dev/qbus/qd.c

1.16   thorpej /*	$NetBSD: qd.c,v 1.16 2000/01/18 19:53:42 thorpej Exp $	*/
 1.1  jonathan
 1.1  jonathan /*-
 1.1  jonathan  * Copyright (c) 1988 Regents of the University of California.
 1.1  jonathan  * All rights reserved.
 1.1  jonathan  *
 1.1  jonathan  * Redistribution and use in source and binary forms, with or without
 1.1  jonathan  * modification, are permitted provided that the following conditions
 1.1  jonathan  * are met:
 1.1  jonathan  * 1. Redistributions of source code must retain the above copyright
 1.1  jonathan  *    notice, this list of conditions and the following disclaimer.
 1.1  jonathan  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  jonathan  *    notice, this list of conditions and the following disclaimer in the
 1.1  jonathan  *    documentation and/or other materials provided with the distribution.
 1.1  jonathan  * 3. All advertising materials mentioning features or use of this software
 1.1  jonathan  *    must display the following acknowledgement:
 1.1  jonathan  *	This product includes software developed by the University of
 1.1  jonathan  *	California, Berkeley and its contributors.
 1.1  jonathan  * 4. Neither the name of the University nor the names of its contributors
 1.1  jonathan  *    may be used to endorse or promote products derived from this software
 1.1  jonathan  *    without specific prior written permission.
 1.1  jonathan  *
 1.1  jonathan  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 1.1  jonathan  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1  jonathan  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1  jonathan  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 1.1  jonathan  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1  jonathan  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1  jonathan  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1  jonathan  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1  jonathan  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1  jonathan  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1  jonathan  * SUCH DAMAGE.
 1.1  jonathan  *
 1.1  jonathan  *	@(#)qd.c	7.1 (Berkeley) 6/28/91
 1.1  jonathan  */
 1.1  jonathan
 1.1  jonathan /************************************************************************
 1.1  jonathan *									*
 1.1  jonathan *			Copyright (c) 1985-1988 by			*
 1.1  jonathan *		Digital Equipment Corporation, Maynard, MA		*
 1.1  jonathan *			All rights reserved.				*
 1.1  jonathan *									*
 1.1  jonathan *   This software is furnished under a license and may be used and	*
 1.1  jonathan *   copied  only  in accordance with the terms of such license and	*
 1.1  jonathan *   with the  inclusion  of  the  above  copyright  notice.   This	*
 1.1  jonathan *   software  or  any  other copies thereof may not be provided or	*
 1.1  jonathan *   otherwise made available to any other person.  No title to and	*
 1.1  jonathan *   ownership of the software is hereby transferred.			*
 1.1  jonathan *									*
 1.1  jonathan *   The information in this software is subject to change  without	*
 1.1  jonathan *   notice  and should not be construed as a commitment by Digital	*
 1.1  jonathan *   Equipment Corporation.						*
 1.1  jonathan *									*
 1.1  jonathan *   Digital assumes no responsibility for the use  or  reliability	*
 1.1  jonathan *   of its software on equipment which is not supplied by Digital.	*
 1.1  jonathan *									*
 1.1  jonathan *************************************************************************/
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * qd.c - QDSS display driver for VAXSTATION-II GPX workstation
 1.1  jonathan  */
 1.8  jonathan
 1.8  jonathan #include "opt_ddb.h"
 1.1  jonathan
 1.1  jonathan #include "qd.h"
 1.1  jonathan
 1.5     ragge #include <sys/param.h>
1.12     ragge #include <sys/systm.h>
 1.5     ragge #include <sys/conf.h>
 1.5     ragge #include <sys/tty.h>
 1.5     ragge #include <sys/kernel.h>
 1.5     ragge #include <sys/device.h>
1.12     ragge #include <sys/poll.h>
1.15     ragge #include <sys/buf.h>
1.12     ragge
1.12     ragge #include <vm/vm.h>
1.12     ragge
1.12     ragge #include <dev/cons.h>
1.12     ragge
1.15     ragge #include <machine/bus.h>
1.15     ragge #include <machine/scb.h>
1.15     ragge
1.15     ragge #ifdef __vax__
1.15     ragge #include <machine/sid.h>
1.15     ragge #include <machine/cpu.h>
1.12     ragge #include <machine/pte.h>
1.15     ragge #endif
1.15     ragge
1.15     ragge #include <dev/qbus/ubavar.h>
1.12     ragge
1.15     ragge #include <dev/qbus/qduser.h>
1.15     ragge #include <dev/qbus/qdreg.h>
1.15     ragge #include <dev/qbus/qdioctl.h>
 1.5     ragge
 1.5     ragge #include "ioconf.h"
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * QDSS driver status flags for tracking operational state
 1.1  jonathan  */
 1.1  jonathan struct qdflags {
 1.1  jonathan 	u_int inuse;		/* which minor dev's are in use now */
 1.1  jonathan 	u_int config;		/* I/O page register content */
 1.1  jonathan 	u_int mapped;		/* user mapping status word */
 1.1  jonathan 	u_int kernel_loop;	/* if kernel console is redirected */
 1.1  jonathan 	u_int user_dma;		/* DMA from user space in progress */
 1.1  jonathan 	u_short pntr_id;	/* type code of pointing device */
 1.1  jonathan 	u_short duart_imask;	/* shadowing for duart intrpt mask reg */
 1.1  jonathan 	u_short adder_ie;	/* shadowing for adder intrpt enbl reg */
 1.1  jonathan 	u_short curs_acc;	/* cursor acceleration factor */
 1.1  jonathan 	u_short curs_thr;	/* cursor acceleration threshold level */
 1.1  jonathan 	u_short tab_res;	/* tablet resolution factor */
 1.1  jonathan 	u_short selmask;	/* mask for active qd select entries */
 1.1  jonathan };
 1.1  jonathan
 1.1  jonathan /*
1.15     ragge  * Softc struct to keep track of all states in this driver.
1.15     ragge  */
1.15     ragge struct	qd_softc {
1.15     ragge 	struct	device sc_dev;
1.15     ragge 	bus_space_tag_t	sc_iot;
1.15     ragge 	bus_space_handle_t sc_ioh;
1.15     ragge 	bus_dma_tag_t	sc_dmat;
1.15     ragge };
1.15     ragge
1.15     ragge /*
 1.1  jonathan  * bit definitions for 'inuse' entry
 1.1  jonathan  */
 1.1  jonathan #define CONS_DEV	0x01
 1.1  jonathan #define GRAPHIC_DEV	0x04
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * bit definitions for 'mapped' member of flag structure
 1.1  jonathan  */
 1.1  jonathan #define MAPDEV		0x01		/* hardware is mapped */
 1.1  jonathan #define MAPDMA		0x02		/* DMA buffer mapped */
 1.1  jonathan #define MAPEQ		0x04		/* event queue buffer mapped */
 1.1  jonathan #define MAPSCR		0x08		/* scroll param area mapped */
 1.1  jonathan #define MAPCOLOR	0x10		/* color map writing buffer mapped */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * bit definitions for 'selmask' member of qdflag structure
 1.1  jonathan  */
 1.1  jonathan #define SEL_READ	0x01		/* read select is active */
 1.1  jonathan #define SEL_WRITE	0x02		/* write select is active */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * constants used in shared memory operations
 1.1  jonathan  */
 1.1  jonathan #define EVENT_BUFSIZE  1024	/* # of bytes per device's event buffer */
 1.1  jonathan #define MAXEVENTS  ( (EVENT_BUFSIZE - sizeof(struct qdinput))	 \
 1.1  jonathan 	/ sizeof(struct _vs_event) )
 1.1  jonathan #define DMA_BUFSIZ	(1024 * 10)
 1.1  jonathan #define COLOR_BUFSIZ  ((sizeof(struct color_buf) + 512) & ~0x01FF)
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * reference to an array of "uba_device" structures built by the auto
 1.1  jonathan  * configuration program.  The uba_device structure decribes the device
 1.1  jonathan  * sufficiently for the driver to talk to it.  The auto configuration code
 1.1  jonathan  * fills in the uba_device structures (located in ioconf.c) from user
 1.1  jonathan  * maintained info.
 1.1  jonathan  */
 1.1  jonathan struct uba_device *qdinfo[NQD];  /* array of pntrs to each QDSS's */
 1.5     ragge struct tty *qd_tty[NQD*4];	/* teletype structures for each.. */
1.13     ragge volatile char *qvmem[NQD];
1.13     ragge volatile struct pte *QVmap[NQD];
 1.1  jonathan #define CHUNK	  (64 * 1024)
 1.1  jonathan #define QMEMSIZE  (1024 * 1024 * 4)	/* 4 meg */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * static storage used by multiple functions in this code
 1.1  jonathan  */
 1.1  jonathan int Qbus_unmap[NQD];		/* Qbus mapper release code */
 1.1  jonathan struct qdmap qdmap[NQD];	/* QDSS register map structure */
1.15     ragge struct qdflags qdflags[NQD];	/* QDSS register map structure */
 1.1  jonathan caddr_t qdbase[NQD];		/* base address of each QDSS unit */
 1.1  jonathan struct buf qdbuf[NQD];		/* buf structs used by strategy */
 1.1  jonathan short qdopened[NQD];		/* graphics device is open exclusive use */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * the array "event_shared[]" is made up of a number of event queue buffers
 1.1  jonathan  * equal to the number of QDSS's configured into the running kernel (NQD).
 1.1  jonathan  * Each event queue buffer begins with an event queue header (struct qdinput)
 1.1  jonathan  * followed by a group of event queue entries (struct _vs_event).  The array
 1.1  jonathan  * "*eq_header[]" is an array of pointers to the start of each event queue
 1.1  jonathan  * buffer in "event_shared[]".
 1.1  jonathan  */
 1.1  jonathan #define EQSIZE ((EVENT_BUFSIZE * NQD) + 512)
 1.1  jonathan
 1.1  jonathan char event_shared[EQSIZE];	    /* reserve space for event bufs */
 1.1  jonathan struct qdinput *eq_header[NQD];     /* event queue header pntrs */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * This allocation method reserves enough memory pages for NQD shared DMA I/O
 1.1  jonathan  * buffers.  Each buffer must consume an integral number of memory pages to
 1.1  jonathan  * guarantee that a following buffer will begin on a page boundary.  Also,
 1.1  jonathan  * enough space is allocated so that the FIRST I/O buffer can start at the
 1.1  jonathan  * 1st page boundary after "&DMA_shared".  Page boundaries are used so that
 1.1  jonathan  * memory protections can be turned on/off for individual buffers.
 1.1  jonathan  */
 1.1  jonathan #define IOBUFSIZE  ((DMA_BUFSIZ * NQD) + 512)
 1.1  jonathan
 1.1  jonathan char DMA_shared[IOBUFSIZE];	    /* reserve I/O buffer space */
 1.1  jonathan struct DMAreq_header *DMAheader[NQD];  /* DMA buffer header pntrs */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * The driver assists a client in scroll operations by loading dragon
 1.1  jonathan  * registers from an interrupt service routine.	The loading is done using
 1.1  jonathan  * parameters found in memory shrade between the driver and it's client.
 1.1  jonathan  * The scroll parameter structures are ALL loacted in the same memory page
 1.1  jonathan  * for reasons of memory economy.
 1.1  jonathan  */
 1.1  jonathan char scroll_shared[2 * 512];	/* reserve space for scroll structs */
 1.1  jonathan struct scroll *scroll[NQD];	/* pointers to scroll structures */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * the driver is programmable to provide the user with color map write
 1.1  jonathan  * services at VSYNC interrupt time.  At interrupt time the driver loads
 1.1  jonathan  * the color map with any user-requested load data found in shared memory
 1.1  jonathan  */
 1.1  jonathan #define COLOR_SHARED  ((COLOR_BUFSIZ * NQD) + 512)
 1.1  jonathan
 1.1  jonathan char color_shared[COLOR_SHARED];      /* reserve space: color bufs */
 1.1  jonathan struct color_buf *color_buf[NQD];     /* pointers to color bufs */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * mouse input event structures
 1.1  jonathan  */
 1.1  jonathan struct mouse_report last_rep[NQD];
 1.1  jonathan struct mouse_report current_rep[NQD];
 1.1  jonathan
 1.5     ragge struct selinfo qdrsel[NQD]; 	/* process waiting for select */
 1.1  jonathan struct _vs_cursor cursor[NQD];	/* console cursor */
 1.1  jonathan int qdcount = 0;		/* count of successfully probed qd's */
 1.1  jonathan int nNQD = NQD;
 1.1  jonathan int DMAbuf_size = DMA_BUFSIZ;
 1.1  jonathan int QDlast_DMAtype;             /* type of the last DMA operation */
 1.1  jonathan
 1.5     ragge /* #define QDSSMAJOR	41 */	/* QDSS major device number.  We don't care! */
 1.5     ragge
 1.1  jonathan /*
 1.1  jonathan  * macro to get system time.  Used to time stamp event queue entries
 1.1  jonathan  */
 1.1  jonathan #define TOY ((time.tv_sec * 100) + (time.tv_usec / 10000))
 1.1  jonathan
 1.6     ragge void qd_attach __P((struct device *, struct device *, void *));
 1.6     ragge static int qd_match __P((struct device *, struct cfdata *, void *));
 1.6     ragge
 1.5     ragge static void qddint(int);			/* DMA gate array intrpt service */
 1.5     ragge static void qdaint(int);			/* Dragon ADDER intrpt service */
 1.5     ragge static void qdiint(int);
 1.1  jonathan
 1.1  jonathan #define QDPRIOR (PZERO-1)		/* must be negative */
 1.1  jonathan #define FALSE	0
 1.5     ragge #ifdef TRUE
 1.5     ragge #undef TRUE
 1.5     ragge #endif
 1.1  jonathan #define TRUE	~FALSE
 1.1  jonathan #define BAD	-1
 1.1  jonathan #define GOOD	0
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * macro to create a system virtual page number from system virtual adrs
 1.1  jonathan  */
1.11     ragge #define VTOP(x)  (((int)x & ~0xC0000000) >> VAX_PGSHIFT)
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * QDSS register address offsets from start of QDSS address space
 1.1  jonathan  */
 1.1  jonathan #define QDSIZE	 (52 * 1024)	/* size of entire QDSS foot print */
 1.1  jonathan #define TMPSIZE  (16 * 1024)	/* template RAM is 8k SHORT WORDS */
 1.1  jonathan #define TMPSTART 0x8000 	/* offset of template RAM from base adrs */
 1.1  jonathan #define REGSIZE  (5 * 512)	/* regs touch 2.5k (5 pages) of addr space */
 1.1  jonathan #define REGSTART 0xC000 	/* offset of reg pages from base adrs */
 1.1  jonathan #define ADDER	(REGSTART+0x000)
 1.1  jonathan #define DGA	(REGSTART+0x200)
 1.1  jonathan #define DUART	(REGSTART+0x400)
 1.1  jonathan #define MEMCSR	(REGSTART+0x800)
 1.1  jonathan #define CLRSIZE  (3 * 512)		/* color map size */
 1.1  jonathan #define CLRSTART (REGSTART+0xA00)	/* color map start offset from base */
 1.1  jonathan /*  0x0C00 really */
 1.1  jonathan #define RED	(CLRSTART+0x000)
 1.1  jonathan #define BLUE	(CLRSTART+0x200)
 1.1  jonathan #define GREEN	(CLRSTART+0x400)
 1.1  jonathan
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * QDSS minor device numbers.  The *real* minor device numbers are in
 1.1  jonathan  * the bottom two bits of the major/minor device spec.  Bits 2 and up are
 1.1  jonathan  * used to specify the QDSS device number (ie: which one?)
