sane-project-backends/backend/mustek_usb2_asic.c

/* sane - Scanner Access Now Easy.

   Copyright (C) 2005 Mustek.
   Originally maintained by Mustek
   Author:Roy 2005.5.24

   This file is part of the SANE package.

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License as
   published by the Free Software Foundation; either version 2 of the
   License, or (at your option) any later version.

   This program is distributed in the hope that it will be useful, but
   WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 59 Temple Place - Suite 330, Boston,
   MA 02111-1307, USA.

   As a special exception, the authors of SANE give permission for
   additional uses of the libraries contained in this release of SANE.

   The exception is that, if you link a SANE library with other files
   to produce an executable, this does not by itself cause the
   resulting executable to be covered by the GNU General Public
   License.  Your use of that executable is in no way restricted on
   account of linking the SANE library code into it.

   This exception does not, however, invalidate any other reasons why
   the executable file might be covered by the GNU General Public
   License.

   If you submit changes to SANE to the maintainers to be included in
   a subsequent release, you agree by submitting the changes that
   those changes may be distributed with this exception intact.

   If you write modifications of your own for SANE, it is your choice
   whether to permit this exception to apply to your modifications.
   If you do not wish that, delete this exception notice.

   This file implements a SANE backend for the Mustek BearPaw 2448 TA Pro 
   and similar USB2 scanners. */

#define DEBUG_DECLARE_ONLY
#include "../include/sane/config.h"

#include <stdlib.h>
#include <string.h>
#include <unistd.h>

#ifdef _MSC_VER
#define _USE_MATH_DEFINES
#endif
#include <math.h>

#include "../include/sane/sane.h"
#include "../include/sane/sanei_usb.h"
#include "../include/sane/sanei_backend.h"

#include "mustek_usb2_asic.h"


/* ---------------------- low level ASIC functions -------------------------- */

static SANE_Byte RegisterBankStatus = ~0;

static SANE_Status
WriteIOControl (PAsic chip, unsigned short wValue, unsigned short wIndex,
		unsigned short wLength, SANE_Byte * lpBuf)
{
  SANE_Status status;

  status = sanei_usb_control_msg (chip->fd, 0x40, 0x01, wValue, wIndex, wLength,
				  lpBuf);
  if (status != SANE_STATUS_GOOD)
    DBG (DBG_ERR, "WriteIOControl Error!\n");

  return status;
}

static SANE_Status
ReadIOControl (PAsic chip, unsigned short wValue, unsigned short wIndex,
	       unsigned short wLength, SANE_Byte * lpBuf)
{
  SANE_Status status;

  status = sanei_usb_control_msg (chip->fd, 0xc0, 0x01, wValue, wIndex, wLength,
				  lpBuf);
  if (status != SANE_STATUS_GOOD)
    DBG (DBG_ERR, "ReadIOControl Error!\n");

  return status;
}

static SANE_Status
Mustek_ClearFIFO (PAsic chip)
{
  SANE_Status status;
  SANE_Byte buf[4];
  DBG (DBG_ASIC, "Mustek_ClearFIFO: Enter\n");

  buf[0] = 0;
  buf[1] = 0;
  buf[2] = 0;
  buf[3] = 0;

  status = WriteIOControl (chip, 0x05, 0, 4, buf);
  if (status != SANE_STATUS_GOOD)
    return status;

  status = WriteIOControl (chip, 0xc0, 0, 4, buf);

  DBG (DBG_ASIC, "Mustek_ClearFIFO: Exit\n");
  return status;
}

static SANE_Status
SwitchBank (PAsic chip, unsigned short reg)
{
  SANE_Status status;
  SANE_Byte buf[4];
  SANE_Byte bank;

  bank = HIBYTE(reg);
  if (bank > SELECT_REGISTER_BANK2)
    {
      DBG (DBG_ERR, "SwitchBank: invalid register %d\n", reg);
      return SANE_STATUS_INVAL;
    }

  if (RegisterBankStatus != bank)
    {
      buf[0] = ES01_5F_REGISTER_BANK_SELECT;
      buf[1] = bank;
      buf[2] = ES01_5F_REGISTER_BANK_SELECT;
      buf[3] = bank;
      status = WriteIOControl (chip, 0xb0, 0, 4, buf);
      if (status != SANE_STATUS_GOOD)
	return status;

      RegisterBankStatus = bank;
      DBG (DBG_ASIC, "RegisterBankStatus=%d\n", RegisterBankStatus);
    }

  return SANE_STATUS_GOOD;
}

static SANE_Status
Mustek_SendData (PAsic chip, unsigned short reg, SANE_Byte data)
{
  SANE_Status status;
  SANE_Byte buf[4];
  DBG (DBG_ASIC, "Mustek_SendData: Enter. reg=%x,data=%x\n", reg, data);

  status = SwitchBank (chip, reg);
  if (status != SANE_STATUS_GOOD)
    return status;

  buf[0] = LOBYTE (reg);
  buf[1] = data;
  buf[2] = LOBYTE (reg);
  buf[3] = data;
  status = WriteIOControl (chip, 0xb0, 0, 4, buf);
  if (status != SANE_STATUS_GOOD)
    DBG (DBG_ERR, ("Mustek_SendData: write error\n"));

  return status;
}

static SANE_Status
Mustek_ReceiveData (PAsic chip, SANE_Byte * reg)
{
  SANE_Status status;
  SANE_Byte buf[4];

  DBG (DBG_ASIC, "Mustek_ReceiveData\n");

  status = ReadIOControl (chip, 0x07, 0, 4, buf);
  *reg = buf[0];

  return status;
}

static SANE_Status
Mustek_WriteAddressLineForRegister (PAsic chip, SANE_Byte x)
{
  SANE_Status status;
  SANE_Byte buf[4];

  DBG (DBG_ASIC, "Mustek_WriteAddressLineForRegister: Enter\n");

  buf[0] = x;
  buf[1] = x;
  buf[2] = x;
  buf[3] = x;
  status = WriteIOControl (chip, 0x04, x, 4, buf);

  DBG (DBG_ASIC, "Mustek_WriteAddressLineForRegister: Exit\n");
  return status;
}

static SANE_Status
SetRWSize (PAsic chip, SANE_Byte ReadWrite, unsigned int size)
{
  SANE_Status status;
  DBG (DBG_ASIC, "SetRWSize: Enter\n");

  if (ReadWrite == READ_RAM)
    size >>= 1;

  status = Mustek_SendData (chip, ES01_7C_DMA_SIZE_BYTE0, BYTE0 (size));
  if (status != SANE_STATUS_GOOD)
    return status;
  status = Mustek_SendData (chip, ES01_7D_DMA_SIZE_BYTE1, BYTE1 (size));
  if (status != SANE_STATUS_GOOD)
    return status;
  status = Mustek_SendData (chip, ES01_7E_DMA_SIZE_BYTE2, BYTE2 (size));
  if (status != SANE_STATUS_GOOD)
    return status;
  status = Mustek_SendData (chip, ES01_7F_DMA_SIZE_BYTE3, BYTE3 (size));

  DBG (DBG_ASIC, "SetRWSize: Exit\n");
  return status;
}

static SANE_Status
Mustek_DMARead (PAsic chip, unsigned int size, SANE_Byte * lpData)
{
  SANE_Status status;
  size_t cur_read_size;

  DBG (DBG_ASIC, "Mustek_DMARead: Enter. size=%d\n", size);

  status = Mustek_ClearFIFO (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  while (size > 0)
    {
      cur_read_size = (size > DMA_BLOCK_SIZE) ? DMA_BLOCK_SIZE : size;

      status = SetRWSize (chip, READ_RAM, cur_read_size);
      if (status != SANE_STATUS_GOOD)
	return status;

      status = WriteIOControl (chip, 0x03, 0, 4, (SANE_Byte *) &cur_read_size);
      if (status != SANE_STATUS_GOOD)
	return status;

      status = sanei_usb_read_bulk (chip->fd, lpData, &cur_read_size);
      if (status != SANE_STATUS_GOOD)
	{
	  DBG (DBG_ERR, "Mustek_DMARead: read error\n");
	  return status;
	}

      size -= cur_read_size;
      lpData += cur_read_size;
    }

  if (cur_read_size < DMA_BLOCK_SIZE)
    usleep (20000);

  DBG (DBG_ASIC, "Mustek_DMARead: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
Mustek_DMAWrite (PAsic chip, unsigned int size, SANE_Byte * lpData)
{
  SANE_Status status;
  size_t cur_write_size;

  DBG (DBG_ASIC, "Mustek_DMAWrite: Enter. size=%d\n", size);

  status = Mustek_ClearFIFO (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  while (size > 0)
    {
      cur_write_size = (size > DMA_BLOCK_SIZE) ? DMA_BLOCK_SIZE : size;

      status = SetRWSize (chip, WRITE_RAM, cur_write_size);
      if (status != SANE_STATUS_GOOD)
	return status;

      status = WriteIOControl (chip, 0x02, 0, 4, (SANE_Byte *) &cur_write_size);
      if (status != SANE_STATUS_GOOD)
	return status;

      status = sanei_usb_write_bulk (chip->fd, lpData, &cur_write_size);
      if (status != SANE_STATUS_GOOD)
	{
	  DBG (DBG_ERR, "Mustek_DMAWrite: write error\n");
	  return status;
	}

      size -= cur_write_size;
      lpData += cur_write_size;
    }

  status = Mustek_ClearFIFO (chip);

  DBG (DBG_ASIC, "Mustek_DMAWrite: Exit\n");
  return status;
}

static SANE_Status
Mustek_SendData2Byte (PAsic chip, unsigned short reg, SANE_Byte data)
{
  static SANE_Bool isTransfer = SANE_FALSE;
  static SANE_Byte dataBuf[4];
  SANE_Status status = SANE_STATUS_GOOD;

  if (!isTransfer)
    {
      dataBuf[0] = LOBYTE (reg);
      dataBuf[1] = data;
      isTransfer = SANE_TRUE;
    }
  else
    {
      dataBuf[2] = LOBYTE (reg);
      dataBuf[3] = data;
      isTransfer = SANE_FALSE;

      status = SwitchBank (chip, reg);
      if (status != SANE_STATUS_GOOD)
	return status;

      status = WriteIOControl (chip, 0xb0, 0, 4, dataBuf);
    }

  return status;
}


/* ---------------------- ASIC motor functions ----------------------------- */

static SANE_Status
LLFSetRamAddress (PAsic chip, unsigned int dwStartAddr, unsigned int dwEndAddr,
		  SANE_Byte bAccessTarget)
{
  SANE_Status status;

  DBG (DBG_ASIC, "LLFSetRamAddress:Enter\n");

  /* Set start address. Unit is a word. */
  Mustek_SendData (chip, ES01_A0_HostStartAddr0_7, BYTE0 (dwStartAddr));

  if (bAccessTarget == ON_CHIP_FINAL_GAMMA)
    {
      Mustek_SendData (chip, ES01_A1_HostStartAddr8_15,
		       BYTE1 (dwStartAddr) | ACCESS_FINAL_GAMMA_ES01);
      Mustek_SendData (chip, ES01_A2_HostStartAddr16_21,
		       BYTE2 (dwStartAddr) | ACCESS_GAMMA_RAM);
    }
  else if (bAccessTarget == ON_CHIP_PRE_GAMMA)
    {
      Mustek_SendData (chip, ES01_A1_HostStartAddr8_15,
		       BYTE1 (dwStartAddr) | ACCESS_PRE_GAMMA_ES01);
      Mustek_SendData (chip, ES01_A2_HostStartAddr16_21,
		       BYTE2 (dwStartAddr) | ACCESS_GAMMA_RAM);
    }
  else  /* DRAM */
    {
      Mustek_SendData (chip, ES01_A1_HostStartAddr8_15, BYTE1 (dwStartAddr));
      Mustek_SendData (chip, ES01_A2_HostStartAddr16_21,
		       BYTE2 (dwStartAddr) | ACCESS_DRAM);
    }

  /* Set end address. */
  Mustek_SendData (chip, ES01_A3_HostEndAddr0_7, BYTE0 (dwEndAddr));
  Mustek_SendData (chip, ES01_A4_HostEndAddr8_15, BYTE1 (dwEndAddr));
  Mustek_SendData (chip, ES01_A5_HostEndAddr16_21, BYTE2 (dwEndAddr));

  status = Mustek_ClearFIFO (chip);

  DBG (DBG_ASIC, "LLFSetRamAddress: Exit\n");
  return status;
}

static SANE_Status
LLFRamAccess (PAsic chip, LLF_RAMACCESS * RamAccess)
{
  SANE_Status status;
  SANE_Byte a[2];

  DBG (DBG_ASIC, "LLFRamAccess: Enter\n");

  status = LLFSetRamAddress (chip, RamAccess->StartAddress, 0xffffff,
			     RamAccess->IsOnChipGamma);
  if (status != SANE_STATUS_GOOD)
    return status;

  /* set SDRAM delay time */
  Mustek_SendData (chip, ES01_79_AFEMCLK_SDRAMCLK_DELAY_CONTROL,
		   SDRAMCLK_DELAY_12_ns);

  if (RamAccess->ReadWrite == WRITE_RAM)
    {
      status = Mustek_DMAWrite (chip, RamAccess->RwSize, RamAccess->BufferPtr);
      if (status != SANE_STATUS_GOOD)
	return status;

      /* steal read 2 byte */
      usleep (20000);
      RamAccess->RwSize = 2;
      RamAccess->BufferPtr = a;
      RamAccess->ReadWrite = READ_RAM;
      status = LLFRamAccess (chip, RamAccess);
      DBG (DBG_ASIC, "end steal 2 byte!\n");
    }
  else	/* read RAM */
    {
      status = Mustek_DMARead (chip, RamAccess->RwSize, RamAccess->BufferPtr);
    }

  DBG (DBG_ASIC, "LLFRamAccess: Exit\n");
  return status;
}

static void
LLFSetMotorCurrentAndPhase (PAsic chip,
			    LLF_MOTOR_CURRENT_AND_PHASE * MotorCurrentAndPhase)
{
  static const SANE_Byte MotorPhaseFullStep[] =
    { 0x08, 0x09, 0x01, 0x00 };
  static const SANE_Byte MotorPhaseHalfStep[] =
    { 0x25, 0x07, 0x24, 0x30, 0x2c, 0x0e, 0x2d, 0x39 };

