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selphy_print/backend_mitsu70x.c

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/*
* Mitsubishi CP-D70/D707 Photo Printer CUPS backend -- libusb-1.0 version
*
* (c) 2013-2015 Solomon Peachy <pizza@shaftnet.org>
*
* The latest version of this program can be found at:
*
* http://git.shaftnet.org/cgit/selphy_print.git
*
* 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 3 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.
*
* [http://www.gnu.org/licenses/gpl-3.0.html]
*
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <signal.h>
#define BACKEND mitsu70x_backend
#include "backend_common.h"
#define USB_VID_MITSU 0x06D3
#define USB_PID_MITSU_D70X 0x3B30
#define USB_PID_MITSU_K60 0x3B31
//#define USB_PID_MITSU_D80 XXXXXX
#define USB_VID_KODAK 0x040a
#define USB_PID_KODAK305 0x404f
//#define USB_VID_FUJIFILM XXXXXX
//#define USB_PID_FUJI_ASK300 XXXXXX
//#define ENABLE_CORRTABLES
/* Private data stucture */
struct mitsu70x_ctx {
struct libusb_device_handle *dev;
uint8_t endp_up;
uint8_t endp_down;
int type;
uint8_t *databuf;
int datalen;
int matte;
uint16_t jobid;
uint16_t rows;
uint16_t cols;
#ifdef ENABLE_CORRTABLES
struct mitsu70x_corrdata *corrdata;
struct mitsu70x_corrdatalens *corrdatalens;
char *laminatefname;
#endif
};
/* Printer data structures */
struct mitsu70x_jobstatus {
uint8_t hdr[4];
uint16_t jobid;
uint16_t mecha_no;
uint8_t job_status[4];
uint8_t memory;
uint8_t power;
uint8_t mecha_status[2];
uint8_t temperature;
uint8_t error_status[3];
uint8_t reserved[6];
} __attribute__((packed));
struct mitsu70x_jobs {
uint8_t hdr[4];
uint16_t dummy;
uint16_t jobid_0;
uint8_t job0_status[4];
uint16_t jobid_1;
uint8_t job1_status[4];
// XXX are there more?
} __attribute__((packed));
#define TEMPERATURE_NORMAL 0x00
#define TEMPERATURE_PREHEAT 0x40
#define TEMPERATURE_COOLING 0x80
#define MECHA_STATUS_INIT 0x80
#define MECHA_STATUS_FEED 0x50
#define MECHA_STATUS_LOAD 0x40
#define MECHA_STATUS_PRINT 0x20
#define MECHA_STATUS_IDLE 0x00
#define JOB_STATUS0_NONE 0x00
#define JOB_STATUS0_DATA 0x10
#define JOB_STATUS0_QUEUE 0x20
#define JOB_STATUS0_PRINT 0x50
#define JOB_STATUS0_ASSIGN 0x70 // XXX undefined.
#define JOB_STATUS0_END 0x80
#define JOB_STATUS1_PRINT_MEDIALOAD 0x10
#define JOB_STATUS1_PRINT_PRE_Y 0x20
#define JOB_STATUS1_PRINT_Y 0x30
#define JOB_STATUS1_PRINT_PRE_M 0x40
#define JOB_STATUS1_PRINT_M 0x50
#define JOB_STATUS1_PRINT_PRE_C 0x60
#define JOB_STATUS1_PRINT_C 0x70
#define JOB_STATUS1_PRINT_PRE_OC 0x80
#define JOB_STATUS1_PRINT_OC 0x90
#define JOB_STATUS1_PRINT_EJECT 0xA0
#define JOB_STATUS1_END_OK 0x00
#define JOB_STATUS1_END_MECHA 0x10 // 0x10...0x7f
#define JOB_STATUS1_END_HEADER 0x80
#define JOB_STATUS1_END_PRINT 0x90
#define JOB_STATUS1_END_INTERRUPT 0xA0
#define JOB_STATUS2_END_HEADER_ERROR 0x00
#define JOB_STATUS2_END_HEADER_MEMORY 0x10
#define JOB_STATUS2_END_PRINT_MEDIA 0x00
#define JOB_STATUS2_END_PRINT_PREVERR 0x10
#define JOB_STATUS2_END_INT_TIMEOUT 0x00
#define JOB_STATUS2_END_INT_CANCEL 0x10
#define JOB_STATUS2_END_INT_DISCON 0x20
/* Error codes */
#define ERROR_STATUS0_NOSTRIPBIN 0x01
#define ERROR_STATUS0_NORIBBON 0x02
#define ERROR_STATUS0_NOPAPER 0x03
#define ERROR_STATUS0_MEDIAMISMATCH 0x04
#define ERROR_STATUS0_RIBBONCNTEND 0x05
#define ERROR_STATUS0_BADRIBBON 0x06
#define ERROR_STATUS0_BADJOBPARAM 0x07
#define ERROR_STATUS0_PAPEREND 0x08
#define ERROR_STATUS0_RIBBONEND 0x09
#define ERROR_STATUS0_DOOROPEN_IDLE 0x0A
#define ERROR_STATUS0_DOOROPEN_PRNT 0x0B
#define ERROR_STATUS0_POWEROFF 0x0C // nonsense.. heh.
#define ERROR_STATUS0_NOMCOP 0x0D
#define ERROR_STATUS0_RIBBONSKIP1 0x0E
#define ERROR_STATUS0_RIBBONSKIP2 0x0F
#define ERROR_STATUS0_RIBBONJAM 0x10
#define ERROR_STATUS0_RIBBON_OTHER 0x11 // 0x11->0x1F
#define ERROR_STATUS0_PAPER_JAM 0x20 // 0x20->0x2F
#define ERROR_STATUS0_MECHANICAL 0x30 // 0x30->0x39
#define ERROR_STATUS0_RFID 0x3A
#define ERROR_STATUS0_FLASH 0x3B
#define ERROR_STATUS0_EEPROM 0x3C
#define ERROR_STATUS0_PREHEAT 0x3D
#define ERROR_STATUS0_MDASTATE 0x3E
#define ERROR_STATUS0_PSUFANLOCKED 0x3F
#define ERROR_STATUS0_OTHERS 0x40 // 0x40..?
