gcc/ada/doc/gnat_rm/security_hardening_features.rst - gcc - Git at Google

 .. _Security_Hardening_Features:

 ***************************
 Security Hardening Features
 ***************************

 This chapter describes Ada extensions aimed at security hardening that
 are provided by GNAT.

 The features in this chapter are currently experimental and subject to
 change.

 .. Register Scrubbing:

 Register Scrubbing
 ==================

 GNAT can generate code to zero-out hardware registers before returning
 from a subprogram.

 It can be enabled with the :switch:`-fzero-call-used-regs={choice}`
 command-line option, to affect all subprograms in a compilation, and
 with a :samp:`Machine_Attribute` pragma, to affect only specific
 subprograms.

 .. code-block:: ada

      procedure Foo;
      pragma Machine_Attribute (Foo, "zero_call_used_regs", "used");
      --  Before returning, Foo scrubs only call-clobbered registers
      --  that it uses itself.

      function Bar return Integer;
      pragma Machine_Attribute (Bar, "zero_call_used_regs", "all");
      --  Before returning, Bar scrubs all call-clobbered registers.


 For usage and more details on the command-line option, on the
 ``zero_call_used_regs`` attribute, and on their use with other
 programming languages, see :title:`Using the GNU Compiler Collection
 (GCC)`.


 .. Stack Scrubbing:

 Stack Scrubbing
 ===============

 GNAT can generate code to zero-out stack frames used by subprograms.

 It can be activated with the :samp:`Machine_Attribute` pragma, on
 specific subprograms and variables, or their types.  (This attribute
 always applies to a type, even when it is associated with a subprogram
 or a variable.)

 .. code-block:: ada

      function Foo returns Integer;
      pragma Machine_Attribute (Foo, "strub");
      --  Foo and its callers are modified so as to scrub the stack
      --  space used by Foo after it returns.  Shorthand for:
      --  pragma Machine_Attribute (Foo, "strub", "at-calls");

      procedure Bar;
      pragma Machine_Attribute (Bar, "strub", "internal");
      --  Bar is turned into a wrapper for its original body,
      --  and they scrub the stack used by the original body.

      Var : Integer;
      pragma Machine_Attribute (Var, "strub");
      --  Reading from Var in a subprogram enables stack scrubbing
      --  of the stack space used by the subprogram.  Furthermore, if
      --  Var is declared within a subprogram, this also enables
      --  scrubbing of the stack space used by that subprogram.


 Given these declarations, Foo has its type and body modified as
 follows:

 .. code-block:: ada

      function Foo (<WaterMark> : in out System.Address) returns Integer
      is
        --  ...
      begin
        <__strub_update> (<WaterMark>);  --  Updates the stack WaterMark.
        --  ...
      end;


 whereas its callers are modified from:

 .. code-block:: ada

      X := Foo;

 to:

 .. code-block:: ada

      declare
        <WaterMark> : System.Address;
      begin
        <__strub_enter> (<WaterMark>);  -- Initialize <WaterMark>.
        X := Foo (<WaterMark>);
        <__strub_leave> (<WaterMark>);  -- Scrubs stack up to <WaterMark>.
      end;


 As for Bar, because it is strubbed in internal mode, its callers are
 not modified.  Its definition is modified roughly as follows:

 .. code-block:: ada

      procedure Bar is
        <WaterMark> : System.Address;
        procedure Strubbed_Bar (<WaterMark> : in out System.Address) is
        begin
          <__strub_update> (<WaterMark>);  --  Updates the stack WaterMark.
          -- original Bar body.
        end Strubbed_Bar;
      begin
        <__strub_enter> (<WaterMark>);  -- Initialize <WaterMark>.
        Strubbed_Bar (<WaterMark>);
        <__strub_leave> (<WaterMark>);  -- Scrubs stack up to <WaterMark>.
      end Bar;


 There are also :switch:`-fstrub={choice}` command-line options to
 control default settings.  For usage and more details on the
 command-line options, on the ``strub`` attribute, and their use with
 other programming languages, see :title:`Using the GNU Compiler
 Collection (GCC)`.