 1.1  jonathan  */
 1.1  jonathan
 1.1  jonathan #define CONS		0
 1.1  jonathan #define GRAPHIC 	2
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * console cursor bitmap (white block cursor)
 1.1  jonathan  */
 1.1  jonathan short cons_cursor[32] = {
 1.1  jonathan 	/* A */ 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF,
 1.1  jonathan 	0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF,
 1.1  jonathan 	/* B */ 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF,
 1.1  jonathan 	0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF, 0x00FF
 1.1  jonathan };
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * constants used in font operations
 1.1  jonathan  */
 1.1  jonathan #define CHARS		190 			/* # of chars in the font */
 1.1  jonathan #define CHAR_HEIGHT	15			/* char height in pixels */
 1.1  jonathan #define CHAR_WIDTH	8			/* char width in pixels*/
 1.1  jonathan #define FONT_WIDTH	(CHAR_WIDTH * CHARS)	/* font width in pixels */
 1.1  jonathan #define ROWS		CHAR_HEIGHT
 1.1  jonathan #define FONT_X		0			/* font's off screen adrs */
 1.1  jonathan #define FONT_Y		(2048 - CHAR_HEIGHT)
 1.1  jonathan
 1.1  jonathan /* Offset to second row characters (XXX - should remove) */
 1.1  jonathan #define FONT_OFFSET	((MAX_SCREEN_X/CHAR_WIDTH)*CHAR_HEIGHT)
 1.1  jonathan
 1.1  jonathan extern char q_font[];		/* reference font object code */
 1.1  jonathan extern	u_short q_key[];	/* reference key xlation tables */
 1.1  jonathan extern	u_short q_shift_key[];
 1.1  jonathan extern	char *q_special[];
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * definitions for cursor acceleration reporting
 1.1  jonathan  */
 1.1  jonathan #define ACC_OFF 	0x01		/* acceleration is inactive */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * virtual console support.
 1.1  jonathan  */
 1.1  jonathan extern struct cdevsw *consops;
 1.6     ragge cons_decl(qd);
 1.6     ragge cdev_decl(qd);
 1.6     ragge void setup_dragon __P((int));
 1.6     ragge void init_shared __P((int));
 1.6     ragge void clear_qd_screen __P((int));
 1.6     ragge void ldfont __P((int));
 1.6     ragge void ldcursor __P((int, short *));
 1.6     ragge void setup_input __P((int));
 1.6     ragge void blitc __P((int, u_char));
 1.6     ragge void scroll_up __P((volatile struct adder *));
 1.6     ragge void write_ID __P((volatile struct adder *, short, short));
 1.6     ragge int wait_status __P((volatile struct adder *, int));
 1.6     ragge void led_control __P((int, int, int));
 1.5     ragge void qdstart(struct tty *);
1.13     ragge void qdearly(void);
 1.1  jonathan int qdpolling = 0;
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * LK-201 state storage for input console keyboard conversion to ASCII
 1.1  jonathan  */
 1.1  jonathan struct q_keyboard {
 1.1  jonathan 	int shift;			/* state variables	*/
 1.1  jonathan 	int cntrl;
 1.1  jonathan 	int lock;
 1.1  jonathan 	int lastcode;			/* last keycode typed	*/
 1.1  jonathan 	unsigned kup[8];		/* bits for each keycode*/
 1.1  jonathan 	unsigned dkeys[8];		/* down/up mode keys	*/
 1.1  jonathan 	char last;			/* last character	*/
 1.1  jonathan } q_keyboard;
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * tty settings on first open
 1.1  jonathan  */
 1.1  jonathan #define IFLAG (BRKINT|ISTRIP|IXON|IXANY|ICRNL|IMAXBEL)
 1.1  jonathan #define OFLAG (OPOST|OXTABS|ONLCR)
 1.1  jonathan #define LFLAG (ISIG|ICANON|ECHO|IEXTEN)
 1.1  jonathan #define CFLAG (PARENB|CREAD|CS7|CLOCAL)
 1.1  jonathan
 1.1  jonathan /*
 1.5     ragge  * Kernel virtual addresses where we can map in the QBUS io page and the
 1.5     ragge  * QDSS memory during qdcninit.  pmap_bootstrap fills this in.
 1.1  jonathan  */
 1.5     ragge void *qd_ubaio;
 1.1  jonathan
 1.5     ragge /* This is the QDSS unit 0 CSR.  It is hard-coded in here so that the
 1.5     ragge  * QDSS can be used as the console.  The console routines don't get
 1.5     ragge  * any config info.  The ROM also autodetects at this address, so
 1.5     ragge  * the console QDSS should be at this address.  Furthermore, nothing
 1.5     ragge  * else shuld be at this address instead because that would confuse the
 1.5     ragge  * ROM and this driver.
 1.5     ragge  */
 1.1  jonathan #define QDSSCSR 0x1F00
 1.1  jonathan
 1.5     ragge volatile u_short *qdaddr;         /* Virtual address for QDSS CSR */
 1.1  jonathan
 1.5     ragge /*
 1.5     ragge  * This flag is set to 1 if the console initialization (qdcninit)
 1.5     ragge  * has been performed on qd0.  That initialization is required and must
 1.5     ragge  * be done before the device probe routine.
 1.5     ragge  */
1.13     ragge int qd0cninited = 0, qd0iscons = 0;
1.13     ragge
1.13     ragge /*
1.13     ragge  * Do early check if the qdss is console. If not; don't allocate
1.13     ragge  * any memory for it in bootstrap.
1.13     ragge  */
1.13     ragge void
1.13     ragge qdearly()
1.13     ragge {
1.13     ragge 	extern vaddr_t virtual_avail;
1.13     ragge 	int tmp;
1.13     ragge
1.13     ragge 	/* Make sure we're running on a system that can have a QDSS */
1.13     ragge 	if (vax_boardtype == VAX_BTYP_630)  {
1.13     ragge 		/* Now check some undocumented flag */
1.13     ragge 		if ((*(int *)(0x200B801E) & 0x60) == 0)
1.13     ragge 			/* The KA630 isn't using a QDSS as the console,
1.13     ragge 			 * so we won't either */
1.13     ragge 			return;
1.13     ragge 	} else if (vax_boardtype != VAX_BTYP_650)
1.13     ragge 		return;
1.13     ragge
1.13     ragge 	/* How to check for console on KA650? We assume that if there is a
1.13     ragge 	 * QDSS, it is console.
1.13     ragge 	 */
1.15     ragge #define	QIOPAGE	0x20000000	/* XXX */
1.15     ragge #define	UBAIOPAGES 16
1.13     ragge 	tmp = QIOPAGE + ubdevreg(QDSSCSR);
1.13     ragge 	if (badaddr((caddr_t)tmp, sizeof(short)))
1.13     ragge 		return;
1.13     ragge
1.13     ragge 	MAPVIRT(qvmem[0], 64 * 1024 * NQD / VAX_NBPG);
1.13     ragge 	MAPVIRT(qd_ubaio, 16);
1.13     ragge 	pmap_map((int)qd_ubaio, QIOPAGE, QIOPAGE + UBAIOPAGES * VAX_NBPG,
1.13     ragge 	    VM_PROT_READ|VM_PROT_WRITE);
1.13     ragge 	qdaddr = (u_short *)((u_int)qd_ubaio + ubdevreg(QDSSCSR));
1.13     ragge 	qd0iscons = 1;
1.13     ragge }
 1.1  jonathan
 1.5     ragge void
 1.5     ragge qdcnprobe(cndev)
1.13     ragge 	struct  consdev *cndev;
 1.5     ragge {
1.13     ragge 	int i;
 1.1  jonathan
1.13     ragge 	cndev->cn_pri = CN_DEAD;
 1.5     ragge
 1.6     ragge 	if (mfpr(PR_MAPEN) == 0)
 1.6     ragge 		return; /* Cannot use qd if vm system is OFF */
 1.6     ragge
1.13     ragge 	if (!qd0iscons)
1.13     ragge 		return;
1.13     ragge
1.13     ragge 	/* Find the console device corresponding to the console QDSS */
1.13     ragge 	for (i = 0; i < nchrdev; i++)
1.13     ragge 		if (cdevsw[i].d_open == qdopen)  {
1.13     ragge 			      cndev->cn_dev = makedev(i,0);
1.13     ragge 			      cndev->cn_pri = CN_INTERNAL;
1.13     ragge 			      return;
1.13     ragge 		 }
1.13     ragge 	return;
 1.5     ragge }
 1.5     ragge
 1.5     ragge
 1.5     ragge /*
 1.5     ragge  * Init QDSS as console (before probe routine)
 1.5     ragge  */
 1.6     ragge void
 1.5     ragge qdcninit(cndev)
1.13     ragge 	struct  consdev *cndev;
 1.5     ragge {
 1.5     ragge 	caddr_t phys_adr;		/* physical QDSS base adrs */
 1.5     ragge 	u_int mapix;			/* index into QVmap[] array */
1.13     ragge 	int unit;
 1.1  jonathan
1.13     ragge 	/* qdaddr must point to CSR for this unit! */
 1.5     ragge
1.13     ragge 	/* The console QDSS is QDSS unit 0 */
1.13     ragge 	unit = 0;
 1.5     ragge
1.13     ragge 	/*
 1.1  jonathan 	 * Map q-bus memory used by qdss. (separate map)
 1.1  jonathan 	 */
 1.1  jonathan 	mapix = QMEMSIZE - (CHUNK * (unit + 1));
1.15     ragge #define	QMEM 0x30000000
1.13     ragge 	(int)phys_adr = QMEM + mapix;
1.13     ragge 	pmap_map((int)(qvmem[0]), (int)phys_adr, (int)(phys_adr + (CHUNK*NQD)),
1.13     ragge 				    VM_PROT_READ|VM_PROT_WRITE);
 1.5     ragge
1.13     ragge 	/*
 1.5     ragge 	 * Set QVmap to point to page table entries for what we just
 1.5     ragge 	 * mapped.
 1.5     ragge 	 */
1.13     ragge 	QVmap[0] = (struct pte *)kvtopte(qvmem[0]);
 1.5     ragge
1.13     ragge 	/*
 1.1  jonathan 	 * tell QDSS which Q memory address base to decode
 1.1  jonathan 	 * (shifted right 16 bits - its in 64K units)
 1.1  jonathan 	 */
 1.1  jonathan 	*qdaddr = (u_short)((int)mapix >> 16);
 1.1  jonathan 	qdflags[unit].config = *(u_short *)qdaddr;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * load qdmap struct with the virtual addresses of the QDSS elements
 1.1  jonathan 	 */
 1.1  jonathan 	qdbase[unit] = (caddr_t) (qvmem[0]);
 1.1  jonathan 	qdmap[unit].template = qdbase[unit] + TMPSTART;
 1.1  jonathan 	qdmap[unit].adder = qdbase[unit] + ADDER;
 1.1  jonathan 	qdmap[unit].dga = qdbase[unit] + DGA;
 1.1  jonathan 	qdmap[unit].duart = qdbase[unit] + DUART;
 1.1  jonathan 	qdmap[unit].memcsr = qdbase[unit] + MEMCSR;
 1.1  jonathan 	qdmap[unit].red = qdbase[unit] + RED;
 1.1  jonathan 	qdmap[unit].blue = qdbase[unit] + BLUE;
 1.1  jonathan 	qdmap[unit].green = qdbase[unit] + GREEN;
 1.1  jonathan
 1.1  jonathan 	qdflags[unit].duart_imask = 0;	/* init shadow variables */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * init the QDSS
 1.1  jonathan 	 */
 1.5     ragge
 1.1  jonathan 	*(short *)qdmap[unit].memcsr |= SYNC_ON; /* once only: turn on sync */
 1.1  jonathan
 1.1  jonathan 	cursor[unit].x = 0;
 1.1  jonathan 	cursor[unit].y = 0;
 1.1  jonathan 	init_shared(unit);		/* init shared memory */
 1.1  jonathan 	setup_dragon(unit);		/* init the ADDER/VIPER stuff */
 1.1  jonathan 	clear_qd_screen(unit);		/* clear the screen */
 1.1  jonathan 	ldfont(unit);			/* load the console font */
 1.1  jonathan 	ldcursor(unit, cons_cursor);	/* load default cursor map */
 1.1  jonathan 	setup_input(unit);		/* init the DUART */
 1.1  jonathan
1.13     ragge 	/* Set flag so probe knows */
1.13     ragge 	qd0cninited = 1;
 1.5     ragge } /* qdcninit */
 1.1  jonathan
1.15     ragge /* see <sys/device.h> */
1.15     ragge struct cfattach qd_ca = {
1.15     ragge 	sizeof(struct qd_softc), qd_match, qd_attach
1.15     ragge };
1.15     ragge
1.15     ragge #define	QD_RCSR(reg) \
1.15     ragge 	bus_space_read_2(sc->sc_iot, sc->sc_ioh, reg)
1.15     ragge #define	QD_WCSR(reg, val) \
1.15     ragge 	bus_space_write_2(sc->sc_iot, sc->sc_ioh, reg, val)
 1.5     ragge
 1.1  jonathan /*
 1.1  jonathan  *  Configure QDSS into Q memory and make it intrpt.
