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sane-project-backends/backend/genesys/gl843.cpp

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91 KiB
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Czysty Wina Historia

/* 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, 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.
*/
#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)
{
GenesysRegister *r = sanei_genesys_get_address(regs, REG_0x9D);
int value = 1;
if (r != nullptr)
{
switch (r->value & 0x0c)
{
case 0x04:
value = 2;
break;
case 0x08:
value = 4;
break;
default:
value = 1;
}
}
DBG(DBG_io, "%s: step multiplier is %d\n", __func__, value);
return value;
}
/** copy sensor specific settings */
static void gl843_setup_sensor(Genesys_Device* dev, const Genesys_Sensor& sensor,
Genesys_Register_Set* regs)
{
DBG_HELPER(dbg);
for (const auto& custom_reg : sensor.custom_regs) {
regs->set8(custom_reg.address, custom_reg.value);
}
if (!has_flag(dev->model->flags, ModelFlag::FULL_HWDPI_MODE) &&
dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7200I &&
dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7300 &&
dev->model->model_id != ModelId::PLUSTEK_OPTICFILM_7500I)
{
regs->set8(0x7d, 0x90);
}
dev->segment_order = sensor.segment_order;
}
/** @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
// gl843_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);
}
const auto& sensor = sanei_genesys_find_sensor_any(dev);
sanei_genesys_set_dpihw(dev->reg, sensor, sensor.optical_res);
// 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);
}
}
// Send slope table for motor movement slope_table in machine byte order
static void gl843_send_slope_table(Genesys_Device* dev, int table_nr,
const std::vector<uint16_t>& slope_table,
int steps)
{
DBG_HELPER_ARGS(dbg, "table_nr = %d, steps = %d", table_nr, steps);
int i;
std::vector<uint8_t> table(steps * 2);
for (i = 0; i < steps; i++)
{
table[i * 2] = slope_table[i] & 0xff;
table[i * 2 + 1] = slope_table[i] >> 8;
}
if (dev->interface->is_mock()) {
dev->interface->record_slope_table(table_nr, slope_table);
}
// slope table addresses are fixed : 0x40000, 0x48000, 0x50000, 0x58000, 0x60000
// XXX STEF XXX USB 1.1 ? sanei_genesys_write_0x8c (dev, 0x0f, 0x14);
dev->interface->write_gamma(0x28, 0x40000 + 0x8000 * table_nr, table.data(), steps * 2);
}
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)
{
DBG(DBG_proc, "%s(): setting DAC %u\n", __func__,
static_cast<unsigned>(dev->model->adc_id));
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);
}
DBG(DBG_proc, "%s(): frontend reset complete\n", __func__);
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,
MotorFlag 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));
int use_fast_fed, coeff;
unsigned int lincnt;
unsigned feedl, dist;
GenesysRegister *r;
uint32_t z1, z2;
/* get step multiplier */
unsigned step_multiplier = gl843_get_step_multiplier (reg);
use_fast_fed = 0;
if ((scan_yres >= 300 && feed_steps > 900) || (has_flag(flags, MotorFlag::FEED))) {
use_fast_fed = 1;
}
lincnt=scan_lines;
reg->set24(REG_LINCNT, lincnt);
DBG(DBG_io, "%s: lincnt=%d\n", __func__, lincnt);
/* compute register 02 value */
r = sanei_genesys_get_address(reg, REG_0x02);
r->value = 0x00;
sanei_genesys_set_motor_power(*reg, true);
if (use_fast_fed) {
r->value |= REG_0x02_FASTFED;
} else {
r->value &= ~REG_0x02_FASTFED;
}
/* in case of automatic go home, move until home sensor */
if (has_flag(flags, MotorFlag::AUTO_GO_HOME)) {
r->value |= REG_0x02_AGOHOME | REG_0x02_NOTHOME;
}
/* disable backtracking */
if (has_flag(flags, MotorFlag::DISABLE_BUFFER_FULL_MOVE)
||(scan_yres>=2400 && dev->model->model_id != ModelId::CANON_4400F)
||(scan_yres>=sensor.optical_res))
{
r->value |= REG_0x02_ACDCDIS;
}
if (has_flag(flags, MotorFlag::REVERSE)) {
r->value |= REG_0x02_MTRREV;
} else {
r->value &= ~REG_0x02_MTRREV;
}
// scan and backtracking slope table
auto scan_table = sanei_genesys_slope_table(dev->model->asic_type, scan_yres, exposure,
dev->motor.base_ydpi, step_multiplier,
motor_profile);
gl843_send_slope_table(dev, SCAN_TABLE, scan_table.table, scan_table.steps_count);
gl843_send_slope_table(dev, BACKTRACK_TABLE, scan_table.table, scan_table.steps_count);
gl843_send_slope_table(dev, STOP_TABLE, scan_table.table, scan_table.steps_count);
reg->set8(REG_STEPNO, scan_table.steps_count / step_multiplier);
reg->set8(REG_FASTNO, scan_table.steps_count / step_multiplier);
reg->set8(REG_FSHDEC, scan_table.steps_count / 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);
