src/third_party/llvm-project/compiler-rt/lib/dfsan/dfsan.cc - cobalt - Git at Google

 //===-- dfsan.cc ----------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // 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 "sanitizer_common/sanitizer_atomic.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_file.h"
 #include "sanitizer_common/sanitizer_flags.h"
 #include "sanitizer_common/sanitizer_flag_parser.h"
 #include "sanitizer_common/sanitizer_libc.h"

 #include "dfsan/dfsan.h"

 using namespace __dfsan;

 typedef atomic_uint16_t atomic_dfsan_label;
 static const dfsan_label kInitializingLabel = -1;

 static const uptr kNumLabels = 1 << (sizeof(dfsan_label) * 8);

 static atomic_dfsan_label __dfsan_last_label;
 static dfsan_label_info __dfsan_label_info[kNumLabels];

 Flags __dfsan::flags_data;

 SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL dfsan_label __dfsan_retval_tls;
 SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL dfsan_label __dfsan_arg_tls[64];

 SANITIZER_INTERFACE_ATTRIBUTE uptr __dfsan_shadow_ptr_mask;

 // On Linux/x86_64, memory is laid out as follows:
 //
 // +--------------------+ 0x800000000000 (top of memory)
 // | application memory |
 // +--------------------+ 0x700000008000 (kAppAddr)
 // |                    |
 // |       unused       |
 // |                    |
 // +--------------------+ 0x200200000000 (kUnusedAddr)
 // |    union table     |
 // +--------------------+ 0x200000000000 (kUnionTableAddr)
 // |   shadow memory    |
 // +--------------------+ 0x000000010000 (kShadowAddr)
 // | reserved by kernel |
 // +--------------------+ 0x000000000000
 //
 // To derive a shadow memory address from an application memory address,
 // bits 44-46 are cleared to bring the address into the range
 // [0x000000008000,0x100000000000).  Then the address is shifted left by 1 to
 // account for the double byte representation of shadow labels and move the
 // address into the shadow memory range.  See the function shadow_for below.

 // On Linux/MIPS64, memory is laid out as follows:
 //
 // +--------------------+ 0x10000000000 (top of memory)
 // | application memory |
 // +--------------------+ 0xF000008000 (kAppAddr)
 // |                    |
 // |       unused       |
 // |                    |
 // +--------------------+ 0x2200000000 (kUnusedAddr)
 // |    union table     |
 // +--------------------+ 0x2000000000 (kUnionTableAddr)
 // |   shadow memory    |
 // +--------------------+ 0x0000010000 (kShadowAddr)
 // | reserved by kernel |
 // +--------------------+ 0x0000000000

 // On Linux/AArch64 (39-bit VMA), memory is laid out as follow:
 //
 // +--------------------+ 0x8000000000 (top of memory)
 // | application memory |
 // +--------------------+ 0x7000008000 (kAppAddr)
 // |                    |
 // |       unused       |
 // |                    |
 // +--------------------+ 0x1200000000 (kUnusedAddr)
 // |    union table     |
 // +--------------------+ 0x1000000000 (kUnionTableAddr)
 // |   shadow memory    |
 // +--------------------+ 0x0000010000 (kShadowAddr)
 // | reserved by kernel |
 // +--------------------+ 0x0000000000

 // On Linux/AArch64 (42-bit VMA), memory is laid out as follow:
 //
 // +--------------------+ 0x40000000000 (top of memory)
 // | application memory |
 // +--------------------+ 0x3ff00008000 (kAppAddr)
 // |                    |
 // |       unused       |
 // |                    |
 // +--------------------+ 0x1200000000 (kUnusedAddr)
 // |    union table     |
 // +--------------------+ 0x8000000000 (kUnionTableAddr)
 // |   shadow memory    |
 // +--------------------+ 0x0000010000 (kShadowAddr)
 // | reserved by kernel |
 // +--------------------+ 0x0000000000

