MISC系列(51)–010 Editor模板编写入门
2021-03-25 16:04:37 Author: blog.nsfocus.net(查看原文) 阅读量:121 收藏

☆ 背景介绍

上周在看Zend VM OPcache,它的bin文件格式是版本强相关的,随PHP版本不同需要不同的解析方式。010 Editor提供的模板不适用于我当时看的版本。起初我在原模板基础上小修小改对付着用,后来发现需要修改的地方比较多,也不太适应原作者的解析思路,就打算自己写一个匹配版本的解析模板。

从未完整写过010 Editor模板,直接解析Zend VM OPcache的bin,会碰上很多与目标不直接相关的低级问题,比如基础语法、功能函数等等。决定先写一个Python脚本,对一组稍显复杂的自定义数据结构进行自定义序列化输出,然后写010 Editor模板解析前述序列化数据,以此掌握010 Editor模板基础语法、功能函数。

☆ SerializeTest.py

#! /usr/bin/env python
# -*- encoding: utf-8 -*-

import struct
import hexdump

#
#########################################################################
#

#
# little-endian
#
def i2b_8_l ( n ) :
    return( struct.pack( '<B', ( n & 0xff ) ) )
#
# end of i2b_8_l
#

def i2b_32_l ( n ) :
    return( struct.pack( '<I', ( n & 0xffffffff ) ) )
#
# end of i2b_32_l
#

def i2b_64_l ( n ) :
    return( struct.pack( '<Q', ( n & 0xffffffffffffffff ) ) )
#
# end of i2b_64_l
#

def b2i_8_l ( buf ) :
    return( int( struct.unpack( '<B', buf[0:1] )[0] ) )
#
# end of b2i_8_l
#

def b2i_32_l ( buf ) :
    return( int( struct.unpack( '<I', buf[0:4] )[0] ) )
#
# end of b2i_32_l
#

def b2i_64_l ( buf ) :
    return( int( struct.unpack( '<Q', buf[0:8] )[0] ) )
#
# end of b2i_64_l
#

#
# str转bytes
#
def s2b ( s, e="utf-8" ) :
    return( s.encode( encoding=e ) )
#
# end of s2b
#

#
# bytes转str
#
def b2s ( b, e="utf-8" ) :
    return( str( b, encoding=e ) )
#
# end of b2s
#

#
# 替换bytes中指定偏移、指定长度的内容
#
def PatchBytes ( buf, off, size, sth ) :
    return( buf[0:off] + sth + buf[off+size:] )
#
# PatchBytes
#

def WriteBytes ( filename, buf, mode='wb' ) :
    with open( filename, mode ) as f :
        f.write( buf )
#
# end of WriteBytes
#

#
#########################################################################
#

#
# count + off_array + buf_array
#
def SerializeArray ( array ) :
    count   = len( array )
    off     = b''
    buf     = b''
    j       = 4 + 4 * count
    for i in range( count ) :
        off    += i2b_32_l( j )
        tmp     = array[i].Serialize()
        buf    += tmp
        j      += len( tmp )
    return( i2b_32_l( count ) + off + buf )
#
# end of SerializeArray
#

#
# count + off_array + buf_array
#
def DeserializeArray ( buf, cls ) :
    if ( len( buf ) < 4 ) :
        return( None )
    count   = b2i_32_l( buf[0:4] )
    if ( 4 + 4 * count > len( buf ) ) :
        return( None )
    array   = []
    for i in range( count ) :
        j       = b2i_32_l( buf[4+i*4:4+i*4+4] )
        tmp     = cls.Deserialize( buf[j:] )
        if ( tmp is None ) :
            return( None )
        array.append( tmp )
    return( array )
#
# end of DeserializeArray
#

#
#########################################################################
#

#
# struct _zend_string {
#     uint32_t id;
#     size_t len;
#     char val[1];
# }
#
class MyString () :

    def __init__ ( self, id, sth ) :
        self.id     = id
        self.sth    = sth
    #
    # end of __init__
    #

    def __repr__ ( self ) :
        return( "MyString [%u:%s]" % ( self.id, self.sth ) )
    #
    # end of __repr__
    #

    def show ( self ) :
        print( "MyString [%u:%s]" % ( self.id, self.sth ) )
    #
    # end of show
    #

