Source/JavaScriptCore/disassembler/udis86/udis86.c - WebKit - Git at Google

 /* udis86 - libudis86/udis86.c
  *
  * Copyright (c) 2002-2013 Vivek Thampi
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without modification,
  * are permitted provided that the following conditions are met:
  *
  *     * Redistributions of source code must retain the above copyright notice,
  *       this list of conditions and the following disclaimer.
  *     * Redistributions in binary form must reproduce the above copyright notice,
  *       this list of conditions and the following disclaimer in the documentation
  *       and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
  * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
  * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
  * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
  * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
  * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
  * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"

 #if ENABLE(UDIS86)

 #include "udis86_udint.h"
 #include "udis86_extern.h"
 #include "udis86_decode.h"

 #if !defined(__UD_STANDALONE__)
 #include <string.h>
 #endif /* !__UD_STANDALONE__ */

 static void ud_inp_init(struct ud *u);

 /* =============================================================================
  * ud_init
  *    Initializes ud_t object.
  * =============================================================================
  */
 extern void
 ud_init(struct ud* u)
 {
   memset((void*)u, 0, sizeof(struct ud));
   ud_set_mode(u, 16);
   u->mnemonic = UD_Iinvalid;
   ud_set_pc(u, 0);
 #ifndef __UD_STANDALONE__
   ud_set_input_file(u, stdin);
 #endif /* __UD_STANDALONE__ */

   ud_set_asm_buffer(u, u->asm_buf_int, sizeof(u->asm_buf_int));
 }


 /* =============================================================================
  * ud_disassemble
  *    Disassembles one instruction and returns the number of
  *    bytes disassembled. A zero means end of disassembly.
  * =============================================================================
  */
 extern unsigned int
 ud_disassemble(struct ud* u)
 {
   int len;
   if (u->inp_end) {
     return 0;
   }
   if ((len = ud_decode(u)) > 0) {
     if (u->translator != NULL) {
       u->asm_buf[0] = '\0';
       u->translator(u);
     }
   }
   return len;
 }


 /* =============================================================================
  * ud_set_mode() - Set Disassemly Mode.
  * =============================================================================
  */
 extern void
 ud_set_mode(struct ud* u, uint8_t m)
 {
   switch(m) {
   case 16:
   case 32:
   case 64: u->dis_mode = m ; return;
   default: u->dis_mode = 16; return;
   }
 }

 /* =============================================================================
  * ud_set_vendor() - Set vendor.
  * =============================================================================
  */
 extern void
 ud_set_vendor(struct ud* u, unsigned v)
 {
   switch(v) {
   case UD_VENDOR_INTEL:
     u->vendor = v;
     break;
   case UD_VENDOR_ANY:
     u->vendor = v;
     break;
   default:
     u->vendor = UD_VENDOR_AMD;
   }
 }

 /* =============================================================================
  * ud_set_pc() - Sets code origin.
  * =============================================================================
  */
 extern void
 ud_set_pc(struct ud* u, uint64_t o)
 {
   u->pc = o;
 }

 /* =============================================================================
  * ud_set_syntax() - Sets the output syntax.
  * =============================================================================
  */
 extern void
 ud_set_syntax(struct ud* u, void (*t)(struct ud*))
 {
   u->translator = t;
 }

 /* =============================================================================
  * ud_insn() - returns the disassembled instruction
  * =============================================================================
  */
 const char*
 ud_insn_asm(const struct ud* u)
 {
   return u->asm_buf;
 }

 /* =============================================================================
  * ud_insn_offset() - Returns the offset.
  * =============================================================================
  */
 uint64_t
 ud_insn_off(const struct ud* u)
 {
   return u->insn_offset;
 }


 /* =============================================================================
  * ud_insn_hex() - Returns hex form of disassembled instruction.
  * =============================================================================
  */
 const char*
 ud_insn_hex(struct ud* u)
 {
   u->insn_hexcode[0] = 0;
   if (!u->error) {
     unsigned int i;
     const unsigned char *src_ptr = ud_insn_ptr(u);
     char* src_hex = (char*) u->insn_hexcode;
     char* const src_hex_base = src_hex;
     /* for each byte used to decode instruction */
     for (i = 0; i < ud_insn_len(u) && i < sizeof(u->insn_hexcode) / 2;
          ++i, ++src_ptr) {
       snprintf(src_hex, sizeof(u->insn_hexcode) - (src_hex - src_hex_base), "%02x", *src_ptr & 0xFF);
       src_hex += 2;
     }
   }
   return u->insn_hexcode;
 }


