platform

type AddressSpace interface {
	// MapFile creates a shared mapping of offsets fr from f at address addr.
	// Any existing overlapping mappings are silently replaced.
	//
	// If precommit is true, the platform should eagerly commit resources (e.g.
	// physical memory) to the mapping. The precommit flag is advisory and
	// implementations may choose to ignore it.
	//
	// Preconditions:
	//	* addr and fr must be page-aligned.
	//	* fr.Length() > 0.
	//	* at.Any() == true.
	//	* At least one reference must be held on all pages in fr, and must
	//		continue to be held as long as pages are mapped.
	MapFile(addr hostarch.Addr, f memmap.File, fr memmap.FileRange, at hostarch.AccessType, precommit bool) error

	// Unmap unmaps the given range.
	//
	// Preconditions:
	//	* addr is page-aligned.
	//	* length > 0.
	Unmap(addr hostarch.Addr, length uint64)

	// Release releases this address space. After releasing, a new AddressSpace
	// must be acquired via platform.NewAddressSpace().
	Release()

	// PreFork() is called before creating a copy of AddressSpace. This
	// guarantees that this address space will be in a consistent state.
	PreFork()

	// PostFork() is called after creating a copy of AddressSpace.
	PostFork()

	// AddressSpaceIO methods are supported iff the associated platform's
	// Platform.SupportsAddressSpaceIO() == true. AddressSpaces for which this
	// does not hold may panic if AddressSpaceIO methods are invoked.
	AddressSpaceIO
}

type AddressSpaceIO interface {
	// CopyOut copies len(src) bytes from src to the memory mapped at addr. It
	// returns the number of bytes copied. If the number of bytes copied is <
	// len(src), it returns a non-nil error explaining why.
	CopyOut(addr hostarch.Addr, src []byte) (int, error)

	// CopyIn copies len(dst) bytes from the memory mapped at addr to dst.
	// It returns the number of bytes copied. If the number of bytes copied is
	// < len(dst), it returns a non-nil error explaining why.
	CopyIn(addr hostarch.Addr, dst []byte) (int, error)

	// ZeroOut sets toZero bytes to 0, starting at addr. It returns the number
	// of bytes zeroed. If the number of bytes zeroed is < toZero, it returns a
	// non-nil error explaining why.
	ZeroOut(addr hostarch.Addr, toZero uintptr) (uintptr, error)

	// SwapUint32 atomically sets the uint32 value at addr to new and returns
	// the previous value.
	//
	// Preconditions: addr must be aligned to a 4-byte boundary.
	SwapUint32(addr hostarch.Addr, new uint32) (uint32, error)

	// CompareAndSwapUint32 atomically compares the uint32 value at addr to
	// old; if they are equal, the value in memory is replaced by new. In
	// either case, the previous value stored in memory is returned.
	//
	// Preconditions: addr must be aligned to a 4-byte boundary.
	CompareAndSwapUint32(addr hostarch.Addr, old, new uint32) (uint32, error)

	// LoadUint32 atomically loads the uint32 value at addr and returns it.
	//
	// Preconditions: addr must be aligned to a 4-byte boundary.
	LoadUint32(addr hostarch.Addr) (uint32, error)
}

type Constructor interface {
	// New returns a new platform instance.
	//
	// Arguments:
	//
	//	* deviceFile - the device file (e.g. /dev/kvm for the KVM platform).
	New(deviceFile *fd.FD) (Platform, error)

	// OpenDevice opens the path to the device used by the platform.
	// Passing in an empty string will use the default path for the device,
	// e.g. "/dev/kvm" for the KVM platform.
	OpenDevice(devicePath string) (*fd.FD, error)

	// Requirements returns platform specific requirements.
	Requirements() Requirements

	// PrecompiledSeccompInfo returns a list of `SeccompInfo`s that is
	// useful to precompile into the Sentry.
	PrecompiledSeccompInfo() []SeccompInfo
}

type Context interface {
	// Switch resumes execution of the thread specified by the arch.Context64
	// in the provided address space. This call will block while the thread
	// is executing.
	//
	// If cpu is non-negative, and it is not the number of the CPU that the
	// thread executes on, Context should return ErrContextCPUPreempted. cpu
	// can only be non-negative if Platform.DetectsCPUPreemption() is true;
	// Contexts from Platforms for which this does not hold may ignore cpu, or
	// panic if cpu is non-negative.
	//
	// Switch may return one of the following special errors:
	//
	//	- nil: The Context invoked a system call.
	//
	//	- ErrContextSignal: The Context was interrupted by a signal. The
	//		returned *linux.SignalInfo contains information about the signal. If
	//		linux.SignalInfo.Signo == SIGSEGV, the returned hostarch.AccessType
	//		contains the access type of the triggering fault. The caller owns
	//		the returned SignalInfo.
	//
	//	- ErrContextInterrupt: The Context was interrupted by a call to
	//		Interrupt(). Switch() may return ErrContextInterrupt spuriously. In
	//		particular, most implementations of Interrupt() will cause the first
	//		following call to Switch() to return ErrContextInterrupt if there is no
	//		concurrent call to Switch().
	//
	//	- ErrContextCPUPreempted: See the definition of that error for details.
	Switch(ctx context.Context, mm MemoryManager, ac *arch.Context64, cpu int32) (*linux.SignalInfo, hostarch.AccessType, error)

