sandbox/linux/bpf_dsl/bpf_dsl.h - bauxite - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_
 #define SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_

 #include <stdint.h>

 #include <utility>
 #include <vector>

 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "sandbox/linux/bpf_dsl/bpf_dsl_forward.h"
 #include "sandbox/linux/bpf_dsl/cons.h"
 #include "sandbox/linux/bpf_dsl/trap_registry.h"
 #include "sandbox/sandbox_export.h"

 // The sandbox::bpf_dsl namespace provides a domain-specific language
 // to make writing BPF policies more expressive.  In general, the
 // object types all have value semantics (i.e., they can be copied
 // around, returned from or passed to function calls, etc. without any
 // surprising side effects), though not all support assignment.
 //
 // An idiomatic and demonstrative (albeit silly) example of this API
 // would be:
 //
 //      #include "sandbox/linux/bpf_dsl/bpf_dsl.h"
 //
 //      using namespace sandbox::bpf_dsl;
 //
 //      class SillyPolicy : public Policy {
 //       public:
 //        SillyPolicy() {}
 //        ~SillyPolicy() override {}
 //        ResultExpr EvaluateSyscall(int sysno) const override {
 //          if (sysno == __NR_fcntl) {
 //            Arg<int> fd(0), cmd(1);
 //            Arg<unsigned long> flags(2);
 //            const uint64_t kGoodFlags = O_ACCMODE | O_NONBLOCK;
 //            return If(fd == 0 && cmd == F_SETFL && (flags & ~kGoodFlags) == 0,
 //                      Allow())
 //                .ElseIf(cmd == F_DUPFD || cmd == F_DUPFD_CLOEXEC,
 //                        Error(EMFILE))
 //                .Else(Trap(SetFlagHandler, NULL));
 //          } else {
 //            return Allow();
 //          }
 //        }
 //
 //       private:
 //        DISALLOW_COPY_AND_ASSIGN(SillyPolicy);
 //      };
 //
 // More generally, the DSL currently supports the following grammar:
 //
 //   result = Allow() | Error(errno) | Kill(msg) | Trace(aux)
 //          | Trap(trap_func, aux) | UnsafeTrap(trap_func, aux)
 //          | If(bool, result)[.ElseIf(bool, result)].Else(result)
 //          | Switch(arg)[.Case(val, result)].Default(result)
 //   bool   = BoolConst(boolean) | !bool | bool && bool | bool || bool
 //          | arg == val | arg != val
 //   arg    = Arg<T>(num) | arg & mask
 //
 // The semantics of each function and operator are intended to be
 // intuitive, but are described in more detail below.
 //
 // (Credit to Sean Parent's "Inheritance is the Base Class of Evil"
 // talk at Going Native 2013 for promoting value semantics via shared
 // pointers to immutable state.)

 namespace sandbox {
 namespace bpf_dsl {

 // ResultExpr is an opaque reference to an immutable result expression tree.
 typedef scoped_refptr<const internal::ResultExprImpl> ResultExpr;

 // BoolExpr is an opaque reference to an immutable boolean expression tree.
 typedef scoped_refptr<const internal::BoolExprImpl> BoolExpr;

 // Allow specifies a result that the system call should be allowed to
 // execute normally.
 SANDBOX_EXPORT ResultExpr Allow();

 // Error specifies a result that the system call should fail with
 // error number |err|.  As a special case, Error(0) will result in the
 // system call appearing to have succeeded, but without having any
 // side effects.
 SANDBOX_EXPORT ResultExpr Error(int err);

 // Kill specifies a result to kill the program and print an error message.
 SANDBOX_EXPORT ResultExpr Kill(const char* msg);

 // Trace specifies a result to notify a tracing process via the
 // PTRACE_EVENT_SECCOMP event and allow it to change or skip the system call.
 // The value of |aux| will be available to the tracer via PTRACE_GETEVENTMSG.
 SANDBOX_EXPORT ResultExpr Trace(uint16_t aux);

 // Trap specifies a result that the system call should be handled by
 // trapping back into userspace and invoking |trap_func|, passing
 // |aux| as the second parameter.
 SANDBOX_EXPORT ResultExpr
     Trap(TrapRegistry::TrapFnc trap_func, const void* aux);