 // On Linux/AArch64 (48-bit VMA), memory is laid out as follow:
 //
 // +--------------------+ 0x1000000000000 (top of memory)
 // | application memory |
 // +--------------------+ 0xffff00008000 (kAppAddr)
 // |       unused       |
 // +--------------------+ 0xaaaab0000000 (top of PIE address)
 // | application PIE    |
 // +--------------------+ 0xaaaaa0000000 (top of PIE address)
 // |                    |
 // |       unused       |
 // |                    |
 // +--------------------+ 0x1200000000 (kUnusedAddr)
 // |    union table     |
 // +--------------------+ 0x8000000000 (kUnionTableAddr)
 // |   shadow memory    |
 // +--------------------+ 0x0000010000 (kShadowAddr)
 // | reserved by kernel |
 // +--------------------+ 0x0000000000

 typedef atomic_dfsan_label dfsan_union_table_t[kNumLabels][kNumLabels];

 #ifdef DFSAN_RUNTIME_VMA
 // Runtime detected VMA size.
 int __dfsan::vmaSize;
 #endif

 static uptr UnusedAddr() {
   return MappingArchImpl<MAPPING_UNION_TABLE_ADDR>()
          + sizeof(dfsan_union_table_t);
 }

 static atomic_dfsan_label *union_table(dfsan_label l1, dfsan_label l2) {
   return &(*(dfsan_union_table_t *) UnionTableAddr())[l1][l2];
 }

 // Checks we do not run out of labels.
 static void dfsan_check_label(dfsan_label label) {
   if (label == kInitializingLabel) {
     Report("FATAL: DataFlowSanitizer: out of labels\n");
     Die();
   }
 }

 // Resolves the union of two unequal labels.  Nonequality is a precondition for
 // this function (the instrumentation pass inlines the equality test).
 extern "C" SANITIZER_INTERFACE_ATTRIBUTE
 dfsan_label __dfsan_union(dfsan_label l1, dfsan_label l2) {
   DCHECK_NE(l1, l2);

   if (l1 == 0)
     return l2;
   if (l2 == 0)
     return l1;

   if (l1 > l2)
     Swap(l1, l2);

   atomic_dfsan_label *table_ent = union_table(l1, l2);
   // We need to deal with the case where two threads concurrently request
   // a union of the same pair of labels.  If the table entry is uninitialized,
   // (i.e. 0) use a compare-exchange to set the entry to kInitializingLabel
   // (i.e. -1) to mark that we are initializing it.
   dfsan_label label = 0;
   if (atomic_compare_exchange_strong(table_ent, &label, kInitializingLabel,
                                      memory_order_acquire)) {
     // Check whether l2 subsumes l1.  We don't need to check whether l1
     // subsumes l2 because we are guaranteed here that l1 < l2, and (at least
     // in the cases we are interested in) a label may only subsume labels
     // created earlier (i.e. with a lower numerical value).
     if (__dfsan_label_info[l2].l1 == l1 ||
         __dfsan_label_info[l2].l2 == l1) {
       label = l2;
     } else {
       label =
         atomic_fetch_add(&__dfsan_last_label, 1, memory_order_relaxed) + 1;
       dfsan_check_label(label);
       __dfsan_label_info[label].l1 = l1;
       __dfsan_label_info[label].l2 = l2;
     }
     atomic_store(table_ent, label, memory_order_release);
   } else if (label == kInitializingLabel) {
     // Another thread is initializing the entry.  Wait until it is finished.
     do {
       internal_sched_yield();
       label = atomic_load(table_ent, memory_order_acquire);
     } while (label == kInitializingLabel);
   }
   return label;
 }

 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) {
     dfsan_label next_label = ls[i];
     if (label != next_label)
       label = __dfsan_union(label, next_label);
   }
   return label;
 }

