/* gsc.c - device driver for handy scanners * * Current version supports: * * - Genius GS-4500 * * Copyright (c) 1995 Gunther Schadow. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Gunther Schadow. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "gsc.h" #if NGSC > 0 #include "param.h" #include "systm.h" #include "proc.h" #include "user.h" #include "buf.h" #include "malloc.h" #include "kernel.h" #include "ioctl.h" #include "tty.h" #include "uio.h" #include "syslog.h" #include "i386/isa/isa.h" #include "i386/isa/isa_device.h" #include "i386/isa/gscreg.h" #include "i386/include/gsc.h" /*********************************************************************** * * CONSTANTS & DEFINES * ***********************************************************************/ #define PROBE_FAIL 0 #define PROBE_SUCCESS 1 #define SUCCESS 0 #define FAIL -1 #define INVALID FAIL #define DMA1_READY 0x08 #ifdef GSCDEBUG #define lprintf if(scu->flags & DEBUG) printf #else #define lprintf (void) #endif #define MIN(a, b) (((a) < (b)) ? (a) : (b)) #define TIMEOUT (hz*15) /* timeout while reading a buffer - default value */ #define LONG (hz/60) /* timesteps while reading a buffer */ #define GSCPRI PRIBIO /* priority while reading a buffer */ /*********************************************************************** * * LAYOUT OF THE MINOR NUMBER * ***********************************************************************/ #define UNIT_MASK 0xc0 /* unit gsc0 .. gsc3 */ #define UNIT(x) (x >> 6) #define DBUG_MASK 0x20 #define FRMT_MASK 0x18 /* output format */ #define FRMT_RAW 0x00 /* output bits as read from scanner */ #define FRMT_GRAY 0x10 /* output graymap (not implemented yet) */ #define FRMT_PBM 0x08 /* output pbm format */ #define FRMT_PGM 0x18 /*********************************************************************** * * THE GEMOMETRY TABLE * ***********************************************************************/ #define GEOMTAB_SIZE 7 const struct gsc_geom { int dpi; /* dots per inch */ int dpl; /* dots per line */ int g_res; /* get resolution value (status flag) */ int s_res; /* set resolution value (control register) */ } geomtab[GEOMTAB_SIZE] = { { 100, 424, GSC_RES_100, GSC_CNT_424}, { 200, 840, GSC_RES_200, GSC_CNT_840}, { 300, 1264, GSC_RES_300, GSC_CNT_1264}, { 400, 1648, GSC_RES_400, GSC_CNT_1648}, { -1, 1696, -1, GSC_CNT_1696}, { -2, 2644, -2, GSC_CNT_2544}, { -3, 3648, -3, GSC_CNT_3648}, }; #define NEW_GEOM { INVALID, INVALID, INVALID, INVALID } /*********************************************************************** * * THE TABLE OF UNITS * ***********************************************************************/ struct _sbuf { size_t size; size_t poi; char *base; }; struct gsc_unit { int channel; /* DMA channel */ int data; /* - video port */ int stat; /* - status port */ int ctrl; /* - control port */ int clrp; /* - clear port */ int flags; #define ATTACHED 0x01 #define OPEN 0x02 #define READING 0x04 #define EOF 0x08 #define DEBUG 0x10 #define PBM_MODE 0x20 int geometry; /* resolution as geomtab index */ int blen; /* length of buffer in lines */ int btime; /* timeout of buffer in seconds/hz */ struct _sbuf sbuf; char ctrl_byte; /* the byte actually