 1.1  jonathan  *
 1.1  jonathan  *  side effects: QDSS gets mapped into Qbus memory space at the first
 1.1  jonathan  *		 vacant 64kb boundary counting back from the top of
 1.1  jonathan  *		 Qbus memory space (qvmem+4mb)
 1.1  jonathan  *
 1.1  jonathan  *  return: QDSS bus request level and vector address returned in
 1.1  jonathan  *	   registers by UNIX convention.
 1.1  jonathan  *
 1.1  jonathan  */
 1.5     ragge static int
 1.5     ragge qd_match(parent, match, aux)
1.13     ragge 	struct device *parent;
 1.6     ragge 	struct cfdata *match;
1.13     ragge 	void *aux;
 1.5     ragge {
1.15     ragge 	struct qd_softc ssc;
1.15     ragge 	struct qd_softc *sc = &ssc;
1.13     ragge 	struct uba_attach_args *ua = aux;
1.13     ragge 	struct uba_softc *uh = (void *)parent;
 1.1  jonathan 	register int unit;
 1.5     ragge 	volatile struct dga *dga;       /* pointer to gate array structure */
 1.1  jonathan 	int vector;
 1.1  jonathan #ifdef notdef
 1.1  jonathan 	int *ptep;			/* page table entry pointer */
 1.1  jonathan 	caddr_t phys_adr;		/* physical QDSS base adrs */
 1.1  jonathan 	u_int mapix;
 1.1  jonathan #endif
 1.1  jonathan
1.15     ragge 	/* Create a "fake" softc with only a few fields used. */
1.15     ragge 	sc->sc_iot = ua->ua_iot;
1.15     ragge 	sc->sc_ioh = ua->ua_ioh;
1.15     ragge 	sc->sc_dmat = ua->ua_dmat;
 1.1  jonathan 	/*
 1.1  jonathan 	 * calculate board unit number from I/O page register address
 1.1  jonathan 	 */
1.15     ragge 	unit = (int) (((int)sc->sc_ioh >> 1) & 0x0007);
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * QDSS regs must be mapped to Qbus memory space at a 64kb
1.13     ragge 	 * physical boundary.  The Qbus memory space is mapped into
 1.1  jonathan 	 * the system memory space at config time.  After config
 1.1  jonathan 	 * runs, "qvmem[0]" (ubavar.h) holds the system virtual adrs
 1.1  jonathan 	 * of the start of Qbus memory.   The Qbus memory page table
 1.1  jonathan 	 * is found via an array of pte ptrs called "QVmap[]" (ubavar.h)
 1.1  jonathan 	 * which is also loaded at config time.   These are the
 1.1  jonathan 	 * variables used below to find a vacant 64kb boundary in
 1.1  jonathan 	 * Qbus memory, and load it's corresponding physical adrs
 1.1  jonathan 	 * into the QDSS's I/O page CSR.
 1.1  jonathan 	 */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * Only if QD is the graphics device.
 1.1  jonathan 	 */
 1.1  jonathan
1.13     ragge 	/* if this QDSS is NOT the console, then do init here.. */
 1.1  jonathan
 1.1  jonathan 	if (unit != 0) {
 1.4  christos 		printf("qd: can't support two qdss's (yet)\n");
 1.1  jonathan #ifdef notdef	/* can't test */
 1.1  jonathan 		if (v_consputc != qdputc  ||  unit != 0) {
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* read QDSS config info
 1.1  jonathan 			*/
 1.1  jonathan 			qdflags[unit].config = *(u_short *)reg;
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* find an empty 64kb adrs boundary
 1.1  jonathan 			*/
 1.1  jonathan
 1.1  jonathan 			qdbase[unit] = (caddr_t) (qvmem[0] + QMEMSIZE - CHUNK);
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* find the cpusw entry that matches this machine.
 1.1  jonathan 			*/
 1.1  jonathan 			cpup = &cpusw[cpu];
 1.1  jonathan 			while (!(BADADDR(qdbase[unit], sizeof(short))))
 1.1  jonathan 				qdbase[unit] -= CHUNK;
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* tell QDSS which Q memory address base to decode
 1.1  jonathan 			*/
 1.1  jonathan 			mapix = (int) (VTOP(qdbase[unit]) - VTOP(qvmem[0]));
 1.1  jonathan 			ptep = (int *) QVmap[0] + mapix;
1.11     ragge 			phys_adr = (caddr_t)(((int)*ptep&0x001FFFFF)<<VAX_PGSHIFT);
 1.1  jonathan 			*(u_short *)reg = (u_short) ((int)phys_adr >> 16);
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* load QDSS adrs map with system addresses
 1.1  jonathan 			* of device regs
 1.1  jonathan 			*/
 1.1  jonathan 			qdmap[unit].template = qdbase[unit] + TMPSTART;
 1.1  jonathan 			qdmap[unit].adder = qdbase[unit] + ADDER;
 1.1  jonathan 			qdmap[unit].dga = qdbase[unit] + DGA;
 1.1  jonathan 			qdmap[unit].duart = qdbase[unit] + DUART;
 1.1  jonathan 			qdmap[unit].memcsr = qdbase[unit] + MEMCSR;
 1.1  jonathan 			qdmap[unit].red = qdbase[unit] + RED;
 1.1  jonathan 			qdmap[unit].blue = qdbase[unit] + BLUE;
 1.1  jonathan 			qdmap[unit].green = qdbase[unit] + GREEN;
 1.1  jonathan
 1.1  jonathan 			/* device init */
 1.1  jonathan
 1.1  jonathan 			cursor[unit].x = 0;
 1.1  jonathan 			cursor[unit].y = 0;
 1.1  jonathan 			init_shared(unit);		/* init shared memory */
 1.1  jonathan 			setup_dragon(unit); 	/* init the ADDER/VIPER stuff */
 1.1  jonathan 			ldcursor(unit, cons_cursor);	/* load default cursor map */
 1.1  jonathan 			setup_input(unit);		/* init the DUART */
 1.1  jonathan 			clear_qd_screen(unit);
 1.1  jonathan 			ldfont(unit);			/* load the console font */
 1.1  jonathan
 1.1  jonathan 			/* once only: turn on sync */
 1.1  jonathan
 1.1  jonathan 			*(short *)qdmap[unit].memcsr |= SYNC_ON;
 1.1  jonathan 		}
 1.1  jonathan #endif /*notdef*/
 1.5     ragge 	} else {
1.13     ragge 		/* We are dealing with qd0 */
1.13     ragge
1.13     ragge 		if (!qd0cninited) {
1.13     ragge 			/*
 1.5     ragge 			 * qd0 has not been initiallized as the console.
 1.5     ragge 			 * We need to do some initialization now
 1.5     ragge 			 *
1.13     ragge 			 * XXX
 1.5     ragge 			 * However, if the QDSS is not the console then
 1.5     ragge 			 * that stupid undocumented bit (see qdcnprobe)
 1.5     ragge 			 * is cleared.  Then the QDSS refuses to work.
 1.5     ragge 			 * (What did the ROM do to it!?)
 1.5     ragge 			 * XXX
 1.5     ragge 			 */
1.13     ragge 			 return 0;
 1.5     ragge
 1.5     ragge #if 0
1.13     ragge 			 qdaddr = (void *)reg;
 1.5     ragge
1.13     ragge 			 /* Lame probe for QDSS.  Should be ok for qd0 */
1.13     ragge 			 if (badaddr((caddr_t)qdaddr, sizeof(short)))
1.13     ragge 				 return 0;
 1.5     ragge
1.13     ragge 			 qdcninit(NULL);
 1.5     ragge #endif
 1.5     ragge 		}
 1.1  jonathan 	}
 1.5     ragge
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* The QDSS interrupts at HEX vectors xx0 (DMA) xx4
 1.1  jonathan 	* (ADDER) and xx8 (DUART).  Therefore, we take three
 1.1  jonathan 	* vectors from the vector pool, and then continue
 1.1  jonathan 	* to take them until we get a xx0 HEX vector.  The
 1.1  jonathan 	* pool provides vectors in contiguous decending
 1.1  jonathan 	* order.
 1.1  jonathan 	*/
 1.1  jonathan
 1.5     ragge 	vector = (uh->uh_lastiv -= 4*3);	/* take three vectors */
 1.1  jonathan
 1.1  jonathan 	while (vector & 0x0F) {		   /* if lo nibble != 0.. */
 1.1  jonathan 		/* ..take another vector */
 1.5     ragge 		vector = (uh->uh_lastiv -= 4);
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* setup DGA to do a DMA interrupt (transfer count = 0)
 1.1  jonathan 	*/
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 	dga->csr = (short) HALT;	/* disable everything */
 1.1  jonathan 	dga->ivr = (short) vector;	/* load intrpt base vector */
 1.1  jonathan 	dga->bytcnt_lo = (short) 0;	/* DMA xfer count = 0 */
 1.1  jonathan 	dga->bytcnt_hi = (short) 0;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* turn on DMA interrupts
 1.1  jonathan 	*/
 1.1  jonathan 	dga->csr &= ~SET_DONE_FIFO;
 1.1  jonathan 	dga->csr |= DMA_IE | DL_ENB;
 1.1  jonathan
 1.1  jonathan 	DELAY(20000);			/* wait for the intrpt */
 1.1  jonathan 	dga->csr = HALT;		/* stop the wheels */
 1.1  jonathan
1.13     ragge 	/* Set interrupt vector for DMA service routine */
1.13     ragge 	ua->ua_ivec = qddint;
 1.5     ragge
 1.1  jonathan 	/*
 1.1  jonathan 	* score this as an existing qdss
 1.1  jonathan 	*/
 1.1  jonathan 	qdcount++;
 1.1  jonathan
1.13     ragge 	return 1;
 1.1  jonathan } /* qdprobe */
 1.1  jonathan
 1.1  jonathan
 1.5     ragge void qd_attach(parent, self, aux)
1.13     ragge 	   struct device *parent, *self;
1.13     ragge 	   void *aux;
 1.5     ragge      {
 1.5     ragge 	register struct uba_attach_args *ua = aux;
 1.5     ragge
1.13     ragge 	register int unit;	/* QDSS module # for this call */
 1.5     ragge
 1.5     ragge 	printf("\n");
 1.5     ragge
 1.5     ragge 	unit = self->dv_unit;		/* get QDSS number */
 1.5     ragge
 1.5     ragge 	/* Grab the other two interrupt vectors */
1.12     ragge 	scb_vecalloc(ua->ua_cvec + 4, qdaint, self->dv_unit, SCB_ISTACK);
1.12     ragge 	scb_vecalloc(ua->ua_cvec + 8, qdiint, self->dv_unit, SCB_ISTACK);
1.12     ragge
 1.1  jonathan 	/*
 1.1  jonathan 	* init "qdflags[]" for this QDSS
 1.1  jonathan 	*/
 1.1  jonathan 	qdflags[unit].inuse = 0;	/* init inuse variable EARLY! */
 1.1  jonathan 	qdflags[unit].mapped = 0;
 1.1  jonathan 	qdflags[unit].kernel_loop = -1;
 1.1  jonathan 	qdflags[unit].user_dma = 0;
 1.1  jonathan 	qdflags[unit].curs_acc = ACC_OFF;
 1.1  jonathan 	qdflags[unit].curs_thr = 128;
 1.1  jonathan 	qdflags[unit].tab_res = 2;	/* default tablet resolution factor */
 1.1  jonathan 	qdflags[unit].duart_imask = 0;	/* init shadow variables */
 1.1  jonathan 	qdflags[unit].adder_ie = 0;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init structures used in kbd/mouse interrupt service.	This code must
 1.1  jonathan 	* come after the "init_shared()" routine has run since that routine
 1.1  jonathan 	* inits the eq_header[unit] structure used here.
 1.1  jonathan 	*/
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init the "latest mouse report" structure
 1.1  jonathan 	*/
 1.1  jonathan 	last_rep[unit].state = 0;
 1.1  jonathan 	last_rep[unit].dx = 0;
 1.1  jonathan 	last_rep[unit].dy = 0;
 1.1  jonathan 	last_rep[unit].bytcnt = 0;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init the event queue (except mouse position)
 1.1  jonathan 	*/
 1.1  jonathan 	eq_header[unit]->header.events =
 1.1  jonathan 	    (struct _vs_event *)((int)eq_header[unit] + sizeof(struct qdinput));
 1.1  jonathan
 1.1  jonathan 	eq_header[unit]->header.size = MAXEVENTS;
 1.1  jonathan 	eq_header[unit]->header.head = 0;
 1.1  jonathan 	eq_header[unit]->header.tail = 0;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * open exclusive for graphics device.
 1.1  jonathan 	 */
 1.1  jonathan 	qdopened[unit] = 0;
 1.1  jonathan
 1.1  jonathan } /* qdattach */
 1.1  jonathan
 1.5     ragge
 1.1  jonathan /*ARGSUSED*/
 1.6     ragge int
 1.5     ragge qdopen(dev, flag, mode, p)
 1.1  jonathan 	dev_t dev;
 1.5     ragge 	int flag, mode;
1.13     ragge 	struct proc *p;
 1.1  jonathan {
 1.5     ragge 	volatile register struct dga *dga;	/* ptr to gate array struct */
 1.1  jonathan 	register struct tty *tp;
 1.5     ragge 	volatile struct duart *duart;
 1.1  jonathan 	int unit;
 1.1  jonathan 	int minor_dev;
 1.1  jonathan
 1.1  jonathan 	minor_dev = minor(dev); /* get QDSS minor device number */
 1.1  jonathan 	unit = minor_dev >> 2;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* check for illegal conditions
 1.1  jonathan 	*/
1.13     ragge 	if (unit >= qd_cd.cd_ndevs || qd_cd.cd_devs[unit] == NULL)
1.13     ragge 		return (ENXIO);		/* no such device or address */
 1.1  jonathan
1.13     ragge 	duart = (struct duart *) qdmap[unit].duart;
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan
 1.1  jonathan 	if ((minor_dev & 0x03) == 2) {
 1.1  jonathan 		/*
 1.1  jonathan 		* this is the graphic device...