  SANE_Byte MotorPhaseMask;
  int i;

  DBG (DBG_ASIC, "LLFSetMotorCurrentAndPhase: Enter\n");

  if (MotorCurrentAndPhase->MotorDriverIs3967 == 1)
    MotorPhaseMask = 0xFE;
  else
    MotorPhaseMask = 0xFF;

  DBG (DBG_ASIC, "MotorPhaseMask=0x%x\n", MotorPhaseMask);
  Mustek_SendData (chip, ES02_50_MOTOR_CURRENT_CONTORL,
		   DOWN_LOAD_MOTOR_TABLE_ENABLE);

  if (MotorCurrentAndPhase->MoveType == _4_TABLE_SPACE_FOR_FULL_STEP)
    {
      Mustek_SendData (chip, ES01_AB_PWM_CURRENT_CONTROL,
		       MOTOR_PWM_CURRENT_0 | MOTOR1_GPO_VALUE_0);

      for (i = 0; i < 4; i++)
	{
	  Mustek_SendData2Byte (chip, ES02_52_MOTOR_CURRENT_TABLE_A,
				MotorCurrentAndPhase->MotorCurrent);
	  Mustek_SendData2Byte (chip, ES02_53_MOTOR_CURRENT_TABLE_B,
				MotorCurrentAndPhase->MotorCurrent);
	  Mustek_SendData2Byte (chip, ES02_51_MOTOR_PHASE_TABLE_1,
				MotorPhaseFullStep[i] & MotorPhaseMask);
	}
    }
  else if (MotorCurrentAndPhase->MoveType == _8_TABLE_SPACE_FOR_1_DIV_2_STEP)
    {
      Mustek_SendData (chip, ES01_AB_PWM_CURRENT_CONTROL,
		       MOTOR_PWM_CURRENT_1 | MOTOR1_GPO_VALUE_0);

      for (i = 0; i < 8; i++)
	{
	  Mustek_SendData2Byte (chip, ES02_52_MOTOR_CURRENT_TABLE_A,
				MotorCurrentAndPhase->MotorCurrent);
	  Mustek_SendData2Byte (chip, ES02_53_MOTOR_CURRENT_TABLE_B,
				MotorCurrentAndPhase->MotorCurrent);
	  Mustek_SendData2Byte (chip, ES02_51_MOTOR_PHASE_TABLE_1,
				MotorPhaseHalfStep[i] & MotorPhaseMask);
	}
    }
  else if (MotorCurrentAndPhase->MoveType == _16_TABLE_SPACE_FOR_1_DIV_4_STEP)
    {
      Mustek_SendData (chip, ES01_AB_PWM_CURRENT_CONTROL,
		       MOTOR_PWM_CURRENT_2 | MOTOR1_GPO_VALUE_0);

      for (i = 0; i < 16; i++)
	{
	  double x = (((i % 4) * M_PI * 90) / 4) / 180;
	  Mustek_SendData2Byte (chip, ES02_52_MOTOR_CURRENT_TABLE_A, (SANE_Byte)
				(MotorCurrentAndPhase->MotorCurrent * sin (x)));
	  Mustek_SendData2Byte (chip, ES02_53_MOTOR_CURRENT_TABLE_B, (SANE_Byte)
				(MotorCurrentAndPhase->MotorCurrent * cos (x)));
	  Mustek_SendData2Byte (chip, ES02_51_MOTOR_PHASE_TABLE_1,
				MotorPhaseFullStep[i / 4] & MotorPhaseMask);
	}
    }
  else if (MotorCurrentAndPhase->MoveType == _32_TABLE_SPACE_FOR_1_DIV_8_STEP)
    {
      Mustek_SendData (chip, ES01_AB_PWM_CURRENT_CONTROL,
		       MOTOR_PWM_CURRENT_3 | MOTOR1_GPO_VALUE_0);

      for (i = 0; i < 32; i++)
	{
	  double x = (((i % 8) * M_PI * 90) / 8) / 180;
	  Mustek_SendData2Byte (chip, ES02_52_MOTOR_CURRENT_TABLE_A, (SANE_Byte)
				(MotorCurrentAndPhase->MotorCurrent * sin (x)));
	  Mustek_SendData2Byte (chip, ES02_53_MOTOR_CURRENT_TABLE_B, (SANE_Byte)
				(MotorCurrentAndPhase->MotorCurrent * cos (x)));
	  Mustek_SendData2Byte (chip, ES02_51_MOTOR_PHASE_TABLE_1,
				MotorPhaseFullStep[i / 8] & MotorPhaseMask);
	}
    }

  Mustek_SendData (chip, ES02_50_MOTOR_CURRENT_CONTORL,
		   MotorCurrentAndPhase->MoveType);

  DBG (DBG_ASIC, "LLFSetMotorCurrentAndPhase: Exit\n");
}

static SANE_Status
LLFSetMotorTable (PAsic chip, unsigned int dwTableBaseAddr,
		  unsigned short *MotorTablePtr)
{
  SANE_Status status;
  LLF_RAMACCESS RamAccess;

  DBG (DBG_ASIC, "LLFSetMotorTable: Enter\n");

  RamAccess.ReadWrite = WRITE_RAM;
  RamAccess.IsOnChipGamma = EXTERNAL_RAM;
  RamAccess.StartAddress = dwTableBaseAddr;
  RamAccess.RwSize = MOTOR_TABLE_SIZE * sizeof (unsigned short);
  RamAccess.BufferPtr = (SANE_Byte *) MotorTablePtr;

  status = LLFRamAccess (chip, &RamAccess);

  /* tell scan chip the motor table address, unit is 2^14 words */
  Mustek_SendData (chip, ES01_9D_MotorTableAddrA14_A21,
		   (SANE_Byte) (dwTableBaseAddr >> TABLE_OFFSET_BASE));

  DBG (DBG_ASIC, "LLFSetMotorTable: Exit\n");
  return status;
}

static SANE_Status
LLFSetShadingTable (PAsic chip, unsigned int dwTableBaseAddr,
		    unsigned int dwTableSize, unsigned short *ShadingTablePtr)
{
  SANE_Status status;
  LLF_RAMACCESS RamAccess;

  DBG (DBG_ASIC, "LLFSetShadingTable: Enter\n");

  RamAccess.ReadWrite = WRITE_RAM;
  RamAccess.IsOnChipGamma = EXTERNAL_RAM;
  RamAccess.StartAddress = dwTableBaseAddr;
  RamAccess.RwSize = dwTableSize;
  RamAccess.BufferPtr = (SANE_Byte *) ShadingTablePtr;

  status = LLFRamAccess (chip, &RamAccess);

  /* tell scan chip the shading table address, unit is 2^14 words */
  Mustek_SendData (chip, ES01_9B_ShadingTableAddrA14_A21,
		   (SANE_Byte) (dwTableBaseAddr >> TABLE_OFFSET_BASE));

  DBG (DBG_ASIC, "LLFSetShadingTable: Exit\n");
  return status;
}

static SANE_Status
LLFMotorMove (PAsic chip, LLF_MOTORMOVE * LLF_MotorMove)
{
  SANE_Status status;
  unsigned int motor_steps;
  SANE_Byte temp_motor_action;

  DBG (DBG_ASIC, "LLFMotorMove: Enter\n");

  status = PrepareScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  DBG (DBG_ASIC, "Set start/end pixel\n");

  Mustek_SendData (chip, ES01_B8_ChannelRedExpStartPixelLSB, LOBYTE (100));
  Mustek_SendData (chip, ES01_B9_ChannelRedExpStartPixelMSB, HIBYTE (100));
  Mustek_SendData (chip, ES01_BA_ChannelRedExpEndPixelLSB, LOBYTE (101));
  Mustek_SendData (chip, ES01_BB_ChannelRedExpEndPixelMSB, HIBYTE (101));

  Mustek_SendData (chip, ES01_BC_ChannelGreenExpStartPixelLSB, LOBYTE (100));
  Mustek_SendData (chip, ES01_BD_ChannelGreenExpStartPixelMSB, HIBYTE (100));
  Mustek_SendData (chip, ES01_BE_ChannelGreenExpEndPixelLSB, LOBYTE (101));
  Mustek_SendData (chip, ES01_BF_ChannelGreenExpEndPixelMSB, HIBYTE (101));

  Mustek_SendData (chip, ES01_C0_ChannelBlueExpStartPixelLSB, LOBYTE (100));
  Mustek_SendData (chip, ES01_C1_ChannelBlueExpStartPixelMSB, HIBYTE (100));
  Mustek_SendData (chip, ES01_C2_ChannelBlueExpEndPixelLSB, LOBYTE (101));
  Mustek_SendData (chip, ES01_C3_ChannelBlueExpEndPixelMSB, HIBYTE (101));

  /* set motor accelerate steps, max. 511 steps */
  Mustek_SendData (chip, ES01_E0_MotorAccStep0_7,
		   LOBYTE (LLF_MotorMove->AccStep));
  Mustek_SendData (chip, ES01_E1_MotorAccStep8_8,
		   HIBYTE (LLF_MotorMove->AccStep));
  DBG (DBG_ASIC, "AccStep=%d\n", LLF_MotorMove->AccStep);

  /* set motor decelerate steps, max. 255 steps */
  Mustek_SendData (chip, ES01_E5_MotorDecStep, LLF_MotorMove->DecStep);
  DBG (DBG_ASIC, "DecStep=%d\n", LLF_MotorMove->DecStep);

  /* Set motor uniform speed.
     Only used for UNIFORM_MOTOR_AND_SCAN_SPEED_ENABLE. If you use acc mode,
     these two registers are not used. */
  Mustek_SendData (chip, ES01_FD_MotorFixedspeedLSB,
		   LOBYTE (LLF_MotorMove->FixMoveSpeed));
  Mustek_SendData (chip, ES01_FE_MotorFixedspeedMSB,
		   HIBYTE (LLF_MotorMove->FixMoveSpeed));
  DBG (DBG_ASIC, "FixMoveSpeed=%d\n", LLF_MotorMove->FixMoveSpeed);

  /* set motor type */
  Mustek_SendData (chip, ES01_A6_MotorOption,
		   MOTOR_0_ENABLE | HOME_SENSOR_0_ENABLE | TABLE_DEFINE_ES03);

  /* Set motor speed unit for all motor modes, including uniform. */
  Mustek_SendData (chip, ES01_F6_MotorControl1,
		   SPEED_UNIT_1_PIXEL_TIME |
		   MOTOR_SYNC_UNIT_1_PIXEL_TIME);

  if (LLF_MotorMove->ActionType == ACTION_TYPE_BACKTOHOME)
    {
      DBG (DBG_ASIC, "ACTION_TYPE_BACKTOHOME\n");
      temp_motor_action = MOTOR_BACK_HOME_AFTER_SCAN_ENABLE;
      motor_steps = 30000 * 2;
    }
  else
    {
      DBG (DBG_ASIC, "Forward or Backward\n");
      temp_motor_action = MOTOR_MOVE_TO_FIRST_LINE_ENABLE;
      motor_steps = LLF_MotorMove->FixMoveSteps;

      if (LLF_MotorMove->ActionType == ACTION_TYPE_BACKWARD)
	{
	  DBG (DBG_ASIC, "ACTION_TYPE_BACKWARD\n");
	  temp_motor_action |= INVERT_MOTOR_DIRECTION_ENABLE;
	}
    }

  Mustek_SendData (chip, ES01_94_PowerSaveControl,
		   TIMER_POWER_SAVE_ENABLE |
		   USB_POWER_SAVE_ENABLE | USB_REMOTE_WAKEUP_ENABLE |
		   LED_MODE_FLASH_SLOWLY);

  /* set number of movement steps with fixed speed */
  Mustek_SendData (chip, ES01_E2_MotorStepOfMaxSpeed0_7, BYTE0 (motor_steps));
  Mustek_SendData (chip, ES01_E3_MotorStepOfMaxSpeed8_15, BYTE1 (motor_steps));
  Mustek_SendData (chip, ES01_E4_MotorStepOfMaxSpeed16_19, BYTE2 (motor_steps));
  DBG (DBG_ASIC, "motor_steps=%d\n", motor_steps);

  if (LLF_MotorMove->ActionMode == ACTION_MODE_UNIFORM_SPEED_MOVE)
    temp_motor_action |= UNIFORM_MOTOR_AND_SCAN_SPEED_ENABLE;

  Mustek_SendData (chip, ES01_F3_ActionOption, temp_motor_action);
  Mustek_SendData (chip, ES01_F4_ActiveTrigger, ACTION_TRIGGER_ENABLE);

  if (LLF_MotorMove->ActionType == ACTION_TYPE_BACKTOHOME)
    {
      status = WaitCarriageHome (chip);
      if (status != SANE_STATUS_GOOD)
        return status;
    }

  status = WaitUnitReady (chip);

  DBG (DBG_ASIC, "LLFMotorMove: Exit\n");
  return status;
}

static void
SetMotorStepTable (PAsic chip, LLF_MOTORMOVE * MotorStepsTable,
		   unsigned short wStartY, unsigned int dwScanImageSteps,
		   unsigned short wYResolution)
{
  unsigned short wAccSteps = 511;
  unsigned short wForwardSteps = 20;
  SANE_Byte bDecSteps = 255;
  unsigned short wScanAccSteps = 511;
  unsigned short wFixScanSteps = 20;
  SANE_Byte bScanDecSteps = 255;
  unsigned short wScanBackTrackingSteps = 40;
  unsigned short wScanRestartSteps = 40;

  DBG (DBG_ASIC, "SetMotorStepTable: Enter\n");

  switch (wYResolution)
    {
    case 2400:
    case 1200:
      wScanAccSteps = 100;
      bScanDecSteps = 10;
      wScanBackTrackingSteps = 10;
      wScanRestartSteps = 10;
      break;
    case 600:
    case 300:
      wScanAccSteps = 300;
      bScanDecSteps = 40;
      break;
    case 150:
      wScanAccSteps = 300;
      bScanDecSteps = 40;
      break;
    case 100:
    case 75:
    case 50:
      wScanAccSteps = 300;
      bScanDecSteps = 40;
      break;
    }