 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();
 }

 // Like __dfsan_union, but for use from the client or custom functions.  Hence
 // the equality comparison is done here before calling __dfsan_union.
 SANITIZER_INTERFACE_ATTRIBUTE dfsan_label
 dfsan_union(dfsan_label l1, dfsan_label l2) {
   if (l1 == l2)
     return l1;
   return __dfsan_union(l1, l2);
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE
 dfsan_label dfsan_create_label(const char *desc, void *userdata) {
   dfsan_label label =
     atomic_fetch_add(&__dfsan_last_label, 1, memory_order_relaxed) + 1;
   dfsan_check_label(label);
   __dfsan_label_info[label].l1 = __dfsan_label_info[label].l2 = 0;
   __dfsan_label_info[label].desc = desc;
   __dfsan_label_info[label].userdata = userdata;
   return label;
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE
 void __dfsan_set_label(dfsan_label label, void *addr, uptr size) {
   for (dfsan_label *labelp = shadow_for(addr); size != 0; --size, ++labelp) {
     // 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 (label == *labelp)
       continue;

     *labelp = label;
   }
 }

 SANITIZER_INTERFACE_ATTRIBUTE
 void dfsan_set_label(dfsan_label label, void *addr, uptr size) {
   __dfsan_set_label(label, addr, size);
 }

 SANITIZER_INTERFACE_ATTRIBUTE
 void dfsan_add_label(dfsan_label label, void *addr, uptr size) {
   for (dfsan_label *labelp = shadow_for(addr); size != 0; --size, ++labelp)
     if (*labelp != label)
       *labelp = __dfsan_union(*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;
 }

 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);
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE
 const struct dfsan_label_info *dfsan_get_label_info(dfsan_label label) {
   return &__dfsan_label_info[label];
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE int
 dfsan_has_label(dfsan_label label, dfsan_label elem) {
   if (label == elem)
     return true;
   const dfsan_label_info *info = dfsan_get_label_info(label);
   if (info->l1 != 0) {
     return dfsan_has_label(info->l1, elem) || dfsan_has_label(info->l2, elem);
   } else {
     return false;
   }
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label
 dfsan_has_label_with_desc(dfsan_label label, const char *desc) {
   const dfsan_label_info *info = dfsan_get_label_info(label);
   if (info->l1 != 0) {
     return dfsan_has_label_with_desc(info->l1, desc) ||
            dfsan_has_label_with_desc(info->l2, desc);
   } else {
     return internal_strcmp(desc, info->desc) == 0;
   }
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE uptr
 dfsan_get_label_count(void) {
   dfsan_label max_label_allocated =
       atomic_load(&__dfsan_last_label, memory_order_relaxed);

   return static_cast<uptr>(max_label_allocated);
 }

 extern "C" SANITIZER_INTERFACE_ATTRIBUTE void
 dfsan_dump_labels(int fd) {
   dfsan_label last_label =
       atomic_load(&__dfsan_last_label, memory_order_relaxed);

   for (uptr l = 1; l <= last_label; ++l) {
     char buf[64];
     internal_snprintf(buf, sizeof(buf), "%u %u %u ", l,
                       __dfsan_label_info[l].l1, __dfsan_label_info[l].l2);
     WriteToFile(fd, buf, internal_strlen(buf));
     if (__dfsan_label_info[l].l1 == 0 && __dfsan_label_info[l].desc) {
       WriteToFile(fd, __dfsan_label_info[l].desc,
                   internal_strlen(__dfsan_label_info[l].desc));
     }
     WriteToFile(fd, "\n", 1);
   }
 }

 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();
   flags().SetDefaults();

   FlagParser parser;
   RegisterCommonFlags(&parser);
   RegisterDfsanFlags(&parser, &flags());
   parser.ParseString(GetEnv("DFSAN_OPTIONS"));
   InitializeCommonFlags();
   if (Verbosity()) ReportUnrecognizedFlags();
   if (common_flags()->help) parser.PrintFlagDescriptions();
 }

 static void InitializePlatformEarly() {
   AvoidCVE_2016_2143();
 #ifdef DFSAN_RUNTIME_VMA
   __dfsan::vmaSize =
     (MostSignificantSetBitIndex(GET_CURRENT_FRAME()) + 1);
   if (__dfsan::vmaSize == 39 || __dfsan::vmaSize == 42 ||
       __dfsan::vmaSize == 48) {
     __dfsan_shadow_ptr_mask = ShadowMask();
   } else {
     Printf("FATAL: DataFlowSanitizer: unsupported VMA range\n");
     Printf("FATAL: Found %d - Supported 39, 42, and 48\n", __dfsan::vmaSize);
     Die();
   }
 #endif
 }

 static void dfsan_fini() {
   if (internal_strcmp(flags().dump_labels_at_exit, "") != 0) {
     fd_t fd = OpenFile(flags().dump_labels_at_exit, WrOnly);
     if (fd == kInvalidFd) {
       Report("WARNING: DataFlowSanitizer: unable to open output file %s\n",
              flags().dump_labels_at_exit);
       return;
     }

