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exception.go
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exception.go
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// Copyright 2018 Saferwall. All rights reserved.
// Use of this source code is governed by Apache v2 license
// license that can be found in the LICENSE file.
package pe
import (
"encoding/binary"
"strconv"
)
const (
// Unwind information flags.
// UnwFlagNHandler - The function has no handler.
UnwFlagNHandler = uint8(0x0)
// UnwFlagEHandler - The function has an exception handler that should
// be called when looking for functions that need to examine exceptions.
UnwFlagEHandler = uint8(0x1)
// UnwFlagUHandler - The function has a termination handler that should
// be called when unwinding an exception.
UnwFlagUHandler = uint8(0x2)
// UnwFlagChainInfo - This unwind info structure is not the primary one
// for the procedure. Instead, the chained unwind info entry is the contents
// of a previous RUNTIME_FUNCTION entry. For information, see Chained unwind
// info structures. If this flag is set, then the UNW_FLAG_EHANDLER and
// UNW_FLAG_UHANDLER flags must be cleared. Also, the frame register and
// fixed-stack allocation field must have the same values as in the primary
// unwind info.
UnwFlagChainInfo = uint8(0x4)
)
// The meaning of the operation info bits depends upon the operation code.
// To encode a general-purpose (integer) register, this mapping is used:
const (
rax = iota
rcx
rdx
rbx
rsp
rbp
rsi
rdi
r8
r9
r10
r11
r12
r13
r14
r15
)
// OpInfoRegisters maps registers to string.
var OpInfoRegisters = map[uint8]string{
rax: "RAX",
rcx: "RCX",
rdx: "RDX",
rbx: "RBX",
rsp: "RSP",
rbp: "RBP",
rsi: "RSI",
rdi: "RDI",
r8: "R8",
r9: "R9",
r10: "R10",
r11: "R11",
r12: "R12",
r13: "R13",
r14: "R14",
r15: "R15",
}
// UnwindOpType represents the type of an unwind opcode.
type UnwindOpType uint8
// _UNWIND_OP_CODES
const (
// Push a nonvolatile integer register, decrementing RSP by 8. The
// operation info is the number of the register. Because of the constraints
// on epilogs, UWOP_PUSH_NONVOL unwind codes must appear first in the
// prolog and correspondingly, last in the unwind code array. This relative
// ordering applies to all other unwind codes except UWOP_PUSH_MACHFRAME.
UwOpPushNonVol = UnwindOpType(0)
// Allocate a large-sized area on the stack. There are two forms. If the
// operation info equals 0, then the size of the allocation divided by 8 is
// recorded in the next slot, allowing an allocation up to 512K - 8. If the
// operation info equals 1, then the unscaled size of the allocation is
// recorded in the next two slots in little-endian format, allowing
// allocations up to 4GB - 8.
UwOpAllocLarge = UnwindOpType(1)
// Allocate a small-sized area on the stack. The size of the allocation is
// the operation info field * 8 + 8, allowing allocations from 8 to 128
// bytes.
UwOpAllocSmall = UnwindOpType(2)
// Establish the frame pointer register by setting the register to some
// offset of the current RSP. The offset is equal to the Frame Register
// offset (scaled) field in the UNWIND_INFO * 16, allowing offsets from 0
// to 240. The use of an offset permits establishing a frame pointer that
// points to the middle of the fixed stack allocation, helping code density
// by allowing more accesses to use short instruction forms. The operation
// info field is reserved and shouldn't be used.
UwOpSetFpReg = UnwindOpType(3)
// Save a nonvolatile integer register on the stack using a MOV instead of
// a PUSH. This code is primarily used for shrink-wrapping, where a
// nonvolatile register is saved to the stack in a position that was
// previously allocated. The operation info is the number of the register.
// The scaled-by-8 stack offset is recorded in the next unwind operation
// code slot, as described in the note above.
UwOpSaveNonVol = UnwindOpType(4)
// Save a nonvolatile integer register on the stack with a long offset,
// using a MOV instead of a PUSH. This code is primarily used for
// shrink-wrapping, where a nonvolatile register is saved to the stack in a
// position that was previously allocated. The operation info is the number
// of the register. The unscaled stack offset is recorded in the next two
// unwind operation code slots, as described in the note above.
UwOpSaveNonVolFar = UnwindOpType(5)
// For version 1 of the UNWIND_INFO structure, this code was called
// UWOP_SAVE_XMM and occupied 2 records, it retained the lower 64 bits of
// the XMM register, but was later removed and is now skipped. In practice,
// this code has never been used.