  /* not including T0,T1 steps */
  if (wStartY < (wAccSteps + wForwardSteps + bDecSteps + wScanAccSteps))
    {
      wAccSteps = 1;
      bDecSteps = 1;
      wFixScanSteps = (short)(wStartY - wScanAccSteps) > 0 ?
	(wStartY - wScanAccSteps) : 0;
      wForwardSteps = 0;

      chip->isMotorMoveToFirstLine = 0;
    }
  else
    {
      wForwardSteps = (short)(wStartY - wAccSteps - (unsigned short) bDecSteps -
	wScanAccSteps - wFixScanSteps) > 0 ?
	(wStartY - wAccSteps - (unsigned short) bDecSteps - wScanAccSteps -
	 wFixScanSteps) : 0;

      chip->isMotorMoveToFirstLine = MOTOR_MOVE_TO_FIRST_LINE_ENABLE;
    }

  dwScanImageSteps += wAccSteps;
  dwScanImageSteps += wForwardSteps;
  dwScanImageSteps += bDecSteps;
  dwScanImageSteps += wScanAccSteps;
  dwScanImageSteps += wFixScanSteps;
  dwScanImageSteps += bScanDecSteps;
  dwScanImageSteps += 2;

  MotorStepsTable->wScanAccSteps = wScanAccSteps;
  MotorStepsTable->bScanDecSteps = bScanDecSteps;

  /* state 1 */
  Mustek_SendData (chip, ES01_E0_MotorAccStep0_7, LOBYTE (wAccSteps));
  Mustek_SendData (chip, ES01_E1_MotorAccStep8_8, HIBYTE (wAccSteps));
  /* state 2 */
  Mustek_SendData (chip, ES01_E2_MotorStepOfMaxSpeed0_7,
		   LOBYTE (wForwardSteps));
  Mustek_SendData (chip, ES01_E3_MotorStepOfMaxSpeed8_15,
		   HIBYTE (wForwardSteps));
  Mustek_SendData (chip, ES01_E4_MotorStepOfMaxSpeed16_19, 0);
  /* state 3 */
  Mustek_SendData (chip, ES01_E5_MotorDecStep, bDecSteps);
  /* state 4 */
  Mustek_SendData (chip, ES01_AE_MotorSyncPixelNumberM16LSB, 0);
  Mustek_SendData (chip, ES01_AF_MotorSyncPixelNumberM16MSB, 0);
  /* state 5 */
  Mustek_SendData (chip, ES01_EC_ScanAccStep0_7, LOBYTE (wScanAccSteps));
  Mustek_SendData (chip, ES01_ED_ScanAccStep8_8, HIBYTE (wScanAccSteps));
  /* state 6 */
  Mustek_SendData (chip, ES01_EE_FixScanStepLSB, LOBYTE (wFixScanSteps));
  Mustek_SendData (chip, ES01_8A_FixScanStepMSB, HIBYTE (wFixScanSteps));
  /* state 8 */
  Mustek_SendData (chip, ES01_EF_ScanDecStep, bScanDecSteps);
  /* state 10 */
  Mustek_SendData (chip, ES01_E6_ScanBackTrackingStepLSB,
		   LOBYTE (wScanBackTrackingSteps));
  Mustek_SendData (chip, ES01_E7_ScanBackTrackingStepMSB,
		   HIBYTE (wScanBackTrackingSteps));
  /* state 15 */
  Mustek_SendData (chip, ES01_E8_ScanRestartStepLSB,
		   LOBYTE (wScanRestartSteps));
  Mustek_SendData (chip, ES01_E9_ScanRestartStepMSB,
		   HIBYTE (wScanRestartSteps));
  /* state 19 */
  Mustek_SendData (chip, ES01_EA_ScanBackHomeExtStepLSB, LOBYTE (100));
  Mustek_SendData (chip, ES01_EB_ScanBackHomeExtStepMSB, HIBYTE (100));

  /* total motor steps */
  Mustek_SendData (chip, ES01_F0_ScanImageStep0_7, BYTE0 (dwScanImageSteps));
  Mustek_SendData (chip, ES01_F1_ScanImageStep8_15, BYTE1 (dwScanImageSteps));
  Mustek_SendData (chip, ES01_F2_ScanImageStep16_19, BYTE2 (dwScanImageSteps));

  DBG (DBG_ASIC, "SetMotorStepTable: Exit\n");
}

static void
SetMotorStepTableForCalibration (PAsic chip, LLF_MOTORMOVE * MotorStepsTable,
				 unsigned int dwScanImageSteps)
{
  unsigned short wScanAccSteps = 1;
  SANE_Byte bScanDecSteps = 1;
  unsigned short wFixScanSteps = 0;
  unsigned short wScanBackTrackingSteps = 20;

  DBG (DBG_ASIC, "SetMotorStepTableForCalibration: Enter\n");

  chip->isMotorMoveToFirstLine = 0;

  dwScanImageSteps += wScanAccSteps;
  dwScanImageSteps += wFixScanSteps;
  dwScanImageSteps += bScanDecSteps;

  MotorStepsTable->wScanAccSteps = wScanAccSteps;
  MotorStepsTable->bScanDecSteps = bScanDecSteps;

  /* state 4 */
  Mustek_SendData (chip, ES01_AE_MotorSyncPixelNumberM16LSB, 0);
  Mustek_SendData (chip, ES01_AF_MotorSyncPixelNumberM16MSB, 0);
  /* state 5 */
  Mustek_SendData (chip, ES01_EC_ScanAccStep0_7, LOBYTE (wScanAccSteps));
  Mustek_SendData (chip, ES01_ED_ScanAccStep8_8, HIBYTE (wScanAccSteps));
  /* state 6 */
  Mustek_SendData (chip, ES01_EE_FixScanStepLSB, LOBYTE (wFixScanSteps));
  Mustek_SendData (chip, ES01_8A_FixScanStepMSB, HIBYTE (wFixScanSteps));
  /* state 8 */
  Mustek_SendData (chip, ES01_EF_ScanDecStep, bScanDecSteps);
  /* state 10 */
  Mustek_SendData (chip, ES01_E6_ScanBackTrackingStepLSB,
		   LOBYTE (wScanBackTrackingSteps));
  Mustek_SendData (chip, ES01_E7_ScanBackTrackingStepMSB,
		   HIBYTE (wScanBackTrackingSteps));
  /* state 15 */
  Mustek_SendData (chip, ES01_E8_ScanRestartStepLSB,
		   LOBYTE (wScanBackTrackingSteps));
  Mustek_SendData (chip, ES01_E9_ScanRestartStepMSB,
		   HIBYTE (wScanBackTrackingSteps));

  Mustek_SendData (chip, ES01_F0_ScanImageStep0_7, BYTE0 (dwScanImageSteps));
  Mustek_SendData (chip, ES01_F1_ScanImageStep8_15, BYTE1 (dwScanImageSteps));
  Mustek_SendData (chip, ES01_F2_ScanImageStep16_19, BYTE2 (dwScanImageSteps));

  DBG (DBG_ASIC, "SetMotorStepTableForCalibration: Exit\n");
}

static void
CalculateScanMotorTable (LLF_CALCULATEMOTORTABLE * lpCalculateMotorTable)
{
  unsigned short wEndSpeed, wStartSpeed;
  unsigned short wScanAccSteps;
  SANE_Byte bScanDecSteps;
  unsigned short * lpMotorTable;
  long double y;
  unsigned short i;

  DBG (DBG_ASIC, "CalculateScanMotorTable: Enter\n");

  wStartSpeed = lpCalculateMotorTable->StartSpeed;
  wEndSpeed = lpCalculateMotorTable->EndSpeed;
  wScanAccSteps = lpCalculateMotorTable->AccStepBeforeScan;
  bScanDecSteps = lpCalculateMotorTable->DecStepAfterScan;
  lpMotorTable = lpCalculateMotorTable->lpMotorTable;

  /* motor T0 & T6 acc table */
  for (i = 0; i < 512; i++)
    {
      y = 6000 - 3500;
      y *= pow (0.09, (M_PI_2 * i) / 512) - pow (0.09, (M_PI_2 * 511) / 512);
      y += 4500;
      lpMotorTable[i] = (unsigned short) y;	/* T0 */
      lpMotorTable[i + 512 * 6] = (unsigned short) y;	/* T6 */
    }

  /* motor T1 & T7 dec table */
  for (i = 0; i < 256; i++)
    {
      y = 6000 - 3500;
      y *= pow (0.3, (M_PI_2 * i) / 256);
      y = 6000 - y;
      lpMotorTable[i + 512] = (unsigned short) y;	/* T1 */
      lpMotorTable[i + 512 * 7] = (unsigned short) y;	/* T7 */
    }

  for (i = 0; i < wScanAccSteps; i++)
    {
      y = wStartSpeed - wEndSpeed;
      y *= pow (0.09, (M_PI_2 * i) / wScanAccSteps) -
	   pow (0.09, (M_PI_2 * (wScanAccSteps - 1)) / wScanAccSteps);
      y += wEndSpeed;
      lpMotorTable[i + 512 * 2] = (unsigned short) y;	/* T2 */
      lpMotorTable[i + 512 * 4] = (unsigned short) y;	/* T4 */
    }
  for (i = wScanAccSteps; i < 512; i++)
    {
      lpMotorTable[i + 512 * 2] = wEndSpeed;	/* T2 */
      lpMotorTable[i + 512 * 4] = wEndSpeed;	/* T4 */
    }

  for (i = 0; i < (unsigned short) bScanDecSteps; i++)
    {
      y = wStartSpeed - wEndSpeed;
      y *= pow (0.3, (M_PI_2 * i) / bScanDecSteps);
      y = wStartSpeed - y;
      lpMotorTable[i + 512 * 3] = (unsigned short) y;	/* T3 */
      lpMotorTable[i + 512 * 5] = (unsigned short) y;	/* T5 */
    }
  for (i = bScanDecSteps; i < 256; i++)
    {
      lpMotorTable[i + 512 * 3] = wStartSpeed;	/* T3 */
      lpMotorTable[i + 512 * 5] = wStartSpeed;	/* T5 */
    }

  DBG (DBG_ASIC, "CalculateScanMotorTable: Exit\n");
}

static void
CalculateMoveMotorTable (LLF_CALCULATEMOTORTABLE * lpCalculateMotorTable)
{
  unsigned short wEndSpeed, wStartSpeed;
  unsigned short wScanAccSteps;
  unsigned short * lpMotorTable;
  long double y;
  unsigned short i;

  DBG (DBG_ASIC, "CalculateMoveMotorTable: Enter\n");

  wStartSpeed = lpCalculateMotorTable->StartSpeed;
  wEndSpeed = lpCalculateMotorTable->EndSpeed;
  wScanAccSteps = lpCalculateMotorTable->AccStepBeforeScan;
  lpMotorTable = lpCalculateMotorTable->lpMotorTable;

  for (i = 0; i < 512; i++)
    {
      /* before scan acc table */
      y = (wStartSpeed - wEndSpeed) *
	pow (0.09, (M_PI_2 * i) / 512) + wEndSpeed;
      lpMotorTable[i] = (unsigned short) y;
      lpMotorTable[i + 512 * 2] = (unsigned short) y;
      lpMotorTable[i + 512 * 4] = (unsigned short) y;
      lpMotorTable[i + 512 * 6] = (unsigned short) y;
    }

  for (i = 0; i < 256; i++)
    {
      y = wStartSpeed - (wStartSpeed - wEndSpeed) *
	pow (0.3, (M_PI_2 * i) / 256);
      lpMotorTable[i + 512] = (unsigned short) y;
      lpMotorTable[i + 512 * 3] = (unsigned short) y;
      lpMotorTable[i + 512 * 5] = (unsigned short) y;
      lpMotorTable[i + 512 * 7] = (unsigned short) y;
    }

  for (i = 0; i < wScanAccSteps; i++)
    {
      y = (wStartSpeed - wEndSpeed) *
	(pow (0.09, (M_PI_2 * i) / wScanAccSteps) -
	 pow (0.09, (M_PI_2 * (wScanAccSteps - 1)) / wScanAccSteps)) +
	wEndSpeed;
      lpMotorTable[i + 512 * 2] = (unsigned short) y;
    }

  DBG (DBG_ASIC, "CalculateMoveMotorTable: Exit\n");
}

static SANE_Byte
CalculateMotorCurrent (unsigned short dwMotorSpeed)
{
  if (dwMotorSpeed < 2000)
    return 255;
  else if (dwMotorSpeed < 3500)
    return 200;
  else if (dwMotorSpeed < 5000)
    return 160;
  else if (dwMotorSpeed < 10000)
    return 70;
  else if (dwMotorSpeed < 17000)
    return 60;
  else	/* >= 17000 */
    return 50;
}

static SANE_Status
MotorMove (PAsic chip, unsigned short wStartSpeed, unsigned short wEndSpeed,
	   unsigned int dwFixMoveSpeed, SANE_Byte bMotorCurrent,
	   unsigned int dwTotalSteps, SANE_Byte bActionType)
{
  SANE_Status status;
  unsigned short * MotorTable;
  LLF_CALCULATEMOTORTABLE CalMotorTable;
  LLF_MOTOR_CURRENT_AND_PHASE CurrentPhase;
  LLF_MOTORMOVE MotorMove;

  DBG (DBG_ASIC, "MotorMove: Enter\n");

  MotorTable = malloc (MOTOR_TABLE_SIZE * sizeof (unsigned short));
  if (!MotorTable)
    {
      DBG (DBG_ASIC, "MotorTable == NULL\n");
      return SANE_STATUS_NO_MEM;
    }

  CalMotorTable.StartSpeed = wStartSpeed;
  CalMotorTable.EndSpeed = wEndSpeed;
  CalMotorTable.AccStepBeforeScan = 511;
  CalMotorTable.lpMotorTable = MotorTable;
  CalculateMoveMotorTable (&CalMotorTable);

  CurrentPhase.MoveType = _4_TABLE_SPACE_FOR_FULL_STEP;
  CurrentPhase.MotorDriverIs3967 = 0;
  CurrentPhase.MotorCurrent = bMotorCurrent;
  LLFSetMotorCurrentAndPhase (chip, &CurrentPhase);

  status = LLFSetMotorTable (chip, 0x3000, MotorTable);
  free (MotorTable);
  if (status != SANE_STATUS_GOOD)
    return status;

