/* $Id: VBoxCompilerPlugInsGcc.cpp 57353 2015-08-14 14:31:09Z vboxsync $ */ /** @file * gccplugin - GCC plugin for checking IPRT format strings. */ /* * Copyright (C) 2006-2015 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #include #include #include #if __GNUC__ == 4 && __GNUC_MINOR__ == 5 # include "gmp.h" extern "C" { #endif #if __GNUC__ == 4 && __GNUC_MINOR__ == 5 # include "coretypes.h" #endif #include "plugin.h" #include "gimple.h" #include "basic-block.h" #include "tree.h" #include "tree-pass.h" #include "cp/cp-tree.h" #if __GNUC__ == 4 && __GNUC_MINOR__ == 5 } #endif #include "VBoxCompilerPlugIns.h" /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** License indicator. */ int plugin_is_GPL_compatible; /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /** Convencience macro not present in earlier gcc versions. */ #ifndef VAR_P # define VAR_P(a_hNode) (TREE_CODE(a_hNode) == VAR_DECL) #endif /** For use with messages. * @todo needs some more work... Actually, seems we're a bit handicapped by * working on gimplified stuff. */ #define MY_LOC(a_hPreferred, a_pState) EXPR_LOC_OR_LOC(a_hPreferred, (a_pState)->hFmtLoc) /** @name Compatibility glue * @{ */ #if __GNUC__ == 4 && __GNUC_MINOR__ == 5 # define linemap_location_from_macro_expansion_p(a, b) false #endif #if __GNUC__ == 4 && __GNUC_MINOR__ == 5 static tree gimple_call_fntype(gimple hStmt) { tree hDecl = gimple_call_fndecl(hStmt); if (hDecl) return TREE_TYPE(hDecl); hDecl = gimple_call_fn(hStmt); if (TREE_CODE(hDecl) == OBJ_TYPE_REF) hDecl = OBJ_TYPE_REF_EXPR(hDecl); if (DECL_P(hDecl)) { tree hType = TREE_TYPE(hDecl); if (POINTER_TYPE_P(hType)) hType = TREE_TYPE(hType); return hType; } return NULL_TREE; /* caller bitches about this*/ } #endif #if __GNUC__ > 4 || __GNUC_MINOR__ > 5 # define MY_INT_FITS_SHWI(hNode) (hNode).fits_shwi() # define MY_INT_TO_SHWI(hNode) (hNode).to_shwi() #else # define MY_INT_FITS_SHWI(hNode) double_int_fits_in_shwi_p(hNode) # define MY_INT_TO_SHWI(hNode) double_int_to_shwi(hNode) #endif #ifndef EXPR_LOC_OR_LOC # define EXPR_LOC_OR_LOC(a,b) (b) #endif /** @} */ /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ static bool MyPassGateCallback(void); static unsigned int MyPassExecuteCallback(void); static tree AttributeHandler(tree *, tree, tree, int, bool *); /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** Plug-in info. */ static const struct plugin_info g_PlugInInfo = { version: "0.0.0-ALPHA", help : "Implements the __iprt_format__ attribute for checking format strings and arguments." }; /** My pass. */ static struct gimple_opt_pass g_MyPass = { pass: { type : GIMPLE_PASS, name : "*iprt-format-checks", /* asterisk = no dump */ #if __GNUC__ != 4 || __GNUC_MINOR__ != 5 optinfo_flags : 0, #endif gate : MyPassGateCallback, execute : MyPassExecuteCallback, sub : NULL, next : NULL, static_pass_number : 0, tv_id : TV_NONE, properties_required : 0, properties_provided : 0, properties_destroyed : 0, todo_flags_start : 0, todo_flags_finish : 0, } }; /** The registration info for my pass. */ static const struct register_pass_info g_MyPassInfo = { pass : &g_MyPass.pass, reference_pass_name : "ssa", ref_pass_instance_number : 1, pos_op : PASS_POS_INSERT_BEFORE, }; /** Attribute