/* sane - Scanner Access Now Easy.

   Copyright (C) 2010-2013 Stéphane Voltz <stef.dev@free.fr>


   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, see <https://www.gnu.org/licenses/>.
*/

#define DEBUG_DECLARE_ONLY

#include "gl843_registers.h"
#include "gl843.h"
#include "test_settings.h"

#include <string>
#include <vector>

namespace genesys {
namespace gl843 {

/**
 * compute the step multiplier used
 */
static int gl843_get_step_multiplier(Genesys_Register_Set* regs)
{
    switch (regs->get8(REG_0x9D) & 0x0c) {
        case 0x04: return 2;
        case 0x08: return 4;
        default: return 1;
    }
}

/** @brief set all registers to default values .
 * This function is called only once at the beginning and
 * fills register startup values for registers reused across scans.
 * Those that are rarely modified or not modified are written
 * individually.
 * @param dev device structure holding register set to initialize
 */
static void
gl843_init_registers (Genesys_Device * dev)
{
    // Within this function SENSOR_DEF marker documents that a register is part
    // of the sensors definition and the actual value is set in
    // scanner_setup_sensor().

    // 0x6c, 0x6d, 0x6e, 0x6f, 0xa6, 0xa7, 0xa8, 0xa9 are defined in the Gpo sensor struct

    DBG_HELPER(dbg);

    dev->reg.clear();

    dev->reg.init_reg(0x01, 0x00);
    dev->reg.init_reg(0x02, 0x78);
    dev->reg.init_reg(0x03, 0x1f);
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x03, 0x1d);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x03, 0x1c);
    }

    dev->reg.init_reg(0x04, 0x10);
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x04, 0x22);
    }

    // fine tune upon device description
    dev->reg.init_reg(0x05, 0x80);
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
      dev->reg.init_reg(0x05, 0x08);
    }

    auto initial_scan_method = dev->model->default_method;
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        initial_scan_method = ScanMethod::TRANSPARENCY;
    }
    const auto& sensor = sanei_genesys_find_sensor_any(dev);
    const auto& dpihw_sensor = sanei_genesys_find_sensor(dev, sensor.full_resolution,
                                                         3, initial_scan_method);
    sanei_genesys_set_dpihw(dev->reg, dpihw_sensor.register_dpihw);

    // TODO: on 8600F the windows driver turns off GAIN4 which is recommended
    dev->reg.init_reg(0x06, 0xd8); /* SCANMOD=110, PWRBIT and GAIN4 */
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x06, 0xd8); /* SCANMOD=110, PWRBIT and GAIN4 */
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I) {
        dev->reg.init_reg(0x06, 0xd0);
    }
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x06, 0xf0); /* SCANMOD=111, PWRBIT and no GAIN4 */
    }

  dev->reg.init_reg(0x08, 0x00);
  dev->reg.init_reg(0x09, 0x00);
  dev->reg.init_reg(0x0a, 0x00);
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x0a, 0x18);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x0a, 0x10);
    }

    // This register controls clock and RAM settings and is further modified in
    // gl843_boot
    dev->reg.init_reg(0x0b, 0x6a);

    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0x0b, 0x69); // 16M only
    }
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x0b, 0x89);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I) {
        dev->reg.init_reg(0x0b, 0x2a);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I) {
        dev->reg.init_reg(0x0b, 0x4a);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x0b, 0x69);
    }

    if (dev->model->model_id != ModelId::CANON_8400F &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300)
    {
        dev->reg.init_reg(0x0c, 0x00);
    }

    // EXPR[0:15], EXPG[0:15], EXPB[0:15]: Exposure time settings.
    dev->reg.init_reg(0x10, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x11, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x12, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x13, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x14, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x15, 0x00); // SENSOR_DEF
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        dev->reg.set16(REG_EXPR, 0x9c40);
        dev->reg.set16(REG_EXPG, 0x9c40);
        dev->reg.set16(REG_EXPB, 0x9c40);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.set16(REG_EXPR, 0x2c09);
        dev->reg.set16(REG_EXPG, 0x22b8);
        dev->reg.set16(REG_EXPB, 0x10f0);
    }

    // CCD signal settings.
    dev->reg.init_reg(0x16, 0x33); // SENSOR_DEF
    dev->reg.init_reg(0x17, 0x1c); // SENSOR_DEF
    dev->reg.init_reg(0x18, 0x10); // SENSOR_DEF

    // EXPDMY[0:7]: Exposure time of dummy lines.
    dev->reg.init_reg(0x19, 0x2a); // SENSOR_DEF

    // Various CCD clock settings.
    dev->reg.init_reg(0x1a, 0x04); // SENSOR_DEF
    dev->reg.init_reg(0x1b, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x1c, 0x20); // SENSOR_DEF
    dev->reg.init_reg(0x1d, 0x04); // SENSOR_DEF

    dev->reg.init_reg(0x1e, 0x10);
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        dev->reg.init_reg(0x1e, 0x20);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x1e, 0xa0);
    }

    dev->reg.init_reg(0x1f, 0x01);
    if (dev->model->model_id == ModelId::CANON_8600F) {
      dev->reg.init_reg(0x1f, 0xff);
    }

    dev->reg.init_reg(0x20, 0x10);
    dev->reg.init_reg(0x21, 0x04);

    dev->reg.init_reg(0x22, 0x10);
    dev->reg.init_reg(0x23, 0x10);
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x22, 0xc8);
        dev->reg.init_reg(0x23, 0xc8);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x22, 0x50);
        dev->reg.init_reg(0x23, 0x50);
    }

    dev->reg.init_reg(0x24, 0x04);
    dev->reg.init_reg(0x25, 0x00);
    dev->reg.init_reg(0x26, 0x00);
    dev->reg.init_reg(0x27, 0x00);
    dev->reg.init_reg(0x2c, 0x02);
    dev->reg.init_reg(0x2d, 0x58);
    // BWHI[0:7]: high level of black and white threshold
    dev->reg.init_reg(0x2e, 0x80);
    // BWLOW[0:7]: low level of black and white threshold
    dev->reg.init_reg(0x2f, 0x80);
    dev->reg.init_reg(0x30, 0x00);
    dev->reg.init_reg(0x31, 0x14);
    dev->reg.init_reg(0x32, 0x27);
    dev->reg.init_reg(0x33, 0xec);

    // DUMMY: CCD dummy and optically black pixel count
    dev->reg.init_reg(0x34, 0x24);
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x34, 0x14);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x34, 0x3c);
    }

    // MAXWD: If available buffer size is less than 2*MAXWD words, then
    // "buffer full" state will be set.
    dev->reg.init_reg(0x35, 0x00);
    dev->reg.init_reg(0x36, 0xff);
    dev->reg.init_reg(0x37, 0xff);

    // LPERIOD: Line period or exposure time for CCD or CIS.
    dev->reg.init_reg(0x38, 0x55); // SENSOR_DEF
    dev->reg.init_reg(0x39, 0xf0); // SENSOR_DEF

    // FEEDL[0:24]: The number of steps of motor movement.
    dev->reg.init_reg(0x3d, 0x00);
    dev->reg.init_reg(0x3e, 0x00);
    dev->reg.init_reg(0x3f, 0x01);