 /* =============================================================================
  * ud_insn_ptr
  *    Returns a pointer to buffer containing the bytes that were
  *    disassembled.
  * =============================================================================
  */
 extern const uint8_t*
 ud_insn_ptr(const struct ud* u)
 {
   return (u->inp_buf == NULL) ?
             u->inp_sess : u->inp_buf + (u->inp_buf_index - u->inp_ctr);
 }


 /* =============================================================================
  * ud_insn_len
  *    Returns the count of bytes disassembled.
  * =============================================================================
  */
 extern unsigned int
 ud_insn_len(const struct ud* u)
 {
   return u->inp_ctr;
 }


 /* =============================================================================
  * ud_insn_get_opr
  *    Return the operand struct representing the nth operand of
  *    the currently disassembled instruction. Returns NULL if
  *    there's no such operand.
  * =============================================================================
  */
 const struct ud_operand*
 ud_insn_opr(const struct ud *u, unsigned int n)
 {
   if (n > 3 || u->operand[n].type == UD_NONE) {
     return NULL;
   } else {
     return &u->operand[n];
   }
 }


 /* =============================================================================
  * ud_opr_is_sreg
  *    Returns non-zero if the given operand is of a segment register type.
  * =============================================================================
  */
 int
 ud_opr_is_sreg(const struct ud_operand *opr)
 {
   return opr->type == UD_OP_REG &&
          opr->base >= UD_R_ES   &&
          opr->base <= UD_R_GS;
 }


 /* =============================================================================
  * ud_opr_is_sreg
  *    Returns non-zero if the given operand is of a general purpose
  *    register type.
  * =============================================================================
  */
 int
 ud_opr_is_gpr(const struct ud_operand *opr)
 {
   return opr->type == UD_OP_REG &&
          opr->base >= UD_R_AL   &&
          opr->base <= UD_R_R15;
 }


 /* =============================================================================
  * ud_set_user_opaque_data
  * ud_get_user_opaque_data
  *    Get/set user opaqute data pointer
  * =============================================================================
  */
 void
 ud_set_user_opaque_data(struct ud * u, void* opaque)
 {
   u->user_opaque_data = opaque;
 }

 void*
 ud_get_user_opaque_data(const struct ud *u)
 {
   return u->user_opaque_data;
 }


 /* =============================================================================
  * ud_set_asm_buffer
  *    Allow the user to set an assembler output buffer. If `buf` is NULL,
  *    we switch back to the internal buffer.
  * =============================================================================
  */
 void
 ud_set_asm_buffer(struct ud *u, char *buf, size_t size)
 {
   if (buf == NULL) {
     ud_set_asm_buffer(u, u->asm_buf_int, sizeof(u->asm_buf_int));
   } else {
     u->asm_buf = buf;
     u->asm_buf_size = size;
   }
 }


 /* =============================================================================
  * ud_set_sym_resolver
  *    Set symbol resolver for relative targets used in the translation
  *    phase.
  *
  *    The resolver is a function that takes a uint64_t address and returns a
  *    symbolic name for the that address. The function also takes a second
  *    argument pointing to an integer that the client can optionally set to a
  *    non-zero value for offsetted targets. (symbol+offset) The function may
  *    also return NULL, in which case the translator only prints the target
  *    address.
  *
  *    The function pointer maybe NULL which resets symbol resolution.
  * =============================================================================
  */
 void
 ud_set_sym_resolver(struct ud *u, const char* (*resolver)(struct ud*,
                                                           uint64_t addr,
                                                           int64_t *offset))
 {
   u->sym_resolver = resolver;
 }


 /* =============================================================================
  * ud_insn_mnemonic
  *    Return the current instruction mnemonic.
  * =============================================================================
  */
 enum ud_mnemonic_code
 ud_insn_mnemonic(const struct ud *u)
 {
   return u->mnemonic;
 }


 /* =============================================================================
  * ud_lookup_mnemonic
  *    Looks up mnemonic code in the mnemonic string table.
  *    Returns NULL if the mnemonic code is invalid.
  * =============================================================================
  */
 const char*
 ud_lookup_mnemonic(enum ud_mnemonic_code c)
 {
   if (c < UD_MAX_MNEMONIC_CODE) {
     return ud_mnemonics_str[c];
   } else {
     return NULL;
   }
 }


 /*
  * ud_inp_init
  *    Initializes the input system.
  */
 static void
 ud_inp_init(struct ud *u)
 {
   u->inp_hook      = NULL;
   u->inp_buf       = NULL;
   u->inp_buf_size  = 0;
   u->inp_buf_index = 0;
   u->inp_curr      = 0;
   u->inp_ctr       = 0;
   u->inp_end       = 0;
   u->inp_peek      = UD_EOI;
   UD_NON_STANDALONE(u->inp_file = NULL);
 }


