selphy_print/backend_mitsud90.c
Solomon Peachy b7560192b9 Docs: CP-M1A vs CP-M1E
(Just in case thre's any confusion..)
2019-12-10 11:45:43 -05:00

1442 lines
36 KiB
C

/*
* Mitsubishi CP-D90DW Photo Printer CUPS backend
*
* (c) 2019 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]
*
* SPDX-License-Identifier: GPL-3.0+
*
*/
#define BACKEND mitsud90_backend
#include "backend_common.h"
#define USB_VID_MITSU 0x06D3
#define USB_PID_MITSU_D90 0x3B60
const char *mitsu70x_media_types(uint8_t brand, uint8_t type);
const char *mitsu70x_temperatures(uint8_t temp);
/* Printer data structures */
#define D90_STATUS_TYPE_MODEL 0x01 // 10, null-terminated ASCII. 'CPD90D'
#define D90_STATUS_TYPE_x02 0x02 // 1, 0x5f ?
#define D90_STATUS_TYPE_FW_0b 0x0b // 8, 34 31 34 42 31 31 a7 de (414D11)
#define D90_STATUS_TYPE_FW_MA 0x0c // 8, 34 31 35 41 38 31 86 bf (415A81) // MAIN FW
#define D90_STATUS_TYPE_FW_F 0x0d // 8, 34 31 36 41 35 31 dc 8a (416A51) // FPGA FW
#define D90_STATUS_TYPE_FW_T 0x0e // 8, 34 31 37 45 31 31 e7 e6 (417E11) // TABLE FW
#define D90_STATUS_TYPE_FW_0f 0x0f // 8, 34 31 38 41 31 32 6c 64 (418A12)
#define D90_STATUS_TYPE_FW_11 0x11 // 8, 34 32 31 51 31 31 74 f2 (421Q11)
#define D90_STATUS_TYPE_FW_ME 0x13 // 8, 34 31 39 45 31 31 15 bf (419E11) // MECHA FW
#define D90_STATUS_TYPE_ERROR 0x16 // 11 (see below)
#define D90_STATUS_TYPE_MECHA 0x17 // 2 (see below)
#define D90_STATUS_TYPE_x1e 0x1e // 1, power state or time? (x00)
#define D90_STATUS_TYPE_TEMP 0x1f // 1 (see below)
#define D90_STATUS_TYPE_x22 0x22 // 2, all 0
#define D90_STATUS_TYPE_x28 0x28 // 2, all 0, seen some sort of counter?
#define D90_STATUS_TYPE_x29 0x29 // 8, e0 07 00 00 21 e6 b3 22
#define D90_STATUS_TYPE_MEDIA 0x2a // 10 (see below)
#define D90_STATUS_TYPE_x2b 0x2b // 2, all 0
#define D90_STATUS_TYPE_x2c 0x2c // 2, 00 56
#define D90_STATUS_TYPE_x65 0x65 // 50, ac 80 00 01 bb b8 fe 48 05 13 5d 9c 00 33 00 00 00 00 00 00 00 00 00 00 00 00 02 39 00 00 00 00 03 13 00 02 10 40 00 00 00 00 00 00 05 80 00 3a 00 00
#define D90_STATUS_TYPE_ISER 0x82 // 1, 80 (iserial disabled)
#define D90_STATUS_TYPE_x83 0x83 // 1, 00
#define D90_STATUS_TYPE_x84 0x84 // 1, 00
//#define D90_STATUS_TYPE_x85 0x85 // 2, 00 ?? BE, wait time?
// combined total of 5.
struct mitsud90_fw_resp_single {
uint8_t version[6];
uint16_t csum;
} __attribute__((packed));
struct mitsud90_media_resp {
uint8_t hdr[4]; /* e4 47 44 30 */
struct {
uint8_t brand;
uint8_t type;
uint8_t unk_a[2];
uint16_t capacity; /* BE */
uint16_t remain; /* BE */
uint8_t unk_b[2];
} __attribute__((packed)) media; /* D90_STATUS_TYPE_MEDIA */
} __attribute__((packed));
struct mitsud90_status_resp {
uint8_t hdr[4]; /* e4 47 44 30 */
/* D90_STATUS_TYPE_ERROR */
uint8_t code[2]; /* 00 is ok, nonzero is error */
uint8_t unk[9];
/* D90_STATUS_TYPE_MECHA */
uint8_t mecha[2];
/* D90_STATUS_TYPE_TEMP */
uint8_t temp;
} __attribute__((packed));
struct mitsud90_info_resp {
uint8_t hdr[4]; /* e4 47 44 30 */
uint8_t model[10];
uint8_t x02;
struct mitsud90_fw_resp_single fw_vers[7];
uint8_t x1e;
uint8_t x22[2];
uint8_t x28[2];
uint8_t x29[8];
uint8_t x2b[2];
uint8_t x2c[2];
uint8_t x65[50];
uint8_t iserial;
uint8_t x83;
uint8_t x84;
} __attribute__((packed));
#define D90_MECHA_STATUS_IDLE 0x00
#define D90_MECHA_STATUS_PRINTING 0x50
#define D90_MECHA_STATUS_INIT 0x80
#define D90_MECHA_STATUS_INIT_FEEDCUT 0x10
#define D90_MECHA_STATUS_PRINT_FEEDING 0x10 // feeding ?
#define D90_MECHA_STATUS_PRINT_PRE_Y 0x21 // pre Y ?
#define D90_MECHA_STATUS_PRINT_Y 0x22 // Y ?
#define D90_MECHA_STATUS_PRINT_PRE_M 0x23 // pre M ?
#define D90_MECHA_STATUS_PRINT_M 0x24 // M ?
#define D90_MECHA_STATUS_PRINT_PRE_C 0x25 // pre C ? guess!