    // Latch points for high and low bytes of R, G and B channels of AFE. If
    // multiple clocks per pixel are consumed, then the setting defines during
    // which clock the corresponding value will be read.
    // RHI[0:4]: The latch point for high byte of R channel.
    // RLOW[0:4]: The latch point for low byte of R channel.
    // GHI[0:4]: The latch point for high byte of G channel.
    // GLOW[0:4]: The latch point for low byte of G channel.
    // BHI[0:4]: The latch point for high byte of B channel.
    // BLOW[0:4]: The latch point for low byte of B channel.
    dev->reg.init_reg(0x52, 0x01); // SENSOR_DEF
    dev->reg.init_reg(0x53, 0x04); // SENSOR_DEF
    dev->reg.init_reg(0x54, 0x07); // SENSOR_DEF
    dev->reg.init_reg(0x55, 0x0a); // SENSOR_DEF
    dev->reg.init_reg(0x56, 0x0d); // SENSOR_DEF
    dev->reg.init_reg(0x57, 0x10); // SENSOR_DEF

    // VSMP[0:4]: The position of the image sampling pulse for AFE in cycles.
    // VSMPW[0:2]: The length of the image sampling pulse for AFE in cycles.
    dev->reg.init_reg(0x58, 0x1b); // SENSOR_DEF

    dev->reg.init_reg(0x59, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x5a, 0x40); // SENSOR_DEF

    // 0x5b-0x5c: GMMADDR[0:15] address for gamma or motor tables download
    // SENSOR_DEF

    // DECSEL[0:2]: The number of deceleration steps after touching home sensor
    // STOPTIM[0:4]: The stop duration between change of directions in
    // backtracking
    dev->reg.init_reg(0x5e, 0x23);
    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0x5e, 0x3f);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x5e, 0x85);
    }
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x5e, 0x1f);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x5e, 0x01);
    }

    //FMOVDEC: The number of deceleration steps in table 5 for auto-go-home
    dev->reg.init_reg(0x5f, 0x01);
    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0x5f, 0xf0);
    }
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x5f, 0xf0);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x5f, 0x01);
    }

    // Z1MOD[0:20]
    dev->reg.init_reg(0x60, 0x00);
    dev->reg.init_reg(0x61, 0x00);
    dev->reg.init_reg(0x62, 0x00);

    // Z2MOD[0:20]
    dev->reg.init_reg(0x63, 0x00);
    dev->reg.init_reg(0x64, 0x00);
    dev->reg.init_reg(0x65, 0x00);

    // STEPSEL[0:1]. Motor movement step mode selection for tables 1-3 in
    // scanning mode.
    // MTRPWM[0:5]. Motor phase PWM duty cycle setting for tables 1-3
    dev->reg.init_reg(0x67, 0x7f); // MOTOR_PROFILE
    // FSTPSEL[0:1]: Motor movement step mode selection for tables 4-5 in
    // command mode.
    // FASTPWM[5:0]: Motor phase PWM duty cycle setting for tables 4-5
    dev->reg.init_reg(0x68, 0x7f); // MOTOR_PROFILE

    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300) {
        dev->reg.init_reg(0x67, 0x80);
        dev->reg.init_reg(0x68, 0x80);
    }

    // FSHDEC[0:7]: The number of deceleration steps after scanning is finished
    // (table 3)
    dev->reg.init_reg(0x69, 0x01); // MOTOR_PROFILE

    // FMOVNO[0:7] The number of acceleration or deceleration steps for fast
    // moving (table 4)
    dev->reg.init_reg(0x6a, 0x04); // MOTOR_PROFILE

    // GPIO-related register bits
    dev->reg.init_reg(0x6b, 0x30);
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        dev->reg.init_reg(0x6b, 0x72);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x6b, 0xb1);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x6b, 0xf4);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x6b, 0x31);
    }

    // 0x6c, 0x6d, 0x6e, 0x6f are set according to gpio tables. See
    // gl843_init_gpio.

    // RSH[0:4]: The position of rising edge of CCD RS signal in cycles
    // RSL[0:4]: The position of falling edge of CCD RS signal in cycles
    // CPH[0:4]: The position of rising edge of CCD CP signal in cycles.
    // CPL[0:4]: The position of falling edge of CCD CP signal in cycles
    dev->reg.init_reg(0x70, 0x01); // SENSOR_DEF
    dev->reg.init_reg(0x71, 0x03); // SENSOR_DEF
    dev->reg.init_reg(0x72, 0x04); // SENSOR_DEF
    dev->reg.init_reg(0x73, 0x05); // SENSOR_DEF

    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0x70, 0x01);
        dev->reg.init_reg(0x71, 0x03);
        dev->reg.init_reg(0x72, 0x01);
        dev->reg.init_reg(0x73, 0x03);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x70, 0x01);
        dev->reg.init_reg(0x71, 0x03);
        dev->reg.init_reg(0x72, 0x03);
        dev->reg.init_reg(0x73, 0x04);
    }
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x70, 0x00);
        dev->reg.init_reg(0x71, 0x02);
        dev->reg.init_reg(0x72, 0x02);
        dev->reg.init_reg(0x73, 0x04);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x70, 0x00);
        dev->reg.init_reg(0x71, 0x02);
        dev->reg.init_reg(0x72, 0x00);
        dev->reg.init_reg(0x73, 0x00);
    }

    // CK1MAP[0:17], CK3MAP[0:17], CK4MAP[0:17]: CCD clock bit mapping setting.
    dev->reg.init_reg(0x74, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x75, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x76, 0x3c); // SENSOR_DEF
    dev->reg.init_reg(0x77, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x78, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x79, 0x9f); // SENSOR_DEF
    dev->reg.init_reg(0x7a, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x7b, 0x00); // SENSOR_DEF
    dev->reg.init_reg(0x7c, 0x55); // SENSOR_DEF

    // various AFE settings
    dev->reg.init_reg(0x7d, 0x00);
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x7d, 0x20);
    }

    // GPOLED[x]: LED vs GPIO settings
    dev->reg.init_reg(0x7e, 0x00);

    // BSMPDLY, VSMPDLY
    // LEDCNT[0:1]: Controls led blinking and its period
    dev->reg.init_reg(0x7f, 0x00);

    // VRHOME, VRMOVE, VRBACK, VRSCAN: Vref settings of the motor driver IC for
    // moving in various situations.
    dev->reg.init_reg(0x80, 0x00); // MOTOR_PROFILE
    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0x80, 0x0c);
    }
    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->reg.init_reg(0x80, 0x28);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x80, 0x50);
    }
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x80, 0x0f);
    }

    if (dev->model->model_id != ModelId::CANON_4400F) {
        dev->reg.init_reg(0x81, 0x00);
        dev->reg.init_reg(0x82, 0x00);
        dev->reg.init_reg(0x83, 0x00);
        dev->reg.init_reg(0x84, 0x00);
        dev->reg.init_reg(0x85, 0x00);
        dev->reg.init_reg(0x86, 0x00);
    }

    dev->reg.init_reg(0x87, 0x00);
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        dev->reg.init_reg(0x87, 0x02);
    }

    // MTRPLS[0:7]: The width of the ADF motor trigger signal pulse.
    if (dev->model->model_id != ModelId::CANON_8400F &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300)
    {
        dev->reg.init_reg(0x94, 0xff);
    }

    // 0x95-0x97: SCANLEN[0:19]: Controls when paper jam bit is set in sheetfed
    // scanners.

