/* * Copyright (c) 1999-2018 Apple Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this * file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_LICENSE_HEADER_END@ */ /* * @OSF_COPYRIGHT@ */ /* * Mach Operating System * Copyright (c) 1991,1990 Carnegie Mellon University * All Rights Reserved. * * Permission to use, copy, modify and distribute this software and its * documentation is hereby granted, provided that both the copyright * notice and this permission notice appear in all copies of the * software, derivative works or modified versions, and any portions * thereof, and that both notices appear in supporting documentation. * * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. * * Carnegie Mellon requests users of this software to return to * * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU * School of Computer Science * Carnegie Mellon University * Pittsburgh PA 15213-3890 * * any improvements or extensions that they make and grant Carnegie Mellon * the rights to redistribute these changes. */ #include #include #include #include "write.h" #include "utils.h" #include "global.h" #include "error.h" #ifndef max #define max(a,b) (((a) > (b)) ? (a) : (b)) #endif /* max */ void WriteLogDefines(FILE *file, string_t who); void WriteIdentificationString(FILE *file); static void WriteFieldDecl(FILE *file, argument_t *arg); static void WriteKPD_Iterator(FILE *file, boolean_t in, boolean_t varying, argument_t *arg, boolean_t bracket) { ipc_type_t *it = arg->argType; char string[MAX_STR_LEN]; fprintf(file, "\t{\n"); fprintf(file, "\t %s\t*ptr;\n", it->itKPDType); fprintf(file, "\t int\ti"); if (varying && !in) fprintf(file, ", j"); fprintf(file, ";\n\n"); if (in) sprintf(string, "In%dP", arg->argRequestPos); else sprintf(string, "OutP"); fprintf(file, "\t ptr = &%s->%s[0];\n", string, arg->argMsgField); if (varying) { argument_t *count = arg->argCount; if (in) fprintf(file, "\t for (i = 0; i < In%dP->%s; ptr++, i++) %s\n", count->argRequestPos, count->argMsgField, (bracket) ? "{" : ""); else { fprintf(file, "\t j = min(%d, ", it->itKPD_Number); if (akCheck(count->argKind, akbVarNeeded)) fprintf(file, "%s);\n", count->argName); else fprintf(file, "%s->%s);\n", string, count->argMsgField); fprintf(file, "\t for (i = 0; i < j; ptr++, i++) %s\n", (bracket) ? "{" : ""); } } else fprintf(file, "\t for (i = 0; i < %d; ptr++, i++) %s\n", it->itKPD_Number, (bracket) ? "{" : ""); } static void WriteMyIncludes(FILE *file, statement_t *stats) { if (ServerHeaderFileName == strNULL || UseSplitHeaders) WriteIncludes(file, FALSE, FALSE); if (ServerHeaderFileName != strNULL) { char *cp; /* Strip any leading path from ServerHeaderFileName. */ cp = strrchr(ServerHeaderFileName, '/'); if (cp == 0) cp = ServerHeaderFileName; else cp++; /* skip '/' */ fprintf(file, "#include \"%s\"\n", cp); } if (ServerHeaderFileName == strNULL || UseSplitHeaders) WriteImplImports(file, stats, FALSE); if (UseEventLogger) { if (IsKernelServer) { fprintf(file, "#if\t__MigKernelSpecificCode\n"); fprintf(file, "#include \n"); fprintf(file, "#endif\t/* __MigKernelSpecificCode */\n"); } fprintf(file, "#if MIG_DEBUG\n"); fprintf(file, "#include \n"); fprintf(file, "#endif /* MIG_DEBUG */\n"); } fprintf(file, "\n"); } static void WriteGlobalDecls(FILE *file) { if (BeAnsiC) { fprintf(file, "#define novalue void\n"); } else { fprintf(file, "#if\t%s\n", NewCDecl); fprintf(file, "#define novalue void\n"); fprintf(file, "#else\n"); fprintf(file, "#define novalue int\n"); fprintf(file, "#endif\t/* %s */\n", NewCDecl); } fprintf(file, "\n"); if (RCSId != strNULL) WriteRCSDecl(file, strconcat(SubsystemName, "_server"), RCSId); /* Used for locations in the request message, *not* reply message. Reply message locations aren't dependent on IsKernelServer. */ if (IsKernelServer) { fprintf(file, "#if\t__MigKernelSpecificCode\n"); fprintf(file, "#define msgh_request_port\tmsgh_remote_port\n"); fprintf(file, "#define MACH_MSGH_BITS_REQUEST(bits)"); fprintf(file, "\tMACH_MSGH_BITS_REMOTE(bits)\n"); fprintf(file, "#define msgh_reply_port\t\tmsgh_local_port\n"); fprintf(file, "#define MACH_MSGH_BITS_REPLY(bits)"); fprintf(file, "\tMACH_MSGH_BITS_LOCAL(bits)\n"); fprintf(file, "#else\n"); } fprintf(file, "#define msgh_request_port\tmsgh_local_port\n"); fprintf(file, "#define MACH_MSGH_BITS_REQUEST(bits)"); fprintf(file, "\tMACH_MSGH_BITS_LOCAL(bits)\n"); fprintf(file, "#define msgh_reply_port\t\tmsgh_remote_port\n"); fprintf(file, "#define MACH_MSGH_BITS_REPLY(bits)"); fprintf(file, "\tMACH_MSGH_BITS_REMOTE(bits)\n"); if (IsKernelServer) { fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } fprintf(file, "\n"); if (UseEventLogger) WriteLogDefines(file, "MACH_MSG_LOG_SERVER"); fprintf(file, "#define MIG_RETURN_ERROR(X, code)\t{\\\n"); fprintf(file, "\t\t\t\t((mig_reply_error_t *)X)->RetCode = code;\\\n"); fprintf(file, "\t\t\t\t((mig_reply_error_t *)X)->NDR = NDR_record;\\\n"); fprintf(file, "\t\t\t\treturn;\\\n"); fprintf(file, "\t\t\t\t}\n"); fprintf(file, "\n"); } static void WriteForwardDeclarations(FILE *file, statement_t *stats) { statement_t *stat; fprintf(file, "/* Forward Declarations */\n\n"); for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { fprintf(file, "\nmig_internal novalue _X%s\n", stat->stRoutine->rtName); fprintf(file, "\t(mach_msg_header_t *InHeadP, mach_msg_header_t *OutHeadP);\n"); } fprintf(file, "\n"); } static void WriteMIGCheckDefines(FILE *file) { fprintf(file, "#define\t__MIG_check__Request__%s_subsystem__ 1\n", SubsystemName); fprintf(file, "\n"); } static void WriteNDRDefines(FILE *file) { fprintf(file, "#define\t__NDR_convert__Request__%s_subsystem__ 1\n", SubsystemName); fprintf(file, "\n"); } static void WriteProlog(FILE *file, statement_t *stats) { WriteIdentificationString(file); fprintf(file, "\n"); fprintf(file, "/* Module %s */\n", SubsystemName); fprintf(file, "\n"); WriteMIGCheckDefines(file); if (CheckNDR) WriteNDRDefines(file); WriteMyIncludes(file, stats); WriteBogusDefines(file); WriteApplDefaults(file, "Rcv"); WriteGlobalDecls(file); if (ServerHeaderFileName == strNULL) { WriteRequestTypes(file, stats); WriteReplyTypes(file, stats); WriteServerReplyUnion(file, stats); } } static void WriteSymTabEntries(FILE *file, statement_t *stats) { statement_t *stat; u_int current = 0; for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { int num = stat->stRoutine->rtNumber; char *name = stat->stRoutine->rtName; while (++current <= num) fprintf(file,"\t\t\t{ \"\", 0, 0 },\n"); fprintf(file, "\t{ \"%s\", %d, _X%s },\n", name, SubsystemBase + current - 1, name); } while (++current <= rtNumber) fprintf(file,"\t{ \"\", 0, 0 },\n"); } static void WriteRoutineEntries(FILE *file, statement_t *stats) { u_int current = 0; statement_t *stat; char *sig_array, *rt_name; int arg_count, descr_count; int offset = 0; size_t serverSubsysNameLen = strlen(ServerSubsys); fprintf(file, "\t{\n"); for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { routine_t *rt = stat->stRoutine; size_t rtNameLen = strlen(rt->rtName); // Include length of rt->rtName in calculation of necessary buffer size, since that string // is actually written into the buffer along with the Server Subsystem name. sig_array = (char *) malloc(serverSubsysNameLen + rtNameLen + 80); rt_name = (char *) malloc(rtNameLen + 5); while (current++ < rt->rtNumber) fprintf(file, "\t\t{0, 0, 0, 0, 0, 0},\n"); // NOTE: if either of the two string constants in the sprintf() function calls below get // much longer, be sure to increase the constant '80' (in the first malloc() call) to ensure // that the allocated buffer is large enough. (Currently, I count 66 characters in the first // string constant, 65 in the second. 80 ought to be enough for now...) if (UseRPCTrap) { sprintf(sig_array, "&%s.arg_descriptor[%d], (mach_msg_size_t)sizeof(__Reply__%s_t)", ServerSubsys, offset, rt->rtName); } else { sprintf(sig_array, "(routine_arg_descriptor_t)0, (mach_msg_size_t)sizeof(__Reply__%s_t)", rt->rtName); } sprintf(rt_name, "_X%s", rt->rtName); descr_count = rtCountArgDescriptors(rt->rtArgs, &arg_count); offset += descr_count; WriteRPCRoutineDescriptor(file, rt, arg_count, (UseRPCTrap) ? descr_count : 0, rt_name, sig_array); fprintf(file, ",\n"); free(sig_array); free(rt_name); } while (current++ < rtNumber) fprintf(file, "\t\t{0, 0, 0, 0, 0, 0},\n"); fprintf(file, "\t}"); } static void WriteArgDescriptorEntries(FILE *file, statement_t *stats) { statement_t *stat; fprintf(file, ",\n\n\t{\n"); for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { routine_t *rt = stat->stRoutine; /* For each arg of the routine, write an arg descriptor: */ WriteRPCRoutineArgDescriptor(file, rt); } fprintf(file, "\t},\n\n"); } /* * Write out the description of this subsystem, for use in direct RPC */ static void WriteSubsystem(FILE *file, statement_t *stats) { statement_t *stat; int descr_count = 0; for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { routine_t *rt = stat->stRoutine; descr_count += rtCountArgDescriptors(rt->rtArgs, (int *) 0); } fprintf(file, "\n"); if (ServerHeaderFileName == strNULL) { WriteMigExternal(file); fprintf(file, "boolean_t %s(", ServerDemux); if (BeAnsiC) { fprintf(file, "\n\t\tmach_msg_header_t *InHeadP,"); fprintf(file, "\n\t\tmach_msg_header_t *OutHeadP"); } fprintf(file, ");\n\n"); WriteMigExternal(file); fprintf(file, "mig_routine_t %s_routine(", ServerDemux); if (BeAnsiC) { fprintf(file, "\n\t\tmach_msg_header_t *InHeadP"); } fprintf(file, ");\n\n"); } fprintf(file, "\n/* Description of this subsystem, for use in direct RPC */\n"); if (ServerHeaderFileName == strNULL) { fprintf(file, "const struct %s {\n", ServerSubsys); if (UseRPCTrap) { fprintf(file, "\tstruct subsystem *\tsubsystem;\t/* Reserved for system use */\n"); } else { fprintf(file, "\tmig_server_routine_t \tserver;\t/* Server routine */\n"); } fprintf(file, "\tmach_msg_id_t\tstart;\t/* Min routine number */\n"); fprintf(file, "\tmach_msg_id_t\tend;\t/* Max routine number + 1 */\n"); fprintf(file, "\tunsigned int\tmaxsize;\t/* Max msg size */\n"); if (UseRPCTrap) { fprintf(file, "\tvm_address_t\tbase_addr;\t/* Base address */\n"); fprintf(file, "\tstruct rpc_routine_descriptor\t/*Array of routine descriptors */\n"); } else { fprintf(file, "\tvm_address_t\treserved;\t/* Reserved */\n"); fprintf(file, "\tstruct routine_descriptor\t/*Array of routine descriptors */\n"); } fprintf(file, "\t\troutine[%d];\n", rtNumber); if (UseRPCTrap) { fprintf(file, "\tstruct rpc_routine_arg_descriptor\t/*Array of arg descriptors */\n"); fprintf(file, "\t\targ_descriptor[%d];\n", descr_count); } fprintf(file, "} %s = {\n", ServerSubsys); } else { fprintf(file, "const struct %s %s = {\n", ServerSubsys, ServerSubsys); } if (UseRPCTrap) { fprintf(file, "\t0,\n"); } else { fprintf(file, "\t%s_routine,\n", ServerDemux); } fprintf(file, "\t%d,\n", SubsystemBase); fprintf(file, "\t%d,\n", SubsystemBase + rtNumber); fprintf(file, "\t(mach_msg_size_t)sizeof(union __ReplyUnion__%s),\n", ServerSubsys); if (UseRPCTrap) { fprintf(file, "\t(vm_address_t)&%s,\n", ServerSubsys); } else { fprintf(file, "\t(vm_address_t)0,\n"); } WriteRoutineEntries(file, stats); if (UseRPCTrap) WriteArgDescriptorEntries(file, stats); else fprintf(file, "\n"); fprintf(file, "};\n\n"); } #if NOT_CURRENTLY_USED static void WriteArraySizes(FILE *file, statement_t *stats) { u_int current = 0; statement_t *stat; for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) { routine_t *rt = stat->stRoutine; while (current++ < rt->rtNumber) fprintf(file, "\t\t0,\n"); fprintf(file, "\t\t(mach_msg_size_t)sizeof(__Reply__%s_t),\n", rt->rtName); } while (current++ < rtNumber) fprintf(file, "\t\t\t0,\n"); } #endif /* NOT_CURRENTLY_USED */ void WriteServerRequestUnion(FILE *file, statement_t *stats) { statement_t *stat; fprintf(file, "\n"); fprintf(file, "/* union of all requests */\n\n"); fprintf(file, "#ifndef __RequestUnion__%s__defined\n", ServerSubsys); fprintf(file, "#define __RequestUnion__%s__defined\n", ServerSubsys); fprintf(file, "union __RequestUnion__%s {\n", ServerSubsys); for (stat = stats; stat != stNULL; stat = stat->stNext) { if (stat->stKind == skRoutine) { routine_t *rt; rt = stat->stRoutine; fprintf(file, "\t__Request__%s_t Request_%s;\n", rt->rtName, rt->rtName); } } fprintf(file, "};\n"); fprintf(file, "#endif /* __RequestUnion__%s__defined */\n", ServerSubsys); } void WriteServerReplyUnion(FILE *file, statement_t *stats) { statement_t *stat; fprintf(file, "\n"); fprintf(file, "/* union of all replies */\n\n"); fprintf(file, "#ifndef __ReplyUnion__%s__defined\n", ServerSubsys); fprintf(file, "#define __ReplyUnion__%s__defined\n", ServerSubsys); fprintf(file, "union __ReplyUnion__%s {\n", ServerSubsys); for (stat = stats; stat != stNULL; stat = stat->stNext) { if (stat->stKind == skRoutine) { routine_t *rt; rt = stat->stRoutine; fprintf(file, "\t__Reply__%s_t Reply_%s;\n", rt->rtName, rt->rtName); } } fprintf(file, "};\n"); fprintf(file, "#endif /* __ReplyUnion__%s__defined */\n", ServerSubsys); } static void WriteDispatcher(FILE *file, statement_t *stats) { /* * Write the subsystem stuff. */ fprintf(file, "\n"); WriteSubsystem(file, stats); /* * Then, the server routine */ fprintf(file, "mig_external boolean_t %s\n", ServerDemux); if (BeAnsiC) { fprintf(file, "\t(mach_msg_header_t *InHeadP, mach_msg_header_t *OutHeadP)\n"); } else { fprintf(file, "#if\t%s\n", NewCDecl); fprintf(file, "\t(mach_msg_header_t *InHeadP, mach_msg_header_t *OutHeadP)\n"); fprintf(file, "#else\n"); fprintf(file, "\t(InHeadP, OutHeadP)\n"); fprintf(file, "\tmach_msg_header_t *InHeadP, *OutHeadP;\n"); fprintf(file, "#endif\t/* %s */\n", NewCDecl); } fprintf(file, "{\n"); fprintf(file, "\t/*\n"); fprintf(file, "\t * typedef struct {\n"); fprintf(file, "\t * \tmach_msg_header_t Head;\n"); fprintf(file, "\t * \tNDR_record_t NDR;\n"); fprintf(file, "\t * \tkern_return_t RetCode;\n"); fprintf(file, "\t * } mig_reply_error_t;\n"); fprintf(file, "\t */\n"); fprintf(file, "\n"); fprintf(file, "\tmig_routine_t routine;\n"); fprintf(file, "\n"); fprintf(file, "\tOutHeadP->msgh_bits = "); fprintf(file, "MACH_MSGH_BITS(MACH_MSGH_BITS_REPLY(InHeadP->msgh_bits), 0);\n"); fprintf(file, "\tOutHeadP->msgh_remote_port = InHeadP->msgh_reply_port;\n"); fprintf(file, "\t/* Minimal size: routine() will update it if different */\n"); fprintf(file, "\tOutHeadP->msgh_size = (mach_msg_size_t)sizeof(mig_reply_error_t);\n"); fprintf(file, "\tOutHeadP->msgh_local_port = MACH_PORT_NULL;\n"); fprintf(file, "\tOutHeadP->msgh_id = InHeadP->msgh_id + 100;\n"); fprintf(file, "\tOutHeadP->msgh_reserved = 0;\n"); fprintf(file, "\n"); fprintf(file, "\tif ((InHeadP->msgh_id > %d) || (InHeadP->msgh_id < %d) ||\n", SubsystemBase + rtNumber - 1, SubsystemBase); fprintf(file, "\t ((routine = %s.routine[InHeadP->msgh_id - %d].stub_routine) == 0)) {\n", ServerSubsys, SubsystemBase); fprintf(file, "\t\t((mig_reply_error_t *)OutHeadP)->NDR = NDR_record;\n"); fprintf(file, "\t\t((mig_reply_error_t *)OutHeadP)->RetCode = MIG_BAD_ID;\n"); if (UseEventLogger) { fprintf(file, "#if MIG_DEBUG\n"); fprintf(file, "\t\tLOG_ERRORS(MACH_MSG_LOG_SERVER, MACH_MSG_ERROR_UNKNOWN_ID,\n"); fprintf(file, "\t\t\t&InHeadP->msgh_id, __FILE__, __LINE__);\n"); fprintf(file, "#endif /* MIG_DEBUG */\n"); } fprintf(file, "\t\treturn FALSE;\n"); fprintf(file, "\t}\n"); /* Call appropriate routine */ fprintf(file, "\t(*routine) (InHeadP, OutHeadP);\n"); fprintf(file, "\treturn TRUE;\n"); fprintf(file, "}\n"); fprintf(file, "\n"); /* * Then, the _server_routine routine */ fprintf(file, "mig_external mig_routine_t %s_routine\n", ServerDemux); if (BeAnsiC) { fprintf(file, "\t(mach_msg_header_t *InHeadP)\n"); } else { fprintf(file, "#if\t%s\n", NewCDecl); fprintf(file, "\t(mach_msg_header_t *InHeadP)\n"); fprintf(file, "#else\n"); fprintf(file, "\t(InHeadP)\n"); fprintf(file, "\tmach_msg_header_t *InHeadP;\n"); fprintf(file, "#endif\t/* %s */\n", NewCDecl); } fprintf(file, "{\n"); fprintf(file, "\tint msgh_id;\n"); fprintf(file, "\n"); fprintf(file, "\tmsgh_id = InHeadP->msgh_id - %d;\n", SubsystemBase); fprintf(file, "\n"); fprintf(file, "\tif ((msgh_id > %d) || (msgh_id < 0))\n", rtNumber - 1); fprintf(file, "\t\treturn 0;\n"); fprintf(file, "\n"); fprintf(file, "\treturn %s.routine[msgh_id].stub_routine;\n", ServerSubsys); fprintf(file, "}\n"); /* symtab */ if (GenSymTab) { fprintf(file,"\nmig_symtab_t _%sSymTab[] = {\n",SubsystemName); WriteSymTabEntries(file,stats); fprintf(file,"};\n"); fprintf(file,"int _%sSymTabBase = %d;\n",SubsystemName,SubsystemBase); fprintf(file,"int _%sSymTabEnd = %d;\n",SubsystemName,SubsystemBase+rtNumber); } } #if NOT_CURRENTLY_USED /* * Returns the return type of the server-side work function. * Suitable for "extern %s serverfunc()". */ static char * ServerSideType(routine_t *rt) { return rt->rtRetCode->argType->itTransType; } #endif /* NOT_CURRENTLY_USED */ static void WriteRetCode(FILE *file, argument_t *ret) { ipc_type_t *it = ret->argType; if (akCheck(ret->argKind, akbVarNeeded)) { fprintf(file, "\t%s %s;\n", it->itTransType, ret->argVarName); } } static void WriteLocalVarDecl(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; ipc_type_t *btype = it->itElement; if (IS_VARIABLE_SIZED_UNTYPED(it)) fprintf(file, "\t%s %s[%d]", btype->itTransType, arg->argVarName, btype->itNumber ? it->itNumber/btype->itNumber : 0); else if (IS_MULTIPLE_KPD(it)) { if (btype->itTransType != strNULL) fprintf(file, "\t%s %s[%d]", btype->itTransType, arg->argVarName, it->itKPD_Number); else /* arrays of ool or oolport */ fprintf(file, "\tvoid *%s[%d]", arg->argVarName, it->itKPD_Number); } else fprintf(file, "\t%s %s", it->itTransType, arg->argVarName); } #if NOT_CURRENTLY_USED static void WriteServerArgDecl(FILE *file, argument_t *arg) { fprintf(file, "%s %s%s", arg->argType->itTransType, arg->argByReferenceServer ? "*" : "", arg->argVarName); } #endif /* NOT_CURRENTLY_USED */ /* * Writes the local variable declarations which are always * present: InP, OutP, the server-side work function. */ static void WriteVarDecls(FILE *file, routine_t *rt) { int i; fprintf(file, "\tRequest *In0P = (Request *) InHeadP;\n"); for (i = 1; i <= rt->rtMaxRequestPos; i++) fprintf(file, "\tRequest *In%dP;\n", i); fprintf(file, "\tReply *OutP = (Reply *) OutHeadP;\n"); /* if reply is variable, we may need msgh_size_delta and msgh_size */ if (rt->rtNumReplyVar > 1) fprintf(file, "\tunsigned int msgh_size;\n"); if (rt->rtMaxReplyPos > 0) fprintf(file, "\tunsigned int msgh_size_delta;\n"); if (rt->rtNumReplyVar > 1 || rt->rtMaxReplyPos > 0) fprintf(file, "\n"); if (rt->rtServerImpl) { fprintf(file, "\tmach_msg_max_trailer_t *TrailerP;\n"); fprintf(file, "#if\t__MigTypeCheck\n"); fprintf(file, "\tunsigned int trailer_size __attribute__((unused));\n"); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); } fprintf(file, "#ifdef\t__MIG_check__Request__%s_t__defined\n", rt->rtName); fprintf(file, "\tkern_return_t check_result;\n"); fprintf(file, "#endif\t/* __MIG_check__Request__%s_t__defined */\n", rt->rtName); fprintf(file, "\n"); } static void WriteReplyInit(FILE *file, routine_t *rt) { fprintf(file, "\n"); if (rt->rtNumReplyVar > 1 || rt->rtMaxReplyPos) /* WritheAdjustMsgSize() has been executed at least once! */ fprintf(file, "\tOutP = (Reply *) OutHeadP;\n"); if (!rt->rtSimpleReply) /* complex reply message */ fprintf(file, "\tOutP->Head.msgh_bits |= MACH_MSGH_BITS_COMPLEX;\n"); if (rt->rtNumReplyVar == 0) { fprintf(file, "\tOutP->Head.msgh_size = "); rtMinReplySize(file, rt, "Reply"); fprintf(file, ";\n"); } else if (rt->rtNumReplyVar > 1) fprintf(file, "\tOutP->Head.msgh_size = msgh_size;\n"); /* the case rt->rtNumReplyVar = 1 is taken care of in WriteAdjustMsgSize() */ } static void WriteRetCArgCheckError(FILE *file, routine_t *rt) { fprintf(file, "\tif (!(In0P->Head.msgh_bits & MACH_MSGH_BITS_COMPLEX) &&\n"); fprintf(file, "\t (In0P->Head.msgh_size == (mach_msg_size_t)sizeof(mig_reply_error_t)))\n"); fprintf(file, "\t{\n"); } static void WriteRetCArgFinishError(FILE *file, routine_t *rt) { argument_t *retcode = rt->rtRetCArg; fprintf(file, "\treturn;\n"); fprintf(file, "\t}\n"); retcode->argMsgField = "KERN_SUCCESS"; } static void WriteCheckHead(FILE *file, routine_t *rt) { fprintf(file, "#if\t__MigTypeCheck\n"); if (rt->rtNumRequestVar > 0) fprintf(file, "\tmsgh_size = In0P->Head.msgh_size;\n"); if (rt->rtSimpleRequest) { /* Expecting a simple message. */ fprintf(file, "\tif ((In0P->Head.msgh_bits & MACH_MSGH_BITS_COMPLEX) ||\n"); if (rt->rtNumRequestVar > 0) { fprintf(file, "\t (msgh_size < "); rtMinRequestSize(file, rt, "__Request"); fprintf(file, ") || (msgh_size > (mach_msg_size_t)sizeof(__Request)))\n"); } else fprintf(file, "\t (In0P->Head.msgh_size != (mach_msg_size_t)sizeof(__Request)))\n"); } else { /* Expecting a complex message. */ fprintf(file, "\tif ("); if (rt->rtRetCArg != argNULL) fprintf(file, "("); fprintf(file, "!