sandbox/linux/seccomp-bpf/errorcode.h - bauxite - Git at Google

 // Copyright (c) 2012 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_SECCOMP_BPF_ERRORCODE_H__
 #define SANDBOX_LINUX_SECCOMP_BPF_ERRORCODE_H__

 #include "sandbox/linux/seccomp-bpf/trap.h"
 #include "sandbox/sandbox_export.h"

 namespace sandbox {
 namespace bpf_dsl {
 class PolicyCompiler;
 }

 // This class holds all the possible values that can be returned by a sandbox
 // policy.
 // We can either wrap a symbolic ErrorCode (i.e. ERR_XXX enum values), an
 // errno value (in the range 0..4095), a pointer to a TrapFnc callback
 // handling a SECCOMP_RET_TRAP trap, or a complex constraint.
 // All of the commonly used values are stored in the "err_" field. So, code
 // that is using the ErrorCode class typically operates on a single 32bit
 // field.
 //
 // TODO(mdempsky): Nuke from orbit. The only reason this class still
 // exists is for Verifier, which will eventually be replaced by a true
 // BPF symbolic evaluator and constraint solver.
 class SANDBOX_EXPORT ErrorCode {
  public:
   enum {
     // Allow this system call. The value of ERR_ALLOWED is pretty much
     // completely arbitrary. But we want to pick it so that is is unlikely
     // to be passed in accidentally, when the user intended to return an
     // "errno" (see below) value instead.
     ERR_ALLOWED = 0x04000000,

     // If the progress is being ptraced with PTRACE_O_TRACESECCOMP, then the
     // tracer will be notified of a PTRACE_EVENT_SECCOMP and allowed to change
     // or skip the system call.  The lower 16 bits of err will be available to
     // the tracer via PTRACE_GETEVENTMSG.
     ERR_TRACE   = 0x08000000,

     // Deny the system call with a particular "errno" value.
     // N.B.: It is also possible to return "0" here. That would normally
     //       indicate success, but it won't actually run the system call.
     //       This is very different from return ERR_ALLOWED.
     ERR_MIN_ERRNO = 0,
 #if defined(__mips__)
     // MIPS only supports errno up to 1133
     ERR_MAX_ERRNO = 1133,
 #else
     // TODO(markus): Android only supports errno up to 255
     // (crbug.com/181647).
     ERR_MAX_ERRNO = 4095,
 #endif
   };

   // While BPF filter programs always operate on 32bit quantities, the kernel
   // always sees system call arguments as 64bit values. This statement is true
   // no matter whether the host system is natively operating in 32bit or 64bit.
   // The BPF compiler hides the fact that BPF instructions cannot directly
   // access 64bit quantities. But policies are still advised to specify whether
   // a system call expects a 32bit or a 64bit quantity.
   enum ArgType {
     // When passed as an argument to SandboxBPF::Cond(), TP_32BIT requests that
     // the conditional test should operate on the 32bit part of the system call
     // argument.
     // On 64bit architectures, this verifies that user space did not pass
     // a 64bit value as an argument to the system call. If it did, that will be
     // interpreted as an attempt at breaking the sandbox and results in the
     // program getting terminated.
     // In other words, only perform a 32bit test, if you are sure this
     // particular system call would never legitimately take a 64bit
     // argument.
     // Implementation detail: TP_32BIT does two things. 1) it restricts the
     // conditional test to operating on the LSB only, and 2) it adds code to
     // the BPF filter program verifying that the MSB  the kernel received from
     // user space is either 0, or 0xFFFFFFFF; the latter is acceptable, iff bit
     // 31 was set in the system call argument. It deals with 32bit arguments
     // having been sign extended.
     TP_32BIT,

     // When passed as an argument to SandboxBPF::Cond(), TP_64BIT requests that
     // the conditional test should operate on the full 64bit argument. It is
     // generally harmless to perform a 64bit test on 32bit systems, as the
     // kernel will always see the top 32 bits of all arguments as zero'd out.
     // This approach has the desirable property that for tests of pointer
     // values, we can always use TP_64BIT no matter the host architecture.
     // But of course, that also means, it is possible to write conditional
     // policies that turn into no-ops on 32bit systems; this is by design.
     TP_64BIT,
   };