    #
    # 返回bytes
    #
    def Serialize ( self ) :
        b   = s2b( self.sth )
        return( i2b_32_l( self.id ) + i2b_32_l( len( b ) ) + b )
    #
    # end of Serialize
    #

    @staticmethod
    def Deserialize ( buf ) :
        if ( len( buf ) < 8 ) :
            return( None )
        id  = b2i_32_l( buf[0:4] )
        i   = b2i_32_l( buf[4:4+4] )
        if ( 8 + i > len( buf ) ) :
            return( None )
        sth = b2s( buf[8:8+i] )
        return( MyString( id, sth ) )
    #
    # end of Deserialize
    #

    # #
    # # count + off_array + buf_array
    # #
    # @staticmethod
    # def SerializeArray ( array ) :
    #     count   = len( array )
    #     off     = b''
    #     buf     = b''
    #     j       = 4 + 4 * count
    #     for i in range( count ) :
    #         off    += i2b_32_l( j )
    #         tmp     = array[i].Serialize()
    #         buf    += tmp
    #         j      += len( tmp )
    #     return( i2b_32_l( count ) + off + buf )
    # #
    # # end of SerializeArray
    # #

    # #
    # # count + off_array + buf_array
    # #
    # @staticmethod
    # def DeserializeArray ( buf ) :
    #     if ( len( buf ) < 4 ) :
    #         return( None )
    #     count   = b2i_32_l( buf[0:4] )
    #     k       = 4 + 4 * count
    #     if ( k > len( buf ) ) :
    #         return( None )
    #     array   = []
    #     for i in range( count ) :
    #         j       = b2i_32_l( buf[4+i*4:4+i*4+4] )
    #         if ( k != j ) :
    #             return( None )
    #         tmp     = MyString.Deserialize( buf[j:] )
    #         if ( tmp is None ) ;
    #             return( None )
    #         array.append( tmp )
    #         k      += len( tmp )
    #     return( array )
    # #
    # # end of DeserializeArray
    # #

#
# end of MyString
#

#
#########################################################################
#

#
# struct _zval_struct {
#     zend_value value;
#     union {
#         uint32_t type_info;
#     } u1;
#     union {
#         uint32_t lineno;
#     } u2;
# }
#
class MyZval () :

    def __init__ ( self, value, type_info, lineno ) :
        #
        # 64位整数
        #
        self.value      = value
        #
        # 32位整数
        #
        self.type_info  = type_info
        self.lineno     = lineno
    #
    # end of __init__
    #

    def __repr__ ( self ) :
        return( "MyZval [%#x:%u:%u]" % ( self.value, self.type_info, self.lineno ) )
    #
    # end of __repr__
    #

    def show ( self ) :
        print( "MyZval [%#x:%u:%u]" % ( self.value, self.type_info, self.lineno ) )
    #
    # end of show
    #

    #
    # 返回bytes
    #
    def Serialize ( self ) :
        return( i2b_64_l( self.value ) + i2b_32_l( self.type_info ) + i2b_32_l( self.lineno ) )
    #
    # end of Serialize
    #

    @staticmethod
    def Deserialize ( buf ) :
        if ( len( buf ) < 16 ) :
            return( None )
        value       = b2i_64_l( buf[0:8] )
        type_info   = b2i_32_l( buf[8:8+4] )
        lineno      = b2i_32_l( buf[12:12+4] )
        return( MyZval( value, type_info, lineno ) )
    #
    # end of Deserialize
    #