  MotorMove.ActionType = bActionType;
  if (dwTotalSteps >= 766)
    {
      MotorMove.ActionMode = ACTION_MODE_ACCDEC_MOVE;
      MotorMove.AccStep = 511;
      MotorMove.DecStep = 255;
    }
  else
    {
      MotorMove.ActionMode = ACTION_MODE_UNIFORM_SPEED_MOVE;
      MotorMove.AccStep = 1;
      MotorMove.DecStep = 1;
    }
  MotorMove.FixMoveSteps = dwTotalSteps -
			   (MotorMove.AccStep + MotorMove.DecStep);
  MotorMove.FixMoveSpeed = dwFixMoveSpeed;
  status = LLFMotorMove (chip, &MotorMove);

  DBG (DBG_ASIC, "MotorMove: Exit\n");
  return status;
}


/* ---------------------- medium level ASIC functions ---------------------- */

static void
InitTiming (PAsic chip)
{
  DBG (DBG_ASIC, "InitTiming: Enter\n");

  chip->Timing.AFE_ADCCLK_Timing = 0x3c3c3c00;
  chip->Timing.AFE_ADCVS_Timing  = 0x00c00000;
  chip->Timing.AFE_ADCRS_Timing  = 0x00000c00;
  chip->Timing.AFE_ChannelA_LatchPos = 3080;
  chip->Timing.AFE_ChannelB_LatchPos = 3602;
  chip->Timing.AFE_ChannelC_LatchPos = 5634;
  chip->Timing.AFE_ChannelD_LatchPos = 1546;
  chip->Timing.AFE_Secondary_FF_LatchPos = 12;

  chip->Timing.CCD_DummyCycleTiming = 0;
  chip->Timing.PHTG_PulseWidth = 12;
  chip->Timing.PHTG_WaitWidth = 1;
  chip->Timing.PHTG_TimingAdj = 1;
  chip->Timing.PHTG_TimingSetup = 0;
  chip->Timing.ChannelR_StartPixel = 100;
  chip->Timing.ChannelR_EndPixel = 200;
  chip->Timing.ChannelG_StartPixel = 100;
  chip->Timing.ChannelG_EndPixel = 200;
  chip->Timing.ChannelB_StartPixel = 100;
  chip->Timing.ChannelB_EndPixel = 200;

  chip->Timing.CCD_PH2_Timing  = 0x000fff00;
  chip->Timing.CCD_PHRS_Timing = 0x000f0000;
  chip->Timing.CCD_PHCP_Timing = 0x0000f000;
  chip->Timing.CCD_PH1_Timing  = 0xfff00000;

  chip->Timing.wCCDPixelNumber_Full = 11250;
  chip->Timing.wCCDPixelNumber_Half = 7500;

  DBG (DBG_ASIC, "InitTiming: Exit\n");
}

static SANE_Status
OpenScanChip (PAsic chip)
{
  SANE_Status status;
  SANE_Byte x[4];

  DBG (DBG_ASIC, "OpenScanChip: Enter\n");

  x[0] = 0x64;
  x[1] = 0x64;
  x[2] = 0x64;
  x[3] = 0x64;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x65;
  x[1] = 0x65;
  x[2] = 0x65;
  x[3] = 0x65;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x44;
  x[1] = 0x44;
  x[2] = 0x44;
  x[3] = 0x44;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x45;
  x[1] = 0x45;
  x[2] = 0x45;
  x[3] = 0x45;
  status = WriteIOControl (chip, 0x90, 0, 4, x);

  DBG (DBG_ASIC, "OpenScanChip: Exit\n");
  return status;
}

static SANE_Status
CloseScanChip (PAsic chip)
{
  SANE_Status status;
  SANE_Byte x[4];

  DBG (DBG_ASIC, "CloseScanChip: Enter\n");

  x[0] = 0x64;
  x[1] = 0x64;
  x[2] = 0x64;
  x[3] = 0x64;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x65;
  x[1] = 0x65;
  x[2] = 0x65;
  x[3] = 0x65;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x16;
  x[1] = 0x16;
  x[2] = 0x16;
  x[3] = 0x16;
  status = WriteIOControl (chip, 0x90, 0, 4, x);
  if (status != SANE_STATUS_GOOD)
    return status;

  x[0] = 0x17;
  x[1] = 0x17;
  x[2] = 0x17;
  x[3] = 0x17;
  status = WriteIOControl (chip, 0x90, 0, 4, x);

  DBG (DBG_ASIC, "CloseScanChip: Exit\n");
  return status;
}

static SANE_Status
PrepareScanChip (PAsic chip)
{
  SANE_Status status;

  DBG (DBG_ASIC, "PrepareScanChip: Enter\n");

  Mustek_SendData (chip, ES01_F3_ActionOption, 0);
  Mustek_SendData (chip, ES01_86_DisableAllClockWhenIdle, 0);
  Mustek_SendData (chip, ES01_F4_ActiveTrigger, 0);

  status = WaitUnitReady (chip);

  DBG (DBG_ASIC, "PrepareScanChip: Exit\n");
  return status;
}

static SANE_Status
SafeInitialChip (PAsic chip)
{
  SANE_Status status;

  DBG (DBG_ASIC, "SafeInitialChip: Enter\n");

  status = PrepareScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  DBG (DBG_ASIC, "isFirstOpenChip=%d\n", chip->isFirstOpenChip);
  if (chip->isFirstOpenChip)
    {
      status = DRAM_Test (chip);
      if (status != SANE_STATUS_GOOD)
	{
	  DBG (DBG_ASIC, "DRAM_Test: Error\n");
	  return status;
	}
      chip->isFirstOpenChip = SANE_FALSE;
    }

  DBG (DBG_ASIC, "SafeInitialChip: Exit\n");
  return status;
}

static SANE_Status
DRAM_Test (PAsic chip)
{
  SANE_Status status;
  LLF_RAMACCESS RamAccess;
  SANE_Byte buf[DRAM_TEST_SIZE];
  unsigned int i;

  DBG (DBG_ASIC, "DRAM_Test: Enter\n");

  for (i = 0; i < sizeof (buf); i++)
    buf[i] = i;

  RamAccess.ReadWrite = WRITE_RAM;
  RamAccess.IsOnChipGamma = EXTERNAL_RAM;
  RamAccess.StartAddress = 0;
  RamAccess.RwSize = sizeof (buf);
  RamAccess.BufferPtr = buf;

  status = LLFRamAccess (chip, &RamAccess);
  if (status != SANE_STATUS_GOOD)
    return status;

  memset (buf, 0, sizeof (buf));

  RamAccess.ReadWrite = READ_RAM;

  status = LLFRamAccess (chip, &RamAccess);
  if (status != SANE_STATUS_GOOD)
    return status;

  for (i = 0; i < sizeof (buf); i++)
    {
      if (buf[i] != i)
	{
	  DBG (DBG_ERR, "DRAM test error at offset %d\n", i);
	  return SANE_STATUS_IO_ERROR;
	}
    }

  DBG (DBG_ASIC, "DRAM_Text: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
GetChipStatus (PAsic chip, SANE_Byte Selector, SANE_Byte * ChipStatus)
{
  SANE_Status status;
  DBG (DBG_ASIC, "GetChipStatus: Enter\n");

  status = Mustek_SendData (chip, ES01_8B_Status, Selector);
  if (status != SANE_STATUS_GOOD)
    return status;

  status = Mustek_WriteAddressLineForRegister (chip, ES01_8B_Status);
  if (status != SANE_STATUS_GOOD)
    return status;

  if (ChipStatus)
    status = Mustek_ReceiveData (chip, ChipStatus);

  DBG (DBG_ASIC, "GetChipStatus: Exit\n");
  return status;
}

static SANE_Status
IsCarriageHome (PAsic chip, SANE_Bool * LampHome)
{
  SANE_Status status;
  SANE_Byte temp;

  DBG (DBG_ASIC, "IsCarriageHome: Enter\n");

  status = GetChipStatus (chip, H1H0L1L0_PS_MJ, &temp);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ASIC, "IsCarriageHome: Error!\n");
      return status;
    }

  *LampHome = (temp & SENSOR0_DETECTED) ? SANE_TRUE : SANE_FALSE;
  DBG (DBG_ASIC, "LampHome=%d\n", *LampHome);

  DBG (DBG_ASIC, "IsCarriageHome: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
WaitCarriageHome (PAsic chip)
{
  SANE_Status status;
  SANE_Bool LampHome;
  int i;

  DBG (DBG_ASIC, "WaitCarriageHome: Enter\n");

  for (i = 0; i < 100; i++)
    {
      status = IsCarriageHome (chip, &LampHome);
      if (status != SANE_STATUS_GOOD)
	return status;
      if (LampHome)
	break;
      usleep (300000);
    }
  DBG (DBG_ASIC, "Waited %d s\n", (unsigned short) (i * 0.3));

  status = Mustek_SendData (chip, ES01_F4_ActiveTrigger, 0);
  if ((status == SANE_STATUS_GOOD) && (i == 100))
    status = SANE_STATUS_DEVICE_BUSY;

  DBG (DBG_ASIC, "WaitCarriageHome: Exit\n");
  return status;
}

static SANE_Status
WaitUnitReady (PAsic chip)
{
  SANE_Status status;
  SANE_Byte temp;
  int i = 0;

  DBG (DBG_ASIC, "WaitUnitReady: Enter\n");

  do
    {
      status = GetChipStatus (chip, SCAN_STATE, &temp);
      if (status != SANE_STATUS_GOOD)
	{
	  DBG (DBG_ASIC, "WaitUnitReady: Error!\n");
	  return status;
	}
      if ((temp & 0x1f) == 0)
	break;
      usleep (100000);
    }
  while (++i < 300);
  DBG (DBG_ASIC, "Waited %d s\n", (unsigned short) (i * 0.1));

  Mustek_SendData (chip, ES01_F4_ActiveTrigger, 0);

  DBG (DBG_ASIC, "WaitUnitReady: Exit\n");
  return SANE_STATUS_GOOD;
}


static void
SetCCDTiming (PAsic chip)
{
  DBG (DBG_ASIC, "SetCCDTiming: Enter\n");

  Mustek_SendData (chip, ES01_82_AFE_ADCCLK_TIMING_ADJ_BYTE0,
		   BYTE0 (chip->Timing.AFE_ADCCLK_Timing));
  Mustek_SendData (chip, ES01_83_AFE_ADCCLK_TIMING_ADJ_BYTE1,
		   BYTE1 (chip->Timing.AFE_ADCCLK_Timing));
  Mustek_SendData (chip, ES01_84_AFE_ADCCLK_TIMING_ADJ_BYTE2,
		   BYTE2 (chip->Timing.AFE_ADCCLK_Timing));
  Mustek_SendData (chip, ES01_85_AFE_ADCCLK_TIMING_ADJ_BYTE3,
		   BYTE3 (chip->Timing.AFE_ADCCLK_Timing));

  Mustek_SendData (chip, ES01_1F0_AFERS_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.AFE_ADCRS_Timing));
  Mustek_SendData (chip, ES01_1F1_AFERS_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.AFE_ADCRS_Timing));
  Mustek_SendData (chip, ES01_1F2_AFERS_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.AFE_ADCRS_Timing));
  Mustek_SendData (chip, ES01_1F3_AFERS_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.AFE_ADCRS_Timing));

  Mustek_SendData (chip, ES01_1EC_AFEVS_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.AFE_ADCVS_Timing));
  Mustek_SendData (chip, ES01_1ED_AFEVS_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.AFE_ADCVS_Timing));
  Mustek_SendData (chip, ES01_1EE_AFEVS_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.AFE_ADCVS_Timing));
  Mustek_SendData (chip, ES01_1EF_AFEVS_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.AFE_ADCVS_Timing));

  Mustek_SendData (chip, ES01_160_CHANNEL_A_LATCH_POSITION_HB,
		   HIBYTE (chip->Timing.AFE_ChannelA_LatchPos));
  Mustek_SendData (chip, ES01_161_CHANNEL_A_LATCH_POSITION_LB,
		   LOBYTE (chip->Timing.AFE_ChannelA_LatchPos));

  Mustek_SendData (chip, ES01_162_CHANNEL_B_LATCH_POSITION_HB,
		   HIBYTE (chip->Timing.AFE_ChannelB_LatchPos));
  Mustek_SendData (chip, ES01_163_CHANNEL_B_LATCH_POSITION_LB,
		   LOBYTE (chip->Timing.AFE_ChannelB_LatchPos));

  Mustek_SendData (chip, ES01_164_CHANNEL_C_LATCH_POSITION_HB,
		   HIBYTE (chip->Timing.AFE_ChannelC_LatchPos));
  Mustek_SendData (chip, ES01_165_CHANNEL_C_LATCH_POSITION_LB,
		   LOBYTE (chip->Timing.AFE_ChannelC_LatchPos));

  Mustek_SendData (chip, ES01_166_CHANNEL_D_LATCH_POSITION_HB,
		   HIBYTE (chip->Timing.AFE_ChannelD_LatchPos));
  Mustek_SendData (chip, ES01_167_CHANNEL_D_LATCH_POSITION_LB,
		   LOBYTE (chip->Timing.AFE_ChannelD_LatchPos));

  Mustek_SendData (chip, ES01_168_SECONDARY_FF_LATCH_POSITION,
		   chip->Timing.AFE_Secondary_FF_LatchPos);

  Mustek_SendData (chip, ES01_1D0_DUMMY_CYCLE_TIMING_B0,
		   BYTE0 (chip->Timing.CCD_DummyCycleTiming));
  Mustek_SendData (chip, ES01_1D1_DUMMY_CYCLE_TIMING_B1,
		   BYTE1 (chip->Timing.CCD_DummyCycleTiming));
  Mustek_SendData (chip, ES01_1D2_DUMMY_CYCLE_TIMING_B2,
		   BYTE2 (chip->Timing.CCD_DummyCycleTiming));
  Mustek_SendData (chip, ES01_1D3_DUMMY_CYCLE_TIMING_B3,
		   BYTE3 (chip->Timing.CCD_DummyCycleTiming));

  Mustek_SendData (chip, ES01_1D4_PH1_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.CCD_PH1_Timing));
  Mustek_SendData (chip, ES01_1D5_PH1_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.CCD_PH1_Timing));
  Mustek_SendData (chip, ES01_1D6_PH1_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.CCD_PH1_Timing));
  Mustek_SendData (chip, ES01_1D7_PH1_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.CCD_PH1_Timing));