 /* =============================================================================
  * ud_inp_set_hook
  *    Sets input hook.
  * =============================================================================
  */
 void
 ud_set_input_hook(register struct ud* u, int (*hook)(struct ud*))
 {
   ud_inp_init(u);
   u->inp_hook = hook;
 }

 /* =============================================================================
  * ud_inp_set_buffer
  *    Set buffer as input.
  * =============================================================================
  */
 void
 ud_set_input_buffer(register struct ud* u, const uint8_t* buf, size_t len)
 {
   ud_inp_init(u);
   u->inp_buf = buf;
   u->inp_buf_size = len;
   u->inp_buf_index = 0;
 }


 #ifndef __UD_STANDALONE__
 /* =============================================================================
  * ud_input_set_file
  *    Set FILE as input.
  * =============================================================================
  */
 static int
 inp_file_hook(struct ud* u)
 {
   return fgetc(u->inp_file);
 }

 void
 ud_set_input_file(register struct ud* u, FILE* f)
 {
   ud_inp_init(u);
   u->inp_hook = inp_file_hook;
   u->inp_file = f;
 }
 #endif /* __UD_STANDALONE__ */


 /* =============================================================================
  * ud_input_skip
  *    Skip n input bytes.
  * ============================================================================
  */
 void
 ud_input_skip(struct ud* u, size_t n)
 {
   if (u->inp_end) {
     return;
   }
   if (u->inp_buf == NULL) {
     while (n--) {
       int c = u->inp_hook(u);
       if (c == UD_EOI) {
         goto eoi;
       }
     }
     return;
   } else {
     if (n > u->inp_buf_size ||
         u->inp_buf_index > u->inp_buf_size - n) {
       u->inp_buf_index = u->inp_buf_size;
       goto eoi;
     }
     u->inp_buf_index += n;
     return;
   }
 eoi:
   u->inp_end = 1;
   UDERR(u, "cannot skip, eoi received\b");
   return;
 }


 /* =============================================================================
  * ud_input_end
  *    Returns non-zero on end-of-input.
  * =============================================================================
  */
 int
 ud_input_end(const struct ud *u)
 {
   return u->inp_end;
 }

 #endif // ENABLE(UDIS86)

 /* vim:set ts=2 sw=2 expandtab */
	/* udis86 - libudis86/udis86.c
	*
	* Copyright (c) 2002-2013 Vivek Thampi
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without modification,
	* are permitted provided that the following conditions are met:
	*
	* * Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
	* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
	* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
	* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
	* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
	* ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
	* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"

	#if ENABLE(UDIS86)

	#include "udis86_udint.h"
	#include "udis86_extern.h"
	#include "udis86_decode.h"

	#if !defined(__UD_STANDALONE__)
	#include <string.h>
	#endif /* !__UD_STANDALONE__ */

	static void ud_inp_init(struct ud *u);

	/* =============================================================================
	* ud_init
	* Initializes ud_t object.
	* =============================================================================
	*/
	extern void
	ud_init(struct ud* u)
	{
	memset((void*)u, 0, sizeof(struct ud));
	ud_set_mode(u, 16);
	u->mnemonic = UD_Iinvalid;
	ud_set_pc(u, 0);
	#ifndef __UD_STANDALONE__
	ud_set_input_file(u, stdin);
	#endif /* __UD_STANDALONE__ */

	ud_set_asm_buffer(u, u->asm_buf_int, sizeof(u->asm_buf_int));
	}


	/* =============================================================================
	* ud_disassemble
	* Disassembles one instruction and returns the number of
	* bytes disassembled. A zero means end of disassembly.
	* =============================================================================
	*/
	extern unsigned int
	ud_disassemble(struct ud* u)
	{
	int len;
	if (u->inp_end) {
	return 0;
	}
	if ((len = ud_decode(u)) > 0) {
	if (u->translator != NULL) {
	u->asm_buf[0] = '\0';
	u->translator(u);
	}
	}
	return len;
	}


	/* =============================================================================
	* ud_set_mode() - Set Disassemly Mode.
	* =============================================================================
	*/
	extern void
	ud_set_mode(struct ud* u, uint8_t m)
	{
	switch(m) {
	case 16:
	case 32:
	case 64: u->dis_mode = m ; return;
	default: u->dis_mode = 16; return;
	}
	}