#define D90_MECHA_STATUS_PRINT_C 0x26 // C ?
#define D90_MECHA_STATUS_PRINT_PRE_OC 0x27 // pre OC ? guess!
#define D90_MECHA_STATUS_PRINT_OC 0x28 // O C?
#define D90_MECHA_STATUS_PRINTING_x2f 0x2f // ??
#define D90_MECHA_STATUS_PRINTING_x38 0x38 // eject ?
#define D90_ERROR_STATUS_OK 0x00
#define D90_ERROR_STATUS_OK_WARMING 0x40
#define D90_ERROR_STATUS_OK_COOLING 0x80
#define D90_ERROR_STATUS_RIBBON 0x21
#define D90_ERROR_STATUS_PAPER 0x22
#define D90_ERROR_STATUS_PAP_RIB 0x23
#define D90_ERROR_STATUS_OPEN 0x29
struct mitsud90_job_query {
uint8_t hdr[4]; /* 1b 47 44 31 */
uint16_t jobid; /* BE */
};
struct mitsud90_job_resp {
uint8_t hdr[4]; /* e4 47 44 31 */
uint8_t unk1;
uint8_t unk2;
uint16_t unk3;
};
struct mitsud90_job_hdr {
uint8_t hdr[6]; /* 1b 53 50 30 00 33 */
uint16_t cols; /* BE */
uint16_t rows; /* BE */
uint8_t unk[4]; /* 64 00 00 01 */
uint8_t margincut; /* 1 for enabled, 0 for disabled */
union {
#if 0
struct {
uint8_t margin;
uint16_t position;
} cuts[3] __attribute__((packed));
#endif
uint8_t cutzero[9];
} __attribute__((packed));
uint8_t zero[24];
/*@x30*/uint8_t overcoat;
uint8_t quality;
uint8_t colorcorr;
uint8_t sharp_h;
uint8_t sharp_v;
uint8_t zero_b[5];
union {
struct {
uint16_t pano_on; /* 0x0001 when pano is on, */
uint8_t pano_tot; /* 2 or 3 */
uint8_t pano_pg; /* 1, 2, 3 */
uint16_t pano_rows; /* always 0x097c (BE), ie 2428 ie 8" print */
uint16_t pano_rows2; /* Always 0x30 less than pano_rows */
uint16_t pano_zero; /* 0x0000 */
uint8_t pano_unk[6]; /* 02 58 00 0c 00 06 */
} pano __attribute__((packed));
uint8_t zero_c[16];
};
uint8_t zero_d[6];
uint8_t zero_fill[432];
} __attribute__((packed));
struct mitsud90_plane_hdr {
uint8_t hdr[6]; /* 1b 5a 54 01 00 09 */
uint16_t origin_cols;
uint16_t origin_rows;
uint16_t cols; /* BE */
uint16_t rows; /* BE */
uint8_t zero_fill[498];
};
struct mitsud90_job_footer {
uint8_t hdr[4]; /* 1b 42 51 31 */
uint8_t pad;
uint8_t seconds; /* 0x05 by default (windows) */
};
struct mitsud90_memcheck {
uint8_t hdr[4]; /* 1b 47 44 33 */
uint8_t unk[2]; /* 00 33 */
uint16_t cols; /* BE */
uint16_t rows; /* BE */
uint8_t unk_b[4]; /* 64 00 00 01 */
uint8_t zero_fill[498];
};
struct mitsud90_memcheck_resp {
uint8_t hdr[4]; /* e4 47 44 43 */
uint8_t size_bad; /* 0x00 is ok */
uint8_t mem_bad; /* 0x00 is ok */
};
const char *mitsud90_mecha_statuses(const uint8_t *code)
{
switch (code[0]) {
case D90_MECHA_STATUS_IDLE:
return "Idle";
case D90_MECHA_STATUS_PRINTING:
switch (code[1]) {
case D90_MECHA_STATUS_PRINT_FEEDING:
return "Feeding Media";
case D90_MECHA_STATUS_PRINT_PRE_Y:
case D90_MECHA_STATUS_PRINT_Y:
return "Printing Yellow";
case D90_MECHA_STATUS_PRINT_PRE_M:
case D90_MECHA_STATUS_PRINT_M:
return "Printing Magenta";
case D90_MECHA_STATUS_PRINT_PRE_C:
case D90_MECHA_STATUS_PRINT_C:
return "Printing Cyan";
case D90_MECHA_STATUS_PRINT_PRE_OC:
case D90_MECHA_STATUS_PRINT_OC:
return "Applying Overcoat";
case D90_MECHA_STATUS_PRINTING_x2f:
case D90_MECHA_STATUS_PRINTING_x38:
return "Ejecting Media?";
default:
return "Printing (Unknown)";
}
case D90_MECHA_STATUS_INIT:
if (code[1] == D90_MECHA_STATUS_INIT_FEEDCUT)
return "Feed & Cut paper";
else
return "Initializing";
default:
return "Unknown";
}
}
const char *mitsud90_error_codes(const uint8_t *code)
{
switch(code[0]) {
case D90_ERROR_STATUS_OK:
if (code[1] & D90_ERROR_STATUS_OK_WARMING)
return "Heating";
else if (code[1] & D90_ERROR_STATUS_OK_COOLING)
return "Cooling Down";
else
return "Idle";
case D90_ERROR_STATUS_RIBBON:
switch (code[1]) {
case 0x00:
return "Ribbon exhausted";
case 0x10:
return "Insufficient remaining ribbon";
case 0x20:
return "Ribbon Cue Timeout";
case 0x30:
return "Cannot Cue Ribbon";
case 0x90:
return "No ribbon";
default:
return "Unknown Ribbon Error";
}
case D90_ERROR_STATUS_PAPER:
switch (code[1]) {
case 0x00:
return "No paper";
case 0x02:
return "Paper exhausted";
default:
return "Unknown Paper Error";
}
case D90_ERROR_STATUS_PAP_RIB:
switch (code[1]) {
case 0x00:
return "Ribbon/Paper mismatch";
case 0x90:
return "Ribbon/Job mismatch";
default:
return "Unknown ribbon match error";
}
case 0x26:
return "Illegal Ribbon";
case 0x28:
return "Cut Bin Missing";