  Mustek_SendData (chip, ES01_D0_PH1_0, 0);
  Mustek_SendData (chip, ES01_D1_PH2_0, 4);
  Mustek_SendData (chip, ES01_D4_PHRS_0, 0);
  Mustek_SendData (chip, ES01_D5_PHCP_0, 0);

  Mustek_SendData (chip, ES01_1D8_PH2_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.CCD_PH2_Timing));
  Mustek_SendData (chip, ES01_1D9_PH2_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.CCD_PH2_Timing));
  Mustek_SendData (chip, ES01_1DA_PH2_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.CCD_PH2_Timing));
  Mustek_SendData (chip, ES01_1DB_PH2_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.CCD_PH2_Timing));

  Mustek_SendData (chip, ES01_1E4_PHRS_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.CCD_PHRS_Timing));
  Mustek_SendData (chip, ES01_1E5_PHRS_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.CCD_PHRS_Timing));
  Mustek_SendData (chip, ES01_1E6_PHRS_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.CCD_PHRS_Timing));
  Mustek_SendData (chip, ES01_1E7_PHRS_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.CCD_PHRS_Timing));

  Mustek_SendData (chip, ES01_1E8_PHCP_TIMING_ADJ_B0,
		   BYTE0 (chip->Timing.CCD_PHCP_Timing));
  Mustek_SendData (chip, ES01_1E9_PHCP_TIMING_ADJ_B1,
		   BYTE1 (chip->Timing.CCD_PHCP_Timing));
  Mustek_SendData (chip, ES01_1EA_PHCP_TIMING_ADJ_B2,
		   BYTE2 (chip->Timing.CCD_PHCP_Timing));
  Mustek_SendData (chip, ES01_1EB_PHCP_TIMING_ADJ_B3,
		   BYTE3 (chip->Timing.CCD_PHCP_Timing));

  DBG (DBG_ASIC, "SetCCDTiming: Exit\n");
}

static void
SetLineTimeAndExposure (PAsic chip)
{
  DBG (DBG_ASIC, "SetLineTimeAndExposure: Enter\n");

  Mustek_SendData (chip, ES01_C4_MultiTGTimesRed, 0);
  Mustek_SendData (chip, ES01_C5_MultiTGTimesGreen, 0);
  Mustek_SendData (chip, ES01_C6_MultiTGTimesBlue, 0);

  Mustek_SendData (chip, ES01_C7_MultiTGDummyPixelNumberLSB, 0);
  Mustek_SendData (chip, ES01_C8_MultiTGDummyPixelNumberMSB, 0);

  Mustek_SendData (chip, ES01_C9_CCDDummyPixelNumberLSB, 0);
  Mustek_SendData (chip, ES01_CA_CCDDummyPixelNumberMSB, 0);

  Mustek_SendData (chip, ES01_CB_CCDDummyCycleNumber, 0);

  DBG (DBG_ASIC, "SetLineTimeAndExposure: Exit\n");
}

static void
SetLEDTime (PAsic chip)
{
  DBG (DBG_ASIC, "SetLEDTime: Enter\n");

  Mustek_SendData (chip, ES01_B8_ChannelRedExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelR_StartPixel));
  Mustek_SendData (chip, ES01_B9_ChannelRedExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelR_StartPixel));
  Mustek_SendData (chip, ES01_BA_ChannelRedExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelR_EndPixel));
  Mustek_SendData (chip, ES01_BB_ChannelRedExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelR_EndPixel));

  Mustek_SendData (chip, ES01_BC_ChannelGreenExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelG_StartPixel));
  Mustek_SendData (chip, ES01_BD_ChannelGreenExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelG_StartPixel));
  Mustek_SendData (chip, ES01_BE_ChannelGreenExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelG_EndPixel));
  Mustek_SendData (chip, ES01_BF_ChannelGreenExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelG_EndPixel));

  Mustek_SendData (chip, ES01_C0_ChannelBlueExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelB_StartPixel));
  Mustek_SendData (chip, ES01_C1_ChannelBlueExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelB_StartPixel));
  Mustek_SendData (chip, ES01_C2_ChannelBlueExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelB_EndPixel));
  Mustek_SendData (chip, ES01_C3_ChannelBlueExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelB_EndPixel));

  DBG (DBG_ASIC, "SetLEDTime: Exit\n");
}

static void
SetAFEGainOffset (PAsic chip)
{
  int i, j;

  DBG (DBG_ASIC, "SetAFEGainOffset: Enter\n");

  for (i = 0; i < 3; i++)
    {
      Mustek_SendData (chip, ES01_60_AFE_AUTO_GAIN_OFFSET_RED_LB + (i * 2),
		       (chip->AD.Gain[i] << 1) | chip->AD.Direction[i]);
      Mustek_SendData (chip, ES01_61_AFE_AUTO_GAIN_OFFSET_RED_HB + (i * 2),
		       chip->AD.Offset[i]);
    }

  Mustek_SendData (chip, ES01_2A0_AFE_GAIN_OFFSET_CONTROL, 0x01);

  for (i = 0; i < 3; i++)
    {
      for (j = 0; j < 4; j++)
	{
	  Mustek_SendData (chip, ES01_2A1_AFE_AUTO_CONFIG_GAIN,
			   (chip->AD.Gain[i] << 1) | chip->AD.Direction[i]);
	  Mustek_SendData (chip, ES01_2A2_AFE_AUTO_CONFIG_OFFSET,
			   chip->AD.Offset[i]);
	}
    }

  for (i = 0; i < 36; i++)
    {
      Mustek_SendData (chip, ES01_2A1_AFE_AUTO_CONFIG_GAIN, 0);
      Mustek_SendData (chip, ES01_2A2_AFE_AUTO_CONFIG_OFFSET, 0);
    }

  Mustek_SendData (chip, ES01_2A0_AFE_GAIN_OFFSET_CONTROL, 0x00);

  for (i = 0; i < 3; i++)
    Mustek_SendData (chip, ES01_04_ADAFEPGACH1 + (i * 2), chip->AD.Gain[i]);

  for (i = 0; i < 3; i++)
    {
      if (chip->AD.Direction[i] == DIR_NEGATIVE)
	Mustek_SendData (chip, ES01_0B_AD9826OffsetRedN + (i * 2),
			 chip->AD.Offset[i]);
      else
	Mustek_SendData (chip, ES01_0A_AD9826OffsetRedP + (i * 2),
			 chip->AD.Offset[i]);
    }

  DBG (DBG_ASIC, "SetAFEGainOffset: Exit\n");
}

static void
SetScanMode (PAsic chip, SANE_Byte bScanBits)
{
  SANE_Byte temp_f5_register;

  DBG (DBG_ASIC, "SetScanMode(): Enter\n");

  if (bScanBits >= 24)
    temp_f5_register = COLOR_ES02 | GRAY_GREEN_BLUE_ES02;
  else
    temp_f5_register = GRAY_ES02 | GRAY_GREEN_ES02;

  if ((bScanBits == 8) || (bScanBits == 24))
    temp_f5_register |= _8_BITS_ES02;
  else if (bScanBits == 1)
    temp_f5_register |= _1_BIT_ES02;
  else
    temp_f5_register |= _16_BITS_ES02;

  Mustek_SendData (chip, ES01_F5_ScanDataFormat, temp_f5_register);

  DBG (DBG_ASIC, "F5_ScanDataFormat=0x%x\n", temp_f5_register);
  DBG (DBG_ASIC, "SetScanMode(): Exit\n");
}

static void
SetPackAddress (PAsic chip, unsigned short wWidth, unsigned short wX,
		double XRatioAdderDouble, double XRatioTypeDouble,
		SANE_Byte bClearPulseWidth, unsigned short * pValidPixelNumber)
{
  unsigned short ValidPixelNumber;
  int i;

  DBG (DBG_ASIC, "SetPackAddress: Enter\n");

  ValidPixelNumber = (unsigned short) ((wWidth + 10 + 15) * XRatioAdderDouble);
  ValidPixelNumber &= ~15;

  for (i = 0; i < 16; i++)
    {
      Mustek_SendData (chip, ES01_2B0_SEGMENT0_OVERLAP_SEGMENT1 + i, 0);
      Mustek_SendData (chip, ES01_2C0_VALID_PIXEL_PARAMETER_OF_SEGMENT1 + i, 0);
    }

  Mustek_SendData (chip, ES01_1B0_SEGMENT_PIXEL_NUMBER_LB,
		   LOBYTE (ValidPixelNumber));
  Mustek_SendData (chip, ES01_1B1_SEGMENT_PIXEL_NUMBER_HB,
		   HIBYTE (ValidPixelNumber));

  Mustek_SendData (chip, ES01_169_NUMBER_OF_SEGMENT_PIXEL_LB,
		   LOBYTE (ValidPixelNumber));
  Mustek_SendData (chip, ES01_16A_NUMBER_OF_SEGMENT_PIXEL_HB,
		   HIBYTE (ValidPixelNumber));
  Mustek_SendData (chip, ES01_16B_BETWEEN_SEGMENT_INVALID_PIXEL, 0);

  Mustek_SendData (chip, ES01_B6_LineWidthPixelLSB, LOBYTE (ValidPixelNumber));
  Mustek_SendData (chip, ES01_B7_LineWidthPixelMSB, HIBYTE (ValidPixelNumber));

  Mustek_SendData (chip, ES01_19A_CHANNEL_LINE_GAP_LB,
		   LOBYTE (ValidPixelNumber));
  Mustek_SendData (chip, ES01_19B_CHANNEL_LINE_GAP_HB,
		   HIBYTE (ValidPixelNumber));
  DBG (DBG_ASIC, "ValidPixelNumber=%d\n", ValidPixelNumber);

  for (i = 0; i < 36; i++)
    Mustek_SendData (chip, 0x270 + i, 0);

  Mustek_SendData (chip, 0x270, BYTE0 (ValidPixelNumber * 2));
  Mustek_SendData (chip, 0x271, BYTE1 (ValidPixelNumber * 2));
  Mustek_SendData (chip, 0x272, BYTE2 (ValidPixelNumber * 2));

  Mustek_SendData (chip, 0x27C, BYTE0 (ValidPixelNumber * 4));
  Mustek_SendData (chip, 0x27D, BYTE1 (ValidPixelNumber * 4));
  Mustek_SendData (chip, 0x27E, BYTE2 (ValidPixelNumber * 4));

  Mustek_SendData (chip, 0x288, BYTE0 (ValidPixelNumber * 6));
  Mustek_SendData (chip, 0x289, BYTE1 (ValidPixelNumber * 6));
  Mustek_SendData (chip, 0x28A, BYTE2 (ValidPixelNumber * 6));
  DBG (DBG_ASIC, "channel gap=%d\n", ValidPixelNumber * 2);


  Mustek_SendData (chip, ES01_B4_StartPixelLSB, LOBYTE (wX));
  Mustek_SendData (chip, ES01_B5_StartPixelMSB, HIBYTE (wX));


  Mustek_SendData (chip, ES01_1B9_LINE_PIXEL_NUMBER_LB,
		   LOBYTE (XRatioTypeDouble * (ValidPixelNumber - 1)));
  Mustek_SendData (chip, ES01_1BA_LINE_PIXEL_NUMBER_HB,
		   HIBYTE (XRatioTypeDouble * (ValidPixelNumber - 1)));

  /* final start read out pixel */
  Mustek_SendData (chip, ES01_1F4_START_READ_OUT_PIXEL_LB, 0);
  Mustek_SendData (chip, ES01_1F5_START_READ_OUT_PIXEL_HB, 0);

  if (wWidth > (ValidPixelNumber - 10))
    DBG (DBG_ERR, "read out pixel greater than max pixel! image will shift!\n");

  /* final read pixel width */
  Mustek_SendData (chip, ES01_1F6_READ_OUT_PIXEL_LENGTH_LB,
		   LOBYTE (wWidth + 9));
  Mustek_SendData (chip, ES01_1F7_READ_OUT_PIXEL_LENGTH_HB,
		   HIBYTE (wWidth + 9));

  /* data output sequence */
  Mustek_SendData (chip, ES01_1F8_PACK_CHANNEL_SELECT_B0, 0);
  Mustek_SendData (chip, ES01_1F9_PACK_CHANNEL_SELECT_B1, 0);
  Mustek_SendData (chip, ES01_1FA_PACK_CHANNEL_SELECT_B2, 0x18);

  Mustek_SendData (chip, ES01_1FB_PACK_CHANNEL_SIZE_B0,
		   BYTE0 (ValidPixelNumber * 2));
  Mustek_SendData (chip, ES01_1FC_PACK_CHANNEL_SIZE_B1,
		   BYTE1 (ValidPixelNumber * 2));
  Mustek_SendData (chip, ES01_1FD_PACK_CHANNEL_SIZE_B2,
		   BYTE2 (ValidPixelNumber * 2));

  Mustek_SendData (chip, ES01_16C_LINE_SHIFT_OUT_TIMES_DIRECTION, 0x01);
  Mustek_SendData (chip, ES01_1CD_DUMMY_CLOCK_NUMBER, 0);
  Mustek_SendData (chip, ES01_1CE_LINE_SEGMENT_NUMBER, 0x00);
  Mustek_SendData (chip, ES01_D8_PHTG_EDGE_TIMING_ADJUST, 0x17);

  Mustek_SendData (chip, ES01_D9_CLEAR_PULSE_WIDTH, bClearPulseWidth);

  Mustek_SendData (chip, ES01_DA_CLEAR_SIGNAL_INVERTING_OUTPUT, 0x54 | 0x01);
  Mustek_SendData (chip, ES01_CD_TG_R_CONTROL, 0x3C);
  Mustek_SendData (chip, ES01_CE_TG_G_CONTROL, 0);
  Mustek_SendData (chip, ES01_CF_TG_B_CONTROL, 0x3C);


  /* set pack area address */
  DBG (DBG_ASIC, "PackAreaStartAddress=%d\n", PackAreaStartAddress);

  Mustek_SendData (chip, ES01_16D_EXPOSURE_CYCLE1_SEGMENT1_START_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress));
  Mustek_SendData (chip, ES01_16E_EXPOSURE_CYCLE1_SEGMENT1_START_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress));
  Mustek_SendData (chip, ES01_16F_EXPOSURE_CYCLE1_SEGMENT1_START_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress));

  for ( i = ES01_170_EXPOSURE_CYCLE1_SEGMENT2_START_ADDR_BYTE0;
       i <= ES01_18E_EXPOSURE_CYCLE3_SEGMENT4_START_ADDR_BYTE0; i += 3)
    {
      Mustek_SendData (chip, i, BYTE0 (PackAreaStartAddress + 0xC0000));
      Mustek_SendData (chip, i + 1, BYTE1 (PackAreaStartAddress + 0xC0000));
      Mustek_SendData (chip, i + 2, BYTE2 (PackAreaStartAddress + 0xC0000));
    }