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdopened[unit] != 0)
 1.1  jonathan 			return(EBUSY);
 1.1  jonathan 		else
 1.1  jonathan 			qdopened[unit] = 1;
 1.1  jonathan 		qdflags[unit].inuse |= GRAPHIC_DEV;  /* graphics dev is open */
 1.1  jonathan 		/*
 1.1  jonathan 		 * enble kbd & mouse intrpts in DUART mask reg
 1.1  jonathan 		 */
 1.1  jonathan 		qdflags[unit].duart_imask |= 0x22;
 1.1  jonathan 		duart->imask = qdflags[unit].duart_imask;
 1.1  jonathan 	} else {
 1.5     ragge 	       /* Only one console */
1.13     ragge 	       if (minor_dev) return ENXIO;
 1.5     ragge
 1.5     ragge 	       /* If not done already, allocate tty structure */
 1.5     ragge 	       if (qd_tty[minor_dev] == NULL)
1.13     ragge 		       qd_tty[minor_dev] = ttymalloc();
1.13     ragge
 1.5     ragge 	       if (qd_tty[minor_dev] == NULL)
1.13     ragge 		       return ENXIO;
 1.5     ragge
 1.5     ragge 	       /*
 1.1  jonathan 		* this is the console
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].inuse |= CONS_DEV;  /* mark console as open */
 1.1  jonathan 		dga->csr |= CURS_ENB;
 1.1  jonathan 		qdflags[unit].duart_imask |= 0x02;
 1.1  jonathan 		duart->imask = qdflags[unit].duart_imask;
 1.1  jonathan 		/*
 1.1  jonathan 		* some setup for tty handling
 1.1  jonathan 		*/
 1.5     ragge 		tp = qd_tty[minor_dev];
 1.5     ragge 		/* tp->t_addr = ui->ui_addr; */
 1.1  jonathan 		tp->t_oproc = qdstart;
1.13     ragge 		tp->t_dev = dev;
 1.1  jonathan 		if ((tp->t_state & TS_ISOPEN) == 0) {
 1.1  jonathan 			ttychars(tp);
 1.1  jonathan 			tp->t_ispeed = B9600;
 1.1  jonathan 			tp->t_ospeed = B9600;
 1.1  jonathan 			tp->t_state = TS_ISOPEN | TS_CARR_ON;
 1.1  jonathan 			tp->t_iflag = TTYDEF_IFLAG;
 1.1  jonathan 			tp->t_oflag = TTYDEF_OFLAG;
 1.1  jonathan 			tp->t_lflag = TTYDEF_LFLAG;
 1.1  jonathan 			tp->t_cflag = TTYDEF_CFLAG;
1.13     ragge 			ttsetwater(tp);
 1.1  jonathan 		}
 1.1  jonathan 		/*
 1.1  jonathan 		* enable intrpts, open line discipline
 1.1  jonathan 		*/
1.13     ragge 		dga->csr |= GLOBAL_IE;	/* turn on the interrupts */
 1.1  jonathan 		return ((*linesw[tp->t_line].l_open)(dev, tp));
 1.1  jonathan 	}
 1.1  jonathan 	dga->csr |= GLOBAL_IE;	/* turn on the interrupts */
 1.1  jonathan 	return(0);
 1.1  jonathan
 1.1  jonathan } /* qdopen */
 1.1  jonathan
 1.1  jonathan /*ARGSUSED*/
 1.6     ragge int
 1.1  jonathan qdclose(dev, flag, mode, p)
 1.1  jonathan 	dev_t dev;
 1.1  jonathan 	int flag, mode;
 1.1  jonathan 	struct proc *p;
 1.1  jonathan {
 1.1  jonathan 	register struct tty *tp;
 1.1  jonathan 	register struct qdmap *qd;
 1.5     ragge 	volatile register int *ptep;
 1.5     ragge 	volatile struct dga *dga;      	/* gate array register map pointer */
 1.5     ragge 	volatile struct duart *duart;
 1.5     ragge 	volatile struct adder *adder;
 1.1  jonathan 	int unit;
 1.1  jonathan 	int minor_dev;
 1.1  jonathan 	u_int mapix;
 1.1  jonathan 	int i;				/* SIGNED index */
1.13     ragge 	struct uba_softc *uh;
 1.5     ragge
 1.1  jonathan 	minor_dev = minor(dev); 	/* get minor device number */
 1.1  jonathan 	unit = minor_dev >> 2;		/* get QDSS number */
 1.1  jonathan 	qd = &qdmap[unit];
 1.1  jonathan
1.13     ragge 	uh = (struct uba_softc *)
1.13     ragge 	     (((struct device *)(qd_cd.cd_devs[unit]))->dv_parent);
 1.5     ragge
 1.5     ragge
 1.1  jonathan 	if ((minor_dev & 0x03) == 2) {
 1.1  jonathan 		/*
 1.1  jonathan 		* this is the graphic device...
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdopened[unit] != 1)
1.13     ragge 			return(EBUSY);
 1.1  jonathan 		else
 1.1  jonathan 			qdopened[unit] = 0;	/* allow it to be re-opened */
 1.1  jonathan 		/*
 1.1  jonathan 		* re-protect device memory
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPDEV) {
 1.1  jonathan 			/*
 1.1  jonathan 			* TEMPLATE RAM
 1.1  jonathan 			*/
 1.1  jonathan 			mapix = VTOP((int)qd->template) - VTOP(qvmem[0]);
 1.1  jonathan 			ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 			for (i = 0; i < vax_btop(TMPSIZE); i++, ptep++)
 1.1  jonathan 				*ptep = (*ptep & ~PG_PROT) | PG_V | PG_KW;
 1.1  jonathan 			/*
 1.1  jonathan 			* ADDER
 1.1  jonathan 			*/
 1.1  jonathan 			mapix = VTOP((int)qd->adder) - VTOP(qvmem[0]);
 1.1  jonathan 			ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 			for (i = 0; i < vax_btop(REGSIZE); i++, ptep++)
 1.1  jonathan 				*ptep = (*ptep & ~PG_PROT) | PG_V | PG_KW;
 1.1  jonathan 			/*
 1.1  jonathan 			* COLOR MAPS
 1.1  jonathan 			*/
 1.1  jonathan 			mapix = VTOP((int)qd->red) - VTOP(qvmem[0]);
 1.1  jonathan 			ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 			for (i = 0; i < vax_btop(CLRSIZE); i++, ptep++)
 1.1  jonathan 				*ptep = (*ptep & ~PG_PROT) | PG_V | PG_KW;
 1.1  jonathan 		}
 1.1  jonathan
 1.1  jonathan 		/*
 1.1  jonathan 		* re-protect DMA buffer and free the map registers
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPDMA) {
1.15     ragge 			panic("Unmapping unmapped buffer");
1.15     ragge #ifdef notyet
1.15     ragge /*
1.15     ragge  * Ragge 990620:
1.15     ragge  * Can't happen because the buffer can't be mapped.
1.15     ragge  */
 1.1  jonathan 			dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 			adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 			dga->csr &= ~DMA_IE;
 1.1  jonathan 			dga->csr &= ~0x0600;	     /* kill DMA */
 1.1  jonathan 			adder->command = CANCEL;
 1.1  jonathan 			/*
 1.1  jonathan 			 * if DMA was running, flush spurious intrpt
 1.1  jonathan 			 */
 1.1  jonathan 			if (dga->bytcnt_lo != 0) {
 1.1  jonathan 				dga->bytcnt_lo = 0;
 1.1  jonathan 				dga->bytcnt_hi = 0;
 1.1  jonathan 				DMA_SETIGNORE(DMAheader[unit]);
 1.1  jonathan 				dga->csr |= DMA_IE;
 1.1  jonathan 				dga->csr &= ~DMA_IE;
 1.1  jonathan 			}
 1.1  jonathan 			ptep = (int *)
 1.5     ragge 			   ((VTOP(DMAheader[unit]*4)) + (mfpr(PR_SBR)|0x80000000));
1.10     ragge 			for (i = 0; i < vax_btop(DMAbuf_size); i++, ptep++)
 1.1  jonathan 				*ptep = (*ptep & ~PG_PROT) | PG_V | PG_KW;
 1.5     ragge 			ubarelse(uh, &Qbus_unmap[unit]);
1.15     ragge #endif
 1.1  jonathan 		}
 1.1  jonathan
 1.1  jonathan 		/*
 1.1  jonathan 		* re-protect 1K (2 pages) event queue
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPEQ) {
 1.1  jonathan 			ptep = (int *)
 1.5     ragge 			   ((VTOP(eq_header[unit])*4) + (mfpr(PR_SBR)|0x80000000));
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V; ptep++;
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V;
 1.1  jonathan 		}
 1.1  jonathan 		/*
 1.1  jonathan 		* re-protect scroll param area and disable scroll intrpts
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPSCR) {
 1.1  jonathan 			ptep = (int *) ((VTOP(scroll[unit]) * 4)
 1.5     ragge 				+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 			/*
 1.1  jonathan 			 * re-protect 512 scroll param area
 1.1  jonathan 			 */
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V;
 1.1  jonathan 			adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 			qdflags[unit].adder_ie &= ~FRAME_SYNC;
 1.1  jonathan 			adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		}
 1.1  jonathan 		/*
 1.1  jonathan 		* re-protect color map write buffer area and kill intrpts
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPCOLOR) {
 1.1  jonathan 			ptep = (int *) ((VTOP(color_buf[unit]) * 4)
 1.5     ragge 				+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V; ptep++;
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V;
 1.1  jonathan 			color_buf[unit]->status = 0;
 1.1  jonathan 			adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 			qdflags[unit].adder_ie &= ~VSYNC;
 1.1  jonathan 			adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		}
 1.5     ragge 		mtpr(0, PR_TBIA);
 1.1  jonathan 		/* flag everything now unmapped */
 1.1  jonathan 		qdflags[unit].mapped = 0;
 1.1  jonathan 		qdflags[unit].inuse &= ~GRAPHIC_DEV;
 1.1  jonathan 		qdflags[unit].curs_acc = ACC_OFF;
 1.1  jonathan 		qdflags[unit].curs_thr = 128;
 1.1  jonathan 		/*
 1.1  jonathan 		* restore the console
 1.1  jonathan 		*/
 1.1  jonathan 		dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 		adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 		dga->csr &= ~DMA_IE;
 1.1  jonathan 		dga->csr &= ~0x0600;	/* halt the DMA! (just in case...) */
 1.1  jonathan 		dga->csr |= DMA_ERR;	/* clear error condition */
 1.1  jonathan 		adder->command = CANCEL;
 1.1  jonathan 		/*
 1.1  jonathan 		 * if DMA was running, flush spurious intrpt
 1.1  jonathan 		 */
 1.1  jonathan 		if (dga->bytcnt_lo != 0) {
 1.1  jonathan 			dga->bytcnt_lo = 0;
 1.1  jonathan 			dga->bytcnt_hi = 0;
 1.1  jonathan 			DMA_SETIGNORE(DMAheader[unit]);
 1.1  jonathan 			dga->csr |= DMA_IE;
 1.1  jonathan 			dga->csr &= ~DMA_IE;
 1.1  jonathan 		}
 1.1  jonathan 		init_shared(unit);		/* init shared memory */
 1.1  jonathan 		setup_dragon(unit);		/* init ADDER/VIPER */
 1.1  jonathan 		ldcursor(unit, cons_cursor);	/* load default cursor map */
 1.1  jonathan 		setup_input(unit);		/* init the DUART */
 1.1  jonathan 		ldfont(unit);
 1.1  jonathan 		cursor[unit].x = 0;
 1.1  jonathan 		cursor[unit].y = 0;
 1.1  jonathan 		/*
 1.1  jonathan 		 * shut off the mouse rcv intrpt and turn on kbd intrpts
 1.1  jonathan 		 */
 1.1  jonathan 		duart = (struct duart *) qdmap[unit].duart;
 1.1  jonathan 		qdflags[unit].duart_imask &= ~(0x20);
 1.1  jonathan 		qdflags[unit].duart_imask |= 0x02;
 1.1  jonathan 		duart->imask = qdflags[unit].duart_imask;
 1.1  jonathan 		/*
 1.1  jonathan 		* shut off interrupts if all is closed
 1.1  jonathan 		*/
 1.1  jonathan 		if (!(qdflags[unit].inuse & CONS_DEV)) {
 1.1  jonathan 			dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 			dga->csr &= ~(GLOBAL_IE | DMA_IE);
 1.1  jonathan 		}
 1.1  jonathan 	} else {
 1.1  jonathan 		/*
 1.1  jonathan 		* this is the console
 1.1  jonathan 		*/
 1.5     ragge 		tp = qd_tty[minor_dev];
 1.1  jonathan 		(*linesw[tp->t_line].l_close)(tp, flag);
 1.1  jonathan 		ttyclose(tp);
 1.1  jonathan 		tp->t_state = 0;
 1.1  jonathan 		qdflags[unit].inuse &= ~CONS_DEV;
 1.1  jonathan 		/*
 1.1  jonathan 		* if graphics device is closed, kill interrupts
 1.1  jonathan 		*/
 1.1  jonathan 		if (!(qdflags[unit].inuse & GRAPHIC_DEV)) {
 1.1  jonathan 			dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 			dga->csr &= ~(GLOBAL_IE | DMA_IE);
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	return(0);
 1.1  jonathan
 1.1  jonathan } /* qdclose */
 1.1  jonathan
 1.6     ragge int
 1.5     ragge qdioctl(dev, cmd, datap, flags, p)
 1.1  jonathan 	dev_t dev;
 1.5     ragge 	u_long cmd;
1.13     ragge 	caddr_t datap;
 1.1  jonathan 	int flags;
1.13     ragge 	struct proc *p;
 1.1  jonathan {
 1.5     ragge 	volatile register int *ptep;	/* page table entry pointer */
 1.1  jonathan 	register int mapix;		/* QVmap[] page table index */
 1.1  jonathan 	register struct _vs_event *event;
 1.1  jonathan 	register struct tty *tp;
 1.9     ragge 	register int i;
 1.1  jonathan 	struct qdmap *qd;		/* pointer to device map struct */
 1.5     ragge 	volatile struct dga *dga;	/* Gate Array reg structure pntr */
 1.5     ragge 	volatile struct duart *duart;	/* DUART reg structure pointer */
 1.5     ragge 	volatile struct adder *adder;	/* ADDER reg structure pointer */
 1.1  jonathan 	struct prgkbd *cmdbuf;
 1.1  jonathan 	struct prg_cursor *curs;
 1.1  jonathan 	struct _vs_cursor *pos;
 1.1  jonathan 	int unit = minor(dev) >> 2;	/* number of caller's QDSS */
 1.1  jonathan 	u_int minor_dev = minor(dev);
 1.1  jonathan 	int error;
 1.1  jonathan 	int s;
 1.1  jonathan 	short *temp;			/* a pointer to template RAM */
1.13     ragge 	struct uba_softc *uh;
 1.5     ragge
1.13     ragge 	uh = (struct uba_softc *)
1.13     ragge 	     (((struct device *)(qd_cd.cd_devs[unit]))->dv_parent);
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* service graphic device ioctl commands
 1.1  jonathan 	*/
 1.1  jonathan 	switch (cmd) {
 1.1  jonathan
 1.1  jonathan 	case QD_GETEVENT:
 1.1  jonathan 		/*
 1.1  jonathan 		* extract the oldest event from the event queue
 1.1  jonathan 		*/
 1.1  jonathan 		if (ISEMPTY(eq_header[unit])) {
 1.1  jonathan 			event = (struct _vs_event *) datap;
 1.1  jonathan 			event->vse_device = VSE_NULL;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 		event = (struct _vs_event *) GETBEGIN(eq_header[unit]);
 1.1  jonathan 		s = spl5();
 1.1  jonathan 		GETEND(eq_header[unit]);
 1.1  jonathan 		splx(s);
 1.1  jonathan 		bcopy((caddr_t)event, datap, sizeof(struct _vs_event));
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_RESET:
 1.1  jonathan 		/*
 1.1  jonathan 		* init the dragon stuff, DUART, and driver variables
 1.1  jonathan 		*/
 1.1  jonathan 		init_shared(unit);		/* init shared memory */
 1.1  jonathan 		setup_dragon(unit);	      /* init the ADDER/VIPER stuff */
 1.1  jonathan 		clear_qd_screen(unit);
 1.1  jonathan 		ldcursor(unit, cons_cursor);	/* load default cursor map */
 1.1  jonathan 		ldfont(unit);			/* load the console font */
 1.1  jonathan 		setup_input(unit);		/* init the DUART */
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_SET:
 1.1  jonathan 		/*
 1.1  jonathan 		* init the DUART and driver variables
 1.1  jonathan 		*/
 1.1  jonathan 		init_shared(unit);
 1.1  jonathan 		setup_input(unit);
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_CLRSCRN:
 1.1  jonathan 		/*
 1.1  jonathan 		* clear the QDSS screen.  (NOTE that this reinits the dragon)
 1.1  jonathan 		*/
 1.1  jonathan #ifdef notdef	/* has caused problems and isn't necessary */
 1.1  jonathan 		setup_dragon(unit);
 1.1  jonathan 		clear_qd_screen(unit);
 1.1  jonathan #endif
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_WTCURSOR:
 1.1  jonathan 		/*
 1.1  jonathan 		* load a cursor into template RAM
 1.1  jonathan 		*/
 1.1  jonathan 		ldcursor(unit, (short *)datap);
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_RDCURSOR:
 1.1  jonathan
 1.1  jonathan 		temp = (short *) qdmap[unit].template;
 1.1  jonathan 		/*
 1.1  jonathan 		 * cursor is 32 WORDS from the end of the 8k WORD...