   // Deprecated.
   enum Operation {
     // Test whether the system call argument is equal to the operand.
     OP_EQUAL,

     // Tests a system call argument against a bit mask.
     // The "ALL_BITS" variant performs this test: "arg & mask == mask"
     // This implies that a mask of zero always results in a passing test.
     // The "ANY_BITS" variant performs this test: "arg & mask != 0"
     // This implies that a mask of zero always results in a failing test.
     OP_HAS_ALL_BITS,
     OP_HAS_ANY_BITS,
   };

   enum ErrorType {
     ET_INVALID,
     ET_SIMPLE,
     ET_TRAP,
     ET_COND,
   };

   // We allow the default constructor, as it makes the ErrorCode class
   // much easier to use. But if we ever encounter an invalid ErrorCode
   // when compiling a BPF filter, we deliberately generate an invalid
   // program that will get flagged both by our Verifier class and by
   // the Linux kernel.
   ErrorCode();
   explicit ErrorCode(int err);

   // For all practical purposes, ErrorCodes are treated as if they were
   // structs. The copy constructor and assignment operator are trivial and
   // we do not need to explicitly specify them.
   // Most notably, it is in fact perfectly OK to directly copy the passed_ and
   // failed_ field. They only ever get set by our private constructor, and the
   // callers handle life-cycle management for these objects.

   // Destructor
   ~ErrorCode() {}

   bool Equals(const ErrorCode& err) const;
   bool LessThan(const ErrorCode& err) const;

   uint32_t err() const { return err_; }
   ErrorType error_type() const { return error_type_; }

   bool safe() const { return safe_; }

   uint64_t mask() const { return mask_; }
   uint64_t value() const { return value_; }
   int argno() const { return argno_; }
   ArgType width() const { return width_; }
   const ErrorCode* passed() const { return passed_; }
   const ErrorCode* failed() const { return failed_; }

   struct LessThan {
     bool operator()(const ErrorCode& a, const ErrorCode& b) const {
       return a.LessThan(b);
     }
   };

  private:
   friend bpf_dsl::PolicyCompiler;
   friend class CodeGen;
   friend class SandboxBPF;
   friend class Trap;

   // If we are wrapping a callback, we must assign a unique id. This id is
   // how the kernel tells us which one of our different SECCOMP_RET_TRAP
   // cases has been triggered.
   ErrorCode(uint16_t trap_id, Trap::TrapFnc fnc, const void* aux, bool safe);

   // Some system calls require inspection of arguments. This constructor
   // allows us to specify additional constraints.
   ErrorCode(int argno,
             ArgType width,
             uint64_t mask,
             uint64_t value,
             const ErrorCode* passed,
             const ErrorCode* failed);

   ErrorType error_type_;

   union {
     // Fields needed for SECCOMP_RET_TRAP callbacks
     struct {
       Trap::TrapFnc fnc_;  // Callback function and arg, if trap was
       void* aux_;          //   triggered by the kernel's BPF filter.
       bool safe_;          // Keep sandbox active while calling fnc_()
     };

     // Fields needed when inspecting additional arguments.
     struct {
       uint64_t mask_;            // Mask that we are comparing under.
       uint64_t value_;           // Value that we are comparing with.
       int argno_;                // Syscall arg number that we are inspecting.
       ArgType width_;            // Whether we are looking at a 32/64bit value.
       const ErrorCode* passed_;  // Value to be returned if comparison passed,
       const ErrorCode* failed_;  //   or if it failed.
     };
   };

   // 32bit field used for all possible types of ErrorCode values. This is
   // the value that uniquely identifies any ErrorCode and it (typically) can
   // be emitted directly into a BPF filter program.
   uint32_t err_;
 };