  DBG (DBG_ASIC, "set PackAreaStartAddress finished\n");

  for (i = 0; i < 16; i++)
    Mustek_SendData (chip, 0x260 + i, 0);
  DBG (DBG_ASIC, "Set Invalid Pixel finished\n");


  /* set pack start address */
  Mustek_SendData (chip, ES01_19E_PACK_AREA_R_START_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress));
  Mustek_SendData (chip, ES01_19F_PACK_AREA_R_START_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress));
  Mustek_SendData (chip, ES01_1A0_PACK_AREA_R_START_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress));

  Mustek_SendData (chip, ES01_1A1_PACK_AREA_G_START_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress + (ValidPixelNumber * 2)));
  Mustek_SendData (chip, ES01_1A2_PACK_AREA_G_START_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress + (ValidPixelNumber * 2)));
  Mustek_SendData (chip, ES01_1A3_PACK_AREA_G_START_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress + (ValidPixelNumber * 2)));

  Mustek_SendData (chip, ES01_1A4_PACK_AREA_B_START_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress + (ValidPixelNumber * 4)));
  Mustek_SendData (chip, ES01_1A5_PACK_AREA_B_START_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress + (ValidPixelNumber * 4)));
  Mustek_SendData (chip, ES01_1A6_PACK_AREA_B_START_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress + (ValidPixelNumber * 4)));

  /* set pack end address */
  Mustek_SendData (chip, ES01_1A7_PACK_AREA_R_END_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress + (ValidPixelNumber * 2 - 1)));
  Mustek_SendData (chip, ES01_1A8_PACK_AREA_R_END_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress + (ValidPixelNumber * 2 - 1)));
  Mustek_SendData (chip, ES01_1A9_PACK_AREA_R_END_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress + (ValidPixelNumber * 2 - 1)));

  Mustek_SendData (chip, ES01_1AA_PACK_AREA_G_END_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress + (ValidPixelNumber * 4 - 1)));
  Mustek_SendData (chip, ES01_1AB_PACK_AREA_G_END_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress + (ValidPixelNumber * 4 - 1)));
  Mustek_SendData (chip, ES01_1AC_PACK_AREA_G_END_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress + (ValidPixelNumber * 4 - 1)));

  Mustek_SendData (chip, ES01_1AD_PACK_AREA_B_END_ADDR_BYTE0,
		   BYTE0 (PackAreaStartAddress + (ValidPixelNumber * 6 - 1)));
  Mustek_SendData (chip, ES01_1AE_PACK_AREA_B_END_ADDR_BYTE1,
		   BYTE1 (PackAreaStartAddress + (ValidPixelNumber * 6 - 1)));
  Mustek_SendData (chip, ES01_1AF_PACK_AREA_B_END_ADDR_BYTE2,
		   BYTE2 (PackAreaStartAddress + (ValidPixelNumber * 6 - 1)));
  DBG (DBG_ASIC, "PackAreaStartAddress + (ValidPixelNumber*2)=%d\n",
       (PackAreaStartAddress + (ValidPixelNumber * 2)));

  Mustek_SendData (chip, ES01_19C_MAX_PACK_LINE, 2);
  Mustek_SendData (chip, ES01_19D_PACK_THRESHOLD_LINE, 1);

  if (pValidPixelNumber)
    *pValidPixelNumber = ValidPixelNumber;

  DBG (DBG_ASIC, "SetPackAddress: Exit\n");
}

static void
SetExtraSettings (PAsic chip, unsigned short wXResolution,
		  unsigned short wCCD_PixelNumber, SANE_Bool bypassShading)
{
  SANE_Byte temp_ff_register = 0;

  DBG (DBG_ASIC, "SetExtraSettings: Enter\n");

  Mustek_SendData (chip, ES01_B8_ChannelRedExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelR_StartPixel));
  Mustek_SendData (chip, ES01_B9_ChannelRedExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelR_StartPixel));
  Mustek_SendData (chip, ES01_BA_ChannelRedExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelR_EndPixel));
  Mustek_SendData (chip, ES01_BB_ChannelRedExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelR_EndPixel));

  Mustek_SendData (chip, ES01_BC_ChannelGreenExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelG_StartPixel));
  Mustek_SendData (chip, ES01_BD_ChannelGreenExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelG_StartPixel));
  Mustek_SendData (chip, ES01_BE_ChannelGreenExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelG_EndPixel));
  Mustek_SendData (chip, ES01_BF_ChannelGreenExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelG_EndPixel));

  Mustek_SendData (chip, ES01_C0_ChannelBlueExpStartPixelLSB,
		   LOBYTE (chip->Timing.ChannelB_StartPixel));
  Mustek_SendData (chip, ES01_C1_ChannelBlueExpStartPixelMSB,
		   HIBYTE (chip->Timing.ChannelB_StartPixel));
  Mustek_SendData (chip, ES01_C2_ChannelBlueExpEndPixelLSB,
		   LOBYTE (chip->Timing.ChannelB_EndPixel));
  Mustek_SendData (chip, ES01_C3_ChannelBlueExpEndPixelMSB,
		   HIBYTE (chip->Timing.ChannelB_EndPixel));

  Mustek_SendData (chip, ES01_B2_PHTGPulseWidth, chip->Timing.PHTG_PulseWidth);
  Mustek_SendData (chip, ES01_B3_PHTGWaitWidth, chip->Timing.PHTG_WaitWidth);

  Mustek_SendData (chip, ES01_CC_PHTGTimingAdjust,
		   chip->Timing.PHTG_TimingAdj);
  Mustek_SendData (chip, ES01_D0_PH1_0, chip->Timing.PHTG_TimingSetup);

  DBG (DBG_ASIC, "ChannelR_StartPixel=%d,ChannelR_EndPixel=%d\n",
       chip->Timing.ChannelR_StartPixel, chip->Timing.ChannelR_EndPixel);

  if (wXResolution == SENSOR_DPI)
    Mustek_SendData (chip, ES01_DE_CCD_SETUP_REGISTER, EVEN_ODD_ENABLE_ES01);
  else
    Mustek_SendData (chip, ES01_DE_CCD_SETUP_REGISTER, 0);

  temp_ff_register |= BYPASS_PRE_GAMMA_ENABLE;
  temp_ff_register |= BYPASS_CONVOLUTION_ENABLE;
  temp_ff_register |= BYPASS_MATRIX_ENABLE;
  temp_ff_register |= BYPASS_GAMMA_ENABLE;

  if (bypassShading)
    {
      temp_ff_register |= BYPASS_DARK_SHADING_ENABLE;
      temp_ff_register |= BYPASS_WHITE_SHADING_ENABLE;
    }

  Mustek_SendData (chip, ES01_FF_SCAN_IMAGE_OPTION, temp_ff_register);
  DBG (DBG_ASIC, "FF_SCAN_IMAGE_OPTION=0x%x\n", temp_ff_register);

  /* pixel process time */
  Mustek_SendData (chip, ES01_B0_CCDPixelLSB, LOBYTE (wCCD_PixelNumber));
  Mustek_SendData (chip, ES01_B1_CCDPixelMSB, HIBYTE (wCCD_PixelNumber));
  Mustek_SendData (chip, ES01_DF_ICG_CONTROL,
		   BEFORE_PHRS_416_1t_ns | ICG_UNIT_4_PIXEL_TIME);
  DBG (DBG_ASIC, "wCCD_PixelNumber=%d\n", wCCD_PixelNumber);

  Mustek_SendData (chip, ES01_88_LINE_ART_THRESHOLD_HIGH_VALUE, 128);
  Mustek_SendData (chip, ES01_89_LINE_ART_THRESHOLD_LOW_VALUE, 127);

  usleep (50000);

  DBG (DBG_ASIC, "SetExtraSettings: Exit\n");
}


/* ---------------------- high level ASIC functions ------------------------ */

/* HOLD: We don't want to have global vid/pids */
static const unsigned short ProductID = 0x0409;
static const unsigned short VendorID = 0x055f;

SANE_String_Const device_name;

static SANE_Status
attach_one_scanner (SANE_String_Const devname)
{
  DBG (DBG_INFO, "attach_one_scanner: devname = %s\n", devname);
  device_name = devname;
  return SANE_STATUS_GOOD;
}

static SANE_Status
Asic_Open (PAsic chip)
{
  SANE_Status status;

  DBG (DBG_ASIC, "Asic_Open: Enter\n");

  if (chip->firmwarestate > FS_OPENED)
    {
      DBG (DBG_ASIC, "chip has been opened. fd=%d\n", chip->fd);
      return SANE_STATUS_INVAL;
    }

  device_name = NULL;
  sanei_usb_init ();
  status = sanei_usb_find_devices (VendorID, ProductID, attach_one_scanner);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_Open: sanei_usb_find_devices failed: %s\n",
	   sane_strstatus (status));
      return status;
    }
  if (!device_name)
    {
      DBG (DBG_ERR, "Asic_Open: no scanner found\n");
      return SANE_STATUS_INVAL;
    }

  status = sanei_usb_open (device_name, &chip->fd);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_Open: sanei_usb_open of %s failed: %s\n",
	   device_name, sane_strstatus (status));
      return status;
    }

  status = OpenScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ASIC, "Asic_Open: OpenScanChip error\n");
      sanei_usb_close (chip->fd);
      return status;
    }

  Mustek_SendData (chip, ES01_94_PowerSaveControl,
		   TIMER_POWER_SAVE_ENABLE |
		   USB_POWER_SAVE_ENABLE | USB_REMOTE_WAKEUP_ENABLE |
		   LED_MODE_FLASH_SLOWLY);
  Mustek_SendData (chip, ES01_86_DisableAllClockWhenIdle, 0);
  Mustek_SendData (chip, ES01_79_AFEMCLK_SDRAMCLK_DELAY_CONTROL,
		   SDRAMCLK_DELAY_12_ns);

  /* SDRAM initialization sequence */
  Mustek_SendData (chip, ES01_87_SDRAM_Timing, 0xf1);
  Mustek_SendData (chip, ES01_87_SDRAM_Timing, 0xa5);
  Mustek_SendData (chip, ES01_87_SDRAM_Timing, 0x91);
  Mustek_SendData (chip, ES01_87_SDRAM_Timing, 0x81);
  Mustek_SendData (chip, ES01_87_SDRAM_Timing, 0xf0);

  chip->firmwarestate = FS_OPENED;

  status = WaitUnitReady (chip);
  if (status != SANE_STATUS_GOOD)
    {
      sanei_usb_close (chip->fd);
      return status;
    }

  status = SafeInitialChip (chip);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_Open: SafeInitialChip error\n");
      sanei_usb_close (chip->fd);
      return status;
    }

  DBG (DBG_INFO, "Asic_Open: device %s successfully opened\n", device_name);
  DBG (DBG_ASIC, "Asic_Open: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
Asic_Close (PAsic chip)
{
  SANE_Status status;
  DBG (DBG_ASIC, "Asic_Close: Enter\n");

  if (chip->firmwarestate < FS_OPENED)
    {
      DBG (DBG_ASIC, "Asic_Close: Scanner is not opened\n");
      return SANE_STATUS_GOOD;
    }
  if (chip->firmwarestate > FS_OPENED)
    {
      DBG (DBG_ASIC,
	   "Asic_Close: Scanner is scanning, trying to stop scanning\n");
      Asic_ScanStop (chip);
    }

  Mustek_SendData (chip, ES01_86_DisableAllClockWhenIdle,
		   CLOSE_ALL_CLOCK_ENABLE);

  status = CloseScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    DBG (DBG_ERR, "Asic_Close: CloseScanChip error\n");

  sanei_usb_close (chip->fd);

  chip->firmwarestate = FS_ATTACHED;

  DBG (DBG_ASIC, "Asic_Close: Exit\n");
  return status;
}

static void
Asic_Initialize (PAsic chip)
{
  DBG (DBG_ASIC, "Asic_Initialize: Enter\n");

  DBG (DBG_ASIC, "isFirstOpenChip=%d, setting to SANE_TRUE\n",
       chip->isFirstOpenChip);
  chip->isFirstOpenChip = SANE_TRUE;

  chip->UsbHost = HT_USB10;
  chip->dwBytesCountPerRow = 0;
  chip->isMotorMoveToFirstLine = MOTOR_MOVE_TO_FIRST_LINE_ENABLE;
  chip->lpShadingTable = NULL;

  InitTiming (chip);

  chip->firmwarestate = FS_ATTACHED;

  DBG (DBG_ASIC, "Asic_Initialize: Exit\n");
}

static SANE_Status
Asic_TurnLamp (PAsic chip, SANE_Bool isLampOn)
{
  DBG (DBG_ASIC, "Asic_TurnLamp: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_TurnLamp: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  Mustek_SendData (chip, ES01_99_LAMP_PWM_FREQ_CONTROL, 1);
  if (isLampOn)
    Mustek_SendData (chip, ES01_90_Lamp0PWM, LAMP0_PWM_DEFAULT);
  else
    Mustek_SendData (chip, ES01_90_Lamp0PWM, 0);

  DBG (DBG_ASIC, "Asic_TurnLamp: Exit\n");
  return SANE_STATUS_GOOD;
}


static SANE_Status
Asic_TurnTA (PAsic chip, SANE_Bool isTAOn)
{
  DBG (DBG_ASIC, "Asic_TurnTA: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_TurnTA: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  Mustek_SendData (chip, ES01_99_LAMP_PWM_FREQ_CONTROL, 1);
  if (isTAOn)
    Mustek_SendData (chip, ES01_91_Lamp1PWM, LAMP1_PWM_DEFAULT);
  else
    Mustek_SendData (chip, ES01_91_Lamp1PWM, 0);