gl843_send_slope_table(dev, FAST_TABLE, fast_table.table, fast_table.steps_count);
gl843_send_slope_table(dev, HOME_TABLE, fast_table.table, fast_table.steps_count);
reg->set8(REG_FMOVNO, fast_table.steps_count / 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);
}
/* substract acceleration distance from feedl */
feedl=feed_steps;
feedl <<= static_cast<unsigned>(motor_profile.step_type);
dist = scan_table.steps_count / step_multiplier;
if (use_fast_fed)
{
dist += (fast_table.steps_count / step_multiplier) * 2;
}
DBG(DBG_io2, "%s: acceleration distance=%d\n", __func__, dist);
/* 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);
DBG(DBG_io, "%s: feedl=%d\n", __func__, feedl);
/* doesn't seem to matter that much */
sanei_genesys_calculate_zmod(use_fast_fed,
exposure,
scan_table.table,
scan_table.steps_count / step_multiplier,
feedl,
scan_table.steps_count / step_multiplier,
&z1,
&z2);
if(scan_yres>600)
{
z1=0;
z2=0;
}
reg->set24(REG_Z1MOD, z1);
DBG(DBG_info, "%s: z1 = %d\n", __func__, z1);
reg->set24(REG_Z2MOD, z2);
DBG(DBG_info, "%s: z2 = %d\n", __func__, z2);
r = sanei_genesys_get_address(reg, REG_0x1E);
r->value &= 0xf0; /* 0 dummy lines */
r->value |= scan_dummy; /* dummy lines */
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.steps_count / step_multiplier);
/* Vref XXX STEF XXX : optical divider or step type ? */
r = sanei_genesys_get_address (reg, 0x80);
if (!has_flag(dev->model->flags, ModelFlag::FULL_HWDPI_MODE))
{
r->value = 0x50;
coeff = sensor.get_hwdpi_divisor_for_dpi(scan_yres);
if (dev->model->motor_id == MotorId::KVSS080) {
if(coeff>=1)
{
r->value |= 0x05;
}
}
else {
switch(coeff)
{
case 4:
r->value |= 0x0a;
break;
case 2:
r->value |= 0x0f;
break;
case 1:
r->value |= 0x0f;
break;
}
}
}
}
/** @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 channles used (1 or 3)
* @param depth bit depth of the scan (1, 8 or 16 bits)
* @param ccd_size_divisor true specifies how much x coordinates must be shrunk
* @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 dpihw;
unsigned int tgtime; /**> exposure time multiplier */
GenesysRegister *r;
/* tgtime */
tgtime = exposure / 65536 + 1;
DBG(DBG_io2, "%s: tgtime=%d\n", __func__, tgtime);
// to manage high resolution device while keeping good low resolution scanning speed, we make
// hardware dpi vary
dpihw = sensor.get_register_hwdpi(session.output_resolution);
DBG(DBG_io2, "%s: dpihw=%d\n", __func__, dpihw);
/* sensor parameters */
gl843_setup_sensor(dev, sensor, reg);
// resolution is divided according to CKSEL
unsigned ccd_pixels_per_system_pixel = sensor.ccd_pixels_per_system_pixel();
DBG(DBG_io2, "%s: ccd_pixels_per_system_pixel=%d\n", __func__, ccd_pixels_per_system_pixel);
dev->cmd_set->set_fe(dev, sensor, AFE_SET);
/* enable shading */
regs_set_optical_off(dev->model->asic_type, *reg);
r = sanei_genesys_get_address (reg, REG_0x01);
if (has_flag(session.params.flags, ScanFlag::DISABLE_SHADING) ||
has_flag(dev->model->flags, ModelFlag::NO_CALIBRATION) ||
session.use_host_side_calib)
{
r->value &= ~REG_0x01_DVDSET;
} else {
r->value |= REG_0x01_DVDSET;
}
bool use_shdarea = dpihw > 600;
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;
}
if (use_shdarea) {
r->value |= REG_0x01_SHDAREA;
} else {
r->value &= ~REG_0x01_SHDAREA;
}
r = sanei_genesys_get_address (reg, REG_0x03);
if (dev->model->model_id == ModelId::CANON_8600F) {
r->value |= REG_0x03_AVEENB;
} else {
r->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 */
r->value &= ~REG_0x03_XPASEL;
if (has_flag(session.params.flags, ScanFlag::USE_XPA)) {
r->value |= REG_0x03_XPASEL;
}
reg->state.is_xpa_on = has_flag(session.params.flags, ScanFlag::USE_XPA);
/* BW threshold */
r = sanei_genesys_get_address(reg, REG_0x2E);
r->value = dev->settings.threshold;
r = sanei_genesys_get_address(reg, REG_0x2F);
r->value = dev->settings.threshold;
/* monochrome / color scan */
r = sanei_genesys_get_address(reg, REG_0x04);
switch (session.params.depth) {
case 8:
r->value &= ~(REG_0x04_LINEART | REG_0x04_BITSET);
break;
case 16:
r->value &= ~REG_0x04_LINEART;
r->value |= REG_0x04_BITSET;
break;
}
r->value &= ~(REG_0x04_FILTER | REG_0x04_AFEMOD);
if (session.params.channels == 1)
{
switch (session.params.color_filter)
{
case ColorFilter::RED:
r->value |= 0x14;
break;
case ColorFilter::BLUE:
r->value |= 0x1c;
break;
case ColorFilter::GREEN:
r->value |= 0x18;
break;
default:
break; // should not happen
}
} else {
switch (dev->frontend.layout.type) {
case FrontendType::WOLFSON:
r->value |= 0x10; // pixel by pixel
break;
case FrontendType::ANALOG_DEVICES:
r->value |= 0x20; // slow color pixel by pixel
break;
default:
throw SaneException("Invalid frontend type %d",
static_cast<unsigned>(dev->frontend.layout.type));
}
}
sanei_genesys_set_dpihw(*reg, sensor, 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;
}
unsigned dpiset = session.output_resolution * session.ccd_size_divisor *
ccd_pixels_per_system_pixel;
if (sensor.dpiset_override != 0) {
dpiset = sensor.dpiset_override;
}
reg->set16(REG_DPISET, dpiset);
DBG(DBG_io2, "%s: dpiset used=%d\n", __func__, 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 ccd_size_divisor likely does not make sense
reg->set24(REG_MAXWD, (session.output_line_bytes / session.ccd_size_divisor) >> 1);
reg->set16(REG_LPERIOD, exposure / tgtime);
DBG(DBG_io2, "%s: exposure used=%d\n", __func__, exposure/tgtime);
r = sanei_genesys_get_address (reg, REG_DUMMY);
r->value = 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);
DBG(DBG_info, "%s : exposure=%d pixels\n", __func__, exposure);
DBG(DBG_info, "%s : scan_step_type=%d\n", __func__,
static_cast<unsigned>(motor_profile.step_type));
// now _LOGICAL_ optical values used are known, setup registers
gl843_init_optical_regs_scan(dev, sensor, reg, exposure, session);
/*** motor parameters ***/
MotorFlag mflags = MotorFlag::NONE;
if (has_flag(session.params.flags, ScanFlag::DISABLE_BUFFER_FULL_MOVE)) {
mflags |= MotorFlag::DISABLE_BUFFER_FULL_MOVE;
}
if (has_flag(session.params.flags, ScanFlag::FEEDING)) {
mflags |= MotorFlag::FEED;
}
if (has_flag(session.params.flags, ScanFlag::USE_XPA)) {
mflags |= MotorFlag::USE_XPA;
}
if (has_flag(session.params.flags, ScanFlag::REVERSE)) {
mflags |= MotorFlag::REVERSE;
}
gl843_init_motor_regs_scan(dev, sensor, session, reg, motor_profile, exposure, slope_dpi,
session.optical_line_count, dummy, session.params.starty, mflags);
dev->read_buffer.clear();
dev->read_buffer.alloc(session.buffer_size_read);
build_image_pipeline(dev, sensor, 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);
}
static float get_model_x_offset_ta(const Genesys_Device& dev,
const Genesys_Settings& settings)
{
if (dev.model->model_id == ModelId::CANON_8600F && settings.xres == 4800) {
return 85.0f;
}
if (dev.model->model_id == ModelId::CANON_4400F && settings.xres == 4800) {
return dev.model->x_offset_ta - 10.0;
}
return dev.model->x_offset_ta;
}
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: 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 = get_model_x_offset_ta(*dev, settings);
} else {
start = dev->model->x_offset;
}
start = start + settings.tl_x;
if ((dev->model->model_id == ModelId::CANON_4400F &&
settings.scan_method == ScanMethod::TRANSPARENCY) ||
dev->model->model_id == ModelId::CANON_8400F ||
dev->model->model_id == ModelId::CANON_8600F)
{
// FIXME: this is probably just an artifact of a bug elsewhere
start /= sensor.get_ccd_size_divisor_for_dpi(settings.xres);
}
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.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) {
DBG(DBG_io, "%s: skip_lines=%zu\n", __func__, 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:
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);
}
static bool should_calibrate_only_active_area(const Genesys_Device& dev,
const Genesys_Settings& settings)
{
if (settings.scan_method == ScanMethod::TRANSPARENCY ||
settings.scan_method == ScanMethod::TRANSPARENCY_INFRARED)
{
if (dev.model->model_id == ModelId::CANON_4400F && settings.xres >= 4800) {
return true;
}
if (dev.model->model_id == ModelId::CANON_8600F && settings.xres == 4800) {
return true;
}
}
return false;
}
// 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.get_logical_hwdpi(dev->settings.xres);
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 = get_model_x_offset_ta(*dev, dev->settings);
offset /= calib_sensor.get_ccd_size_divisor_for_dpi(resolution);
offset = static_cast<float>((offset * resolution) / MM_PER_INCH);
float size = dev->model->x_size_ta;
size /= calib_sensor.get_ccd_size_divisor_for_dpi(resolution);
size = static_cast<float>((size * resolution) / 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: 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);
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.flags = flags;
compute_session(dev, session, calib_sensor);
init_regs_for_scan_session(dev, calib_sensor, &regs, session);
dev->calib_session = session;
}
/** @brief set up registers for the actual scan
*/
void CommandSetGl843::init_regs_for_scan(Genesys_Device* dev, const Genesys_Sensor& sensor,
Genesys_Register_Set& regs) const
{
