#ifndef _APPS_STD_SKEL_H #define _APPS_STD_SKEL_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 "apps_std.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 #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 #ifndef _ALLOCATOR_H #define _ALLOCATOR_H #include #include 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 //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 _APPS_STD_SLIM_H #define _APPS_STD_SLIM_H #include "remote.h" #include #ifndef __QAIC_SLIM #define __QAIC_SLIM(ff) ff #endif #ifndef __QAIC_SLIM_EXPORT #define __QAIC_SLIM_EXPORT #endif static const Type types[7]; static const Type* const typeArrays[15] = {&(types[2]),&(types[2]),&(types[2]),&(types[5]),&(types[5]),&(types[2]),&(types[2]),&(types[6]),&(types[6]),&(types[6]),&(types[6]),&(types[6]),&(types[6]),&(types[3]),&(types[4])}; static const StructType structTypes[3] = {{0x1,&(typeArrays[0]),0x8,0x0,0x8,0x8,0x1,0x8},{0x2,&(typeArrays[13]),0x104,0x0,0x104,0x4,0x1,0x4},{0xd,&(typeArrays[0]),0x60,0x0,0x60,0x8,0x1,0x8}}; static const SequenceType sequenceTypes[1] = {{&(types[1]),0x0,0x4,0x4,0x0}}; static const Type types[7] = {{0x1,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x1},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8)},{0x8,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x8},{0x4,{{(const uintptr_t)0,(const uintptr_t)1}}, 2,0x4},{0xff,{{(const uintptr_t)&(types[0]),(const uintptr_t)0xff}}, 8,0x1},{0x4,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x4},{0x8,{{(const uintptr_t)0,(const uintptr_t)1}}, 2,0x8}}; static const Parameter parameters[16] = {{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8),0,0},{0x4,{{(const uintptr_t)0,(const uintptr_t)1}}, 2,0x4,3,0},{0x4,{{(const uintptr_t)0,(const uintptr_t)1}}, 2,0x4,0,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)&(types[0]),(const uintptr_t)0x0}}, 9,SLIM_IFPTR32(0x4,0x8),3,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)&(types[0]),(const uintptr_t)0x0}}, 9,SLIM_IFPTR32(0x4,0x8),0,0},{0x4,{{0,0}}, 3,0x4,0,0},{0x8,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x8,3,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)0x0,0}}, 4,SLIM_IFPTR32(0x4,0x8),3,0},{SLIM_IFPTR32(0x8,0x10),{{(const uintptr_t)&(sequenceTypes[0]),0}}, 25,SLIM_IFPTR32(0x4,0x8),3,0},{0x4,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x4,3,0},{0x2,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x2,3,0},{0x1,{{(const uintptr_t)0,(const uintptr_t)0}}, 2,0x1,3,0},{0x8,{{(const uintptr_t)&(structTypes[0]),0}}, 6,0x8,3,0},{0x8,{{(const uintptr_t)&(structTypes[0]),0}}, 6,0x8,0,0},{0x104,{{(const uintptr_t)&(structTypes[1]),0}}, 6,0x4,3,0},{0x60,{{(const uintptr_t)&(structTypes[2]),0}}, 6,0x8,3,0}}; static const Parameter* const parameterArrays[44] = {(&(parameters[0])),(&(parameters[0])),(&(parameters[8])),(&(parameters[9])),(&(parameters[10])),(&(parameters[0])),(&(parameters[0])),(&(parameters[0])),(&(parameters[0])),(&(parameters[1])),(&(parameters[2])),(&(parameters[4])),(&(parameters[1])),(&(parameters[1])),(&(parameters[2])),(&(parameters[3])),(&(parameters[1])),(&(parameters[1])),(&(parameters[2])),(&(parameters[0])),(&(parameters[0])),(&(parameters[1])),(&(parameters[13])),(&(parameters[14])),(&(parameters[1])),(&(parameters[0])),(&(parameters[0])),(&(parameters[2])),(&(parameters[0])),(&(parameters[7])),(&(parameters[1])),(&(parameters[2])),(&(parameters[2])),(&(parameters[5])),(&(parameters[0])),(&(parameters[15])),(&(parameters[0])),(&(parameters[12])),(&(parameters[0])),(&(parameters[11])),(&(parameters[2])),(&(parameters[6])),(&(parameters[2])),(&(parameters[1]))}; static const Method