case D90_ERROR_STATUS_OPEN:
switch (code[1]) {
case 0x00:
return "Printer Open during Stop";
case 0x10:
return "Printer Open during Initialization";
case 0x90:
return "Printer Open during Printing";
default:
return "Unknown Door error";
}
case 0x2f:
return "Printer turned off during printing";
case 0x31:
return "Ink feed stop";
case 0x32:
return "Ink Skip 1 timeout";
case 0x33:
return "Ink Skip 2 timeout";
case 0x34:
return "Ink Sticking";
case 0x35:
return "Ink return stop";
case 0x36:
return "Ink Rewind timeout";
case 0x37:
return "Winding sensing error";
case 0x40:
case 0x41:
case 0x42:
case 0x43:
case 0x44:
return "Paper Jam";
case 0x60:
if (code[1] == 0x20)
return "Preheat error";
else if (code[1] == 0x04)
return "Humidity sensor error";
else if (code[1] & 0x1f)
return "Thermistor error";
else
return "Unknown error";
case 0x61:
if (code[1] == 0x00)
return "Color Sensor Error";
else if (code[1] & 0x10)
return "Matte OP Error";
else
return "Unknown error";
case 0x62:
return "Data Transfer error";
case 0x63:
return "EEPROM error";
case 0x64:
return "Flash access error";
case 0x65:
return "FPGA configuration error";
case 0x66:
return "Power voltage Error";
case 0x67:
return "RFID access error";
case 0x68:
if (code[1] == 0x00)
return "Fan Lock Error";
else if (code[1] == 0x90)
return "MDA Error";
else
return "Unknown error";
case 0x69:
if (code[1] == 0x10)
return "DDR Error";
else if (code[1] == 0x00)
return "Firmware Error";
else
return "Unknown error";
case 0x70:
case 0x71:
case 0x73:
case 0x75:
return "Mechanical Error (check ribbon and power cycle)";
case 0x82:
return "USB Timeout";
case 0x83:
return "Illegal paper size";
case 0x84:
return "Illegal parameter";
case 0x85:
return "Job Cancel";
case 0x89:
return "Last Job Error";
default:
return "Unknown";
}
}
static void mitsud90_dump_status(struct mitsud90_status_resp *resp)
{
INFO("Error Status: %s (%02x %02x) -- %02x %02x %02x %02x %02x %02x %02x %02x %02x\n",
mitsud90_error_codes(resp->code),
resp->code[0], resp->code[1],
resp->unk[0], resp->unk[1], resp->unk[2], resp->unk[3],
resp->unk[4], resp->unk[5], resp->unk[6], resp->unk[7],
resp->unk[8]);
INFO("Printer Status: %s (%02x %02x)\n",
mitsud90_mecha_statuses(resp->mecha),
resp->mecha[0], resp->mecha[1]);
INFO("Temperature Status: %s\n",
mitsu70x_temperatures(resp->temp));
}
/* Private data structure */
struct mitsud90_printjob {
uint8_t *databuf;
int datalen;
int copies;
};
struct mitsud90_ctx {
struct libusb_device_handle *dev;
uint8_t endp_up;
uint8_t endp_down;
int type;
/* Used in parsing.. */
struct mitsud90_job_footer holdover;
int holdover_on;
struct marker marker;
};
static int mitsud90_query_media(struct mitsud90_ctx *ctx, struct mitsud90_media_resp *resp)
{
uint8_t cmdbuf[8];
int ret, num;
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x47;
cmdbuf[2] = 0x44;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0;
cmdbuf[5] = 0;
cmdbuf[6] = 0x01; /* Number of commands */
cmdbuf[7] = D90_STATUS_TYPE_MEDIA;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, sizeof(cmdbuf))))
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 CUPS_BACKEND_OK;
}
static int mitsud90_query_status(struct mitsud90_ctx *ctx, struct mitsud90_status_resp *resp)
{
uint8_t cmdbuf[10];
int ret, num;
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x47;
cmdbuf[2] = 0x44;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0;
cmdbuf[5] = 0;
cmdbuf[6] = 0x03; /* Number of commands */
cmdbuf[7] = D90_STATUS_TYPE_ERROR;
cmdbuf[8] = D90_STATUS_TYPE_MECHA;
cmdbuf[9] = D90_STATUS_TYPE_TEMP;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, sizeof(cmdbuf))))
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 CUPS_BACKEND_OK;
}
/* Generic functions */
static void *mitsud90_init(void)
{
struct mitsud90_ctx *ctx = malloc(sizeof(struct mitsud90_ctx));
if (!ctx) {
ERROR("Memory Allocation Failure!\n");
return NULL;
}
memset(ctx, 0, sizeof(struct mitsud90_ctx));
return ctx;
}
static int mitsud90_attach(void *vctx, struct libusb_device_handle *dev, int type,
uint8_t endp_up, uint8_t endp_down, int iface, uint8_t jobid)
{
struct mitsud90_ctx *ctx = vctx;