  DBG (DBG_ASIC, "Asic_TurnTA: Exit\n");
  return SANE_STATUS_GOOD;
}


static SANE_Byte
GetBytePerPixel (SANE_Byte bBitPerPixel)
{
  switch (bBitPerPixel)
    {
    case 48:
      return 6;
    case 24:
      return 3;
    case 16:
      return 2;
    case 8:
    default:
      return 1;
    }
}

static SANE_Byte
GetDummyCycleNumber (PAsic chip, unsigned short wYResolution,
		     SCANSOURCE lsLightSource)
{
  SANE_Byte bDummyCycleNum = 0;
  if (lsLightSource == SS_Reflective)
    {
      if (chip->UsbHost == HT_USB10)
        {
          switch (wYResolution)
            {
	    case 2400:
	    case 1200:
	      if (chip->dwBytesCountPerRow > 22000)
	        bDummyCycleNum = 4;
	      else if (chip->dwBytesCountPerRow > 15000)
	        bDummyCycleNum = 3;
	      else if (chip->dwBytesCountPerRow > 10000)
	        bDummyCycleNum = 2;
	      else if (chip->dwBytesCountPerRow > 5000)
	        bDummyCycleNum = 1;
	      break;
	    case 600:
	    case 300:
	    case 150:
	    case 100:
	      if (chip->dwBytesCountPerRow > 21000)
	        bDummyCycleNum = 7;
	      else if (chip->dwBytesCountPerRow > 18000)
	        bDummyCycleNum = 6;
	      else if (chip->dwBytesCountPerRow > 15000)
	        bDummyCycleNum = 5;
	      else if (chip->dwBytesCountPerRow > 12000)
	        bDummyCycleNum = 4;
	      else if (chip->dwBytesCountPerRow > 9000)
	        bDummyCycleNum = 3;
	      else if (chip->dwBytesCountPerRow > 6000)
	        bDummyCycleNum = 2;
	      else if (chip->dwBytesCountPerRow > 3000)
	        bDummyCycleNum = 1;
	      break;
	    case 75:
	    case 50:
	      bDummyCycleNum = 1;
	      break;
	    }
	}
      else
	{
	  switch (wYResolution)
	    {
	    case 2400:
	    case 1200:
	    case 75:
	    case 50:
	      bDummyCycleNum = 1;
	      break;
	    }
	}
    }
  return bDummyCycleNum;
}

static SANE_Status
Asic_SetWindow (PAsic chip, SCANSOURCE lsLightSource,
		SANE_Byte bScanType, SANE_Byte bScanBits,
		unsigned short wXResolution, unsigned short wYResolution,
		unsigned short wX, unsigned short wY,
		unsigned short wWidth, unsigned short wLength)
{
  SANE_Status status;
  unsigned short ValidPixelNumber;
  unsigned short wThinkCCDResolution;
  unsigned short wCCD_PixelNumber;
  unsigned short XRatioTypeWord;
  double XRatioTypeDouble;
  double XRatioAdderDouble;
  LLF_MOTORMOVE lpMotorStepsTable;
  SANE_Byte bDummyCycleNum;
  unsigned short wMultiMotorStep;
  SANE_Byte bMotorMoveType;
  unsigned int dwLinePixelReport;
  unsigned int StartSpeed, EndSpeed;
  LLF_CALCULATEMOTORTABLE CalMotorTable;
  LLF_MOTOR_CURRENT_AND_PHASE CurrentPhase;
  unsigned int dwTableBaseAddr, dwEndAddr;
  SANE_Byte isMotorMove;
  SANE_Byte isMotorMoveToFirstLine;
  SANE_Byte isUniformSpeedToScan;
  SANE_Byte isScanBackTracking;
  unsigned short * lpMotorTable;
  unsigned int RealTableSize;
  unsigned short wFullBank;

  DBG (DBG_ASIC, "Asic_SetWindow: Enter\n");
  DBG (DBG_ASIC, "lsLightSource=%d,bScanType=%d,bScanBits=%d," \
		 "wXResolution=%d,wYResolution=%d,wX=%d,wY=%d," \
		 "wWidth=%d,wLength=%d\n",
       lsLightSource, bScanType, bScanBits, wXResolution, wYResolution, wX, wY,
       wWidth, wLength);

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_SetWindow: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  status = PrepareScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  /* LED flash */
  Mustek_SendData (chip, ES01_94_PowerSaveControl,
		   TIMER_POWER_SAVE_ENABLE |
		   USB_POWER_SAVE_ENABLE | USB_REMOTE_WAKEUP_ENABLE |
		   LED_MODE_FLASH_SLOWLY | 0x40 | 0x80);

  /* calculate byte per line */
  chip->dwBytesCountPerRow = (unsigned int) wWidth *
			     GetBytePerPixel (bScanBits);
  DBG (DBG_ASIC, "dwBytesCountPerRow=%d\n", chip->dwBytesCountPerRow);

  if (bScanType == SCAN_TYPE_NORMAL)
    bDummyCycleNum = GetDummyCycleNumber (chip, wYResolution, lsLightSource);
  else
    bDummyCycleNum = 1;

  SetCCDTiming (chip);

  if (wXResolution > (SENSOR_DPI / 2))
    {
      wThinkCCDResolution = SENSOR_DPI;
      Mustek_SendData (chip, ES01_98_GPIOControl8_15, 0x01);
      Mustek_SendData (chip, ES01_96_GPIOValue8_15, 0x01);
    }
  else
    {
      wThinkCCDResolution = SENSOR_DPI / 2;
      Mustek_SendData (chip, ES01_98_GPIOControl8_15, 0x01);
      Mustek_SendData (chip, ES01_96_GPIOValue8_15, 0x00);
    }

  if (lsLightSource == SS_Reflective)
    {
      if (wXResolution > (SENSOR_DPI / 2))
        wCCD_PixelNumber = chip->Timing.wCCDPixelNumber_Full;
      else
        wCCD_PixelNumber = chip->Timing.wCCDPixelNumber_Half;
    }
  else
    {
      if (bScanType == SCAN_TYPE_NORMAL)
	wCCD_PixelNumber = TA_IMAGE_PIXELNUMBER;
      else
	wCCD_PixelNumber = TA_CAL_PIXELNUMBER;
    }

  SetLineTimeAndExposure (chip);
  Mustek_SendData (chip, ES01_CB_CCDDummyCycleNumber, bDummyCycleNum);
  SetLEDTime (chip);

  Mustek_SendData (chip, ES01_74_HARDWARE_SETTING,
		   MOTOR1_SERIAL_INTERFACE_G10_8_ENABLE);

  Mustek_SendData (chip, ES01_9A_AFEControl, AD9826_AFE);
  if (bScanType == SCAN_TYPE_NORMAL)
    SetAFEGainOffset (chip);
  Mustek_SendData (chip, ES01_DB_PH_RESET_EDGE_TIMING_ADJUST, 0x00);
  Mustek_SendData (chip, ES01_DC_CLEAR_EDGE_TO_PH_TG_EDGE_WIDTH, 0);
  Mustek_SendData (chip, ES01_00_ADAFEConfiguration, 0x70);
  Mustek_SendData (chip, ES01_02_ADAFEMuxConfig, 0x80);

  Mustek_SendData (chip, ES01_F7_DigitalControl, 0);

  /* calculate X ratio */
  XRatioTypeDouble = (double) wXResolution / wThinkCCDResolution;
  XRatioTypeWord = (unsigned short) (XRatioTypeDouble * 32768);
  XRatioAdderDouble = 1 / XRatioTypeDouble;

  /* 32768 = 1.00000 -> get all pixel */
  Mustek_SendData (chip, ES01_9E_HorizontalRatio1to15LSB,
		   LOBYTE (XRatioTypeWord));
  Mustek_SendData (chip, ES01_9F_HorizontalRatio1to15MSB,
		   HIBYTE (XRatioTypeWord));
  DBG (DBG_ASIC,
       "XRatioTypeDouble=%.2f,XRatioAdderDouble=%.2f,XRatioTypeWord=%d\n",
       XRatioTypeDouble, XRatioAdderDouble, XRatioTypeWord);

  /* set motor type */
  if (bScanType == SCAN_TYPE_CALIBRATE_DARK)
    isMotorMove = 0;
  else
    isMotorMove = MOTOR_0_ENABLE;
  Mustek_SendData (chip, ES01_A6_MotorOption,
		   isMotorMove | HOME_SENSOR_0_ENABLE | TABLE_DEFINE_ES03);
  Mustek_SendData (chip, ES01_F6_MotorControl1,
		   SPEED_UNIT_1_PIXEL_TIME | MOTOR_SYNC_UNIT_1_PIXEL_TIME);

  if ((bScanType == SCAN_TYPE_NORMAL) && (wYResolution >= SENSOR_DPI))
    bMotorMoveType = _8_TABLE_SPACE_FOR_1_DIV_2_STEP;
  else
    bMotorMoveType = _4_TABLE_SPACE_FOR_FULL_STEP;

  switch (bMotorMoveType)
    {
    default:
    case _4_TABLE_SPACE_FOR_FULL_STEP:
      wMultiMotorStep = 1;
      break;
    case _8_TABLE_SPACE_FOR_1_DIV_2_STEP:
      wMultiMotorStep = 2;
      break;
    case _16_TABLE_SPACE_FOR_1_DIV_4_STEP:
      wMultiMotorStep = 4;
      break;
    case _32_TABLE_SPACE_FOR_1_DIV_8_STEP:
      wMultiMotorStep = 8;
      break;
    }
  wY *= wMultiMotorStep;

  SetScanMode (chip, bScanBits);

  if (lsLightSource == SS_Reflective)
    Mustek_SendData (chip, ES01_F8_WHITE_SHADING_DATA_FORMAT,
		     SHADING_3_INT_13_DEC_ES01);
  else
    Mustek_SendData (chip, ES01_F8_WHITE_SHADING_DATA_FORMAT,
		     SHADING_4_INT_12_DEC_ES01);

  SetPackAddress (chip, wWidth, wX, XRatioAdderDouble,
		  XRatioTypeDouble, 0, &ValidPixelNumber);
  SetExtraSettings (chip, wXResolution, wCCD_PixelNumber,
		    (bScanType == SCAN_TYPE_NORMAL) ? SANE_FALSE : SANE_TRUE);

  if (bScanType == SCAN_TYPE_NORMAL)
    {
      SetMotorStepTable (chip, &lpMotorStepsTable, wY,
			 wLength * SENSOR_DPI / wYResolution * wMultiMotorStep,
			 wYResolution);
    }
  else
    {
      SetMotorStepTableForCalibration (chip, &lpMotorStepsTable,
			 wLength * SENSOR_DPI / wYResolution * wMultiMotorStep);
    }

  /* calculate line time */
  dwLinePixelReport = (2 + (chip->Timing.PHTG_PulseWidth + 1) +
		       (chip->Timing.PHTG_WaitWidth + 1) +
		       (wCCD_PixelNumber + 1)) * (bDummyCycleNum + 1);

  EndSpeed = (dwLinePixelReport * wYResolution / SENSOR_DPI) / wMultiMotorStep;
  DBG (DBG_ASIC, "Motor Time = %d\n", EndSpeed);
  if (EndSpeed > 0xffff)
    {
      DBG (DBG_ASIC, "Motor Time overflow!\n");
      return SANE_STATUS_INVAL;
    }

  isMotorMoveToFirstLine = chip->isMotorMoveToFirstLine;
  isUniformSpeedToScan = UNIFORM_MOTOR_AND_SCAN_SPEED_ENABLE;
  isScanBackTracking = 0;
  if (bScanType == SCAN_TYPE_NORMAL)
    {
      if (EndSpeed >= 20000)
	{
	  status = Asic_MotorMove (chip, 1, wY / wMultiMotorStep);
	  if (status != SANE_STATUS_GOOD)
	    return status;

	  isMotorMoveToFirstLine = 0;
	}
      else
	{
	  isUniformSpeedToScan = 0;
	  isScanBackTracking = SCAN_BACK_TRACKING_ENABLE;
	}
    }
  Mustek_SendData (chip, ES01_F3_ActionOption, isMotorMoveToFirstLine |
		   SCAN_ENABLE | isScanBackTracking | isUniformSpeedToScan);

  if (EndSpeed > 8000)
    {
      StartSpeed = EndSpeed;
    }
  else
    {
      if (EndSpeed <= 1000)
        StartSpeed = EndSpeed + 4500;
      else
        StartSpeed = EndSpeed + 3500;
    }
  DBG (DBG_ASIC, "StartSpeed=%d, EndSpeed=%d\n", StartSpeed, EndSpeed);

  Mustek_SendData (chip, ES01_FD_MotorFixedspeedLSB, LOBYTE (EndSpeed));
  Mustek_SendData (chip, ES01_FE_MotorFixedspeedMSB, HIBYTE (EndSpeed));

  lpMotorTable = malloc (MOTOR_TABLE_SIZE * sizeof (unsigned short));
  if (!lpMotorTable)
    {
      DBG (DBG_ERR, "Asic_SetWindow: lpMotorTable == NULL\n");
      return SANE_STATUS_NO_MEM;
    }
  memset (lpMotorTable, 0, MOTOR_TABLE_SIZE * sizeof (unsigned short));

  CalMotorTable.StartSpeed = StartSpeed;
  CalMotorTable.EndSpeed = EndSpeed;
  CalMotorTable.AccStepBeforeScan = lpMotorStepsTable.wScanAccSteps;
  CalMotorTable.DecStepAfterScan = lpMotorStepsTable.bScanDecSteps;
  CalMotorTable.lpMotorTable = lpMotorTable;
  if (bScanType == SCAN_TYPE_NORMAL)
    CalculateScanMotorTable (&CalMotorTable);
  else
    CalculateMoveMotorTable (&CalMotorTable);

  CurrentPhase.MoveType = bMotorMoveType;
  CurrentPhase.MotorDriverIs3967 = 0;
  if (bScanType == SCAN_TYPE_NORMAL)
    CurrentPhase.MotorCurrent = CalculateMotorCurrent (EndSpeed);
  else
    CurrentPhase.MotorCurrent = 200;
  LLFSetMotorCurrentAndPhase (chip, &CurrentPhase);

  DBG (DBG_ASIC, "MotorCurrent=%d, LinePixelReport=%d\n",
       CurrentPhase.MotorCurrent, dwLinePixelReport);