     Report("INFO: DataFlowSanitizer: dumping labels to %s\n",
            flags().dump_labels_at_exit);
     dfsan_dump_labels(fd);
     CloseFile(fd);
   }
 }

 static void dfsan_init(int argc, char **argv, char **envp) {
   InitializeFlags();

   InitializePlatformEarly();

   if (!MmapFixedNoReserve(ShadowAddr(), UnusedAddr() - ShadowAddr()))
     Die();

   // Protect the region of memory we don't use, to preserve the one-to-one
   // mapping from application to shadow memory. But if ASLR is disabled, Linux
   // will load our executable in the middle of our unused region. This mostly
   // works so long as the program doesn't use too much memory. We support this
   // case by disabling memory protection when ASLR is disabled.
   uptr init_addr = (uptr)&dfsan_init;
   if (!(init_addr >= UnusedAddr() && init_addr < AppAddr()))
     MmapFixedNoAccess(UnusedAddr(), AppAddr() - UnusedAddr());

   InitializeInterceptors();

   // Register the fini callback to run when the program terminates successfully
   // or it is killed by the runtime.
   Atexit(dfsan_fini);
   AddDieCallback(dfsan_fini);

   __dfsan_label_info[kInitializingLabel].desc = "<init label>";
 }

 #if SANITIZER_CAN_USE_PREINIT_ARRAY
 __attribute__((section(".preinit_array"), used))
 static void (*dfsan_init_ptr)(int, char **, char **) = dfsan_init;
 #endif
	//===-- dfsan.cc ----------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// 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 "sanitizer_common/sanitizer_atomic.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_file.h"
	#include "sanitizer_common/sanitizer_flags.h"
	#include "sanitizer_common/sanitizer_flag_parser.h"
	#include "sanitizer_common/sanitizer_libc.h"

	#include "dfsan/dfsan.h"

	using namespace __dfsan;

	typedef atomic_uint16_t atomic_dfsan_label;
	static const dfsan_label kInitializingLabel = -1;

	static const uptr kNumLabels = 1 << (sizeof(dfsan_label) * 8);

	static atomic_dfsan_label __dfsan_last_label;
	static dfsan_label_info __dfsan_label_info[kNumLabels];

	Flags __dfsan::flags_data;

	SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL dfsan_label __dfsan_retval_tls;
	SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL dfsan_label __dfsan_arg_tls[64];

	SANITIZER_INTERFACE_ATTRIBUTE uptr __dfsan_shadow_ptr_mask;

	// On Linux/x86_64, memory is laid out as follows:
	//
	// +--------------------+ 0x800000000000 (top of memory)
	// \| application memory \|
	// +--------------------+ 0x700000008000 (kAppAddr)
	// \| \|
	// \| unused \|
	// \| \|
	// +--------------------+ 0x200200000000 (kUnusedAddr)
	// \| union table \|
	// +--------------------+ 0x200000000000 (kUnionTableAddr)
	// \| shadow memory \|
	// +--------------------+ 0x000000010000 (kShadowAddr)
	// \| reserved by kernel \|
	// +--------------------+ 0x000000000000
	//
	// To derive a shadow memory address from an application memory address,
	// bits 44-46 are cleared to bring the address into the range
	// [0x000000008000,0x100000000000). Then the address is shifted left by 1 to
	// account for the double byte representation of shadow labels and move the
	// address into the shadow memory range. See the function shadow_for below.