    // ONDUR[0:15]: The duration of PWM ON phase for LAMP control
    // OFFDUR[0:15]: The duration of PWM OFF phase for LAMP control
    // both of the above are in system clocks
    if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->reg.init_reg(0x98, 0x00);
        dev->reg.init_reg(0x99, 0x00);
        dev->reg.init_reg(0x9a, 0x00);
        dev->reg.init_reg(0x9b, 0x00);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        // TODO: move to set for scan
        dev->reg.init_reg(0x98, 0x03);
        dev->reg.init_reg(0x99, 0x30);
        dev->reg.init_reg(0x9a, 0x01);
        dev->reg.init_reg(0x9b, 0x80);
    }

    // RMADLY[0:1], MOTLAG, CMODE, STEPTIM, MULDMYLN, IFRS
    dev->reg.init_reg(0x9d, 0x04);
    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->reg.init_reg(0x9d, 0x00);
    }
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8400F ||
        dev->model->model_id == ModelId::CANON_8600F ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I ||
        dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0x9d, 0x08); // sets the multiplier for slope tables
    }


    // SEL3INV, TGSTIME[0:2], TGWTIME[0:2]
    if (dev->model->model_id != ModelId::CANON_8400F &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300)
    {
      dev->reg.init_reg(0x9e, 0x00); // SENSOR_DEF
    }

    if (dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300) {
        dev->reg.init_reg(0xa2, 0x0f);
    }

    // RFHSET[0:4]: Refresh time of SDRAM in units of 2us
    if (dev->model->model_id == ModelId::CANON_4400F ||
        dev->model->model_id == ModelId::CANON_8600F)
    {
        dev->reg.init_reg(0xa2, 0x1f);
    }

    // 0xa6-0xa9: controls gpio, see gl843_gpio_init

    // not documented
    if (dev->model->model_id != ModelId::CANON_4400F &&
        dev->model->model_id != ModelId::CANON_8400F &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300)
    {
        dev->reg.init_reg(0xaa, 0x00);
    }

    // GPOM9, MULSTOP[0-2], NODECEL, TB3TB1, TB5TB2, FIX16CLK.
    if (dev->model->model_id != ModelId::CANON_8400F &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
        dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300) {
        dev->reg.init_reg(0xab, 0x50);
    }
    if (dev->model->model_id == ModelId::CANON_4400F) {
        dev->reg.init_reg(0xab, 0x00);
    }
    if (dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::CANON_8600F ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0xab, 0x40);
    }

    // VRHOME[3:2], VRMOVE[3:2], VRBACK[3:2]: Vref setting of the motor driver IC
    // for various situations.
    if (dev->model->model_id == ModelId::CANON_8600F ||
        dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C)
    {
        dev->reg.init_reg(0xac, 0x00);
    }

    if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I) {
        uint8_t data[32] = {
            0x8c, 0x8f, 0xc9, 0x00, 0x01, 0x00, 0x00, 0x00,
            0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
            0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
            0x6a, 0x73, 0x63, 0x68, 0x69, 0x65, 0x6e, 0x00,
        };

        dev->interface->write_buffer(0x3c, 0x3ff000, data, 32);
    }
}

static void gl843_set_ad_fe(Genesys_Device* dev)
{
    for (const auto& reg : dev->frontend.regs) {
        dev->interface->write_fe_register(reg.address, reg.value);
    }
}

// Set values of analog frontend
void CommandSetGl843::set_fe(Genesys_Device* dev, const Genesys_Sensor& sensor, uint8_t set) const
{
    DBG_HELPER_ARGS(dbg, "%s", set == AFE_INIT ? "init" :
                               set == AFE_SET ? "set" :
                               set == AFE_POWER_SAVE ? "powersave" : "huh?");
    (void) sensor;

    if (set == AFE_INIT) {
        dev->frontend = dev->frontend_initial;
    }

    // check analog frontend type
    // FIXME: looks like we write to that register with initial data
    uint8_t fe_type = dev->interface->read_register(REG_0x04) & REG_0x04_FESET;
    if (fe_type == 2) {
        gl843_set_ad_fe(dev);
        return;
    }
    if (fe_type != 0) {
        throw SaneException(SANE_STATUS_UNSUPPORTED, "unsupported frontend type %d", fe_type);
    }

    for (unsigned i = 1; i <= 3; i++) {
        dev->interface->write_fe_register(i, dev->frontend.regs.get_value(0x00 + i));
    }
    for (const auto& reg : sensor.custom_fe_regs) {
        dev->interface->write_fe_register(reg.address, reg.value);
    }

    for (unsigned i = 0; i < 3; i++) {
        dev->interface->write_fe_register(0x20 + i, dev->frontend.get_offset(i));
    }

    if (dev->model->sensor_id == SensorId::CCD_KVSS080) {
        for (unsigned i = 0; i < 3; i++) {
            dev->interface->write_fe_register(0x24 + i, dev->frontend.regs.get_value(0x24 + i));
        }
    }

    for (unsigned i = 0; i < 3; i++) {
        dev->interface->write_fe_register(0x28 + i, dev->frontend.get_gain(i));
    }
}

static void gl843_init_motor_regs_scan(Genesys_Device* dev,
                                       const Genesys_Sensor& sensor,
                                       const ScanSession& session,
                                       Genesys_Register_Set* reg,
                                       const MotorProfile& motor_profile,
                                       unsigned int exposure,
                                       unsigned scan_yres,
                                       unsigned int scan_lines,
                                       unsigned int scan_dummy,
                                       unsigned int feed_steps,
                                       ScanFlag flags)
{
    DBG_HELPER_ARGS(dbg, "exposure=%d, scan_yres=%d, step_type=%d, scan_lines=%d, scan_dummy=%d, "
                         "feed_steps=%d, flags=%x",
                    exposure, scan_yres, static_cast<unsigned>(motor_profile.step_type),
                    scan_lines, scan_dummy, feed_steps, static_cast<unsigned>(flags));

    unsigned feedl, dist;

  /* get step multiplier */
    unsigned step_multiplier = gl843_get_step_multiplier (reg);

    bool use_fast_fed = false;

    if ((scan_yres >= 300 && feed_steps > 900) || (has_flag(flags, ScanFlag::FEEDING))) {
        use_fast_fed = true;
    }
    if (has_flag(dev->model->flags, ModelFlag::DISABLE_FAST_FEEDING)) {
        use_fast_fed = false;
    }

    reg->set24(REG_LINCNT, scan_lines);

    reg->set8(REG_0x02, 0);
    sanei_genesys_set_motor_power(*reg, true);

    std::uint8_t reg02 = reg->get8(REG_0x02);
    if (use_fast_fed) {
        reg02 |= REG_0x02_FASTFED;
    } else {
        reg02 &= ~REG_0x02_FASTFED;
    }

    // in case of automatic go home, move until home sensor
    if (has_flag(flags, ScanFlag::AUTO_GO_HOME)) {
        reg02 |= REG_0x02_AGOHOME | REG_0x02_NOTHOME;
    }

  /* disable backtracking */
    if (has_flag(flags, ScanFlag::DISABLE_BUFFER_FULL_MOVE) ||
        (scan_yres>=2400 && dev->model->model_id != ModelId::CANON_4400F) ||
        (scan_yres>=sensor.full_resolution))
    {
        reg02 |= REG_0x02_ACDCDIS;
    }

    if (has_flag(flags, ScanFlag::REVERSE)) {
        reg02 |= REG_0x02_MTRREV;
    } else {
        reg02 &= ~REG_0x02_MTRREV;
    }
    reg->set8(REG_0x02, reg02);

    // scan and backtracking slope table
    auto scan_table = create_slope_table(dev->model->asic_type, dev->motor, scan_yres, exposure,
                                         step_multiplier, motor_profile);

    scanner_send_slope_table(dev, sensor, SCAN_TABLE, scan_table.table);
    scanner_send_slope_table(dev, sensor, BACKTRACK_TABLE, scan_table.table);
    scanner_send_slope_table(dev, sensor, STOP_TABLE, scan_table.table);

    reg->set8(REG_STEPNO, scan_table.table.size() / step_multiplier);
    reg->set8(REG_FASTNO, scan_table.table.size() / step_multiplier);
    reg->set8(REG_FSHDEC, scan_table.table.size() / step_multiplier);