(In0P->Head.msgh_bits & MACH_MSGH_BITS_COMPLEX) ||\n"); fprintf(file, "\t (In0P->msgh_body.msgh_descriptor_count != %d) ||\n", rt->rtRequestKPDs); if (rt->rtNumRequestVar > 0) { fprintf(file, "\t (msgh_size < "); rtMinRequestSize(file, rt, "__Request"); fprintf(file, ") || (msgh_size > (mach_msg_size_t)sizeof(__Request))"); } else fprintf(file, "\t (In0P->Head.msgh_size != (mach_msg_size_t)sizeof(__Request))"); if (rt->rtRetCArg == argNULL) fprintf(file, ")\n"); else { fprintf(file, ") &&\n"); fprintf(file, "\t ((In0P->Head.msgh_bits & MACH_MSGH_BITS_COMPLEX) ||\n"); fprintf(file, "\t In0P->Head.msgh_size != (mach_msg_size_t)sizeof(mig_reply_error_t) ||\n"); fprintf(file, "\t ((mig_reply_error_t *)In0P)->RetCode == KERN_SUCCESS))\n"); } } fprintf(file, "\t\treturn MIG_BAD_ARGUMENTS;\n"); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); fprintf(file, "\n"); } void WriteRequestNDRConvertIntRepArgCond(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; fprintf(file, "defined(__NDR_convert__int_rep__Request__%s_t__%s__defined)", rt->rtName, arg->argMsgField); } void WriteRequestNDRConvertCharRepArgCond(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) fprintf(file, "defined(__NDR_convert__char_rep__Request__%s_t__%s__defined)", rt->rtName, arg->argMsgField); else fprintf(file, "0"); } void WriteRequestNDRConvertFloatRepArgCond(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) fprintf(file, "defined(__NDR_convert__float_rep__Request__%s_t__%s__defined)", rt->rtName, arg->argMsgField); else fprintf(file, "0"); } void WriteRequestNDRConvertIntRepArgDecl(FILE *file, argument_t *arg) { WriteNDRConvertArgDecl(file, arg, "int_rep", "Request"); } void WriteRequestNDRConvertCharRepArgDecl(FILE *file, argument_t *arg) { if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) WriteNDRConvertArgDecl(file, arg, "char_rep", "Request"); } void WriteRequestNDRConvertFloatRepArgDecl(FILE *file, argument_t *arg) { if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) WriteNDRConvertArgDecl(file, arg, "float_rep", "Request"); } void WriteRequestNDRConvertArgUse(FILE *file, argument_t *arg, char *convert) { routine_t *rt = arg->argRoutine; argument_t *count = arg->argCount; char argname[MAX_STR_LEN]; if ((akIdent(arg->argKind) == akeCount || akIdent(arg->argKind) == akeCountInOut) && (arg->argParent && akCheck(arg->argParent->argKind, akbSendNdr))) return; if (arg->argKPD_Type == MACH_MSG_OOL_DESCRIPTOR) { if (count && !arg->argSameCount && !strcmp(convert, "int_rep")) { fprintf(file, "#if defined(__NDR_convert__int_rep__Request__%s_t__%s__defined)\n", rt->rtName, count->argMsgField); fprintf(file, "\t\t__NDR_convert__int_rep__Request__%s_t__%s(&In%dP->%s, In%dP->NDR.int_rep);\n", rt->rtName, count->argMsgField, count->argRequestPos, count->argMsgField, count->argRequestPos); fprintf(file, "#endif\t/* __NDR_convert__int_rep__Request__%s_t__%s__defined */\n", rt->rtName, count->argMsgField); } sprintf(argname, "(%s)(In%dP->%s.address)", FetchServerType(arg->argType), arg->argRequestPos, arg->argMsgField); } else { sprintf(argname, "&In%dP->%s", arg->argRequestPos, arg->argMsgField); } fprintf(file, "#if defined(__NDR_convert__%s__Request__%s_t__%s__defined)\n", convert, rt->rtName, arg->argMsgField); fprintf(file, "\t\t__NDR_convert__%s__Request__%s_t__%s(%s, In0P->NDR.%s", convert, rt->rtName, arg->argMsgField, argname, convert); if (count) fprintf(file, ", In%dP->%s", count->argRequestPos, count->argMsgField); fprintf(file, ");\n"); fprintf(file, "#endif\t/* __NDR_convert__%s__Request__%s_t__%s__defined */\n", convert, rt->rtName, arg->argMsgField); } void WriteRequestNDRConvertIntRepOneArgUse(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; fprintf(file, "#if defined(__NDR_convert__int_rep__Request__%s_t__%s__defined)\n", rt->rtName, arg->argMsgField); fprintf(file, "\tif (In0P->NDR.int_rep != NDR_record.int_rep)\n"); fprintf(file, "\t\t__NDR_convert__int_rep__Request__%s_t__%s(&In%dP->%s, In%dP->NDR.int_rep);\n", rt->rtName, arg->argMsgField, arg->argRequestPos, arg->argMsgField, arg->argRequestPos); fprintf(file, "#endif\t/* __NDR_convert__int_rep__Request__%s_t__%s__defined */\n", rt->rtName, arg->argMsgField); } void WriteRequestNDRConvertIntRepArgUse(FILE *file, argument_t *arg) { WriteRequestNDRConvertArgUse(file, arg, "int_rep"); } void WriteRequestNDRConvertCharRepArgUse(FILE *file, argument_t *arg) { if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) WriteRequestNDRConvertArgUse(file, arg, "char_rep"); } void WriteRequestNDRConvertFloatRepArgUse(FILE *file, argument_t *arg) { if (akIdent(arg->argKind) != akeCount && akIdent(arg->argKind) != akeCountInOut) WriteRequestNDRConvertArgUse(file, arg, "float_rep"); } static void WriteCalcArgSize(FILE *file, argument_t *arg) { ipc_type_t *ptype = arg->argType; if (PackMsg == FALSE) { fprintf(file, "%d", ptype->itTypeSize + ptype->itPadSize); return; } if (IS_OPTIONAL_NATIVE(ptype)) fprintf(file, "(In%dP->__Present__%s ? _WALIGNSZ_(%s) : 0)" , arg->argRequestPos, arg->argMsgField, ptype->itServerType); else { ipc_type_t *btype = ptype->itElement; argument_t *count = arg->argCount; int multiplier = btype->itTypeSize; if (btype->itTypeSize % itWordAlign != 0) fprintf(file, "_WALIGN_"); fprintf(file, "("); if (multiplier > 1) fprintf(file, "%d * ", multiplier); fprintf(file, "In%dP->%s", count->argRequestPos, count->argMsgField); fprintf(file, ")"); } } static void WriteCheckArgSize(FILE *file, routine_t *rt, argument_t *arg, const char *comparator) { ipc_type_t *ptype = arg->argType; fprintf(file, "\tif (((msgh_size - "); rtMinRequestSize(file, rt, "__Request"); fprintf(file, ") "); if (PackMsg == FALSE) { fprintf(file, "%s %d)", comparator, ptype->itTypeSize + ptype->itPadSize); } else if (IS_OPTIONAL_NATIVE(ptype)) { fprintf(file, "%s (In%dP->__Present__%s ? _WALIGNSZ_(%s) : 0))" , comparator, arg->argRequestPos, arg->argMsgField, ptype->itServerType); } else { ipc_type_t *btype = ptype->itElement; argument_t *count = arg->argCount; int multiplier = btype->itTypeSize; if (multiplier > 1) fprintf(file, "/ %d ", multiplier); fprintf(file, "< In%dP->%s) ||\n", count->argRequestPos, count->argMsgField); fprintf(file, "\t (msgh_size %s ", comparator); rtMinRequestSize(file, rt, "__Request"); fprintf(file, " + "); WriteCalcArgSize(file, arg); fprintf(file, ")"); } fprintf(file, ")\n\t\treturn MIG_BAD_ARGUMENTS;\n"); } static void WriteCheckMsgSize(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; if (arg->argCount && !arg->argSameCount) WriteRequestNDRConvertIntRepOneArgUse(file, arg->argCount); if (arg->argRequestPos == rt->rtMaxRequestPos) { fprintf(file, "#if\t__MigTypeCheck\n"); /* verify that the user-code-provided count does not exceed the maximum count allowed by the type. */ fprintf(file, "\t" "if ( In%dP->%s > %d )\n", arg->argCount->argRequestPos, arg->argCount->argMsgField, arg->argType->itNumber); fputs("\t\t" "return MIG_BAD_ARGUMENTS;\n", file); /* ...end... */ WriteCheckArgSize(file, rt, arg, "!="); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); } else { /* If there aren't any more variable-sized arguments after this, then we must check for exact msg-size and we don't need to update msgh_size. */ boolean_t LastVarArg = arg->argRequestPos+1 == rt->rtNumRequestVar; /* calculate the actual size in bytes of the data field. note that this quantity must be a multiple of four. hence, if the base type size isn't a multiple of four, we have to round up. note also that btype->itNumber must divide btype->itTypeSize (see itCalculateSizeInfo). */ fprintf(file, "\tmsgh_size_delta = "); WriteCalcArgSize(file, arg); fprintf(file, ";\n"); fprintf(file, "#if\t__MigTypeCheck\n"); /* verify that the user-code-provided count does not exceed the maximum count allowed by the type. */ fprintf(file, "\t" "if ( In%dP->%s > %d )\n", arg->argCount->argRequestPos, arg->argCount->argMsgField, arg->argType->itNumber); fputs("\t\t" "return MIG_BAD_ARGUMENTS;\n", file); /* ...end... */ /* Don't decrement msgh_size until we've checked that it won't underflow. */ WriteCheckArgSize(file, rt, arg, LastVarArg ? "!=" : "<"); if (!LastVarArg) fprintf(file, "\tmsgh_size -= msgh_size_delta;\n"); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); } fprintf(file, "\n"); } static char * InArgMsgField(argument_t *arg, char *str) { static char buffer[MAX_STR_LEN]; char who[20] = {0}; /* * Inside the kernel, the request and reply port fields * really hold ipc_port_t values, not mach_port_t values. * Hence we must cast the values. */ if (!(arg->argFlags & flRetCode)) { if (akCheck(arg->argKind, akbServerImplicit)) sprintf(who, "TrailerP->"); else sprintf(who, "In%dP->", arg->argRequestPos); } #ifdef MIG_KERNEL_PORT_CONVERSION if (IsKernelServer && ((akIdent(arg->argKind) == akeRequestPort) || (akIdent(arg->argKind) == akeReplyPort))) sprintf(buffer, "(ipc_port_t) %s%s%s", who, str, (arg->argSuffix != strNULL) ? arg->argSuffix : arg->argMsgField); else #endif sprintf(buffer, "%s%s%s", who, str, (arg->argSuffix != strNULL) ? arg->argSuffix : arg->argMsgField); return buffer; } static void WriteExtractArgValue(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; string_t recast; #ifdef MIG_KERNEL_PORT_CONVERSION if (IsKernelServer && it->itPortType && streql(it->itServerType, "ipc_port_t") && akIdent(arg->argKind) != akeRequestPort && akIdent(arg->argKind) != akeReplyPort) recast = "(mach_port_t)"; else #endif recast = ""; if (it->itInTrans != strNULL) WriteCopyType(file, it, FALSE, "%s", "/* %s */ %s(%s%s)", arg->argVarName, it->itInTrans, recast, InArgMsgField(arg, "")); else WriteCopyType(file, it, FALSE, "%s", "/* %s */ %s%s", arg->argVarName, recast, InArgMsgField(arg, "")); fprintf(file, "\n"); } /* * argKPD_Extract discipline for Port types. */ static void WriteExtractKPD_port(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *recast = ""; WriteKPD_Iterator(file, TRUE, it->itVarArray, arg, FALSE); /* translation function do not apply to complex types */ #ifdef MIG_KERNEL_PORT_CONVERSION if (IsKernelServer) recast = "(mach_port_t)"; #endif fprintf(file, "\t\t%s[i] = %sptr->name;\n", arg->argVarName, recast); fprintf(file, "\t}\n"); } /* * argKPD_Extract discipline for out-of-line types. */ static void WriteExtractKPD_ool(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; WriteKPD_Iterator(file, TRUE, it->itVarArray, arg, FALSE); fprintf(file, "\t\t%s[i] = ptr->address;\n", arg->argVarName); fprintf(file, "\t}\n"); } /* * argKPD_Extract discipline for out-of-line Port types. */ static void WriteExtractKPD_oolport(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; WriteKPD_Iterator(file, TRUE, it->itVarArray, arg, FALSE); fprintf(file, "\t\t%s[i] = ptr->address;\n", arg->argVarName); fprintf(file, "\t}\n"); if (arg->argPoly != argNULL && akCheckAll(arg->argPoly->argKind, akbSendRcv)) { argument_t *poly = arg->argPoly; char *pref = poly->argByReferenceServer ? "*" : ""; fprintf(file, "\t%s%s = In%dP->%s[0].disposition;\n", pref, poly->argVarName, arg->argRequestPos, arg->argMsgField); } } static void WriteInitializeCount(FILE *file, argument_t *arg) { ipc_type_t *ptype = arg->argParent->argType; ipc_type_t *btype = ptype->itElement; identifier_t newstr; /* * Initialize 'count' argument for variable-length inline OUT parameter * with maximum allowed number of elements. */ if (akCheck(arg->argKind, akbVarNeeded)) newstr = arg->argMsgField; else newstr = (identifier_t)strconcat("OutP->", arg->argMsgField); fprintf(file, "\t%s = ", newstr); if (IS_MULTIPLE_KPD(ptype)) fprintf(file, "%d;\n", ptype->itKPD_Number); else fprintf(file, "%d;\n", btype->itNumber? ptype->itNumber/btype->itNumber : 0); /* * If the user passed in a count, then we use the minimum. * We can't let the user completely override our maximum, * or the user might convince the server to overwrite the buffer. */ if (arg->argCInOut != argNULL) { char *msgfield = InArgMsgField(arg->argCInOut, ""); fprintf(file, "\tif (%s < %s)\n", msgfield, newstr); fprintf(file, "\t\t%s = %s;\n", newstr, msgfield); } fprintf(file, "\n"); } static void WriteAdjustRequestMsgPtr(FILE *file, argument_t *arg) { ipc_type_t *ptype = arg->argType; if (PackMsg == FALSE) { fprintf(file, "\t*In%dPP = In%dP = (__Request *) ((pointer_t) In%dP);\n\n", arg->argRequestPos+1, arg->argRequestPos+1, arg->argRequestPos); return; } fprintf(file, "\t*In%dPP = In%dP = (__Request *) ((pointer_t) In%dP + msgh_size_delta - ", arg->argRequestPos+1, arg->argRequestPos+1, arg->argRequestPos); if (IS_OPTIONAL_NATIVE(ptype)) fprintf(file, "_WALIGNSZ_(%s)", ptype->itUserType); else fprintf(file, "%d", ptype->itTypeSize + ptype->itPadSize); fprintf(file, ");\n\n"); } static void WriteCheckRequestTrailerArgs(FILE *file, routine_t *rt) { argument_t *arg; if (rt->rtServerImpl) WriteCheckTrailerHead(file, rt, FALSE); for (arg = rt->rtArgs; arg != argNULL; arg = arg->argNext) { if (akCheck(arg->argKind, akbServerImplicit)) WriteCheckTrailerSize(file, FALSE, arg); } } static void WriteExtractArg(FILE *file, argument_t *arg) { if (akCheckAll(arg->argKind, akbSendRcv|akbVarNeeded)) { if (akCheck(arg->argKind, akbSendKPD)) (*arg->argKPD_Extract)(file, arg); else WriteExtractArgValue(file, arg); } if ((akIdent(arg->argKind) == akeCount) && akCheck(arg->argKind, akbReturnSnd)) { ipc_type_t *ptype = arg->argParent->argType; /* * the count will be initialized to 0 in the case of * unbounded arrays (MigInLine = TRUE): this is because * the old interface used to pass to the target procedure * the maximum in-line size (it was 2048 bytes) */ if (IS_VARIABLE_SIZED_UNTYPED(ptype) || IS_MIG_INLINE_EMUL(ptype) || (IS_MULTIPLE_KPD(ptype) && ptype->itVarArray)) WriteInitializeCount(file, arg); } } static void WriteServerCallArg(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; boolean_t NeedClose = FALSE; u_int elemsize = 0; string_t at = (arg->argByReferenceServer || it->itNativePointer) ? "&" : ""; string_t star = (arg->argByReferenceServer) ? " *" : ""; string_t msgfield = (arg->argSuffix != strNULL) ? arg->argSuffix : arg->argMsgField; if ((it->itInTrans != strNULL) && akCheck(arg->argKind, akbSendRcv) && !akCheck(arg->argKind, akbVarNeeded)) { fprintf(file, "%s%s(", at, it->itInTrans); NeedClose = TRUE; } if (akCheckAll(arg->argKind, akbVarNeeded|akbServerArg)) fprintf(file, "%s%s", at, arg->argVarName); else if (akCheckAll(arg->argKind, akbSendRcv|akbSendKPD)) { if (!it->itInLine) /* recast the void *, although it is not necessary */ fprintf(file, "(%s%s)%s(%s)", it->itTransType, star, at, InArgMsgField(arg, "")); else #ifdef MIG_KERNEL_PORT_CONVERSION if (IsKernelServer && streql(it->itServerType, "ipc_port_t")) /* recast the port to the kernel internal form value */ fprintf(file, "(ipc_port_t%s)%s(%s)", star, at, InArgMsgField(arg, "")); else #endif fprintf(file, "%s%s", at, InArgMsgField(arg, "")); } else if (akCheck(arg->argKind, akbSendRcv)) { if (IS_OPTIONAL_NATIVE(it)) { fprintf(file, "(%s ? ", InArgMsgField(arg, "__Present__")); fprintf(file, "%s%s.__Real__%s : %s)", at, InArgMsgField(arg, ""), arg->argMsgField, it->itBadValue); } else { if (akIdent(arg->argKind) == akeCount && arg->argParent) { char *suffix = arg->argParent->argSuffix; ipc_type_t *elemType = arg->argParent->argType->itElement; /* temporarily squash any name suffix such as ".address" (we'll be adding our own) */ arg->argParent->argSuffix = NULL; switch (arg->argParent->argKPD_Type) { case MACH_MSG_OOL_PORTS_DESCRIPTOR: /* count of the number of descriptors */ fprintf(file, "%s%s.count", at, InArgMsgField(arg->argParent, "")); break; case MACH_MSG_OOL_DESCRIPTOR: /* descriptor buffer size / element size */ if (!(arg->argByReferenceServer || it->itNativePointer)) { fprintf(file, "%s%s.size", at, InArgMsgField(arg->argParent, "")); elemsize = ((elemType->itNumber * elemType->itSize) + 7) / 8; if (elemsize > 1) { fprintf(file, " / %d", elemsize); } } else { fprintf(file, "%s%s", at, InArgMsgField(arg, "")); } break; default: fprintf(file, "%s%s", at, InArgMsgField(arg, "")); break; } arg->argParent->argSuffix = suffix; } else { fprintf(file, "%s%s", at, InArgMsgField(arg, "")); } } } else if (akCheckAll(arg->argKind, akbReturnSnd|akbReturnKPD)) { if (!it->itInLine) /* recast the void *, although it is not necessary */ fprintf(file, "(%s%s)%s(OutP->%s)", it->itTransType, star, at, msgfield); else #ifdef MIG_KERNEL_PORT_CONVERSION if (IsKernelServer && streql(it->itServerType, "ipc_port_t")) /* recast the port to the kernel internal form value */ fprintf(file, "(mach_port_t%s)%s(OutP->%s)", star, at, msgfield); else #endif fprintf(file, "%sOutP->%s", at, msgfield); } else if (akCheck(arg->argKind, akbReturnSnd)) fprintf(file, "%sOutP->%s", at, msgfield); if (NeedClose) fprintf(file, ")"); } /* * Shrunk version of WriteServerCallArg, to implement the RetCode functionality: * we have received a mig_reply_error_t, therefore we want to call the target * routine with all 0s except for the error code (and the implicit data). * We know that we are a SimpleRoutine. */ static void WriteConditionalCallArg(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; boolean_t NeedClose = FALSE; if ((it->itInTrans != strNULL) && akCheck(arg->argKind, akbSendRcv) && !akCheck(arg->argKind, akbVarNeeded)) { fprintf(file, "%s(", it->itInTrans); NeedClose = TRUE; } if (akCheck(arg->argKind, akbSendRcv)) { if (akIdent(arg->argKind) == akeRequestPort || akCheck(arg->argKind, akbServerImplicit)) fprintf(file, "%s", InArgMsgField(arg, "")); else if (akIdent(arg->argKind) == akeRetCode) fprintf(file, "((mig_reply_error_t *)In0P)->RetCode"); else fprintf(file, "(%s)(0)", it->itTransType); } if (NeedClose) fprintf(file, ")"); } static void WriteDestroyArg(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; /* * Deallocate IN/INOUT out-of-line args if specified by "auto" flag. * * We also have to deallocate in the cases where the target routine * is given a itInLine semantic whereas the underlying transmission * was out-of-line */ if ((argIsIn(arg) && akCheck(arg->argKind, akbSendKPD|akbReturnKPD) && arg->argKPD_Type == MACH_MSG_OOL_DESCRIPTOR && (arg->argFlags & flAuto)) || IS_MIG_INLINE_EMUL(it) ) { /* * Deallocate only if out-of-line. */ argument_t *count = arg->argCount; ipc_type_t *btype = it->itElement; int multiplier = btype->itNumber ? btype->itSize / (8 * btype->itNumber) : 0; if (IsKernelServer) { fprintf(file, "#if __MigKernelSpecificCode\n"); fprintf(file, "\tvm_map_copy_discard(%s);\n", InArgMsgField(arg, "")); fprintf(file, "#else\n"); } fprintf(file, "\tmig_deallocate((vm_offset_t) %s, ", InArgMsgField(arg, "")); if (it->itVarArray) { char *suffix = arg->argSuffix; /* * temporarily squash any name suffix such as ".address" * (we'll be adding our own) */ arg->argSuffix = NULL; switch (arg->argKPD_Type) { case MACH_MSG_OOL_PORTS_DESCRIPTOR: if (multiplier > 1) { fprintf(file, "%d * ", multiplier); } fprintf(file, "%s.count);\n", InArgMsgField(arg, "")); break; case MACH_MSG_OOL_DESCRIPTOR: fprintf(file, "%s.size);\n", InArgMsgField(arg, "")); break; default: if (multiplier > 1) { fprintf(file, "%d * ", multiplier); } fprintf(file, "%s);\n", InArgMsgField(count, "")); break; } arg->argSuffix = suffix; } else fprintf(file, "%d);\n", (it->itNumber * it->itSize + 7) / 8); if (IsKernelServer) { fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } fprintf(file, "\t%s = (void *) 0;\n", InArgMsgField(arg, "")); fprintf(file, "\tIn%dP->%s.%s = (mach_msg_size_t) 0;\n", arg->argRequestPos, arg->argMsgField, (RPCPortArray(arg) ? "count" : "size")); } else { if (akCheck(arg->argKind, akbVarNeeded)) fprintf(file, "\t%s(%s);\n", it->itDestructor, arg->argVarName); else fprintf(file, "\t%s(%s);\n", it->itDestructor, InArgMsgField(arg, "")); } } static void WriteDestroyPortArg(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; /* * If a translated port argument occurs in the body of a request * message, and the message is successfully processed, then the * port right should be deallocated. However, the called function * didn't see the port right; it saw the translation. So we have * to release the port right for it. * * The test over it->itInTrans will exclude any complex type * made out of ports */ if ((it->itInTrans != strNULL) && (it->itOutName == MACH_MSG_TYPE_PORT_SEND)) { fprintf(file, "\n"); fprintf(file, "\tif (IP_VALID((ipc_port_t)%s))\n", InArgMsgField(arg, "")); fprintf(file, "\t\tipc_port_release_send((ipc_port_t)%s);\n", InArgMsgField(arg, "")); } } /* * Check whether WriteDestroyPortArg would generate any code for arg. */ boolean_t CheckDestroyPortArg(argument_t *arg) { ipc_type_t *it = arg->argType; if ((it->itInTrans != strNULL) && (it->itOutName == MACH_MSG_TYPE_PORT_SEND)) { return TRUE; } return FALSE; } static void WriteServerCall(FILE *file, routine_t *rt, void (*func)(FILE *, argument_t *)) { argument_t *arg = rt->rtRetCode; ipc_type_t *it = arg->argType; boolean_t NeedClose = FALSE; fprintf(file, "\t"); if (akCheck(arg->argKind, akbVarNeeded)) fprintf(file, "%s = ", arg->argMsgField); else fprintf(file, "OutP->%s = ", arg->argMsgField); if (it->itOutTrans != strNULL) { fprintf(file, "%s(", it->itOutTrans); NeedClose = TRUE; } fprintf(file, "%s(", rt->rtServerName); WriteList(file, rt->rtArgs, func, akbServerArg, ", ", ""); if (NeedClose) fprintf(file, ")"); fprintf(file, ");\n"); } static void WriteCheckReturnValue(FILE *file, routine_t *rt) { argument_t *arg = rt->rtRetCode; char string[MAX_STR_LEN]; if (akCheck(arg->argKind, akbVarNeeded)) sprintf(string, "%s", arg->argMsgField); else sprintf(string, "OutP->%s", arg->argMsgField); fprintf(file, "\tif (%s != KERN_SUCCESS) {\n", string); fprintf(file, "\t\tMIG_RETURN_ERROR(OutP, %s);\n", string); fprintf(file, "\t}\n"); } /* * WriteInitKPD_port, WriteInitKPD_ool, WriteInitKPD_oolport * initializes the OutP KPD fields (this job cannot be done once * the target routine has been called, otherwise informations * would be lost) */ /* * argKPD_Init discipline for Port types. */ static void WriteInitKPD_port(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *subindex = ""; boolean_t close = FALSE; char firststring[MAX_STR_LEN]; char string[MAX_STR_LEN]; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, FALSE, arg, TRUE); (void)sprintf(firststring, "\t*ptr"); (void)sprintf(string, "\tptr->"); subindex = "[i]"; close = TRUE; } else { (void)sprintf(firststring, "OutP->%s", arg->argMsgField); (void)sprintf(string, "OutP->%s.", arg->argMsgField); } fprintf(file, "#if\tUseStaticTemplates\n"); fprintf(file, "\t%s = %s;\n", firststring, arg->argTTName); fprintf(file, "#else\t/* UseStaticTemplates */\n"); if (IS_MULTIPLE_KPD(it) && it->itVarArray) fprintf(file, "\t%sname = MACH_PORT_NULL;\n", string); if (arg->argPoly == argNULL) { if (IsKernelServer) { fprintf(file, "#if __MigKernelSpecificCode\n"); fprintf(file, "\t%sdisposition = %s;\n", string, it->itOutNameStr); fprintf(file, "#else\n"); } fprintf(file, "\t%sdisposition = %s;\n", string, it->itInNameStr); if (IsKernelServer) fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } fprintf(file, "#if !