//===-- dfsan.cpp ---------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file is a part of DataFlowSanitizer. // // DataFlowSanitizer runtime. This file defines the public interface to // DataFlowSanitizer as well as the definition of certain runtime functions // called automatically by the compiler (specifically the instrumentation pass // in llvm/lib/Transforms/Instrumentation/DataFlowSanitizer.cpp). // // The public interface is defined in include/sanitizer/dfsan_interface.h whose // functions are prefixed dfsan_ while the compiler interface functions are // prefixed __dfsan_. //===----------------------------------------------------------------------===// #include "dfsan/dfsan.h" #include "dfsan/dfsan_chained_origin_depot.h" #include "dfsan/dfsan_flags.h" #include "dfsan/dfsan_origin.h" #include "dfsan/dfsan_thread.h" #include "sanitizer_common/sanitizer_atomic.h" #include "sanitizer_common/sanitizer_common.h" #include "sanitizer_common/sanitizer_file.h" #include "sanitizer_common/sanitizer_flag_parser.h" #include "sanitizer_common/sanitizer_flags.h" #include "sanitizer_common/sanitizer_internal_defs.h" #include "sanitizer_common/sanitizer_libc.h" #include "sanitizer_common/sanitizer_report_decorator.h" #include "sanitizer_common/sanitizer_stacktrace.h" using namespace __dfsan; Flags __dfsan::flags_data; // The size of TLS variables. These constants must be kept in sync with the ones // in DataFlowSanitizer.cpp. static const int kDFsanArgTlsSize = 800; static const int kDFsanRetvalTlsSize = 800; static const int kDFsanArgOriginTlsSize = 800; SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL u64 __dfsan_retval_tls[kDFsanRetvalTlsSize / sizeof(u64)]; SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL u32 __dfsan_retval_origin_tls; SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL u64 __dfsan_arg_tls[kDFsanArgTlsSize / sizeof(u64)]; SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL u32 __dfsan_arg_origin_tls[kDFsanArgOriginTlsSize / sizeof(u32)]; // Instrumented code may set this value in terms of -dfsan-track-origins. // * undefined or 0: do not track origins. // * 1: track origins at memory store operations. // * 2: track origins at memory load and store operations. // TODO: track callsites. extern "C" SANITIZER_WEAK_ATTRIBUTE const int __dfsan_track_origins; extern "C" SANITIZER_INTERFACE_ATTRIBUTE int dfsan_get_track_origins() { return &__dfsan_track_origins ? __dfsan_track_origins : 0; } // On Linux/x86_64, memory is laid out as follows: // // +--------------------+ 0x800000000000 (top of memory) // | application 3 | // +--------------------+ 0x700000000000 // | invalid | // +--------------------+ 0x610000000000 // | origin 1 | // +--------------------+ 0x600000000000 // | application 2 | // +--------------------+ 0x510000000000 // | shadow 1 | // +--------------------+ 0x500000000000 // | invalid | // +--------------------+ 0x400000000000 // | origin 3 | // +--------------------+ 0x300000000000 // | shadow 3 | // +--------------------+ 0x200000000000 // | origin 2 | // +--------------------+ 0x110000000000 // | invalid | // +--------------------+ 0x100000000000 // | shadow 2 | // +--------------------+ 0x010000000000 // | application 1 | // +--------------------+ 0x000000000000 // // MEM_TO_SHADOW(mem) = mem ^ 0x500000000000 // SHADOW_TO_ORIGIN(shadow) = shadow + 0x100000000000 extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label __dfsan_union_load(const dfsan_label *ls, uptr n) { dfsan_label label = ls[0]; for (uptr i = 1; i != n; ++i) label |= ls[i]; return label; } // Return the union of all the n labels from addr at the high 32 bit, and the // origin of the first taint byte at the low 32 bit. extern "C" SANITIZER_INTERFACE_ATTRIBUTE u64 __dfsan_load_label_and_origin(const void *addr, uptr n) { dfsan_label label = 0; u64 ret = 0; uptr p = (uptr)addr; dfsan_label *s = shadow_for((void *)p); for (uptr i = 0; i < n; ++i) { dfsan_label l = s[i]; if (!l) continue; label |= l; if (!ret) ret = *(dfsan_origin *)origin_for((void *)(p + i)); } return ret | (u64)label << 32; } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_unimplemented(char *fname) { if (flags().warn_unimplemented) Report("WARNING: DataFlowSanitizer: call to uninstrumented function %s\n", fname); } // Use '-mllvm -dfsan-debug-nonzero-labels' and break on this function // to try to figure out where labels are being introduced in a nominally // label-free program. extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_nonzero_label() { if (flags().warn_nonzero_labels) Report("WARNING: DataFlowSanitizer: saw nonzero label\n"); } // Indirect call to an uninstrumented vararg function. We don't have a way of // handling these at the moment. extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_vararg_wrapper(const char *fname) { Report("FATAL: DataFlowSanitizer: unsupported indirect call to vararg " "function %s\n", fname); Die(); } // Resolves the union of two labels. SANITIZER_INTERFACE_ATTRIBUTE dfsan_label dfsan_union(dfsan_label l1, dfsan_label l2) { return l1 | l2; } static const uptr kOriginAlign = sizeof(dfsan_origin); static const uptr kOriginAlignMask = ~(kOriginAlign - 1UL); static uptr OriginAlignUp(uptr u) { return (u + kOriginAlign - 1) & kOriginAlignMask; } static uptr OriginAlignDown(uptr u) { return u & kOriginAlignMask; } // Return the origin of the first taint byte in the size bytes from the address // addr. static dfsan_origin GetOriginIfTainted(uptr addr, uptr size) { for (uptr i = 0; i < size; ++i, ++addr) { dfsan_label *s = shadow_for((void *)addr); if (*s) { // Validate address region. CHECK(MEM_IS_SHADOW(s)); return *(dfsan_origin *)origin_for((void *)addr); } } return 0; } // For platforms which support slow unwinder only, we need to restrict the store // context size to 1, basically only storing the current pc, because the slow // unwinder which is based on libunwind is not async signal safe and causes // random freezes in forking applications as well as in signal handlers. // DFSan supports only Linux. So we do not restrict the store context size. #define GET_STORE_STACK_TRACE_PC_BP(pc, bp) \ BufferedStackTrace stack; \ stack.Unwind(pc, bp, nullptr, true, flags().store_context_size); #define PRINT_CALLER_STACK_TRACE \ { \ GET_CALLER_PC_BP_SP; \ (void)sp; \ GET_STORE_STACK_TRACE_PC_BP(pc, bp) \ stack.Print(); \ } // Return a chain with the previous ID id and the current stack. // from_init = true if this is the first chain of an origin tracking path. static u32 ChainOrigin(u32 id, StackTrace *stack, bool from_init = false) { // StackDepot is not async signal safe. Do not create new chains in a signal // handler. DFsanThread *t = GetCurrentThread(); if (t && t->InSignalHandler()) return id; // As an optimization the origin of an application byte is updated only when // its shadow is non-zero. Because we are only interested in the origins of // taint labels, it does not matter what origin a zero label has. This reduces // memory write cost. MSan does similar optimization. The following invariant // may not hold because of some bugs. We check the invariant to help debug. if (!from_init && id == 0 && flags().check_origin_invariant) { Printf(" DFSan found invalid origin invariant\n"); PRINT_CALLER_STACK_TRACE } Origin o = Origin::FromRawId(id); stack->tag = StackTrace::TAG_UNKNOWN; Origin chained = Origin::CreateChainedOrigin(o, stack); return chained.raw_id(); } static void ChainAndWriteOriginIfTainted(uptr src, uptr size, uptr dst, StackTrace *stack) { dfsan_origin o = GetOriginIfTainted(src, size); if (o) { o = ChainOrigin(o, stack); *(dfsan_origin *)origin_for((void *)dst) = o; } } // Copy the origins of the size bytes from src to dst. The source and target // memory ranges cannot be overlapped. This is used by memcpy. stack records the // stack trace of the memcpy. When dst and src are not 4-byte aligned properly, // origins at the unaligned address boundaries may be overwritten because four // contiguous bytes share the same origin. static void CopyOrigin(const void *dst, const void *src, uptr size, StackTrace *stack) { uptr d = (uptr)dst; uptr beg = OriginAlignDown(d); // Copy left unaligned origin if that memory is tainted. if (beg < d) { ChainAndWriteOriginIfTainted((uptr)src, beg + kOriginAlign - d, beg, stack); beg += kOriginAlign; } uptr end = OriginAlignDown(d + size); // If both ends fall into the same 4-byte slot, we are done. if (end < beg) return; // Copy right unaligned origin if that memory is tainted. if (end < d + size) ChainAndWriteOriginIfTainted((uptr)src + (end - d), (d + size) - end, end, stack); if (beg >= end) return; // Align src up. uptr src_a = OriginAlignUp((uptr)src); dfsan_origin *src_o = origin_for((void *)src_a); u32 *src_s = (u32 *)shadow_for((void *)src_a); dfsan_origin *src_end = origin_for((void *)(src_a + (end - beg))); dfsan_origin *dst_o = origin_for((void *)beg); dfsan_origin last_src_o = 0; dfsan_origin last_dst_o = 0; for (; src_o < src_end; ++src_o, ++src_s, ++dst_o) { if (!