written to ctrl port */ int height; /* height, for pnm modes */ size_t bcount; /* bytes to read, for pnm modes */ struct _sbuf hbuf; /* buffer for pnm header data */ } unittab[NGSC]; /* I could not find a reasonable buffer size limit other than by * experiments. MAXPHYS is obviously too much, while DEV_BSIZE and * PAGE_SIZE are really too small. There must be something wrong * with isa_dmastart/isa_dmarangecheck HELP!!! */ #define MAX_BUFSIZE 0x3000 #define DEFAULT_BLEN 59 /*********************************************************************** * * THE PER-DRIVER RECORD FOR ISA.C * ***********************************************************************/ int gscprobe (struct isa_device *isdp); int gscattach(struct isa_device *isdp); struct isa_driver gscdriver = { gscprobe, gscattach, "gsc" }; /*********************************************************************** * * LOCALLY USED SUBROUTINES * ***********************************************************************/ /*********************************************************************** * * lookup_geometry -- lookup a record in the geometry table by pattern * * The caller supplies a geometry record pattern, where INVALID * matches anything. Returns the index in the table or INVALID if * lookup fails. */ static int lookup_geometry(struct gsc_geom geom, const struct gsc_unit *scu) { struct gsc_geom tab; int i; for(i=0; istat); if ( ( geom.g_res = inb(scu->stat) ) == FAIL ) return INVALID; geom.g_res &= GSC_RES_MASK; return lookup_geometry(geom, scu); } /*********************************************************************** * * buffer_allocate -- allocate/reallocate a buffer */ static int buffer_allocate(struct gsc_unit *scu) { size_t size; size = scu->blen * geomtab[scu->geometry].dpl / 8; lprintf("gsc.buffer_allocate: need 0x%x bytes\n", size); if ( size > MAX_BUFSIZE ) { lprintf("gsc.buffer_allocate: 0x%x bytes are too much\n", size); return ENOMEM; } if ( scu->sbuf.base != NULL ) if ( scu->sbuf.size == size ) { lprintf("gsc.buffer_allocate: keep old buffer\n"); return SUCCESS; } else { lprintf("gsc.buffer_allocate: release old buffer\n"); free( scu->sbuf.base, M_DEVBUF ); } scu->sbuf.base = (char *)malloc(size, M_DEVBUF, M_WAITOK); if ( scu->sbuf.base == NULL ) { lprintf("gsc.buffer_allocate: " "buffer allocatation failed for size = 0x%x\n", scu->sbuf.size); return ENOMEM; } scu->sbuf.size = size; scu->sbuf.poi = size; lprintf("gsc.buffer_allocate: ok\n"); return SUCCESS; } /*********************************************************************** * * buffer_read -- scan a buffer */ static int buffer_read(struct gsc_unit *scu) { int stb; int res = SUCCESS; int chan_bit; char *p; int sps; int delay; lprintf("gsc.buffer_read: begin\n"); if (scu->ctrl_byte == INVALID) { lprintf("gsc.buffer_read: invalid ctrl_byte\n"); return EIO; } sps=splbio(); outb( scu->ctrl, scu->ctrl_byte | GSC_POWER_ON ); outb( scu->clrp, 0 ); stb = inb( scu->stat ); isa_dmastart(B_READ, scu->sbuf.base, scu->sbuf.size, scu->channel); chan_bit = 0x01 << scu->channel; for(delay=0; !