// For version 2 of the UNWIND_INFO structure, this code is called
// UWOP_EPILOG, takes 2 entries, and describes the function epilogue.
UwOpEpilog = UnwindOpType(6)
// For version 1 of the UNWIND_INFO structure, this code was called
// UWOP_SAVE_XMM_FAR and occupied 3 records, it saved the lower 64 bits of
// the XMM register, but was later removed and is now skipped. In practice,
// this code has never been used.
// For version 2 of the UNWIND_INFO structure, this code is called
// UWOP_SPARE_CODE, takes 3 entries, and makes no sense.
UwOpSpareCode = UnwindOpType(7)
// Save all 128 bits of a nonvolatile XMM register on the stack. The
// operation info is the number of the register. The scaled-by-16 stack
// offset is recorded in the next slot.
UwOpSaveXmm128 = UnwindOpType(8)
// Save all 128 bits of a nonvolatile XMM register on the stack with a long
// offset. The operation info is the number of the register. The unscaled
// stack offset is recorded in the next two slots.
UwOpSaveXmm128Far = UnwindOpType(9)
// Push a machine frame. This unwind code is used to record the effect of a
// hardware interrupt or exception.
UwOpPushMachFrame = UnwindOpType(10)
// UWOP_SET_FPREG_LARGE is a CLR Unix-only extension to the Windows AMD64
// unwind codes. It is not part of the standard Windows AMD64 unwind codes
// specification. UWOP_SET_FPREG allows for a maximum of a 240 byte offset
// between RSP and the frame pointer, when the frame pointer is
// established. UWOP_SET_FPREG_LARGE has a 32-bit range scaled by 16. When
// UWOP_SET_FPREG_LARGE is used, UNWIND_INFO.FrameRegister must be set to
// the frame pointer register, and UNWIND_INFO.FrameOffset must be set to
// 15 (its maximum value). UWOP_SET_FPREG_LARGE is followed by two
// UNWIND_CODEs that are combined to form a 32-bit offset (the same as
// UWOP_SAVE_NONVOL_FAR). This offset is then scaled by 16. The result must
// be less than 2^32 (that is, the top 4 bits of the unscaled 32-bit number
// must be zero). This result is used as the frame pointer register offset
// from RSP at the time the frame pointer is established. Either
// UWOP_SET_FPREG or UWOP_SET_FPREG_LARGE can be used, but not both.
UwOpSetFpRegLarge = UnwindOpType(11)
)
// ImageRuntimeFunctionEntry represents an entry in the function table on 64-bit
// Windows (IMAGE_RUNTIME_FUNCTION_ENTRY). Table-based exception handling request
// a table entry for all functions that allocate stack space or call another
// function (for example, non-leaf functions).
type ImageRuntimeFunctionEntry struct {
// The address of the start of the function.
BeginAddress uint32 `json:"begin_address"`
// The address of the end of the function.
EndAddress uint32 `json:"end_address"`
// The unwind data info structure is used to record the effects a function
// has on the stack pointer, and where the nonvolatile registers are saved
// on the stack.
UnwindInfoAddress uint32 `json:"unwind_info_address"`
}
// ImageARMRuntimeFunctionEntry represents the function table entry for the ARM
// platform.
type ImageARMRuntimeFunctionEntry struct {
// Function Start RVA is the 32-bit RVA of the start of the function. If
// the function contains thumb code, the low bit of this address must be set.
BeginAddress uint32 `bitfield:",functionstart" json:"begin_address"`
// Flag is a 2-bit field that indicates how to interpret the remaining
// 30 bits of the second .pdata word. If Flag is 0, then the remaining bits
// form an Exception Information RVA (with the low two bits implicitly 0).
// If Flag is non-zero, then the remaining bits form a Packed Unwind Data
// structure.
Flag uint8 `json:"flag"`
/* Exception Information RVA or Packed Unwind Data.
Exception Information RVA is the address of the variable-length exception
information structure, stored in the .xdata section.
This data must be 4-byte aligned.
Packed Unwind Data is a compressed description of the operations required
to unwind from a function, assuming a canonical form. In this case, no
.xdata record is required. */
ExceptionFlag uint32 `json:"exception_flag"`
}
// UnwindCode is used to record the sequence of operations in the prolog that
// affect the nonvolatile registers and RSP. Each code item has this format:
/* typedef union _UNWIND_CODE {
struct {
UCHAR CodeOffset;
UCHAR UnwindOp : 4;
UCHAR OpInfo : 4;
} DUMMYUNIONNAME;
struct {
UCHAR OffsetLow;
UCHAR UnwindOp : 4;
UCHAR OffsetHigh : 4;
} EpilogueCode;
USHORT FrameOffset;
} UNWIND_CODE, *PUNWIND_CODE;*/
//
// It provides information about the amount of stack space allocated, the location
// of saved non-volatile registers, and whether or not a frame register is used
// and what relation it has to the rest of the stack.
type UnwindCode struct {
// Offset (from the beginning of the prolog) of the end of the instruction
// that performs is operation, plus 1 (that is, the offset of the start of
// the next instruction).