	/* =============================================================================
	* ud_set_vendor() - Set vendor.
	* =============================================================================
	*/
	extern void
	ud_set_vendor(struct ud* u, unsigned v)
	{
	switch(v) {
	case UD_VENDOR_INTEL:
	u->vendor = v;
	break;
	case UD_VENDOR_ANY:
	u->vendor = v;
	break;
	default:
	u->vendor = UD_VENDOR_AMD;
	}
	}

	/* =============================================================================
	* ud_set_pc() - Sets code origin.
	* =============================================================================
	*/
	extern void
	ud_set_pc(struct ud* u, uint64_t o)
	{
	u->pc = o;
	}

	/* =============================================================================
	* ud_set_syntax() - Sets the output syntax.
	* =============================================================================
	*/
	extern void
	ud_set_syntax(struct ud* u, void (t)(struct ud))
	{
	u->translator = t;
	}

	/* =============================================================================
	* ud_insn() - returns the disassembled instruction
	* =============================================================================
	*/
	const char*
	ud_insn_asm(const struct ud* u)
	{
	return u->asm_buf;
	}

	/* =============================================================================
	* ud_insn_offset() - Returns the offset.
	* =============================================================================
	*/
	uint64_t
	ud_insn_off(const struct ud* u)
	{
	return u->insn_offset;
	}


	/* =============================================================================
	* ud_insn_hex() - Returns hex form of disassembled instruction.
	* =============================================================================
	*/
	const char*
	ud_insn_hex(struct ud* u)
	{
	u->insn_hexcode[0] = 0;
	if (!u->error) {
	unsigned int i;
	const unsigned char *src_ptr = ud_insn_ptr(u);
	char* src_hex = (char*) u->insn_hexcode;
	char* const src_hex_base = src_hex;
	/* for each byte used to decode instruction */
	for (i = 0; i < ud_insn_len(u) && i < sizeof(u->insn_hexcode) / 2;
	++i, ++src_ptr) {
	snprintf(src_hex, sizeof(u->insn_hexcode) - (src_hex - src_hex_base), "%02x", *src_ptr & 0xFF);
	src_hex += 2;
	}
	}
	return u->insn_hexcode;
	}


	/* =============================================================================
	* ud_insn_ptr
	* Returns a pointer to buffer containing the bytes that were
	* disassembled.
	* =============================================================================
	*/
	extern const uint8_t*
	ud_insn_ptr(const struct ud* u)
	{
	return (u->inp_buf == NULL) ?
	u->inp_sess : u->inp_buf + (u->inp_buf_index - u->inp_ctr);
	}


	/* =============================================================================
	* ud_insn_len
	* Returns the count of bytes disassembled.
	* =============================================================================
	*/
	extern unsigned int
	ud_insn_len(const struct ud* u)
	{
	return u->inp_ctr;
	}


	/* =============================================================================
	* ud_insn_get_opr
	* Return the operand struct representing the nth operand of
	* the currently disassembled instruction. Returns NULL if
	* there's no such operand.
	* =============================================================================
	*/
	const struct ud_operand*
	ud_insn_opr(const struct ud *u, unsigned int n)
	{
	if (n > 3 \|\| u->operand[n].type == UD_NONE) {
	return NULL;
	} else {
	return &u->operand[n];
	}
	}


	/* =============================================================================
	* ud_opr_is_sreg
	* Returns non-zero if the given operand is of a segment register type.
	* =============================================================================
	*/
	int
	ud_opr_is_sreg(const struct ud_operand *opr)
	{
	return opr->type == UD_OP_REG &&
	opr->base >= UD_R_ES &&
	opr->base <= UD_R_GS;
	}


	/* =============================================================================
	* ud_opr_is_sreg
	* Returns non-zero if the given operand is of a general purpose
	* register type.
	* =============================================================================
	*/
	int
	ud_opr_is_gpr(const struct ud_operand *opr)
	{
	return opr->type == UD_OP_REG &&
	opr->base >= UD_R_AL &&
	opr->base <= UD_R_R15;
	}


	/* =============================================================================
	* ud_set_user_opaque_data
	* ud_get_user_opaque_data
	* Get/set user opaqute data pointer
	* =============================================================================
	*/
	void
	ud_set_user_opaque_data(struct ud * u, void* opaque)
	{
	u->user_opaque_data = opaque;
	}

	void*
	ud_get_user_opaque_data(const struct ud *u)
	{
	return u->user_opaque_data;
	}