 }  // namespace sandbox

 #endif  // SANDBOX_LINUX_SECCOMP_BPF_ERRORCODE_H__
	// Copyright (c) 2012 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_SECCOMP_BPF_ERRORCODE_H__
	#define SANDBOX_LINUX_SECCOMP_BPF_ERRORCODE_H__

	#include "sandbox/linux/seccomp-bpf/trap.h"
	#include "sandbox/sandbox_export.h"

	namespace sandbox {
	namespace bpf_dsl {
	class PolicyCompiler;
	}

	// This class holds all the possible values that can be returned by a sandbox
	// policy.
	// We can either wrap a symbolic ErrorCode (i.e. ERR_XXX enum values), an
	// errno value (in the range 0..4095), a pointer to a TrapFnc callback
	// handling a SECCOMP_RET_TRAP trap, or a complex constraint.
	// All of the commonly used values are stored in the "err_" field. So, code
	// that is using the ErrorCode class typically operates on a single 32bit
	// field.
	//
	// TODO(mdempsky): Nuke from orbit. The only reason this class still
	// exists is for Verifier, which will eventually be replaced by a true
	// BPF symbolic evaluator and constraint solver.
	class SANDBOX_EXPORT ErrorCode {
	public:
	enum {
	// Allow this system call. The value of ERR_ALLOWED is pretty much
	// completely arbitrary. But we want to pick it so that is is unlikely
	// to be passed in accidentally, when the user intended to return an
	// "errno" (see below) value instead.
	ERR_ALLOWED = 0x04000000,

	// If the progress is being ptraced with PTRACE_O_TRACESECCOMP, then the
	// tracer will be notified of a PTRACE_EVENT_SECCOMP and allowed to change
	// or skip the system call. The lower 16 bits of err will be available to
	// the tracer via PTRACE_GETEVENTMSG.
	ERR_TRACE = 0x08000000,

	// Deny the system call with a particular "errno" value.
	// N.B.: It is also possible to return "0" here. That would normally
	// indicate success, but it won't actually run the system call.
	// This is very different from return ERR_ALLOWED.
	ERR_MIN_ERRNO = 0,
	#if defined(__mips__)
	// MIPS only supports errno up to 1133
	ERR_MAX_ERRNO = 1133,
	#else
	// TODO(markus): Android only supports errno up to 255
	// (crbug.com/181647).
	ERR_MAX_ERRNO = 4095,
	#endif
	};

	// While BPF filter programs always operate on 32bit quantities, the kernel
	// always sees system call arguments as 64bit values. This statement is true
	// no matter whether the host system is natively operating in 32bit or 64bit.
	// The BPF compiler hides the fact that BPF instructions cannot directly
	// access 64bit quantities. But policies are still advised to specify whether
	// a system call expects a 32bit or a 64bit quantity.
	enum ArgType {
	// When passed as an argument to SandboxBPF::Cond(), TP_32BIT requests that
	// the conditional test should operate on the 32bit part of the system call
	// argument.
	// On 64bit architectures, this verifies that user space did not pass
	// a 64bit value as an argument to the system call. If it did, that will be
	// interpreted as an attempt at breaking the sandbox and results in the
	// program getting terminated.
	// In other words, only perform a 32bit test, if you are sure this
	// particular system call would never legitimately take a 64bit
	// argument.
	// Implementation detail: TP_32BIT does two things. 1) it restricts the
	// conditional test to operating on the LSB only, and 2) it adds code to
	// the BPF filter program verifying that the MSB the kernel received from
	// user space is either 0, or 0xFFFFFFFF; the latter is acceptable, iff bit
	// 31 was set in the system call argument. It deals with 32bit arguments
	// having been sign extended.
	TP_32BIT,

	// When passed as an argument to SandboxBPF::Cond(), TP_64BIT requests that
	// the conditional test should operate on the full 64bit argument. It is
	// generally harmless to perform a 64bit test on 32bit systems, as the
	// kernel will always see the top 32 bits of all arguments as zero'd out.
	// This approach has the desirable property that for tests of pointer
	// values, we can always use TP_64BIT no matter the host architecture.
	// But of course, that also means, it is possible to write conditional
	// policies that turn into no-ops on 32bit systems; this is by design.
	TP_64BIT,
	};