#
# end of MyZval
#

#
#########################################################################
#

#
# struct _zend_op {
#     znode_op op1;
#     znode_op op2;
#     znode_op result;
#     uint32_t lineno;
#     zend_uchar opcode;
#     zend_uchar op1_type;
#     zend_uchar op2_type;
#     zend_uchar result_type;
# }
#
class MyZendOp () :

    def __init__ ( self, op1, op2, result, lineno, opcode, op1_type, op2_type, result_type ) :
        #
        # 32位整数
        #
        self.op1            = op1
        self.op2            = op2
        self.result         = result
        self.lineno         = lineno
        #
        # unsigned char
        #
        self.opcode         = opcode
        self.op1_type       = op1_type
        self.op2_type       = op2_type
        self.result_type    = result_type
    #
    # end of __init__
    #

    def __repr__ ( self ) :
        return( "MyZendOp [%#x:%#x:%#x (%u)]" % ( self.opcode, self.op1, self.op2, self.lineno ) )
    #
    # end of __repr__
    #

    def show ( self ) :
        print( "MyZendOp [%#x:%#x:%#x (%u)]" % ( self.opcode, self.op1, self.op2, self.lineno ) )
    #
    # end of show
    #

    #
    # 返回bytes
    #
    def Serialize ( self ) :
        return  \
        (
            i2b_32_l( self.op1 ) +
            i2b_32_l( self.op2 ) +
            i2b_32_l( self.result ) +
            i2b_32_l( self.lineno ) +
            i2b_8_l( self.opcode ) +
            i2b_8_l( self.op1_type ) +
            i2b_8_l( self.op2_type ) +
            i2b_8_l( self.result_type )
        )
    #
    # end of Serialize
    #

    @staticmethod
    def Deserialize ( buf ) :
        if ( len( buf ) < 20 ) :
            return( None )
        op1         = b2i_32_l( buf[0:4] )
        op2         = b2i_32_l( buf[4:4+4] )
        result      = b2i_32_l( buf[8:8+4] )
        lineno      = b2i_32_l( buf[12:12+4] )
        # opcode      = b2i_8_l( buf[16:16+1] )
        # op1_type    = b2i_8_l( buf[17:17+1] )
        # op2_type    = b2i_8_l( buf[18:18+1] )
        # result_type = b2i_8_l( buf[19:19+1] )
        opcode      = buf[16]
        op1_type    = buf[17]
        op2_type    = buf[18]
        result_type = buf[19]
        return( MyZendOp( op1, op2, result, lineno, opcode, op1_type, op2_type, result_type ) )
    #
    # end of Deserialize
    #

#
# end of MyZendOp
#

#
#########################################################################
#

#
# struct _zend_op_array {
#     zend_uchar type;
#     uint32_t last;
#     zend_op *opcodes;
#     int last_var;
#     zend_string **vars;
#     zend_string *filename;
#     int last_literal;
#     zval *literals;
# }
#
class MyZendOpArray () :

    def __init__ ( self, type, opcodes, vars, filename, literals ) :
        self.type       = type
        #
        # MyZendOp[]
        #
        self.opcodes    = opcodes
        #
        # MyString[]
        #
        self.vars       = vars
        self.filename   = filename
        #
        # MyZval[]
        #
        self.literals   = literals
    #
    # end of __init__
    #

    def __repr__ ( self ) :
        return( "MyZendOpArray [%u:%s]" % ( self.type, self.filename ) )
    #
    # end of __repr__
    #

    def show ( self ) :
        print( "MyZendOpArray [%u:%s]" % ( self.type, self.filename ) )
        for i in range( len( self.opcodes ) ) :
            print( self.opcodes[i] )
        for i in range( len( self.vars ) ) :
            print( self.vars[i] )
        for i in range( len( self.literals ) ) :
            print( self.literals[i] )
    #
    # end of show
    #