	// PullFullState() pulls a full state of the application thread.
	//
	// A platform can support lazy loading/restoring of a thread state
	// which includes registers and a floating point state.
	//
	// For example, when the Sentry handles a system call, it may have only
	// syscall arguments without other registers and a floating point
	// state. And in this case, if the Sentry will need to construct a
	// signal frame to call a signal handler, it will need to call
	// PullFullState() to load all registers and FPU state.
	//
	// Preconditions: The caller must be running on the task goroutine.
	PullFullState(as AddressSpace, ac *arch.Context64) error

	// FullStateChanged() indicates that a thread state has been changed by
	// the Sentry. This happens in case of the rt_sigreturn, execve, etc.
	//
	// First, it indicates that the Sentry has the full state of the thread
	// and PullFullState() has to do nothing if it is called after
	// FullStateChanged().
	//
	// Second, it forces restoring the full state of the application
	// thread. A platform can support lazy loading/restoring of a thread
	// state. This means that if the Sentry has not changed a thread state,
	// the platform may not restore it.
	//
	// Preconditions: The caller must be running on the task goroutine.
	FullStateChanged()

	// Interrupt interrupts a concurrent call to Switch(), causing it to return
	// ErrContextInterrupt.
	Interrupt()

	// Release() releases any resources associated with this context.
	Release()

	// PrepareSleep() is called when the tread switches to the
	// interruptible sleep state.
	PrepareSleep()
}

type ContextError struct {
	// Err is the underlying error.
	Err error
	// Errno is an approximation of what type of error this is supposed to
	// be as defined by the linux errnos.
	Errno unix.Errno
}

type DoesNotOwnPageTables struct{}

type DoesOwnPageTables struct{}

type MMapMinAddr struct {
}

type MemoryManager interface {
	//usermem.IO provides access to the contents of a virtual memory space.
	usermem.IO
	// MMap establishes a memory mapping.
	MMap(ctx context.Context, opts memmap.MMapOpts) (hostarch.Addr, error)
	// AddressSpace returns the AddressSpace bound to mm.
	AddressSpace() AddressSpace
	// FindVMAByName finds a vma with the specified name.
	FindVMAByName(ar hostarch.AddrRange, hint string) (hostarch.Addr, uint64, error)
}

type NoAddressSpaceIO struct{}

type NoCPUPreemptionDetection struct{}

type Platform interface {
	// SupportsAddressSpaceIO returns true if AddressSpaces returned by this
	// Platform support AddressSpaceIO methods.
	//
	// The value returned by SupportsAddressSpaceIO is guaranteed to remain
	// unchanged over the lifetime of the Platform.
	SupportsAddressSpaceIO() bool

	// CooperativelySchedulesAddressSpace returns true if the Platform has a
	// limited number of AddressSpaces, such that mm.MemoryManager.Deactivate
	// should call AddressSpace.Release when there are no goroutines that
	// require the mm.MemoryManager to have an active AddressSpace.
	//
	// The value returned by CooperativelySchedulesAddressSpace is guaranteed
	// to remain unchanged over the lifetime of the Platform.
	CooperativelySchedulesAddressSpace() bool

	// DetectsCPUPreemption returns true if Contexts returned by the Platform
	// can reliably return ErrContextCPUPreempted.
	DetectsCPUPreemption() bool

	// HaveGlobalMemoryBarrier returns true if the GlobalMemoryBarrier method
	// is supported.
	HaveGlobalMemoryBarrier() bool

	// OwnsPageTables returns true if the Platform implementation manages any
	// page tables directly (rather than via host mmap(2) etc.) As of this
	// writing, this property is relevant because the AddressSpace interface
	// does not support specification of memory type (cacheability), such that
	// host FDs specifying memory types (e.g. device drivers) can only set them
	// correctly in host-managed page tables.
	OwnsPageTables() bool

	// MapUnit returns the alignment used for optional mappings into this
	// platform's AddressSpaces. Higher values indicate lower per-page costs
	// for AddressSpace.MapFile. As a special case, a MapUnit of 0 indicates
	// that the cost of AddressSpace.MapFile is effectively independent of the
	// number of pages mapped. If MapUnit is non-zero, it must be a power-of-2
	// multiple of hostarch.PageSize.
	MapUnit() uint64