specifications. */ static const struct attribute_spec g_AttribSpecs[] = { { name : "iprt_format", min_length : 2, max_length : 2, decl_required : false, type_required : true, function_type_required : true, handler : AttributeHandler, #if __GNUC__ != 4 || __GNUC_MINOR__ != 5 affects_type_identity : false #endif }, { name : "iprt_format_maybe_null", min_length : 2, max_length : 2, decl_required : false, type_required : true, function_type_required : true, handler : AttributeHandler, #if __GNUC__ != 4 || __GNUC_MINOR__ != 5 affects_type_identity : false #endif } }; #ifdef DEBUG /** * Debug function for printing the scope of a decl. * @param hDecl Declaration to print scope for. */ static void dprintScope(tree hDecl) { # if 0 /* later? */ tree hScope = CP_DECL_CONTEXT(hDecl); if (hScope == global_namespace) return; if (TREE_CODE(hScope) == RECORD_TYPE) hScope = TYPE_NAME(hScope); /* recurse */ dprintScope(hScope); /* name the scope. */ dprintf("::%s", DECL_NAME(hScope) ? IDENTIFIER_POINTER(DECL_NAME(hScope)) : ""); # endif } /** * Debug function for printing a declaration. * @param hDecl The declaration to print. */ static void dprintDecl(tree hDecl) { enum tree_code const enmDeclCode = TREE_CODE(hDecl); tree const hType = TREE_TYPE(hDecl); enum tree_code const enmTypeCode = hType ? TREE_CODE(hType) : (enum tree_code)-1; #if 0 if ( enmTypeCode == RECORD_TYPE && enmDeclCode == TYPE_DECL && DECL_ARTIFICIAL(hDecl)) dprint_class(hType); #endif dprintf("%s ", tree_code_name[enmDeclCode]); dprintScope(hDecl); dprintf("::%s", DECL_NAME(hDecl) ? IDENTIFIER_POINTER(DECL_NAME(hDecl)) : ""); if (hType) dprintf(" type %s", tree_code_name[enmTypeCode]); dprintf(" @%s:%d", DECL_SOURCE_FILE(hDecl), DECL_SOURCE_LINE(hDecl)); } #endif /* DEBUG */ static location_t MyGetLocationPlusColumnOffset(location_t hLoc, unsigned int offColumn) { /* * Skip NOOPs, reserved locations and macro expansion. */ if ( offColumn != 0 && hLoc >= RESERVED_LOCATION_COUNT && !linemap_location_from_macro_expansion_p(line_table, hLoc)) { #if __GNUC__ >= 5 /** @todo figure this... */ /* * There is an API for doing this, nice. */ location_t hNewLoc = linemap_position_for_loc_and_offset(line_table, hLoc, offColumn); if (hNewLoc && hNewLoc != hLoc) { dprintf("MyGetLocationPlusColumnOffset: hNewLoc=%#x hLoc=%#x offColumn=%u\n", hNewLoc, hLoc, offColumn); return hNewLoc; } #elif __GNUC_MINOR__ > 5 /* * Have to do the job ourselves, it seems. This is a bit hairy... */ line_map const *pMap = NULL; location_t hLoc2 = linemap_resolve_location(line_table, hLoc, LRK_SPELLING_LOCATION, &pMap); if (hLoc2) hLoc = hLoc2; /* Guard against wrap arounds and overlaps. */ if ( hLoc + offColumn > MAP_START_LOCATION(pMap) /** @todo Use MAX_SOURCE_LOCATION? */ && ( pMap == LINEMAPS_LAST_ORDINARY_MAP(line_table) || hLoc + offColumn < MAP_START_LOCATION((pMap + 1)))) { /* Calc new column and check that it's within the valid range. */ unsigned int uColumn = SOURCE_COLUMN(pMap, hLoc) + offColumn; if (uColumn < RT_BIT_32(ORDINARY_MAP_NUMBER_OF_COLUMN_BITS(pMap))) { /* Try add the position. If we get a valid result, replace the location. */ source_location hNewLoc = linemap_position_for_line_and_column((line_map *)pMap, SOURCE_LINE(pMap, hLoc), uColumn); if ( hNewLoc <= line_table->highest_location && linemap_lookup(line_table, hNewLoc) != NULL) { dprintf("MyGetLocationPlusColumnOffset: hNewLoc=%#x hLoc=%#x offColumn=%u uColumn=%u\n", hNewLoc, hLoc, offColumn, uColumn); return hNewLoc; } } } #endif } dprintf("MyGetLocationPlusColumnOffset: taking fallback\n"); return hLoc; } static location_t MyGetFormatStringLocation(PVFMTCHKSTATE pState, const char *pszLoc) { location_t hLoc = pState->hFmtLoc; #if __GNUC__ != 4 || __GNUC_MINOR__ > 5 intptr_t offString = pszLoc - pState->pszFmt; if ( offString >= 0 && !linemap_location_from_macro_expansion_p(line_table, hLoc)) { unsigned uCol = 1 + offString; expanded_location XLoc = expand_location_to_spelling_point(hLoc); int cchLine = 0; # if __GNUC__ >= 5 /** @todo figure this... */ const char *pszLine = location_get_source_line(XLoc, &cchLine); # else const char *pszLine = location_get_source_line(XLoc); if (pszLine) { const char *pszEol = strpbrk(pszLine, "\n\r"); if (!pszEol) pszEol = strchr(pszLine, '\0'); cchLine = (int)(pszEol - pszLine); } # endif if (pszLine) { /** @todo Adjust the position by parsing the source. */ pszLine += XLoc.column - 1; cchLine -= XLoc.column - 1; } hLoc = MyGetLocationPlusColumnOffset(hLoc, uCol); } #endif return hLoc; } /** * Non-recursive worker for MyCheckFormatRecursive. * * This will attempt to result @a hFmtArg into a string literal which it then * passes on to MyCheckFormatString for the actual analyzis. * * @param pState The format string checking state. * @param hFmtArg The format string node. */ DECL_NO_INLINE(static, void) MyCheckFormatNonRecursive(PVFMTCHKSTATE pState, tree hFmtArg) { dprintf("checker: hFmtArg=%p %s\n", hFmtArg, tree_code_name[TREE_CODE(hFmtArg)]); /* * Try resolve variables into constant strings. */ if (VAR_P(hFmtArg)) { hFmtArg = decl_constant_value(hFmtArg); STRIP_NOPS(hFmtArg); /* Used as argument and assigned call result. */ dprintf("checker1: variable => hFmtArg=%p %s\n", hFmtArg, tree_code_name[TREE_CODE(hFmtArg)]); } /* * Fend off NULLs. */ if (integer_zerop(hFmtArg)) { if (pState->fMaybeNull) VFmtChkVerifyEndOfArgs(pState, 0); else error_at(MY_LOC(hFmtArg, pState), "Format string should not be NULL"); } /* * Need address expression to get any further. */ else if (TREE_CODE(hFmtArg) != ADDR_EXPR) dprintf("checker1: Not address expression (%s)\n", tree_code_name[TREE_CODE(hFmtArg)]); else { pState->hFmtLoc = EXPR_LOC_OR_LOC(hFmtArg, pState->hFmtLoc); hFmtArg = TREE_OPERAND(hFmtArg, 0); /* * Deal with fixed string indexing, if possible. */ HOST_WIDE_INT off = 0; if ( TREE_CODE(hFmtArg) == ARRAY_REF && MY_INT_FITS_SHWI(TREE_INT_CST(TREE_OPERAND(hFmtArg, 1))) && MY_INT_FITS_SHWI(TREE_INT_CST(TREE_OPERAND(hFmtArg, 1))) ) { off = MY_INT_TO_SHWI(TREE_INT_CST(TREE_OPERAND(hFmtArg, 1))); if (off < 0) { dprintf("checker1: ARRAY_REF, off=%ld\n", off); return; } hFmtArg = TREE_OPERAND(hFmtArg, 0); dprintf("checker1: ARRAY_REF => hFmtArg=%p %s, off=%ld\n", hFmtArg, tree_code_name[TREE_CODE(hFmtArg)], off); } /* * Deal with static const char g_szFmt[] = "qwerty"; Take care as * the actual string constant may not necessarily include the terminator. */ tree hArraySize = NULL_TREE; if ( VAR_P(hFmtArg) && TREE_CODE(TREE_TYPE(hFmtArg)) == ARRAY_TYPE) { tree hArrayInitializer = decl_constant_value(hFmtArg); if ( hArrayInitializer != hFmtArg && TREE_CODE(hArrayInitializer) == STRING_CST) { hArraySize = DECL_SIZE_UNIT(hFmtArg); hFmtArg = hArrayInitializer; } } /* * Are we dealing with a string literal now? */ if (TREE_CODE(hFmtArg) != STRING_CST) dprintf("checker1: Not string literal (%s)\n", tree_code_name[TREE_CODE(hFmtArg)]); else if (TYPE_MAIN_VARIANT(TREE_TYPE(TREE_TYPE(hFmtArg))) != char_type_node) warning_at(pState->hFmtLoc, 0, "expected 'char' type string literal"); else { /* * Yes we are, so get the pointer to the string and its length. */ const char *pszFmt = TREE_STRING_POINTER(hFmtArg); int cchFmt = TREE_STRING_LENGTH(hFmtArg); /* Adjust cchFmt to the initialized array size if appropriate. */ if (hArraySize != NULL_TREE) { if (TREE_CODE(hArraySize) != INTEGER_CST) warning_at(pState->hFmtLoc, 0, "Expected integer array size (not %s)", tree_code_name[TREE_CODE(hArraySize)]); else if (!MY_INT_FITS_SHWI(TREE_INT_CST(hArraySize))) warning_at(pState->hFmtLoc, 0, "Unexpected integer overflow in array size constant"); else { HOST_WIDE_INT cbArray = MY_INT_TO_SHWI(TREE_INT_CST(hArraySize)); if ( cbArray <= 0 || cbArray != (int)cbArray) warning_at(pState->hFmtLoc, 0, "Unexpected integer array size constant value: %ld", cbArray); else if (cchFmt > cbArray) { dprintf("checker1: cchFmt=%d => cchFmt=%ld (=cbArray)\n", cchFmt, cbArray); cchFmt = (int)cbArray; } } } /* Apply the offset, if given. */ if (off) { if (off >= cchFmt) { dprintf("checker1: off=%ld >= cchFmt=%d -> skipping\n", off, cchFmt); return; } pszFmt += off; cchFmt -= (int)off; } /* * Check for unterminated strings. */ if ( cchFmt < 1 || pszFmt[cchFmt - 1] != '\0') warning_at(pState->hFmtLoc, 0, "Unterminated format string (cchFmt=%d)", cchFmt); /* * Call worker to check the actual string. */ else MyCheckFormatCString(pState, pszFmt); } } } /** * Deal recursively with special format string constructs. * * This will call MyCheckFormatNonRecursive to validate each format string. * * @param pState The format string checking state. * @param hFmtArg The format string node. */ static void MyCheckFormatRecursive(PVFMTCHKSTATE pState, tree hFmtArg) { /* * Catch wrong attribute use. */ if (hFmtArg == NULL_TREE) error_at(pState->hFmtLoc, "IPRT format attribute is probably used incorrectly (hFmtArg is NULL)"); /* * NULL format strings may cause crashes. */ else if (integer_zerop(hFmtArg)) { if (pState->fMaybeNull) VFmtChkVerifyEndOfArgs(pState, 0); else error_at(MY_LOC(hFmtArg, pState), "Format string should not be NULL"); } /* * Check both branches of a ternary operator. */ else if (TREE_CODE(hFmtArg) == COND_EXPR) { MyCheckFormatRecursive(pState, TREE_OPERAND(hFmtArg, 1)); MyCheckFormatRecursive(pState, TREE_OPERAND(hFmtArg, 2)); } /* * Strip coercion. */ else if ( CONVERT_EXPR_P(hFmtArg) && TYPE_PRECISION(TREE_TYPE(hFmtArg)) == TYPE_PRECISION(TREE_TYPE(TREE_OPERAND(hFmtArg, 0))) ) MyCheckFormatRecursive(pState, TREE_OPERAND(hFmtArg, 0)); /* * We're good, hand it to the non-recursive worker. */ else MyCheckFormatNonRecursive(pState, hFmtArg); } /** * Execute my pass. * @returns Flags indicates stuff todo, we