 Note that Ada secondary stacks are not scrubbed.  The restriction
 ``No_Secondary_Stack`` avoids their use, and thus their accidental
 preservation of data that should be scrubbed.

 Attributes ``Access`` and ``Unconstrained_Access`` of variables and
 constants with ``strub`` enabled require types with ``strub`` enabled;
 there is no way to express an access-to-strub type otherwise.
 ``Unchecked_Access`` bypasses this constraint, but the resulting
 access type designates a non-strub type.

 .. code-block:: ada

      VI : aliased Integer;
      pragma Machine_Attribute (VI, "strub");
      XsVI : access Integer := VI'Access; -- Error.
      UXsVI : access Integer := VI'Unchecked_Access; -- OK,
      --  UXsVI does *not* enable strub in subprograms that
      --  dereference it to obtain the UXsVI.all value.

      type Strub_Int is new Integer;
      pragma Machine_Attribute (Strub_Int, "strub");
      VSI : aliased Strub_Int;
      XsVSI : access Strub_Int := VSI'Access; -- OK,
      --  VSI and XsVSI.all both enable strub in subprograms that
      --  read their values.


 Every access-to-subprogram type, renaming, and overriding and
 overridden dispatching operations that may refer to a subprogram with
 an attribute-modified interface must be annotated with the same
 interface-modifying attribute.  Access-to-subprogram types can be
 explicitly converted to different strub modes, as long as they are
 interface-compatible (i.e., adding or removing ``at-calls`` is not
 allowed).  For example, a ``strub``-``disabled`` subprogram can be
 turned ``callable`` through such an explicit conversion:

 .. code-block:: ada

      type TBar is access procedure;

      type TBar_Callable is access procedure;
      pragma Machine_Attribute (TBar_Callable, "strub", "callable");
      --  The attribute modifies the procedure type, rather than the
      --  access type, because of the extra argument after "strub",
      --  only applicable to subprogram types.

      Bar_Callable_Ptr : constant TBar_Callable
 		:= TBar_Callable (TBar'(Bar'Access));

      procedure Bar_Callable renames Bar_Callable_Ptr.all;
      pragma Machine_Attribute (Bar_Callable, "strub", "callable");


 Note that the renaming declaration is expanded to a full subprogram
 body, it won't be just an alias.  Only if it is inlined will it be as
 efficient as a call by dereferencing the access-to-subprogram constant
 Bar_Callable_Ptr.


 .. Hardened Conditionals:

 Hardened Conditionals
 =====================

 GNAT can harden conditionals to protect against control-flow attacks.

 This is accomplished by two complementary transformations, each
 activated by a separate command-line option.

 The option :switch:`-fharden-compares` enables hardening of compares
 that compute results stored in variables, adding verification that the
 reversed compare yields the opposite result, turning:

 .. code-block:: ada

     B := X = Y;


 into:

 .. code-block:: ada

     B := X = Y;
     declare
       NotB : Boolean := X /= Y; -- Computed independently of B.
     begin
       if B = NotB then
         <__builtin_trap>;
       end if;
     end;


 The option :switch:`-fharden-conditional-branches` enables hardening
 of compares that guard conditional branches, adding verification of
 the reversed compare to both execution paths, turning:

 .. code-block:: ada

     if X = Y then
       X := Z + 1;
     else
       Y := Z - 1;
     end if;


 into:

 .. code-block:: ada

     if X = Y then
       if X /= Y then -- Computed independently of X = Y.
         <__builtin_trap>;
       end if;
       X := Z + 1;
     else
       if X /= Y then -- Computed independently of X = Y.
         null;
       else
         <__builtin_trap>;
       end if;
       Y := Z - 1;
     end if;


 These transformations are introduced late in the compilation pipeline,
 long after boolean expressions are decomposed into separate compares,
 each one turned into either a conditional branch or a compare whose
 result is stored in a boolean variable or temporary.  Compiler
 optimizations, if enabled, may also turn conditional branches into
 stored compares, and vice-versa, or into operations with implied
 conditionals (e.g. MIN and MAX).  Conditionals may also be optimized
 out entirely, if their value can be determined at compile time, and
 occasionally multiple compares can be combined into one.