	// MinUserAddress returns the minimum mappable address on this
	// platform.
	MinUserAddress() hostarch.Addr

	// MaxUserAddress returns the maximum mappable address on this
	// platform.
	MaxUserAddress() hostarch.Addr

	// NewAddressSpace returns a new memory context for this platform.
	//
	// If mappingsID is not nil, the platform may assume that (1) all calls
	// to NewAddressSpace with the same mappingsID represent the same
	// (mutable) set of mappings, and (2) the set of mappings has not
	// changed since the last time AddressSpace.Release was called on an
	// AddressSpace returned by a call to NewAddressSpace with the same
	// mappingsID.
	//
	// If a new AddressSpace cannot be created immediately, a nil
	// AddressSpace is returned, along with channel that is closed when
	// the caller should retry a call to NewAddressSpace.
	//
	// In general, this blocking behavior only occurs when
	// CooperativelySchedulesAddressSpace (above) returns false.
	NewAddressSpace(mappingsID any) (AddressSpace, <-chan struct{}, error)

	// NewContext returns a new execution context.
	NewContext(context.Context) Context

	// PreemptAllCPUs causes all concurrent calls to Context.Switch(), as well
	// as the first following call to Context.Switch() for each Context, to
	// return ErrContextCPUPreempted.
	//
	// PreemptAllCPUs is only supported if DetectsCPUPremption() == true.
	// Platforms for which this does not hold may panic if PreemptAllCPUs is
	// called.
	PreemptAllCPUs() error

	// GlobalMemoryBarrier blocks until all threads running application code
	// (via Context.Switch) and all task goroutines "have passed through a
	// state where all memory accesses to user-space addresses match program
	// order between entry to and return from [GlobalMemoryBarrier]", as for
	// membarrier(2).
	//
	// Preconditions: HaveGlobalMemoryBarrier() == true.
	GlobalMemoryBarrier() error

	// SeccompInfo returns seccomp-related information about this platform.
	SeccompInfo() SeccompInfo
}

type Requirements struct {
	// RequiresCurrentPIDNS indicates that the sandbox has to be started in the
	// current pid namespace.
	RequiresCurrentPIDNS bool
	// RequiresCapSysPtrace indicates that the sandbox has to be started with
	// the CAP_SYS_PTRACE capability.
	RequiresCapSysPtrace bool
}

type SeccompInfo interface {
	// Variables returns a map from named variables to the value they should
	// have with the platform as currently initialized.
	// Variables are known only at runtime, but are not part of a platform's
	// configuration. For example, the KVM platform having an FD representing
	// the KVM VM is a variable: it is only known at runtime, but does not
	// change the structure of the syscall rules.
	// The set of variable names must be static regardless of platform
	// configuration.
	Variables() precompiledseccomp.Values

	// ConfigKey returns a string that uniquely represents the set of
	// configuration information from which syscall rules are derived,
	// other than variables or CPU architecture.
	// This should at least contain the platform name.
	// If syscall rules are dependent on the platform's configuration,
	// this should return a string that encapsulates the values of these
	// configuration options.
	// For example, if some option of the platform causes it to require a
	// new syscall to be allowed, this option should be part of this string.
	ConfigKey() string

	// SyscallFilters returns syscalls made exclusively by this platform.
	// `vars` maps variable names (as returned by `Variables()`) to values,
	// and **the rules should depend on `vars`**. These will not necessarily
	// map to the result of calling `Variables()` on the current `SeccompInfo`;
	// during seccomp rule precompilation, these will be set to placeholder
	// values.
	SyscallFilters(vars precompiledseccomp.Values) seccomp.SyscallRules

	// HottestSyscalls returns the list of syscall numbers that this platform
	// calls most often, most-frequently-called first. No more than a dozen
	// syscalls. Returning an empty or a nil slice is OK.
	// This is used to produce a more efficient seccomp-bpf program that can
	// check for the most frequently called syscalls first.
	// What matters here is only the frequency at which a syscall is called,
	// not the total amount of CPU time that is used to process it in the host
	// kernel.
	HottestSyscalls() []uintptr
}

type SegmentationFault struct {
	// Addr is the address at which the fault occurred.
	Addr hostarch.Addr
}

type StaticSeccompInfo struct {
	// PlatformName is the platform name.
	PlatformName string

	// Filters is the platform's syscall filters.
	Filters seccomp.SyscallRules

	// HotSyscalls is the list of syscalls numbers that this platform
	// calls most often, most-frequently-called first.
	// See `SeccompInfo.HottestSyscalls` for more.
	HotSyscalls []uintptr
}

type UseHostGlobalMemoryBarrier struct{}

type UseHostProcessMemoryBarrier struct{}