struct mitsud90_media_resp resp;
UNUSED(jobid);
UNUSED(iface);
ctx->dev = dev;
ctx->endp_up = endp_up;
ctx->endp_down = endp_down;
ctx->type = type;
if (test_mode < TEST_MODE_NOATTACH) {
if (mitsud90_query_media(ctx, &resp))
return CUPS_BACKEND_FAILED;
} else {
resp.media.brand = 0xff;
resp.media.type = 0x0f;
resp.media.capacity = cpu_to_be16(230);
resp.media.remain = cpu_to_be16(200);
}
ctx->marker.color = "#00FFFF#FF00FF#FFFF00";
ctx->marker.numtype = resp.media.type;
ctx->marker.name = mitsu70x_media_types(resp.media.brand, resp.media.type);
ctx->marker.levelmax = be16_to_cpu(resp.media.capacity);
ctx->marker.levelnow = be16_to_cpu(resp.media.remain);
return CUPS_BACKEND_OK;
}
static void mitsud90_cleanup_job(const void *vjob)
{
const struct mitsud90_printjob *job = vjob;
if (job->databuf)
free(job->databuf);
free((void*)job);
}
static int mitsud90_read_parse(void *vctx, const void **vjob, int data_fd, int copies) {
struct mitsud90_ctx *ctx = vctx;
int i, remain;
struct mitsud90_job_hdr *hdr;
struct mitsud90_printjob *job;;
if (!ctx)
return CUPS_BACKEND_FAILED;
job = malloc(sizeof(*job));
if (!job) {
ERROR("Memory allocation failure!\n");
return CUPS_BACKEND_RETRY_CURRENT;
}
memset(job, 0, sizeof(*job));
job->copies = copies;
/* Just allocate a worst-case buffer */
job->datalen = 0;
job->databuf = malloc(sizeof(struct mitsud90_job_hdr) +
sizeof(struct mitsud90_plane_hdr) +
sizeof(struct mitsud90_job_footer) +
1852*2729*3);
if (!job->databuf) {
ERROR("Memory allocation failure!\n");
mitsud90_cleanup_job(job);
return CUPS_BACKEND_RETRY_CURRENT;
}
/* Make sure there's no holdover */
if (ctx->holdover_on) {
memcpy(job->databuf, &ctx->holdover, sizeof(ctx->holdover));
job->datalen += sizeof(ctx->holdover);
ctx->holdover_on = 0;
}
/* Read in first header. */
remain = sizeof(struct mitsud90_job_hdr) - job->datalen;
while (remain) {
i = read(data_fd, (job->databuf + job->datalen), remain);
if (i == 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
if (i < 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
remain -= i;
job->datalen += i;
}
/* Sanity check header */
hdr = (struct mitsud90_job_hdr *) job->databuf;
if (hdr->hdr[0] != 0x1b ||
hdr->hdr[1] != 0x53 ||
hdr->hdr[2] != 0x50 ||
hdr->hdr[3] != 0x30 ) {
ERROR("Unrecognized data format (%02x%02x%02x%02x)!\n",
hdr->hdr[0], hdr->hdr[1], hdr->hdr[2], hdr->hdr[3]);
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
/* Now read in the rest */
remain = sizeof(struct mitsud90_plane_hdr) + be16_to_cpu(hdr->cols) * be16_to_cpu(hdr->rows) * 3;
while(remain) {
i = read(data_fd, job->databuf + job->datalen, remain);
if (i == 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
if (i < 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
job->datalen += i;
remain -= i;
}
/* Read in the footer. Hopefully. */
remain = sizeof(struct mitsud90_job_footer);
i = read(data_fd, job->databuf + job->datalen, remain);
if (i == 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
if (i < 0) {
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
/* See if this is a job footer. If it is, keep, else holdover. */
if (job->databuf[job->datalen + 0] != 0x1b ||
job->databuf[job->datalen + 1] != 0x42 ||
job->databuf[job->datalen + 2] != 0x51 ||
job->databuf[job->datalen + 3] != 0x31) {
memcpy(&ctx->holdover, job->databuf + job->datalen, sizeof(struct mitsud90_job_footer));
ctx->holdover_on = 1;
} else {
job->datalen += i;
ctx->holdover_on = 0;
}
/* Sanity check */
if (hdr->pano.pano_on) {
ERROR("Unable to handle panorama jobs yet\n");
mitsud90_cleanup_job(job);
return CUPS_BACKEND_CANCEL;
}
*vjob = job;
return CUPS_BACKEND_OK;
}
static int mitsud90_main_loop(void *vctx, const void *vjob) {
struct mitsud90_ctx *ctx = vctx;
struct mitsud90_job_hdr *hdr;
struct mitsud90_status_resp resp;
uint8_t last_status[2] = {0xff, 0xff};
int sent;
int ret;
int copies;
const struct mitsud90_printjob *job = vjob;
if (!ctx)
return CUPS_BACKEND_FAILED;
if (!job)
return CUPS_BACKEND_FAILED;
copies = job->copies;
hdr = (struct mitsud90_job_hdr*) job->databuf;
INFO("Waiting for printer idle...\n");
top:
sent = 0;
// XXX Figure out if printer is asleep, and wake it up if necessary.