 It is thus difficult to predict which of these two options will affect
 a specific compare operation expressed in source code.  Using both
 options ensures that every compare that is neither optimized out nor
 optimized into implied conditionals will be hardened.

 The addition of reversed compares can be observed by enabling the dump
 files of the corresponding passes, through command-line options
 :switch:`-fdump-tree-hardcmp` and :switch:`-fdump-tree-hardcbr`,
 respectively.

 They are separate options, however, because of the significantly
 different performance impact of the hardening transformations.

 For usage and more details on the command-line options, see
 :title:`Using the GNU Compiler Collection (GCC)`.  These options can
 be used with other programming languages supported by GCC.


 .. Hardened Booleans:

 Hardened Booleans
 =================

 Ada has built-in support for introducing boolean types with
 alternative representations, using representation clauses:

 .. code-block:: ada

    type HBool is new Boolean;
    for HBool use (16#5a#, 16#a5#);
    for HBool'Size use 8;


 When validity checking is enabled, the compiler will check that
 variables of such types hold values corresponding to the selected
 representations.

 There are multiple strategies for where to introduce validity checking
 (see :switch:`-gnatV` options).  Their goal is to guard against
 various kinds of programming errors, and GNAT strives to omit checks
 when program logic rules out an invalid value, and optimizers may
 further remove checks found to be redundant.

 For additional hardening, the ``hardbool`` :samp:`Machine_Attribute`
 pragma can be used to annotate boolean types with representation
 clauses, so that expressions of such types used as conditions are
 checked even when compiling with :switch:`-gnatVT`:

 .. code-block:: ada

    pragma Machine_Attribute (HBool, "hardbool");

    function To_Boolean (X : HBool) returns Boolean is (Boolean (X));


 is compiled roughly like:

 .. code-block:: ada

    function To_Boolean (X : HBool) returns Boolean is
    begin
      if X not in True | False then
        raise Constraint_Error;
      elsif X in True then
        return True;
      else
        return False;
      end if;
    end To_Boolean;


 Note that :switch:`-gnatVn` will disable even ``hardbool`` testing.

 Analogous behavior is available as a GCC extension to the C and
 Objective C programming languages, through the ``hardbool`` attribute,
 with the difference that, instead of raising a Constraint_Error
 exception, when a hardened boolean variable is found to hold a value
 that stands for neither True nor False, the program traps.  For usage
 and more details on that attribute, see :title:`Using the GNU Compiler
 Collection (GCC)`.


 .. Control Flow Redundancy:

 Control Flow Redundancy
 =======================

 GNAT can guard against unexpected execution flows, such as branching
 into the middle of subprograms, as in Return Oriented Programming
 exploits.

 In units compiled with :switch:`-fharden-control-flow-redundancy`,
 subprograms are instrumented so that, every time they are called,
 basic blocks take note as control flows through them, and, before
 returning, subprograms verify that the taken notes are consistent with
 the control-flow graph.

 Functions with too many basic blocks, or with multiple return points,
 call a run-time function to perform the verification.  Other functions
 perform the verification inline before returning.

 Optimizing the inlined verification can be quite time consuming, so
 the default upper limit for the inline mode is set at 16 blocks.
 Command-line option :switch:`--param hardcfr-max-inline-blocks=` can
 override it.

 Even though typically sparse control-flow graphs exhibit run-time
 verification time nearly proportional to the block count of a
 subprogram, it may become very significant for generated subprograms
 with thousands of blocks.  Command-line option
 :switch:`--param hardcfr-max-blocks=` can set an upper limit for
 instrumentation.

 For each block that is marked as visited, the mechanism checks that at
 least one of its predecessors, and at least one of its successors, are
 also marked as visited.