DBG_HELPER(dbg);
ScanSession session = calculate_scan_session(dev, sensor, dev->settings);
init_regs_for_scan_session(dev, sensor, &regs, 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
{
DBG_HELPER(dbg);
int avg[3], avga, avge;
int turn;
uint16_t expr, expg, expb;
// offset calibration is always done in color mode
unsigned channels = 3;
// take a copy, as we're going to modify exposure
auto calib_sensor = sanei_genesys_find_sensor(dev, sensor.optical_res, channels,
dev->settings.scan_method);
/* initial calibration reg values */
regs = dev->reg;
ScanSession session;
session.params.xres = calib_sensor.optical_res;
session.params.yres = dev->motor.base_ydpi;
session.params.startx = 0;
session.params.starty = 0;
session.params.pixels = dev->model->x_size_calib_mm * calib_sensor.optical_res / MM_PER_INCH;
session.params.lines = 1;
session.params.depth = 16;
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.flags = ScanFlag::DISABLE_SHADING |
ScanFlag::DISABLE_GAMMA |
ScanFlag::SINGLE_LINE |
ScanFlag::IGNORE_STAGGER_OFFSET |
ScanFlag::IGNORE_COLOR_OFFSET;
compute_session(dev, session, calib_sensor);
init_regs_for_scan_session(dev, calib_sensor, &regs, session);
dev->interface->write_registers(regs);
/*
we try to get equal bright leds here:
loop:
average per color
adjust exposure times
*/
expr = calib_sensor.exposure.red;
expg = calib_sensor.exposure.green;
expb = calib_sensor.exposure.blue;
turn = 0;
bool acceptable = false;
do
{
calib_sensor.exposure.red = expr;
calib_sensor.exposure.green = expg;
calib_sensor.exposure.blue = expb;
regs_set_exposure(dev->model->asic_type, regs, calib_sensor.exposure);
dev->interface->write_registers(regs);
DBG(DBG_info, "%s: starting first line reading\n", __func__);
dev->cmd_set->begin_scan(dev, calib_sensor, &regs, true);
if (is_testing_mode()) {
dev->interface->test_checkpoint("led_calibration");
move_back_home(dev, true);
return calib_sensor.exposure;
}
auto image = read_unshuffled_image_from_scanner(dev, session,
session.output_total_bytes_raw);
scanner_stop_action_no_move(*dev, regs);
if (DBG_LEVEL >= DBG_data)
{
char fn[30];
std::snprintf(fn, 30, "gl843_led_%02d.pnm", turn);
sanei_genesys_write_pnm_file(fn, image);
}
acceptable = true;
for (unsigned ch = 0; ch < channels; ch++) {
avg[ch] = 0;
for (std::size_t x = 0; x < image.get_width(); x++) {
avg[ch] += image.get_raw_channel(x, 0, ch);
}
avg[ch] /= image.get_width();
}
DBG(DBG_info, "%s: average: %d,%d,%d\n", __func__, avg[0], avg[1], avg[2]);
acceptable = true;
if (avg[0] < avg[1] * 0.95 || avg[1] < avg[0] * 0.95 ||
avg[0] < avg[2] * 0.95 || avg[2] < avg[0] * 0.95 ||
avg[1] < avg[2] * 0.95 || avg[2] < avg[1] * 0.95)
acceptable = false;
if (!acceptable)
{
avga = (avg[0] + avg[1] + avg[2]) / 3;
expr = (expr * avga) / avg[0];
expg = (expg * avga) / avg[1];
expb = (expb * avga) / avg[2];
/*
keep the resulting exposures below this value.
too long exposure drives the ccd into saturation.
we may fix this by relying on the fact that
we get a striped scan without shading, by means of
statistical calculation
*/
avge = (expr + expg + expb) / 3;
/* don't overflow max exposure */
if (avge > 3000)
{
expr = (expr * 2000) / avge;
expg = (expg * 2000) / avge;
expb = (expb * 2000) / avge;
}
if (avge < 50)
{
expr = (expr * 50) / avge;
expg = (expg * 50) / avge;
expb = (expb * 50) / avge;
}
}
scanner_stop_action(*dev);
turn++;
}
while (!acceptable && turn < 100);
DBG(DBG_info, "%s: acceptable exposure: %d,%d,%d\n", __func__, expr, expg, expb);
move_back_home(dev, true);
return calib_sensor.exposure;
}
/**
* average dark pixels of a 8 bits scan of a given channel
*/
static int dark_average_channel(const Image& image, unsigned black, unsigned channel)
{
auto channels = get_pixel_channels(image.get_format());
unsigned avg[3];
// computes average values on black margin
for (unsigned ch = 0; ch < channels; ch++) {
avg[ch] = 0;
unsigned count = 0;
// FIXME: start with the second line because the black pixels often have noise on the first
// line; the cause is probably incorrectly cleaned up previous scan
for (std::size_t y = 1; y < image.get_height(); y++) {
for (unsigned j = 0; j < black; j++) {
avg[ch] += image.get_raw_channel(j, y, ch);
count++;
}
}
if (count > 0) {
avg[ch] /= count;
}
DBG(DBG_info, "%s: avg[%d] = %d\n", __func__, ch, avg[ch]);
}
DBG(DBG_info, "%s: average = %d\n", __func__, avg[channel]);
return avg[channel];
}
/** @brief calibrate AFE offset
* Iterate doing scans at target dpi until AFE offset if correct. One
* color line is scanned at a time. Scanning head doesn't move.