(defined(KERNEL) && defined(__LP64__))\n"); fprintf(file, "\t%spad1 = 0;\n", string); fprintf(file, "#endif\n"); fprintf(file, "\t%spad2 = 0;\n", string); fprintf(file, "\t%stype = MACH_MSG_PORT_DESCRIPTOR;\n", string); fprintf(file, "#if defined(KERNEL)\n"); fprintf(file, "\t%spad_end = 0;\n", string); fprintf(file, "#endif\n"); fprintf(file, "#endif\t/* UseStaticTemplates */\n"); if (close) fprintf(file, "\t }\n\t}\n"); fprintf(file, "\n"); } /* * argKPD_Init discipline for out-of-line types. */ static void WriteInitKPD_ool(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char firststring[MAX_STR_LEN]; char string[MAX_STR_LEN]; boolean_t VarArray; u_int howmany, howbig; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, FALSE, arg, TRUE); (void)sprintf(firststring, "\t*ptr"); (void)sprintf(string, "\tptr->"); VarArray = it->itElement->itVarArray; howmany = it->itElement->itNumber; howbig = it->itElement->itSize; } else { (void)sprintf(firststring, "OutP->%s", arg->argMsgField); (void)sprintf(string, "OutP->%s.", arg->argMsgField); VarArray = it->itVarArray; howmany = it->itNumber; howbig = it->itSize; } fprintf(file, "#if\tUseStaticTemplates\n"); fprintf(file, "\t%s = %s;\n", firststring, arg->argTTName); fprintf(file, "#else\t/* UseStaticTemplates */\n"); if (!VarArray) fprintf(file, "\t%ssize = %d;\n", string, (howmany * howbig + 7)/8); if (arg->argDeallocate != d_MAYBE) fprintf(file, "\t%sdeallocate = %s;\n", string, (arg->argDeallocate == d_YES) ? "TRUE" : "FALSE"); fprintf(file, "\t%scopy = %s;\n", string, (arg->argFlags & flPhysicalCopy) ? "MACH_MSG_PHYSICAL_COPY" : "MACH_MSG_VIRTUAL_COPY"); #ifdef ALIGNMENT fprintf(file, "\t%salignment = MACH_MSG_ALIGN_%d;\n", string, arg->argMsgField, (howbig < 8) ? 1 : howbig / 8); #endif fprintf(file, "\t%spad1 = 0;\n", string); fprintf(file, "\t%stype = MACH_MSG_OOL_DESCRIPTOR;\n", string); fprintf(file, "#if defined(KERNEL) && !defined(__LP64__)\n"); fprintf(file, "\t%spad_end = 0;\n", string); fprintf(file, "#endif\n"); fprintf(file, "#endif\t/* UseStaticTemplates */\n"); if (IS_MULTIPLE_KPD(it)) fprintf(file, "\t }\n\t}\n"); fprintf(file, "\n"); } /* * argKPD_Init discipline for out-of-line Port types. */ static void WriteInitKPD_oolport(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; boolean_t VarArray; ipc_type_t *howit; u_int howmany; char firststring[MAX_STR_LEN]; char string[MAX_STR_LEN]; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, FALSE, arg, TRUE); (void)sprintf(firststring, "\t*ptr"); (void)sprintf(string, "\tptr->"); VarArray = it->itElement->itVarArray; howmany = it->itElement->itNumber; howit = it->itElement; } else { (void)sprintf(firststring, "OutP->%s", arg->argMsgField); (void)sprintf(string, "OutP->%s.", arg->argMsgField); VarArray = it->itVarArray; howmany = it->itNumber; howit = it; } fprintf(file, "#if\tUseStaticTemplates\n"); fprintf(file, "\t%s = %s;\n", firststring, arg->argTTName); fprintf(file, "#else\t/* UseStaticTemplates */\n"); if (!VarArray) fprintf(file, "\t%scount = %d;\n", string, howmany); if (arg->argPoly == argNULL) { if (IsKernelServer) { fprintf(file, "#if\t__MigKernelSpecificCode\n"); fprintf(file, "\t%sdisposition = %s;\n", string, howit->itOutNameStr); fprintf(file, "#else\n"); } fprintf(file, "\t%sdisposition = %s;\n", string, howit->itInNameStr); if (IsKernelServer) fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } if (arg->argDeallocate != d_MAYBE) fprintf(file, "\t%sdeallocate = %s;\n", string, (arg->argDeallocate == d_YES) ? "TRUE" : "FALSE"); fprintf(file, "\t%stype = MACH_MSG_OOL_PORTS_DESCRIPTOR;\n", string); fprintf(file, "#endif\t/* UseStaticTemplates */\n"); if (IS_MULTIPLE_KPD(it)) fprintf(file, "\t }\n\t}\n"); fprintf(file, "\n"); } static void WriteInitKPDValue(FILE *file, argument_t *arg) { (*arg->argKPD_Init)(file, arg); } static void WriteAdjustMsgCircular(FILE *file, argument_t *arg) { fprintf(file, "\n"); fprintf(file,"#if\t__MigKernelSpecificCode\n"); if (arg->argType->itOutName == MACH_MSG_TYPE_POLYMORPHIC) fprintf(file, "\tif (%s == MACH_MSG_TYPE_PORT_RECEIVE)\n", arg->argPoly->argVarName); /* * The carried port right can be accessed in OutP->XXXX. Normally * the server function stuffs it directly there. If it is InOut, * then it has already been copied into the reply message. * If the server function deposited it into a variable (perhaps * because the reply message is variable-sized) then it has already * been copied into the reply message. * * The old MiG does not check for circularity in the case of * array of ports. So do I ... */ fprintf(file, "\t if (IP_VALID((ipc_port_t) In0P->Head.msgh_reply_port) &&\n"); fprintf(file, "\t IP_VALID((ipc_port_t) OutP->%s.name) &&\n", arg->argMsgField); fprintf(file, "\t ipc_port_check_circularity((ipc_port_t) OutP->%s.name, (ipc_port_t) In0P->Head.msgh_reply_port))\n", arg->argMsgField); fprintf(file, "\t\tOutP->Head.msgh_bits |= MACH_MSGH_BITS_CIRCULAR;\n"); fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } /* * argKPD_Pack discipline for Port types. */ static void WriteKPD_port(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *subindex = ""; char *recast = ""; boolean_t close = FALSE; char string[MAX_STR_LEN]; ipc_type_t *real_it; if (akCheck(arg->argKind, akbVarNeeded)) { if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, it->itVarArray, arg, TRUE); (void)sprintf(string, "\tptr->"); subindex = "[i]"; close = TRUE; real_it = it->itElement; } else { (void)sprintf(string, "OutP->%s.", arg->argMsgField); real_it = it; } #ifdef MIG_KERNEL_PORT_CONVERSIONS if (IsKernelServer && streql(real_it->itTransType, "ipc_port_t")) recast = "(mach_port_t)"; #endif if (it->itOutTrans != strNULL && !close) fprintf(file, "\t%sname = (mach_port_t)%s(%s);\n", string, it->itOutTrans, arg->argVarName); else fprintf(file, "\t%sname = %s%s%s;\n", string, recast, arg->argVarName, subindex); if (arg->argPoly != argNULL && akCheckAll(arg->argPoly->argKind, akbReturnSnd)) { argument_t *poly = arg->argPoly; if (akCheck(arg->argPoly->argKind, akbVarNeeded)) fprintf(file, "\t%sdisposition = %s;\n", string, poly->argVarName); else if (close) fprintf(file, "\t%sdisposition = OutP->%s;\n", string, poly->argSuffix); } if (close) fprintf(file, "\t }\n\t}\n"); fprintf(file, "\n"); } else if (arg->argPoly != argNULL && akCheckAll(arg->argPoly->argKind, akbReturnSnd|akbVarNeeded)) fprintf(file, "\tOutP->%s.disposition = %s;\n", arg->argMsgField, arg->argPoly->argVarName); /* * If this is a KernelServer, and the reply message contains * a receive right, we must check for the possibility of a * port/message circularity. If queueing the reply message * would cause a circularity, we mark the reply message * with the circular bit. */ if (IsKernelServer && !(IS_MULTIPLE_KPD(it)) && ((arg->argType->itOutName == MACH_MSG_TYPE_PORT_RECEIVE) || (arg->argType->itOutName == MACH_MSG_TYPE_POLYMORPHIC))) WriteAdjustMsgCircular(file, arg); } /* * argKPD_Pack discipline for out-of-line types. */ static void WriteKPD_ool(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char string[MAX_STR_LEN]; boolean_t VarArray; argument_t *count; u_int howbig; char *subindex; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, it->itVarArray, arg, TRUE); (void)sprintf(string, "\tptr->"); VarArray = it->itElement->itVarArray; count = arg->argSubCount; howbig = it->itElement->itSize; subindex = "[i]"; } else { (void)sprintf(string, "OutP->%s.", arg->argMsgField); VarArray = it->itVarArray; count = arg->argCount; howbig = it->itSize; subindex = ""; } if (akCheck(arg->argKind, akbVarNeeded)) fprintf(file, "\t%saddress = (void *)%s%s;\n", string, arg->argMsgField, subindex); if (arg->argDealloc != argNULL) if (akCheck(arg->argDealloc->argKind, akbVarNeeded) || IS_MULTIPLE_KPD(it)) fprintf(file, "\t%sdeallocate = %s;\n", string, arg->argDealloc->argVarName); if (VarArray) { fprintf(file, "\t%ssize = ", string); if (akCheck(count->argKind, akbVarNeeded)) fprintf(file, "%s%s", count->argName, subindex); else fprintf(file, "OutP->%s%s", count->argMsgField, subindex); if (count->argMultiplier > 1 || howbig > 8) fprintf(file, " * %d;\n", count->argMultiplier * howbig / 8); else fprintf(file, ";\n"); } if (IS_MULTIPLE_KPD(it)) { fprintf(file, "\t }\n"); if (it->itVarArray && !it->itElement->itVarArray) { fprintf(file, "\t for (i = j; i < %d; ptr++, i++)\n", it->itKPD_Number); /* since subordinate arrays aren't variable, they are initialized from template: here we must no-op 'em */ fprintf(file, "\t\tptr->size = 0;\n"); } fprintf(file, "\t}\n"); } fprintf(file, "\n"); } /* * argKPD_Pack discipline for out-of-line Port types. */ static void WriteKPD_oolport(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; boolean_t VarArray; argument_t *count; char *subindex, string[MAX_STR_LEN]; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, FALSE, it->itVarArray, arg, TRUE); (void)sprintf(string, "\tptr->"); VarArray = it->itElement->itVarArray; count = arg->argSubCount; subindex = "[i]"; } else { (void)sprintf(string, "OutP->%s.", arg->argMsgField); VarArray = it->itVarArray; count = arg->argCount; subindex = ""; } if (akCheck(arg->argKind, akbVarNeeded)) fprintf(file, "\t%saddress = (void *)%s%s;\n", string, arg->argMsgField, subindex); if (arg->argDealloc != argNULL) if (akCheck(arg->argDealloc->argKind, akbVarNeeded) || IS_MULTIPLE_KPD(it)) fprintf(file, "\t%sdeallocate = %s;\n", string, arg->argDealloc->argVarName); if (VarArray) { fprintf(file, "\t%scount = ", string); if (akCheck(count->argKind, akbVarNeeded)) fprintf(file, "%s%s;\n", count->argName, subindex); else fprintf(file, "OutP->%s%s;\n", count->argMsgField, subindex); } if (arg->argPoly != argNULL && akCheckAll(arg->argPoly->argKind, akbReturnSnd)) if (akCheck(arg->argPoly->argKind, akbVarNeeded) || IS_MULTIPLE_KPD(it)) fprintf(file, "\t%sdisposition = %s;\n", string, arg->argPoly->argVarName); if (IS_MULTIPLE_KPD(it)) { fprintf(file, "\t }\n"); if (it->itVarArray && !it->itElement->itVarArray) { fprintf(file, "\t for (i = j; i < %d; ptr++, i++)\n", it->itKPD_Number); /* since subordinate arrays aren't variable, they are initialized from template: here we must no-op 'em */ fprintf(file, "\t%scount = 0;\n", string); } fprintf(file, "\t}\n"); } fprintf(file, "\n"); } /* * argKPD_TypeCheck discipline for Port types. */ static void WriteTCheckKPD_port(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *tab = ""; char string[MAX_STR_LEN]; boolean_t close = FALSE; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, TRUE, FALSE, arg, TRUE); (void)sprintf(string, "ptr->"); tab = "\t"; close = TRUE; } else (void)sprintf(string, "In%dP->%s.", arg->argRequestPos, arg->argMsgField); fprintf(file, "\t%sif (%stype != MACH_MSG_PORT_DESCRIPTOR", tab, string); /* * We can't check disposition on varArray * (because some of the entries could be empty). */ if (!it->itVarArray) { if (arg->argPoly != argNULL) { switch (it->itOutName) { case MACH_MSG_TYPE_MOVE_RECEIVE: fprintf(file, " || \n\t%s %sdisposition != MACH_MSG_TYPE_MOVE_RECEIVE", tab, string); break; case MACH_MSG_TYPE_MOVE_SEND_ONCE: fprintf(file, " || (\n\t%s %sdisposition != MACH_MSG_TYPE_MOVE_SEND_ONCE", tab, string); fprintf(file, " && \n\t%s %sdisposition != MACH_MSG_TYPE_MAKE_SEND_ONCE)", tab, string); break; case MACH_MSG_TYPE_MOVE_SEND: fprintf(file, " || (\n\t%s %sdisposition != MACH_MSG_TYPE_MOVE_SEND", tab, string); fprintf(file, " && \n\t%s %sdisposition != MACH_MSG_TYPE_MAKE_SEND", tab, string); fprintf(file, " && \n\t%s %sdisposition != MACH_MSG_TYPE_COPY_SEND)", tab, string); break; } } else { fprintf(file, " ||\n\t%s %sdisposition != %s", tab, string, it->itOutNameStr); } } fprintf(file, ")\n"); fprintf(file, "\t\treturn MIG_TYPE_ERROR;\n"); if (close) fprintf(file, "\t }\n\t}\n"); } /* * argKPD_TypeCheck discipline for out-of-line types. */ static void WriteTCheckKPD_ool(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *tab, string[MAX_STR_LEN]; boolean_t test; u_int howmany, howbig; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, TRUE, FALSE, arg, TRUE); tab = "\t\t\t"; sprintf(string, "ptr->"); howmany = it->itElement->itNumber; howbig = it->itElement->itSize; test = !it->itVarArray && !it->itElement->itVarArray; } else { tab = ""; sprintf(string, "In%dP->%s.", arg->argRequestPos, arg->argMsgField); howmany = it->itNumber; howbig = it->itSize; test = !it->itVarArray; } fprintf(file, "\t%sif (%stype != MACH_MSG_OOL_DESCRIPTOR", tab, string); if (test) { /* if VarArray we may use no-op; if itElement->itVarArray size might change */ fprintf(file, " ||\n\t%s %ssize != %d", tab, string, (howmany * howbig + 7)/8); } fprintf(file, ")\n"); fprintf(file, "\t\t%s" "return MIG_TYPE_ERROR;\n", tab); if (IS_MULTIPLE_KPD(it)) fprintf(file, "\t }\n\t}\n"); } /* * argKPD_TypeCheck discipline for out-of-line Port types. */ static void WriteTCheckKPD_oolport(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; char *tab, string[MAX_STR_LEN]; boolean_t test; u_int howmany; char *howstr; if (IS_MULTIPLE_KPD(it)) { WriteKPD_Iterator(file, TRUE, FALSE, arg, TRUE); tab = "\t"; sprintf(string, "ptr->"); howmany = it->itElement->itNumber; test = !it->itVarArray && !it->itElement->itVarArray; howstr = it->itElement->itOutNameStr; } else { tab = ""; sprintf(string, "In%dP->%s.", arg->argRequestPos, arg->argMsgField); howmany = it->itNumber; test = !it->itVarArray; howstr = it->itOutNameStr; } fprintf(file, "\t%sif (%stype != MACH_MSG_OOL_PORTS_DESCRIPTOR", tab, string); if (test) /* if VarArray we may use no-op; if itElement->itVarArray size might change */ fprintf(file, " ||\n\t%s %scount != %d", tab, string, howmany); if (arg->argPoly == argNULL) fprintf(file, " ||\n\t%s %sdisposition != %s", tab, string, howstr); fprintf(file, ")\n"); fprintf(file, "\t\treturn MIG_TYPE_ERROR;\n"); if (IS_MULTIPLE_KPD(it)) fprintf(file, "\t }\n\t}\n"); } /************************************************************* * Writes code to check that the type of each of the arguments * in the reply message is what is expected. Called by * WriteRoutine for each in && typed argument in the request message. *************************************************************/ static void WriteTypeCheck(FILE *file, argument_t *arg) { fprintf(file, "#if\t__MigTypeCheck\n"); (*arg->argKPD_TypeCheck)(file, arg); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); } static void WritePackArgValueNormal(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; if (IS_VARIABLE_SIZED_UNTYPED(it) || it->itNoOptArray) { if (it->itString) { /* * Copy variable-size C string with mig_strncpy. * Save the string length (+ 1 for trailing 0) * in the argument`s count field. */ fprintf(file, "#ifdef USING_MIG_STRNCPY_ZEROFILL\n"); fprintf(file, "\tif (mig_strncpy_zerofill != NULL) {\n"); fprintf(file, "\t\tOutP->%s = (%s) mig_strncpy_zerofill(OutP->%s, %s, %d);\n", arg->argCount->argMsgField, arg->argCount->argType->itTransType, arg->argMsgField, arg->argVarName, it->itNumber); fprintf(file, "\t} else {\n"); fprintf(file, "#endif /* USING_MIG_STRNCPY_ZEROFILL */\n"); fprintf(file, "\t\tOutP->%s = (%s) mig_strncpy(OutP->%s, %s, %d);\n", arg->argCount->argMsgField, arg->argCount->argType->itTransType, arg->argMsgField, arg->argVarName, it->itNumber); fprintf(file, "#ifdef USING_MIG_STRNCPY_ZEROFILL\n"); fprintf(file, "\t}\n"); fprintf(file, "#endif /* USING_MIG_STRNCPY_ZEROFILL */\n"); fprintf(file, "\tOutP->%sOffset = 0;\n", arg->argMsgField); } else if (it->itNoOptArray) fprintf(file, "\t(void)memcpy((char *) OutP->%s, (const char *) %s, %d);\n", arg->argMsgField, arg->argVarName, it->itTypeSize); else { argument_t *count = arg->argCount; ipc_type_t *btype = it->itElement; identifier_t newstr; /* Note btype->itNumber == count->argMultiplier */ fprintf(file, "\t(void)memcpy((char *) OutP->%s, (const char *) %s, ", arg->argMsgField, arg->argVarName); if (btype->itTypeSize > 1) fprintf(file, "%d * ", btype->itTypeSize); /* count is a akbVarNeeded if arg is akbVarNeeded */ if (akCheck(count->argKind, akbVarNeeded)) newstr = count->argVarName; else newstr = (identifier_t)strconcat("OutP->", count->argMsgField); fprintf(file, "%s);\n", newstr); } } else if (it->itOutTrans != strNULL) WriteCopyType(file, it, TRUE, "OutP->%s", "/* %s */ %s(%s)", arg->argMsgField, it->itOutTrans, arg->argVarName); else WriteCopyType(file, it, TRUE, "OutP->%s", "/* %s */ %s", arg->argMsgField, arg->argVarName); if (arg->argPadName != NULL && it->itPadSize != 0) { fprintf(file, "\t for (int i = 0; i < %d; i++)\n", it->itPadSize); fprintf(file, "\t\t OutP->%s[i] = 0;\n", arg->argPadName); } } static void WritePackArgValueVariable(FILE *file, argument_t *arg) { ipc_type_t *it = arg->argType; /* * only itString are treated here so far */ if (it->itString) { /* * Emit logic to call strlen to calculate the size of the argument, and ensure that it fits within the 32-bit result field * in the Reply, when targeting a 64-bit architecture. If a 32-bit architecture is the target, we emit code to just call * strlen() directly (since it'll return a 32-bit value that is guaranteed to fit). */ fputs("#ifdef __LP64__\n", file); fprintf(file, "\t{\n" "\t\t" "size_t strLength = strlen(OutP->%s) + 1;\n", arg->argMsgField); fputs( "\t\t" "if (strLength > 0xffffffff)\n" "\t\t\t" "MIG_RETURN_ERROR(OutP, MIG_BAD_ARGUMENTS);\n", file); fprintf(file, "\t\t" "OutP->%s = (mach_msg_type_number_t) strLength;\n" "\t}\n", arg->argCount->argMsgField); fputs("#else\n", file); fprintf(file, "\tOutP->%s = (mach_msg_type_number_t) strlen(OutP->%s) + 1;\n", arg->argCount->argMsgField, arg->argMsgField); fputs("#endif /* __LP64__ */\n", file); } } static void WriteCopyArgValue(FILE *file, argument_t *arg) { fprintf(file, "\n"); WriteCopyType(file, arg->argType, TRUE, "/* %d */ OutP->%s", "In%dP->%s", arg->argRequestPos, (arg->argSuffix != strNULL) ? arg->argSuffix : arg->argMsgField); } static void WriteInitArgValue(FILE *file, argument_t *arg) { fprintf(file, "\n"); fprintf(file, "\tOutP->%s = %s;\n\n", arg->argMsgField, arg->argVarName); } /* * Calculate the size of a variable-length message field. */ static void WriteArgSize(FILE *file, argument_t *arg) { ipc_type_t *ptype = arg->argType; int bsize = ptype->itElement->itTypeSize; argument_t *count = arg->argCount; /* If the base type size of the data field isn`t a multiple of 4, we have to round up. */ if (bsize % itWordAlign != 0) fprintf(file, "_WALIGN_"); /* Here, we generate ((value + %d) & ~%d). We have to put two (( at the * the beginning. */ fprintf(file, "(("); if (bsize > 1) fprintf(file, "%d * ", bsize); if (ptype->itString || !akCheck(count->argKind, akbVarNeeded)) /* get count from descriptor in message */ fprintf(file, "OutP->%s", count->argMsgField); else /* get count from argument */ fprintf(file, "%s", count->argVarName); /* * If the base type size is not a multiple of sizeof(natural_t), * we have to round up. */ if (bsize % sizeof(natural_t) != 0) fprintf(file, " + %d) & ~%d)", (int)sizeof(natural_t)-1, (int)sizeof(natural_t)-1); else fprintf(file, "))"); } /* * Adjust message size and advance reply pointer. * Called after packing a variable-length argument that * has more arguments following. */ static void WriteAdjustMsgSize(FILE *file, argument_t *arg) { routine_t *rt = arg->argRoutine; ipc_type_t *ptype = arg->argType; /* There are more Out arguments. We need to adjust msgh_size and advance OutP, so we save the size of the current field in msgh_size_delta. */ fprintf(file, "\tmsgh_size_delta = "); WriteArgSize(file, arg); fprintf(file, ";\n"); if (rt->rtNumReplyVar == 1) { /* We can still address the message header directly. Fill in the size field. */ fprintf(file, "\tOutP->Head.msgh_size = "); rtMinReplySize(file, rt, "Reply"); fprintf(file, " + msgh_size_delta;\n"); } else if (arg->argReplyPos == 0) { /* First variable-length argument. The previous msgh_size value is the minimum reply size. */ fprintf(file, "\tmsgh_size = "); rtMinReplySize(file, rt, "Reply"); fprintf(file, " + msgh_size_delta;\n"); } else fprintf(file, "\tmsgh_size += msgh_size_delta;\n"); fprintf(file, "\tOutP = (Reply *) ((pointer_t) OutP + msgh_size_delta - %d);\n", ptype->itTypeSize + ptype->itPadSize); } /* * Calculate the size of the message. Called after the * last argument has been packed. */ static void WriteFinishMsgSize(FILE *file, argument_t *arg) { /* No more Out arguments. If this is the only variable Out argument, we can assign to msgh_size directly. */ if (arg->argReplyPos == 0) { fprintf(file, "\tOutP->Head.msgh_size = "); rtMinReplySize(file, arg->argRoutine, "Reply"); fprintf(file, " + ("); WriteArgSize(file, arg); fprintf(file, ");\n"); } else { fprintf(file, "\tmsgh_size += "); WriteArgSize(file, arg); fprintf(file, ";\n"); } } /* * Handle reply arguments - fill in message types and copy arguments * that need to be copied. */ static void WriteReplyArgs(FILE *file, routine_t *rt) { argument_t *arg; argument_t *lastVarArg; /* * 1. The Kernel Processed Data */ for (arg = rt->rtArgs; arg != argNULL; arg = arg->argNext) if (akCheckAll(arg->argKind, akbReturnSnd|akbReturnKPD)) (*arg->argKPD_Pack)(file, arg); /* * 2. The Data Stream */ lastVarArg = argNULL; for (arg = rt->rtArgs; arg != argNULL; arg = arg->argNext) { /* * Adjust message size and advance message pointer if * the last request argument was variable-length and the * request position will change. */ if (lastVarArg != argNULL && lastVarArg->argReplyPos < arg->argReplyPos) { WriteAdjustMsgSize(file, lastVarArg); lastVarArg = argNULL; } if (akCheckAll(arg->argKind, akbReturnSnd|akbReturnBody|akbVarNeeded)) WritePackArgValueNormal(file, arg); else if (akCheckAll(arg->argKind, akbReturnSnd|akbReturnBody|akbVariable)) WritePackArgValueVariable(file, arg); if (akCheck(arg->argKind, akbReplyCopy)) WriteCopyArgValue(file, arg); if (akCheck(arg->argKind, akbReplyInit)) WriteInitArgValue(file, arg); /* * Remember whether this was variable-length. */ if (akCheckAll(arg->argKind, akbReturnSnd|akbReturnBody|akbVariable)) lastVarArg = arg; } /* * Finish the message size. */ if (lastVarArg != argNULL) WriteFinishMsgSize(file, lastVarArg); } static void WriteFieldDecl(FILE *file, argument_t *arg) { if (akCheck(arg->argKind, akbSendKPD) || akCheck(arg->argKind, akbReturnKPD)) WriteFieldDeclPrim(file, arg, FetchKPDType); else WriteFieldDeclPrim(file, arg, FetchServerType); } static void InitKPD_Disciplines(argument_t *args) { argument_t *arg; extern void KPD_noop(FILE *file, argument_t *arg); extern void KPD_error(FILE *file, argument_t *arg); extern void WriteTemplateKPD_port(FILE *file, argument_t *arg, boolean_t in); extern void WriteTemplateKPD_ool(FILE *file, argument_t *arg, boolean_t in); extern void WriteTemplateKPD_oolport(FILE *file, argument_t *arg, boolean_t in); /* * WriteInitKPD_port, WriteKPD_port, WriteExtractKPD_port, * WriteInitKPD_ool, WriteKPD_ool, WriteExtractKPD_ool, * WriteInitKPD_oolport, WriteKPD_oolport, WriteExtractKPD_oolport * are local to this module (which is the reason why this initialization * takes place here rather than in utils.c). * Common routines for user and server will be established SOON, and * all of them (including the initialization) will be transfert to * utils.c * All the KPD disciplines are defaulted to be KPD_error(). * Note that akbSendKPD and akbReturnKPd are not exclusive, * because of inout type of parameters. */ for (arg = args; arg != argNULL; arg = arg->argNext) if (akCheck(arg->argKind, akbSendKPD|akbReturnKPD)) switch (arg->argKPD_Type) { case MACH_MSG_PORT_DESCRIPTOR: if akCheck(arg->argKind, akbSendKPD) { arg->argKPD_Extract = (IS_MULTIPLE_KPD(arg->argType)) ? WriteExtractKPD_port : WriteExtractArgValue; arg->argKPD_TypeCheck = WriteTCheckKPD_port; } if akCheck(arg->argKind, akbReturnKPD) { arg->argKPD_Template = WriteTemplateKPD_port; arg->argKPD_Init = WriteInitKPD_port; arg->argKPD_Pack = WriteKPD_port; } break; case MACH_MSG_OOL_DESCRIPTOR: if akCheck(arg->argKind, akbSendKPD) { arg->argKPD_Extract = (IS_MULTIPLE_KPD(arg->argType)) ? WriteExtractKPD_ool : WriteExtractArgValue; arg->argKPD_TypeCheck = WriteTCheckKPD_ool; } if akCheck(arg->argKind, akbReturnKPD) { arg->argKPD_Template = WriteTemplateKPD_ool; arg->argKPD_Init = WriteInitKPD_ool; arg->argKPD_Pack = WriteKPD_ool; } break; case MACH_MSG_OOL_PORTS_DESCRIPTOR: if akCheck(arg->argKind, akbSendKPD) { arg->argKPD_Extract = (IS_MULTIPLE_KPD(arg->argType)) ? WriteExtractKPD_oolport : WriteExtractArgValue; arg->argKPD_TypeCheck = WriteTCheckKPD_oolport; } if akCheck(arg->argKind, akbReturnKPD) { arg->argKPD_Template = WriteTemplateKPD_oolport; arg->argKPD_Init = WriteInitKPD_oolport; arg->argKPD_Pack = WriteKPD_oolport; } break; default: printf("MiG internal error: type of kernel processed data unknown\n"); exit(1); } /* end of switch */ } static void WriteStringTerminatorCheck(FILE *file, routine_t *rt) { // generate code to verify that the length of a C string is not greater than the size of the // buffer in which it is stored. argument_t *argPtr; int msg_limit_calculated = FALSE; int found_string_argument = FALSE; int variable_length_args_present = (rt->rtMaxRequestPos > 0); // scan through arguments to see if there are any strings for (argPtr = rt->rtArgs; argPtr != NULL; argPtr = argPtr->argNext) { if ((argPtr->argKind & akbRequest) && argPtr->argType->itString) { found_string_argument = TRUE; break; } } if (found_string_argument) { // create a new scope, for local variables fputs("#if __MigTypeCheck\n" "\t" "{" "\n", file); for (argPtr = rt->rtArgs; argPtr != NULL; argPtr = argPtr->argNext) { if ((argPtr->argKind & akbRequest) && argPtr->argType->itString) { //fprintf(stderr, "### found itString: variable name = %s, max length = %d\n", argPtr->argName, argPtr->argType->itNumber); if (!msg_limit_calculated) { msg_limit_calculated = TRUE; // only need to do this once fputs("\t\t" "char * msg_limit = ((char *) In0P) + In0P->Head.msgh_size;\n", file); if (IsKernelServer) { fputs("#if __MigKernelSpecificCode\n", file); fputs("\t\t" "size_t strnlen_limit;" "\n", file); fputs("#else\n", file); } fputs("\t\t" "size_t memchr_limit;" "\n", file); if (IsKernelServer) { fputs("#endif /* __MigKernelSpecificCode */" "\n", file); } fputc('\n', file); } // I would really prefer to use strnlen() here, to ensure that the byte scanning logic does not extend beyond // the end of the buffer, but it's not necessarily guaranteed to be available. Instead, I'll use memchr(), // and let it look for the terminating null byte. // (later...) // It turns out that the kernel does not have memchr() available, but strnlen() IS available, so we'll just // have to emit some conditional code to use the appropriate runtime environment scanning function. // if (IsKernelServer) { fputs("#if __MigKernelSpecificCode\n", file); fputs("\t\t" "strnlen_limit = min((msg_limit - ", file); // If there are variable-length arguments within the message, the proper (adjusted) // pointers must be used to access those strings fprintf(file, "In%dP->%s), %d);" "\n", (variable_length_args_present ? argPtr->argRequestPos : 0), argPtr->argName, argPtr->argType->itNumber); fputs("\t\t" "if (", file); fprintf(file, "( strnlen(In%dP->%s, strnlen_limit) >= %d + 1 )", (variable_length_args_present ? argPtr->argRequestPos : 0), argPtr->argName, argPtr->argType->itNumber); fputs(")" "\n" "\t\t\t" "return MIG_BAD_ARGUMENTS; // string length exceeds buffer length!" "\n", file); fputs("#else\n", file); } // If there are variable-length arguments within the message, the proper (adjusted) // pointers must be used to access those strings fprintf(file, "\t\t" "memchr_limit = min((msg_limit - In%dP->%s), %d);" "\n", (variable_length_args_present ? argPtr->argRequestPos : 0), argPtr->argName, argPtr->argType->itNumber); fputs("\t\t" "if (", file); fprintf(file, "( memchr(In%dP->%s, '\\0', memchr_limit) == NULL )", (variable_length_args_present ? argPtr->argRequestPos : 0), argPtr->argName); fputs(")" "\n" "\t\t\t" "return MIG_BAD_ARGUMENTS; // string length exceeds buffer length!" "\n", file); if (IsKernelServer) { fputs("#endif /* __MigKernelSpecificCode */" "\n", file); } } } fputs("\t" "}" "\n" "#endif" "\t" "/* __MigTypeCheck */" "\n\n", file); // terminate new scope } return; } static void WriteOOLSizeCheck(FILE *file, routine_t *rt) { /* Emit code to validate the actual size of ool data vs. the reported size */ argument_t *argPtr; boolean_t openedTypeCheckConditional = FALSE; // scan through arguments to see if there are any ool data blocks for (argPtr = rt->rtArgs; argPtr != NULL; argPtr = argPtr->argNext) { if (akCheck(argPtr->argKind, akbSendKPD)) { ipc_type_t *it = argPtr->argType; boolean_t multiple_kpd = IS_MULTIPLE_KPD(it); char string[MAX_STR_LEN]; boolean_t test; argument_t *argCountPtr; char *tab; if (argPtr->argKPD_Type == MACH_MSG_OOL_DESCRIPTOR) { if (multiple_kpd) { if ( !openedTypeCheckConditional ) { openedTypeCheckConditional = TRUE; fputs("#if __MigTypeCheck\n", file); } WriteKPD_Iterator(file, TRUE, FALSE, argPtr, TRUE); tab = "\t"; sprintf(string, "ptr->"); test = !it->itVarArray && !it->itElement->itVarArray; it = it->itElement; // point to element descriptor, so size calculation is correct argCountPtr = argPtr->argSubCount; } else { tab = ""; sprintf(string, "In%dP->%s.", argPtr->argRequestPos, argPtr->argMsgField); test = !it->itVarArray; argCountPtr = argPtr->argCount; } if (!test) { int multiplier = (argCountPtr->argMultiplier > 1 || it->itSize > 8) ? argCountPtr->argMultiplier * it->itSize / 8 : 1; if ( !openedTypeCheckConditional ) { openedTypeCheckConditional = TRUE; fputs("#if __MigTypeCheck\n", file); } fprintf(file, "\t%s" "if (%ssize ", tab, string); if (multiplier > 1) fprintf(file, "/ %d ", multiplier); fprintf(file,"!