/* Query status, wait for idle or error out */
do {
if (mitsud90_query_status(ctx, &resp))
return CUPS_BACKEND_FAILED;
if (resp.code[0] != D90_ERROR_STATUS_OK) {
ERROR("Printer reported error condition: %s (%02x %02x)\n",
mitsud90_error_codes(resp.code), resp.code[0], resp.code[1]);
return CUPS_BACKEND_STOP;
}
if (resp.code[1] & D90_ERROR_STATUS_OK_WARMING ||
resp.temp & D90_ERROR_STATUS_OK_WARMING ) {
INFO("Printer warming up\n");
sleep(1);
continue;
}
if (resp.code[1] & D90_ERROR_STATUS_OK_COOLING ||
resp.temp & D90_ERROR_STATUS_OK_COOLING) {
INFO("Printer cooling down\n");
sleep(1);
continue;
}
if (resp.mecha[0] != last_status[0] ||
resp.mecha[1] != last_status[1]) {
INFO("Printer status: %s\n",
mitsud90_mecha_statuses(resp.mecha));
last_status[0] = resp.mecha[0];
last_status[1] = resp.mecha[1];
}
if (resp.mecha[0] == D90_MECHA_STATUS_IDLE) {
break;
// we don't have to wait until idle, just
// until we have free buffers. Don't know how
// to check this though.. XXXX
}
} while(1);
/* Send memory check */
{
struct mitsud90_memcheck mem;
struct mitsud90_memcheck_resp mem_resp;
int num;
memcpy(&mem, hdr, sizeof(mem));
mem.hdr[0] = 0x1b;
mem.hdr[1] = 0x47;
mem.hdr[2] = 0x44;
mem.hdr[3] = 0x33;
if ((ret = send_data(ctx->dev, ctx->endp_down,
(uint8_t*) &mem, sizeof(mem))))
return CUPS_BACKEND_FAILED;
ret = read_data(ctx->dev, ctx->endp_up,
(uint8_t*)&mem_resp, sizeof(mem_resp), &num);
if (ret < 0)
return ret;
if (num != sizeof(mem_resp)) {
ERROR("Short Read! (%d/%d)\n", num, (int)sizeof(mem_resp));
return 4;
}
if (mem_resp.size_bad || mem_resp.mem_bad == 0xff) {
ERROR("Printer reported bad print params (%02x)\n", mem_resp.size_bad);
return CUPS_BACKEND_CANCEL;
}
if (mem_resp.mem_bad) {
ERROR("Printer buffers full, retrying!\n");
sleep(1);
goto top;
}
}
/* Send header */
if ((ret = send_data(ctx->dev, ctx->endp_down,
job->databuf + sent, sizeof(*hdr))))
return CUPS_BACKEND_FAILED;
sent += sizeof(*hdr);
/* Send Plane header */
if ((ret = send_data(ctx->dev, ctx->endp_down,
job->databuf + sent, sizeof(*hdr))))
return CUPS_BACKEND_FAILED;
sent += sizeof(*hdr);
/* Send payload + footer */
if ((ret = send_data(ctx->dev, ctx->endp_down,
job->databuf + sent, job->datalen - sent)))
return CUPS_BACKEND_FAILED;
// sent += (job->datalen - sent);
/* Wait for completion */
do {
sleep(1);
if (mitsud90_query_status(ctx, &resp))
return CUPS_BACKEND_FAILED;
if (resp.code[0] != D90_ERROR_STATUS_OK) {
ERROR("Printer reported error condition: %s (%02x %02x)\n",
mitsud90_error_codes(resp.code), resp.code[0], resp.code[1]);
return CUPS_BACKEND_STOP;
}
if (resp.mecha[0] != last_status[0] ||
resp.mecha[1] != last_status[1]) {
INFO("Printer status: %s\n",
mitsud90_mecha_statuses(resp.mecha));
last_status[0] = resp.mecha[0];
last_status[1] = resp.mecha[1];
}
/* Terminate when printing complete */
if (resp.mecha[0] == D90_MECHA_STATUS_IDLE) {
break;
}
if (fast_return && copies <= 1) { /* Copies generated by backend? */
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 int mitsud90_query_job(struct mitsud90_ctx *ctx, uint16_t jobid,
struct mitsud90_job_resp *resp)
{
struct mitsud90_job_query req;
int ret, num;
req.hdr[0] = 0x1b;
req.hdr[1] = 0x47;
req.hdr[2] = 0x44;
req.hdr[3] = 0x31;
req.jobid = cpu_to_be16(jobid);
if ((ret = send_data(ctx->dev, ctx->endp_down,
(uint8_t*) &req, sizeof(req))))
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 CUPS_BACKEND_OK;
}
static int mitsud90_get_jobstatus(struct mitsud90_ctx *ctx, uint16_t jobid)
{
struct mitsud90_job_resp resp;
if (mitsud90_query_job(ctx, jobid, &resp))
return CUPS_BACKEND_FAILED;
INFO("Job Status: %04x = %02x/%02x/%04x\n",
jobid, resp.unk1, resp.unk2, be16_to_cpu(resp.unk3));
return CUPS_BACKEND_OK;
}
static int mitsud90_get_media(struct mitsud90_ctx *ctx)
{
struct mitsud90_media_resp resp;
if (mitsud90_query_media(ctx, &resp))
return CUPS_BACKEND_FAILED;
INFO("Media Type: %s (%02x/%02x)\n",
mitsu70x_media_types(resp.media.brand, resp.media.type),
resp.media.brand,
resp.media.type);
INFO("Prints Remaining: %03d/%03d\n",
be16_to_cpu(resp.media.remain),
be16_to_cpu(resp.media.capacity));
return CUPS_BACKEND_OK;