 1.1  jonathan 		 *  ...template space
 1.1  jonathan 		 */
 1.1  jonathan 		temp += (8 * 1024) - 32;
 1.1  jonathan 		for (i = 0; i < 32; ++i, datap += sizeof(short))
 1.1  jonathan 			*(short *)datap = *temp++;
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_POSCURSOR:
 1.1  jonathan 		/*
 1.1  jonathan 		* position the mouse cursor
 1.1  jonathan 		*/
 1.1  jonathan 		dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 		pos = (struct _vs_cursor *) datap;
 1.1  jonathan 		s = spl5();
 1.1  jonathan 		dga->x_cursor = TRANX(pos->x);
 1.1  jonathan 		dga->y_cursor = TRANY(pos->y);
 1.1  jonathan 		eq_header[unit]->curs_pos.x = pos->x;
 1.1  jonathan 		eq_header[unit]->curs_pos.y = pos->y;
 1.1  jonathan 		splx(s);
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_PRGCURSOR:
 1.1  jonathan 		/*
 1.1  jonathan 		* set the cursor acceleration factor
 1.1  jonathan 		*/
 1.1  jonathan 		curs = (struct prg_cursor *) datap;
 1.1  jonathan 		s = spl5();
 1.1  jonathan 		qdflags[unit].curs_acc = curs->acc_factor;
 1.1  jonathan 		qdflags[unit].curs_thr = curs->threshold;
 1.1  jonathan 		splx(s);
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_MAPDEVICE:
 1.5     ragge 	       /*
 1.1  jonathan 		* enable 'user write' to device pages
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].mapped |= MAPDEV;
 1.1  jonathan 		qd = (struct qdmap *) &qdmap[unit];
 1.1  jonathan 		/*
 1.1  jonathan 		* enable user write to template RAM
 1.1  jonathan 		*/
 1.1  jonathan 		mapix = VTOP((int)qd->template) - VTOP(qvmem[0]);
 1.1  jonathan 		ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 		for (i = 0; i < vax_btop(TMPSIZE); i++, ptep++)
 1.5     ragge 			*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge
 1.5     ragge 	       /*
 1.1  jonathan 		* enable user write to registers
 1.1  jonathan 		*/
 1.1  jonathan 		mapix = VTOP((int)qd->adder) - VTOP(qvmem[0]);
 1.1  jonathan 		ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 		for (i = 0; i < vax_btop(REGSIZE); i++, ptep++)
 1.5     ragge 			*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge
 1.1  jonathan 		/*
 1.1  jonathan 		* enable user write to color maps
 1.1  jonathan 		*/
 1.1  jonathan 		mapix = VTOP((int)qd->red) - VTOP(qvmem[0]);
 1.1  jonathan 		ptep = (int *)(QVmap[0] + mapix);
1.10     ragge 		for (i = 0; i < vax_btop(CLRSIZE); i++, ptep++)
 1.5     ragge 			*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge
1.13     ragge 	       /*
 1.1  jonathan 		* enable user write to DUART
 1.1  jonathan 		*/
 1.1  jonathan 		mapix = VTOP((int)qd->duart) - VTOP(qvmem[0]);
 1.1  jonathan 		ptep = (int *)(QVmap[0] + mapix);
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V; /* duart page */
 1.1  jonathan
 1.5     ragge 		mtpr(0, PR_TBIA);		/* invalidate translation buffer */
 1.1  jonathan
1.13     ragge 		/*
 1.1  jonathan 		 * stuff qdmap structure in return buffer
 1.1  jonathan 		 */
 1.1  jonathan 		bcopy((caddr_t)qd, datap, sizeof(struct qdmap));
 1.5     ragge
1.13     ragge 		break;
 1.1  jonathan
1.15     ragge #ifdef notyet
1.15     ragge /*
1.15     ragge  * Ragge 999620:
1.15     ragge  * Can't map in the graphic buffer into user space for now.
1.15     ragge  * The best way to fix this is to convert this driver to wscons.
1.15     ragge  */
 1.1  jonathan 	case QD_MAPIOBUF:
 1.1  jonathan 		/*
 1.1  jonathan 		 * do setup for DMA by user process
 1.1  jonathan 		 *
 1.1  jonathan 		 * set 'user write enable' bits for DMA buffer
 1.1  jonathan 		 */
 1.1  jonathan 		qdflags[unit].mapped |= MAPDMA;
 1.1  jonathan 		ptep = (int *) ((VTOP(DMAheader[unit]) * 4)
 1.5     ragge 			+ (mfpr(PR_SBR) | 0x80000000));
1.10     ragge 		for (i = 0; i < vax_btop(DMAbuf_size); i++, ptep++)
 1.5     ragge 			*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
1.15     ragge 		mtpr(0, PR_TBIA);	/* invalidate translation buffer */
 1.1  jonathan 		/*
 1.1  jonathan 		* set up QBUS map registers for DMA
 1.1  jonathan 		*/
 1.1  jonathan 		DMAheader[unit]->QBAreg =
 1.5     ragge 		    uballoc(uh, (caddr_t)DMAheader[unit], DMAbuf_size, 0);
 1.1  jonathan 		if (DMAheader[unit]->QBAreg == 0)
 1.4  christos 		    printf("qd%d: qdioctl: QBA setup error\n", unit);
 1.1  jonathan 		Qbus_unmap[unit] = DMAheader[unit]->QBAreg;
 1.1  jonathan 		DMAheader[unit]->QBAreg &= 0x3FFFF;
 1.1  jonathan 		/*
 1.1  jonathan 		* return I/O buf adr
 1.1  jonathan 		*/
 1.1  jonathan 		*(int *)datap = (int) DMAheader[unit];
 1.1  jonathan 		break;
1.15     ragge #endif
 1.1  jonathan
 1.1  jonathan 	case QD_MAPSCROLL:
 1.1  jonathan 		/*
 1.1  jonathan 		* map the shared scroll param area and enable scroll interpts
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].mapped |= MAPSCR;
 1.1  jonathan 		ptep = (int *) ((VTOP(scroll[unit]) * 4)
 1.5     ragge 			+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 		/*
 1.1  jonathan 		 * allow user write to scroll area
 1.1  jonathan 		 */
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge 		mtpr(0, PR_TBIA);			/* invalidate translation buf */
 1.1  jonathan 		scroll[unit]->status = 0;
 1.1  jonathan 		adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 		qdflags[unit].adder_ie |= FRAME_SYNC;
 1.1  jonathan 		adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		*(int *)datap = (int) scroll[unit]; /* return scroll area */
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_UNMAPSCROLL:
 1.1  jonathan 		/*
 1.1  jonathan 		* unmap shared scroll param area and disable scroll intrpts
 1.1  jonathan 		*/
 1.1  jonathan 		if (qdflags[unit].mapped & MAPSCR) {
 1.1  jonathan 			qdflags[unit].mapped &= ~MAPSCR;
 1.1  jonathan 			ptep = (int *) ((VTOP(scroll[unit]) * 4)
 1.5     ragge 				+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 			/*
 1.1  jonathan 			 * re-protect 512 scroll param area
 1.1  jonathan 			 */
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V;
 1.5     ragge 			mtpr(0, PR_TBIA);	/* smash CPU's translation buf */
 1.1  jonathan 			adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 			qdflags[unit].adder_ie &= ~FRAME_SYNC;
 1.1  jonathan 			adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_MAPCOLOR:
 1.1  jonathan 		/*
 1.1  jonathan 		* map shared color map write buf and turn on vsync intrpt
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].mapped |= MAPCOLOR;
 1.1  jonathan 		ptep = (int *) ((VTOP(color_buf[unit]) * 4)
 1.5     ragge 			+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 		/*
 1.1  jonathan 		 * allow user write to color map write buffer
 1.1  jonathan 		 */
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V; ptep++;
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge 		mtpr(0, PR_TBIA);			/* clr CPU translation buf */
 1.1  jonathan 		adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 		qdflags[unit].adder_ie |= VSYNC;
 1.1  jonathan 		adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		/*
 1.1  jonathan 		 * return color area address
 1.1  jonathan 		 */
 1.1  jonathan 		*(int *)datap = (int) color_buf[unit];
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_UNMAPCOLOR:
 1.1  jonathan 		/*
 1.1  jonathan 		 * unmap shared color map write buffer and kill VSYNC intrpts
 1.1  jonathan 		 */
 1.1  jonathan 		if (qdflags[unit].mapped & MAPCOLOR) {
 1.1  jonathan 			qdflags[unit].mapped &= ~MAPCOLOR;
 1.1  jonathan 			ptep = (int *) ((VTOP(color_buf[unit]) * 4)
 1.5     ragge 				+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 			/*
 1.1  jonathan 			 * re-protect color map write buffer
 1.1  jonathan 			 */
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V; ptep++;
 1.1  jonathan 			*ptep = (*ptep & ~PG_PROT) | PG_KW | PG_V;
 1.5     ragge 			mtpr(0, PR_TBIA);
 1.1  jonathan 			adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 			qdflags[unit].adder_ie &= ~VSYNC;
 1.1  jonathan 			adder->interrupt_enable = qdflags[unit].adder_ie;
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_MAPEVENT:
 1.1  jonathan 		/*
 1.1  jonathan 		* give user write access to the event queue
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].mapped |= MAPEQ;
 1.1  jonathan 		ptep = (int *) ((VTOP(eq_header[unit]) * 4)
 1.5     ragge 			+ (mfpr(PR_SBR) | 0x80000000));
 1.1  jonathan 		/*
 1.1  jonathan 		 * allow user write to 1K event queue
 1.1  jonathan 		 */
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V; ptep++;
 1.5     ragge 		*ptep = (*ptep & ~PG_PROT) | PG_RW | PG_V;
 1.5     ragge 		mtpr(0, PR_TBIA);			/* clr CPU translation buf */
 1.1  jonathan 		/*
 1.1  jonathan 		 * return event queue address
 1.1  jonathan 		 */
 1.1  jonathan 		*(int *)datap = (int)eq_header[unit];
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_PRGKBD:
 1.1  jonathan 		/*
 1.1  jonathan 		* pass caller's programming commands to LK201
 1.1  jonathan 		*/
 1.1  jonathan 		duart = (struct duart *)qdmap[unit].duart;
 1.1  jonathan 		cmdbuf = (struct prgkbd *)datap;    /* pnt to kbd cmd buf */
 1.1  jonathan 		/*
 1.1  jonathan 		* send command
 1.1  jonathan 		*/
 1.1  jonathan 		for (i = 1000; i > 0; --i) {
 1.1  jonathan 			if (duart->statusA&XMT_RDY) {
 1.1  jonathan 				duart->dataA = cmdbuf->cmd;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		if (i == 0) {
 1.4  christos 			printf("qd%d: qdioctl: timeout on XMT_RDY [1]\n", unit);
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 		/*
 1.1  jonathan 		* send param1?