 // UnsafeTrap is like Trap, except the policy is marked as "unsafe"
 // and allowed to use SandboxSyscall to invoke any system call.
 //
 // NOTE: This feature, by definition, disables all security features of
 //   the sandbox. It should never be used in production, but it can be
 //   very useful to diagnose code that is incompatible with the sandbox.
 //   If even a single system call returns "UnsafeTrap", the security of
 //   entire sandbox should be considered compromised.
 SANDBOX_EXPORT ResultExpr
     UnsafeTrap(TrapRegistry::TrapFnc trap_func, const void* aux);

 // BoolConst converts a bool value into a BoolExpr.
 SANDBOX_EXPORT BoolExpr BoolConst(bool value);

 // Various ways to combine boolean expressions into more complex expressions.
 // They follow standard boolean algebra laws.
 SANDBOX_EXPORT BoolExpr operator!(const BoolExpr& cond);
 SANDBOX_EXPORT BoolExpr operator&&(const BoolExpr& lhs, const BoolExpr& rhs);
 SANDBOX_EXPORT BoolExpr operator||(const BoolExpr& lhs, const BoolExpr& rhs);

 template <typename T>
 class SANDBOX_EXPORT Arg {
  public:
   // Initializes the Arg to represent the |num|th system call
   // argument (indexed from 0), which is of type |T|.
   explicit Arg(int num);

   Arg(const Arg& arg) : num_(arg.num_), mask_(arg.mask_) {}

   // Returns an Arg representing the current argument, but after
   // bitwise-and'ing it with |rhs|.
   friend Arg operator&(const Arg& lhs, uint64_t rhs) {
     return Arg(lhs.num_, lhs.mask_ & rhs);
   }

   // Returns a boolean expression comparing whether the system call argument
   // (after applying any bitmasks, if appropriate) equals |rhs|.
   friend BoolExpr operator==(const Arg& lhs, T rhs) { return lhs.EqualTo(rhs); }

   // Returns a boolean expression comparing whether the system call argument
   // (after applying any bitmasks, if appropriate) does not equal |rhs|.
   friend BoolExpr operator!=(const Arg& lhs, T rhs) { return !(lhs == rhs); }

  private:
   Arg(int num, uint64_t mask) : num_(num), mask_(mask) {}

   BoolExpr EqualTo(T val) const;

   int num_;
   uint64_t mask_;

   DISALLOW_ASSIGN(Arg);
 };

 // If begins a conditional result expression predicated on the
 // specified boolean expression.
 SANDBOX_EXPORT Elser If(const BoolExpr& cond, const ResultExpr& then_result);

 class SANDBOX_EXPORT Elser {
  public:
   Elser(const Elser& elser);
   ~Elser();

   // ElseIf extends the conditional result expression with another
   // "if then" clause, predicated on the specified boolean expression.
   Elser ElseIf(const BoolExpr& cond, const ResultExpr& then_result) const;

   // Else terminates a conditional result expression using |else_result| as
   // the default fallback result expression.
   ResultExpr Else(const ResultExpr& else_result) const;

  private:
   typedef std::pair<BoolExpr, ResultExpr> Clause;

   explicit Elser(cons::List<Clause> clause_list);

   cons::List<Clause> clause_list_;

   friend Elser If(const BoolExpr&, const ResultExpr&);
   template <typename T>
   friend Caser<T> Switch(const Arg<T>&);
   DISALLOW_ASSIGN(Elser);
 };

 // Switch begins a switch expression dispatched according to the
 // specified argument value.
 template <typename T>
 SANDBOX_EXPORT Caser<T> Switch(const Arg<T>& arg);

 template <typename T>
 class SANDBOX_EXPORT Caser {
  public:
   Caser(const Caser<T>& caser) : arg_(caser.arg_), elser_(caser.elser_) {}
   ~Caser() {}

   // Case adds a single-value "case" clause to the switch.
   Caser<T> Case(T value, ResultExpr result) const;

   // Cases adds a multiple-value "case" clause to the switch.
   // See also the SANDBOX_BPF_DSL_CASES macro below for a more idiomatic way
   // of using this function.
   Caser<T> Cases(const std::vector<T>& values, ResultExpr result) const;