(inb(DMA1_READY) & 0x01 << scu->channel); delay += LONG) { if(delay >= scu->btime) { splx(sps); lprintf("gsc.buffer_read: timeout\n"); res = EWOULDBLOCK; break; } res = tsleep((caddr_t)scu, GSCPRI | PCATCH, "gscread", LONG); if ( ( res == 0 ) || ( res == EWOULDBLOCK ) ) res = SUCCESS; else break; } splx(sps); isa_dmadone(B_READ, scu->sbuf.base, scu->sbuf.size, scu->channel); outb( scu->clrp, 0 ); if(res != SUCCESS) { lprintf("gsc.buffer_read: aborted with %d\n", res); return res; } lprintf("gsc.buffer_read: invert buffer\n"); for(p = scu->sbuf.base + scu->sbuf.size - 1; p >= scu->sbuf.base; p--) *p = ~*p; scu->sbuf.poi = 0; lprintf("gsc.buffer_read: ok\n"); return SUCCESS; } /*********************************************************************** * * the main functions * ***********************************************************************/ /*********************************************************************** * * gscprobe * * read status port and check for proper configuration: * - if address group matches (status byte has reasonable value) * - if DMA channel matches (status byte has correct value) */ int gscprobe (struct isa_device *isdp) { int unit = isdp->id_unit; struct gsc_unit *scu = unittab + unit; int stb; struct gsc_geom geom = NEW_GEOM; scu->flags = DEBUG; lprintf("gsc%d.probe " "on iobase 0x%03x, irq %d, drq %d, addr %d, size %d\n", unit, isdp->id_iobase, isdp->id_irq, isdp->id_drq, isdp->id_maddr, isdp->id_msize); if ( isdp->id_iobase < 0 ) { lprintf("gsc%d.probe: no iobase given\n", unit); return PROBE_FAIL; } stb = inb( GSC_STAT(isdp->id_iobase) ); if (stb == FAIL) { lprintf("gsc%d.probe: get status byte failed\n", unit); return PROBE_FAIL; } scu->data = GSC_DATA(isdp->id_iobase); scu->stat = GSC_STAT(isdp->id_iobase); scu->ctrl = GSC_CTRL(isdp->id_iobase); scu->clrp = GSC_CLRP(isdp->id_iobase); outb(scu->clrp,stb); stb = inb(scu->stat); switch(stb & GSC_CNF_MASK) { case GSC_CNF_DMA1: lprintf("gsc%d.probe: DMA 1\n", unit); scu->channel = 1; break; case GSC_CNF_DMA3: lprintf("gsc%d.probe: DMA 3\n", unit); scu->channel = 3; break; case GSC_CNF_IRQ3: lprintf("gsc%d.probe: IRQ 3\n", unit); goto probe_noirq; case GSC_CNF_IRQ5: lprintf("gsc%d.probe: IRQ 5\n", unit); probe_noirq: lprintf("gsc%d.probe: sorry, can't use IRQ yet\n", unit); return PROBE_FAIL; default: lprintf("gsc%d.probe: invalid status byte\n", unit, stb); return PROBE_FAIL; } geom.g_res = stb & GSC_RES_MASK; scu->geometry = lookup_geometry(geom, scu); if (scu->geometry == INVALID) { lprintf("gsc%d.probe: geometry lookup failed\n", unit); return PROBE_FAIL; } else { scu->ctrl_byte = geomtab[scu->geometry].s_res; outb(scu->ctrl, scu->ctrl_byte | GSC_POWER_ON); lprintf("gsc%d.probe: status 0x%02x, %ddpi\n", unit, stb, geomtab[scu->geometry].dpi); outb(scu->ctrl, scu->ctrl_byte & ~GSC_POWER_ON); } lprintf("gsc%d.probe: ok\n", unit); scu->flags &= ~DEBUG; return PROBE_SUCCESS; } /*********************************************************************** * * gscattach * * finish initialization of unit structure * get geometry value */ int gscattach(struct isa_device *isdp) { int unit = isdp->id_unit; struct gsc_unit *scu = unittab + unit; scu->flags |= DEBUG; lprintf("gsc%d.attach: " "iobase 0x%03x, irq %d, drq %d, addr %d, size %d\n", unit, isdp->id_iobase, isdp->id_irq, isdp->id_drq, isdp->id_maddr, isdp->id_msize); printf("gsc%d: GeniScan GS-4500 at %ddpi\n", unit, geomtab[scu->geometry].dpi); /* initialize buffer structure */ scu->sbuf.base = NULL; scu->sbuf.size = INVALID; scu->sbuf.poi = INVALID; scu->blen = DEFAULT_BLEN; scu->btime = TIMEOUT; scu->flags |= ATTACHED; lprintf("gsc%d.attach: ok\n", unit); scu->flags &= ~DEBUG; return SUCCESS; /* attach must not fail */ } /*********************************************************************** * * gscopen * * set open flag * set modes according to minor number * don't switch scanner on, wait until first read ioctls go before */ int gscopen (dev_t dev, int flag) { int unit = UNIT(minor(dev)) & UNIT_MASK; struct gsc_unit *scu = unittab + unit; if ( minor(dev) & DBUG_MASK ) scu->flags |= DEBUG; else scu->flags &= ~DEBUG; switch(minor(dev) & FRMT_MASK) { case FRMT_PBM: scu->flags |= PBM_MODE; lprintf("gsc%d.open: pbm mode\n", unit); break; case FRMT_RAW: lprintf("gsc%d.open: raw mode\n", unit); scu->flags &= ~PBM_MODE; break; default: lprintf("gsc%d.open: gray maps are not yet supported", unit); return ENXIO; } lprintf("gsc%d.open: minor %d\n", unit, minor(dev)); if ( unit >= NGSC || !( scu->flags & ATTACHED ) ) { lprintf("gsc%d.open: unit was not attached successfully 0x04x\n", unit, scu->flags); return ENXIO; } if ( scu->flags & OPEN ) { lprintf("gsc%d.open: already open", unit); return EBUSY; } scu->flags |= OPEN; return SUCCESS; } /*********************************************************************** * * gscclose * * turn off scanner * release the buffer */ int gscclose (dev_t dev, int flag) { int unit = UNIT(minor(dev)); struct gsc_unit *scu = unittab + unit; lprintf("gsc%d.close: minor %d\n", unit, minor(dev)); if ( unit >= NGSC || !( scu->flags & ATTACHED ) ) { lprintf("gsc%d.read: unit was not attached successfully 0x04x\n", unit, scu->flags); return ENXIO; } outb(scu->ctrl, scu->ctrl_byte & ~GSC_POWER_ON); if ( scu->sbuf.base != NULL ) free( scu->sbuf.base, M_DEVBUF ); scu->sbuf.base = NULL; scu->sbuf.size = INVALID; scu->sbuf.poi = INVALID; scu->flags &= ~(DEBUG | OPEN | READING); return SUCCESS; } /*********************************************************************** * * gscread */ int gscread (dev_t dev, struct uio *uio) { int unit = UNIT(minor(dev)); struct gsc_unit *scu = unittab + unit; size_t nbytes; int res; lprintf("gsc%d.read: minor %d\n", unit, minor(dev)); if ( unit >= NGSC || !( scu->flags & ATTACHED ) ) { lprintf("gsc%d.read: unit was not attached successfully 0x04x\n", unit, scu->flags); return ENXIO; } if ( !(scu->flags & READING) ) { res = buffer_allocate(scu); if ( res == SUCCESS ) scu->flags |= READING; else return res; scu->ctrl_byte = geomtab[scu->geometry].s_res; /* initialize for pbm mode */ if ( scu->flags & PBM_MODE ) { char *p; int width = geomtab[scu->geometry].dpl; sprintf(scu->sbuf.base,"P4 %d %d\n", width, scu->height); scu->bcount = scu->height * width / 8; lprintf("gsc%d.read: initializing pbm mode: `%s', bcount: 0x%x\n", unit, scu->sbuf.base, scu->bcount); /* move header to end of sbuf */ for(p=scu->sbuf.base; *p; p++); while(--p >= scu->sbuf.base) { *(char *)(scu->sbuf.base + --scu->sbuf.poi) = *p; scu->bcount++; } } } lprintf("gsc%d.read(before