	// On Linux/MIPS64, memory is laid out as follows:
	//
	// +--------------------+ 0x10000000000 (top of memory)
	// \| application memory \|
	// +--------------------+ 0xF000008000 (kAppAddr)
	// \| \|
	// \| unused \|
	// \| \|
	// +--------------------+ 0x2200000000 (kUnusedAddr)
	// \| union table \|
	// +--------------------+ 0x2000000000 (kUnionTableAddr)
	// \| shadow memory \|
	// +--------------------+ 0x0000010000 (kShadowAddr)
	// \| reserved by kernel \|
	// +--------------------+ 0x0000000000

	// On Linux/AArch64 (39-bit VMA), memory is laid out as follow:
	//
	// +--------------------+ 0x8000000000 (top of memory)
	// \| application memory \|
	// +--------------------+ 0x7000008000 (kAppAddr)
	// \| \|
	// \| unused \|
	// \| \|
	// +--------------------+ 0x1200000000 (kUnusedAddr)
	// \| union table \|
	// +--------------------+ 0x1000000000 (kUnionTableAddr)
	// \| shadow memory \|
	// +--------------------+ 0x0000010000 (kShadowAddr)
	// \| reserved by kernel \|
	// +--------------------+ 0x0000000000

	// On Linux/AArch64 (42-bit VMA), memory is laid out as follow:
	//
	// +--------------------+ 0x40000000000 (top of memory)
	// \| application memory \|
	// +--------------------+ 0x3ff00008000 (kAppAddr)
	// \| \|
	// \| unused \|
	// \| \|
	// +--------------------+ 0x1200000000 (kUnusedAddr)
	// \| union table \|
	// +--------------------+ 0x8000000000 (kUnionTableAddr)
	// \| shadow memory \|
	// +--------------------+ 0x0000010000 (kShadowAddr)
	// \| reserved by kernel \|
	// +--------------------+ 0x0000000000

	// On Linux/AArch64 (48-bit VMA), memory is laid out as follow:
	//
	// +--------------------+ 0x1000000000000 (top of memory)
	// \| application memory \|
	// +--------------------+ 0xffff00008000 (kAppAddr)
	// \| unused \|
	// +--------------------+ 0xaaaab0000000 (top of PIE address)
	// \| application PIE \|
	// +--------------------+ 0xaaaaa0000000 (top of PIE address)
	// \| \|
	// \| unused \|
	// \| \|
	// +--------------------+ 0x1200000000 (kUnusedAddr)
	// \| union table \|
	// +--------------------+ 0x8000000000 (kUnionTableAddr)
	// \| shadow memory \|
	// +--------------------+ 0x0000010000 (kShadowAddr)
	// \| reserved by kernel \|
	// +--------------------+ 0x0000000000

	typedef atomic_dfsan_label dfsan_union_table_t[kNumLabels][kNumLabels];

	#ifdef DFSAN_RUNTIME_VMA
	// Runtime detected VMA size.
	int __dfsan::vmaSize;
	#endif

	static uptr UnusedAddr() {
	return MappingArchImpl<MAPPING_UNION_TABLE_ADDR>()
	+ sizeof(dfsan_union_table_t);
	}

	static atomic_dfsan_label *union_table(dfsan_label l1, dfsan_label l2) {
	return &((dfsan_union_table_t ) UnionTableAddr())[l1][l2];
	}

	// Checks we do not run out of labels.
	static void dfsan_check_label(dfsan_label label) {
	if (label == kInitializingLabel) {
	Report("FATAL: DataFlowSanitizer: out of labels\n");
	Die();
	}
	}