   // Terminate the switch with a "default" clause.
   ResultExpr Default(ResultExpr result) const;

  private:
   Caser(const Arg<T>& arg, Elser elser) : arg_(arg), elser_(elser) {}

   Arg<T> arg_;
   Elser elser_;

   template <typename U>
   friend Caser<U> Switch(const Arg<U>&);
   DISALLOW_ASSIGN(Caser);
 };

 // Recommended usage is to put
 //    #define CASES SANDBOX_BPF_DSL_CASES
 // near the top of the .cc file (e.g., nearby any "using" statements), then
 // use like:
 //    Switch(arg).CASES((3, 5, 7), result)...;
 #define SANDBOX_BPF_DSL_CASES(values, result) \
   Cases(SANDBOX_BPF_DSL_CASES_HELPER values, result)

 // Helper macro to construct a std::vector from an initializer list.
 // TODO(mdempsky): Convert to use C++11 initializer lists instead.
 #define SANDBOX_BPF_DSL_CASES_HELPER(value, ...)                           \
   ({                                                                       \
     const __typeof__(value) bpf_dsl_cases_values[] = {value, __VA_ARGS__}; \
     std::vector<__typeof__(value)>(                                        \
         bpf_dsl_cases_values,                                              \
         bpf_dsl_cases_values + arraysize(bpf_dsl_cases_values));           \
   })

 // =====================================================================
 // Official API ends here.
 // =====================================================================

 namespace internal {

 // Make argument-dependent lookup work.  This is necessary because although
 // BoolExpr is defined in bpf_dsl, since it's merely a typedef for
 // scoped_refptr<const internal::BoolExplImpl>, argument-dependent lookup only
 // searches the "internal" nested namespace.
 using bpf_dsl::operator!;
 using bpf_dsl::operator||;
 using bpf_dsl::operator&&;

 // Returns a boolean expression that represents whether system call
 // argument |num| of size |size| is equal to |val|, when masked
 // according to |mask|.  Users should use the Arg template class below
 // instead of using this API directly.
 SANDBOX_EXPORT BoolExpr
     ArgEq(int num, size_t size, uint64_t mask, uint64_t val);

 // Returns the default mask for a system call argument of the specified size.
 SANDBOX_EXPORT uint64_t DefaultMask(size_t size);

 }  // namespace internal

 template <typename T>
 Arg<T>::Arg(int num)
     : num_(num), mask_(internal::DefaultMask(sizeof(T))) {
 }

 // Definition requires ArgEq to have been declared.  Moved out-of-line
 // to minimize how much internal clutter users have to ignore while
 // reading the header documentation.
 //
 // Additionally, we use this helper member function to avoid linker errors
 // caused by defining operator== out-of-line.  For a more detailed explanation,
 // see http://www.parashift.com/c++-faq-lite/template-friends.html.
 template <typename T>
 BoolExpr Arg<T>::EqualTo(T val) const {
   return internal::ArgEq(num_, sizeof(T), mask_, static_cast<uint64_t>(val));
 }

 template <typename T>
 SANDBOX_EXPORT Caser<T> Switch(const Arg<T>& arg) {
   return Caser<T>(arg, Elser(nullptr));
 }

 template <typename T>
 Caser<T> Caser<T>::Case(T value, ResultExpr result) const {
   return SANDBOX_BPF_DSL_CASES((value), result);
 }

 template <typename T>
 Caser<T> Caser<T>::Cases(const std::vector<T>& values,
                          ResultExpr result) const {
   // Theoretically we could evaluate arg_ just once and emit a more efficient
   // dispatch table, but for now we simply translate into an equivalent
   // If/ElseIf/Else chain.

   typedef typename std::vector<T>::const_iterator Iter;
   BoolExpr test = BoolConst(false);
   for (Iter i = values.begin(), end = values.end(); i != end; ++i) {
     test = test || (arg_ == *i);
   }
   return Caser<T>(arg_, elser_.ElseIf(test, result));
 }

 template <typename T>
 ResultExpr Caser<T>::Default(ResultExpr result) const {
   return elser_.Else(result);
 }

 }  // namespace bpf_dsl
 }  // namespace sandbox

 #endif  // SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_
	#define SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_