 1.1  jonathan 		*/
 1.1  jonathan 		if (cmdbuf->cmd & LAST_PARAM)
 1.1  jonathan 			break;
 1.1  jonathan 		for (i = 1000; i > 0; --i) {
 1.1  jonathan 			if (duart->statusA&XMT_RDY) {
 1.1  jonathan 				duart->dataA = cmdbuf->param1;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		if (i == 0) {
 1.4  christos 			printf("qd%d: qdioctl: timeout on XMT_RDY [2]\n", unit);
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 		/*
 1.1  jonathan 		* send param2?
 1.1  jonathan 		*/
 1.1  jonathan 		if (cmdbuf->param1 & LAST_PARAM)
 1.1  jonathan 		    break;
 1.1  jonathan 		for (i = 1000; i > 0; --i) {
 1.1  jonathan 			if (duart->statusA&XMT_RDY) {
 1.1  jonathan 				duart->dataA = cmdbuf->param2;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		if (i == 0) {
 1.4  christos 			printf("qd%d: qdioctl: timeout on XMT_RDY [3]\n", unit);
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_PRGMOUSE:
 1.1  jonathan 		/*
 1.1  jonathan 		* pass caller's programming commands to the mouse
 1.1  jonathan 		*/
 1.1  jonathan 		duart = (struct duart *) qdmap[unit].duart;
 1.1  jonathan 		for (i = 1000; i > 0; --i) {
 1.1  jonathan 			if (duart->statusB&XMT_RDY) {
 1.1  jonathan 				duart->dataB = *datap;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		if (i == 0) {
 1.4  christos 			printf("qd%d: qdioctl: timeout on XMT_RDY [4]\n", unit);
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_RDCONFIG:
 1.1  jonathan 		/*
 1.1  jonathan 		* get QDSS configuration word and return it
 1.1  jonathan 		*/
 1.1  jonathan 		*(short *)datap = qdflags[unit].config;
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_KERN_LOOP:
 1.1  jonathan 	case QD_KERN_UNLOOP:
 1.1  jonathan 		/*
 1.1  jonathan 		 * vestige from ultrix.  BSD uses TIOCCONS to redirect
 1.1  jonathan 		 * kernel console output.
 1.1  jonathan 		 */
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_PRGTABLET:
 1.1  jonathan 		/*
 1.1  jonathan 		* program the tablet
 1.1  jonathan 		*/
 1.1  jonathan 		duart = (struct duart *) qdmap[unit].duart;
 1.1  jonathan 		for (i = 1000; i > 0; --i) {
 1.1  jonathan 			if (duart->statusB&XMT_RDY) {
 1.1  jonathan 				duart->dataB = *datap;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		if (i == 0) {
 1.4  christos 			printf("qd%d: qdioctl: timeout on XMT_RDY [5]\n", unit);
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case QD_PRGTABRES:
 1.1  jonathan 		/*
 1.1  jonathan 		* program the tablet report resolution factor
 1.1  jonathan 		*/
 1.1  jonathan 		qdflags[unit].tab_res = *(short *)datap;
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	default:
 1.1  jonathan 		/*
 1.1  jonathan 		* service tty ioctl's
 1.1  jonathan 		*/
 1.1  jonathan 		if (!(minor_dev & 0x02)) {
 1.5     ragge 			tp = qd_tty[minor_dev];
 1.1  jonathan 			error =
 1.5     ragge
 1.5     ragge 		   (*linesw[tp->t_line].l_ioctl)(tp, cmd, datap, flags, p);
 1.1  jonathan 			if (error >= 0) {
 1.1  jonathan 				return(error);
 1.1  jonathan 			}
 1.5     ragge 			error = ttioctl(tp, cmd, datap, flags, p);
 1.1  jonathan 			if (error >= 0) {
 1.1  jonathan 				return(error);
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	return(0);
 1.1  jonathan
 1.1  jonathan } /* qdioctl */
 1.1  jonathan
 1.5     ragge
 1.6     ragge int
 1.5     ragge qdpoll(dev, events, p)
1.13     ragge 	dev_t dev;
1.13     ragge 	int events;
1.13     ragge 	struct proc *p;
 1.1  jonathan {
 1.9     ragge 	register int s;
 1.9     ragge 	register int unit;
 1.1  jonathan 	register struct tty *tp;
 1.1  jonathan 	u_int minor_dev = minor(dev);
1.13     ragge 	int revents = 0;
 1.1  jonathan
 1.1  jonathan 	s = spl5();
 1.1  jonathan 	unit = minor_dev >> 2;
 1.1  jonathan
1.13     ragge 	if ((minor_dev & 0x03) == 2)  {
1.13     ragge 		/*
 1.5     ragge 		 * This is a graphics device, so check for events.
 1.5     ragge 		 */
 1.1  jonathan
1.13     ragge 		if (events & (POLLIN | POLLRDNORM))
 1.5     ragge 			if(!(ISEMPTY(eq_header[unit])))
1.13     ragge 				revents |= events & (POLLIN | POLLRDNORM);
 1.5     ragge
1.13     ragge 		if (events & (POLLOUT | POLLWRNORM))
 1.1  jonathan 			if (DMA_ISEMPTY(DMAheader[unit]))
1.13     ragge 				revents |= events & (POLLOUT | POLLWRNORM);
 1.5     ragge
1.13     ragge 		if (revents == 0)  {
1.13     ragge 			if (events & (POLLIN | POLLRDNORM))  {
1.13     ragge 				selrecord(p, &qdrsel[unit]);
1.13     ragge 				qdflags[unit].selmask |= SEL_READ;
 1.5     ragge 			}
 1.5     ragge
1.13     ragge 			if (events & (POLLOUT | POLLWRNORM))  {
1.13     ragge 				selrecord(p, &qdrsel[unit]);
1.13     ragge 				qdflags[unit].selmask |= SEL_WRITE;
 1.5     ragge 			}
1.13     ragge 		}
 1.5     ragge 	} else  {
1.13     ragge 		/*
1.13     ragge 		* this is a tty device
1.13     ragge 		*/
1.13     ragge 		tp = qd_tty[minor_dev];
 1.5     ragge
1.13     ragge 		if (events & (POLLIN | POLLRDNORM))  {
 1.5     ragge 		     /* This is ttnread.  It's static and I don't feel
 1.5     ragge 		      * like altering platform independant parts of NetBSD
 1.5     ragge 		      */
 1.5     ragge 		     int nread;
 1.5     ragge 		     /* if (tp->t_lflag & PENDIN)
1.13     ragge 				     ttypend(tp); */
 1.5     ragge 		     nread = tp->t_canq.c_cc;
 1.5     ragge 		     if (!(tp->t_lflag & ICANON))  {
1.13     ragge 			     nread += tp->t_rawq.c_cc;
1.13     ragge 			     if (nread < tp->t_cc[VMIN] && !tp->t_cc[VTIME])
1.13     ragge 				     nread = 0;
 1.5     ragge 		     }
1.13     ragge 		     if (nread > 0)
1.13     ragge 			     revents |= events & (POLLIN | POLLRDNORM);
1.13     ragge 		}
 1.5     ragge
1.13     ragge 		if (events & (POLLOUT | POLLWRNORM))
1.13     ragge 			if (tp->t_outq.c_cc <= tp->t_lowat)
1.13     ragge 				revents |= events & (POLLOUT | POLLWRNORM);
 1.5     ragge
1.13     ragge 		if (revents == 0)  {
1.13     ragge 			if (events & (POLLIN | POLLRDNORM))
1.13     ragge 				selrecord(p, &tp->t_rsel);
 1.5     ragge
1.13     ragge 			if (events & (POLLOUT | POLLWRNORM))
1.13     ragge 				selrecord(p, &tp->t_wsel);
1.13     ragge 		}
 1.1  jonathan 	}
 1.5     ragge
 1.1  jonathan 	splx(s);
 1.5     ragge 	return (revents);
 1.5     ragge } /* qdpoll() */
 1.1  jonathan
 1.1  jonathan
 1.5     ragge void qd_strategy(struct buf *bp);
 1.1  jonathan
 1.5     ragge /*ARGSUSED*/
 1.6     ragge int
 1.5     ragge qdwrite(dev, uio, flag)
 1.1  jonathan 	dev_t dev;
 1.1  jonathan 	struct uio *uio;
 1.1  jonathan {
 1.1  jonathan 	register struct tty *tp;
 1.9     ragge 	register int minor_dev;
 1.9     ragge 	register int unit;
 1.1  jonathan
 1.1  jonathan 	minor_dev = minor(dev);
 1.1  jonathan 	unit = (minor_dev >> 2) & 0x07;
 1.1  jonathan
 1.1  jonathan 	if (((minor_dev&0x03) != 0x02) && (qdflags[unit].inuse&CONS_DEV)) {
 1.5     ragge 	       /*
 1.1  jonathan 		* this is the console...
 1.1  jonathan 		*/
 1.5     ragge 		tp = qd_tty[minor_dev];
 1.5     ragge 		return ((*linesw[tp->t_line].l_write)(tp, uio, flag));
 1.1  jonathan 	} else if (qdflags[unit].inuse & GRAPHIC_DEV) {
 1.5     ragge 	       /*
 1.1  jonathan 		* this is a DMA xfer from user space
 1.1  jonathan 		*/
 1.1  jonathan 		return (physio(qd_strategy, &qdbuf[unit],
 1.1  jonathan 		dev, B_WRITE, minphys, uio));
 1.1  jonathan 	}
 1.1  jonathan 	return (ENXIO);
 1.1  jonathan }
 1.1  jonathan
 1.5     ragge /*ARGSUSED*/
 1.6     ragge int
 1.5     ragge qdread(dev, uio, flag)
 1.1  jonathan 	dev_t dev;
 1.1  jonathan 	struct uio *uio;
 1.1  jonathan {
 1.1  jonathan 	register struct tty *tp;
 1.9     ragge 	register int minor_dev;
 1.9     ragge 	register int unit;
 1.1  jonathan
 1.1  jonathan 	minor_dev = minor(dev);
 1.1  jonathan 	unit = (minor_dev >> 2) & 0x07;
 1.1  jonathan
 1.1  jonathan 	if ((minor_dev & 0x03) != 0x02 && qdflags[unit].inuse & CONS_DEV) {
1.13     ragge 	       /*
 1.1  jonathan 		* this is the console
 1.1  jonathan 		*/
 1.5     ragge 		tp = qd_tty[minor_dev];
 1.5     ragge 		return ((*linesw[tp->t_line].l_read)(tp, uio, flag));
 1.1  jonathan 	} else if (qdflags[unit].inuse & GRAPHIC_DEV) {
 1.5     ragge 	       /*
 1.1  jonathan 		* this is a bitmap-to-processor xfer
 1.1  jonathan 		*/
 1.1  jonathan 		return (physio(qd_strategy, &qdbuf[unit],
 1.1  jonathan 		dev, B_READ, minphys, uio));
 1.1  jonathan 	}
 1.1  jonathan 	return (ENXIO);
 1.1  jonathan }
 1.1  jonathan
 1.1  jonathan /***************************************************************
 1.1  jonathan *
 1.1  jonathan *	qd_strategy()... strategy routine to do DMA
 1.1  jonathan *
 1.1  jonathan ***************************************************************/
 1.1  jonathan
 1.6     ragge void
 1.6     ragge qd_strategy(bp)
 1.1  jonathan 	register struct buf *bp;
 1.1  jonathan {
 1.5     ragge 	volatile register struct dga *dga;
 1.5     ragge 	volatile register struct adder *adder;
 1.9     ragge 	register int unit;
 1.1  jonathan 	int QBAreg;
 1.1  jonathan 	int s;
 1.1  jonathan 	int cookie;
1.13     ragge 	struct uba_softc *uh;
 1.5     ragge
 1.1  jonathan 	unit = (minor(bp->b_dev) >> 2) & 0x07;
 1.1  jonathan
1.13     ragge 	uh = (struct uba_softc *)
1.13     ragge 	     (((struct device *)(qd_cd.cd_devs[unit]))->dv_parent);
 1.5     ragge
 1.1  jonathan 	/*
 1.1  jonathan 	* init pointers
 1.1  jonathan 	*/
 1.6     ragge 	dga = (struct dga *) qdmap[unit].dga;
1.15     ragge panic("qd_strategy");
1.15     ragge #ifdef notyet
 1.5     ragge 	if ((QBAreg = ubasetup(uh, bp, 0)) == 0) {
 1.4  christos 		printf("qd%d: qd_strategy: QBA setup error\n", unit);
 1.1  jonathan 		goto STRAT_ERR;
 1.1  jonathan 	}
1.15     ragge #endif
 1.1  jonathan 	s = spl5();
 1.1  jonathan 	qdflags[unit].user_dma = -1;
 1.1  jonathan 	dga->csr |= DMA_IE;
 1.1  jonathan 	cookie = QBAreg & 0x3FFFF;
 1.1  jonathan 	dga->adrs_lo = (short) cookie;
 1.1  jonathan 	dga->adrs_hi = (short) (cookie >> 16);
 1.1  jonathan 	dga->bytcnt_lo = (short) bp->b_bcount;
 1.1  jonathan 	dga->bytcnt_hi = (short) (bp->b_bcount >> 16);
 1.5     ragge
 1.1  jonathan 	while (qdflags[unit].user_dma) {
 1.1  jonathan 		sleep((caddr_t)&qdflags[unit].user_dma, QDPRIOR);
 1.1  jonathan 	}
 1.1  jonathan 	splx(s);
1.15     ragge #ifdef notyet
 1.5     ragge 	ubarelse(uh, &QBAreg);
1.15     ragge #endif
 1.1  jonathan 	if (!(dga->csr & DMA_ERR)) {
1.16   thorpej 		biodone(bp);
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
1.15     ragge /* STRAT_ERR: */
1.13     ragge 	adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 	adder->command = CANCEL;	/* cancel adder activity */
 1.1  jonathan 	dga->csr &= ~DMA_IE;
 1.1  jonathan 	dga->csr &= ~0x0600;		/* halt DMA (reset fifo) */
 1.1  jonathan 	dga->csr |= DMA_ERR;		/* clear error condition */
 1.1  jonathan 	bp->b_flags |= B_ERROR; 	/* flag an error to physio() */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * if DMA was running, flush spurious intrpt
 1.1  jonathan 	 */
 1.1  jonathan 	if (dga->bytcnt_lo != 0) {
 1.1  jonathan 		dga->bytcnt_lo = 0;
 1.1  jonathan 		dga->bytcnt_hi = 0;
 1.1  jonathan 		DMA_SETIGNORE(DMAheader[unit]);
 1.1  jonathan 		dga->csr |= DMA_IE;
 1.1  jonathan 	}
1.16   thorpej 	biodone(bp);
 1.5     ragge } /* qd_strategy */
 1.1  jonathan
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  Start output to the console screen
 1.1  jonathan  */
 1.5     ragge void qdstart(tp)
 1.5     ragge 	struct tty *tp;
 1.1  jonathan {
 1.9     ragge 	register int which_unit, unit, c;
 1.1  jonathan 	int s;
 1.1  jonathan
 1.1  jonathan 	unit = minor(tp->t_dev);
 1.1  jonathan 	which_unit = (unit >> 2) & 0x3;
 1.1  jonathan 	unit &= 0x03;
 1.1  jonathan
 1.1  jonathan 	s = spl5();
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* If it's currently active, or delaying, no need to do anything.