/* Error classifications */
#define ERROR_STATUS1_PAPER 0x01
#define ERROR_STATUS1_RIBBON 0x02
#define ERROR_STATUS1_SETTING 0x03
#define ERROR_STATUS1_OPEN 0x05
#define ERROR_STATUS1_NOSTRIPBIN 0x06
#define ERROR_STATUS1_PAPERJAM 0x07
#define ERROR_STATUS1_RIBBONSYS 0x08
#define ERROR_STATUS1_MECHANICAL 0x09
#define ERROR_STATUS1_ELECTRICAL 0x0A
#define ERROR_STATUS1_FIRMWARE 0x0E
#define ERROR_STATUS1_OTHER 0x0F
/* Error recovery conditions */
#define ERROR_STATUS2_AUTO 0x00
#define ERROR_STATUS2_RELOAD_PAPER 0x01
#define ERROR_STATUS2_RELOAD_RIBBON 0x02
#define ERROR_STATUS2_CHANGE_BOTH 0x03
#define ERROR_STATUS2_CHANGE_ONE 0x04
#define ERROR_STATUS2_CLOSEUNIT 0x05
#define ERROR_STATUS2_ATTACHSTRIPBIN 0x06
#define ERROR_STATUS2_CLEARJAM 0x07
#define ERROR_STATUS2_CHECKRIBBON 0x08
#define ERROR_STATUS2_OPENCLOSEUNIT 0x0A
#define ERROR_STATUS2_POWEROFF 0x0F
struct mitsu70x_status_deck {
uint8_t mecha_status[2];
uint8_t temperature;
uint8_t error_status[3];
uint8_t rsvd_a[10];
uint8_t media_brand;
uint8_t media_type;
uint8_t rsvd_b[2];
uint16_t capacity; /* media capacity */
uint16_t remain; /* media remaining */
uint8_t rsvd_c[2];
uint16_t rsvd_d;
uint16_t prints; /* lifetime prints on deck? */
uint16_t rsvd_e[17];
} __attribute__((packed));
struct mitsu70x_status_ver {
char ver[6];
uint16_t checksum; /* Presumably BE */
} __attribute__((packed));
struct mitsu70x_printerstatus_resp {
uint8_t hdr[4];
uint8_t unk[36];
int16_t model[6]; /* LE, UTF-16 */
int16_t serno[6]; /* LE, UTF-16 */
struct mitsu70x_status_ver vers[7];
uint8_t null[8];
struct mitsu70x_status_deck lower;
struct mitsu70x_status_deck upper;
} __attribute__((packed));
struct mitsu70x_memorystatus_resp {
uint8_t hdr[3];
uint8_t memory;
uint8_t size;
uint8_t rsvd;
} __attribute__((packed));
struct mitsu70x_hdr {
uint8_t hdr[4]; /* 1b 5a 54 XX */
uint16_t jobid;
uint8_t zero0[10];
uint16_t cols;
uint16_t rows;
uint16_t lamcols;
uint16_t lamrows;
uint8_t speed;
uint8_t zero1[7];
uint8_t deck;
uint8_t zero2[7];
uint8_t laminate; /* 00 == on, 01 == off */
uint8_t laminate_mode;
uint8_t zero3[6];
uint8_t multicut;
uint8_t zero4[15];
uint8_t pad[448];
} __attribute__((packed));
#ifdef ENABLE_CORRTABLES
/* Correction data definitions */
#define CORRDATA_DEF
struct mitsu70x_corrdata {
uint16_t liney[2730];
uint16_t linem[2730];
uint16_t linec[2730];
uint16_t gnmby[256]; // B->Y conversion matrix
uint16_t gnmgm[256]; // G->M conversion matrix
uint16_t gnmrc[256]; // R->C conversion matrix
double fm[256];
double ksp[128];
double ksm[128];
double osp[128];
double osm[128];
double kp[11];
double km[11];
double hk[4];
uint16_t speed[3];
double fh[5]; /* only 4 in length on D70 Normal/Superfine */
double shk[72];
double uh[101];
uint16_t rolk[13]; /* Missing on D70x family */
uint32_t rev[76]; /* Missing on D70x and ASK300 */
};
struct mitsu70x_corrdatalens {
size_t liney;
size_t linem;
size_t linec;
size_t gnmby;
size_t gnmgm;
size_t gnmrc;
size_t fm;
size_t ksp;
size_t ksm;
size_t osp;
size_t osm;
size_t kp;
size_t km;
size_t hk;
size_t speed;
size_t fh;
size_t shk;
size_t uh;
size_t rolk;
size_t rev;
};
#include "D70/CPD70N01.h" // Normal/Fine
#include "D70/CPD70S01.h" // Superfine
#include "D70/CPD70U01.h" // Ultrafine
//#include "D70/CPD80E01.h" // ???