 Verification is performed just before a subprogram returns.  The
 following fragment:

 .. code-block:: ada

    if X then
      Y := F (Z);
      return;
    end if;


 gets turned into:

 .. code-block:: ada

    type Visited_Bitmap is array (1..N) of Boolean with Pack;
    Visited : aliased Visited_Bitmap := (others => False);
    --  Bitmap of visited blocks.  N is the basic block count.
    [...]
    --  Basic block #I
    Visited(I) := True;
    if X then
      --  Basic block #J
      Visited(J) := True;
      Y := F (Z);
      CFR.Check (N, Visited'Access, CFG'Access);
      --  CFR is a hypothetical package whose Check procedure calls
      --  libgcc's __hardcfr_check, that traps if the Visited bitmap
      --  does not hold a valid path in CFG, the run-time
      --  representation of the control flow graph in the enclosing
      --  subprogram.
      return;
    end if;
    --  Basic block #K
    Visited(K) := True;


 Verification would also be performed before tail calls, if any
 front-ends marked them as mandatory or desirable, but none do.
 Regular calls are optimized into tail calls too late for this
 transformation to act on it.

 In order to avoid adding verification after potential tail calls,
 which would prevent tail-call optimization, we recognize returning
 calls, i.e., calls whose result, if any, is returned by the calling
 subprogram to its caller immediately after the call returns.
 Verification is performed before such calls, whether or not they are
 ultimately optimized to tail calls.  This behavior is enabled by
 default whenever sibcall optimization is enabled (see
 :switch:`-foptimize-sibling-calls`); it may be disabled with
 :switch:`-fno-hardcfr-check-returning-calls`, or enabled with
 :switch:`-fhardcfr-check-returning-calls`, regardless of the
 optimization, but the lack of other optimizations may prevent calls
 from being recognized as returning calls:

 .. code-block:: ada

      --  CFR.Check here, with -fhardcfr-check-returning-calls.
      P (X);
      --  CFR.Check here, with -fno-hardcfr-check-returning-calls.
      return;

 or:

 .. code-block:: ada

      --  CFR.Check here, with -fhardcfr-check-returning-calls.
      R := F (X);
      --  CFR.Check here, with -fno-hardcfr-check-returning-calls.
      return R;


 Any subprogram from which an exception may escape, i.e., that may
 raise or propagate an exception that isn't handled internally, is
 conceptually enclosed by a cleanup handler that performs verification,
 unless this is disabled with :switch:`-fno-hardcfr-check-exceptions`.
 With this feature enabled, a subprogram body containing:

 .. code-block:: ada

      --  ...
        Y := F (X);  -- May raise exceptions.
      --  ...
        raise E;  -- Not handled internally.
      --  ...


 gets modified as follows:

 .. code-block:: ada

    begin
      --  ...
        Y := F (X);  -- May raise exceptions.
      --  ...
        raise E;  -- Not handled internally.
      --  ...
    exception
      when others =>
        CFR.Check (N, Visited'Access, CFG'Access);
        raise;
    end;


 Verification may also be performed before No_Return calls, whether
 only nothrow ones, with
 :switch:`-fhardcfr-check-noreturn-calls=nothrow`, or all of them, with
 :switch:`-fhardcfr-check-noreturn-calls=always`.  The default is
 :switch:`-fhardcfr-check-noreturn-calls=never` for this feature, that
 disables checking before No_Return calls.

 When a No_Return call returns control to its caller through an
 exception, verification may have already been performed before the
 call, if :switch:`-fhardcfr-check-noreturn-calls=always` is in effect.
 The compiler arranges for already-checked No_Return calls without a
 preexisting handler to bypass the implicitly-added cleanup handler and
 thus the redundant check, but a local exception or cleanup handler, if
 present, will modify the set of visited blocks, and checking will take
 place again when the caller reaches the next verification point,
 whether it is a return or reraise statement after the exception is
 otherwise handled, or even another No_Return call.

 The instrumentation for hardening with control flow redundancy can be
 observed in dump files generated by the command-line option
 :switch:`-fdump-tree-hardcfr`.