}
static int mitsud90_get_status(struct mitsud90_ctx *ctx)
{
struct mitsud90_status_resp resp;
if (mitsud90_query_status(ctx, &resp))
return CUPS_BACKEND_FAILED;
mitsud90_dump_status(&resp);
return CUPS_BACKEND_OK;
}
int mitsud90_get_info(struct mitsud90_ctx *ctx)
{
uint8_t cmdbuf[26];
int ret, num;
struct mitsud90_info_resp resp;
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x47;
cmdbuf[2] = 0x44;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0;
cmdbuf[5] = 0;
cmdbuf[6] = 19; /* Number of commands */
cmdbuf[7] = D90_STATUS_TYPE_MODEL;
cmdbuf[8] = D90_STATUS_TYPE_x02;
cmdbuf[9] = D90_STATUS_TYPE_FW_0b;
cmdbuf[10] = D90_STATUS_TYPE_FW_MA;
cmdbuf[11] = D90_STATUS_TYPE_FW_F;
cmdbuf[12] = D90_STATUS_TYPE_FW_T;
cmdbuf[13] = D90_STATUS_TYPE_FW_0f;
cmdbuf[14] = D90_STATUS_TYPE_FW_11;
cmdbuf[15] = D90_STATUS_TYPE_FW_ME;
cmdbuf[16] = D90_STATUS_TYPE_x1e;
cmdbuf[17] = D90_STATUS_TYPE_x22;
cmdbuf[18] = D90_STATUS_TYPE_x28;
cmdbuf[19] = D90_STATUS_TYPE_x29;
cmdbuf[20] = D90_STATUS_TYPE_x2b;
cmdbuf[21] = D90_STATUS_TYPE_x2c;
cmdbuf[22] = D90_STATUS_TYPE_x65;
cmdbuf[23] = D90_STATUS_TYPE_ISER;
cmdbuf[24] = D90_STATUS_TYPE_x83;
cmdbuf[25] = D90_STATUS_TYPE_x84;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, sizeof(cmdbuf))))
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;
}
/* start dumping output */
memset(cmdbuf, 0, sizeof(cmdbuf));
memcpy(cmdbuf, resp.model, sizeof(resp.model));
INFO("Model: %s\n", (char*)cmdbuf);
for (num = 0; num < 7 ; num++) {
memset(cmdbuf, 0, sizeof(cmdbuf));
memcpy(cmdbuf, resp.fw_vers[num].version, sizeof(resp.fw_vers[num].version));
INFO("FW Component %02d: %s (%04x)\n",
num, cmdbuf, be16_to_cpu(resp.fw_vers[num].csum));
}
INFO("TYPE_02: %02x\n", resp.x02);
INFO("TYPE_1e: %02x\n", resp.x1e);
INFO("TYPE_22: %02x %02x\n", resp.x22[0], resp.x22[1]);
INFO("TYPE_28: %02x %02x\n", resp.x28[0], resp.x28[1]);
INFO("TYPE_29: %02x %02x %02x %02x %02x %02x %02x %02x\n",
resp.x29[0], resp.x29[1], resp.x29[2], resp.x29[3],
resp.x29[4], resp.x29[5], resp.x29[6], resp.x29[7]);
INFO("TYPE_2b: %02x %02x\n", resp.x2b[0], resp.x2b[1]);
INFO("TYPE_2c: %02x %02x\n", resp.x2c[0], resp.x2c[1]);
INFO("TYPE_65:");
for (num = 0; num < 50 ; num++) {
DEBUG2(" %02x", resp.x65[num]);
}
DEBUG2("\n");
INFO("iSerial: %s\n", resp.iserial ? "Disabled" : "Enabled");
INFO("TYPE_83: %02x\n", resp.x83);
INFO("TYPE_84: %02x\n", resp.x84);
// XXX what about resume, wait time, "cut limit", sleep time ?
return CUPS_BACKEND_OK;
}
static int mitsud90_dumpall(struct mitsud90_ctx *ctx)
{
int i;
uint8_t cmdbuf[8];
uint8_t buf[256];
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x47;
cmdbuf[2] = 0x44;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0;
cmdbuf[5] = 0;
cmdbuf[6] = 0x01; /* Number of commands */
for (i = 0 ; i < 256 ; i++) {
int num, ret;
cmdbuf[7] = i;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, sizeof(cmdbuf))))
return ret;
memset(buf, 0, sizeof(buf));
ret = read_data(ctx->dev, ctx->endp_up,
buf, sizeof(buf), &num);
if (ret <= 0)
continue;
if (num > 4) {
DEBUG("TYPE %02x LEN: %d (%d)\n", i, num, num - 4);
DEBUG("<--");
for (ret = 0; ret < num ; ret ++) {
DEBUG2(" %x", buf[ret]);
}
DEBUG2("\n");
}
}
return CUPS_BACKEND_OK;
}
static int mitsud90_set_iserial(struct mitsud90_ctx *ctx, uint8_t enabled)
{
uint8_t cmdbuf[23];
int ret, num;
enabled = (enabled) ? 0: 0x80;
/* Send Parameter.. */
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x31;
cmdbuf[2] = 0x36;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0x41;
cmdbuf[5] = 0xbe;
cmdbuf[6] = 0x00;
cmdbuf[7] = 0x00;
cmdbuf[8] = 0x00;
cmdbuf[9] = 0x01;
cmdbuf[10] = 0x00;
cmdbuf[11] = 0x00;
cmdbuf[12] = 0x00;
cmdbuf[13] = 0x11;
cmdbuf[14] = 0xff;
cmdbuf[15] = 0xff;
cmdbuf[16] = 0xff;
cmdbuf[17] = 0xfe;
cmdbuf[18] = 0xff;
cmdbuf[19] = 0xff;
cmdbuf[20] = 0xff;
cmdbuf[21] = 0xfe;
cmdbuf[22] = enabled;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, sizeof(cmdbuf))))
return ret;
ret = read_data(ctx->dev, ctx->endp_up,
cmdbuf, sizeof(cmdbuf), &num);
/* No response */
return ret;
}
static int mitsud90_set_sleeptime(struct mitsud90_ctx *ctx, uint16_t time)