    #
    # 返回bytes
    #
    # 只是一种演示方案,不是真实案例,有些字段安排甚至说不上合理,源自Zend
    # VM OPcache,
    #
    def Serialize ( self ) :
        buf             = i2b_8_l( self.type )

        last            = len( self.opcodes )
        buf            += i2b_32_l( last )
        opcodes_index   = len( buf )
        #
        # 占位
        #
        buf            += i2b_32_l( 0 )
        opcodes_buf     = SerializeArray( self.opcodes )[4:]

        last_var        = len( self.vars )
        buf            += i2b_32_l( last_var )
        vars_index      = len( buf )
        #
        # 占位
        #
        buf            += i2b_32_l( 0 )
        vars_buf        = SerializeArray( self.vars )[4:]

        filename_index  = len( buf )
        #
        # 占位
        #
        buf            += i2b_32_l( 0 )
        filename_buf    = self.filename.Serialize()

        last_literal    = len( self.literals )
        buf            += i2b_32_l( last_literal )
        literals_index  = len( buf )
        #
        # 占位
        #
        buf            += i2b_32_l( 0 )
        literals_buf    = SerializeArray( self.literals )[4:]

        buf             = PatchBytes( buf, opcodes_index, 4, i2b_32_l( len( buf ) ) )
        buf            += opcodes_buf

        buf             = PatchBytes( buf, vars_index, 4, i2b_32_l( len( buf ) ) )
        buf            += vars_buf

        buf             = PatchBytes( buf, filename_index, 4, i2b_32_l( len( buf ) ) )
        buf            += filename_buf

        buf             = PatchBytes( buf, literals_index, 4, i2b_32_l( len( buf ) ) )
        buf            += literals_buf

        return( buf )
    #
    # end of Serialize
    #

    @staticmethod
    def Deserialize ( buf ) :
        if ( len( buf ) < 29 ) :
            return( None )
        type            = b2i_8_l( buf[0:1] )

        last            = b2i_32_l( buf[1:1+4] )
        opcodes_off     = b2i_32_l( buf[5:5+4] )
        opcodes         = DeserializeArray( i2b_32_l( last ) + buf[opcodes_off:], MyZendOp )
        if ( opcodes is None ) :
            return( None )

        last_var        = b2i_32_l( buf[9:9+4] )
        vars_off        = b2i_32_l( buf[13:13+4] )
        vars            = DeserializeArray( i2b_32_l( last_var ) + buf[vars_off:], MyString )
        if ( vars is None ) :
            return( None )

        filename_off    = b2i_32_l( buf[17:17+4] )
        filename        = MyString.Deserialize( buf[filename_off:] )
        if ( filename is None ) :
            return( None )

        last_literal    = b2i_32_l( buf[21:21+4] )
        literals_off    = b2i_32_l( buf[25:25+4] )
        literals        = DeserializeArray( i2b_32_l( last_literal ) + buf[literals_off:], MyZval )
        if ( literals is None ) :
            return( None )

        return( MyZendOpArray( type, opcodes, vars, filename, literals ) )
    #
    # end of Deserialize
    #

#
# end of MyZendOpArray
#

#
#########################################################################
#

# mystr       = MyString( 0, "Test" )
# mystr.show()
# buf         = mystr.Serialize()
# hexdump.hexdump( buf )
# mystr       = MyString.Deserialize( buf )
# mystr.show()
#
# myzval      = MyZval( 0xffffffff00112233, 6, 12 )
# myzval.show()
# buf         = myzval.Serialize()
# hexdump.hexdump( buf )
# myzval      = MyZval.Deserialize( buf )
# myzval.show()
#
# myzendop    = MyZendOp  \
# (
#     1, 2, 3, 4, 5, 6, 7, 8
# )
# myzendop.show()
# buf         = myzendop.Serialize()
# hexdump.hexdump( buf )
# myzendop    = MyZendOp.Deserialize( buf )
# myzendop.show()