methods[23] = {{REMOTE_SCALARS_MAKEX(0,0,0x3,0x1,0x0,0x0),0x8,0x4,3,3,(&(parameterArrays[7])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x3,0x1,0x0,0x0),0xc,0x4,4,4,(&(parameterArrays[18])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x0,0x0,0x0),0x4,0x0,1,1,(&(parameterArrays[10])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x2,0x0,0x0),0x8,0x8,6,4,(&(parameterArrays[14])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x1,0x0,0x0),0x8,0x8,5,4,(&(parameterArrays[10])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x2,0x0,0x0),0x8,0x4,5,3,(&(parameterArrays[14])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x0,0x0,0x0),0x8,0x0,3,2,(&(parameterArrays[10])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x1,0x0,0x0),0x4,0x4,2,2,(&(parameterArrays[42])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x0,0x0,0x0),0xc,0x0,3,3,(&(parameterArrays[31])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x1,0x0,0x0),0x4,0x8,2,2,(&(parameterArrays[40])),0x4,0x8},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x0,0x0,0x0),0x4,0x0,1,1,(&(parameterArrays[0])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x2,0x0,0x0),0x8,0x4,5,3,(&(parameterArrays[28])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x3,0x0,0x0,0x0),0xc,0x0,3,3,(&(parameterArrays[25])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x5,0x1,0x0,0x0),0x10,0x4,5,5,(&(parameterArrays[5])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,255,255,15,15),0xc,0x6,7,5,(&(parameterArrays[0])),0x4,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x1,0x0,0x0),0x4,0x1,2,2,(&(parameterArrays[38])),0x4,0x1},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x1,0x0,0x0),0x4,0x8,2,2,(&(parameterArrays[36])),0x4,0x8},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x0,0x0,0x0),0x8,0x0,1,1,(&(parameterArrays[22])),0x8,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x1,0x0,0x0),0x8,0x108,3,3,(&(parameterArrays[22])),0x8,0x4},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x0,0x0,0x0),0x8,0x0,2,2,(&(parameterArrays[26])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x2,0x1,0x0,0x0),0x4,0x60,2,2,(&(parameterArrays[34])),0x4,0x8},{REMOTE_SCALARS_MAKEX(0,0,0x1,0x0,0x0,0x0),0x8,0x0,2,2,(&(parameterArrays[31])),0x4,0x0},{REMOTE_SCALARS_MAKEX(0,0,0x3,0x0,0x0,0x0),0x8,0x0,2,2,(&(parameterArrays[0])),0x4,0x0}}; static const Method* const methodArrays[34] = {&(methods[0]),&(methods[1]),&(methods[2]),&(methods[2]),&(methods[3]),&(methods[4]),&(methods[5]),&(methods[6]),&(methods[7]),&(methods[8]),&(methods[9]),&(methods[2]),&(methods[7]),&(methods[7]),&(methods[2]),&(methods[10]),&(methods[11]),&(methods[12]),&(methods[10]),&(methods[13]),&(methods[5]),&(methods[14]),&(methods[15]),&(methods[2]),&(methods[10]),&(methods[7]),&(methods[16]),&(methods[17]),&(methods[18]),&(methods[19]),&(methods[10]),&(methods[20]),&(methods[21]),&(methods[22])}; static const char strings[530] = "get_search_paths_with_env\0fdopen_decrypt\0fopen_with_env\0print_string\0bytesWritten\0fileExists\0maxPathLen\0envvarname\0ctimensec\0mtimensec\0atimensec\0valLenReq\0posLenReq\0bytesRead\0closedir\0numPaths\0unsetenv\0override\0clearerr\0newname\0oldname\0frename\0readdir\0opendir\0fremove\0fsetpos\0fgetpos\0freopen\0ftrunc\0dirent\0handle\0exists\0getenv\0ferror\0rewind\0whence\0offset\0fwrite\0fclose\0fflush\0ctime\0mtime\0atime\0nlink\0rmdir\0mkdir\0fsync\0paths\0fgets\0delim\0fseek\0ftell\0fread\0psout\0fopen\0size\0rdev\0stat\0path\0feof\0flen\0bEOF\0mode\0tsz\0ino\0val\0str\0buf\0sin\0"; static const uint16_t methodStrings[129] = {476,110,476,506,472,510,501,394,471,466,388,135,382,125,376,115,244,180,306,299,510,110,496,0,104,430,418,184,93,41,104,430,110,501,454,355,526,522,69,496,448,526,522,165,496,284,526,110,501,454,252,110,180,306,424,526,522,496,195,110,514,202,320,110,514,145,436,526,348,341,276,526,272,155,460,110,501,454,236,228,220,292,526,348,406,110,501,175,180,306,26,526,454,82,481,313,327,526,216,486,526,496,491,526,492,442,526,272,268,526,272,400,110,260,110,412,526,193,110,56,518,211,526,334,526,362,526,369,526}; static