* @param dev device to calibrate
*/
void CommandSetGl843::offset_calibration(Genesys_Device* dev, const Genesys_Sensor& sensor,
Genesys_Register_Set& regs) const
{
DBG_HELPER(dbg);
if (dev->frontend.layout.type != FrontendType::WOLFSON)
return;
unsigned channels;
int pass, resolution, lines;
int topavg[3], bottomavg[3], avg[3];
int top[3], bottom[3], black_pixels, pixels, factor, dpihw;
/* offset calibration is always done in color mode */
channels = 3;
lines = 8;
// compute divider factor to compute final pixels number
dpihw = sensor.get_logical_hwdpi(dev->settings.xres);
factor = sensor.optical_res / dpihw;
resolution = dpihw;
const auto& calib_sensor = sanei_genesys_find_sensor(dev, resolution, channels,
dev->settings.scan_method);
int target_pixels = dev->model->x_size_calib_mm * resolution / MM_PER_INCH;
int start_pixel = 0;
black_pixels = calib_sensor.black_pixels / factor;
if (should_calibrate_only_active_area(*dev, dev->settings)) {
float offset = get_model_x_offset_ta(*dev, dev->settings);
offset /= calib_sensor.get_ccd_size_divisor_for_dpi(resolution);
start_pixel = static_cast<int>((offset * resolution) / MM_PER_INCH);
float size = dev->model->x_size_ta;
size /= calib_sensor.get_ccd_size_divisor_for_dpi(resolution);
target_pixels = static_cast<int>((size * resolution) / MM_PER_INCH);
}
if (dev->model->model_id == ModelId::CANON_4400F &&
dev->settings.scan_method == ScanMethod::FLATBED)
{
return;
}
ScanFlag 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 = start_pixel;
session.params.starty = 0;
session.params.pixels = target_pixels;
session.params.lines = lines;
session.params.depth = 8;
session.params.channels = channels;
session.params.scan_method = dev->settings.scan_method;
session.params.scan_mode = ScanColorMode::COLOR_SINGLE_PASS;
session.params.color_filter = ColorFilter::RED;
session.params.flags = flags;
compute_session(dev, session, calib_sensor);
pixels = session.output_pixels;
DBG(DBG_io, "%s: dpihw =%d\n", __func__, dpihw);
DBG(DBG_io, "%s: factor =%d\n", __func__, factor);
DBG(DBG_io, "%s: resolution =%d\n", __func__, resolution);
DBG(DBG_io, "%s: pixels =%d\n", __func__, pixels);
DBG(DBG_io, "%s: black_pixels=%d\n", __func__, black_pixels);
init_regs_for_scan_session(dev, calib_sensor, &regs, session);
sanei_genesys_set_motor_power(regs, false);
// init gain and offset
for (unsigned ch = 0; ch < 3; ch++)
{
bottom[ch] = 10;
dev->frontend.set_offset(ch, bottom[ch]);
dev->frontend.set_gain(ch, 0);
}
dev->cmd_set->set_fe(dev, calib_sensor, AFE_SET);
// scan with bottom AFE settings
dev->interface->write_registers(regs);
DBG(DBG_info, "%s: starting first line reading\n", __func__);
dev->cmd_set->begin_scan(dev, calib_sensor, &regs, true);
if (is_testing_mode()) {
dev->interface->test_checkpoint("offset_calibration");
scanner_stop_action_no_move(*dev, regs);
return;
}
auto first_line = read_unshuffled_image_from_scanner(dev, session,
session.output_total_bytes_raw);
scanner_stop_action_no_move(*dev, regs);
if (DBG_LEVEL >= DBG_data)
{
char fn[40];
std::snprintf(fn, 40, "gl843_bottom_offset_%03d_%03d_%03d.pnm",
bottom[0], bottom[1], bottom[2]);
sanei_genesys_write_pnm_file(fn, first_line);
}
for (unsigned ch = 0; ch < 3; ch++) {
bottomavg[ch] = dark_average_channel(first_line, black_pixels, ch);
DBG(DBG_io2, "%s: bottom avg %d=%d\n", __func__, ch, bottomavg[ch]);
}
// now top value
for (unsigned ch = 0; ch < 3; ch++) {
top[ch] = 255;
dev->frontend.set_offset(ch, top[ch]);
}
dev->cmd_set->set_fe(dev, calib_sensor, AFE_SET);
// scan with top AFE values
dev->interface->write_registers(regs);
DBG(DBG_info, "%s: starting second line reading\n", __func__);
dev->cmd_set->begin_scan(dev, calib_sensor, &regs, true);
auto second_line = read_unshuffled_image_from_scanner(dev, session,
session.output_total_bytes_raw);
scanner_stop_action_no_move(*dev, regs);
for (unsigned ch = 0; ch < 3; ch++){
topavg[ch] = dark_average_channel(second_line, black_pixels, ch);
DBG(DBG_io2, "%s: top avg %d=%d\n", __func__, ch, topavg[ch]);
}
pass = 0;
std::vector<uint8_t> debug_image;
size_t debug_image_lines = 0;
std::string debug_image_info;
/* loop until acceptable level */
while ((pass < 32)
&& ((top[0] - bottom[0] > 1)
|| (top[1] - bottom[1] > 1) || (top[2] - bottom[2] > 1)))
{
pass++;
// settings for new scan
for (unsigned ch = 0; ch < 3; ch++) {
if (top[ch] - bottom[ch] > 1) {
dev->frontend.set_offset(ch, (top[ch] + bottom[ch]) / 2);
}
}
dev->cmd_set->set_fe(dev, calib_sensor, AFE_SET);
// scan with no move
dev->interface->write_registers(regs);
DBG(DBG_info, "%s: starting second line reading\n", __func__);
dev->cmd_set->begin_scan(dev, calib_sensor, &regs, true);