	#include <stdint.h>

	#include <utility>
	#include <vector>

	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "sandbox/linux/bpf_dsl/bpf_dsl_forward.h"
	#include "sandbox/linux/bpf_dsl/cons.h"
	#include "sandbox/linux/bpf_dsl/trap_registry.h"
	#include "sandbox/sandbox_export.h"

	// The sandbox::bpf_dsl namespace provides a domain-specific language
	// to make writing BPF policies more expressive. In general, the
	// object types all have value semantics (i.e., they can be copied
	// around, returned from or passed to function calls, etc. without any
	// surprising side effects), though not all support assignment.
	//
	// An idiomatic and demonstrative (albeit silly) example of this API
	// would be:
	//
	// #include "sandbox/linux/bpf_dsl/bpf_dsl.h"
	//
	// using namespace sandbox::bpf_dsl;
	//
	// class SillyPolicy : public Policy {
	// public:
	// SillyPolicy() {}
	// ~SillyPolicy() override {}
	// ResultExpr EvaluateSyscall(int sysno) const override {
	// if (sysno == __NR_fcntl) {
	// Arg<int> fd(0), cmd(1);
	// Arg<unsigned long> flags(2);
	// const uint64_t kGoodFlags = O_ACCMODE \| O_NONBLOCK;
	// return If(fd == 0 && cmd == F_SETFL && (flags & ~kGoodFlags) == 0,
	// Allow())
	// .ElseIf(cmd == F_DUPFD \|\| cmd == F_DUPFD_CLOEXEC,
	// Error(EMFILE))
	// .Else(Trap(SetFlagHandler, NULL));
	// } else {
	// return Allow();
	// }
	// }
	//
	// private:
	// DISALLOW_COPY_AND_ASSIGN(SillyPolicy);
	// };
	//
	// More generally, the DSL currently supports the following grammar:
	//
	// result = Allow() \| Error(errno) \| Kill(msg) \| Trace(aux)
	// \| Trap(trap_func, aux) \| UnsafeTrap(trap_func, aux)
	// \| If(bool, result)[.ElseIf(bool, result)].Else(result)
	// \| Switch(arg)[.Case(val, result)].Default(result)
	// bool = BoolConst(boolean) \| !bool \| bool && bool \| bool \|\| bool
	// \| arg == val \| arg != val
	// arg = Arg<T>(num) \| arg & mask
	//
	// The semantics of each function and operator are intended to be
	// intuitive, but are described in more detail below.
	//
	// (Credit to Sean Parent's "Inheritance is the Base Class of Evil"
	// talk at Going Native 2013 for promoting value semantics via shared
	// pointers to immutable state.)

	namespace sandbox {
	namespace bpf_dsl {

	// ResultExpr is an opaque reference to an immutable result expression tree.
	typedef scoped_refptr<const internal::ResultExprImpl> ResultExpr;

	// BoolExpr is an opaque reference to an immutable boolean expression tree.
	typedef scoped_refptr<const internal::BoolExprImpl> BoolExpr;

	// Allow specifies a result that the system call should be allowed to
	// execute normally.
	SANDBOX_EXPORT ResultExpr Allow();

	// Error specifies a result that the system call should fail with
	// error number \|err\|. As a special case, Error(0) will result in the
	// system call appearing to have succeeded, but without having any
	// side effects.
	SANDBOX_EXPORT ResultExpr Error(int err);

	// Kill specifies a result to kill the program and print an error message.
	SANDBOX_EXPORT ResultExpr Kill(const char* msg);

	// Trace specifies a result to notify a tracing process via the
	// PTRACE_EVENT_SECCOMP event and allow it to change or skip the system call.
	// The value of \|aux\| will be available to the tracer via PTRACE_GETEVENTMSG.
	SANDBOX_EXPORT ResultExpr Trace(uint16_t aux);

	// Trap specifies a result that the system call should be handled by
	// trapping back into userspace and invoking \|trap_func\|, passing
	// \|aux\| as the second parameter.
	SANDBOX_EXPORT ResultExpr
	Trap(TrapRegistry::TrapFnc trap_func, const void* aux);