*src_s) continue; if (*src_o != last_src_o) { last_src_o = *src_o; last_dst_o = ChainOrigin(last_src_o, stack); } *dst_o = last_dst_o; } } // Copy the origins of the size bytes from src to dst. The source and target // memory ranges may be overlapped. So the copy is done in a reverse order. // This is used by memmove. stack records the stack trace of the memmove. static void ReverseCopyOrigin(const void *dst, const void *src, uptr size, StackTrace *stack) { uptr d = (uptr)dst; uptr end = OriginAlignDown(d + size); // Copy right unaligned origin if that memory is tainted. if (end < d + size) ChainAndWriteOriginIfTainted((uptr)src + (end - d), (d + size) - end, end, stack); uptr beg = OriginAlignDown(d); if (beg + kOriginAlign < end) { // Align src up. uptr src_a = OriginAlignUp((uptr)src); void *src_end = (void *)(src_a + end - beg - kOriginAlign); dfsan_origin *src_end_o = origin_for(src_end); u32 *src_end_s = (u32 *)shadow_for(src_end); dfsan_origin *src_begin_o = origin_for((void *)src_a); dfsan_origin *dst = origin_for((void *)(end - kOriginAlign)); dfsan_origin last_src_o = 0; dfsan_origin last_dst_o = 0; for (; src_end_o >= src_begin_o; --src_end_o, --src_end_s, --dst) { if (!*src_end_s) continue; if (*src_end_o != last_src_o) { last_src_o = *src_end_o; last_dst_o = ChainOrigin(last_src_o, stack); } *dst = last_dst_o; } } // Copy left unaligned origin if that memory is tainted. if (beg < d) ChainAndWriteOriginIfTainted((uptr)src, beg + kOriginAlign - d, beg, stack); } // Copy or move the origins of the len bytes from src to dst. The source and // target memory ranges may or may not be overlapped. This is used by memory // transfer operations. stack records the stack trace of the memory transfer // operation. static void MoveOrigin(const void *dst, const void *src, uptr size, StackTrace *stack) { // Validate address regions. if (!MEM_IS_SHADOW(shadow_for(dst)) || !MEM_IS_SHADOW(shadow_for((void *)((uptr)dst + size))) || !MEM_IS_SHADOW(shadow_for(src)) || !MEM_IS_SHADOW(shadow_for((void *)((uptr)src + size)))) { CHECK(false); return; } // If destination origin range overlaps with source origin range, move // origins by copying origins in a reverse order; otherwise, copy origins in // a normal order. The orders of origin transfer are consistent with the // orders of how memcpy and memmove transfer user data. uptr src_aligned_beg = OriginAlignDown((uptr)src); uptr src_aligned_end = OriginAlignDown((uptr)src + size); uptr dst_aligned_beg = OriginAlignDown((uptr)dst); if (dst_aligned_beg < src_aligned_end && dst_aligned_beg >= src_aligned_beg) return ReverseCopyOrigin(dst, src, size, stack); return CopyOrigin(dst, src, size, stack); } // Set the size bytes from the addres dst to be the origin value. static void SetOrigin(const void *dst, uptr size, u32 origin) { if (size == 0) return; // Origin mapping is 4 bytes per 4 bytes of application memory. // Here we extend the range such that its left and right bounds are both // 4 byte aligned. uptr x = unaligned_origin_for((uptr)dst); uptr beg = OriginAlignDown(x); uptr end = OriginAlignUp(x + size); // align up. u64 origin64 = ((u64)origin << 32) | origin; // This is like memset, but the value is 32-bit. We unroll by 2 to write // 64 bits at once. May want to unroll further to get 128-bit stores. if (beg & 7ULL) { if (*(u32 *)beg != origin) *(u32 *)beg = origin; beg += 4; } for (uptr addr = beg; addr < (end & ~7UL); addr += 8) { if (*(u64 *)addr == origin64) continue; *(u64 *)addr = origin64; } if (end & 7ULL) if (*(u32 *)(end - kOriginAlign) != origin) *(u32 *)(end - kOriginAlign) = origin; } #define RET_CHAIN_ORIGIN(id) \ GET_CALLER_PC_BP_SP; \ (void)sp; \ GET_STORE_STACK_TRACE_PC_BP(pc, bp); \ return ChainOrigin(id, &stack); // Return a new origin chain with the previous ID id and the current stack // trace. extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin __dfsan_chain_origin(dfsan_origin id) { RET_CHAIN_ORIGIN(id) } // Return a new origin chain with the previous ID id and the current stack // trace if the label is tainted. extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin __dfsan_chain_origin_if_tainted(dfsan_label label, dfsan_origin id) { if (!label) return id; RET_CHAIN_ORIGIN(id) } // Copy or move the origins of the len bytes from src to dst. extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_mem_origin_transfer( const void *dst, const void *src, uptr len) { if (src == dst) return; GET_CALLER_PC_BP; GET_STORE_STACK_TRACE_PC_BP(pc, bp); MoveOrigin(dst, src, len, &stack); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void dfsan_mem_origin_transfer( const void *dst, const void *src, uptr len) { __dfsan_mem_origin_transfer(dst, src, len); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void dfsan_mem_shadow_transfer( void *dst, const void *src, uptr len) { internal_memcpy((void *)__dfsan::shadow_for(dst), (const void *)__dfsan::shadow_for(src), len * sizeof(dfsan_label)); } namespace __dfsan { bool dfsan_inited = false; bool dfsan_init_is_running = false; void dfsan_copy_memory(void *dst, const void *src, uptr size) { internal_memcpy(dst, src, size); dfsan_mem_shadow_transfer(dst, src, size); if (dfsan_get_track_origins()) dfsan_mem_origin_transfer(dst, src, size); } // Releases the pages within the origin address range. static void ReleaseOrigins(void *addr, uptr size) { const uptr beg_origin_addr = (uptr)__dfsan::origin_for(addr); const void *end_addr = (void *)((uptr)addr + size); const uptr end_origin_addr = (uptr)__dfsan::origin_for(end_addr); if (end_origin_addr - beg_origin_addr < common_flags()->clear_shadow_mmap_threshold) return; const uptr page_size = GetPageSizeCached(); const uptr beg_aligned = RoundUpTo(beg_origin_addr, page_size); const uptr end_aligned = RoundDownTo(end_origin_addr, page_size); if (!MmapFixedSuperNoReserve(beg_aligned, end_aligned - beg_aligned)) Die(); } static void WriteZeroShadowInRange(uptr beg, uptr end) { // Don't write the label if it is already the value we need it to be. // In a program where most addresses are not labeled, it is common that // a page of shadow memory is entirely zeroed. The Linux copy-on-write // implementation will share all of the zeroed pages, making a copy of a // page when any value is written. The un-sharing will happen even if // the value written does not change the value in memory. Avoiding the // write when both |label| and |*labelp| are zero dramatically reduces // the amount of real memory used by large programs. if (!mem_is_zero((const char *)beg, end - beg)) internal_memset((void *)beg, 0, end - beg); } // Releases the pages within the shadow address range, and sets // the shadow addresses not on the pages to be 0. static void ReleaseOrClearShadows(void *addr, uptr size) { const uptr beg_shadow_addr = (uptr)__dfsan::shadow_for(addr); const void *end_addr = (void *)((uptr)addr + size); const uptr end_shadow_addr = (uptr)__dfsan::shadow_for(end_addr); if (end_shadow_addr - beg_shadow_addr < common_flags()->clear_shadow_mmap_threshold) { WriteZeroShadowInRange(beg_shadow_addr, end_shadow_addr); return; } const uptr page_size = GetPageSizeCached(); const uptr beg_aligned = RoundUpTo(beg_shadow_addr, page_size); const uptr end_aligned = RoundDownTo(end_shadow_addr, page_size); if (beg_aligned >= end_aligned) { WriteZeroShadowInRange(beg_shadow_addr, end_shadow_addr); } else { if (beg_aligned != beg_shadow_addr) WriteZeroShadowInRange(beg_shadow_addr, beg_aligned); if (end_aligned != end_shadow_addr) WriteZeroShadowInRange(end_aligned, end_shadow_addr); if (!MmapFixedSuperNoReserve(beg_aligned, end_aligned - beg_aligned)) Die(); } } void SetShadow(dfsan_label label, void *addr, uptr size, dfsan_origin origin) { if (0 != label) { const uptr beg_shadow_addr = (uptr)__dfsan::shadow_for(addr); internal_memset((void *)beg_shadow_addr, label, size); if (dfsan_get_track_origins()) SetOrigin(addr, size, origin); return; } if (dfsan_get_track_origins()) ReleaseOrigins(addr, size); ReleaseOrClearShadows(addr, size); } } // namespace __dfsan // If the label s is tainted, set the size bytes from the address p to be a new // origin chain with the previous ID o and the current stack trace. This is // used by instrumentation to reduce code size when too much code is inserted. extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_maybe_store_origin( dfsan_label s, void *p, uptr size, dfsan_origin o) { if (UNLIKELY(s)) { GET_CALLER_PC_BP_SP; (void)sp; GET_STORE_STACK_TRACE_PC_BP(pc, bp); SetOrigin(p, size, ChainOrigin(o, &stack)); } } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_set_label( dfsan_label label, dfsan_origin origin, void *addr, uptr size) { __dfsan::SetShadow(label, addr, size, origin); } SANITIZER_INTERFACE_ATTRIBUTE void dfsan_set_label(dfsan_label label, void *addr, uptr size) { dfsan_origin init_origin = 0; if (label && dfsan_get_track_origins()) { GET_CALLER_PC_BP; GET_STORE_STACK_TRACE_PC_BP(pc, bp); init_origin = ChainOrigin(0, &stack, true); } __dfsan::SetShadow(label, addr, size, init_origin); } SANITIZER_INTERFACE_ATTRIBUTE void dfsan_add_label(dfsan_label label, void *addr, uptr size) { if (0 == label) return; if (dfsan_get_track_origins()) { GET_CALLER_PC_BP; GET_STORE_STACK_TRACE_PC_BP(pc, bp); dfsan_origin init_origin = ChainOrigin(0, &stack, true); SetOrigin(addr, size, init_origin); } for (dfsan_label *labelp = shadow_for(addr); size != 0; --size, ++labelp) *labelp |= label; } // Unlike the other dfsan interface functions the behavior of this function // depends on the label of one of its arguments. Hence it is implemented as a // custom function. extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label __dfsw_dfsan_get_label(long data, dfsan_label data_label, dfsan_label *ret_label) { *ret_label = 0; return data_label; } extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label __dfso_dfsan_get_label( long data, dfsan_label data_label, dfsan_label *ret_label, dfsan_origin data_origin, dfsan_origin *ret_origin) { *ret_label = 0; *ret_origin = 0; return data_label; } // This function is used if dfsan_get_origin is called when origin tracking is // off. extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin __dfsw_dfsan_get_origin( long data, dfsan_label data_label, dfsan_label *ret_label) { *ret_label = 0; return 0; } extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin __dfso_dfsan_get_origin( long data, dfsan_label data_label, dfsan_label *ret_label, dfsan_origin data_origin, dfsan_origin *ret_origin) { *ret_label = 0; *ret_origin = 0; return data_origin; } SANITIZER_INTERFACE_ATTRIBUTE dfsan_label dfsan_read_label(const void *addr, uptr size) { if (size == 0) return 0; return __dfsan_union_load(shadow_for(addr), size); } SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin dfsan_read_origin_of_first_taint(const void *addr, uptr size) { return GetOriginIfTainted((uptr)addr, size); } SANITIZER_INTERFACE_ATTRIBUTE void dfsan_set_label_origin(dfsan_label label, dfsan_origin origin, void *addr, uptr size) { __dfsan_set_label(label, origin, addr, size); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE int dfsan_has_label(dfsan_label label, dfsan_label elem) { return (label & elem) == elem; } namespace __dfsan { typedef void (*dfsan_conditional_callback_t)(dfsan_label label, dfsan_origin origin); static dfsan_conditional_callback_t conditional_callback = nullptr; static dfsan_label labels_in_signal_conditional = 0; static void ConditionalCallback(dfsan_label label, dfsan_origin origin) { // Programs have many branches. For efficiency the conditional sink callback // handler needs to ignore as many as possible as early as possible. if (label == 0) { return; } if (conditional_callback == nullptr) { return; } // This initial ConditionalCallback handler needs to be in here in dfsan // runtime (rather than being an entirely user implemented hook) so that it // has access to dfsan thread information. DFsanThread *t = GetCurrentThread(); // A callback operation which does useful work (like record the flow) will // likely be too long executed in a signal handler. if (t && t->InSignalHandler()) { // Record set of labels used in signal handler for