	// Deprecated.
	enum Operation {
	// Test whether the system call argument is equal to the operand.
	OP_EQUAL,

	// Tests a system call argument against a bit mask.
	// The "ALL_BITS" variant performs this test: "arg & mask == mask"
	// This implies that a mask of zero always results in a passing test.
	// The "ANY_BITS" variant performs this test: "arg & mask != 0"
	// This implies that a mask of zero always results in a failing test.
	OP_HAS_ALL_BITS,
	OP_HAS_ANY_BITS,
	};

	enum ErrorType {
	ET_INVALID,
	ET_SIMPLE,
	ET_TRAP,
	ET_COND,
	};

	// We allow the default constructor, as it makes the ErrorCode class
	// much easier to use. But if we ever encounter an invalid ErrorCode
	// when compiling a BPF filter, we deliberately generate an invalid
	// program that will get flagged both by our Verifier class and by
	// the Linux kernel.
	ErrorCode();
	explicit ErrorCode(int err);

	// For all practical purposes, ErrorCodes are treated as if they were
	// structs. The copy constructor and assignment operator are trivial and
	// we do not need to explicitly specify them.
	// Most notably, it is in fact perfectly OK to directly copy the passed_ and
	// failed_ field. They only ever get set by our private constructor, and the
	// callers handle life-cycle management for these objects.

	// Destructor
	~ErrorCode() {}

	bool Equals(const ErrorCode& err) const;
	bool LessThan(const ErrorCode& err) const;

	uint32_t err() const { return err_; }
	ErrorType error_type() const { return error_type_; }

	bool safe() const { return safe_; }

	uint64_t mask() const { return mask_; }
	uint64_t value() const { return value_; }
	int argno() const { return argno_; }
	ArgType width() const { return width_; }
	const ErrorCode* passed() const { return passed_; }
	const ErrorCode* failed() const { return failed_; }

	struct LessThan {
	bool operator()(const ErrorCode& a, const ErrorCode& b) const {
	return a.LessThan(b);
	}
	};

	private:
	friend bpf_dsl::PolicyCompiler;
	friend class CodeGen;
	friend class SandboxBPF;
	friend class Trap;

	// If we are wrapping a callback, we must assign a unique id. This id is
	// how the kernel tells us which one of our different SECCOMP_RET_TRAP
	// cases has been triggered.
	ErrorCode(uint16_t trap_id, Trap::TrapFnc fnc, const void* aux, bool safe);

	// Some system calls require inspection of arguments. This constructor
	// allows us to specify additional constraints.
	ErrorCode(int argno,
	ArgType width,
	uint64_t mask,
	uint64_t value,
	const ErrorCode* passed,
	const ErrorCode* failed);

	ErrorType error_type_;

	union {
	// Fields needed for SECCOMP_RET_TRAP callbacks
	struct {
	Trap::TrapFnc fnc_; // Callback function and arg, if trap was
	void* aux_; // triggered by the kernel's BPF filter.
	bool safe_; // Keep sandbox active while calling fnc_()
	};

	// Fields needed when inspecting additional arguments.
	struct {
	uint64_t mask_; // Mask that we are comparing under.
	uint64_t value_; // Value that we are comparing with.
	int argno_; // Syscall arg number that we are inspecting.
	ArgType width_; // Whether we are looking at a 32/64bit value.
	const ErrorCode* passed_; // Value to be returned if comparison passed,
	const ErrorCode* failed_; // or if it failed.
	};
	};

	// 32bit field used for all possible types of ErrorCode values. This is
	// the value that uniquely identifies any ErrorCode and it (typically) can
	// be emitted directly into a BPF filter program.
	uint32_t err_;
	};

	} // namespace sandbox

	#endif // SANDBOX_LINUX_SECCOMP_BPF_ERRORCODE_H__