	// UnsafeTrap is like Trap, except the policy is marked as "unsafe"
	// and allowed to use SandboxSyscall to invoke any system call.
	//
	// NOTE: This feature, by definition, disables all security features of
	// the sandbox. It should never be used in production, but it can be
	// very useful to diagnose code that is incompatible with the sandbox.
	// If even a single system call returns "UnsafeTrap", the security of
	// entire sandbox should be considered compromised.
	SANDBOX_EXPORT ResultExpr
	UnsafeTrap(TrapRegistry::TrapFnc trap_func, const void* aux);

	// BoolConst converts a bool value into a BoolExpr.
	SANDBOX_EXPORT BoolExpr BoolConst(bool value);

	// Various ways to combine boolean expressions into more complex expressions.
	// They follow standard boolean algebra laws.
	SANDBOX_EXPORT BoolExpr operator!(const BoolExpr& cond);
	SANDBOX_EXPORT BoolExpr operator&&(const BoolExpr& lhs, const BoolExpr& rhs);
	SANDBOX_EXPORT BoolExpr operator\|\|(const BoolExpr& lhs, const BoolExpr& rhs);

	template <typename T>
	class SANDBOX_EXPORT Arg {
	public:
	// Initializes the Arg to represent the \|num\|th system call
	// argument (indexed from 0), which is of type \|T\|.
	explicit Arg(int num);

	Arg(const Arg& arg) : num_(arg.num_), mask_(arg.mask_) {}

	// Returns an Arg representing the current argument, but after
	// bitwise-and'ing it with \|rhs\|.
	friend Arg operator&(const Arg& lhs, uint64_t rhs) {
	return Arg(lhs.num_, lhs.mask_ & rhs);
	}

	// Returns a boolean expression comparing whether the system call argument
	// (after applying any bitmasks, if appropriate) equals \|rhs\|.
	friend BoolExpr operator==(const Arg& lhs, T rhs) { return lhs.EqualTo(rhs); }

	// Returns a boolean expression comparing whether the system call argument
	// (after applying any bitmasks, if appropriate) does not equal \|rhs\|.
	friend BoolExpr operator!=(const Arg& lhs, T rhs) { return !(lhs == rhs); }

	private:
	Arg(int num, uint64_t mask) : num_(num), mask_(mask) {}

	BoolExpr EqualTo(T val) const;

	int num_;
	uint64_t mask_;

	DISALLOW_ASSIGN(Arg);
	};

	// If begins a conditional result expression predicated on the
	// specified boolean expression.
	SANDBOX_EXPORT Elser If(const BoolExpr& cond, const ResultExpr& then_result);

	class SANDBOX_EXPORT Elser {
	public:
	Elser(const Elser& elser);
	~Elser();

	// ElseIf extends the conditional result expression with another
	// "if then" clause, predicated on the specified boolean expression.
	Elser ElseIf(const BoolExpr& cond, const ResultExpr& then_result) const;

	// Else terminates a conditional result expression using \|else_result\| as
	// the default fallback result expression.
	ResultExpr Else(const ResultExpr& else_result) const;

	private:
	typedef std::pair<BoolExpr, ResultExpr> Clause;

	explicit Elser(cons::List<Clause> clause_list);

	cons::List<Clause> clause_list_;

	friend Elser If(const BoolExpr&, const ResultExpr&);
	template <typename T>
	friend Caser<T> Switch(const Arg<T>&);
	DISALLOW_ASSIGN(Elser);
	};

	// Switch begins a switch expression dispatched according to the
	// specified argument value.
	template <typename T>
	SANDBOX_EXPORT Caser<T> Switch(const Arg<T>& arg);

	template <typename T>
	class SANDBOX_EXPORT Caser {
	public:
	Caser(const Caser<T>& caser) : arg_(caser.arg_), elser_(caser.elser_) {}
	~Caser() {}

	// Case adds a single-value "case" clause to the switch.
	Caser<T> Case(T value, ResultExpr result) const;

	// Cases adds a multiple-value "case" clause to the switch.
	// See also the SANDBOX_BPF_DSL_CASES macro below for a more idiomatic way
	// of using this function.
	Caser<T> Cases(const std::vector<T>& values, ResultExpr result) const;