    // fast table
    const auto* fast_profile = get_motor_profile_ptr(dev->motor.fast_profiles, 0, session);
    if (fast_profile == nullptr) {
        fast_profile = &motor_profile;
    }

    auto fast_table = create_slope_table_fastest(dev->model->asic_type, step_multiplier,
                                                 *fast_profile);

    scanner_send_slope_table(dev, sensor, FAST_TABLE, fast_table.table);
    scanner_send_slope_table(dev, sensor, HOME_TABLE, fast_table.table);

    reg->set8(REG_FMOVNO, fast_table.table.size() / step_multiplier);

    if (motor_profile.motor_vref != -1 && fast_profile->motor_vref != 1) {
        std::uint8_t vref = 0;
        vref |= (motor_profile.motor_vref << REG_0x80S_TABLE1_NORMAL) & REG_0x80_TABLE1_NORMAL;
        vref |= (motor_profile.motor_vref << REG_0x80S_TABLE2_BACK) & REG_0x80_TABLE2_BACK;
        vref |= (fast_profile->motor_vref << REG_0x80S_TABLE4_FAST) & REG_0x80_TABLE4_FAST;
        vref |= (fast_profile->motor_vref << REG_0x80S_TABLE5_GO_HOME) & REG_0x80_TABLE5_GO_HOME;
        reg->set8(REG_0x80, vref);
    }

  /* subtract acceleration distance from feedl */
  feedl=feed_steps;
    feedl <<= static_cast<unsigned>(motor_profile.step_type);

    dist = scan_table.table.size() / step_multiplier;

    if (use_fast_fed) {
        dist += (fast_table.table.size() / step_multiplier) * 2;
    }

  /* get sure when don't insane value : XXX STEF XXX in this case we should
   * fall back to single table move */
    if (dist < feedl) {
        feedl -= dist;
    } else {
        feedl = 1;
    }

    reg->set24(REG_FEEDL, feedl);

    // doesn't seem to matter that much
    std::uint32_t z1, z2;
    sanei_genesys_calculate_zmod(use_fast_fed,
                                 exposure,
                                 scan_table.table,
                                 scan_table.table.size() / step_multiplier,
                                 feedl,
                                 scan_table.table.size() / step_multiplier,
                                  &z1,
                                  &z2);
  if(scan_yres>600)
    {
      z1=0;
      z2=0;
    }

    reg->set24(REG_Z1MOD, z1);
    reg->set24(REG_Z2MOD, z2);

    reg->set8_mask(REG_0x1E, scan_dummy, 0x0f);

    reg->set8_mask(REG_0x67, static_cast<unsigned>(motor_profile.step_type) << REG_0x67S_STEPSEL, 0xc0);
    reg->set8_mask(REG_0x68, static_cast<unsigned>(fast_profile->step_type) << REG_0x68S_FSTPSEL, 0xc0);

    // steps for STOP table
    reg->set8(REG_FMOVDEC, fast_table.table.size() / step_multiplier);

    if (dev->model->model_id == ModelId::PANASONIC_KV_SS080 ||
        dev->model->model_id == ModelId::HP_SCANJET_4850C ||
        dev->model->model_id == ModelId::HP_SCANJET_G4010 ||
        dev->model->model_id == ModelId::HP_SCANJET_G4050 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
        dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        // FIXME: take this information from motor struct
        std::uint8_t reg_vref = reg->get8(0x80);
        reg_vref = 0x50;
        unsigned coeff = sensor.full_resolution / scan_yres;
        if (dev->model->motor_id == MotorId::KVSS080) {
            if (coeff >= 1) {
                reg_vref |= 0x05;
            }
        } else {
            switch (coeff) {
                case 4:
                    reg_vref |= 0x0a;
                    break;
                case 2:
                    reg_vref |= 0x0f;
                    break;
                case 1:
                    reg_vref |= 0x0f;
                    break;
            }
        }
        reg->set8(REG_0x80, reg_vref);
    }
}


/** @brief setup optical related registers
 * start and pixels are expressed in optical sensor resolution coordinate
 * space.
 * @param dev device to use
 * @param reg registers to set up
 * @param exposure exposure time to use
 * @param used_res scanning resolution used, may differ from
 *        scan's one
 * @param start logical start pixel coordinate
 * @param pixels logical number of pixels to use
 * @param channels number of color channels used (1 or 3)
 * @param depth bit depth of the scan (1, 8 or 16 bits)
 * @param color_filter to choose the color channel used in gray scans
 * @param flags to drive specific settings such no calibration, XPA use ...
 */
static void gl843_init_optical_regs_scan(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                         Genesys_Register_Set* reg, unsigned int exposure,
                                         const ScanSession& session)
{
    DBG_HELPER_ARGS(dbg, "exposure=%d", exposure);
  unsigned int tgtime;          /**> exposure time multiplier */

  /* tgtime */
  tgtime = exposure / 65536 + 1;
  DBG(DBG_io2, "%s: tgtime=%d\n", __func__, tgtime);

    // sensor parameters
    scanner_setup_sensor(*dev, sensor, *reg);

    dev->cmd_set->set_fe(dev, sensor, AFE_SET);

  /* enable shading */
    regs_set_optical_off(dev->model->asic_type, *reg);
    if (has_flag(session.params.flags, ScanFlag::DISABLE_SHADING) ||
        has_flag(dev->model->flags, ModelFlag::DISABLE_SHADING_CALIBRATION) ||
        session.use_host_side_calib)
    {
        reg->find_reg(REG_0x01).value &= ~REG_0x01_DVDSET;

    } else {
        reg->find_reg(REG_0x01).value |= REG_0x01_DVDSET;
    }

    bool use_shdarea = false;
    if (dev->model->model_id == ModelId::CANON_4400F) {
        use_shdarea = session.params.xres <= 600;
    } else if (dev->model->model_id == ModelId::CANON_8400F) {
        use_shdarea = session.params.xres <= 400;
    } else if (dev->model->model_id == ModelId::CANON_8600F ||
               dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7200I ||
               dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
               dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        use_shdarea = true;
    } else {
        use_shdarea = session.params.xres > 600;
    }

    if (use_shdarea) {
        reg->find_reg(REG_0x01).value |= REG_0x01_SHDAREA;
    } else {
        reg->find_reg(REG_0x01).value &= ~REG_0x01_SHDAREA;
    }

    if (dev->model->model_id == ModelId::CANON_8600F) {
        reg->find_reg(REG_0x03).value |= REG_0x03_AVEENB;
    } else {
        reg->find_reg(REG_0x03).value &= ~REG_0x03_AVEENB;
  }

    // FIXME: we probably don't need to set exposure to registers at this point. It was this way
    // before a refactor.
    sanei_genesys_set_lamp_power(dev, sensor, *reg,
                                 !has_flag(session.params.flags, ScanFlag::DISABLE_LAMP));

  /* select XPA */
    reg->find_reg(REG_0x03).value &= ~REG_0x03_XPASEL;
    if (has_flag(session.params.flags, ScanFlag::USE_XPA)) {
        reg->find_reg(REG_0x03).value |= REG_0x03_XPASEL;
    }
    reg->state.is_xpa_on = has_flag(session.params.flags, ScanFlag::USE_XPA);

    // BW threshold
    reg->set8(REG_0x2E, 0x7f);
    reg->set8(REG_0x2F, 0x7f);