	// Resolves the union of two unequal labels. Nonequality is a precondition for
	// this function (the instrumentation pass inlines the equality test).
	extern "C" SANITIZER_INTERFACE_ATTRIBUTE
	dfsan_label __dfsan_union(dfsan_label l1, dfsan_label l2) {
	DCHECK_NE(l1, l2);

	if (l1 == 0)
	return l2;
	if (l2 == 0)
	return l1;

	if (l1 > l2)
	Swap(l1, l2);

	atomic_dfsan_label *table_ent = union_table(l1, l2);
	// We need to deal with the case where two threads concurrently request
	// a union of the same pair of labels. If the table entry is uninitialized,
	// (i.e. 0) use a compare-exchange to set the entry to kInitializingLabel
	// (i.e. -1) to mark that we are initializing it.
	dfsan_label label = 0;
	if (atomic_compare_exchange_strong(table_ent, &label, kInitializingLabel,
	memory_order_acquire)) {
	// Check whether l2 subsumes l1. We don't need to check whether l1
	// subsumes l2 because we are guaranteed here that l1 < l2, and (at least
	// in the cases we are interested in) a label may only subsume labels
	// created earlier (i.e. with a lower numerical value).
	if (__dfsan_label_info[l2].l1 == l1 \|\|
	__dfsan_label_info[l2].l2 == l1) {
	label = l2;
	} else {
	label =
	atomic_fetch_add(&__dfsan_last_label, 1, memory_order_relaxed) + 1;
	dfsan_check_label(label);
	__dfsan_label_info[label].l1 = l1;
	__dfsan_label_info[label].l2 = l2;
	}
	atomic_store(table_ent, label, memory_order_release);
	} else if (label == kInitializingLabel) {
	// Another thread is initializing the entry. Wait until it is finished.
	do {
	internal_sched_yield();
	label = atomic_load(table_ent, memory_order_acquire);
	} while (label == kInitializingLabel);
	}
	return label;
	}

	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) {
	dfsan_label next_label = ls[i];
	if (label != next_label)
	label = __dfsan_union(label, next_label);
	}
	return label;
	}

	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();
	}

	// Like __dfsan_union, but for use from the client or custom functions. Hence
	// the equality comparison is done here before calling __dfsan_union.
	SANITIZER_INTERFACE_ATTRIBUTE dfsan_label
	dfsan_union(dfsan_label l1, dfsan_label l2) {
	if (l1 == l2)
	return l1;
	return __dfsan_union(l1, l2);
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE
	dfsan_label dfsan_create_label(const char desc, void userdata) {
	dfsan_label label =
	atomic_fetch_add(&__dfsan_last_label, 1, memory_order_relaxed) + 1;
	dfsan_check_label(label);
	__dfsan_label_info[label].l1 = __dfsan_label_info[label].l2 = 0;
	__dfsan_label_info[label].desc = desc;
	__dfsan_label_info[label].userdata = userdata;
	return label;
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE
	void __dfsan_set_label(dfsan_label label, void *addr, uptr size) {
	for (dfsan_label *labelp = shadow_for(addr); size != 0; --size, ++labelp) {
	// 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 (label == *labelp)
	continue;

	*labelp = label;
	}
	}

	SANITIZER_INTERFACE_ATTRIBUTE
	void dfsan_set_label(dfsan_label label, void *addr, uptr size) {
	__dfsan_set_label(label, addr, size);
	}

	SANITIZER_INTERFACE_ATTRIBUTE
	void dfsan_add_label(dfsan_label label, void *addr, uptr size) {
	for (dfsan_label *labelp = shadow_for(addr); size != 0; --size, ++labelp)
	if (*labelp != label)
	labelp = __dfsan_union(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;
	}

	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);
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE
	const struct dfsan_label_info *dfsan_get_label_info(dfsan_label label) {
	return &__dfsan_label_info[label];
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE int
	dfsan_has_label(dfsan_label label, dfsan_label elem) {
	if (label == elem)
	return true;
	const dfsan_label_info *info = dfsan_get_label_info(label);
	if (info->l1 != 0) {
	return dfsan_has_label(info->l1, elem) \|\| dfsan_has_label(info->l2, elem);
	} else {
	return false;
	}
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE dfsan_label
	dfsan_has_label_with_desc(dfsan_label label, const char *desc) {
	const dfsan_label_info *info = dfsan_get_label_info(label);
	if (info->l1 != 0) {
	return dfsan_has_label_with_desc(info->l1, desc) \|\|
	dfsan_has_label_with_desc(info->l2, desc);
	} else {
	return internal_strcmp(desc, info->desc) == 0;
	}
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE uptr
	dfsan_get_label_count(void) {
	dfsan_label max_label_allocated =
	atomic_load(&__dfsan_last_label, memory_order_relaxed);