second_line = read_unshuffled_image_from_scanner(dev, session,
session.output_total_bytes_raw);
scanner_stop_action_no_move(*dev, regs);
if (DBG_LEVEL >= DBG_data)
{
char title[100];
std::snprintf(title, 100, "lines: %d pixels_per_line: %d offsets[0..2]: %d %d %d\n",
lines, pixels,
dev->frontend.get_offset(0),
dev->frontend.get_offset(1),
dev->frontend.get_offset(2));
debug_image_info += title;
std::copy(second_line.get_row_ptr(0),
second_line.get_row_ptr(0) + second_line.get_row_bytes() * second_line.get_height(),
std::back_inserter(debug_image));
debug_image_lines += lines;
}
for (unsigned ch = 0; ch < 3; ch++) {
avg[ch] = dark_average_channel(second_line, black_pixels, ch);
DBG(DBG_info, "%s: avg[%d]=%d offset=%d\n", __func__, ch, avg[ch],
dev->frontend.get_offset(ch));
}
// compute new boundaries
for (unsigned ch = 0; ch < 3; ch++) {
if (topavg[ch] >= avg[ch]) {
topavg[ch] = avg[ch];
top[ch] = dev->frontend.get_offset(ch);
} else {
bottomavg[ch] = avg[ch];
bottom[ch] = dev->frontend.get_offset(ch);
}
}
}
if (DBG_LEVEL >= DBG_data)
{
sanei_genesys_write_file("gl843_offset_all_desc.txt",
reinterpret_cast<const std::uint8_t*>(debug_image_info.data()),
debug_image_info.size());
sanei_genesys_write_pnm_file("gl843_offset_all.pnm",
debug_image.data(), session.params.depth, channels, pixels,
debug_image_lines);
}
DBG(DBG_info, "%s: offset=(%d,%d,%d)\n", __func__,
dev->frontend.get_offset(0),
dev->frontend.get_offset(1),
dev->frontend.get_offset(2));
}
/* alternative coarse gain calibration
this on uses the settings from offset_calibration and
uses only one scanline
*/
/*
with offset and coarse calibration we only want to get our input range into
a reasonable shape. the fine calibration of the upper and lower bounds will
be done with shading.
*/
void CommandSetGl843::coarse_gain_calibration(Genesys_Device* dev, const Genesys_Sensor& sensor,
Genesys_Register_Set& regs, int dpi) const
{
DBG_HELPER_ARGS(dbg, "dpi = %d", dpi);
int dpihw;
float coeff;
int lines;
int resolution;
if (dev->frontend.layout.type != FrontendType::WOLFSON)
return;
dpihw = sensor.get_logical_hwdpi(dpi);
// coarse gain calibration is always done in color mode
unsigned channels = 3;
/* follow CKSEL */
if (dev->model->sensor_id == SensorId::CCD_KVSS080) {
if(dev->settings.xres<sensor.optical_res)
{
coeff = 0.9f;
}
else
{
coeff=1.0;
}
}
else
{
coeff=1.0;
}
resolution=dpihw;
lines=10;
ScanFlag 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;
}
const auto& calib_sensor = sanei_genesys_find_sensor(dev, resolution, channels,
dev->settings.scan_method);
ScanSession session;
session.params.xres = resolution;
session.params.yres = resolution;
session.params.startx = 0;
session.params.starty = 0;
session.params.pixels = dev->model->x_size_calib_mm * resolution / MM_PER_INCH;
session.params.lines = lines;
session.params.depth = 8;
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.flags = flags;
compute_session(dev, session, calib_sensor);
std::size_t pixels = session.output_pixels;
try {
init_regs_for_scan_session(dev, calib_sensor, &regs, session);
} catch (...) {
catch_all_exceptions(__func__, [&](){ sanei_genesys_set_motor_power(regs, false); });
throw;
}
sanei_genesys_set_motor_power(regs, false);
dev->interface->write_registers(regs);
dev->cmd_set->set_fe(dev, calib_sensor, AFE_SET);
dev->cmd_set->begin_scan(dev, calib_sensor, &regs, true);
if (is_testing_mode()) {
dev->interface->test_checkpoint("coarse_gain_calibration");
scanner_stop_action(*dev);
move_back_home(dev, true);
return;
}
auto line = read_unshuffled_image_from_scanner(dev, session, session.output_total_bytes_raw);
scanner_stop_action_no_move(*dev, regs);
if (DBG_LEVEL >= DBG_data) {
sanei_genesys_write_pnm_file("gl843_gain.pnm", line);
}
// average value on each channel
for (unsigned ch = 0; ch < channels; ch++) {
std::vector<uint16_t> values;
// FIXME: start from the second line because the first line often has artifacts. Probably
// caused by unclean cleanup of previous scan
for (std::size_t x = pixels / 4; x < (pixels * 3 / 4); x++) {
values.push_back(line.get_raw_channel(x, 1, ch));
}
// pick target value at 95th percentile of all values. There may be a lot of black values
// in transparency scans for example
std::sort(values.begin(), values.end());
uint16_t curr_output = values[unsigned((values.size() - 1) * 0.95)];
float target_value = calib_sensor.gain_white_ref * coeff;
int code = compute_frontend_gain(curr_output, target_value, dev->frontend.layout.type);
dev->frontend.set_gain(ch, code);
DBG(DBG_proc, "%s: channel %d, max=%d, target=%d, setting:%d\n", __func__, ch, curr_output,
static_cast<int>(target_value), code);
}
if (dev->model->is_cis) {
uint8_t gain0 = dev->frontend.get_gain(0);