CodeOffset uint8 `json:"code_offset"`
// The unwind operation code.
UnwindOp UnwindOpType `json:"unwind_op"`
// Operation info.
OpInfo uint8 `json:"op_info"`
// Allocation size.
Operand string `json:"operand"`
FrameOffset uint16 `json:"frame_offset"`
}
// UnwindInfo represents the _UNWIND_INFO structure. It is used to record the
// effects a function has on the stack pointer, and where the nonvolatile
// registers are saved on the stack.
type UnwindInfo struct {
// (3 bits) Version number of the unwind data, currently 1 and 2.
Version uint8 `json:"version"`
// (5 bits) Three flags are currently defined above.
Flags uint8 `json:"flags"`
// Length of the function prolog in bytes.
SizeOfProlog uint8 `json:"size_of_prolog"`
// The number of slots in the unwind codes array. Some unwind codes,
// for example, UWOP_SAVE_NONVOL, require more than one slot in the array.
CountOfCodes uint8 `json:"count_of_codes"`
// If nonzero, then the function uses a frame pointer (FP), and this field
// is the number of the nonvolatile register used as the frame pointer,
// using the same encoding for the operation info field of UNWIND_CODE nodes.
FrameRegister uint8 `json:"frame_register"`
// If the frame register field is nonzero, this field is the scaled offset
// from RSP that is applied to the FP register when it's established. The
// actual FP register is set to RSP + 16 * this number, allowing offsets
// from 0 to 240. This offset permits pointing the FP register into the
// middle of the local stack allocation for dynamic stack frames, allowing
// better code density through shorter instructions. (That is, more
// instructions can use the 8-bit signed offset form.)
FrameOffset uint8 `json:"frame_offset"`
// An array of items that explains the effect of the prolog on the
// nonvolatile registers and RSP. See the section on UNWIND_CODE for the
// meanings of individual items. For alignment purposes, this array always
// has an even number of entries, and the final entry is potentially
// unused. In that case, the array is one longer than indicated by the
// count of unwind codes field.
UnwindCodes []UnwindCode `json:"unwind_codes"`
// Address of exception handler when UNW_FLAG_EHANDLER is set.
ExceptionHandler uint32 `json:"exception_handler"`
// If flag UNW_FLAG_CHAININFO is set, then the UNWIND_INFO structure ends
// with three UWORDs. These UWORDs represent the RUNTIME_FUNCTION
// information for the function of the chained unwind.
FunctionEntry ImageRuntimeFunctionEntry `json:"function_entry"`
}
//
// The unwind codes are followed by an optional DWORD aligned field that
// contains the exception handler address or the address of chained unwind
// information. If an exception handler address is specified, then it is
// followed by the language specified exception handler data.
//
// union {
// ULONG ExceptionHandler;
// ULONG FunctionEntry;
// };
//
// ULONG ExceptionData[];
//
type ScopeRecord struct {
// This value indicates the offset of the first instruction within a __try
// block located in the function.
BeginAddress uint32 `json:"begin_address"`
// This value indicates the offset to the instruction after the last
// instruction within the __try block (conceptually the __except statement).
EndAddress uint32 `json:"end_address"`
// This value indicates the offset to the function located within the
// parentheses of the __except() statement. In the documentation you'll
// find this routine called the "exception handler" or "exception filter".
HandlerAddress uint32 `json:"handler_address"`
// This value indicates the offset to the first instruction in the __except
// block associated with the __try block.
JumpTarget uint32 `json:"jump_target"`
}
// ScopeTable represents a variable length structure containing a count followed
// by Count "scope records". While the RUNTIME_FUNCTION describes the entire range
// of a function that contains SEH, the SCOPE_TABLE describes each of the individual
// __try/__except blocks within the function.
type ScopeTable struct {
// The count of scope records.
Count uint32 `json:"count"`
// A array of scope record.