 1.1  jonathan 	*/
 1.1  jonathan 	if (tp->t_state & (TS_TIMEOUT|TS_BUSY|TS_TTSTOP))
 1.1  jonathan 		goto out;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* Display chars until the queue is empty.
 1.1  jonathan 	* Drop input from anything but the console
 1.1  jonathan 	* device on the floor.
 1.1  jonathan 	*
 1.1  jonathan 	* XXX - this loop is done at spltty.
 1.1  jonathan 	*
 1.1  jonathan 	*/
 1.1  jonathan 	while (tp->t_outq.c_cc) {
 1.1  jonathan 		c = getc(&tp->t_outq);
 1.1  jonathan 		if (unit == 0)
 1.1  jonathan 			blitc(which_unit, (u_char)c);
 1.1  jonathan 	}
 1.1  jonathan 	/*
 1.1  jonathan 	* If there are sleepers, and output has drained below low
 1.1  jonathan 	* water mark, wake up the sleepers.
 1.1  jonathan 	*/
 1.1  jonathan 	if (tp->t_outq.c_cc <= tp->t_lowat) {
 1.1  jonathan 		if (tp->t_state & TS_ASLEEP){
 1.1  jonathan 			tp->t_state &= ~TS_ASLEEP;
 1.1  jonathan 			wakeup((caddr_t) &tp->t_outq);
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	tp->t_state &= ~TS_BUSY;
 1.1  jonathan
 1.1  jonathan out:
 1.1  jonathan 	splx(s);
 1.1  jonathan
 1.1  jonathan } /* qdstart */
 1.1  jonathan
 1.1  jonathan /*ARGSUSED*/
 1.2   mycroft void
 1.1  jonathan qdstop(tp, flag)
 1.5     ragge 	struct tty *tp;
 1.1  jonathan 	int flag;
 1.1  jonathan {
 1.1  jonathan 	register int s;
 1.1  jonathan
 1.1  jonathan 	s = spl5();	/* block intrpts during state modification */
 1.9     ragge 	if (tp->t_state & TS_BUSY) {
 1.1  jonathan 		if ((tp->t_state & TS_TTSTOP) == 0)
 1.1  jonathan 			tp->t_state |= TS_FLUSH;
 1.1  jonathan 		else
 1.1  jonathan 			tp->t_state &= ~TS_BUSY;
 1.9     ragge 	}
 1.1  jonathan 	splx(s);
 1.1  jonathan }
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  Output a character to the QDSS screen
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan blitc(unit, chr)
 1.5     ragge 	int unit;
 1.5     ragge 	u_char chr;
 1.1  jonathan {
 1.5     ragge 	volatile register struct adder *adder;
 1.5     ragge 	volatile register struct dga *dga;
 1.1  jonathan 	register int i;
 1.1  jonathan 	int nograph = !(qdflags[unit].inuse&GRAPHIC_DEV);
 1.1  jonathan 	static short inescape[NQD];
 1.1  jonathan
 1.1  jonathan 	adder = (struct adder *)qdmap[unit].adder;
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 	/*
 1.1  jonathan 	 * BSD comment: this (&=0177) defeats the extended character
 1.1  jonathan 	 * set code for the glass tty, but if i had the time i would
 1.1  jonathan 	 * spend it ripping out the code completely.  This driver
 1.1  jonathan 	 * is too big for its own good.
 1.1  jonathan 	 */
 1.1  jonathan 	chr &= 0177;
 1.1  jonathan 	/*
 1.1  jonathan 	 * Cursor addressing (so vi will work).
 1.1  jonathan 	 * Decode for "\E=%.%." cursor motion description.
 1.1  jonathan 	 * Corresponds to type "qdcons" in /etc/termcap:
 1.1  jonathan 	 *
 1.1  jonathan 	 *    qd|qdss|qdcons|qdss glass tty (4.4 BSD):\
 1.1  jonathan 	 *      :am:do=^J:le=^H:bs:cm=\E=%.%.:cl=1^Z:co#128:li#57::nd=^L:up=^K:
 1.1  jonathan 	 *
 1.1  jonathan 	 */
 1.1  jonathan 	if (inescape[unit] && nograph) {
 1.1  jonathan 		switch (inescape[unit]++) {
 1.1  jonathan 		case 1:
 1.1  jonathan 			if (chr != '=') {
 1.1  jonathan 				/* abort escape sequence */
 1.1  jonathan 				inescape[unit] = 0;
 1.1  jonathan 				blitc(unit, chr);
 1.1  jonathan 			}
 1.1  jonathan 			return;
 1.1  jonathan 		case 2:
 1.1  jonathan 			/* position row */
 1.1  jonathan 			cursor[unit].y = CHAR_HEIGHT * chr;
 1.1  jonathan 			if (cursor[unit].y > 863 - CHAR_HEIGHT)
 1.1  jonathan 				cursor[unit].y = 863 - CHAR_HEIGHT;
 1.1  jonathan 			dga->y_cursor = TRANY(cursor[unit].y);
 1.1  jonathan 			return;
 1.1  jonathan 		case 3:
 1.1  jonathan 			/* position column */
 1.1  jonathan 			cursor[unit].x = CHAR_WIDTH * chr;
 1.1  jonathan 			if (cursor[unit].x > 1024 - CHAR_WIDTH)
 1.1  jonathan 				cursor[unit].x = 1023 - CHAR_WIDTH;
 1.1  jonathan 			dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 			inescape[unit] = 0;
 1.1  jonathan 			return;
 1.1  jonathan 		default:
 1.1  jonathan 			inescape[unit] = 0;
 1.1  jonathan 			blitc(unit, chr);
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	switch (chr) {
 1.1  jonathan 	case '\r':			/* return char */
 1.1  jonathan 		cursor[unit].x = 0;
 1.1  jonathan 		if (nograph)
 1.1  jonathan 			dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case '\t':			/* tab char */
 1.1  jonathan 		for (i = 8 - ((cursor[unit].x >> 3) & 0x07); i > 0; --i) {
 1.1  jonathan 			blitc(unit, ' ');
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case '\n':			/* line feed char */
 1.1  jonathan 		if ((cursor[unit].y += CHAR_HEIGHT) > (863 - CHAR_HEIGHT)) {
 1.1  jonathan 			if (nograph) {
 1.1  jonathan 				cursor[unit].y -= CHAR_HEIGHT;
 1.1  jonathan 				scroll_up(adder);
 1.1  jonathan 			} else
 1.1  jonathan 				cursor[unit].y = 0;
 1.1  jonathan 		}
 1.1  jonathan 		if (nograph)
 1.1  jonathan 			dga->y_cursor = TRANY(cursor[unit].y);
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case '\b':			/* backspace char */
 1.1  jonathan 		if (cursor[unit].x > 0) {
 1.1  jonathan 			cursor[unit].x -= CHAR_WIDTH;
 1.1  jonathan 			if (nograph)
 1.1  jonathan 				dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan 	case CTRL('k'):		/* cursor up */
 1.1  jonathan 		if (nograph && cursor[unit].y > 0) {
 1.1  jonathan 			cursor[unit].y -= CHAR_HEIGHT;
 1.1  jonathan 			dga->y_cursor = TRANY(cursor[unit].y);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case CTRL('^'):		/* home cursor */
 1.1  jonathan 		if (nograph) {
 1.1  jonathan 			cursor[unit].x = 0;
 1.1  jonathan 			dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 			cursor[unit].y = 0;
 1.1  jonathan 			dga->y_cursor = TRANY(cursor[unit].y);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case CTRL('l'):		/* cursor right */
 1.1  jonathan 		if (nograph && cursor[unit].x < 1023 - CHAR_WIDTH) {
 1.1  jonathan 			cursor[unit].x += CHAR_WIDTH;
 1.1  jonathan 			dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case CTRL('z'):		/* clear screen */
 1.1  jonathan 		if (nograph) {
 1.1  jonathan 			setup_dragon(unit);
 1.1  jonathan 			clear_qd_screen(unit);
 1.1  jonathan 			/* home cursor - termcap seems to assume this */
 1.1  jonathan 			cursor[unit].x = 0;
 1.1  jonathan 			dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 			cursor[unit].y = 0;
 1.1  jonathan 			dga->y_cursor = TRANY(cursor[unit].y);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	case '\033':		/* start escape sequence */
 1.1  jonathan 		if (nograph)
 1.1  jonathan 			inescape[unit] = 1;
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	default:
 1.1  jonathan 		if ((chr < ' ') || (chr > '~'))
 1.1  jonathan 			return;
 1.1  jonathan 	}
 1.1  jonathan 	/*
 1.1  jonathan 	 * setup VIPER operand control registers
 1.1  jonathan 	 */
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0001);  /* select plane #0 */
 1.1  jonathan 	write_ID(adder, SRC1_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_SOURCE | ID | BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x00FE);  /* select other planes */
 1.1  jonathan 	write_ID(adder, SRC1_OCR_B,
 1.1  jonathan 	EXT_SOURCE | INT_NONE | NO_ID | BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x00FF);  /* select all planes */
 1.1  jonathan 	write_ID(adder, DST_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_NONE | NO_ID | NO_BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, MASK_1, 0xFFFF);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | FOREGROUND_COLOR_Z, 1);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | BACKGROUND_COLOR_Z, 0);
 1.1  jonathan 	adder->x_clip_min = 0;
 1.1  jonathan 	adder->x_clip_max = 1024;
 1.1  jonathan 	adder->y_clip_min = 0;
 1.1  jonathan 	adder->y_clip_max = 864;
 1.1  jonathan 	/*
 1.1  jonathan 	 * load DESTINATION origin and vectors
 1.1  jonathan 	 */
 1.1  jonathan 	adder->fast_dest_dy = 0;
 1.1  jonathan 	adder->slow_dest_dx = 0;
 1.1  jonathan 	adder->error_1 = 0;
 1.1  jonathan 	adder->error_2 = 0;
 1.1  jonathan 	adder->rasterop_mode = DST_WRITE_ENABLE | NORMAL;
 1.1  jonathan 	(void)wait_status(adder, RASTEROP_COMPLETE);
 1.1  jonathan 	adder->destination_x = cursor[unit].x;
 1.1  jonathan 	adder->fast_dest_dx = CHAR_WIDTH;
 1.1  jonathan 	adder->destination_y = cursor[unit].y;
 1.1  jonathan 	adder->slow_dest_dy = CHAR_HEIGHT;
 1.1  jonathan 	/*
 1.1  jonathan 	 * load SOURCE origin and vectors
 1.1  jonathan 	 */
 1.1  jonathan 	if ((chr - ' ') > (CHARS - 1))  {
 1.4  christos 		printf("Invalid character (x)%x in blitc\n",chr);
 1.1  jonathan 		chr = ' ';
 1.1  jonathan 	}
 1.1  jonathan 	/*
 1.1  jonathan 	 * X position is modulo the number of characters per line
 1.1  jonathan 	 */
 1.1  jonathan 	adder->source_1_x = FONT_X +
 1.1  jonathan 	    (((chr - ' ') % (MAX_SCREEN_X/CHAR_WIDTH)) * CHAR_WIDTH);
 1.1  jonathan 	/*
 1.1  jonathan 	 * Point to either first or second row
 1.1  jonathan 	 */
 1.1  jonathan 	adder->source_1_y = 2048 - 15 *
 1.1  jonathan 	    (((chr - ' ')/(MAX_SCREEN_X/CHAR_WIDTH)) + 1);
 1.1  jonathan 	adder->source_1_dx = CHAR_WIDTH;
 1.1  jonathan 	adder->source_1_dy = CHAR_HEIGHT;
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R1, FULL_SRC_RESOLUTION | LF_SOURCE);
 1.1  jonathan 	adder->cmd = RASTEROP | OCRB | 0 | S1E | DTE;
 1.1  jonathan 	/*
 1.1  jonathan 	 * update console cursor coordinates
 1.1  jonathan 	 */
 1.1  jonathan 	cursor[unit].x += CHAR_WIDTH;
 1.1  jonathan 	if (nograph)
 1.1  jonathan 		dga->x_cursor = TRANX(cursor[unit].x);
 1.1  jonathan 	if (cursor[unit].x > (1024 - CHAR_WIDTH)) {
 1.1  jonathan 		blitc(unit, '\r');
 1.1  jonathan 		blitc(unit, '\n');
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan } /* blitc */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  INTERRUPT SERVICE ROUTINES
 1.1  jonathan  */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  Service "DMA DONE" interrupt condition
 1.1  jonathan  */
 1.5     ragge
 1.5     ragge static void
 1.1  jonathan qddint(qd)
 1.5     ragge 	int qd;
 1.1  jonathan {
 1.1  jonathan 	register struct DMAreq_header *header;
 1.1  jonathan 	register struct DMAreq *request;
 1.5     ragge 	volatile register struct dga *dga;
 1.5     ragge 	volatile struct adder *adder;
 1.1  jonathan 	int cookie;			/* DMA adrs for QDSS */
 1.1  jonathan
 1.1  jonathan 	(void)spl4(); 			/* allow interval timer in */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init pointers
 1.1  jonathan 	*/
 1.1  jonathan 	header = DMAheader[qd]; 	    /* register for optimization */
 1.1  jonathan 	dga = (struct dga *) qdmap[qd].dga;
 1.1  jonathan 	adder = (struct adder *) qdmap[qd].adder;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if this interrupt flagged as bogus for interrupt flushing purposes..