	return static_cast<uptr>(max_label_allocated);
	}

	extern "C" SANITIZER_INTERFACE_ATTRIBUTE void
	dfsan_dump_labels(int fd) {
	dfsan_label last_label =
	atomic_load(&__dfsan_last_label, memory_order_relaxed);

	for (uptr l = 1; l <= last_label; ++l) {
	char buf[64];
	internal_snprintf(buf, sizeof(buf), "%u %u %u ", l,
	__dfsan_label_info[l].l1, __dfsan_label_info[l].l2);
	WriteToFile(fd, buf, internal_strlen(buf));
	if (__dfsan_label_info[l].l1 == 0 && __dfsan_label_info[l].desc) {
	WriteToFile(fd, __dfsan_label_info[l].desc,
	internal_strlen(__dfsan_label_info[l].desc));
	}
	WriteToFile(fd, "\n", 1);
	}
	}

	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();
	flags().SetDefaults();

	FlagParser parser;
	RegisterCommonFlags(&parser);
	RegisterDfsanFlags(&parser, &flags());
	parser.ParseString(GetEnv("DFSAN_OPTIONS"));
	InitializeCommonFlags();
	if (Verbosity()) ReportUnrecognizedFlags();
	if (common_flags()->help) parser.PrintFlagDescriptions();
	}

	static void InitializePlatformEarly() {
	AvoidCVE_2016_2143();
	#ifdef DFSAN_RUNTIME_VMA
	__dfsan::vmaSize =
	(MostSignificantSetBitIndex(GET_CURRENT_FRAME()) + 1);
	if (__dfsan::vmaSize == 39 \|\| __dfsan::vmaSize == 42 \|\|
	__dfsan::vmaSize == 48) {
	__dfsan_shadow_ptr_mask = ShadowMask();
	} else {
	Printf("FATAL: DataFlowSanitizer: unsupported VMA range\n");
	Printf("FATAL: Found %d - Supported 39, 42, and 48\n", __dfsan::vmaSize);
	Die();
	}
	#endif
	}

	static void dfsan_fini() {
	if (internal_strcmp(flags().dump_labels_at_exit, "") != 0) {
	fd_t fd = OpenFile(flags().dump_labels_at_exit, WrOnly);
	if (fd == kInvalidFd) {
	Report("WARNING: DataFlowSanitizer: unable to open output file %s\n",
	flags().dump_labels_at_exit);
	return;
	}

	Report("INFO: DataFlowSanitizer: dumping labels to %s\n",
	flags().dump_labels_at_exit);
	dfsan_dump_labels(fd);
	CloseFile(fd);
	}
	}

	static void dfsan_init(int argc, char argv, char envp) {
	InitializeFlags();

	InitializePlatformEarly();

	if (!MmapFixedNoReserve(ShadowAddr(), UnusedAddr() - ShadowAddr()))
	Die();

	// Protect the region of memory we don't use, to preserve the one-to-one
	// mapping from application to shadow memory. But if ASLR is disabled, Linux
	// will load our executable in the middle of our unused region. This mostly
	// works so long as the program doesn't use too much memory. We support this
	// case by disabling memory protection when ASLR is disabled.
	uptr init_addr = (uptr)&dfsan_init;
	if (!(init_addr >= UnusedAddr() && init_addr < AppAddr()))
	MmapFixedNoAccess(UnusedAddr(), AppAddr() - UnusedAddr());

	InitializeInterceptors();

	// Register the fini callback to run when the program terminates successfully
	// or it is killed by the runtime.
	Atexit(dfsan_fini);
	AddDieCallback(dfsan_fini);

	__dfsan_label_info[kInitializingLabel].desc = "<init label>";
	}

	#if SANITIZER_CAN_USE_PREINIT_ARRAY
	__attribute__((section(".preinit_array"), used))
	static void (dfsan_init_ptr)(int, char , char *) = dfsan_init;
	#endif