#include "D70/CPD80N01.h" // Normal/Fine
#include "D70/CPD80S01.h" // Superfine
#include "D70/CPD80U01.h" // Ultrafine
#include "D70/ASK300T1.h" // Normal/Fine
#include "D70/ASK300T3.h" // Superfine/Ultrafine
#include "D70/CPS60T01.h" // Normal/Fine
#include "D70/CPS60T03.h" // Superfine/Ultrafine
#include "D70/EK305T01.h" // Normal/Fine
#include "D70/EK305T03.h" // Superfine/Ultrafine
#endif
/* Error dumps, etc */
static char *mitsu70x_mechastatus(uint8_t *sts)
{
switch(sts[0]) {
case MECHA_STATUS_INIT:
return "Initializing";
case MECHA_STATUS_FEED:
return "Paper Feeding/Cutting";
case MECHA_STATUS_LOAD:
return "Media Loading";
case MECHA_STATUS_PRINT:
return "Printing";
case MECHA_STATUS_IDLE:
return "Idle";
default:
break;
}
return "Unknown Mechanical Status";
}
static char *mitsu70x_jobstatuses(uint8_t *sts)
{
switch(sts[0]) {
case JOB_STATUS0_NONE:
return "No Job";
case JOB_STATUS0_DATA:
return "Data transfer";
case JOB_STATUS0_QUEUE:
return "Queued for printing";
case JOB_STATUS0_PRINT:
switch(sts[1]) {
case JOB_STATUS1_PRINT_MEDIALOAD:
return "Media loading\n";
case JOB_STATUS1_PRINT_PRE_Y:
return "Waiting to print yellow plane";
case JOB_STATUS1_PRINT_Y:
return "Printing yellow plane";
case JOB_STATUS1_PRINT_PRE_M:
return "Waiting to print magenta plane";
case JOB_STATUS1_PRINT_M:
return "Printing magenta plane";
case JOB_STATUS1_PRINT_PRE_C:
return "Waiting to print cyan plane";
case JOB_STATUS1_PRINT_C:
return "Printing cyan plane";
case JOB_STATUS1_PRINT_PRE_OC:
return "Waiting to laminate page";
case JOB_STATUS1_PRINT_OC:
return "Laminating page";
case JOB_STATUS1_PRINT_EJECT:
return "Ejecting page";
default:
return "Unknown 'Print' status1\n";
}
break;
case JOB_STATUS0_ASSIGN:
return "Unknown 'Assignment' status1\n";
case JOB_STATUS0_END:
switch(sts[1]) {
case JOB_STATUS1_END_OK:
return "Normal End";
case JOB_STATUS1_END_HEADER:
case JOB_STATUS1_END_PRINT:
switch(sts[2]) {
case JOB_STATUS2_END_PRINT_MEDIA:
return "Incorrect mediasize";
case JOB_STATUS2_END_PRINT_PREVERR:
return "Previous job terminated abnormally";
default:
return "Unknown 'End Print' status2";
}
break;
case JOB_STATUS1_END_INTERRUPT:
switch(sts[2]) {
case JOB_STATUS2_END_INT_TIMEOUT:
return "Timeout";
case JOB_STATUS2_END_INT_CANCEL:
return "Job cancelled";
case JOB_STATUS2_END_INT_DISCON:
return "Printer disconnected";
default:
return "Unknown 'End Print' status2";
}
break;
default:
if (sts[1] >= 0x10 && sts[1] <= 0x7f)
return "Mechanical Error";
else
return "Unknown 'End' status1";
}
break;
default:
break;
}
return "Unknown status0";
}
static char *mitsu70x_errorclass(uint8_t *err)
{
switch(err[1]) {
case ERROR_STATUS1_PAPER:
return "Paper";
case ERROR_STATUS1_RIBBON:
return "Ribbon";
case ERROR_STATUS1_SETTING:
return "Job settings";
case ERROR_STATUS1_OPEN:
return "Cover open";
case ERROR_STATUS1_NOSTRIPBIN:
return "No cut bin";
case ERROR_STATUS1_PAPERJAM:
return "Paper jam";
case ERROR_STATUS1_RIBBONSYS:
return "Ribbon system";
case ERROR_STATUS1_MECHANICAL:
return "Mechanical";
case ERROR_STATUS1_ELECTRICAL:
return "Electrical";
case ERROR_STATUS1_FIRMWARE:
return "Firmware";
case ERROR_STATUS1_OTHER:
return "Other";
default:
break;
}
return "Unknown error class";
}
static char *mitsu70x_errorrecovery(uint8_t *err)
{
switch(err[1]) {
case ERROR_STATUS2_AUTO:
return "Automatic recovery";
case ERROR_STATUS2_RELOAD_PAPER:
return "Reload or change paper";
case ERROR_STATUS2_RELOAD_RIBBON:
return "Reload or change ribbon";
case ERROR_STATUS2_CHANGE_BOTH:
return "Change paper and ribbon";
case ERROR_STATUS2_CHANGE_ONE:
return "Change paper or ribbon";
case ERROR_STATUS2_CLOSEUNIT:
return "Close printer";
case ERROR_STATUS2_ATTACHSTRIPBIN:
return "Attach Strip Bin";
case ERROR_STATUS2_CLEARJAM:
return "Remove and reload paper";
case ERROR_STATUS2_CHECKRIBBON:
return "Check ribbon and reload paper";
case ERROR_STATUS2_OPENCLOSEUNIT:
return "Open then close printer";
case ERROR_STATUS2_POWEROFF:
return "Power-cycle printer";
default:
break;
}
return "Unknown recovery";
}
static char *mitsu70x_errors(uint8_t *err)
{
switch(err[0]) {
case ERROR_STATUS0_NOSTRIPBIN:
return "Strip bin not attached";
case ERROR_STATUS0_NORIBBON:
return "No ribbon detected";
case ERROR_STATUS0_NOPAPER:
return "No paper loaded";
case ERROR_STATUS0_MEDIAMISMATCH:
return "Ribbon/Paper mismatch";
case ERROR_STATUS0_RIBBONCNTEND:
return "Ribbon count end";
case ERROR_STATUS0_BADRIBBON:
return "Illegal Ribbon";
case ERROR_STATUS0_BADJOBPARAM:
return "Job does not match loaded media";
case ERROR_STATUS0_PAPEREND:
return "End of paper detected";
case ERROR_STATUS0_RIBBONEND:
return "End of ribbon detected";
case ERROR_STATUS0_DOOROPEN_IDLE:
case ERROR_STATUS0_DOOROPEN_PRNT:
return "Printer door open";
case ERROR_STATUS0_POWEROFF:
return "Printer powered off"; // nonsense..
case ERROR_STATUS0_RIBBONSKIP1:
case ERROR_STATUS0_RIBBONSKIP2:
return "Ribbon skipped";
case ERROR_STATUS0_RIBBONJAM:
return "Ribbon stuck to paper";
case ERROR_STATUS0_RFID:
return "RFID read error";
case ERROR_STATUS0_FLASH:
return "FLASH read error";
case ERROR_STATUS0_EEPROM:
return "EEPROM read error";
case ERROR_STATUS0_PREHEAT:
return "Preheating unit time out";
case ERROR_STATUS0_MDASTATE:
return "Unknown MDA state";
case ERROR_STATUS0_PSUFANLOCKED:
return "Power supply fan locked up";
default:
break;
}
if (err[0] >= ERROR_STATUS0_RIBBON_OTHER &&
err[0] < ERROR_STATUS0_PAPER_JAM) {
return "Unknown ribbon error";
// XXX use err[1]/err[2] codes?
}
if (err[0] >= ERROR_STATUS0_PAPER_JAM &&
err[0] < ERROR_STATUS0_MECHANICAL) {
return "Paper jam";
// XXX use err[1]/err[2] codes?
}
if (err[0] >= ERROR_STATUS0_MECHANICAL &&
err[0] < ERROR_STATUS0_RFID) {
return "Unknown mechanical error";
// XXX use err[1]/err[2] codes?