if (gain0 > dev->frontend.get_gain(1)) {
gain0 = dev->frontend.get_gain(1);
}
if (gain0 > dev->frontend.get_gain(2)) {
gain0 = dev->frontend.get_gain(2);
}
dev->frontend.set_gain(0, gain0);
dev->frontend.set_gain(1, gain0);
dev->frontend.set_gain(2, gain0);
}
if (channels == 1) {
dev->frontend.set_gain(0, dev->frontend.get_gain(1));
dev->frontend.set_gain(2, dev->frontend.get_gain(1));
}
scanner_stop_action(*dev);
move_back_home(dev, true);
}
// 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, int* channels,
int* total_size) const
{
DBG_HELPER(dbg);
int dpihw;
int resolution;
/* setup scan */
*channels=3;
resolution=600;
dpihw = sensor.get_logical_hwdpi(resolution);
resolution=dpihw;
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;
*total_size = num_pixels * 3 * 1;
*reg = dev->reg;
ScanSession session;
session.params.xres = resolution;
session.params.yres = resolution;
session.params.startx = (num_pixels / 2) * resolution / calib_sensor.optical_res;
session.params.starty = 0;
session.params.pixels = num_pixels;
session.params.lines = 1;
session.params.depth = 8;
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.flags = ScanFlag::DISABLE_SHADING |
ScanFlag::DISABLE_GAMMA |
ScanFlag::SINGLE_LINE |
ScanFlag::IGNORE_STAGGER_OFFSET |
ScanFlag::IGNORE_COLOR_OFFSET;
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);
scanner_move(*dev, dev->model->default_method, 300, Direction::FORWARD);
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, 0);
}
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);
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::CANON_4400F:
case GpioId::CANON_8400F:
default:
break;
}
}
/** @brief move sensor to transparency adaptor
* Move sensor to the calibration of the transparency adapator (XPA).
* @param dev device to use
*/
void CommandSetGl843::move_to_ta(Genesys_Device* dev) const
{
DBG_HELPER(dbg);
const auto& resolution_settings = dev->model->get_resolution_settings(dev->model->default_method);
float resolution = resolution_settings.get_min_resolution_y();
unsigned multiplier = 16;
if (dev->model->model_id == ModelId::CANON_8400F ||
dev->model->model_id == ModelId::CANON_4400F) {
multiplier = 4;
}
unsigned feed = static_cast<unsigned>(multiplier * (dev->model->y_offset_sensor_to_ta * resolution) /
MM_PER_INCH);
scanner_move(*dev, dev->model->default_method, feed, Direction::FORWARD);
}
/** @brief search for a full width black or white strip.
* This function searches for a black or white stripe across the scanning area.
* When searching backward, the searched area must completely be of the desired
* color since this area will be used for calibration which scans forward.
* @param dev scanner device
* @param forward true if searching forward, false if searching backward
* @param black true if searching for a black strip, false for a white strip
*/
void CommandSetGl843::search_strip(Genesys_Device* dev, const Genesys_Sensor& sensor,
bool forward, bool black) const
{
DBG_HELPER_ARGS(dbg, "%s %s", black ? "black" : "white", forward ? "forward" : "reverse");
unsigned channels;
Genesys_Register_Set local_reg;
int dpi;
unsigned int pass, count, found, x, y;
dev->cmd_set->set_fe(dev, sensor, AFE_SET);
scanner_stop_action(*dev);
/* set up for a gray scan at lowest dpi */
dpi = sanei_genesys_get_lowest_dpi(dev);
channels = 1;
const auto& calib_sensor = sanei_genesys_find_sensor(dev, dpi, channels,
dev->settings.scan_method);
/* 10 MM */
/* lines = (10 * dpi) / MM_PER_INCH; */
/* shading calibation is done with dev->motor.base_ydpi */
unsigned lines = static_cast<unsigned>(dev->model->y_size_calib_mm * dpi / MM_PER_INCH);
unsigned pixels = dev->model->x_size_calib_mm * dpi / MM_PER_INCH;
dev->set_head_pos_zero(ScanHeadId::PRIMARY);
local_reg = dev->reg;
ScanSession session;
session.params.xres = dpi;
session.params.yres = dpi;
session.params.startx = 0;
session.params.starty = 0;
session.params.pixels = pixels;
session.params.lines = lines;
session.params.depth = 8;
session.params.channels = channels;
session.params.scan_method = dev->settings.scan_method;
session.params.scan_mode = ScanColorMode::GRAY;
session.params.color_filter = ColorFilter::RED;
session.params.flags = ScanFlag::DISABLE_SHADING | ScanFlag::DISABLE_SHADING;
if (!forward) {
session.params.flags = ScanFlag::REVERSE;
}
compute_session(dev, session, calib_sensor);
init_regs_for_scan_session(dev, calib_sensor, &local_reg, session);
dev->interface->write_registers(local_reg);
dev->cmd_set->begin_scan(dev, calib_sensor, &local_reg, true);
if (is_testing_mode()) {
dev->interface->test_checkpoint("search_strip");
scanner_stop_action(*dev);
return;
}
wait_until_buffer_non_empty(dev);