return 0. */ static unsigned int MyPassExecuteCallback(void) { dprintf("MyPassExecuteCallback:\n"); /* * Enumerate the basic blocks. */ basic_block hBasicBlock; FOR_EACH_BB(hBasicBlock) { dprintf(" hBasicBlock=%p\n", hBasicBlock); /* * Enumerate the statements in the current basic block. * We're interested in calls to functions with the __iprt_format__ attribute. */ for (gimple_stmt_iterator hStmtItr = gsi_start_bb(hBasicBlock); !gsi_end_p(hStmtItr); gsi_next(&hStmtItr)) { gimple const hStmt = gsi_stmt(hStmtItr); enum gimple_code const enmCode = gimple_code(hStmt); #ifdef DEBUG unsigned const cOps = gimple_num_ops(hStmt); dprintf(" hStmt=%p %s (%d) ops=%d\n", hStmt, gimple_code_name[enmCode], enmCode, cOps); for (unsigned iOp = 0; iOp < cOps; iOp++) { tree const hOp = gimple_op(hStmt, iOp); if (hOp) dprintf(" %02d: %p, code %s(%d)\n", iOp, hOp, tree_code_name[TREE_CODE(hOp)], TREE_CODE(hOp)); else dprintf(" %02d: NULL_TREE\n", iOp); } #endif if (enmCode == GIMPLE_CALL) { /* * Check if the function type has the __iprt_format__ attribute. */ tree const hFn = gimple_call_fn(hStmt); dprintf(" hFn =%p %s(%d); args=%d\n", hFn, tree_code_name[TREE_CODE(hFn)], TREE_CODE(hFn), gimple_call_num_args(hStmt)); #ifdef DEBUG if (DECL_P(hFn)) dprintf(" hFn is decl: %s %s:%d\n", DECL_NAME(hFn) ? IDENTIFIER_POINTER(DECL_NAME(hFn)) : "", DECL_SOURCE_FILE(hFn), DECL_SOURCE_LINE(hFn)); tree const hFnDecl = gimple_call_fndecl(hStmt); if (hFnDecl) dprintf(" hFnDecl=%p %s(%d) %s type=%p %s:%d\n", hFnDecl, tree_code_name[TREE_CODE(hFnDecl)], TREE_CODE(hFnDecl), DECL_NAME(hFnDecl) ? IDENTIFIER_POINTER(DECL_NAME(hFnDecl)) : "", TREE_TYPE(hFnDecl), DECL_SOURCE_FILE(hFnDecl), DECL_SOURCE_LINE(hFnDecl)); #endif tree const hFnType = gimple_call_fntype(hStmt); if (hFnType == NULL_TREE) error_at(gimple_location(hStmt), "Failed to resolve function type [fn=%s]\n", tree_code_name[TREE_CODE(hFn)]); else if (POINTER_TYPE_P(hFnType)) error_at(gimple_location(hStmt), "Got a POINTER_TYPE when expecting a function type [fn=%s]\n", tree_code_name[TREE_CODE(hFn)]); if (hFnType) dprintf(" hFnType=%p %s(%d) %s\n", hFnType, tree_code_name[TREE_CODE(hFnType)], TREE_CODE(hFnType), TYPE_NAME(hFnType) ? IDENTIFIER_POINTER(TYPE_NAME(hFnType)) : ""); tree const hAttr = hFnType ? lookup_attribute("iprt_format", TYPE_ATTRIBUTES(hFnType)) : NULL_TREE; tree const hAttrMaybe0 = hFnType ? lookup_attribute("iprt_format_maybe_null", TYPE_ATTRIBUTES(hFnType)) : NULL_TREE; if (hAttr || hAttrMaybe0) { /* * Yeah, it has the attribute! */ tree const hAttrArgs = hAttr ? TREE_VALUE(hAttr) : TREE_VALUE(hAttrMaybe0); VFMTCHKSTATE State; State.iFmt = MY_INT_TO_SHWI(TREE_INT_CST(TREE_VALUE(hAttrArgs))); State.iArgs = MY_INT_TO_SHWI(TREE_INT_CST(TREE_VALUE(TREE_CHAIN(hAttrArgs)))); State.pszFmt = NULL; State.fMaybeNull = hAttr == NULL_TREE; State.hStmt = hStmt; State.hFmtLoc = gimple_location(hStmt); dprintf(" %s() __iprt_format%s__(iFmt=%ld, iArgs=%ld)\n", DECL_NAME(hFnDecl) ? IDENTIFIER_POINTER(DECL_NAME(hFnDecl)) : "", State.fMaybeNull ? "_maybe_null" : "", State.iFmt, State.iArgs); MyCheckFormatRecursive(&State, gimple_call_arg(hStmt, State.iFmt - 1)); } } } } return 0; } /** * Gate callback for my pass that indicates whether it