}
return "Unknown error";
}
#define CMDBUF_LEN 512
#define READBACK_LEN 256
static void *mitsu70x_init(void)
{
struct mitsu70x_ctx *ctx = malloc(sizeof(struct mitsu70x_ctx));
if (!ctx) {
ERROR("Memory Allocation Failure!\n");
return NULL;
}
memset(ctx, 0, sizeof(struct mitsu70x_ctx));
return ctx;
}
static void mitsu70x_attach(void *vctx, struct libusb_device_handle *dev,
uint8_t endp_up, uint8_t endp_down, uint8_t jobid)
{
struct mitsu70x_ctx *ctx = vctx;
struct libusb_device *device;
struct libusb_device_descriptor desc;
ctx->jobid = jobid;
if (!ctx->jobid)
jobid++;
ctx->dev = dev;
ctx->endp_up = endp_up;
ctx->endp_down = endp_down;
device = libusb_get_device(dev);
libusb_get_device_descriptor(device, &desc);
ctx->type = lookup_printer_type(&mitsu70x_backend,
desc.idVendor, desc.idProduct);
}
static void mitsu70x_teardown(void *vctx) {
struct mitsu70x_ctx *ctx = vctx;
if (!ctx)
return;
if (ctx->databuf)
free(ctx->databuf);
free(ctx);
}
static int mitsu70x_read_parse(void *vctx, int data_fd) {
struct mitsu70x_ctx *ctx = vctx;
uint8_t hdr[1024];
int i, remain;
struct mitsu70x_hdr *mhdr = (struct mitsu70x_hdr*)(hdr + sizeof(struct mitsu70x_hdr));
if (!ctx)
return CUPS_BACKEND_FAILED;
if (ctx->databuf) {
free(ctx->databuf);
ctx->databuf = NULL;
}
ctx->matte = 0;
/* Read in initial header */
remain = sizeof(hdr);
while (remain > 0) {
i = read(data_fd, hdr + sizeof(hdr) - remain, remain);
if (i == 0)
return CUPS_BACKEND_CANCEL;
if (i < 0)
return CUPS_BACKEND_CANCEL;
remain -= i;
}
/* Sanity check */
if (hdr[0] != 0x1b ||
hdr[1] != 0x45 ||
hdr[2] != 0x57 ||
hdr[3] != 0x55) {
ERROR("Unrecognized data format!\n");
return CUPS_BACKEND_CANCEL;
}
// XXX sanity-check second header chunk for destined printer...?
#ifdef ENABLE_CORRTABLES
/* Figure out the correction data table to use */
if (ctx->type == P_MITSU_D70X) {
struct mitsu70x_hdr *print = (struct mitsu70x_hdr *) &hdr[512];
ctx->laminatefname = "D70MAT01.raw";
if (print->speed == 3) {
ctx->corrdata = &CPD70S01_data;
ctx->corrdatalens = &CPD70S01_lengths;
} else if (print->speed == 4) {
ctx->corrdata = &CPD70U01_data;
ctx->corrdatalens = &CPD70U01_lengths;
} else {
ctx->corrdata = &CPD70N01_data;
ctx->corrdatalens = &CPD70N01_lengths;
}
} else if (ctx->type == P_MITSU_D80) {
struct mitsu70x_hdr *print = (struct mitsu70x_hdr *) &hdr[512];
ctx->laminatefname = "D80MAT01.raw";
if (print->speed == 3) {
ctx->corrdata = &CPD80S01_data;
ctx->corrdatalens = &CPD80S01_lengths;
} else if (print->speed == 4) {
ctx->corrdata = &CPD80U01_data;
ctx->corrdatalens = &CPD80U01_lengths;
} else {
ctx->corrdata = &CPD80N01_data;
ctx->corrdatalens = &CPD80N01_lengths;
}
// XXX what about CPD80**E**01?
} else if (ctx->type == P_MITSU_K60) {
struct mitsu70x_hdr *print = (struct mitsu70x_hdr *) &hdr[512];
if (print->speed == 3 || print->speed == 4) {
ctx->corrdata = &CPS60T03_data;
ctx->corrdatalens = &CPS60T03_lengths;
} else {
ctx->corrdata = &CPS60T01_data;
ctx->corrdatalens = &CPS60T01_lengths;
}
ctx->laminatefname = "S60MAT02.raw";
} else if (ctx->type == P_KODAK_305) {
struct mitsu70x_hdr *print = (struct mitsu70x_hdr *) &hdr[512];
ctx->laminatefname = "EK305MAT.raw"; // XXX same as K60
if (print->speed == 3 || print->speed == 4) {
ctx->corrdata = &EK305T03_data;
ctx->corrdatalens = &EK305T03_lengths;
} else {
ctx->corrdata = &EK305T01_data;
ctx->corrdatalens = &EK305T01_lengths;
}
} else if (ctx->type == P_FUJI_ASK300) {
struct mitsu70x_hdr *print = (struct mitsu70x_hdr *) &hdr[512];
ctx->laminatefname = "ASK300M2.raw"; // XXX same as D70
if (print->speed == 3 || print->speed == 4) {
ctx->corrdata = &ASK300T3_data;
ctx->corrdatalens = &ASK300T3_lengths;
} else {
ctx->corrdata = &ASK300T1_data;
ctx->corrdatalens = &ASK300T1_lengths;
}
}
#endif
/* Work out printjob size */
ctx->cols = be16_to_cpu(mhdr->cols);
ctx->rows = be16_to_cpu(mhdr->rows);
remain = ctx->rows * ctx->cols * 2;
remain = (remain + 511) / 512 * 512; /* Round to nearest 512 bytes. */
remain *= 3; /* One for each plane */
if (!mhdr->laminate && mhdr->laminate_mode) {
i = be16_to_cpu(mhdr->lamcols) * be16_to_cpu(mhdr->lamrows) * 2;
i = (i + 511) / 512 * 512; /* Round to nearest 512 bytes. */
remain += i;
ctx->matte = 1;
}
ctx->databuf = malloc(sizeof(hdr) + remain);
if (!ctx->databuf) {
ERROR("Memory allocation failure!\n");
return CUPS_BACKEND_FAILED;
}
memcpy(ctx->databuf, &hdr, sizeof(hdr));
ctx->datalen += sizeof(hdr);
/* Read in the spool data */
while(remain) {
i = read(data_fd, ctx->databuf + ctx->datalen, remain);
if (i == 0)
return CUPS_BACKEND_CANCEL;
if (i < 0)
return CUPS_BACKEND_CANCEL;
ctx->datalen += i;
remain -= i;
}
return CUPS_BACKEND_OK;
}
static int mitsu70x_get_jobstatus(struct mitsu70x_ctx *ctx, struct mitsu70x_jobstatus *resp, uint16_t jobid)
{
uint8_t cmdbuf[CMDBUF_LEN];
int num, ret;
/* Send Printer Query */
memset(cmdbuf, 0, CMDBUF_LEN);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x56;
cmdbuf[2] = 0x31;
cmdbuf[3] = 0x30; // XXX 30 == specific, 31 = "all"
cmdbuf[4] = (jobid >> 8) & 0xff;
cmdbuf[5] = jobid & 0xff;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 6)))
return ret;
memset(resp, 0, sizeof(*resp));
ret = read_data(ctx->dev, ctx->endp_up,
(uint8_t*) resp, sizeof(*resp), &num);
if (ret < 0)
return ret;
if (num != sizeof(*resp)) {
ERROR("Short Read! (%d/%d)\n", num, (int)sizeof(*resp));
return 4;
}
return 0;
}
static int mitsu70x_get_jobs(struct mitsu70x_ctx *ctx, struct mitsu70x_jobs *resp)