ScopeRecords []ScopeRecord `json:"scope_records"`
}
// typedef struct _SCOPE_TABLE {
// ULONG Count;
// struct
// {
// ULONG BeginAddress;
// ULONG EndAddress;
// ULONG HandlerAddress;
// ULONG JumpTarget;
// } ScopeRecord[1];
// } SCOPE_TABLE, *PSCOPE_TABLE;
// Exception represent an entry in the function table.
type Exception struct {
RuntimeFunction ImageRuntimeFunctionEntry `json:"runtime_function"`
UnwindInfo UnwindInfo `json:"unwind_info"`
}
func (pe *File) parseUnwindCode(offset uint32, version uint8) (UnwindCode, int) {
unwindCode := UnwindCode{}
advanceBy := 0
// Read the unwind code at offset (2 bytes)
uc, err := pe.ReadUint16(offset)
if err != nil {
return unwindCode, advanceBy
}
unwindCode.CodeOffset = uint8(uc & 0xff)
unwindCode.UnwindOp = UnwindOpType(uc & 0xf00 >> 8)
unwindCode.OpInfo = uint8(uc & 0xf000 >> 12)
switch unwindCode.UnwindOp {
case UwOpAllocSmall:
size := int(unwindCode.OpInfo*8 + 8)
unwindCode.Operand = "Size=" + strconv.Itoa(size)
advanceBy++
case UwOpAllocLarge:
if unwindCode.OpInfo == 0 {
size := int(binary.LittleEndian.Uint16(pe.data[offset+2:]) * 8)
unwindCode.Operand = "Size=" + strconv.Itoa(size)
advanceBy += 2
} else {
size := int(binary.LittleEndian.Uint32(pe.data[offset+2:]) << 16)
unwindCode.Operand = "Size=" + strconv.Itoa(size)
advanceBy += 3
}
case UwOpSetFpReg:
unwindCode.Operand = "Register=" + OpInfoRegisters[unwindCode.OpInfo]
advanceBy++
case UwOpPushNonVol:
unwindCode.Operand = "Register=" + OpInfoRegisters[unwindCode.OpInfo]
advanceBy++
case UwOpSaveNonVol:
fo := binary.LittleEndian.Uint16(pe.data[offset+2:])
unwindCode.FrameOffset = fo * 8
unwindCode.Operand = "Register=" + OpInfoRegisters[unwindCode.OpInfo] +
", Offset=" + strconv.Itoa(int(unwindCode.FrameOffset))
advanceBy += 2
case UwOpSaveNonVolFar:
fo := binary.LittleEndian.Uint32(pe.data[offset+2:])
unwindCode.FrameOffset = uint16(fo * 8)
unwindCode.Operand = "Register=" + OpInfoRegisters[unwindCode.OpInfo] +
", Offset=" + strconv.Itoa(int(unwindCode.FrameOffset))
advanceBy += 3
case UwOpSaveXmm128:
fo := binary.LittleEndian.Uint16(pe.data[offset+2:])
unwindCode.FrameOffset = fo * 16
unwindCode.Operand = "Register=XMM" + strconv.Itoa(int(unwindCode.OpInfo)) +
", Offset=" + strconv.Itoa(int(unwindCode.FrameOffset))
advanceBy += 2
case UwOpSaveXmm128Far:
fo := binary.LittleEndian.Uint32(pe.data[offset+2:])
unwindCode.FrameOffset = uint16(fo)
unwindCode.Operand = "Register=XMM" + strconv.Itoa(int(unwindCode.OpInfo)) +
", Offset=" + strconv.Itoa(int(unwindCode.FrameOffset))
advanceBy += 3
case UwOpSetFpRegLarge:
unwindCode.Operand = "Register=" + OpInfoRegisters[unwindCode.OpInfo]
advanceBy += 2
case UwOpPushMachFrame:
advanceBy++
case UwOpEpilog:
if version == 2 {
unwindCode.Operand = "Flags=" + strconv.Itoa(int(unwindCode.OpInfo)) + ", Size=" + strconv.Itoa(int(unwindCode.CodeOffset))
}
advanceBy += 2
case UwOpSpareCode:
advanceBy += 3
default:
advanceBy++ // so we can get out of the loop
pe.logger.Warnf("Wrong unwind opcode %d", unwindCode.UnwindOp)
}
return unwindCode, advanceBy
}
func (pe *File) parseUnwindInfo(unwindInfo uint32) UnwindInfo {
ui := UnwindInfo{}
offset := pe.GetOffsetFromRva(unwindInfo)
v, err := pe.ReadUint32(offset)
if err != nil {
return ui
}
// The lowest 3 bits
ui.Version = uint8(v & 0x7)
// The next 5 bits.
ui.Flags = uint8(v & 0xf8 >> 3)
// The next byte
ui.SizeOfProlog = uint8(v & 0xff00 >> 8)
// The next byte
ui.CountOfCodes = uint8(v & 0xff0000 >> 16)
// The next 4 bits
ui.FrameRegister = uint8(v & 0xf00000 >> 24)
// The next 4 bits.