type        = 0x41
opcodes     =   \
[
MyZendOp( 1, 2, 3, 4, 5, 6, 7, 8 ),
MyZendOp( 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38 )
]
vars        =   \
[
MyString( 0, "Test_0" ),
MyString( 1, "Test_1" )
]
filename    = MyString( 2, "Test_2.php" )
literals    =   \
[
MyZval( 0xffffffff00112233, 6, 12 ),
MyZval( 0xfefefefe44556677, 7, 13 )
]
myzendoparray   \
            = MyZendOpArray( type, opcodes, vars, filename, literals )
myzendoparray.show()
buf         = myzendoparray.Serialize()
hexdump.hexdump( buf )
WriteBytes( 'SerializeTest.bin', buf )
myzendoparray   \
            = MyZendOpArray.Deserialize( buf )
# print( myzendoparray )
myzendoparray.show()
$ python3 SerializeTest.py
MyZendOpArray [65:MyString [2:Test_2.php]]
MyZendOp [0x5:0x1:0x2 (4)]
MyZendOp [0x35:0x31:0x32 (52)]
MyString [0:Test_0]
MyString [1:Test_1]
MyZval [0xffffffff00112233:6:12]
MyZval [0xfefefefe44556677:7:13]
00000000: 41 02 00 00 00 1D 00 00  00 02 00 00 00 4D 00 00  A............M..
00000010: 00 71 00 00 00 02 00 00  00 83 00 00 00 0C 00 00  .q..............
00000020: 00 20 00 00 00 01 00 00  00 02 00 00 00 03 00 00  . ..............
00000030: 00 04 00 00 00 05 06 07  08 31 00 00 00 32 00 00  .........1...2..
00000040: 00 33 00 00 00 34 00 00  00 35 36 37 38 0C 00 00  .3...4...5678...
00000050: 00 1A 00 00 00 00 00 00  00 06 00 00 00 54 65 73  .............Tes
00000060: 74 5F 30 01 00 00 00 06  00 00 00 54 65 73 74 5F  t_0........Test_
00000070: 31 02 00 00 00 0A 00 00  00 54 65 73 74 5F 32 2E  1........Test_2.
00000080: 70 68 70 0C 00 00 00 1C  00 00 00 33 22 11 00 FF  php........3"...
00000090: FF FF FF 06 00 00 00 0C  00 00 00 77 66 55 44 FE  ...........wfUD.
000000A0: FE FE FE 07 00 00 00 0D  00 00 00                 ...........
MyZendOpArray [65:MyString [2:Test_2.php]]
MyZendOp [0x5:0x1:0x2 (4)]
MyZendOp [0x35:0x31:0x32 (52)]
MyString [0:Test_0]
MyString [1:Test_1]
MyZval [0xffffffff00112233:6:12]
MyZval [0xfefefefe44556677:7:13]

1) 序列化输出结构

直接看SerializeTest.py的实现就能明白序列化方案,下面简介一二。

SerializeTest.py在序列化输出这个结构:

struct _zend_op_array {
    zend_uchar type;
    uint32_t last;
    zend_op *opcodes;       // opcodes[last]
    int last_var;
    zend_string **vars;     // vars[last_var]
    zend_string *filename;
    int last_literal;
    zval *literals;         // literals[last_literal]
}

这是个简化版结构,但足够复杂。其中vars[]本来是指针数组,但对序列化而言,当成zend_string[]序列化出去没啥不同,毕竟在序列化过程中指针都得换个方式处理。

下面这个结构将所有指针换成some_off的形式:

struct _zend_op_array {
    zend_uchar type;
    uint32_t last;
    uint32_t opcodes_off;   // opcodes[last]
    int last_var;
    uint32_t vars_off;      // vars[last_var]
    uint32_t filename_off;  // filename
    int last_literal;
    uint32_t literals_off;  // literals[last_literal]
}

将来序列化输出的格式大致如下:

head + opcodes[] + vars[] + filename + literals[]

head就是上面那个结构,其中的some_off分别对应opcodes[]、vars[]、filename、literals[]的偏移,基址是head的首字节。

序列化输出中的some[]不是简单的结构数组,而是结构数组的序列化输出。本例中some[]的格式大致如下:

off[] + buf[]

off[]是一个偏移数组,靠off[i]定位buf[i]。buf[i]是单个some结构的序列化输出。在SerializeTest.py的实现中,off[i]的基址并不是head的首字节。

参看SerializeTest.py中SerializeArray()、DeserializeArray()的实现。SerializeArray()本来输出的是:

count + off[] + buf[]

off[i]的基址是count的首字节。但some[]不包含count,count被放到head中去了。为啥会这样?本文参考了Zend VM OPcache的实现,在简化结构的同时想展示一些复杂之处,保留了某些原设定。