should execute or not. * @returns true to execute. */ static bool MyPassGateCallback(void) { dprintf("MyPassGateCallback:\n"); return true; } /** * Validate the use of an attribute. * * @returns ?? * @param phOnNode The node the attribute is being used on. * @param hAttrName The attribute name. * @param hAttrArgs The attribute arguments. * @param fFlags Some kind of flags... * @param pfDontAddAttrib Whether to add the attribute to this node or not. */ static tree AttributeHandler(tree *phOnNode, tree hAttrName, tree hAttrArgs, int fFlags, bool *pfDontAddAttrib) { dprintf("AttributeHandler: name=%s fFlags=%#x", IDENTIFIER_POINTER(hAttrName), fFlags); long iFmt = MY_INT_TO_SHWI(TREE_INT_CST(TREE_VALUE(hAttrArgs))); long iArgs = MY_INT_TO_SHWI(TREE_INT_CST(TREE_VALUE(TREE_CHAIN(hAttrArgs)))); dprintf(" iFmt=%ld iArgs=%ld", iFmt, iArgs); tree hType = *phOnNode; dprintf(" hType=%p %s(%d)\n", hType, tree_code_name[TREE_CODE(hType)], TREE_CODE(hType)); if (pfDontAddAttrib) *pfDontAddAttrib = false; return NULL_TREE; } /** * Called when we can register attributes. * * @param pvEventData Ignored. * @param pvUser Ignored. */ static void RegisterAttributesEvent(void *pvEventData, void *pvUser) { NOREF(pvEventData); NOREF(pvUser); dprintf("RegisterAttributesEvent: pvEventData=%p\n", pvEventData); register_attribute(&g_AttribSpecs[0]); register_attribute(&g_AttribSpecs[1]); } /** * The plug-in entry point. * * @returns 0 to indicate success? * @param pPlugInInfo Plugin info structure. * @param pGccVer GCC Version. */ int plugin_init(plugin_name_args *pPlugInInfo, plugin_gcc_version *pGccVer) { dprintf("plugin_init: %s\n", pPlugInInfo->full_name); dprintf("gcc version: basever=%s datestamp=%s devphase=%s revision=%s\n", pGccVer->basever, pGccVer->datestamp, pGccVer->devphase, pGccVer->revision); /* Ask for callback in which we may register the attribute. */ register_callback(pPlugInInfo->base_name, PLUGIN_ATTRIBUTES, RegisterAttributesEvent, NULL /*pvUser*/); /* Register our pass. */ register_callback(pPlugInInfo->base_name, PLUGIN_PASS_MANAGER_SETUP, NULL, (void *)&g_MyPassInfo); /* Register plug-in info. */ register_callback(pPlugInInfo->base_name, PLUGIN_INFO, NULL, (void *)&g_PlugInInfo); return 0; } /* * * Functions used by the common code. * Functions used by the common code. * Functions used by the common code. * */ void VFmtChkWarnFmt(PVFMTCHKSTATE pState, const char *pszLoc, const char *pszFormat, ...) { char szTmp[1024]; va_list va; va_start(va, pszFormat); vsnprintf(szTmp, sizeof(szTmp), pszFormat, va); va_end(va); /* display the warning. */ warning_at(MyGetFormatStringLocation(pState, pszLoc), 0, "%s", szTmp); } void VFmtChkErrFmt(PVFMTCHKSTATE pState, const char *pszLoc, const char *pszFormat, ...) { char szTmp[1024]; va_list va; va_start(va, pszFormat); vsnprintf(szTmp, sizeof(szTmp), pszFormat, va); va_end(va); /* display the warning. */ error_at(MyGetFormatStringLocation(pState, pszLoc), "%s", szTmp); } void VFmtChkVerifyEndOfArgs(PVFMTCHKSTATE pState, unsigned iArg) { dprintf("VFmtChkVerifyEndOfArgs: iArg=%u iArgs=%ld cArgs=%u\n", iArg, pState->iArgs, gimple_call_num_args(pState->hStmt)); if (pState->iArgs > 0) { iArg += pState->iArgs - 1; unsigned cArgs = gimple_call_num_args(pState->hStmt); if (iArg == cArgs) { /* fine */ } else if (iArg < cArgs) { tree hArg = gimple_call_arg(pState->hStmt, iArg); if (cArgs - iArg > 1) error_at(MY_LOC(hArg, pState), "%u extra arguments not consumed by format string", cArgs - iArg); else if ( TREE_CODE(hArg) != INTEGER_CST || !MY_INT_FITS_SHWI(TREE_INT_CST(hArg)) || MY_INT_TO_SHWI(TREE_INT_CST(hArg)) != -99) /* ignore final dummy argument: ..., -99); */ error_at(MY_LOC(hArg, pState), "one extra argument not consumed by format string"); } /* This should be handled elsewhere, but just in case. */ else if (iArg - 1 == cArgs) error_at(pState->hFmtLoc, "one argument too few"); else error_at(pState->hFmtLoc, "%u arguments too few", iArg - cArgs); } } bool VFmtChkRequirePresentArg(PVFMTCHKSTATE pState, const char *pszLoc, unsigned iArg, const char *pszMessage) { if (pState->iArgs > 0) { iArg += pState->iArgs - 1; unsigned cArgs = gimple_call_num_args(pState->hStmt); if (iArg >= cArgs) { VFmtChkErrFmt(pState, pszLoc, "Missing argument! %s", pszMessage); return false; } tree hArg = gimple_call_arg(pState->hStmt, iArg); tree hType = TREE_TYPE(hArg); dprintf("arg%u: hArg=%p [%s] hType=%p [%s] cls=%s\n", iArg, hArg, tree_code_name[TREE_CODE(hArg)], hType, tree_code_name[TREE_CODE(hType)], tree_code_class_strings[TREE_CODE_CLASS(TREE_CODE(hType))]); dprintf(" nm=%p\n", TYPE_NAME(hType)); dprintf(" cb=%p %s value=%ld\n", TYPE_SIZE(hType), tree_code_name[TREE_CODE(TYPE_SIZE(hType))], MY_INT_TO_SHWI(TREE_INT_CST(TYPE_SIZE(hType))) ); dprintf(" unit=%p %s value=%ld\n", TYPE_SIZE_UNIT(hType), tree_code_name[TREE_CODE(TYPE_SIZE_UNIT(hType))], MY_INT_TO_SHWI(TREE_INT_CST(TYPE_SIZE_UNIT(hType))) ); tree hTypeNm = TYPE_NAME(hType); if (hTypeNm) dprintf(" typenm=%p %s '%s'\n", hTypeNm, tree_code_name[TREE_CODE(hTypeNm)], IDENTIFIER_POINTER(DECL_NAME(hTypeNm))); } return true; } bool VFmtChkRequireIntArg(PVFMTCHKSTATE pState, const char *pszLoc, unsigned iArg, const char *pszMessage) { if (VFmtChkRequirePresentArg(pState, pszLoc, iArg, pszMessage)) { /** @todo type check. */ return true; } return false; } bool VFmtChkRequireStringArg(PVFMTCHKSTATE pState, const char *pszLoc, unsigned iArg, const char *pszMessage) { if (VFmtChkRequirePresentArg(pState, pszLoc, iArg, pszMessage)) { /** @todo type check. */ return true; } return false; } bool VFmtChkRequireVaListPtrArg(PVFMTCHKSTATE pState, const char *pszLoc, unsigned iArg, const char *pszMessage) { if (VFmtChkRequirePresentArg(pState, pszLoc, iArg, pszMessage)) { /** @todo type check. */ return true; } return false; } void VFmtChkHandleReplacementFormatString(PVFMTCHKSTATE pState, const char *pszPctM, unsigned iArg) { if (pState->iArgs > 0) { pState->iFmt = pState->iArgs + iArg; pState->iArgs = pState->iFmt + 1; pState->fMaybeNull = false; MyCheckFormatRecursive(pState, gimple_call_arg(pState->hStmt, pState->iFmt - 1)); } } const char *VFmtChkGetFmtLocFile(PVFMTCHKSTATE pState) { return LOCATION_FILE(pState->hFmtLoc); } unsigned int VFmtChkGetFmtLocLine(PVFMTCHKSTATE pState) { return LOCATION_LINE(pState->hFmtLoc); } unsigned int VFmtChkGetFmtLocColumn(PVFMTCHKSTATE pState) { #ifdef LOCATION_COLUMN return LOCATION_COLUMN(pState->hFmtLoc); #else return 1; #endif }