  /* monochrome / color scan */
    switch (session.params.depth) {
    case 8:
            reg->find_reg(REG_0x04).value &= ~(REG_0x04_LINEART | REG_0x04_BITSET);
      break;
    case 16:
            reg->find_reg(REG_0x04).value &= ~REG_0x04_LINEART;
            reg->find_reg(REG_0x04).value |= REG_0x04_BITSET;
      break;
    }

    reg->find_reg(REG_0x04).value &= ~(REG_0x04_FILTER | REG_0x04_AFEMOD);
  if (session.params.channels == 1)
    {
      switch (session.params.color_filter)
	{
            case ColorFilter::RED:
                reg->find_reg(REG_0x04).value |= 0x14;
                break;
            case ColorFilter::BLUE:
                reg->find_reg(REG_0x04).value |= 0x1c;
                break;
            case ColorFilter::GREEN:
                reg->find_reg(REG_0x04).value |= 0x18;
                break;
            default:
                break; // should not happen
	}
    } else {
        switch (dev->frontend.layout.type) {
            case FrontendType::WOLFSON:
                reg->find_reg(REG_0x04).value |= 0x10; // pixel by pixel
                break;
            case FrontendType::ANALOG_DEVICES:
                reg->find_reg(REG_0x04).value |= 0x20; // slow color pixel by pixel
                break;
            default:
                throw SaneException("Invalid frontend type %d",
                                    static_cast<unsigned>(dev->frontend.layout.type));
        }
    }

    const auto& dpihw_sensor = sanei_genesys_find_sensor(dev, session.output_resolution,
                                                         session.params.channels,
                                                         session.params.scan_method);
    sanei_genesys_set_dpihw(*reg, dpihw_sensor.register_dpihw);

    if (should_enable_gamma(session, sensor)) {
        reg->find_reg(REG_0x05).value |= REG_0x05_GMMENB;
    } else {
        reg->find_reg(REG_0x05).value &= ~REG_0x05_GMMENB;
    }

    reg->set16(REG_DPISET, sensor.register_dpiset);

    reg->set16(REG_STRPIXEL, session.pixel_startx);
    reg->set16(REG_ENDPIXEL, session.pixel_endx);

  /* MAXWD is expressed in 2 words unit */
  /* nousedspace = (mem_bank_range * 1024 / 256 -1 ) * 4; */
    // BUG: the division by optical and full resolution factor likely does not make sense
    reg->set24(REG_MAXWD, (session.output_line_bytes *
                           session.optical_resolution / session.full_resolution) >> 1);
    reg->set16(REG_LPERIOD, exposure / tgtime);
    reg->set8(REG_DUMMY, sensor.dummy_pixel);
}

void CommandSetGl843::init_regs_for_scan_session(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                                 Genesys_Register_Set* reg,
                                                 const ScanSession& session) const
{
    DBG_HELPER(dbg);
    session.assert_computed();

  int exposure;

  int slope_dpi = 0;
  int dummy = 0;

  /* we enable true gray for cis scanners only, and just when doing
   * scan since color calibration is OK for this mode
   */

  dummy = 0;
    if (dev->model->model_id == ModelId::CANON_4400F && session.params.yres == 1200) {
        dummy = 1;
    }

  /* slope_dpi */
  /* cis color scan is effectively a gray scan with 3 gray lines per color line and a FILTER of 0 */
  if (dev->model->is_cis)
    slope_dpi = session.params.yres * session.params.channels;
  else
    slope_dpi = session.params.yres;
  slope_dpi = slope_dpi * (1 + dummy);

  /* scan_step_type */
  exposure = sensor.exposure_lperiod;
  if (exposure < 0) {
      throw std::runtime_error("Exposure not defined in sensor definition");
  }
    const auto& motor_profile = get_motor_profile(dev->motor.profiles, exposure, session);

    // now _LOGICAL_ optical values used are known, setup registers
    gl843_init_optical_regs_scan(dev, sensor, reg, exposure, session);
    gl843_init_motor_regs_scan(dev, sensor, session, reg, motor_profile, exposure, slope_dpi,
                               session.optical_line_count, dummy, session.params.starty,
                               session.params.flags);

    setup_image_pipeline(*dev, session);

    dev->read_active = true;

    dev->session = session;

  dev->total_bytes_read = 0;
    dev->total_bytes_to_read = session.output_line_bytes_requested * session.params.lines;

    DBG(DBG_info, "%s: total bytes to send = %zu\n", __func__, dev->total_bytes_to_read);
}

ScanSession CommandSetGl843::calculate_scan_session(const Genesys_Device* dev,
                                                    const Genesys_Sensor& sensor,
                                                    const Genesys_Settings& settings) const
{
    DBG_HELPER(dbg);
    debug_dump(DBG_info, settings);

    ScanFlag flags = ScanFlag::NONE;

    float move = 0.0f;
    if (settings.scan_method == ScanMethod::TRANSPARENCY ||
        settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
    {
        // note: scanner_move_to_ta() function has already been called and the sensor is at the
        // transparency adapter
        if (!dev->ignore_offsets) {
            move = dev->model->y_offset_ta - dev->model->y_offset_sensor_to_ta;
        }
        flags |= ScanFlag::USE_XPA;
    } else {
        if (!dev->ignore_offsets) {
            move = dev->model->y_offset;
        }
    }

    move += settings.tl_y;

    int move_dpi = dev->motor.base_ydpi;
    move = static_cast<float>((move * move_dpi) / MM_PER_INCH);

    float start = 0.0f;
    if (settings.scan_method==ScanMethod::TRANSPARENCY ||
        settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
    {
        start = dev->model->x_offset_ta;
    } else {
        start = dev->model->x_offset;
    }
    start = start + settings.tl_x;

    start = static_cast<float>((start * settings.xres) / MM_PER_INCH);

    ScanSession session;
    session.params.xres = settings.xres;
    session.params.yres = settings.yres;
    session.params.startx = static_cast<unsigned>(start);
    session.params.starty = static_cast<unsigned>(move);
    session.params.pixels = settings.pixels;
    session.params.requested_pixels = settings.requested_pixels;
    session.params.lines = settings.lines;
    session.params.depth = settings.depth;
    session.params.channels = settings.get_channels();
    session.params.scan_method = settings.scan_method;
    session.params.scan_mode = settings.scan_mode;
    session.params.color_filter = settings.color_filter;
    session.params.contrast_adjustment = settings.contrast;
    session.params.brightness_adjustment = settings.brightness;
    session.params.flags = flags;
    compute_session(dev, session, sensor);

    return session;
}

/**
 * for fast power saving methods only, like disabling certain amplifiers
 * @param dev device to use
 * @param enable true to set inot powersaving
 * */
void CommandSetGl843::save_power(Genesys_Device* dev, bool enable) const
{
    DBG_HELPER_ARGS(dbg, "enable = %d", enable);

    // switch KV-SS080 lamp off
    if (dev->model->gpio_id == GpioId::KVSS080) {
        uint8_t val = dev->interface->read_register(REG_0x6C);
        if (enable) {
            val &= 0xef;
        } else {
            val |= 0x10;
        }
        dev->interface->write_register(REG_0x6C, val);
    }
}

void CommandSetGl843::set_powersaving(Genesys_Device* dev, int delay /* in minutes */) const
{
    (void) dev;
    DBG_HELPER_ARGS(dbg, "delay = %d", delay);
}

static bool gl843_get_paper_sensor(Genesys_Device* dev)
{
    DBG_HELPER(dbg);

    uint8_t val = dev->interface->read_register(REG_0x6D);

    return (val & 0x1) == 0;
}

void CommandSetGl843::eject_document(Genesys_Device* dev) const
{
    (void) dev;
    DBG_HELPER(dbg);
}


void CommandSetGl843::load_document(Genesys_Device* dev) const
{
    DBG_HELPER(dbg);
    (void) dev;
}