{
uint8_t cmdbuf[CMDBUF_LEN];
int num, ret;
/* Send Printer Query */
memset(cmdbuf, 0, CMDBUF_LEN);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x56;
cmdbuf[2] = 0x31;
cmdbuf[3] = 0x31;
cmdbuf[4] = 0x00;
cmdbuf[5] = 0x00;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 6)))
return ret;
memset(resp, 0, sizeof(*resp));
ret = read_data(ctx->dev, ctx->endp_up,
(uint8_t*) resp, sizeof(*resp), &num);
if (ret < 0)
return ret;
if (num != sizeof(*resp)) {
ERROR("Short Read! (%d/%d)\n", num, (int)sizeof(*resp));
return 4;
}
return 0;
}
static int mitsu70x_get_memorystatus(struct mitsu70x_ctx *ctx, struct mitsu70x_memorystatus_resp *resp)
{
uint8_t cmdbuf[CMDBUF_LEN];
uint16_t tmp;
int num;
int ret;
memset(cmdbuf, 0, CMDBUF_LEN);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x56;
cmdbuf[2] = 0x33;
cmdbuf[3] = 0x00;
tmp = cpu_to_be16(ctx->cols);
memcpy(cmdbuf + 4, &tmp, 2);
tmp = cpu_to_be16(ctx->rows);
memcpy(cmdbuf + 6, &tmp, 2);
cmdbuf[8] = ctx->matte ? 0x80 : 0x00;
cmdbuf[9] = 0x00;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 10)))
return CUPS_BACKEND_FAILED;
/* Read in the printer status */
ret = read_data(ctx->dev, ctx->endp_up,
(uint8_t*) resp, sizeof(*resp), &num);
if (ret < 0)
return CUPS_BACKEND_FAILED;
if (num != sizeof(*resp)) {
ERROR("Short Read! (%d/%d)\n", num, (int)sizeof(*resp));
return CUPS_BACKEND_FAILED;
}
/* Make sure response is sane */
if (resp->hdr[0] != 0xe4 ||
resp->hdr[1] != 0x56 ||
resp->hdr[2] != 0x33) {
ERROR("Unknown response from printer\n");
return CUPS_BACKEND_FAILED;
}
return 0;
}
static int mitsu70x_get_printerstatus(struct mitsu70x_ctx *ctx, struct mitsu70x_printerstatus_resp *resp)
{
uint8_t cmdbuf[CMDBUF_LEN];
int num, ret;
/* Send Printer Query */
memset(cmdbuf, 0, CMDBUF_LEN);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x56;
cmdbuf[2] = 0x32;
cmdbuf[3] = 0x30;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 4)))
return ret;
memset(resp, 0, sizeof(*resp));
ret = read_data(ctx->dev, ctx->endp_up,
(uint8_t*) resp, sizeof(*resp), &num);
if (ret < 0)
return ret;
if (num != sizeof(*resp)) {
ERROR("Short Read! (%d/%d)\n", num, (int)sizeof(*resp));
return 4;
}
return 0;
}
static int mitsu70x_cancel_job(struct mitsu70x_ctx *ctx, uint16_t jobid)
{
uint8_t cmdbuf[4];
int ret;
/* Send Job cancel. No response. */
memset(cmdbuf, 0, 4);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x44;
cmdbuf[2] = (jobid >> 8) & 0xff;
cmdbuf[3] = jobid & 0xffl;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 4)))
return ret;
return 0;
}
static int mitsu70x_set_sleeptime(struct mitsu70x_ctx *ctx, uint8_t time)
{
uint8_t cmdbuf[4];
int ret;
/* Send Job cancel. No response. */
memset(cmdbuf, 0, 4);
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x53;
cmdbuf[2] = 0x53;
cmdbuf[3] = time;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 4)))
return ret;
return 0;
}
static int mitsu70x_main_loop(void *vctx, int copies) {
struct mitsu70x_ctx *ctx = vctx;
struct mitsu70x_jobstatus jobstatus;
struct mitsu70x_jobs jobs;
struct mitsu70x_hdr *hdr = (struct mitsu70x_hdr*) (ctx->databuf + sizeof(struct mitsu70x_hdr));
int ret;
if (!ctx)
return CUPS_BACKEND_FAILED;
INFO("Waiting for printer idle...\n");
ret = mitsu70x_get_jobs(ctx, &jobs);
if (ret)
return CUPS_BACKEND_FAILED;
top:
/* Query job status for jobid 0 (global) */
ret = mitsu70x_get_jobstatus(ctx, &jobstatus, 0x0000);
if (ret)
return CUPS_BACKEND_FAILED;
/* Make sure we're awake! */
if (jobstatus.power) {
// XXX or should we only send the first 4 bytes? */
INFO("Waking up printer...\n");
if ((ret = send_data(ctx->dev, ctx->endp_down,
ctx->databuf, sizeof(struct mitsu70x_hdr))))
return CUPS_BACKEND_FAILED;
sleep(1);
goto top;
}
/* Make sure temperature is sane */
if (jobstatus.temperature == TEMPERATURE_COOLING) {
INFO("Printer cooling down...\n");
sleep(1);
goto top;
}
/* See if we hit a printer error. */
if (jobstatus.error_status[0]) {
ERROR("%s/%s -> %s: %02x/%02x/%02x\n",
mitsu70x_errorclass(jobstatus.error_status),
mitsu70x_errors(jobstatus.error_status),
mitsu70x_errorrecovery(jobstatus.error_status),
jobstatus.error_status[0],
jobstatus.error_status[1],
jobstatus.error_status[2]);
return CUPS_BACKEND_STOP;
}
/* Perform memory status query */
{
struct mitsu70x_memorystatus_resp memory;
INFO("Checking Memory availability\n");
ret = mitsu70x_get_memorystatus(ctx, &memory);
if (ret)
return CUPS_BACKEND_FAILED;
/* Check size is sane */
if (memory.size || memory.memory == 0xff) {
ERROR("Unsupported print size!\n");
return CUPS_BACKEND_CANCEL;
}
if (memory.memory) {
INFO("Printer buffers full, retrying!\n");
sleep(1);
goto top;
}
}
/* Make sure we don't have any jobid collisions */
while (hdr->jobid == be16_to_cpu(jobs.jobid_0) ||
hdr->jobid == be16_to_cpu(jobs.jobid_1)) {
ctx->jobid++;
if (!ctx->jobid)
ctx->jobid++;
}
/* Set jobid */
hdr->jobid = cpu_to_be16(ctx->jobid);
/* Set deck */
if (ctx->type == P_MITSU_D70X) {
hdr->deck = 0; /* D70 use automatic deck selection */
// XXX alternatively route it based on state and media? */
} else {
hdr->deck = 1; /* All others only have a "lower" deck. */
}
/* Matte operation requires Ultrafine/superfine */
if (ctx->matte) {
if (ctx->type != P_MITSU_D70X) {
hdr->speed = 0x04; /* Force UltraFine */
} else {
hdr->speed = 0x03; /* Force SuperFine */
}
}
/* Any other fixups? */
#if 1 // XXX is this actually needed on the K60 and EK305?