无论如何,这只是一种自定义序列化方案,仅作演示,没啥道理可言。

☆ SerializeTest.bt

$ xxd -g 1 SerializeTest.bin
00000000: 41 02 00 00 00 1d 00 00 00 02 00 00 00 4d 00 00  A............M..
00000010: 00 71 00 00 00 02 00 00 00 83 00 00 00 0c 00 00  .q..............
00000020: 00 20 00 00 00 01 00 00 00 02 00 00 00 03 00 00  . ..............
00000030: 00 04 00 00 00 05 06 07 08 31 00 00 00 32 00 00  .........1...2..
00000040: 00 33 00 00 00 34 00 00 00 35 36 37 38 0c 00 00  .3...4...5678...
00000050: 00 1a 00 00 00 00 00 00 00 06 00 00 00 54 65 73  .............Tes
00000060: 74 5f 30 01 00 00 00 06 00 00 00 54 65 73 74 5f  t_0........Test_
00000070: 31 02 00 00 00 0a 00 00 00 54 65 73 74 5f 32 2e  1........Test_2.
00000080: 70 68 70 0c 00 00 00 1c 00 00 00 33 22 11 00 ff  php........3"...
00000090: ff ff ff 06 00 00 00 0c 00 00 00 77 66 55 44 fe  ...........wfUD.
000000a0: fe fe fe 07 00 00 00 0d 00 00 00                 ...........

SerializeTest.bt是用于解析SerializeTest.bin的010 Editor模板。

//
// struct _zend_string {
//     uint32_t id;
//     size_t len;
//     char val[1];
// }
//
typedef struct _MyString
{
    uint    id;
    uint    len;
    //
    // 自动用前面的len成员定义此处的char[]
    //
    char    val[len];
    //
    // Read functions can also be used to show information beside a struct
    // without having to open the struct in the Template Results. When
    // using read functions with a struct, the read function receives a
    // reference to the struct and the '&' symbol should be used when
    // declaring the parameter.
    //
    // read回调会影响GUI中Value列的显示,只是增强显示效果,可以不提供
    //
} MyString <read=MyStringRepr>;

string MyStringRepr ( MyString &obj )
{
    if ( 0 == obj.len )
    {
        return( "(null)" );
    }
    return( obj.val );
}

//
//////////////////////////////////////////////////////////////////////////
//

//
// struct _zend_op {
//     znode_op op1;
//     znode_op op2;
//     znode_op result;
//     uint32_t lineno;
//     zend_uchar opcode;
//     zend_uchar op1_type;
//     zend_uchar op2_type;
//     zend_uchar result_type;
// }
//
typedef struct _MyZendOp
{
    uint    op1;
    uint    op2;
    uint    result;
    uint    lineno;
    uchar   opcode;
    uchar   op1_type;
    uchar   op2_type;
    uchar   result_type;
} MyZendOp <read=MyZendOpRepr>;

string MyZendOpRepr ( MyZendOp &obj )
{
    string  s;

    SPrintf( s, "%#x ( %#x, %#x ) : %u", obj.opcode, obj.op1, obj.op2, obj.lineno );
    return( s );
}

//
//////////////////////////////////////////////////////////////////////////
//

//
// struct _zval_struct {
//     zend_value value;
//     union {
//         uint32_t type_info;
//     } u1;
//     union {
//         uint32_t lineno;
//     } u2;
// }
//
typedef struct _MyZval
{
    uint64  value <format=hex>;
    uint    type_info;
    uint    lineno;
} MyZval <read=MyZvalRepr>;

string MyZvalRepr ( MyZval &obj )
{
    string  s;

    //
    // 010 Editor显示64位整数时有自己的格式符,不完全同C语言
    //
    SPrintf( s, "0x%Lx : %u : %u", obj.value, obj.type_info, obj.lineno );
    return( s );
}