// now we're on target, we can read data
auto data = read_unshuffled_image_from_scanner(dev, session,
session.output_total_bytes_raw);
scanner_stop_action(*dev);
pass = 0;
if (DBG_LEVEL >= DBG_data)
{
char fn[40];
std::snprintf(fn, 40, "gl843_search_strip_%s_%s%02d.pnm",
black ? "black" : "white", forward ? "fwd" : "bwd", pass);
sanei_genesys_write_pnm_file(fn, data);
}
/* loop until strip is found or maximum pass number done */
found = 0;
while (pass < 20 && !found)
{
dev->interface->write_registers(local_reg);
// now start scan
dev->cmd_set->begin_scan(dev, calib_sensor, &local_reg, true);
wait_until_buffer_non_empty(dev);
// now we're on target, we can read data
data = read_unshuffled_image_from_scanner(dev, session, session.output_total_bytes_raw);
scanner_stop_action(*dev);
if (DBG_LEVEL >= DBG_data)
{
char fn[40];
std::snprintf(fn, 40, "gl843_search_strip_%s_%s%02d.pnm",
black ? "black" : "white", forward ? "fwd" : "bwd", pass);
sanei_genesys_write_pnm_file(fn, data);
}
/* search data to find black strip */
/* when searching forward, we only need one line of the searched color since we
* will scan forward. But when doing backward search, we need all the area of the
* same color */
if (forward)
{
for (y = 0; y < lines && !found; y++)
{
count = 0;
/* count of white/black pixels depending on the color searched */
for (x = 0; x < pixels; x++)
{
/* when searching for black, detect white pixels */
if (black && data.get_raw_channel(x, y, 0) > 90) {
count++;
}
/* when searching for white, detect black pixels */
if (!black && data.get_raw_channel(x, y, 0) < 60) {
count++;
}
}
/* at end of line, if count >= 3%, line is not fully of the desired color
* so we must go to next line of the buffer */
/* count*100/pixels < 3 */
if ((count * 100) / pixels < 3)
{
found = 1;
DBG(DBG_data, "%s: strip found forward during pass %d at line %d\n", __func__,
pass, y);
}
else
{
DBG(DBG_data, "%s: pixels=%d, count=%d (%d%%)\n", __func__, pixels, count,
(100 * count) / pixels);
}
}
}
else /* since calibration scans are done forward, we need the whole area
to be of the required color when searching backward */
{
count = 0;
for (y = 0; y < lines; y++)
{
/* count of white/black pixels depending on the color searched */
for (x = 0; x < pixels; x++)
{
// when searching for black, detect white pixels
if (black && data.get_raw_channel(x, y, 0) > 90) {
count++;
}
// when searching for white, detect black pixels
if (!black && data.get_raw_channel(x, y, 0) < 60) {
count++;
}
}
}
/* at end of area, if count >= 3%, area is not fully of the desired color
* so we must go to next buffer */
if ((count * 100) / (pixels * lines) < 3)
{
found = 1;
DBG(DBG_data, "%s: strip found backward during pass %d \n", __func__, pass);
}
else
{
DBG(DBG_data, "%s: pixels=%d, count=%d (%d%%)\n", __func__, pixels, count,
(100 * count) / pixels);
}
}
pass++;
}
if (found)
{
DBG(DBG_info, "%s: %s strip found\n", __func__, black ? "black" : "white");
}
else
{
throw SaneException(SANE_STATUS_UNSUPPORTED, "%s strip not found", black ? "black" : "white");
}
}
/**
* 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, length, i;
uint8_t *buffer;
int count,offset;
GenesysRegister *r;
uint16_t strpixel, endpixel, startx;
offset=0;
length=size;
r = sanei_genesys_get_address(&dev->reg, REG_0x01);
if (r->value & REG_0x01_SHDAREA)
{
/* recompute STRPIXEL used shading calibration so we can
* compute offset within data for SHDAREA case */
// FIXME: the following is likely incorrect
// start coordinate in optical dpi coordinates
startx = (sensor.dummy_pixel / sensor.ccd_pixels_per_system_pixel()) / dev->session.hwdpi_divisor;
startx *= dev->session.pixel_count_multiplier;
/* current scan coordinates */
strpixel = dev->session.pixel_startx;
endpixel = dev->session.pixel_endx;
if (dev->model->model_id == ModelId::CANON_4400F ||
dev->model->model_id == ModelId::CANON_8600F)
{
int half_ccd_factor = dev->session.optical_resolution /
sensor.get_logical_hwdpi(dev->session.output_resolution);
strpixel /= half_ccd_factor * sensor.ccd_pixels_per_system_pixel();
endpixel /= half_ccd_factor * sensor.ccd_pixels_per_system_pixel();
}
/* 16 bit words, 2 words per color, 3 color channels */
offset=(strpixel-startx)*2*2*3;
length=(endpixel-strpixel)*2*2*3;
DBG(DBG_info, "%s: STRPIXEL=%d, ENDPIXEL=%d, startx=%d\n", __func__, strpixel, endpixel,
startx);
}
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;
/* 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;
}
std::unique_ptr<CommandSet> create_gl843_cmd_set()
{
return std::unique_ptr<CommandSet>(new CommandSetGl843{});
}
} // namespace gl843
} // namespace genesys
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