if (ctx->type != P_MITSU_D70X &&
ctx->cols == 0x0748 &&
ctx->rows == 0x04c2) {
hdr->multicut = 1;
}
#endif
/* We're clear to send data over! */
INFO("Sending Print Job\n");
if ((ret = send_data(ctx->dev, ctx->endp_down,
ctx->databuf + sizeof(struct mitsu70x_hdr),
sizeof(struct mitsu70x_hdr))))
return CUPS_BACKEND_FAILED;
{
/* K60 and 305 need data sent in 256K chunks, but the first
chunk needs to subtract the length of the 512-byte header */
int chunk = 256*1024 - sizeof(struct mitsu70x_hdr);
int sent = 1024;
while (ctx->datalen > 0) {
if ((ret = send_data(ctx->dev, ctx->endp_down,
ctx->databuf + sent, chunk)))
return CUPS_BACKEND_FAILED;
sent += chunk;
chunk = ctx->datalen - sent;
if (chunk > 256*1024)
chunk = 256*1024;
}
}
/* Then wait for completion, if so desired.. */
INFO("Waiting for printer to acknowledge completion\n");
do {
/* Query job status for our used jobid */
ret = mitsu70x_get_jobstatus(ctx, &jobstatus, ctx->jobid);
if (ret)
return CUPS_BACKEND_FAILED;
/* See if we hit a printer error. */
if (jobstatus.error_status[0]) {
ERROR("%s/%s -> %s: %02x/%02x/%02x\n",
mitsu70x_errorclass(jobstatus.error_status),
mitsu70x_errors(jobstatus.error_status),
mitsu70x_errorrecovery(jobstatus.error_status),
jobstatus.error_status[0],
jobstatus.error_status[1],
jobstatus.error_status[2]);
return CUPS_BACKEND_STOP;
}
INFO("%s: %x/%x/%x/%x\n",
mitsu70x_jobstatuses(jobstatus.job_status),
jobstatus.job_status[0],
jobstatus.job_status[1],
jobstatus.job_status[2],
jobstatus.job_status[3]);
if (jobstatus.job_status[0] == JOB_STATUS0_END) {
if (jobstatus.job_status[1] ||
jobstatus.job_status[2] ||
jobstatus.job_status[3]) {
ERROR("Abnormal exit: %02x/%02x/%02x\n",
jobstatus.error_status[0],
jobstatus.error_status[1],
jobstatus.error_status[2]);
return CUPS_BACKEND_STOP;
}
/* Job complete */
break;
}
if (fast_return) {
INFO("Fast return mode enabled.\n");
break;
}
} while(1);
/* Clean up */
if (terminate)
copies = 1;
INFO("Print complete (%d copies remaining)\n", copies - 1);
if (copies && --copies) {
goto top;
}
return CUPS_BACKEND_OK;
}
static void mitsu70x_dump_printerstatus(struct mitsu70x_printerstatus_resp *resp)
{
unsigned int i;
INFO("Model : ");
for (i = 0 ; i < 6 ; i++) {
DEBUG2("%c", le16_to_cpu(resp->model[i]) & 0x7f);
}
DEBUG2("\n");
INFO("Serial Number : ");
for (i = 0 ; i < 6 ; i++) {
DEBUG2("%c", le16_to_cpu(resp->serno[i]) & 0x7f);
}
DEBUG2("\n");
for (i = 0 ; i < 7 ; i++) {
char buf[7];
if (resp->vers[i].ver[5] == '@') /* "DUMMY@" */
continue;
memcpy(buf, resp->vers[i].ver, 6);
buf[6] = 0;
INFO("Component #%d ID: %s (checksum %04x)\n",
i, buf, be16_to_cpu(resp->vers[i].checksum));
}
if (resp->upper.mecha_status[0] == MECHA_STATUS_INIT) { /* IOW, Not present */
INFO("Mechanical Status: %s\n",
mitsu70x_mechastatus(resp->lower.mecha_status));
if (resp->lower.error_status[0]) {
INFO("Error Status: %s/%s -> %s\n",
mitsu70x_errorclass(resp->lower.error_status),
mitsu70x_errors(resp->lower.error_status),
mitsu70x_errorrecovery(resp->lower.error_status));
}
INFO("Media type: %02x/%02x\n",
resp->lower.media_brand,
resp->lower.media_type);
INFO("Prints remaining: %03d/%03d\n",
be16_to_cpu(resp->lower.remain),
be16_to_cpu(resp->lower.capacity));
} else {
INFO("Mechanical Status: Upper: %s\n"
" Lower: %s\n",
mitsu70x_mechastatus(resp->upper.mecha_status),
mitsu70x_mechastatus(resp->lower.mecha_status));
if (resp->upper.error_status[0]) {
INFO("Upper Error Status: %s/%s -> %s\n",
mitsu70x_errorclass(resp->upper.error_status),
mitsu70x_errors(resp->upper.error_status),
mitsu70x_errorrecovery(resp->upper.error_status));
}
if (resp->lower.error_status[0]) {
INFO("Lower Error Status: %s/%s -> %s\n",
mitsu70x_errorclass(resp->lower.error_status),
mitsu70x_errors(resp->lower.error_status),
mitsu70x_errorrecovery(resp->lower.error_status));
}
INFO("Media type: Lower: %02x/%02x\n"
" Upper: %02x/%02x\n",
resp->lower.media_brand,
resp->lower.media_type,
resp->upper.media_brand,
resp->upper.media_type);
INFO("Prints remaining: Lower: %03d/%03d\n"
" Upper: %03d/%03d\n",
be16_to_cpu(resp->lower.remain),
be16_to_cpu(resp->lower.capacity),
be16_to_cpu(resp->upper.remain),
be16_to_cpu(resp->upper.capacity));
}
}
static int mitsu70x_query_status(struct mitsu70x_ctx *ctx)
{
struct mitsu70x_printerstatus_resp resp;
struct mitsu70x_jobs jobs;
int ret;
// XXX only for D70 family...?