/**
 * detects end of document and adjust current scan
 * to take it into account
 * used by sheetfed scanners
 */
void CommandSetGl843::detect_document_end(Genesys_Device* dev) const
{
    DBG_HELPER(dbg);
    bool paper_loaded = gl843_get_paper_sensor(dev);

  /* sheetfed scanner uses home sensor as paper present */
    if (dev->document && !paper_loaded) {
      DBG(DBG_info, "%s: no more document\n", __func__);
        dev->document = false;

        unsigned scanned_lines = 0;
        catch_all_exceptions(__func__, [&](){ sanei_genesys_read_scancnt(dev, &scanned_lines); });

        std::size_t output_lines = dev->session.output_line_count;

        std::size_t offset_lines = static_cast<std::size_t>(
                (dev->model->post_scan * dev->session.params.yres) / MM_PER_INCH);

        std::size_t scan_end_lines = scanned_lines + offset_lines;

        std::size_t remaining_lines = dev->get_pipeline_source().remaining_bytes() /
                dev->session.output_line_bytes_raw;

        DBG(DBG_io, "%s: scanned_lines=%u\n", __func__, scanned_lines);
        DBG(DBG_io, "%s: scan_end_lines=%zu\n", __func__, scan_end_lines);
        DBG(DBG_io, "%s: output_lines=%zu\n", __func__, output_lines);
        DBG(DBG_io, "%s: remaining_lines=%zu\n", __func__, remaining_lines);

        if (scan_end_lines > output_lines) {
            auto skip_lines = scan_end_lines - output_lines;

            if (remaining_lines > skip_lines) {
                remaining_lines -= skip_lines;
                dev->get_pipeline_source().set_remaining_bytes(remaining_lines *
                                                               dev->session.output_line_bytes_raw);
                dev->total_bytes_to_read -= skip_lines * dev->session.output_line_bytes_requested;
            }
        }
    }
}

// Send the low-level scan command
void CommandSetGl843::begin_scan(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                 Genesys_Register_Set* reg, bool start_motor) const
{
    DBG_HELPER(dbg);
    (void) sensor;

  /* set up GPIO for scan */
    switch(dev->model->gpio_id) {
      /* KV case */
        case GpioId::KVSS080:
            dev->interface->write_register(REG_0xA9, 0x00);
            dev->interface->write_register(REG_0xA6, 0xf6);
            // blinking led
            dev->interface->write_register(0x7e, 0x04);
            break;
        case GpioId::G4050:
        case GpioId::G4010:
            dev->interface->write_register(REG_0xA7, 0xfe);
            dev->interface->write_register(REG_0xA8, 0x3e);
            dev->interface->write_register(REG_0xA9, 0x06);
            if ((reg->get8(0x05) & REG_0x05_DPIHW) == REG_0x05_DPIHW_600) {
                dev->interface->write_register(REG_0x6C, 0x20);
                dev->interface->write_register(REG_0xA6, 0x44);
            } else {
                dev->interface->write_register(REG_0x6C, 0x60);
                dev->interface->write_register(REG_0xA6, 0x46);
            }

            if (reg->state.is_xpa_on && reg->state.is_lamp_on) {
                dev->cmd_set->set_xpa_lamp_power(*dev, true);
            }

            if (reg->state.is_xpa_on) {
                dev->cmd_set->set_motor_mode(*dev, *reg, MotorMode::PRIMARY_AND_SECONDARY);
            }

            // blinking led
            dev->interface->write_register(REG_0x7E, 0x01);
            break;
        case GpioId::CANON_8400F:
            if (dev->session.params.xres == 3200)
            {
                GenesysRegisterSettingSet reg_settings = {
                    { 0x6c, 0x00, 0x02 },
                };
                apply_reg_settings_to_device(*dev, reg_settings);
            }
            if (reg->state.is_xpa_on && reg->state.is_lamp_on) {
                dev->cmd_set->set_xpa_lamp_power(*dev, true);
            }
            if (reg->state.is_xpa_on) {
                dev->cmd_set->set_motor_mode(*dev, *reg, MotorMode::PRIMARY_AND_SECONDARY);
            }
            break;
        case GpioId::CANON_8600F:
            if (reg->state.is_xpa_on && reg->state.is_lamp_on) {
                dev->cmd_set->set_xpa_lamp_power(*dev, true);
            }
            if (reg->state.is_xpa_on) {
                dev->cmd_set->set_motor_mode(*dev, *reg, MotorMode::PRIMARY_AND_SECONDARY);
            }
            break;
        case GpioId::PLUSTEK_OPTICFILM_7200I:
        case GpioId::PLUSTEK_OPTICFILM_7300:
        case GpioId::PLUSTEK_OPTICFILM_7500I: {
            if (reg->state.is_xpa_on && reg->state.is_lamp_on) {
                dev->cmd_set->set_xpa_lamp_power(*dev, true);
            }
            break;
        }
        case GpioId::CANON_4400F:
        default:
            break;
    }

    scanner_clear_scan_and_feed_counts(*dev);

    // enable scan and motor
    uint8_t val = dev->interface->read_register(REG_0x01);
    val |= REG_0x01_SCAN;
    dev->interface->write_register(REG_0x01, val);

    scanner_start_action(*dev, start_motor);

    switch (reg->state.motor_mode) {
        case MotorMode::PRIMARY: {
            if (reg->state.is_motor_on) {
                dev->advance_head_pos_by_session(ScanHeadId::PRIMARY);
            }
            break;
        }
        case MotorMode::PRIMARY_AND_SECONDARY: {
            if (reg->state.is_motor_on) {
                dev->advance_head_pos_by_session(ScanHeadId::PRIMARY);
                dev->advance_head_pos_by_session(ScanHeadId::SECONDARY);
            }
            break;
        }
        case MotorMode::SECONDARY: {
            if (reg->state.is_motor_on) {
                dev->advance_head_pos_by_session(ScanHeadId::SECONDARY);
            }
            break;
        }
    }
}


// Send the stop scan command
void CommandSetGl843::end_scan(Genesys_Device* dev, Genesys_Register_Set* reg,
                               bool check_stop) const
{
    DBG_HELPER_ARGS(dbg, "check_stop = %d", check_stop);

    // post scan gpio
    dev->interface->write_register(0x7e, 0x00);

    if (reg->state.is_xpa_on) {
        dev->cmd_set->set_xpa_lamp_power(*dev, false);
    }

    if (!dev->model->is_sheetfed) {
        scanner_stop_action(*dev);
    }
}

/** @brief Moves the slider to the home (top) position slowly
 * */
void CommandSetGl843::move_back_home(Genesys_Device* dev, bool wait_until_home) const
{
    scanner_move_back_home(*dev, wait_until_home);
}