const uint16_t methodStringsArrays[34] = {74,45,127,125,40,35,70,108,105,66,102,123,99,96,121,119,62,58,117,29,54,23,93,115,113,90,50,87,16,84,111,0,81,78}; __QAIC_SLIM_EXPORT const Interface __QAIC_SLIM(apps_std_slim) = {34,&(methodArrays[0]),0,0,&(methodStringsArrays [0]),methodStrings,strings}; #endif //_APPS_STD_SLIM_H extern int adsp_mmap_fd_getinfo(int, uint32_t *); #ifdef __cplusplus extern "C" { #endif static __inline int _skel_method(int (*_pfn)(char*, char*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _in1[1]; uint32_t _in1Len[1]; char* _in2[1]; uint32_t _in2Len[1]; uint32_t* _primIn; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((3 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _COPY(_in2Len, 0, _primIn, 8, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in2Len[0])); _in2[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in2Len[0] > 0) && (_in2[0][(_in2Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in1, *_in2)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_1(int (*_pfn)(uint32_t, uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; uint32_t _in1[1]; uint32_t _in2[1]; uint32_t* _primIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1, 0, _primIn, 4, 4); _COPY(_in2, 0, _primIn, 8, 4); _TRY(_nErr, _pfn(*_in1, *_in2)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_2(int (*_pfn)(char*, uint64_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _in1[1]; uint32_t _in1Len[1]; uint64_t _rout2[12]; uint32_t* _primIn; int _numIn[1]; uint64_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 96); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in1, _rout2)); _COPY(_primROut, 0, _rout2, 0, 96); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_invoke(uint32_t _mid, uint32_t _sc, remote_arg* _pra) { switch(_mid) { case 31: return _skel_method_2((void*)__QAIC_IMPL(apps_std_stat), _sc, _pra); case 32: return _skel_method_1((void*)__QAIC_IMPL(apps_std_ftrunc), _sc, _pra); case 33: return _skel_method((void*)__QAIC_IMPL(apps_std_frename), _sc, _pra); } return AEE_EUNSUPPORTED; } static __inline int _skel_method_3(int (*_pfn)(char*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; uint32_t* _primIn; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_4(int (*_pfn)(char*, uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; uint32_t _in1[1]; uint32_t* _primIn; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_in1, 0, _primIn, 4, 4); _TRY(_nErr, _pfn(*_in0, *_in1)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_5(int (*_pfn)(uint64_t*, uint32_t*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint64_t _in0[1]; uint32_t _rout1[65]; uint32_t _rout2[1]; uint64_t* _primIn; int _numIn[1]; uint32_t* _primROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 264); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 8); _TRY(_nErr, _pfn(_in0, _rout1, _rout2)); _COPY(_primROut, 0, _rout1, 0, 260); _COPY(_primROut, 260, _rout2, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_6(int (*_pfn)(uint64_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint64_t _in0[1]; uint64_t* _primIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 8); _TRY(_nErr, _pfn(_in0)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_7(int (*_pfn)(char*, uint64_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; uint64_t _rout1[1]; uint32_t* _primIn; int _numIn[1]; uint64_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 8); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0, _rout1)); _COPY(_primROut, 0, _rout1, 0, 8); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_8(int (*_pfn)(uint32_t, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; uint32_t _rout1[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _TRY(_nErr, _pfn(*_in0, _rout1)); _COPY(_primROut, 0, _rout1, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_9(int (*_pfn)(uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; uint32_t* _primIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _TRY(_nErr, _pfn(*_in0)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_10(int (*_pfn)(char*, uint8_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; uint8_t _rout1[1]; uint32_t* _primIn; int _numIn[1]; uint8_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 1); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0, _rout1)); _COPY(_primROut, 0, _rout1, 0, 1); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_pack(remote_arg* _praROutPost, remote_arg* _ppraROutPost[1], void* _primROut, char* _rout0[1], uint32_t _rout0Len[1]) { int _nErr = 0; remote_arg* _praROutPostStart = _praROutPost; remote_arg** _ppraROutPostStart = _ppraROutPost; _ppraROutPost = &_praROutPost; _ppraROutPostStart[0] += (_praROutPost - _praROutPostStart) +1; return _nErr; } static __inline int _skel_unpack(_allocator* _al, remote_arg* _praIn, remote_arg* _ppraIn[1], remote_arg* _praROut, remote_arg* _ppraROut[1], remote_arg* _praHIn, remote_arg* _ppraHIn[1], remote_arg* _praHROut, remote_arg* _ppraHROut[1], void* _primIn, void* _primROut, char* _rout0[1], uint32_t _rout0Len[1]) { int _nErr = 0; remote_arg* _praInStart = _praIn; remote_arg** _ppraInStart = _ppraIn; remote_arg* _praROutStart = _praROut; remote_arg** _ppraROutStart = _ppraROut; _ppraIn = &_praIn; _ppraROut = &_praROut; _COPY(_rout0Len, 0, _primIn, 0, 4); _ASSERT(_nErr, (int)((_praROut[0].buf.nLen / 1)) >= (int)(_rout0Len[0])); _rout0[0] = _praROut[0].buf.pv; _ppraInStart[0] += (_praIn - _praInStart) + 0; _ppraROutStart[0] += (_praROut - _praROutStart) +1; _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_11(int (*_pfn)(char*, char*, void*, uint32_t, uint32_t*, uint16_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; char* _in1[1]; uint32_t _in1Len[1]; void* _rout2[1]; uint32_t _rout2Len[1]; uint32_t _rout3[1]; uint16_t _rout4[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; int _numInH[1]; int _numROut[1]; remote_arg* _praIn; remote_arg* _praROut; remote_arg* _praROutPost; remote_arg** _ppraROutPost = &_praROutPost; _allocator _al[1] = {{0}}; remote_arg** _ppraIn = &_praIn; remote_arg** _ppraROut = &_praROut; remote_arg* _praHIn = 0; remote_arg** _ppraHIn = &_praHIn; remote_arg* _praHROut = 0; remote_arg** _ppraHROut = &_praHROut; char* _seq_primIn2; char* _seq_nat2; int _ii; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((4 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 6); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _numInH[0] = REMOTE_SCALARS_INHANDLES(_sc); _numROut[0] = REMOTE_SCALARS_OUTBUFS(_sc); _praIn = (_pra + 1); _praROut = (_praIn + _numIn[0] + 1); _praROutPost = _praROut; _COPY(_in0Len, 0, _primIn, 0, 4); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_in1Len, 0, _primIn, 4, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _COPY(_rout2Len, 0, _primIn, 8, 4); _allocator_init(_al, 0, 0); if(_praHIn == 0) { _praHIn = ((_praROut + _numROut[0]) + 1); } if(_praHROut == 0) (_praHROut = _praHIn + _numInH[0] + 0); _ASSERT(_nErr, (int)((_praIn[2].buf.nLen / 4)) >= (int)(_rout2Len[0])); _ALLOCATE(_nErr, _al, (_rout2Len[0] * SLIM_IFPTR32(8, 16)), SLIM_IFPTR32(4, 8), _rout2[0]); for(_ii = 0, _seq_primIn2 = (char*)_praIn[2].buf.pv, _seq_nat2 = (char*)_rout2[0];_ii < (int)_rout2Len[0];++_ii, _seq_primIn2 = (_seq_primIn2 + 4), _seq_nat2 = (_seq_nat2 + SLIM_IFPTR32(8, 16))) { _TRY(_nErr, _skel_unpack(_al, (_praIn + 3), _ppraIn, (_praROut + 0), _ppraROut, _praHIn, _ppraHIn, _praHROut, _ppraHROut, _seq_primIn2, 0, SLIM_IFPTR32((char**)&(((uint32_t*)_seq_nat2)[0]), (char**)&(((uint64_t*)_seq_nat2)[0])), SLIM_IFPTR32((uint32_t*)&(((uint32_t*)_seq_nat2)[1]), (uint32_t*)&(((uint32_t*)_seq_nat2)[2])))); } _TRY(_nErr, _pfn(*_in0, *_in1, *_rout2, *_rout2Len, _rout3, _rout4)); for(_ii = 0, _seq_nat2 = (char*)_rout2[0];_ii < (int)_rout2Len[0];++_ii, _seq_nat2 = (_seq_nat2 + SLIM_IFPTR32(8, 16))) { _TRY(_nErr, _skel_pack((_praROutPost + 0), _ppraROutPost, 0, SLIM_IFPTR32((char**)&(((uint32_t*)_seq_nat2)[0]), (char**)&(((uint64_t*)_seq_nat2)[0])), SLIM_IFPTR32((uint32_t*)&(((uint32_t*)_seq_nat2)[1]), (uint32_t*)&(((uint32_t*)_seq_nat2)[2])))); } _COPY(_primROut, 0, _rout3, 0, 4); _COPY(_primROut, 4, _rout4, 0, 2); _CATCH(_nErr) {} _allocator_deinit(_al); return _nErr; } static __inline int _skel_method_12(int (*_pfn)(uint32_t, char*, uint32_t, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _rout1[1]; uint32_t _rout1Len[1]; uint32_t _rout2[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; remote_arg* _praROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 2) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_rout1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _praROut = (_praIn + _numIn[0] + 1); _ASSERT(_nErr, (int)((_praROut[0].buf.nLen / 1)) >= (int)(_rout1Len[0])); _rout1[0] = _praROut[0].buf.pv; _TRY(_nErr, _pfn(*_in0, *_rout1, *_rout1Len, _rout2)); _COPY(_primROut, 0, _rout2, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_13(int (*_pfn)(char*, char*, char*, char*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; char* _in1[1]; uint32_t _in1Len[1]; char* _in2[1]; uint32_t _in2Len[1]; char* _in3[1]; uint32_t _in3Len[1]; uint32_t _rout4[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((5 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 16); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_in1Len, 0, _primIn, 4, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _COPY(_in2Len, 0, _primIn, 8, 4); _ASSERT(_nErr, (int)((_praIn[2].buf.nLen / 1)) >= (int)(_in2Len[0])); _in2[0] = _praIn[2].buf.pv; _ASSERT(_nErr, (_in2Len[0] > 0) && (_in2[0][(_in2Len[0] - 1)] == 0)); _COPY(_in3Len, 0, _primIn, 12, 4); _ASSERT(_nErr, (int)((_praIn[3].buf.nLen / 1)) >= (int)(_in3Len[0])); _in3[0] = _praIn[3].buf.pv; _ASSERT(_nErr, (_in3Len[0] > 0) && (_in3[0][(_in3Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0, *_in1, *_in2, *_in3, _rout4)); _COPY(_primROut, 0, _rout4, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_14(int (*_pfn)(char*, char*, uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; char* _in1[1]; uint32_t _in1Len[1]; uint32_t _in2[1]; uint32_t* _primIn; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((3 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_in1Len, 0, _primIn, 4, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _COPY(_in2, 0, _primIn, 8, 4); _TRY(_nErr, _pfn(*_in0, *_in1, *_in2)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_15(int (*_pfn)(char*, char*, uint32_t, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; char* _rout1[1]; uint32_t _rout1Len[1]; uint32_t _rout2[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; remote_arg* _praROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 2) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_rout1Len, 0, _primIn, 4, 4); _praROut = (_praIn + _numIn[0] + 1); _ASSERT(_nErr, (int)((_praROut[0].buf.nLen / 1)) >= (int)(_rout1Len[0])); _rout1[0] = _praROut[0].buf.pv; _TRY(_nErr, _pfn(*_in0, *_rout1, *_rout1Len, _rout2)); _COPY(_primROut, 0, _rout2, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_16(int (*_pfn)(uint32_t, uint64_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; uint64_t _rout1[1]; uint32_t* _primIn; int _numIn[1]; uint64_t* _primROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 4); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 8); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _TRY(_nErr, _pfn(*_in0, _rout1)); _COPY(_primROut, 0, _rout1, 0, 8); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_17(int (*_pfn)(uint32_t, uint32_t, uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; uint32_t _in1[1]; uint32_t _in2[1]; uint32_t* _primIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1, 0, _primIn, 4, 4); _COPY(_in2, 0, _primIn, 8, 4); _TRY(_nErr, _pfn(*_in0, *_in1, *_in2)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_18(int (*_pfn)(uint32_t, char*, uint32_t), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _in1[1]; uint32_t _in1Len[1]; uint32_t* _primIn; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 0) + (((0 + 0) + 0) + 0))) <= _praEnd); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[0].buf.pv; _TRY(_nErr, _pfn(*_in0, *_in1, *_in1Len)); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_19(int (*_pfn)(uint32_t, char*, uint32_t, uint32_t*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _in1[1]; uint32_t _in1Len[1]; uint32_t _rout2[1]; uint32_t _rout3[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((2 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 8); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[0].buf.pv; _TRY(_nErr, _pfn(*_in0, *_in1, *_in1Len, _rout2, _rout3)); _COPY(_primROut, 0, _rout2, 0, 4); _COPY(_primROut, 4, _rout3, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_20(int (*_pfn)(uint32_t, char*, uint32_t, uint32_t*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _rout1[1]; uint32_t _rout1Len[1]; uint32_t _rout2[1]; uint32_t _rout3[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; remote_arg* _praROut; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((1 + 2) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 8); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_rout1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _praROut = (_praIn + _numIn[0] + 1); _ASSERT(_nErr, (int)((_praROut[0].buf.nLen / 1)) >= (int)(_rout1Len[0])); _rout1[0] = _praROut[0].buf.pv; _TRY(_nErr, _pfn(*_in0, *_rout1, *_rout1Len, _rout2, _rout3)); _COPY(_primROut, 0, _rout2, 0, 4); _COPY(_primROut, 4, _rout3, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_21(int (*_pfn)(uint32_t, char*, char*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; uint32_t _in0[1]; char* _in1[1]; uint32_t _in1Len[1]; char* _in2[1]; uint32_t _in2Len[1]; uint32_t _rout3[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((3 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 12); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0, 0, _primIn, 0, 4); _COPY(_in1Len, 0, _primIn, 4, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _COPY(_in2Len, 0, _primIn, 8, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in2Len[0])); _in2[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in2Len[0] > 0) && (_in2[0][(_in2Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0, *_in1, *_in2, _rout3)); _COPY(_primROut, 0, _rout3, 0, 4); _CATCH(_nErr) {} return _nErr; } static __inline int _skel_method_22(int (*_pfn)(char*, char*, uint32_t*), uint32_t _sc, remote_arg* _pra) { remote_arg* _praEnd; char* _in0[1]; uint32_t _in0Len[1]; char* _in1[1]; uint32_t _in1Len[1]; uint32_t _rout2[1]; uint32_t* _primIn; int _numIn[1]; uint32_t* _primROut; remote_arg* _praIn; int _nErr = 0; _praEnd = ((_pra + REMOTE_SCALARS_INBUFS(_sc)) + REMOTE_SCALARS_OUTBUFS(_sc) + REMOTE_SCALARS_INHANDLES(_sc) + REMOTE_SCALARS_OUTHANDLES(_sc)); _ASSERT(_nErr, (_pra + ((3 + 1) + (((0 + 0) + 0) + 0))) <= _praEnd); _numIn[0] = (REMOTE_SCALARS_INBUFS(_sc) - 1); _ASSERT(_nErr, _pra[0].buf.nLen >= 8); _primIn = _pra[0].buf.pv; _ASSERT(_nErr, _pra[(_numIn[0] + 1)].buf.nLen >= 4); _primROut = _pra[(_numIn[0] + 1)].buf.pv; _COPY(_in0Len, 0, _primIn, 0, 4); _praIn = (_pra + 1); _ASSERT(_nErr, (int)((_praIn[0].buf.nLen / 1)) >= (int)(_in0Len[0])); _in0[0] = _praIn[0].buf.pv; _ASSERT(_nErr, (_in0Len[0] > 0) && (_in0[0][(_in0Len[0] - 1)] == 0)); _COPY(_in1Len, 0, _primIn, 4, 4); _ASSERT(_nErr, (int)((_praIn[1].buf.nLen / 1)) >= (int)(_in1Len[0])); _in1[0] = _praIn[1].buf.pv; _ASSERT(_nErr, (_in1Len[0] > 0) && (_in1[0][(_in1Len[0] - 1)] == 0)); _TRY(_nErr, _pfn(*_in0, *_in1, _rout2)); _COPY(_primROut, 0, _rout2, 0, 4); _CATCH(_nErr) {} return _nErr; } __QAIC_SKEL_EXPORT int __QAIC_SKEL(apps_std_skel_invoke)(uint32_t _sc, remote_arg* _pra) __QAIC_SKEL_ATTRIBUTE { switch(REMOTE_SCALARS_METHOD(_sc)) { case 0: return _skel_method_22((void*)__QAIC_IMPL(apps_std_fopen), _sc, _pra); case 1: return _skel_method_21((void*)__QAIC_IMPL(apps_std_freopen), _sc, _pra); case 2: return _skel_method_9((void*)__QAIC_IMPL(apps_std_fflush), _sc, _pra); case 3: return _skel_method_9((void*)__QAIC_IMPL(apps_std_fclose), _sc, _pra); case 4: return _skel_method_20((void*)__QAIC_IMPL(apps_std_fread), _sc, _pra); case 5: return _skel_method_19((void*)__QAIC_IMPL(apps_std_fwrite), _sc, _pra); case 6: return _skel_method_12((void*)__QAIC_IMPL(apps_std_fgetpos), _sc, _pra); case 7: return _skel_method_18((void*)__QAIC_IMPL(apps_std_fsetpos), _sc, _pra); case 8: return _skel_method_8((void*)__QAIC_IMPL(apps_std_ftell), _sc, _pra); case 9: return _skel_method_17((void*)__QAIC_IMPL(apps_std_fseek), _sc, _pra); case 10: return _skel_method_16((void*)__QAIC_IMPL(apps_std_flen), _sc, _pra); case 11: return _skel_method_9((void*)__QAIC_IMPL(apps_std_rewind), _sc, _pra); case 12: return _skel_method_8((void*)__QAIC_IMPL(apps_std_feof), _sc, _pra); case 13: return _skel_method_8((void*)__QAIC_IMPL(apps_std_ferror), _sc, _pra); case 14: return _skel_method_9((void*)__QAIC_IMPL(apps_std_clearerr), _sc, _pra); case 15: return _skel_method_3((void*)__QAIC_IMPL(apps_std_print_string), _sc, _pra); case 16: return _skel_method_15((void*)__QAIC_IMPL(apps_std_getenv), _sc, _pra); case 17: return _skel_method_14((void*)__QAIC_IMPL(apps_std_setenv), _sc, _pra); case 18: return _skel_method_3((void*)__QAIC_IMPL(apps_std_unsetenv), _sc, _pra); case 19: return _skel_method_13((void*)__QAIC_IMPL(apps_std_fopen_with_env), _sc, _pra); case 20: return _skel_method_12((void*)__QAIC_IMPL(apps_std_fgets), _sc, _pra); case 21: return _skel_method_11((void*)__QAIC_IMPL(apps_std_get_search_paths_with_env), _sc, _pra); case 22: return _skel_method_10((void*)__QAIC_IMPL(apps_std_fileExists), _sc, _pra); case 23: return _skel_method_9((void*)__QAIC_IMPL(apps_std_fsync), _sc, _pra); case 24: return _skel_method_3((void*)__QAIC_IMPL(apps_std_fremove), _sc, _pra); case 25: return _skel_method_8((void*)__QAIC_IMPL(apps_std_fdopen_decrypt), _sc, _pra); case 26: return _skel_method_7((void*)__QAIC_IMPL(apps_std_opendir), _sc, _pra); case 27: return _skel_method_6((void*)__QAIC_IMPL(apps_std_closedir), _sc, _pra); case 28: return _skel_method_5((void*)__QAIC_IMPL(apps_std_readdir), _sc, _pra); case 29: return _skel_method_4((void*)__QAIC_IMPL(apps_std_mkdir), _sc, _pra); case 30: return _skel_method_3((void*)__QAIC_IMPL(apps_std_rmdir), _sc, _pra); case 31: { uint32_t* _mid; if(REMOTE_SCALARS_INBUFS(_sc) < 1 || _pra[0].buf.nLen < 4) { return AEE_EBADPARM; } _mid = (uint32_t*)_pra[0].buf.pv; return _skel_invoke(*_mid, _sc, _pra); } } return AEE_EUNSUPPORTED; } #ifdef __cplusplus } #endif #endif //_APPS_STD_SKEL_H