//
//////////////////////////////////////////////////////////////////////////
//

//
// struct _zend_op_array {
//     zend_uchar type;
//     uint32_t last;
//     zend_op *opcodes;
//     int last_var;
//     zend_string **vars;
//     zend_string *filename;
//     int last_literal;
//     zval *literals;
// }
//
typedef struct _MyZendOpArray
{
    local int   saved_pos;
    //
    // local int   i, j, k;
    //

    uchar       type;

    uint        last;
    //
    // An alternate way of specifying the format for a variable is to use
    // the syntax '<format=hex|decimal|octal|binary>' after a variable
    // declaration or a typedef.
    //
    uint        opcodes_off <format=hex,hidden=true>;
    //
    // Returns the current read position of the file. This read position
    // is used when defining variables in a Template. Every time a
    // variable is defined in a template, the read position moves ahead
    // the number of bytes used by the variable.
    //
    saved_pos   = FTell();
    //
    // Sets the current read position to the address pos.
    //
    // FSeek( opcodes_off );
    // j           = opcodes_off - 4;
    // for ( i = 0; i < last; i++ )
    // {
    //     //
    //     // Returns data read from the file at address pos. If no pos is
    //     // given, pos defaults to the current read position as reported by
    //     // FTell. These functions can be used in a Template to read data
    //     // from a file without declaring a variable and note that these
    //     // functions do not affect the current read position.
    //     //
    //     k   = ReadUInt( opcodes_off + i * 4 );
    //     FSeek( j + k );
    //     MyZendOp    myzendop;
    // }
    //
    FSeek( opcodes_off + last * 4 );
    MyZendOp    opcodes[last];
    FSeek( saved_pos );

    uint        last_var;
    //
    // The syntax '<hidden=true>' can be used to hide the display of
    // variables in the Template Results.
    //
    uint        vars_off <format=hex,hidden=true>;
    saved_pos   = FTell();
    //
    // FSeek( vars_off );
    // j           = vars_off - 4;
    // for ( i = 0; i < last_var; i++ )
    // {
    //     k   = ReadUInt( vars_off + i * 4 );
    //     FSeek( j + k );
    //     MyString    mystring;
    // }
    //
    FSeek( vars_off + last_var * 4 );
    MyString    vars[last_var];
    FSeek( saved_pos );

    uint        filename_off <format=hex,hidden=true>;
    saved_pos   = FTell();
    FSeek( filename_off );
    MyString    filename ;
    FSeek( saved_pos );

    uint        last_literal;
    uint        literals_off <format=hex,hidden=true>;
    saved_pos   = FTell();
    //
    // FSeek( literals_off );
    // j           = literals_off - 4;
    // for ( i = 0; i < last_literal; i++ )
    // {
    //     k   = ReadUInt( literals_off + i * 4 );
    //     FSeek( j + k );
    //     MyZval  myzval;
    // }
    //
    FSeek( literals_off + last_literal * 4 );
    MyZval      literals[last_literal];
    FSeek( saved_pos );
} MyZendOpArray;

//
//////////////////////////////////////////////////////////////////////////
//

//
// Indicates that all subsequent reads and writes from the file should use
// little-endian byte order.
//
LittleEndian();

MyZendOpArray   myzendoparray;

在010 Editor中打开SerializeTest.bin,Ctrl-F5打开SerializeTest.bt,F5运行之。

上述模板文件是自解释的,实际试试就知道怎么写、怎么读。从最后一行开始读,依次套用结构、解析成员、显示数据、调用回调等等。

SerializeTest.bin中包含有some_off,但SerializeTest.bt用将之隐藏了,转而在附近显示反序列化之后的some[],尽可能接近人类可读状态。

MyString是个复杂结构,不是单纯的char[],模板用回调函数获取其中的char[],使得GUI中Value列的显示更直观。

010 Editor自带的帮助还可以,我都没怎么看在线帮助,直接看二进制自带的帮助。

☆ 参考资源

[1] 010 Editor Online Manual
    https://www.sweetscape.com/010editor/manual/

文章来源: http://blog.nsfocus.net/misc51-010-editor/
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