ret = mitsu70x_get_printerstatus(ctx, &resp);
if (!ret)
mitsu70x_dump_printerstatus(&resp);
ret = mitsu70x_get_jobs(ctx, &jobs);
if (!ret) {
INFO("JOB0 ID : %06d\n", jobs.jobid_0);
INFO("JOB0 status : %s\n", mitsu70x_jobstatuses(jobs.job0_status));
INFO("JOB1 ID : %06d\n", jobs.jobid_1);
INFO("JOB1 status : %s\n", mitsu70x_jobstatuses(jobs.job1_status));
// XXX are there more?
}
return ret;
}
static int mitsu70x_query_serno(struct libusb_device_handle *dev, uint8_t endp_up, uint8_t endp_down, char *buf, int buf_len)
{
int ret, i;
struct mitsu70x_printerstatus_resp resp = { .hdr = { 0 } };
struct mitsu70x_ctx ctx = {
.dev = dev,
.endp_up = endp_up,
.endp_down = endp_down,
};
ret = mitsu70x_get_printerstatus(&ctx, &resp);
if (buf_len > 6) /* Will we ever have a buffer under 6 bytes? */
buf_len = 6;
for (i = 0 ; i < buf_len ; i++) {
*buf++ = le16_to_cpu(resp.serno[i]) & 0x7f;
}
*buf = 0; /* Null-terminate the returned string */
return ret;
}
static void mitsu70x_cmdline(void)
{
DEBUG("\t\t[ -s ] # Query status\n");
DEBUG("\t\t[ -f ] # Use fast return mode\n");
DEBUG("\t\t[ -k num ] # Set standby time (1-60 minutes, 0 disables)\n");
DEBUG("\t\t[ -X jobid ] # Abort a printjob\n");}
static int mitsu70x_cmdline_arg(void *vctx, int argc, char **argv)
{
struct mitsu70x_ctx *ctx = vctx;
int i, j = 0;
if (!ctx)
return -1;
while ((i = getopt(argc, argv, GETOPT_LIST_GLOBAL "sX:k:")) >= 0) {
switch(i) {
GETOPT_PROCESS_GLOBAL
case 'k':
j = mitsu70x_set_sleeptime(ctx, atoi(optarg));
break;
case 's':
j = mitsu70x_query_status(ctx);
break;
case 'X':
j = mitsu70x_cancel_job(ctx, atoi(optarg));
break;
default:
break; /* Ignore completely */
}
if (j) return j;
}
return 0;
}
/* Exported */
struct dyesub_backend mitsu70x_backend = {
.name = "Mitsubishi CP-D70/D707/K60/D80",
.version = "0.38WIP",
.uri_prefix = "mitsu70x",
.cmdline_usage = mitsu70x_cmdline,
.cmdline_arg = mitsu70x_cmdline_arg,
.init = mitsu70x_init,
.attach = mitsu70x_attach,
.teardown = mitsu70x_teardown,
.read_parse = mitsu70x_read_parse,
.main_loop = mitsu70x_main_loop,
.query_serno = mitsu70x_query_serno,
.devices = {
{ USB_VID_MITSU, USB_PID_MITSU_D70X, P_MITSU_D70X, ""},
{ USB_VID_MITSU, USB_PID_MITSU_K60, P_MITSU_K60, ""},
// { USB_VID_MITSU, USB_PID_MITSU_D80, P_MITSU_D80, ""},
{ USB_VID_KODAK, USB_PID_KODAK305, P_KODAK_305, ""},
// { USB_VID_FUJIFILM, USB_PID_FUJI_ASK300, P_FUJI_ASK300, ""},
{ 0, 0, 0, ""}
}
};
/* Mitsubish CP-D70DW/CP-D707DW/CP-K60DW-S/CP-D80DW/Kodak 305 data format
Spool file consists of two headers followed by three image planes
and an optional lamination data plane. All blocks are rounded up to
a 512-byte boundary.
All multi-byte numbers are big endian, ie MSB first.
Header 1: (Init) (AKA Wake Up)
1b 45 57 55 00 00 00 00 00 00 00 00 00 00 00 00
(padded by NULLs to a 512-byte boundary)
Header 2: (Header)
1b 5a 54 PP JJ JJ 00 00 00 00 00 00 00 00 00 00
XX XX YY YY QQ QQ ZZ ZZ SS 00 00 00 00 00 00 00
UU 00 00 00 00 00 00 00 00 TT 00 00 00 00 00 00
RR 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
(padded by NULLs to a 512-byte boundary)
PP == 0x01 on D70x/D80, 0x02 on K60, 0x90 on K305, 0x04 on DSx80
JJ JJ == Job ID, can leave at 00 00
XX XX == columns
YY YY == rows
QQ QQ == lamination columns (equal to XX XX)
ZZ ZZ == lamination rows (YY YY + 12)
SS == Print mode: 00 = Fine, 03 = SuperFine (D70x/D80/DSx80 only), 04 = UltraFine
(Matte requires Superfine or Ultrafine)
UU == 00 = Auto, 01 = Lower Deck (required for !D70x), 02 = Upper Deck
TT == lamination: 00 glossy, 02 matte.