completeness. labels_in_signal_conditional |= label; return; } conditional_callback(label, origin); } } // namespace __dfsan extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_conditional_callback_origin(dfsan_label label, dfsan_origin origin) { __dfsan::ConditionalCallback(label, origin); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __dfsan_conditional_callback( dfsan_label label) { __dfsan::ConditionalCallback(label, 0); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void dfsan_set_conditional_callback( __dfsan::dfsan_conditional_callback_t callback) { __dfsan::conditional_callback = callback; } extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label dfsan_get_labels_in_signal_conditional() { return __dfsan::labels_in_signal_conditional; } class Decorator : public __sanitizer::SanitizerCommonDecorator { public: Decorator() : SanitizerCommonDecorator() {} const char *Origin() const { return Magenta(); } }; namespace { void PrintNoOriginTrackingWarning() { Decorator d; Printf( " %sDFSan: origin tracking is not enabled. Did you specify the " "-dfsan-track-origins=1 option?%s\n", d.Warning(), d.Default()); } void PrintNoTaintWarning(const void *address) { Decorator d; Printf(" %sDFSan: no tainted value at %x%s\n", d.Warning(), address, d.Default()); } void PrintInvalidOriginWarning(dfsan_label label, const void *address) { Decorator d; Printf( " %sTaint value 0x%x (at %p) has invalid origin tracking. This can " "be a DFSan bug.%s\n", d.Warning(), label, address, d.Default()); } void PrintInvalidOriginIdWarning(dfsan_origin origin) { Decorator d; Printf( " %sOrigin Id %d has invalid origin tracking. This can " "be a DFSan bug.%s\n", d.Warning(), origin, d.Default()); } bool PrintOriginTraceFramesToStr(Origin o, InternalScopedString *out) { Decorator d; bool found = false; while (o.isChainedOrigin()) { StackTrace stack; dfsan_origin origin_id = o.raw_id(); o = o.getNextChainedOrigin(&stack); if (o.isChainedOrigin()) out->append( " %sOrigin value: 0x%x, Taint value was stored to memory at%s\n", d.Origin(), origin_id, d.Default()); else out->append(" %sOrigin value: 0x%x, Taint value was created at%s\n", d.Origin(), origin_id, d.Default()); // Includes a trailing newline, so no need to add it again. stack.PrintTo(out); found = true; } return found; } bool PrintOriginTraceToStr(const void *addr, const char *description, InternalScopedString *out) { CHECK(out); CHECK(dfsan_get_track_origins()); Decorator d; const dfsan_label label = *__dfsan::shadow_for(addr); CHECK(label); const dfsan_origin origin = *__dfsan::origin_for(addr); out->append(" %sTaint value 0x%x (at %p) origin tracking (%s)%s\n", d.Origin(), label, addr, description ? description : "", d.Default()); Origin o = Origin::FromRawId(origin); return PrintOriginTraceFramesToStr(o, out); } } // namespace extern "C" SANITIZER_INTERFACE_ATTRIBUTE void dfsan_print_origin_trace( const void *addr, const char *description) { if (!dfsan_get_track_origins()) { PrintNoOriginTrackingWarning(); return; } const dfsan_label label = *__dfsan::shadow_for(addr); if (!label) { PrintNoTaintWarning(addr); return; } InternalScopedString trace; bool success = PrintOriginTraceToStr(addr, description, &trace); if (trace.length()) Printf("%s", trace.data()); if (!success) PrintInvalidOriginWarning(label, addr); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE uptr dfsan_sprint_origin_trace(const void *addr, const char *description, char *out_buf, uptr out_buf_size) { CHECK(out_buf); if (!dfsan_get_track_origins()) { PrintNoOriginTrackingWarning(); return 0; } const dfsan_label label = *__dfsan::shadow_for(addr); if (!label) { PrintNoTaintWarning(addr); return 0; } InternalScopedString trace; bool success = PrintOriginTraceToStr(addr, description, &trace); if (!success) { PrintInvalidOriginWarning(label, addr); return 0; } if (out_buf_size) { internal_strncpy(out_buf, trace.data(), out_buf_size - 1); out_buf[out_buf_size - 1] = '\0'; } return trace.length(); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void dfsan_print_origin_id_trace( dfsan_origin origin) { if (!dfsan_get_track_origins()) { PrintNoOriginTrackingWarning(); return; } Origin o = Origin::FromRawId(origin); InternalScopedString trace; bool success = PrintOriginTraceFramesToStr(o, &trace); if (trace.length()) Printf("%s", trace.data()); if (!success) PrintInvalidOriginIdWarning(origin); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE uptr dfsan_sprint_origin_id_trace( dfsan_origin origin, char *out_buf, uptr out_buf_size) { CHECK(out_buf); if (!dfsan_get_track_origins()) { PrintNoOriginTrackingWarning(); return 0; } Origin o = Origin::FromRawId(origin); InternalScopedString trace; bool success = PrintOriginTraceFramesToStr(o, &trace); if (!success) { PrintInvalidOriginIdWarning(origin); return 0; } if (out_buf_size) { internal_strncpy(out_buf, trace.data(), out_buf_size - 1); out_buf[out_buf_size - 1] = '\0'; } return trace.length(); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_origin dfsan_get_init_origin(const void *addr) { if (!dfsan_get_track_origins()) return 0; const dfsan_label label = *__dfsan::shadow_for(addr); if (!label) return 0; const dfsan_origin origin = *__dfsan::origin_for(addr); Origin o = Origin::FromRawId(origin); dfsan_origin origin_id = o.raw_id(); while (o.isChainedOrigin()) { StackTrace stack; origin_id = o.raw_id(); o = o.getNextChainedOrigin(&stack); } return origin_id; } void __sanitizer::BufferedStackTrace::UnwindImpl(uptr pc, uptr bp, void *context, bool request_fast, u32 max_depth) { using namespace __dfsan; DFsanThread *t = GetCurrentThread(); if (!t || !StackTrace::WillUseFastUnwind(request_fast)) { return Unwind(max_depth, pc, bp, context, 0, 0, false); } Unwind(max_depth, pc, bp, nullptr, t->stack_top(), t->stack_bottom(), true); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_print_stack_trace() { GET_CALLER_PC_BP; GET_STORE_STACK_TRACE_PC_BP(pc, bp); stack.Print(); } extern "C" SANITIZER_INTERFACE_ATTRIBUTE uptr dfsan_sprint_stack_trace(char *out_buf, uptr out_buf_size) { CHECK(out_buf); GET_CALLER_PC_BP; GET_STORE_STACK_TRACE_PC_BP(pc, bp); return stack.PrintTo(out_buf, out_buf_size); } void Flags::SetDefaults() { #define DFSAN_FLAG(Type, Name, DefaultValue, Description) Name = DefaultValue; #include "dfsan_flags.inc" #undef DFSAN_FLAG } static void RegisterDfsanFlags(FlagParser *parser, Flags *f) { #define DFSAN_FLAG(Type, Name, DefaultValue, Description) \ RegisterFlag(parser, #Name, Description, &f->Name); #include "dfsan_flags.inc" #undef DFSAN_FLAG } static void InitializeFlags() { SetCommonFlagsDefaults(); { CommonFlags cf; cf.CopyFrom(*common_flags()); cf.intercept_tls_get_addr = true; OverrideCommonFlags(cf); } flags().SetDefaults(); FlagParser parser; RegisterCommonFlags(&parser); RegisterDfsanFlags(&parser, &flags()); parser.ParseStringFromEnv("DFSAN_OPTIONS"); InitializeCommonFlags(); if (Verbosity()) ReportUnrecognizedFlags(); if (common_flags()->help) parser.PrintFlagDescriptions(); } SANITIZER_INTERFACE_ATTRIBUTE void dfsan_clear_arg_tls(uptr offset, uptr size) { internal_memset((void *)((uptr)__dfsan_arg_tls + offset), 0, size); } SANITIZER_INTERFACE_ATTRIBUTE void dfsan_clear_thread_local_state() { internal_memset(__dfsan_arg_tls, 0, sizeof(__dfsan_arg_tls)); internal_memset(__dfsan_retval_tls, 0, sizeof(__dfsan_retval_tls)); if (dfsan_get_track_origins()) { internal_memset(__dfsan_arg_origin_tls, 0, sizeof(__dfsan_arg_origin_tls)); internal_memset(&__dfsan_retval_origin_tls, 0, sizeof(__dfsan_retval_origin_tls)); } } extern "C" void dfsan_flush() { const uptr maxVirtualAddress = GetMaxUserVirtualAddress(); for (unsigned i = 0; i < kMemoryLayoutSize; ++i) { uptr start = kMemoryLayout[i].start; uptr end = kMemoryLayout[i].end; uptr size = end - start; MappingDesc::Type type = kMemoryLayout[i].type; if (type != MappingDesc::SHADOW && type != MappingDesc::ORIGIN) continue; // Check if the segment should be mapped based on platform constraints. if (start >= maxVirtualAddress) continue; if (!MmapFixedSuperNoReserve(start, size, kMemoryLayout[i].name)) { Printf("FATAL: DataFlowSanitizer: failed to clear memory region\n"); Die(); } } __dfsan::labels_in_signal_conditional = 0; } // TODO: CheckMemoryLayoutSanity is based on msan. // Consider refactoring these into a shared implementation. static void CheckMemoryLayoutSanity() { uptr prev_end = 0; for (unsigned i = 0; i < kMemoryLayoutSize; ++i) { uptr start = kMemoryLayout[i].start; uptr end = kMemoryLayout[i].end; MappingDesc::Type type = kMemoryLayout[i].type; CHECK_LT(start, end); CHECK_EQ(prev_end, start); CHECK(addr_is_type(start, type)); CHECK(addr_is_type((start + end) / 2, type)); CHECK(addr_is_type(end - 1, type)); if (type == MappingDesc::APP) { uptr addr = start; CHECK(MEM_IS_SHADOW(MEM_TO_SHADOW(addr))); CHECK(MEM_IS_ORIGIN(MEM_TO_ORIGIN(addr))); CHECK_EQ(MEM_TO_ORIGIN(addr), SHADOW_TO_ORIGIN(MEM_TO_SHADOW(addr))); addr = (start + end) / 2; CHECK(MEM_IS_SHADOW(MEM_TO_SHADOW(addr))); CHECK(MEM_IS_ORIGIN(MEM_TO_ORIGIN(addr))); CHECK_EQ(MEM_TO_ORIGIN(addr), SHADOW_TO_ORIGIN(MEM_TO_SHADOW(addr))); addr = end - 1; CHECK(MEM_IS_SHADOW(MEM_TO_SHADOW(addr))); CHECK(MEM_IS_ORIGIN(MEM_TO_ORIGIN(addr))); CHECK_EQ(MEM_TO_ORIGIN(addr), SHADOW_TO_ORIGIN(MEM_TO_SHADOW(addr))); } prev_end = end; } } // TODO: CheckMemoryRangeAvailability is based on msan. // Consider refactoring these into a shared implementation. static bool CheckMemoryRangeAvailability(uptr beg, uptr size) { if (size > 0) { uptr end = beg + size - 1; if (!MemoryRangeIsAvailable(beg, end)) { Printf("FATAL: Memory range %p - %p is not available.\n", beg, end); return false; } } return true; } // TODO: ProtectMemoryRange is based on msan. // Consider refactoring these into a shared implementation. static bool ProtectMemoryRange(uptr beg, uptr size, const char *name) { if (size > 0) { void *addr = MmapFixedNoAccess(beg, size, name); if (beg == 0 && addr) { // Depending on the kernel configuration, we may not be able to protect // the page at address zero. uptr gap = 16 * GetPageSizeCached(); beg += gap; size -= gap; addr = MmapFixedNoAccess(beg, size, name); } if ((uptr)addr != beg) { uptr end = beg + size - 1; Printf("FATAL: Cannot protect memory range %p - %p (%s).\n", beg, end, name); return false; } } return true; } // TODO: InitShadow is based on msan. // Consider refactoring these into a shared implementation. bool InitShadow(bool init_origins) { // Let user know mapping parameters first. VPrintf(1, "dfsan_init %p\n", (void *)&__dfsan::dfsan_init); for (unsigned i = 0; i < kMemoryLayoutSize; ++i) VPrintf(1, "%s: %zx - %zx\n", kMemoryLayout[i].name, kMemoryLayout[i].start, kMemoryLayout[i].end - 1); CheckMemoryLayoutSanity(); if (!MEM_IS_APP(&__dfsan::dfsan_init)) { Printf("FATAL: Code %p is out of application range. Non-PIE build?\n", (uptr)&__dfsan::dfsan_init); return false; } const uptr maxVirtualAddress = GetMaxUserVirtualAddress(); for (unsigned i = 0; i < kMemoryLayoutSize; ++i) { uptr start = kMemoryLayout[i].start; uptr end = kMemoryLayout[i].end; uptr size = end - start; MappingDesc::Type type = kMemoryLayout[i].type; // Check if the segment should be mapped based on platform constraints. if (start >= maxVirtualAddress) continue; bool map = type == MappingDesc::SHADOW || (init_origins && type == MappingDesc::ORIGIN); bool protect = type == MappingDesc::INVALID || (!init_origins && type == MappingDesc::ORIGIN); CHECK(!(map && protect)); if (!map && !protect) CHECK(type == MappingDesc::APP); if (map) { if (!CheckMemoryRangeAvailability(start, size)) return false; if (!MmapFixedSuperNoReserve(start, size, kMemoryLayout[i].name)) return false; if (common_flags()->use_madv_dontdump) DontDumpShadowMemory(start, size); } if (protect) { if (!CheckMemoryRangeAvailability(start, size)) return false; if (!ProtectMemoryRange(start, size, kMemoryLayout[i].name)) return false; } } return true; } static void DFsanInit(int argc, char **argv, char **envp) { CHECK(!dfsan_init_is_running); if (dfsan_inited) return; dfsan_init_is_running = true; SanitizerToolName = "DataflowSanitizer"; AvoidCVE_2016_2143(); InitializeFlags(); CheckASLR(); InitShadow(dfsan_get_track_origins()); initialize_interceptors(); // Set up threads DFsanTSDInit(DFsanTSDDtor); dfsan_allocator_init(); DFsanThread *main_thread = DFsanThread::Create(nullptr, nullptr, nullptr); SetCurrentThread(main_thread); main_thread->Init(); dfsan_init_is_running = false; dfsan_inited = true; } namespace __dfsan { void dfsan_init() { DFsanInit(0, nullptr, nullptr); } } // namespace __dfsan #if SANITIZER_CAN_USE_PREINIT_ARRAY __attribute__((section(".preinit_array"), used)) static void (*dfsan_init_ptr)(int, char **, char **) = DFsanInit; #endif