 For more details on the control flow redundancy command-line options,
 see :title:`Using the GNU Compiler Collection (GCC)`.  These options
 can be used with other programming languages supported by GCC.
	.. _Security_Hardening_Features:

	***************************
	Security Hardening Features
	***************************

	This chapter describes Ada extensions aimed at security hardening that
	are provided by GNAT.

	The features in this chapter are currently experimental and subject to
	change.

	.. Register Scrubbing:

	Register Scrubbing
	==================

	GNAT can generate code to zero-out hardware registers before returning
	from a subprogram.

	It can be enabled with the :switch:`-fzero-call-used-regs={choice}`
	command-line option, to affect all subprograms in a compilation, and
	with a :samp:`Machine_Attribute` pragma, to affect only specific
	subprograms.

	.. code-block:: ada

	procedure Foo;
	pragma Machine_Attribute (Foo, "zero_call_used_regs", "used");
	-- Before returning, Foo scrubs only call-clobbered registers
	-- that it uses itself.

	function Bar return Integer;
	pragma Machine_Attribute (Bar, "zero_call_used_regs", "all");
	-- Before returning, Bar scrubs all call-clobbered registers.


	For usage and more details on the command-line option, on the
	``zero_call_used_regs`` attribute, and on their use with other
	programming languages, see :title:`Using the GNU Compiler Collection
	(GCC)`.


	.. Stack Scrubbing:

	Stack Scrubbing
	===============

	GNAT can generate code to zero-out stack frames used by subprograms.

	It can be activated with the :samp:`Machine_Attribute` pragma, on
	specific subprograms and variables, or their types. (This attribute
	always applies to a type, even when it is associated with a subprogram
	or a variable.)

	.. code-block:: ada

	function Foo returns Integer;
	pragma Machine_Attribute (Foo, "strub");
	-- Foo and its callers are modified so as to scrub the stack
	-- space used by Foo after it returns. Shorthand for:
	-- pragma Machine_Attribute (Foo, "strub", "at-calls");

	procedure Bar;
	pragma Machine_Attribute (Bar, "strub", "internal");
	-- Bar is turned into a wrapper for its original body,
	-- and they scrub the stack used by the original body.

	Var : Integer;
	pragma Machine_Attribute (Var, "strub");
	-- Reading from Var in a subprogram enables stack scrubbing
	-- of the stack space used by the subprogram. Furthermore, if
	-- Var is declared within a subprogram, this also enables
	-- scrubbing of the stack space used by that subprogram.


	Given these declarations, Foo has its type and body modified as
	follows:

	.. code-block:: ada

	function Foo (<WaterMark> : in out System.Address) returns Integer
	is
	-- ...
	begin
	<__strub_update> (<WaterMark>); -- Updates the stack WaterMark.
	-- ...
	end;


	whereas its callers are modified from:

	.. code-block:: ada

	X := Foo;

	to:

	.. code-block:: ada

	declare
	<WaterMark> : System.Address;
	begin
	<__strub_enter> (<WaterMark>); -- Initialize <WaterMark>.
	X := Foo (<WaterMark>);
	<__strub_leave> (<WaterMark>); -- Scrubs stack up to <WaterMark>.
	end;


	As for Bar, because it is strubbed in internal mode, its callers are
	not modified. Its definition is modified roughly as follows:

	.. code-block:: ada

	procedure Bar is
	<WaterMark> : System.Address;
	procedure Strubbed_Bar (<WaterMark> : in out System.Address) is
	begin
	<__strub_update> (<WaterMark>); -- Updates the stack WaterMark.
	-- original Bar body.
	end Strubbed_Bar;
	begin
	<__strub_enter> (<WaterMark>); -- Initialize <WaterMark>.
	Strubbed_Bar (<WaterMark>);
	<__strub_leave> (<WaterMark>); -- Scrubs stack up to <WaterMark>.
	end Bar;


	There are also :switch:`-fstrub={choice}` command-line options to
	control default settings. For usage and more details on the
	command-line options, on the ``strub`` attribute, and their use with
	other programming languages, see :title:`Using the GNU Compiler
	Collection (GCC)`.