= In%dP->%s%s", argCountPtr->argRequestPos, argCountPtr->argVarName, multiple_kpd ? "[i]" : ""); if (it->itOOL_Number) { fprintf(file," || In%dP->%s%s > %d", argCountPtr->argRequestPos, argCountPtr->argVarName, multiple_kpd ? "[i]" : "", it->itOOL_Number); } fprintf(file,")\n"); fprintf(file, "\t\t%s" "return MIG_TYPE_ERROR;\n", tab); } if (multiple_kpd) fprintf(file, "\t }\n\t}\n"); } else if (argPtr->argKPD_Type == MACH_MSG_OOL_PORTS_DESCRIPTOR) { if (multiple_kpd) { if ( !openedTypeCheckConditional ) { openedTypeCheckConditional = TRUE; fputs("#if __MigTypeCheck\n", file); } WriteKPD_Iterator(file, TRUE, FALSE, argPtr, TRUE); tab = "\t"; sprintf(string, "ptr->"); test = !it->itVarArray && !it->itElement->itVarArray; it = it->itElement; // point to element descriptor, so size calculation is correct argCountPtr = argPtr->argSubCount; } else { tab = ""; sprintf(string, "In%dP->%s.", argPtr->argRequestPos, argPtr->argMsgField); test = !it->itVarArray; argCountPtr = argPtr->argCount; } if (!test) { if ( !openedTypeCheckConditional ) { openedTypeCheckConditional = TRUE; fputs("#if __MigTypeCheck\n", file); } fprintf(file, "\t%s" "if (%scount ", tab, string); fprintf(file,"!= In%dP->%s%s", argCountPtr->argRequestPos, argCountPtr->argVarName, multiple_kpd ? "[i]" : ""); if (it->itOOL_Number) { fprintf(file," || In%dP->%s%s > %d", argCountPtr->argRequestPos, argCountPtr->argVarName, multiple_kpd ? "[i]" : "", it->itOOL_Number); } fprintf(file,")\n"); fprintf(file, "\t\t%s" "return MIG_TYPE_ERROR;\n", tab); } if (multiple_kpd) fprintf(file, "\t }\n\t}\n"); } } } if ( openedTypeCheckConditional ) fputs("#endif" "\t" "/* __MigTypeCheck */" "\n\n", file); } void WriteCheckRequest(FILE *file, routine_t *rt) { int i; /* initialize the disciplines for the handling of KPDs */ InitKPD_Disciplines(rt->rtArgs); fprintf(file, "\n"); fprintf(file, "#if ( __MigTypeCheck "); if (CheckNDR) fprintf(file, "|| __NDR_convert__ "); fprintf(file, ")\n"); fprintf(file, "#if __MIG_check__Request__%s_subsystem__\n", SubsystemName); fprintf(file, "#if !defined(__MIG_check__Request__%s_t__defined)\n", rt->rtName); fprintf(file, "#define __MIG_check__Request__%s_t__defined\n", rt->rtName); if (CheckNDR && akCheck(rt->rtNdrCode->argKind, akbRequest)) { WriteList(file, rt->rtArgs, WriteRequestNDRConvertIntRepArgDecl, akbSendNdr, "", ""); WriteList(file, rt->rtArgs, WriteRequestNDRConvertCharRepArgDecl, akbSendNdr, "", ""); WriteList(file, rt->rtArgs, WriteRequestNDRConvertFloatRepArgDecl, akbSendNdr, "", ""); } fprintf(file, "\n"); fprintf(file, "mig_internal kern_return_t __MIG_check__Request__%s_t(__attribute__((__unused__)) __Request__%s_t *In0P", rt->rtName, rt->rtName); for (i = 1; i <= rt->rtMaxRequestPos; i++) fprintf(file, ", __attribute__((__unused__)) __Request__%s_t **In%dPP", rt->rtName, i); fprintf(file, ")\n{\n"); fprintf(file, "\n\ttypedef __Request__%s_t __Request;\n", rt->rtName); for (i = 1; i <= rt->rtMaxRequestPos; i++) fprintf(file, "\t__Request *In%dP;\n", i); if (rt->rtNumRequestVar > 0) { fprintf(file, "#if\t__MigTypeCheck\n"); fprintf(file, "\tunsigned int msgh_size;\n"); fprintf(file, "#endif\t/* __MigTypeCheck */\n"); } if (rt->rtMaxRequestPos > 0) fprintf(file, "\tunsigned int msgh_size_delta;\n"); if (rt->rtNumRequestVar > 0 || rt->rtMaxRequestPos > 0) fprintf(file, "\n"); WriteCheckHead(file, rt); WriteList(file, rt->rtArgs, WriteTypeCheck, akbSendKPD, "\n", "\n"); { argument_t *arg, *lastVarArg; lastVarArg = argNULL; for (arg = rt->rtArgs; arg != argNULL; arg = arg->argNext) { if (lastVarArg != argNULL && lastVarArg->argRequestPos < arg->argRequestPos) { WriteAdjustRequestMsgPtr(file, lastVarArg); lastVarArg = argNULL; } if (akCheckAll(arg->argKind, akbSendRcv|akbSendBody)) { if (akCheck(arg->argKind, akbVariable)) { WriteCheckMsgSize(file, arg); lastVarArg = arg; } } } } if (CheckNDR && akCheck(rt->rtNdrCode->argKind, akbRequest)) { fprintf(file, "#if\t"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertIntRepArgCond, akbSendNdr, " || \\\n\t", "\n"); fprintf(file, "\tif (In0P->NDR.int_rep != NDR_record.int_rep) {\n"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertIntRepArgUse, akbSendNdr, "", ""); fprintf(file, "\t}\n#endif\t/* defined(__NDR_convert__int_rep...) */\n\n"); WriteOOLSizeCheck(file, rt); fprintf(file, "#if\t"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertCharRepArgCond, akbSendNdr, " || \\\n\t", "\n"); fprintf(file, "\tif (In0P->NDR.char_rep != NDR_record.char_rep) {\n"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertCharRepArgUse, akbSendNdr, "", ""); fprintf(file, "\t}\n#endif\t/* defined(__NDR_convert__char_rep...) */\n\n"); fprintf(file, "#if\t"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertFloatRepArgCond, akbSendNdr, " || \\\n\t", "\n"); fprintf(file, "\tif (In0P->NDR.float_rep != NDR_record.float_rep) {\n"); WriteList(file, rt->rtArgs, WriteRequestNDRConvertFloatRepArgUse, akbSendNdr, "", ""); fprintf(file, "\t}\n#endif\t/* defined(__NDR_convert__float_rep...) */\n\n"); } else { WriteOOLSizeCheck(file, rt); } WriteStringTerminatorCheck(file, rt); fprintf(file, "\treturn MACH_MSG_SUCCESS;\n"); fprintf(file, "}\n"); fprintf(file, "#endif /* !defined(__MIG_check__Request__%s_t__defined) */\n", rt->rtName); fprintf(file, "#endif /* __MIG_check__Request__%s_subsystem__ */\n", SubsystemName); fprintf(file, "#endif /* ( __MigTypeCheck "); if (CheckNDR) fprintf(file, "|| __NDR_convert__ "); fprintf(file, ") */\n"); fprintf(file, "\n"); } void WriteCheckRequestCall(FILE *file, routine_t *rt) { int i; fprintf(file, "\n"); fprintf(file, "#if\tdefined(__MIG_check__Request__%s_t__defined)\n", rt->rtName); fprintf(file, "\tcheck_result = __MIG_check__Request__%s_t((__Request *)In0P", rt->rtName); for (i = 1; i <= rt->rtMaxRequestPos; i++) fprintf(file, ", (__Request **)&In%dP", i); fprintf(file, ");\n"); fprintf(file, "\tif (check_result != MACH_MSG_SUCCESS)\n"); fprintf(file, "\t\t{ MIG_RETURN_ERROR(OutP, check_result); }\n"); fprintf(file, "#endif\t/* defined(__MIG_check__Request__%s_t__defined) */\n", rt->rtName); fprintf(file, "\n"); } void WriteCheckRequests(FILE *file, statement_t *stats) { statement_t *stat; for (stat = stats; stat != stNULL; stat = stat->stNext) if (stat->stKind == skRoutine) WriteCheckRequest(file, stat->stRoutine); } static void WriteRoutine(FILE *file, routine_t *rt) { /* Declare the server work function: */ if (ServerHeaderFileName == strNULL) WriteServerRoutine(file, rt); fprintf(file, "\n"); fprintf(file, "/* %s %s */\n", rtRoutineKindToStr(rt->rtKind), rt->rtName); fprintf(file, "mig_internal novalue _X%s\n", rt->rtName); if (BeAnsiC) { fprintf(file, "\t(mach_msg_header_t *InHeadP, mach_msg_header_t *OutHeadP)\n"); } else { fprintf(file, "#if\t%s\n", NewCDecl); fprintf(file, "\t(mach_msg_header_t *InHeadP, mach_msg_header_t *OutHeadP)\n"); fprintf(file, "#else\n"); fprintf(file, "\t(InHeadP, OutHeadP)\n"); fprintf(file, "\tmach_msg_header_t *InHeadP, *OutHeadP;\n"); fprintf(file, "#endif\t/* %s */\n", NewCDecl); } fprintf(file, "{\n"); WriteStructDecl(file, rt->rtArgs, WriteFieldDecl, akbRequest, "Request", rt->rtSimpleRequest, TRUE, rt->rtServerImpl, FALSE); fprintf(file, "\ttypedef __Request__%s_t __Request;\n", rt->rtName); fprintf(file, "\ttypedef __Reply__%s_t Reply __attribute__((unused));\n\n", rt->rtName); /* * Define a Minimal Reply structure to be used in case of errors */ fprintf(file, "\t/*\n"); fprintf(file, "\t * typedef struct {\n"); fprintf(file, "\t * \tmach_msg_header_t Head;\n"); fprintf(file, "\t * \tNDR_record_t NDR;\n"); fprintf(file, "\t * \tkern_return_t RetCode;\n"); fprintf(file, "\t * } mig_reply_error_t;\n"); fprintf(file, "\t */\n"); fprintf(file, "\n"); WriteVarDecls(file, rt); if (IsKernelServer) { fprintf(file, "#if\t__MigKernelSpecificCode\n"); WriteList(file, rt->rtArgs, WriteTemplateDeclOut, akbReturnKPD, "\n", "\n"); fprintf(file, "#else\n"); } WriteList(file, rt->rtArgs, WriteTemplateDeclIn, akbReturnKPD, "\n", "\n"); if (IsKernelServer) { fprintf(file, "#endif /* __MigKernelSpecificCode */\n"); } WriteRetCode(file, rt->rtRetCode); WriteList(file, rt->rtArgs, WriteLocalVarDecl, akbVarNeeded | akbServerArg, ";\n", ";\n\n"); WriteApplMacro(file, "Rcv", "Declare", rt); WriteApplMacro(file, "Rcv", "Before", rt); if (rt->rtRetCArg != argNULL && !rt->rtSimpleRequest) { WriteRetCArgCheckError(file, rt); if (rt->rtServerImpl) WriteCheckTrailerHead(file, rt, FALSE); WriteServerCall(file, rt, WriteConditionalCallArg); WriteRetCArgFinishError(file, rt); } WriteCheckRequestCall(file, rt); WriteCheckRequestTrailerArgs(file, rt); /* * Initialize the KPD records in the Reply structure with the * templates. We do this beforehand because the call to the procedure * will overwrite some of the values (after the call it would be impossible * to initialize the KPD records from the static Templates, because we * would lose data). */ WriteList(file, rt->rtArgs, WriteInitKPDValue, akbReturnKPD, "\n", "\n"); WriteList(file, rt->rtArgs, WriteExtractArg, akbNone, "", ""); if (UseEventLogger) WriteLogMsg(file, rt, LOG_SERVER, LOG_REQUEST); WriteServerCall(file, rt, WriteServerCallArg); WriteReverseList(file, rt->rtArgs, WriteDestroyArg, akbDestroy, "", ""); /* * For one-way routines, it doesn`t make sense to check the return * code, because we return immediately afterwards. However, * kernel servers may want to deallocate port arguments - and the * deallocation must not be done if the return code is not KERN_SUCCESS. */ if (rt->rtOneWay || rt->rtNoReplyArgs) { if (IsKernelServer) { fprintf(file,"#if\t__MigKernelSpecificCode\n"); if (rtCheckMaskFunction(rt->rtArgs, akbSendKPD, CheckDestroyPortArg)) { WriteCheckReturnValue(file, rt); } WriteReverseList(file, rt->rtArgs, WriteDestroyPortArg, akbSendKPD, "", ""); fprintf(file,"#endif /* __MigKernelSpecificCode */\n"); } /* although we have an empty reply, we still have to make sure that some fields such as NDR get properly initialized */ if (!rt->rtOneWay) WriteList(file, rt->rtArgs, WriteInitArgValue, akbReplyInit, "\n", "\n"); } else { WriteCheckReturnValue(file, rt); if (IsKernelServer) { fprintf(file,"#if\t__MigKernelSpecificCode\n"); WriteReverseList(file, rt->rtArgs, WriteDestroyPortArg, akbSendKPD, "", ""); fprintf(file,"#endif /* __MigKernelSpecificCode */\n"); } WriteReplyArgs(file, rt); WriteReplyInit(file, rt); if (!rt->rtSimpleReply) fprintf(file, "\tOutP->msgh_body.msgh_descriptor_count = %d;\n", rt->rtReplyKPDs); } if (UseEventLogger) WriteLogMsg(file, rt, LOG_SERVER, LOG_REPLY); WriteApplMacro(file, "Rcv", "After", rt); fprintf(file, "}\n"); } void WriteServer(FILE *file, statement_t *stats) { statement_t *stat; WriteProlog(file, stats); if (BeAnsiC) WriteForwardDeclarations(file, stats); for (stat = stats; stat != stNULL; stat = stat->stNext) switch (stat->stKind) { case skRoutine: WriteCheckRequest(file, stat->stRoutine); WriteRoutine(file, stat->stRoutine); break; case skIImport: case skImport: case skSImport: case skDImport: case skUImport: break; default: fatal("WriteServer(): bad statement_kind_t (%d)", (int) stat->stKind); } WriteDispatcher(file, stats); }