ui.FrameOffset = uint8(v&0xf0000000>>28) * 6
// Each unwind code struct is 2 bytes wide.
offset += 4
i := 0
for i < int(ui.CountOfCodes) {
ucOffset := offset + 2*uint32(i)
unwindCode, advanceBy := pe.parseUnwindCode(ucOffset, ui.Version)
if advanceBy == 0 {
return ui
}
ui.UnwindCodes = append(ui.UnwindCodes, unwindCode)
i += advanceBy
}
if ui.CountOfCodes&1 == 1 {
offset += 2
}
// An image-relative pointer to either the function's language-specific
// exception or termination handler, if flag UNW_FLAG_CHAININFO is clear
// and one of the flags UNW_FLAG_EHADLER or UNW_FLAG_UHANDLER is set.
if ui.Flags&UnwFlagEHandler != 0 || ui.Flags&UnwFlagUHandler != 0 {
if ui.Flags&UnwFlagChainInfo == 0 {
handlerOffset := offset + 2*uint32(i)
ui.ExceptionHandler = binary.LittleEndian.Uint32(pe.data[handlerOffset:])
}
}
// If the UNW_FLAG_CHAININFO flag is set, then an unwind info structure
// is a secondary one, and the shared exception-handler/chained-info
// address field contains the primary unwind information. This sample
// code retrieves the primary unwind information, assuming that unwindInfo
// is the structure that has the UNW_FLAG_CHAININFO flag set.
if ui.Flags&UnwFlagChainInfo != 0 {
chainOffset := offset + 2*uint32(i)
rf := ImageRuntimeFunctionEntry{}
size := uint32(binary.Size(ImageRuntimeFunctionEntry{}))
err := pe.structUnpack(&rf, chainOffset, size)
if err != nil {
return ui
}
ui.FunctionEntry = rf
}
return ui
}
// Exception directory contains an array of function table entries that are used
// for exception handling.
func (pe *File) parseExceptionDirectory(rva, size uint32) error {
// The target platform determines which format of the function table entry
// to use.
var exceptions []Exception
fileOffset := pe.GetOffsetFromRva(rva)
entrySize := uint32(binary.Size(ImageRuntimeFunctionEntry{}))
entriesCount := size / entrySize
for i := uint32(0); i < entriesCount; i++ {
functionEntry := ImageRuntimeFunctionEntry{}
offset := fileOffset + (entrySize * i)
err := pe.structUnpack(&functionEntry, offset, entrySize)
if err != nil {
return err
}
exception := Exception{RuntimeFunction: functionEntry}
if pe.Is64 {
exception.UnwindInfo = pe.parseUnwindInfo(functionEntry.UnwindInfoAddress)
}
exceptions = append(exceptions, exception)
}
pe.Exceptions = exceptions
if len(exceptions) > 0 {
pe.HasException = true
}
return nil
}
// PrettyUnwindInfoHandlerFlags returns the string representation of the
// `flags` field of the unwind info structure.
func PrettyUnwindInfoHandlerFlags(flags uint8) []string {
var values []string
unwFlagHandlerMap := map[uint8]string{
UnwFlagNHandler: "No Handler",
UnwFlagEHandler: "Exception",
UnwFlagUHandler: "Termination",
UnwFlagChainInfo: "Chain",
}
for k, s := range unwFlagHandlerMap {
if k&flags != 0 {
values = append(values, s)
}
}
return values
}
// String returns the string representation of the an unwind opcode.
func (uo UnwindOpType) String() string {
unOpToString := map[UnwindOpType]string{
UwOpPushNonVol: "UWOP_PUSH_NONVOL",
UwOpAllocLarge: "UWOP_ALLOC_LARE",
UwOpAllocSmall: "UWOP_ALLOC_SMALL",
UwOpSetFpReg: "UWOP_SET_FPREG",
UwOpSaveNonVol: "UWOP_SAVE_NONVOL",
UwOpSaveNonVolFar: "UWOP_SAVE_NONVOL_FAR",
UwOpEpilog: "UWOP_EPILOG",
UwOpSpareCode: "UWOP_SPARE_CODE",
UwOpSaveXmm128: "UWOP_SAVE_XMM128",
UwOpSaveXmm128Far: "UWOP_SAVE_XMM128_FAR",
UwOpPushMachFrame: "UWOP_PUSH_MACHFRAME",
UwOpSetFpRegLarge: "UWOP_SET_FPREG_LARGE",
}
if val, ok := unOpToString[uo]; ok {
return val
}
return "?"
}