	Note that Ada secondary stacks are not scrubbed. The restriction
	``No_Secondary_Stack`` avoids their use, and thus their accidental
	preservation of data that should be scrubbed.

	Attributes ``Access`` and ``Unconstrained_Access`` of variables and
	constants with ``strub`` enabled require types with ``strub`` enabled;
	there is no way to express an access-to-strub type otherwise.
	``Unchecked_Access`` bypasses this constraint, but the resulting
	access type designates a non-strub type.

	.. code-block:: ada

	VI : aliased Integer;
	pragma Machine_Attribute (VI, "strub");
	XsVI : access Integer := VI'Access; -- Error.
	UXsVI : access Integer := VI'Unchecked_Access; -- OK,
	-- UXsVI does not enable strub in subprograms that
	-- dereference it to obtain the UXsVI.all value.

	type Strub_Int is new Integer;
	pragma Machine_Attribute (Strub_Int, "strub");
	VSI : aliased Strub_Int;
	XsVSI : access Strub_Int := VSI'Access; -- OK,
	-- VSI and XsVSI.all both enable strub in subprograms that
	-- read their values.


	Every access-to-subprogram type, renaming, and overriding and
	overridden dispatching operations that may refer to a subprogram with
	an attribute-modified interface must be annotated with the same
	interface-modifying attribute. Access-to-subprogram types can be
	explicitly converted to different strub modes, as long as they are
	interface-compatible (i.e., adding or removing ``at-calls`` is not
	allowed). For example, a ``strub``-``disabled`` subprogram can be
	turned ``callable`` through such an explicit conversion:

	.. code-block:: ada

	type TBar is access procedure;

	type TBar_Callable is access procedure;
	pragma Machine_Attribute (TBar_Callable, "strub", "callable");
	-- The attribute modifies the procedure type, rather than the
	-- access type, because of the extra argument after "strub",
	-- only applicable to subprogram types.

	Bar_Callable_Ptr : constant TBar_Callable
	:= TBar_Callable (TBar'(Bar'Access));

	procedure Bar_Callable renames Bar_Callable_Ptr.all;
	pragma Machine_Attribute (Bar_Callable, "strub", "callable");


	Note that the renaming declaration is expanded to a full subprogram
	body, it won't be just an alias. Only if it is inlined will it be as
	efficient as a call by dereferencing the access-to-subprogram constant
	Bar_Callable_Ptr.


	.. Hardened Conditionals:

	Hardened Conditionals
	=====================

	GNAT can harden conditionals to protect against control-flow attacks.

	This is accomplished by two complementary transformations, each
	activated by a separate command-line option.

	The option :switch:`-fharden-compares` enables hardening of compares
	that compute results stored in variables, adding verification that the
	reversed compare yields the opposite result, turning:

	.. code-block:: ada

	B := X = Y;


	into:

	.. code-block:: ada

	B := X = Y;
	declare
	NotB : Boolean := X /= Y; -- Computed independently of B.
	begin
	if B = NotB then
	<__builtin_trap>;
	end if;
	end;


	The option :switch:`-fharden-conditional-branches` enables hardening
	of compares that guard conditional branches, adding verification of
	the reversed compare to both execution paths, turning:

	.. code-block:: ada

	if X = Y then
	X := Z + 1;
	else
	Y := Z - 1;
	end if;


	into:

	.. code-block:: ada

	if X = Y then
	if X /= Y then -- Computed independently of X = Y.
	<__builtin_trap>;
	end if;
	X := Z + 1;
	else
	if X /= Y then -- Computed independently of X = Y.
	null;
	else
	<__builtin_trap>;
	end if;
	Y := Z - 1;
	end if;


	These transformations are introduced late in the compilation pipeline,
	long after boolean expressions are decomposed into separate compares,
	each one turned into either a conditional branch or a compare whose
	result is stored in a boolean variable or temporary. Compiler
	optimizations, if enabled, may also turn conditional branches into
	stored compares, and vice-versa, or into operations with implied
	conditionals (e.g. MIN and MAX). Conditionals may also be optimized
	out entirely, if their value can be determined at compile time, and
	occasionally multiple compares can be combined into one.

