
	_allocator_init(_al, 0, 0);
	_ALLOCATE(_nErr, _al, ((((_numIn[0] + _numROut[0]) + 1) + 0) * sizeof(_pra[0])), 4, _pra);
	_pra[0].buf.pv = (void*)_primIn;
	_pra[0].buf.nLen = sizeof(_primIn);
	_COPY(_primIn, 0, _in0, 0, 2);
	_COPY(_primIn, 4, _in1Len, 0, 4);
	_praIn = (_pra + 1);
	_praROut = (_praIn + _numIn[0] + 0);
	_ALLOCATE(_nErr, _al, (_in1Len[0] * 4), 4, _praIn[0].buf.pv);
	_praIn[0].buf.nLen = (4 * _in1Len[0]);
	for(_ii = 0, _seq_primIn1 = (char)_praIn[0].buf.pv, _seq_nat1 = (char)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_primIn1 = (_seq_primIn1 + 4), _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
	{
	_TRY(_nErr, _stub_pack(_al, (_praIn + 1), _ppraIn, (_praROut + 0), _ppraROut, _seq_primIn1, 0, SLIM_IFPTR32((char*)&(((uint32_t)_seq_nat1)[0]), (char*)&(((uint64_t)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t)&(((uint32_t)_seq_nat1)[1]), (uint32_t)&(((uint32_t)_seq_nat1)[2]))));
	}
	_TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, (_numIn[0] + 1), (_numROut[0] + 0), 0, 0), _pra));
	_praROutPost = _praROut;
	for(_ii = 0, _seq_nat1 = (char*)_in1[0];_ii < (int)_in1Len[0];++_ii, _seq_nat1 = (_seq_nat1 + SLIM_IFPTR32(8, 16)))
	{
	_TRY(_nErr, _stub_unpack((_praROutPost + 0), _ppraROutPost, 0, SLIM_IFPTR32((char*)&(((uint32_t)_seq_nat1)[0]), (char*)&(((uint64_t)_seq_nat1)[0])), SLIM_IFPTR32((uint32_t)&(((uint32_t)_seq_nat1)[1]), (uint32_t)&(((uint32_t)_seq_nat1)[2]))));
	}
	_CATCH(_nErr) {}
	_allocator_deinit(_al);
	return _nErr;
	}
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_set_logging_params)(remote_handle64 _handle, unsigned short mask, const _cstring1_t* filesToLog, int filesToLogLen) __QAIC_STUB_ATTRIBUTE {
	uint32_t _mid = 4;
	return _stub_method_1(_handle, _mid, (uint16_t)&mask, (void)&filesToLog, (uint32_t)&filesToLogLen);
	}
	static __inline int _stub_method_2(remote_handle64 _handle, uint32_t _mid, uint32_t _rout0[1]) {
	int _numIn[1];
	remote_arg _pra[1];
	uint32_t _primROut[1];
	int _nErr = 0;
	_numIn[0] = 0;
	_pra[(_numIn[0] + 0)].buf.pv = (void*)_primROut;
	_pra[(_numIn[0] + 0)].buf.nLen = sizeof(_primROut);
	_TRY(_nErr, __QAIC_REMOTE(remote_handle64_invoke)(_handle, REMOTE_SCALARS_MAKEX(0, _mid, 0, 1, 0, 0), _pra));
	_COPY(_rout0, 0, _primROut, 0, 4);
	_CATCH(_nErr) {}
	return _nErr;
	}
	__QAIC_STUB_EXPORT int __QAIC_STUB(adsp_current_process1_getASID)(remote_handle64 _handle, unsigned int* asid) __QAIC_STUB_ATTRIBUTE {
	uint32_t _mid = 5;
	return _stub_method_2(_handle, _mid, (uint32_t*)asid);
	}
	#ifdef __cplusplus
	}
	#endif
	#endif //_ADSP_CURRENT_PROCESS1_STUB_H