// init registers for shading calibration shading calibration is done at dpihw
void CommandSetGl843::init_regs_for_shading(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                            Genesys_Register_Set& regs) const
{
    DBG_HELPER(dbg);
    int move;

    float calib_size_mm = 0;
    if (dev->settings.scan_method == ScanMethod::TRANSPARENCY ||
        dev->settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
    {
        calib_size_mm = dev->model->y_size_calib_ta_mm;
    } else {
        calib_size_mm = dev->model->y_size_calib_mm;
    }

    unsigned resolution = sensor.shading_resolution;

    unsigned channels = 3;
  const auto& calib_sensor = sanei_genesys_find_sensor(dev, resolution, channels,
                                                       dev->settings.scan_method);

    unsigned calib_pixels = 0;
    unsigned calib_pixels_offset = 0;

    if (should_calibrate_only_active_area(*dev, dev->settings)) {
        float offset = dev->model->x_offset_ta;
        // FIXME: we should use resolution here
        offset = static_cast<float>((offset * dev->settings.xres) / MM_PER_INCH);

        float size = dev->model->x_size_ta;
        size = static_cast<float>((size * dev->settings.xres) / MM_PER_INCH);

        calib_pixels_offset = static_cast<std::size_t>(offset);
        calib_pixels = static_cast<std::size_t>(size);
    } else {
        calib_pixels_offset = 0;
        calib_pixels = dev->model->x_size_calib_mm * resolution / MM_PER_INCH;
    }

    ScanFlag flags = ScanFlag::DISABLE_SHADING |
                     ScanFlag::DISABLE_GAMMA |
                     ScanFlag::DISABLE_BUFFER_FULL_MOVE;

    if (dev->settings.scan_method == ScanMethod::TRANSPARENCY ||
        dev->settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
    {
        // note: scanner_move_to_ta() function has already been called and the sensor is at the
        // transparency adapter
        move = static_cast<int>(dev->model->y_offset_calib_white_ta - dev->model->y_offset_sensor_to_ta);
        if (dev->model->model_id == ModelId::CANON_8600F && resolution == 2400) {
            move /= 2;
        }
        if (dev->model->model_id == ModelId::CANON_8600F && resolution == 4800) {
            move /= 4;
        }
        flags |= ScanFlag::USE_XPA;
    } else {
        move = static_cast<int>(dev->model->y_offset_calib_white);
    }

    move = static_cast<int>((move * resolution) / MM_PER_INCH);
    unsigned calib_lines = static_cast<unsigned>(calib_size_mm * resolution / MM_PER_INCH);

    ScanSession session;
    session.params.xres = resolution;
    session.params.yres = resolution;
    session.params.startx = calib_pixels_offset;
    session.params.starty = move;
    session.params.pixels = calib_pixels;
    session.params.lines = calib_lines;
    session.params.depth = 16;
    session.params.channels = channels;
    session.params.scan_method = dev->settings.scan_method;
    session.params.scan_mode = dev->settings.scan_mode;
    session.params.color_filter = dev->settings.color_filter;
    session.params.contrast_adjustment = dev->settings.contrast;
    session.params.brightness_adjustment = dev->settings.brightness;
    session.params.flags = flags;
    compute_session(dev, session, calib_sensor);

    init_regs_for_scan_session(dev, calib_sensor, &regs, session);

    dev->calib_session = session;
}

/**
 * This function sends gamma tables to ASIC
 */
void CommandSetGl843::send_gamma_table(Genesys_Device* dev, const Genesys_Sensor& sensor) const
{
    DBG_HELPER(dbg);
  int size;
  int i;

  size = 256;

  /* allocate temporary gamma tables: 16 bits words, 3 channels */
  std::vector<uint8_t> gamma(size * 2 * 3);

    std::vector<uint16_t> rgamma = get_gamma_table(dev, sensor, GENESYS_RED);
    std::vector<uint16_t> ggamma = get_gamma_table(dev, sensor, GENESYS_GREEN);
    std::vector<uint16_t> bgamma = get_gamma_table(dev, sensor, GENESYS_BLUE);

    // copy sensor specific's gamma tables
    for (i = 0; i < size; i++) {
        gamma[i * 2 + size * 0 + 0] = rgamma[i] & 0xff;
        gamma[i * 2 + size * 0 + 1] = (rgamma[i] >> 8) & 0xff;
        gamma[i * 2 + size * 2 + 0] = ggamma[i] & 0xff;
        gamma[i * 2 + size * 2 + 1] = (ggamma[i] >> 8) & 0xff;
        gamma[i * 2 + size * 4 + 0] = bgamma[i] & 0xff;
        gamma[i * 2 + size * 4 + 1] = (bgamma[i] >> 8) & 0xff;
    }

    dev->interface->write_gamma(0x28, 0x0000, gamma.data(), size * 2 * 3);
}

/* this function does the led calibration by scanning one line of the calibration
   area below scanner's top on white strip.

-needs working coarse/gain
*/
SensorExposure CommandSetGl843::led_calibration(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                                Genesys_Register_Set& regs) const
{
    return scanner_led_calibration(*dev, sensor, regs);
}

void CommandSetGl843::offset_calibration(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                         Genesys_Register_Set& regs) const
{
    scanner_offset_calibration(*dev, sensor, regs);
}

void CommandSetGl843::coarse_gain_calibration(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                              Genesys_Register_Set& regs, int dpi) const
{
    scanner_coarse_gain_calibration(*dev, sensor, regs, dpi);
}

// wait for lamp warmup by scanning the same line until difference
// between 2 scans is below a threshold
void CommandSetGl843::init_regs_for_warmup(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                           Genesys_Register_Set* reg) const
{
    DBG_HELPER(dbg);
    (void) sensor;

    unsigned channels = 3;
    unsigned resolution = dev->model->get_resolution_settings(dev->settings.scan_method)
                                     .get_nearest_resolution_x(600);

  const auto& calib_sensor = sanei_genesys_find_sensor(dev, resolution, channels,
                                                       dev->settings.scan_method);
    unsigned num_pixels = dev->model->x_size_calib_mm * resolution / MM_PER_INCH / 2;

  *reg = dev->reg;

    auto flags = ScanFlag::DISABLE_SHADING |
                 ScanFlag::DISABLE_GAMMA |
                 ScanFlag::SINGLE_LINE |
                 ScanFlag::IGNORE_STAGGER_OFFSET |
                 ScanFlag::IGNORE_COLOR_OFFSET;
    if (dev->settings.scan_method == ScanMethod::TRANSPARENCY ||
        dev->settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
    {
        flags |= ScanFlag::USE_XPA;
    }

    ScanSession session;
    session.params.xres = resolution;
    session.params.yres = resolution;
    session.params.startx = (num_pixels / 2) * resolution / calib_sensor.full_resolution;
    session.params.starty = 0;
    session.params.pixels = num_pixels;
    session.params.lines = 1;
    session.params.depth = dev->model->bpp_color_values.front();
    session.params.channels = channels;
    session.params.scan_method = dev->settings.scan_method;
    session.params.scan_mode = ScanColorMode::COLOR_SINGLE_PASS;
    session.params.color_filter = dev->settings.color_filter;
    session.params.contrast_adjustment = 0;
    session.params.brightness_adjustment = 0;
    session.params.flags = flags;

    compute_session(dev, session, calib_sensor);

    init_regs_for_scan_session(dev, calib_sensor, reg, session);

  sanei_genesys_set_motor_power(*reg, false);
}

/**
 * set up GPIO/GPOE for idle state
WRITE GPIO[17-21]= GPIO19
WRITE GPOE[17-21]= GPOE21 GPOE20 GPOE19 GPOE18
genesys_write_register(0xa8,0x3e)
GPIO(0xa8)=0x3e
 */
static void gl843_init_gpio(Genesys_Device* dev)
{
    DBG_HELPER(dbg);
    apply_registers_ordered(dev->gpo.regs, { 0x6e, 0x6f }, [&](const GenesysRegisterSetting& reg)
    {
        dev->interface->write_register(reg.address, reg.value);
    });
}