	It is thus difficult to predict which of these two options will affect
	a specific compare operation expressed in source code. Using both
	options ensures that every compare that is neither optimized out nor
	optimized into implied conditionals will be hardened.

	The addition of reversed compares can be observed by enabling the dump
	files of the corresponding passes, through command-line options
	:switch:`-fdump-tree-hardcmp` and :switch:`-fdump-tree-hardcbr`,
	respectively.

	They are separate options, however, because of the significantly
	different performance impact of the hardening transformations.

	For usage and more details on the command-line options, see
	:title:`Using the GNU Compiler Collection (GCC)`. These options can
	be used with other programming languages supported by GCC.


	.. Hardened Booleans:

	Hardened Booleans
	=================

	Ada has built-in support for introducing boolean types with
	alternative representations, using representation clauses:

	.. code-block:: ada

	type HBool is new Boolean;
	for HBool use (16#5a#, 16#a5#);
	for HBool'Size use 8;


	When validity checking is enabled, the compiler will check that
	variables of such types hold values corresponding to the selected
	representations.

	There are multiple strategies for where to introduce validity checking
	(see :switch:`-gnatV` options). Their goal is to guard against
	various kinds of programming errors, and GNAT strives to omit checks
	when program logic rules out an invalid value, and optimizers may
	further remove checks found to be redundant.

	For additional hardening, the ``hardbool`` :samp:`Machine_Attribute`
	pragma can be used to annotate boolean types with representation
	clauses, so that expressions of such types used as conditions are
	checked even when compiling with :switch:`-gnatVT`:

	.. code-block:: ada

	pragma Machine_Attribute (HBool, "hardbool");

	function To_Boolean (X : HBool) returns Boolean is (Boolean (X));


	is compiled roughly like:

	.. code-block:: ada

	function To_Boolean (X : HBool) returns Boolean is
	begin
	if X not in True \| False then
	raise Constraint_Error;
	elsif X in True then
	return True;
	else
	return False;
	end if;
	end To_Boolean;


	Note that :switch:`-gnatVn` will disable even ``hardbool`` testing.

	Analogous behavior is available as a GCC extension to the C and
	Objective C programming languages, through the ``hardbool`` attribute,
	with the difference that, instead of raising a Constraint_Error
	exception, when a hardened boolean variable is found to hold a value
	that stands for neither True nor False, the program traps. For usage
	and more details on that attribute, see :title:`Using the GNU Compiler
	Collection (GCC)`.


	.. Control Flow Redundancy:

	Control Flow Redundancy
	=======================

	GNAT can guard against unexpected execution flows, such as branching
	into the middle of subprograms, as in Return Oriented Programming
	exploits.

	In units compiled with :switch:`-fharden-control-flow-redundancy`,
	subprograms are instrumented so that, every time they are called,
	basic blocks take note as control flows through them, and, before
	returning, subprograms verify that the taken notes are consistent with
	the control-flow graph.

	Functions with too many basic blocks, or with multiple return points,
	call a run-time function to perform the verification. Other functions
	perform the verification inline before returning.

	Optimizing the inlined verification can be quite time consuming, so
	the default upper limit for the inline mode is set at 16 blocks.
	Command-line option :switch:`--param hardcfr-max-inline-blocks=` can
	override it.

	Even though typically sparse control-flow graphs exhibit run-time
	verification time nearly proportional to the block count of a
	subprogram, it may become very significant for generated subprograms
	with thousands of blocks. Command-line option
	:switch:`--param hardcfr-max-blocks=` can set an upper limit for
	instrumentation.

	For each block that is marked as visited, the mechanism checks that at
	least one of its predecessors, and at least one of its successors, are
	also marked as visited.