RR == 00 (normal), 01 = (Double-cut 4x6), 05 = (double-cut 2x6)
Data planes:
16-bit data, rounded up to 512-byte block (XX * YY * 2 bytes)
Lamination plane: (only present if QQ and ZZ are nonzero)
16-byte data, rounded up to 512-byte block (QQ * ZZ * 2 bytes)
********************************************************************
Command format:
-> 1b 56 32 30
<- [256 byte payload]
PRINTER STATUS
e4 56 32 30 00 00 00 00 00 00 00 00 00 00 00 00 .V20............
00 00 00 00 00 00 00 00 00 00 00 80 00 00 00 00 ................
44 80 00 00 5f 00 00 3d 43 00 50 00 44 00 37 00 D..._..=C.P.D.7.
30 00 44 00 30 00 30 00 31 00 31 00 31 00 37 00 0.D.0.0.1.1.1.7.
33 31 36 54 31 33 21 a3 33 31 35 42 31 32 f5 e5 316T13!.315B12..
33 31 39 42 31 31 a3 fb 33 31 38 45 31 32 50 0d 319B11..318E12P.
33 31 37 41 32 32 a3 82 44 55 4d 4d 59 40 00 00 317A22..DUMMY@..
44 55 4d 4d 59 40 00 00 00 00 00 00 00 00 00 00 DUMMY@..........
LOWER DECK STATUS
00 00 00 00 00 00 02 04 3f 00 00 04 96 00 00 00 MM MM: media capacity
ff 0f 01 00 MM MM NN NN 00 00 00 00 05 28 75 80 NN NN: prints remaining
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
alt (some sort of error state)
00 00 00 0a 05 05 01 d5 38 00 00 00 14 00 00 00
ff ff ff ff ff ff ff ff ff ff 00 00 00 27 72 80
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
UPPER DECK STATUS (if present)
XX XX 00 00 00 00 01 ee 3d 00 00 06 39 00 00 00 MM MM: media capacity
ff 02 00 00 MM MM NN NN 00 00 00 00 06 67 78 00 NN NN: prints remaining
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00 XX XX: 0x80 00 if no deck
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
alt (no deck present)
80 00 00 00 00 00 00 ff ff 00 00 00 00 00 00 00
ff ff ff ff ff ff ff ff ff ff 00 00 00 00 80 00
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00
-> 1b 56 31 30 00 00
<- [26 byte payload]
CP-D707DW:
e4 56 31 30 00 00 00 XX YY ZZ 00 00 TT 00 00 00
00 00 00 00 WW 00 00 00 00 00
XX/YY/ZZ and WW/TT are unknown. Observed values:
00 00 00 00/00
40 80 a0 80/0f
80 80 a0
40 80 90
40 80 00
also seen:
e4 56 31 30 00 00 00 00 00 00 00 00 0f 00 00 00
00 0a 05 05 80 00 00 00 00 00
e4 56 31 30 00 00 00 40 80 90 10 00 0f 00 00 00
00 0a 05 05 80 00 00 00 00 00
e4 56 31 30 00 00 00 00 40 80 00 00 00 ff 40 00
00 00 00 00 80 00 00 00 00 00
print just submitted:
e4 56 31 30 00 00 00 00 40 20 00 00 00 8c 00 00
00 00 00 00 80 00 00 00 00 00
prints running...
e4 56 31 30 00 00 00 00 40 20 00 00 00 cf 00 20
00 00 00 00 80 00 00 00 00 00
CP-K60DW-S:
e4 56 31 30 00 00 00 XX YY 00 00 00 0f 00 00 00
00 00 00 00 80 00 00 00 00 00
XX/YY are unknown, observed values:
40/80
00/00
Memory status query:
-> 1b 56 33 00 XX XX YY YY UU 00
XX XX == columns
YY YY == rows
UU == 0x00 glossy, 0x80 matte
<- [ 6 byte payload ]
e4 56 33 00 00 00
e4 56 33 00 00 01
e4 56 33 ff 01 01
|--- Size check, 00 ok, 01 fail
|------ Memory check, 00 ok, 01 fail, ff bad size
** ** ** ** ** **
The windows drivers seem to send the id and status queries before
and in between each of the chunks sent to the printer. There doesn't
appear to be any particular intelligence in the protocol, but it didn't
work when the raw dump was submitted as-is.
** ** ** ** ** **
Various deck status dumps:
0080 00 00 00 00 00 00 01 d2 39 00 00 00 07 00 00 00 ........9.......
0090 61 8f 00 00 01 40 01 36 00 00 00 00 00 17 79 80 a....@.6......y.
0080 00 00 00 00 00 00 01 c6 39 00 00 00 08 00 00 00 ........9.......
0090 61 8f 00 00 01 40 01 35 00 00 00 00 00 18 79 80 a....@.5......y.
0080 00 00 00 00 00 00 02 19 50 00 00 00 19 00 00 01 ........P.......
0090 6c 8f 00 00 01 40 01 22 00 00 00 00 00 27 83 80 l....@.".....'..
0080 00 00 00 00 00 00 02 00 3e 00 00 04 96 00 00 00 ........>.......
0090 ff 0f 01 00 00 c8 00 52 00 00 00 00 05 28 75 80 .......R.....(u.
00c0 00 00 00 00 00 00 01 f3 3d 00 00 06 39 00 00 00 ........=...9...
00d0 ff 02 00 00 01 90 00 c3 00 00 00 00 06 67 78 00 .............gx.
0080 00 00 00 00 00 00 01 d0 38 00 00 03 70 00 00 00 ........8...p...
0090 ff 02 00 00 01 90 00 1e 01 00 00 00 03 83 72 80 ..............r.
0080 00 00 00 00 00 00 01 d6 39 00 00 00 20 00 00 00 ........9... ...
0090 ff 02 00 00 01 90 01 7c 01 00 00 00 00 33 72 80 .......|.....3r.
00 00 00 0a 05 05 01 d5 38 00 00 00 14 00 00 00
ff ff ff ff ff ff ff ff ff ff 00 00 00 27 72 80 ?? Error ??
80 00 00 00 00 00 00 ff ff 00 00 00 00 00 00 00
ff ff ff ff ff ff ff ff ff ff 00 00 00 00 80 00 NO DECK PRESENT
*/
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