/* *
 * initialize ASIC from power on condition
 */
void CommandSetGl843::asic_boot(Genesys_Device* dev, bool cold) const
{
    DBG_HELPER(dbg);
  uint8_t val;

    if (cold) {
        dev->interface->write_register(0x0e, 0x01);
        dev->interface->write_register(0x0e, 0x00);
    }

  if(dev->usb_mode == 1)
    {
      val = 0x14;
    }
  else
    {
      val = 0x11;
    }
    dev->interface->write_0x8c(0x0f, val);

    // test CHKVER
    val = dev->interface->read_register(REG_0x40);
    if (val & REG_0x40_CHKVER) {
        val = dev->interface->read_register(0x00);
        DBG(DBG_info, "%s: reported version for genesys chip is 0x%02x\n", __func__, val);
    }

  /* Set default values for registers */
  gl843_init_registers (dev);

    if (dev->model->model_id == ModelId::CANON_8600F) {
        // turns on vref control for maximum current of the motor driver
        dev->interface->write_register(REG_0x6B, 0x72);
    } else {
        dev->interface->write_register(REG_0x6B, 0x02);
    }

    // Write initial registers
    dev->interface->write_registers(dev->reg);

  // Enable DRAM by setting a rising edge on bit 3 of reg 0x0b
    val = dev->reg.find_reg(0x0b).value & REG_0x0B_DRAMSEL;
    val = (val | REG_0x0B_ENBDRAM);
    dev->interface->write_register(REG_0x0B, val);
    dev->reg.find_reg(0x0b).value = val;

    if (dev->model->model_id == ModelId::CANON_8400F) {
        dev->interface->write_0x8c(0x1e, 0x01);
        dev->interface->write_0x8c(0x10, 0xb4);
        dev->interface->write_0x8c(0x0f, 0x02);
    }
    else if (dev->model->model_id == ModelId::CANON_8600F) {
        dev->interface->write_0x8c(0x10, 0xc8);
    } else if (dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7300 ||
               dev->model->model_id == ModelId::PLUSTEK_OPTICFILM_7500I)
    {
        dev->interface->write_0x8c(0x10, 0xd4);
    } else {
        dev->interface->write_0x8c(0x10, 0xb4);
    }

  /* CLKSET */
    int clock_freq = REG_0x0B_48MHZ;
    switch (dev->model->model_id) {
        case ModelId::CANON_8600F:
            clock_freq = REG_0x0B_60MHZ;
            break;
        case ModelId::PLUSTEK_OPTICFILM_7200I:
            clock_freq = REG_0x0B_30MHZ;
            break;
        case ModelId::PLUSTEK_OPTICFILM_7300:
        case ModelId::PLUSTEK_OPTICFILM_7500I:
            clock_freq = REG_0x0B_40MHZ;
            break;
        default:
            break;
    }

    val = (dev->reg.find_reg(0x0b).value & ~REG_0x0B_CLKSET) | clock_freq;

    dev->interface->write_register(REG_0x0B, val);
    dev->reg.find_reg(0x0b).value = val;

  /* prevent further writings by bulk write register */
  dev->reg.remove_reg(0x0b);

    // set RAM read address
    dev->interface->write_register(REG_0x29, 0x00);
    dev->interface->write_register(REG_0x2A, 0x00);
    dev->interface->write_register(REG_0x2B, 0x00);

    // setup gpio
    gl843_init_gpio(dev);
    dev->interface->sleep_ms(100);
}

/* *
 * initialize backend and ASIC : registers, motor tables, and gamma tables
 * then ensure scanner's head is at home
 */
void CommandSetGl843::init(Genesys_Device* dev) const
{
  DBG_INIT ();
    DBG_HELPER(dbg);

    sanei_genesys_asic_init(dev);
}

void CommandSetGl843::update_hardware_sensors(Genesys_Scanner* s) const
{
    DBG_HELPER(dbg);
  /* do what is needed to get a new set of events, but try to not lose
     any of them.
   */

    uint8_t val = s->dev->interface->read_register(REG_0x6D);
    DBG(DBG_io, "%s: read buttons_gpio value=0x%x\n", __func__, (int)val);

  switch (s->dev->model->gpio_id)
    {
        case GpioId::KVSS080:
            s->buttons[BUTTON_SCAN_SW].write((val & 0x04) == 0);
            break;
        case GpioId::G4050:
            s->buttons[BUTTON_SCAN_SW].write((val & 0x01) == 0);
            s->buttons[BUTTON_FILE_SW].write((val & 0x02) == 0);
            s->buttons[BUTTON_EMAIL_SW].write((val & 0x04) == 0);
            s->buttons[BUTTON_COPY_SW].write((val & 0x08) == 0);
            break;
        case GpioId::G4010:
            s->buttons[BUTTON_FILE_SW].write((val & 0x01) == 0);
            s->buttons[BUTTON_COPY_SW].write((val & 0x04) == 0);
            s->buttons[BUTTON_TRANSP_SW].write((val & 0x40) == 0);
            s->buttons[BUTTON_SCAN_SW].write((val & 0x08) == 0);
            break;
        case GpioId::CANON_4400F:
        case GpioId::CANON_8400F:
        default:
            break;
    }
}

void CommandSetGl843::update_home_sensor_gpio(Genesys_Device& dev) const
{
    DBG_HELPER(dbg);
    (void) dev;
}

/**
 * Send shading calibration data. The buffer is considered to always hold values
 * for all the channels.
 */
void CommandSetGl843::send_shading_data(Genesys_Device* dev, const Genesys_Sensor& sensor,
                                        uint8_t* data, int size) const
{
    DBG_HELPER(dbg);
    uint32_t final_size, i;
  uint8_t *buffer;
    int count;

    int offset = 0;
    unsigned length = size;

    if (dev->reg.get8(REG_0x01) & REG_0x01_SHDAREA) {
        offset = dev->session.params.startx * sensor.shading_resolution /
                 dev->session.params.xres;

        length = dev->session.output_pixels * sensor.shading_resolution /
                 dev->session.params.xres;

        offset += sensor.shading_pixel_offset;

        // 16 bit words, 2 words per color, 3 color channels
        length *= 2 * 2 * 3;
        offset *= 2 * 2 * 3;
    } else {
        offset += sensor.shading_pixel_offset * 2 * 2 * 3;
    }

    dev->interface->record_key_value("shading_offset", std::to_string(offset));
    dev->interface->record_key_value("shading_length", std::to_string(length));

  /* compute and allocate size for final data */
  final_size = ((length+251) / 252) * 256;
  DBG(DBG_io, "%s: final shading size=%04x (length=%d)\n", __func__, final_size, length);
  std::vector<uint8_t> final_data(final_size, 0);

  /* copy regular shading data to the expected layout */
  buffer = final_data.data();
  count = 0;
    if (offset < 0) {
        count += (-offset);
        length -= (-offset);
        offset = 0;
    }
    if (static_cast<int>(length) + offset > static_cast<int>(size)) {
        length = size - offset;
    }

  /* loop over calibration data */
  for (i = 0; i < length; i++)
    {
      buffer[count] = data[offset+i];
      count++;
      if ((count % (256*2)) == (252*2))
	{
	  count += 4*2;
	}
    }

    dev->interface->write_buffer(0x3c, 0, final_data.data(), count);
}

bool CommandSetGl843::needs_home_before_init_regs_for_scan(Genesys_Device* dev) const
{
    (void) dev;
    return true;
}

void CommandSetGl843::wait_for_motor_stop(Genesys_Device* dev) const
{
    (void) dev;
}

} // namespace gl843
} // namespace genesys