	Verification is performed just before a subprogram returns. The
	following fragment:

	.. code-block:: ada

	if X then
	Y := F (Z);
	return;
	end if;


	gets turned into:

	.. code-block:: ada

	type Visited_Bitmap is array (1..N) of Boolean with Pack;
	Visited : aliased Visited_Bitmap := (others => False);
	-- Bitmap of visited blocks. N is the basic block count.
	[...]
	-- Basic block #I
	Visited(I) := True;
	if X then
	-- Basic block #J
	Visited(J) := True;
	Y := F (Z);
	CFR.Check (N, Visited'Access, CFG'Access);
	-- CFR is a hypothetical package whose Check procedure calls
	-- libgcc's __hardcfr_check, that traps if the Visited bitmap
	-- does not hold a valid path in CFG, the run-time
	-- representation of the control flow graph in the enclosing
	-- subprogram.
	return;
	end if;
	-- Basic block #K
	Visited(K) := True;


	Verification would also be performed before tail calls, if any
	front-ends marked them as mandatory or desirable, but none do.
	Regular calls are optimized into tail calls too late for this
	transformation to act on it.

	In order to avoid adding verification after potential tail calls,
	which would prevent tail-call optimization, we recognize returning
	calls, i.e., calls whose result, if any, is returned by the calling
	subprogram to its caller immediately after the call returns.
	Verification is performed before such calls, whether or not they are
	ultimately optimized to tail calls. This behavior is enabled by
	default whenever sibcall optimization is enabled (see
	:switch:`-foptimize-sibling-calls`); it may be disabled with
	:switch:`-fno-hardcfr-check-returning-calls`, or enabled with
	:switch:`-fhardcfr-check-returning-calls`, regardless of the
	optimization, but the lack of other optimizations may prevent calls
	from being recognized as returning calls:

	.. code-block:: ada

	-- CFR.Check here, with -fhardcfr-check-returning-calls.
	P (X);
	-- CFR.Check here, with -fno-hardcfr-check-returning-calls.
	return;

	or:

	.. code-block:: ada

	-- CFR.Check here, with -fhardcfr-check-returning-calls.
	R := F (X);
	-- CFR.Check here, with -fno-hardcfr-check-returning-calls.
	return R;


	Any subprogram from which an exception may escape, i.e., that may
	raise or propagate an exception that isn't handled internally, is
	conceptually enclosed by a cleanup handler that performs verification,
	unless this is disabled with :switch:`-fno-hardcfr-check-exceptions`.
	With this feature enabled, a subprogram body containing:

	.. code-block:: ada

	-- ...
	Y := F (X); -- May raise exceptions.
	-- ...
	raise E; -- Not handled internally.
	-- ...


	gets modified as follows:

	.. code-block:: ada

	begin
	-- ...
	Y := F (X); -- May raise exceptions.
	-- ...
	raise E; -- Not handled internally.
	-- ...
	exception
	when others =>
	CFR.Check (N, Visited'Access, CFG'Access);
	raise;
	end;


	Verification may also be performed before No_Return calls, whether
	only nothrow ones, with
	:switch:`-fhardcfr-check-noreturn-calls=nothrow`, or all of them, with
	:switch:`-fhardcfr-check-noreturn-calls=always`. The default is
	:switch:`-fhardcfr-check-noreturn-calls=never` for this feature, that
	disables checking before No_Return calls.

	When a No_Return call returns control to its caller through an
	exception, verification may have already been performed before the
	call, if :switch:`-fhardcfr-check-noreturn-calls=always` is in effect.
	The compiler arranges for already-checked No_Return calls without a
	preexisting handler to bypass the implicitly-added cleanup handler and
	thus the redundant check, but a local exception or cleanup handler, if
	present, will modify the set of visited blocks, and checking will take
	place again when the caller reaches the next verification point,
	whether it is a return or reraise statement after the exception is
	otherwise handled, or even another No_Return call.

	The instrumentation for hardening with control flow redundancy can be
	observed in dump files generated by the command-line option
	:switch:`-fdump-tree-hardcfr`.

	For more details on the control flow redundancy command-line options,
	see :title:`Using the GNU Compiler Collection (GCC)`. These options
	can be used with other programming languages supported by GCC.