	/* =============================================================================
	* ud_set_asm_buffer
	* Allow the user to set an assembler output buffer. If `buf` is NULL,
	* we switch back to the internal buffer.
	* =============================================================================
	*/
	void
	ud_set_asm_buffer(struct ud u, char buf, size_t size)
	{
	if (buf == NULL) {
	ud_set_asm_buffer(u, u->asm_buf_int, sizeof(u->asm_buf_int));
	} else {
	u->asm_buf = buf;
	u->asm_buf_size = size;
	}
	}


	/* =============================================================================
	* ud_set_sym_resolver
	* Set symbol resolver for relative targets used in the translation
	* phase.
	*
	* The resolver is a function that takes a uint64_t address and returns a
	* symbolic name for the that address. The function also takes a second
	* argument pointing to an integer that the client can optionally set to a
	* non-zero value for offsetted targets. (symbol+offset) The function may
	* also return NULL, in which case the translator only prints the target
	* address.
	*
	* The function pointer maybe NULL which resets symbol resolution.
	* =============================================================================
	*/
	void
	ud_set_sym_resolver(struct ud u, const char (resolver)(struct ud,
	uint64_t addr,
	int64_t *offset))
	{
	u->sym_resolver = resolver;
	}


	/* =============================================================================
	* ud_insn_mnemonic
	* Return the current instruction mnemonic.
	* =============================================================================
	*/
	enum ud_mnemonic_code
	ud_insn_mnemonic(const struct ud *u)
	{
	return u->mnemonic;
	}


	/* =============================================================================
	* ud_lookup_mnemonic
	* Looks up mnemonic code in the mnemonic string table.
	* Returns NULL if the mnemonic code is invalid.
	* =============================================================================
	*/
	const char*
	ud_lookup_mnemonic(enum ud_mnemonic_code c)
	{
	if (c < UD_MAX_MNEMONIC_CODE) {
	return ud_mnemonics_str[c];
	} else {
	return NULL;
	}
	}


	/*
	* ud_inp_init
	* Initializes the input system.
	*/
	static void
	ud_inp_init(struct ud *u)
	{
	u->inp_hook = NULL;
	u->inp_buf = NULL;
	u->inp_buf_size = 0;
	u->inp_buf_index = 0;
	u->inp_curr = 0;
	u->inp_ctr = 0;
	u->inp_end = 0;
	u->inp_peek = UD_EOI;
	UD_NON_STANDALONE(u->inp_file = NULL);
	}


	/* =============================================================================
	* ud_inp_set_hook
	* Sets input hook.
	* =============================================================================
	*/
	void
	ud_set_input_hook(register struct ud* u, int (hook)(struct ud))
	{
	ud_inp_init(u);
	u->inp_hook = hook;
	}

	/* =============================================================================
	* ud_inp_set_buffer
	* Set buffer as input.
	* =============================================================================
	*/
	void
	ud_set_input_buffer(register struct ud* u, const uint8_t* buf, size_t len)
	{
	ud_inp_init(u);
	u->inp_buf = buf;
	u->inp_buf_size = len;
	u->inp_buf_index = 0;
	}


	#ifndef __UD_STANDALONE__
	/* =============================================================================
	* ud_input_set_file
	* Set FILE as input.
	* =============================================================================
	*/
	static int
	inp_file_hook(struct ud* u)
	{
	return fgetc(u->inp_file);
	}

	void
	ud_set_input_file(register struct ud* u, FILE* f)
	{
	ud_inp_init(u);
	u->inp_hook = inp_file_hook;
	u->inp_file = f;
	}
	#endif /* __UD_STANDALONE__ */


	/* =============================================================================
	* ud_input_skip
	* Skip n input bytes.
	* ============================================================================
	*/
	void
	ud_input_skip(struct ud* u, size_t n)
	{
	if (u->inp_end) {
	return;
	}
	if (u->inp_buf == NULL) {
	while (n--) {
	int c = u->inp_hook(u);
	if (c == UD_EOI) {
	goto eoi;
	}
	}
	return;
	} else {
	if (n > u->inp_buf_size \|\|
	u->inp_buf_index > u->inp_buf_size - n) {
	u->inp_buf_index = u->inp_buf_size;
	goto eoi;
	}
	u->inp_buf_index += n;
	return;
	}
	eoi:
	u->inp_end = 1;
	UDERR(u, "cannot skip, eoi received\b");
	return;
	}


	/* =============================================================================
	* ud_input_end
	* Returns non-zero on end-of-input.
	* =============================================================================
	*/
	int
	ud_input_end(const struct ud *u)
	{
	return u->inp_end;
	}

	#endif // ENABLE(UDIS86)

	/* vim:set ts=2 sw=2 expandtab */