  /* write motor table */
  RealTableSize = MOTOR_TABLE_SIZE;
  dwTableBaseAddr = PackAreaStartAddress - RealTableSize;
  status = LLFSetMotorTable (chip, dwTableBaseAddr, lpMotorTable);
  free (lpMotorTable);
  if (status != SANE_STATUS_GOOD)
    return status;

  if (bScanType == SCAN_TYPE_NORMAL)
    {
      /* set image buffer range and write shading table */
      RealTableSize += ShadingTableSize (ValidPixelNumber);
      dwTableBaseAddr = PackAreaStartAddress -
			((RealTableSize + (TABLE_BASE_SIZE - 1)) &
			 ~(TABLE_BASE_SIZE - 1));

      /* TODO: table size should be stored in Asic structure */
      RealTableSize = sizeof (unsigned short) *
	ShadingTableSize ((int) ((wWidth + 4) * XRatioAdderDouble));
      status = LLFSetShadingTable (chip, dwTableBaseAddr, RealTableSize,
				   chip->lpShadingTable);
      if (status != SANE_STATUS_GOOD)
	return status;
    }

  dwEndAddr = dwTableBaseAddr - 1;

  /* empty bank */
  Mustek_SendData (chip, ES01_FB_BufferEmptySize16WordLSB,
		   LOBYTE (WaitBufferOneLineSize >> 4));
  Mustek_SendData (chip, ES01_FC_BufferEmptySize16WordMSB,
		   HIBYTE (WaitBufferOneLineSize >> 4));

  /* full bank */
  wFullBank = (unsigned short)
  	      ((dwEndAddr - ((chip->dwBytesCountPerRow / 2) * 3)) / BANK_SIZE);
  Mustek_SendData (chip, ES01_F9_BufferFullSize16WordLSB, LOBYTE (wFullBank));
  Mustek_SendData (chip, ES01_FA_BufferFullSize16WordMSB, HIBYTE (wFullBank));

  status = LLFSetRamAddress (chip, 0, dwEndAddr, EXTERNAL_RAM);

  DBG (DBG_ASIC, "Asic_SetWindow: Exit\n");
  return status;
}

static SANE_Status
Asic_ScanStart (PAsic chip)
{
  SANE_Status status;
  DBG (DBG_ASIC, "Asic_ScanStart: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_ScanStart: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  status = GetChipStatus(chip, 0x1c | 0x20, NULL);
  if (status != SANE_STATUS_GOOD)
    return status;

  status = Mustek_ClearFIFO (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  Mustek_SendData (chip, ES01_F4_ActiveTrigger, ACTION_TRIGGER_ENABLE);

  chip->firmwarestate = FS_SCANNING;

  DBG (DBG_ASIC, "Asic_ScanStart: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
Asic_ScanStop (PAsic chip)
{
  SANE_Status status;
  SANE_Byte buf[4];

  DBG (DBG_ASIC, "Asic_ScanStop: Enter\n");

  if (chip->firmwarestate < FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_ScanStop: Scanner is not opened\n");
      return SANE_STATUS_INVAL;
    }
  if (chip->firmwarestate < FS_SCANNING)
    return SANE_STATUS_GOOD;

  usleep (100 * 1000);

  buf[0] = 0x02;	/* stop */
  buf[1] = 0x02;
  buf[2] = 0x02;
  buf[3] = 0x02;
  status = WriteIOControl (chip, 0xc0, 0, 4, buf);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_ScanStop: Stop scan error\n");
      return status;
    }

  buf[0] = 0x00;	/* clear */
  buf[1] = 0x00;
  buf[2] = 0x00;
  buf[3] = 0x00;
  status = WriteIOControl (chip, 0xc0, 0, 4, buf);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_ScanStop: Clear scan error\n");
      return status;
    }

  status = Mustek_DMARead (chip, 2, buf);
  if (status != SANE_STATUS_GOOD)
    {
      DBG (DBG_ERR, "Asic_ScanStop: DMARead error\n");
      return status;
    }

  status = PrepareScanChip (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  status = Mustek_ClearFIFO (chip);
  if (status != SANE_STATUS_GOOD)
    return status;

  chip->firmwarestate = FS_OPENED;

  DBG (DBG_ASIC, "Asic_ScanStop: Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
Asic_ReadImage (PAsic chip, SANE_Byte * pBuffer, unsigned short LinesCount)
{
  SANE_Status status;
  unsigned int dwXferBytes;

  DBG (DBG_ASIC, "Asic_ReadImage: Enter. LinesCount = %d\n", LinesCount);

  if (chip->firmwarestate != FS_SCANNING)
    {
      DBG (DBG_ERR, "Asic_ReadImage: Scanner is not scanning\n");
      return SANE_STATUS_INVAL;
    }

  dwXferBytes = (unsigned int) LinesCount * chip->dwBytesCountPerRow;
  if (dwXferBytes == 0)
    {
      DBG (DBG_ASIC, "Asic_ReadImage: dwXferBytes == 0\n");
      return SANE_STATUS_GOOD;
    }

  status = Mustek_DMARead (chip, dwXferBytes, pBuffer);

  DBG (DBG_ASIC, "Asic_ReadImage: Exit\n");
  return status;
}

#if SANE_UNUSED
static SANE_Status
Asic_CheckFunctionKey (PAsic chip, SANE_Byte * key)
{
  SANE_Status status;
  SANE_Byte bBuffer_1, bBuffer_2;

  DBG (DBG_ASIC, "Asic_CheckFunctionKey: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_CheckFunctionKey: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  Mustek_SendData (chip, ES01_97_GPIOControl0_7, 0x00);
  Mustek_SendData (chip, ES01_95_GPIOValue0_7, 0x17);
  Mustek_SendData (chip, ES01_98_GPIOControl8_15, 0x00);
  Mustek_SendData (chip, ES01_96_GPIOValue8_15, 0x08);

  status = GetChipStatus (chip, GPIO0_7, &bBuffer_1);
  if (status != SANE_STATUS_GOOD)
    return status;
  status = GetChipStatus (chip, GPIO8_15, &bBuffer_2);
  if (status != SANE_STATUS_GOOD)
    return status;

  bBuffer_1 = ~bBuffer1;
  bBuffer_2 = ~bBuffer2;

  if (bBuffer_1 & 0x10)
    *key = 1;	/* Scan key pressed */
  else if (bBuffer_1 & 0x01)
    *key = 2;	/* Copy key pressed */
  else if (bBuffer_1 & 0x04)
    *key = 3;	/* Fax key pressed */
  else if (bBuffer_2 & 0x08)
    *key = 4;	/* Email key pressed */
  else if (bBuffer_1 & 0x02)
    *key = 5;	/* Panel key pressed */
  else
    *key = 0;

  DBG (DBG_ASIC, "CheckFunctionKey=%d\n", *key);
  DBG (DBG_ASIC, "Asic_CheckFunctionKey: Exit\n");
  return SANE_STATUS_GOOD;
}
#endif

static SANE_Status
Asic_IsTAConnected (PAsic chip, SANE_Bool * hasTA)
{
  SANE_Status status;
  SANE_Byte bBuffer_1 = 0xff;

  DBG (DBG_ASIC, "Asic_IsTAConnected: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_IsTAConnected: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  Mustek_SendData (chip, ES01_97_GPIOControl0_7, 0x00);
  Mustek_SendData (chip, ES01_95_GPIOValue0_7, 0x00);
  Mustek_SendData (chip, ES01_98_GPIOControl8_15, 0x00);
  Mustek_SendData (chip, ES01_96_GPIOValue8_15, 0x00);

  status = GetChipStatus (chip, GPIO0_7, &bBuffer_1);
  if (status != SANE_STATUS_GOOD)
    return status;

  *hasTA = (~bBuffer_1 & 0x08) ? SANE_TRUE : SANE_FALSE;

  DBG (DBG_ASIC, "hasTA=%d\n", *hasTA);
  DBG (DBG_ASIC, "Asic_IsTAConnected(): Exit\n");
  return SANE_STATUS_GOOD;
}

static SANE_Status
Asic_ReadCalibrationData (PAsic chip, SANE_Byte * pBuffer,
			  unsigned int dwXferBytes, SANE_Byte bScanBits)
{
  SANE_Status status = SANE_STATUS_GOOD;
  SANE_Byte * pCalBuffer;
  unsigned int dwTotalReadData = 0;
  unsigned int dwReadImageData;

  DBG (DBG_ASIC, "Asic_ReadCalibrationData: Enter\n");

  if (chip->firmwarestate != FS_SCANNING)
    {
      DBG (DBG_ERR, "Asic_ReadCalibrationData: Scanner is not scanning\n");
      return SANE_STATUS_INVAL;
    }

  if (bScanBits == 24)
    {
      unsigned int i;

      pCalBuffer = malloc (dwXferBytes);
      if (!pCalBuffer)
	{
	  DBG (DBG_ERR, "Asic_ReadCalibrationData: Can't malloc bCalBuffer " \
			"memory\n");
	  return SANE_STATUS_NO_MEM;
	}

      while (dwTotalReadData < dwXferBytes)
	{
	  dwReadImageData = dwXferBytes - dwTotalReadData;
	  if (dwReadImageData > 65536)
	    dwReadImageData = 65536;

	  status = Mustek_DMARead (chip, dwReadImageData,
				   pCalBuffer + dwTotalReadData);
	  if (status != SANE_STATUS_GOOD)
	    break;
	  dwTotalReadData += dwReadImageData;
	}

      dwXferBytes /= 3;
      for (i = 0; i < dwXferBytes; i++)
	{
	  pBuffer[i] = pCalBuffer[i * 3];
	  pBuffer[dwXferBytes + i] = pCalBuffer[i * 3 + 1];
	  pBuffer[dwXferBytes * 2 + i] = pCalBuffer[i * 3 + 2];
	}
      free (pCalBuffer);
    }
  else if (bScanBits == 8)
    {
      while (dwTotalReadData < dwXferBytes)
	{
	  dwReadImageData = dwXferBytes - dwTotalReadData;
	  if (dwReadImageData > 65536)
	    dwReadImageData = 65536;

	  status = Mustek_DMARead (chip, dwReadImageData,
				   pBuffer + dwTotalReadData);
	  if (status != SANE_STATUS_GOOD)
	    break;
	  dwTotalReadData += dwReadImageData;
	}
    }

  DBG (DBG_ASIC, "Asic_ReadCalibrationData: Exit\n");
  return status;
}

static SANE_Status
Asic_MotorMove (PAsic chip, SANE_Bool isForward, unsigned int dwTotalSteps)
{
  SANE_Status status;
  SANE_Byte bActionType;

  DBG (DBG_ASIC, "Asic_MotorMove: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_MotorMove: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  bActionType = isForward ? ACTION_TYPE_FORWARD : ACTION_TYPE_BACKWARD;
  status = MotorMove (chip, 5000, 1800, 7000, 200, dwTotalSteps, bActionType);

  DBG (DBG_ASIC, "Asic_MotorMove: Exit\n");
  return status;
}

static SANE_Status
Asic_CarriageHome (PAsic chip)
{
  SANE_Status status;
  SANE_Bool LampHome;

  DBG (DBG_ASIC, "Asic_CarriageHome: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_CarriageHome: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  status = IsCarriageHome (chip, &LampHome);
  if (status != SANE_STATUS_GOOD)
    return status;

  if (!LampHome)
    status = MotorMove (chip, 5000, 1200, 3000, 220, 766,
			ACTION_TYPE_BACKTOHOME);

  DBG (DBG_ASIC, "Asic_CarriageHome: Exit\n");
  return status;
}

static SANE_Status
Asic_SetShadingTable (PAsic chip, unsigned short * lpWhiteShading,
		      unsigned short * lpDarkShading,
		      unsigned short wXResolution, unsigned short wWidth)
{
  unsigned short i, j, n;
  unsigned short wValidPixelNumber;
  double dbXRatioAdderDouble;
  unsigned int wShadingTableSize;

  DBG (DBG_ASIC, "Asic_SetShadingTable: Enter\n");

  if (chip->firmwarestate != FS_OPENED)
    {
      DBG (DBG_ERR, "Asic_SetShadingTable: Scanner is not opened or busy\n");
      return SANE_STATUS_INVAL;
    }

  if (wXResolution > (SENSOR_DPI / 2))
    dbXRatioAdderDouble = SENSOR_DPI / wXResolution;
  else
    dbXRatioAdderDouble = (SENSOR_DPI / 2) / wXResolution;

  wValidPixelNumber = (unsigned short) ((wWidth + 4) * dbXRatioAdderDouble);
  DBG (DBG_ASIC, "wValidPixelNumber = %d\n", wValidPixelNumber);

  /* Clear old shading table, if present.
     First 4 and last 5 elements of shading table cannot be used. */
  wShadingTableSize = ShadingTableSize (wValidPixelNumber) *
    sizeof (unsigned short);
  if (chip->lpShadingTable)
    free (chip->lpShadingTable);

  DBG (DBG_ASIC, "Allocating a new shading table, size=%d byte\n",
       wShadingTableSize);
  chip->lpShadingTable = malloc (wShadingTableSize);
  if (!chip->lpShadingTable)
    {
      DBG (DBG_ASIC, "lpShadingTable == NULL\n");
      return SANE_STATUS_NO_MEM;
    }

  n = 0;
  for (i = 0; i <= (wValidPixelNumber / 40); i++)
    {
      unsigned short numPixel = 40;
      if (i == (wValidPixelNumber / 40))
	numPixel = wValidPixelNumber % 40;

      for (j = 0; j < numPixel; j++)
	{
	  chip->lpShadingTable[i * 256 + j * 6] = lpDarkShading[n * 3];
	  chip->lpShadingTable[i * 256 + j * 6 + 2] = lpDarkShading[n * 3 + 1];
	  chip->lpShadingTable[i * 256 + j * 6 + 4] = lpDarkShading[n * 3 + 2];

	  chip->lpShadingTable[i * 256 + j * 6 + 1] = lpWhiteShading[n * 3];
	  chip->lpShadingTable[i * 256 + j * 6 + 3] = lpWhiteShading[n * 3 + 1];
	  chip->lpShadingTable[i * 256 + j * 6 + 5] = lpWhiteShading[n * 3 + 2];

	  if ((j % (unsigned short) dbXRatioAdderDouble) ==
		  (dbXRatioAdderDouble - 1))
	    n++;

	  if (i == 0 && j < 4 * dbXRatioAdderDouble)
	    n = 0;
	}
    }

  DBG (DBG_ASIC, "Asic_SetShadingTable: Exit\n");
  return SANE_STATUS_GOOD;
}