buffer_read): " "size 0x%x, pointer 0x%x, bcount 0x%x, ok\n", unit, scu->sbuf.size, scu->sbuf.poi, scu->bcount); if ( scu->sbuf.poi == scu->sbuf.size ) if ( (res = buffer_read(scu)) != SUCCESS ) return res; lprintf("gsc%d.read(after buffer_read): " "size 0x%x, pointer 0x%x, bcount 0x%x, ok\n", unit, scu->sbuf.size, scu->sbuf.poi, scu->bcount); nbytes = MIN( uio->uio_resid, scu->sbuf.size - scu->sbuf.poi ); if ( (scu->flags & PBM_MODE) ) nbytes = MIN( nbytes, scu->bcount ); lprintf("gsc%d.read: transferring 0x%x bytes", nbytes); res = uiomove(scu->sbuf.base + scu->sbuf.poi, nbytes, uio); if ( res != SUCCESS ) { lprintf("gsc%d.read: uiomove failed %d", unit, res); return res; } scu->sbuf.poi += nbytes; if ( scu->flags & PBM_MODE ) scu->bcount -= nbytes; lprintf("gsc%d.read: size 0x%x, pointer 0x%x, bcount 0x%x, ok\n", unit, scu->sbuf.size, scu->sbuf.poi, scu->bcount); return SUCCESS; } /*********************************************************************** * * gscioctl * */ int gscioctl (dev_t dev, int cmd, caddr_t data, int flag, struct proc *p) { int unit = UNIT(minor(dev)); struct gsc_unit *scu = unittab + unit; lprintf("gsc%d.ioctl: minor %d\n", unit, minor(dev)); if ( unit >= NGSC || !( scu->flags & ATTACHED ) ) { lprintf("gsc%d.ioctl: unit was not attached successfully 0x04x\n", unit, scu->flags); return ENXIO; } switch(cmd) { case GSC_SRESSW: lprintf("gsc%d.ioctl:GSC_SRESSW\n", unit); if ( scu->flags & READING ) { lprintf("gsc%d:ioctl on already reading unit\n", unit); return EBUSY; } scu->geometry = get_geometry(scu); return SUCCESS; case GSC_GRES: *(int *)data=geomtab[scu->geometry].dpi; lprintf("gsc%d.ioctl:GSC_GRES %ddpi\n", unit, *(int *)data); return SUCCESS; case GSC_GWIDTH: *(int *)data=geomtab[scu->geometry].dpl; lprintf("gsc%d.ioctl:GSC_GWIDTH %d\n", unit, *(int *)data); return SUCCESS; case GSC_SRES: case GSC_SWIDTH: lprintf("gsc%d.ioctl:GSC_SRES or GSC_SWIDTH %d\n", unit, *(int *)data); { int g; struct gsc_geom geom = NEW_GEOM; if ( cmd == GSC_SRES ) geom.dpi = *(int *)data; else geom.dpl = *(int *)data; if ( ( g = lookup_geometry(geom, scu) ) == INVALID ) return EINVAL; scu->geometry = g; return SUCCESS; } case GSC_GHEIGHT: *(int *)data=scu->height; lprintf("gsc%d.ioctl:GSC_GHEIGHT %d\n", unit, *(int *)data); return SUCCESS; case GSC_SHEIGHT: lprintf("gsc%d.ioctl:GSC_SHEIGHT %d\n", unit, *(int *)data); if ( scu->flags & READING ) { lprintf("gsc%d:ioctl on already reading unit\n", unit); return EBUSY; } scu->height=*(int *)data; return SUCCESS; case GSC_GBLEN: *(int *)data=scu->blen; lprintf("gsc%d.ioctl:GSC_GBLEN %d\n", unit, *(int *)data); return SUCCESS; case GSC_SBLEN: lprintf("gsc%d.ioctl:GSC_SBLEN %d\n", unit, *(int *)data); if (*(int *)data * geomtab[scu->geometry].dpl / 8 > MAX_BUFSIZE) { lprintf("gsc%d:ioctl buffer size too high\n", unit); return ENOMEM; } scu->blen=*(int *)data; return SUCCESS; case GSC_GBTIME: *(int *)data = scu->btime / hz; lprintf("gsc%d.ioctl:GSC_GBTIME %d\n", unit, *(int *)data); return SUCCESS; case GSC_SBTIME: scu->btime = *(int *)data * hz; lprintf("gsc%d.ioctl:GSC_SBTIME %d\n", unit, *(int *)data); return SUCCESS; default: return ENOTTY; } } #endif /* NGSC > 0 */