{
uint8_t cmdbuf[24];
int ret;
/* 255 minutes max, according to RE work */
if (time > 255)
time = 255;
/* Send Parameter.. */
cmdbuf[0] = 0x1b;
cmdbuf[1] = 0x31;
cmdbuf[2] = 0x36;
cmdbuf[3] = 0x30;
cmdbuf[4] = 0x41;
cmdbuf[5] = 0xbe;
cmdbuf[6] = 0x00;
cmdbuf[7] = 0x00;
cmdbuf[8] = 0x00;
cmdbuf[9] = 0x02;
cmdbuf[10] = 0x00;
cmdbuf[11] = 0x00;
cmdbuf[12] = 0x05;
cmdbuf[13] = 0x02;
cmdbuf[14] = 0xff;
cmdbuf[15] = 0xff;
cmdbuf[16] = 0xff;
cmdbuf[17] = 0xfd;
cmdbuf[18] = 0xff;
cmdbuf[19] = 0xff;
cmdbuf[20] = 0xfa;
cmdbuf[21] = 0xff;
cmdbuf[22] = (time >> 8) & 0xff;
cmdbuf[23] = time & 0xff;
if ((ret = send_data(ctx->dev, ctx->endp_down,
cmdbuf, 4)))
return ret;
/* No response */
return 0;
}
static void mitsud90_cmdline(void)
{
DEBUG("\t\t[ -i ] # Query printer info\n");
DEBUG("\t\t[ -j jobid ] # Query job status\n");
DEBUG("\t\t[ -k time ] # Set sleep time in minutes\n");
DEBUG("\t\t[ -m ] # Query printer media\n");
DEBUG("\t\t[ -s ] # Query printer status\n");
DEBUG("\t\t[ -x 0|1 ] # Enable/disable iSerial reporting\n");
// DEBUG("\t\t[ -Z ] # Dump all parameters\n");
}
static int mitsud90_cmdline_arg(void *vctx, int argc, char **argv)
{
struct mitsud90_ctx *ctx = vctx;
int i, j = 0;
if (!ctx)
return -1;
while ((i = getopt(argc, argv, GETOPT_LIST_GLOBAL "ij:k:msx:Z")) >= 0) {
switch(i) {
GETOPT_PROCESS_GLOBAL
case 'i':
j = mitsud90_get_info(ctx);
break;
case 'j':
j = mitsud90_get_jobstatus(ctx, atoi(optarg));
break;
case 'k':
j = mitsud90_set_sleeptime(ctx, atoi(optarg));
break;
case 'm':
j = mitsud90_get_media(ctx);
break;
case 's':
j = mitsud90_get_status(ctx);
break;
case 'x':
j = mitsud90_set_iserial(ctx, atoi(optarg));
break;
case 'Z':
j = mitsud90_dumpall(ctx);
break;
default:
break; /* Ignore completely */
}
if (j) return j;
}
return 0;
}
static int mitsud90_query_markers(void *vctx, struct marker **markers, int *count)
{
struct mitsud90_ctx *ctx = vctx;
struct mitsud90_media_resp resp;
*markers = &ctx->marker;
*count = 1;
if (mitsud90_query_media(ctx, &resp))
return CUPS_BACKEND_FAILED;
ctx->marker.levelnow = be16_to_cpu(resp.media.remain);
return CUPS_BACKEND_OK;
}
static const char *mitsud90_prefixes[] = {
"mitsubishi-d90dw",
// backwards compatibility
"mitsud90",
NULL
};
/* Exported */
struct dyesub_backend mitsud90_backend = {
.name = "Mitsubishi CP-D90DW",
.version = "0.15",
.uri_prefixes = mitsud90_prefixes,
.cmdline_arg = mitsud90_cmdline_arg,
.cmdline_usage = mitsud90_cmdline,
.init = mitsud90_init,
.attach = mitsud90_attach,
.cleanup_job = mitsud90_cleanup_job,
.read_parse = mitsud90_read_parse,
.main_loop = mitsud90_main_loop,
.query_markers = mitsud90_query_markers,
.devices = {
{ USB_VID_MITSU, USB_PID_MITSU_D90, P_MITSU_D90, NULL, "mitsubishi-d90dw"},
{ 0, 0, 0, NULL, NULL}
}
};
/*
Mitsubishi CP-D90DW data format
All multi-byte values are BIG endian
[[HEADER 1]]
1b 53 50 30 00 33 XX XX YY YY 64 00 00 01 MM ?? XX XX == COLS, YY XX ROWS (BE)
?? ?? ?? ?? ?? ?? ?? ?? 00 00 00 00 00 00 00 00 <-- cut position, see below
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 MM == 0 for no margin cut, 1 for margin cut
QQ RR SS HH VV 00 00 00 00 00 01 00 03 II 09 7c QQ == 02 matte, 00 glossy,
09 4c 00 00 02 58 00 0c 00 06 RR == 00 auto, 03 == fine, 02 == superfine.
SS == 00 colorcorr, 01 == none
HH/VV sharpening for Horiz/Vert, 0-8, 0 is off, 4 is normal
[pad to 512b]
normal == rows 00 00 00 00 00 00 00 00 00
4x6div2 == 1226 00 02 65 01 00 00 01 00 00
8x6div2 == 2488 01 04 be 00 00 00 00 00 00
guesses based on SDK docs:
9x6div2 == 2728 01 05 36 00 00 00 00 00 00
9x6div3 == 2724 00 03 90 00 07 14 00 00 00
9x6div4 == 2628 00 02 97 00 05 22 00 07 ad
from [01 00 03 03] onwards, only shows in 8x20" PANORAMA prints. Assume 2" overlap.
II == 01 02 03 (which panel # in panorama!)
[02 58] == 600, aka 2" * 300dpi?
[09 4c] == 2380 (48 less than 8 size? (trim length on ends?)
[09 7c] == 2428 (ie 8" print)
(6x20 == 1852x6036)
(6x14 == 1852x4232)
3*8" panels == 2428*3=7284. -6036 = 1248. /2 = 624 (0x270)
[[DATA PLANE HEADER]]
1b 5a 54 01 00 09 00 00 00 00 XX XX YY YY 00 00
...
[pad to 512b]
data, RGB packed, 8bpp. No padding to 512b!