	// Terminate the switch with a "default" clause.
	ResultExpr Default(ResultExpr result) const;

	private:
	Caser(const Arg<T>& arg, Elser elser) : arg_(arg), elser_(elser) {}

	Arg<T> arg_;
	Elser elser_;

	template <typename U>
	friend Caser<U> Switch(const Arg<U>&);
	DISALLOW_ASSIGN(Caser);
	};

	// Recommended usage is to put
	// #define CASES SANDBOX_BPF_DSL_CASES
	// near the top of the .cc file (e.g., nearby any "using" statements), then
	// use like:
	// Switch(arg).CASES((3, 5, 7), result)...;
	#define SANDBOX_BPF_DSL_CASES(values, result) \
	Cases(SANDBOX_BPF_DSL_CASES_HELPER values, result)

	// Helper macro to construct a std::vector from an initializer list.
	// TODO(mdempsky): Convert to use C++11 initializer lists instead.
	#define SANDBOX_BPF_DSL_CASES_HELPER(value, ...) \
	({ \
	const __typeof__(value) bpf_dsl_cases_values[] = {value, __VA_ARGS__}; \
	std::vector<__typeof__(value)>( \
	bpf_dsl_cases_values, \
	bpf_dsl_cases_values + arraysize(bpf_dsl_cases_values)); \
	})

	// =====================================================================
	// Official API ends here.
	// =====================================================================

	namespace internal {

	// Make argument-dependent lookup work. This is necessary because although
	// BoolExpr is defined in bpf_dsl, since it's merely a typedef for
	// scoped_refptr<const internal::BoolExplImpl>, argument-dependent lookup only
	// searches the "internal" nested namespace.
	using bpf_dsl::operator!;
	using bpf_dsl::operator\|\|;
	using bpf_dsl::operator&&;

	// Returns a boolean expression that represents whether system call
	// argument \|num\| of size \|size\| is equal to \|val\|, when masked
	// according to \|mask\|. Users should use the Arg template class below
	// instead of using this API directly.
	SANDBOX_EXPORT BoolExpr
	ArgEq(int num, size_t size, uint64_t mask, uint64_t val);

	// Returns the default mask for a system call argument of the specified size.
	SANDBOX_EXPORT uint64_t DefaultMask(size_t size);

	} // namespace internal

	template <typename T>
	Arg<T>::Arg(int num)
	: num_(num), mask_(internal::DefaultMask(sizeof(T))) {
	}

	// Definition requires ArgEq to have been declared. Moved out-of-line
	// to minimize how much internal clutter users have to ignore while
	// reading the header documentation.
	//
	// Additionally, we use this helper member function to avoid linker errors
	// caused by defining operator== out-of-line. For a more detailed explanation,
	// see http://www.parashift.com/c++-faq-lite/template-friends.html.
	template <typename T>
	BoolExpr Arg<T>::EqualTo(T val) const {
	return internal::ArgEq(num_, sizeof(T), mask_, static_cast<uint64_t>(val));
	}

	template <typename T>
	SANDBOX_EXPORT Caser<T> Switch(const Arg<T>& arg) {
	return Caser<T>(arg, Elser(nullptr));
	}

	template <typename T>
	Caser<T> Caser<T>::Case(T value, ResultExpr result) const {
	return SANDBOX_BPF_DSL_CASES((value), result);
	}

	template <typename T>
	Caser<T> Caser<T>::Cases(const std::vector<T>& values,
	ResultExpr result) const {
	// Theoretically we could evaluate arg_ just once and emit a more efficient
	// dispatch table, but for now we simply translate into an equivalent
	// If/ElseIf/Else chain.

	typedef typename std::vector<T>::const_iterator Iter;
	BoolExpr test = BoolConst(false);
	for (Iter i = values.begin(), end = values.end(); i != end; ++i) {
	test = test \|\| (arg_ == *i);
	}
	return Caser<T>(arg_, elser_.ElseIf(test, result));
	}

	template <typename T>
	ResultExpr Caser<T>::Default(ResultExpr result) const {
	return elser_.Else(result);
	}

	} // namespace bpf_dsl
	} // namespace sandbox

	#endif // SANDBOX_LINUX_BPF_DSL_BPF_DSL_H_