[[FOOTER]]
1b 42 51 31 00 TT ## TT == secs to wait for second print
****************************************************
Comms Protocol for D90 & CP-M1
[[ ERROR STATUS ]]
-> 1b 47 44 30 00 00 01 16
<- e4 47 44 30 00 00 00 00 00 00 00 00 00 00 00 [Normal/OK]
<- e4 47 44 30 XX 00 00 00 00 00 00 00 00 3f 37 [Error condition]
XX == 29 (printer open)
28 (cut bin missing)
<- e4 47 44 30 21 90 00 00 01 00 00 00 00 3f 37 No ribbon
[[ MEDIA STATUS ]]
-> 1b 47 44 30 00 00 01 2a
<- e4 47 44 30 ff 0f 50 00 01 ae 01 9b 01 00 [Normal/OK]
<- e4 47 44 30 ff ff ff ff ff ff ff ff ff ff [Error]
[[ MECHA STATUS ]]
-> 1b 47 44 30 00 00 01 17
<- e4 47 44 30 SS SS
[[ TEMPERATURE QUERY ]]
-> 1b 47 44 30 00 00 01 1f
<- e4 47 44 30 HH
[[ UNKNOWN QUERY ]]
-> 1b 47 44 30 00 00 01 28
<- e4 47 44 30 XX XX Unknown, seems to increment.
[[ JOB STATUS QUERY ?? ]]
-> 1b 47 44 31 00 00 JJ JJ Jobid?
<- e4 47 44 31 XX YY ZZ ZZ No idea.. sure.
[[ COMBINED STATUS QUERIES ]]
-> 1b 47 44 30 00 00 04 16 17 1f 2a
<- e4 47 44 30
MM NN 00 00 ZZ 00 00 00 00 QQ QQ [id 16, total 11]
SS SS [id 17, total 2]
HH [id 1f, total 1]
VV TT WW 00 XX XX YY YY 01 00 [id 2a, total 10]
WW == 0x50 or 0x00 (seen, no idea what it means)
VV == Media vendor (0xff etc)
TT == Media type, 0x02/0x0f etc (see mitsu70x_media_types!)
XX XX == Media capacity, BE
YY YY == Media remain, BE
QQ QQ == 00 00 normal, 3f 37 error
MM NN == MM major err (00 if no error) NN minor error.
ZZ == 01 seen for _some_ errors.
SS SS == Mecha Status (00 == ready, 50 == printing, 80+10 == feedandcut, 80 == initializing?
HH == Temperature state. 00 is OK, 0x40 is low, 0x80 is hot.
II II == ??
JJ JJ == ??
[[ WAKE UP PRINTER ]]
-> 1b 45 57 55
[[ GET iSERIAL ]]
-> 1b 61 36 36 41 be 00 00
00 01 00 00 00 11 ff ff
ff fe ff ff ff ee
<- e4 61 36 36 41 be 00 00
00 01 00 00 00 11 ff ff
ff fe ff ff ff ee XX <- XX is 0x80 or 0x00. (0x80) ISERIAL OFF
[[ GET CUT? ]]
-> 1b 61 36 36 45 ba 00 00
00 01 00 00 05 07 ff ff
ff fe ff ff fa f8
-> e4 61 36 36 45 ba 00 00
00 01 00 00 05 07 ff ff
ff fe ff ff fa f8 XX <- XX is 0x80 or 0x00 (0x00) CUT ON?
[[ GET WAIT TIME ]]
-> 1b 61 36 36 45 00 00 00
00 01 00 00 05 05 ff ff
ff fe ff ff fa fb
-> 1b 61 36 36 45 00 00 00
00 01 00 00 05 05 ff ff
ff fe ff ff fa fb XX <- XX is time in seconds.
[[ GET RESUME? ]]
-> 1b 61 36 36 45 ba 00 00
00 01 00 00 05 06 ff ff
ff fe ff ff fa f9
-> e4 61 36 36 45 ba 00 00
00 01 00 00 05 06 ff ff
ff fe ff ff fa f9 XX <- XX is 0x80 or 0x00 (0x80) (OFF)
[[ GET SLEEP TIME! ]]
-> 1b 61 36 36 45 ba 00 00
00 02 00 00 05 02 ff ff
ff fd ff ff fa fd
<- e4 61 36 36 45 00 00 00
00 02 00 00 05 02 ff ff
ff fd ff ff fa fd XX 00 <- XX, sleep time in minutes.
[[ SET SLEEP TIME! ]]
-> 1b 61 36 30 45 ba 00 00
00 02 00 00 05 02 ff ff
ff fd ff ff fa fd XX 00 <- XX, sleep time in minutes.
[[ SET iSERIAL ]]
-> 1b 61 36 30 41 be 00 00
00 01 00 00 00 11 ff ff
ff fe ff ff ff ee XX <- XX 0x80 OFF, 0x00 ON.
[[ SANITY CHECK PRINT ARGUMENTS / MEM CHECK ]]
-> 1b 47 44 33 00 33 07 3c 04 ca 64 00 00 01 00 00
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
00 00 00 04 04 00 00 00 00 00 00 00 00 00 00 00
[[ pad to 512 ]]
... 07 3c onwards is the same as main payload header.
<- e4 47 44 43 XX YY
... possibly the same as the D70's "memorystatus"
XX == 00 size ok, 01 bad size, ff out of range
YY == 00 memory ok, 01 memory full, 02 driver setting, ff out of range
[[ SEND OVER HDRs and DATA ]]
... Print arguments:
-> 1b 53 50 30 00 33 07 3c 04 ca 64 00 00 01 00 00
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
00 00 00 04 04 00 00 00 00 00 00 00 00 00 00 00
[[ pad to 512 ]]
... Data transfer. Plane header:
-> 1b 5a 54 01 00 09 00 00 00 00 07 3c 04 ca 00 00
[[ pad to 512 ]]
-> [[print data]] [[ padded? ]]
-> [[print data]]
-> 1b 42 51 31 00 ZZ
... Footer.
ZZ == Seconds to wait for follow-up print (0x05)
*/