 1.1  jonathan 	*/
 1.1  jonathan 	if (DMA_ISIGNORE(header)) {
 1.5     ragge 	   DMA_CLRIGNORE(header);
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* dump a DMA hardware error message if appropriate
 1.1  jonathan 	*/
 1.1  jonathan 	if (dga->csr & DMA_ERR) {
 1.1  jonathan
 1.1  jonathan 		if (dga->csr & PARITY_ERR)
 1.4  christos 		    printf("qd%d: qddint: DMA hardware parity fault.\n", qd);
 1.1  jonathan
 1.1  jonathan 		if (dga->csr & BUS_ERR)
 1.4  christos 		    printf("qd%d: qddint: DMA hardware bus error.\n", qd);
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if this was a DMA from user space...
 1.1  jonathan 	*/
 1.1  jonathan 	if (qdflags[qd].user_dma) {
1.13     ragge 		qdflags[qd].user_dma = 0;
 1.1  jonathan 		wakeup((caddr_t)&qdflags[qd].user_dma);
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if we're doing DMA request queue services, field the error condition
 1.1  jonathan 	*/
 1.1  jonathan 	if (dga->csr & DMA_ERR) {
 1.1  jonathan
 1.1  jonathan 		dga->csr &= ~0x0600;		/* halt DMA (reset fifo) */
 1.1  jonathan 		dga->csr |= DMA_ERR;		/* clear error condition */
 1.1  jonathan 		adder->command = CANCEL;	/* cancel adder activity */
 1.1  jonathan
 1.1  jonathan 		DMA_SETERROR(header);	/* flag error in header status word */
 1.1  jonathan 		DMA_CLRACTIVE(header);
 1.1  jonathan 		header->DMAreq[header->oldest].DMAdone |= HARD_ERROR;
 1.1  jonathan 		header->newest = header->oldest;
 1.1  jonathan 		header->used = 0;
 1.1  jonathan
1.13     ragge 		if (qdrsel[qd].si_pid && qdflags[qd].selmask & SEL_WRITE) {
 1.5     ragge 			selwakeup(&qdrsel[qd]);
 1.5     ragge 			qdrsel[qd].si_pid = 0;
 1.1  jonathan 			qdflags[qd].selmask &= ~SEL_WRITE;
 1.1  jonathan 		}
 1.1  jonathan
 1.1  jonathan 		if (dga->bytcnt_lo != 0) {
 1.1  jonathan 			dga->bytcnt_lo = 0;
 1.1  jonathan 			dga->bytcnt_hi = 0;
 1.1  jonathan 			DMA_SETIGNORE(header);
 1.1  jonathan 		}
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if the DMA request queue is now becoming non-full,
 1.1  jonathan 	* wakeup "select" client.
 1.1  jonathan 	*/
 1.1  jonathan 	if (DMA_ISFULL(header)) {
1.13     ragge 		if (qdrsel[qd].si_pid && qdflags[qd].selmask & SEL_WRITE) {
 1.5     ragge 			selwakeup(&qdrsel[qd]);
 1.5     ragge 			qdrsel[qd].si_pid = 0;
 1.1  jonathan 			qdflags[qd].selmask &= ~SEL_WRITE;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	header->DMAreq[header->oldest].DMAdone |= REQUEST_DONE;
 1.1  jonathan 	QDlast_DMAtype = header->DMAreq[header->oldest].DMAtype;
 1.1  jonathan
 1.1  jonathan 	/* check for unexpected interrupt */
 1.1  jonathan 	if (DMA_ISEMPTY(header))
 1.1  jonathan 	    return;
 1.1  jonathan
 1.1  jonathan 	DMA_GETEND(header);	/* update request queue indices */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if no more DMA pending, wake up "select" client and exit
 1.1  jonathan 	*/
 1.1  jonathan 	if (DMA_ISEMPTY(header)) {
 1.5     ragge 		if (qdrsel[qd].si_pid && qdflags[qd].selmask & SEL_WRITE) {
 1.5     ragge 			selwakeup(&qdrsel[qd]);
 1.5     ragge 			qdrsel[qd].si_pid = 0;
 1.1  jonathan 			qdflags[qd].selmask &= ~SEL_WRITE;
 1.1  jonathan 		}
 1.1  jonathan 		DMA_CLRACTIVE(header);  /* flag DMA done */
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* initiate next DMA xfer
 1.1  jonathan 	*/
 1.1  jonathan 	request = DMA_GETBEGIN(header);
 1.1  jonathan 	if (request->DMAtype != QDlast_DMAtype) {
 1.1  jonathan 		dga->csr &= ~0x0600;	  /* halt DMA (reset fifo) */
 1.1  jonathan 		adder->command = CANCEL;  /* cancel adder activity */
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan
 1.1  jonathan 	switch (request->DMAtype) {
 1.1  jonathan
 1.1  jonathan 	case DISPLIST:
 1.1  jonathan 		if (request->DMAtype != QDlast_DMAtype) {
 1.1  jonathan 			dga->csr |= DL_ENB;
 1.1  jonathan 			dga->csr &= ~(BTOP_ENB | BYTE_DMA);
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case PTOB:
 1.1  jonathan 		if (request->DMAtype != QDlast_DMAtype) {
 1.1  jonathan 			if (request->DMAdone & BYTE_PACK)
 1.1  jonathan 			    dga->csr |= (PTOB_ENB | BYTE_DMA);
 1.1  jonathan 			else {
 1.1  jonathan 				dga->csr |= PTOB_ENB;
 1.1  jonathan 				dga->csr &= ~BYTE_DMA;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 	case BTOP:
 1.1  jonathan 		if (request->DMAtype != QDlast_DMAtype) {
 1.1  jonathan 			if (request->DMAdone & BYTE_PACK) {
 1.1  jonathan 				dga->csr &= ~DL_ENB;
 1.1  jonathan 				dga->csr |= (BTOP_ENB | BYTE_DMA);
 1.1  jonathan 			}
 1.1  jonathan 			else {
 1.1  jonathan 				dga->csr |= BTOP_ENB;
 1.1  jonathan 				dga->csr &= ~(BYTE_DMA | DL_ENB);
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 		break;
 1.1  jonathan 	default:
 1.4  christos 		printf("qd%d: qddint: illegal DMAtype parameter.\n", qd);
 1.1  jonathan 		DMA_CLRACTIVE(header);	/* flag DMA done */
 1.1  jonathan 		return;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (request->DMAdone & COUNT_ZERO) {
 1.1  jonathan 		dga->csr &= ~SET_DONE_FIFO;
 1.1  jonathan 	}
 1.1  jonathan 	else if (request->DMAdone & FIFO_EMPTY) {
 1.1  jonathan 		dga->csr |= SET_DONE_FIFO;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (request->DMAdone & WORD_PACK)
 1.1  jonathan 	    dga->csr &= ~BYTE_DMA;
 1.1  jonathan 	else if (request->DMAdone & BYTE_PACK)
 1.1  jonathan 	    dga->csr |= BYTE_DMA;
 1.1  jonathan
 1.1  jonathan 	dga->csr |= DMA_IE;
 1.1  jonathan 	QDlast_DMAtype = request->DMAtype;
 1.1  jonathan
 1.1  jonathan 	cookie = ((int)request->bufp - (int)header) + (int)header->QBAreg;
 1.1  jonathan
 1.1  jonathan 	dga->adrs_lo = (short) cookie;
 1.1  jonathan 	dga->adrs_hi = (short) (cookie >> 16);
 1.1  jonathan
 1.1  jonathan 	dga->bytcnt_lo = (short) request->length;
 1.1  jonathan 	dga->bytcnt_hi = (short) (request->length >> 16);
 1.1  jonathan
 1.1  jonathan 	return;
 1.1  jonathan }
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * ADDER interrupt service routine
 1.1  jonathan  */
 1.5     ragge static void
 1.1  jonathan qdaint(qd)
 1.5     ragge 	int qd;
 1.1  jonathan {
 1.5     ragge 	volatile register struct adder *adder;
 1.1  jonathan 	struct color_buf *cbuf;
 1.1  jonathan 	int i;
 1.1  jonathan 	register struct rgb *rgbp;
 1.5     ragge 	volatile register short *red;
 1.5     ragge 	volatile register short *green;
 1.5     ragge 	volatile register short *blue;
 1.1  jonathan
 1.1  jonathan 	(void)spl4(); 			/* allow interval timer in */
 1.1  jonathan
 1.1  jonathan 	adder = (struct adder *) qdmap[qd].adder;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* service the vertical blank interrupt (VSYNC bit) by loading
 1.1  jonathan 	* any pending color map load request
 1.1  jonathan 	*/
 1.1  jonathan 	if (adder->status & VSYNC) {
 1.1  jonathan 		adder->status &= ~VSYNC;	/* clear the interrupt */
 1.1  jonathan 		cbuf = color_buf[qd];
 1.1  jonathan 		if (cbuf->status & LOAD_COLOR_MAP) {
 1.1  jonathan
 1.1  jonathan 			red = (short *) qdmap[qd].red;
 1.1  jonathan 			green = (short *) qdmap[qd].green;
 1.1  jonathan 			blue = (short *) qdmap[qd].blue;
 1.1  jonathan
 1.1  jonathan 			for (i = cbuf->count, rgbp = cbuf->rgb;
 1.1  jonathan 			     --i >= 0; rgbp++) {
 1.1  jonathan 				red[rgbp->offset] = (short) rgbp->red;
 1.1  jonathan 				green[rgbp->offset] = (short) rgbp->green;
 1.1  jonathan 				blue[rgbp->offset] = (short) rgbp->blue;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			cbuf->status &= ~LOAD_COLOR_MAP;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* service the scroll interrupt (FRAME_SYNC bit)
 1.1  jonathan 	*/
 1.1  jonathan 	if (adder->status & FRAME_SYNC) {
 1.1  jonathan 		adder->status &= ~FRAME_SYNC;	/* clear the interrupt */
 1.1  jonathan
 1.1  jonathan 		if (scroll[qd]->status & LOAD_REGS) {
 1.1  jonathan
 1.1  jonathan 			for (i = 1000, adder->status = 0; i > 0 &&
 1.1  jonathan 			     !(adder->status&ID_SCROLL_READY); --i)
 1.1  jonathan 			      ;
 1.1  jonathan
 1.1  jonathan 			if (i == 0) {
 1.4  christos 			    printf("qd%d: qdaint: timeout on ID_SCROLL_READY\n",
 1.1  jonathan 				qd);
 1.1  jonathan 				return;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			adder->ID_scroll_data = scroll[qd]->viper_constant;
 1.1  jonathan 			adder->ID_scroll_command = ID_LOAD | SCROLL_CONSTANT;
 1.1  jonathan
 1.1  jonathan 			adder->y_scroll_constant =
 1.1  jonathan 				scroll[qd]->y_scroll_constant;
 1.1  jonathan 			adder->y_offset_pending = scroll[qd]->y_offset;
 1.1  jonathan
 1.1  jonathan 			if (scroll[qd]->status & LOAD_INDEX) {
 1.1  jonathan
 1.1  jonathan 				adder->x_index_pending =
 1.1  jonathan 					scroll[qd]->x_index_pending;
 1.1  jonathan 				adder->y_index_pending =
 1.1  jonathan 					scroll[qd]->y_index_pending;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			scroll[qd]->status = 0x00;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan }
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  DUART input interrupt service routine
 1.1  jonathan  *
 1.1  jonathan  *  XXX - this routine should be broken out - it is essentially
 1.1  jonathan  *	      straight line code.
 1.1  jonathan  */
 1.1  jonathan
 1.5     ragge static void
 1.1  jonathan qdiint(qd)
 1.5     ragge 	int qd;
 1.1  jonathan {
 1.1  jonathan 	register struct _vs_event *event;
 1.1  jonathan 	register struct qdinput *eqh;
 1.5     ragge 	volatile struct dga *dga;
 1.5     ragge 	volatile struct duart *duart;
 1.1  jonathan 	struct mouse_report *new_rep;
 1.1  jonathan 	struct tty *tp;
 1.1  jonathan 	u_short chr;
 1.1  jonathan 	u_short status;
 1.1  jonathan 	u_short data;
 1.1  jonathan 	u_short key;
 1.1  jonathan 	char do_wakeup = 0;		/* flag to do a select wakeup call */
 1.1  jonathan 	char a, b, c;			/* mouse button test variables */
 1.1  jonathan
 1.1  jonathan 	(void)spl4(); 			/* allow interval timer in */
 1.1  jonathan
 1.1  jonathan 	eqh = eq_header[qd];		/* optimized as a register */
 1.1  jonathan 	new_rep = &current_rep[qd];
 1.1  jonathan 	duart = (struct duart *) qdmap[qd].duart;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* if the graphic device is turned on..
 1.1  jonathan 	*/
 1.1  jonathan 	if (qdflags[qd].inuse & GRAPHIC_DEV) {
 1.1  jonathan 		/*
 1.1  jonathan 		* empty DUART
 1.1  jonathan 		*/
 1.1  jonathan 		while (duart->statusA&RCV_RDY || duart->statusB&RCV_RDY) {
 1.1  jonathan 			/*
 1.1  jonathan 			 * pick up LK-201 input (if any)
 1.1  jonathan 			 */
 1.1  jonathan 			if (duart->statusA&RCV_RDY) {
 1.1  jonathan
 1.1  jonathan 				/* if error condition, then reset it */
 1.1  jonathan
 1.1  jonathan 				if (duart->statusA&0x70) {
 1.1  jonathan 					duart->cmdA = 0x40;
 1.1  jonathan 					continue;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/* event queue full now? (overflow condition) */
 1.1  jonathan
 1.1  jonathan 				if (ISFULL(eqh) == TRUE) {
 1.4  christos 					printf(
 1.1  jonathan 					 "qd%d: qdiint: event queue overflow\n",
 1.1  jonathan 					   qd);
 1.1  jonathan 					break;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* Check for various keyboard errors  */
 1.1  jonathan
 1.1  jonathan 				key = duart->dataA & 0xFF;
 1.1  jonathan
 1.1  jonathan 				if (key==LK_POWER_ERROR ||
 1.1  jonathan 				    key==LK_KDOWN_ERROR ||
 1.1  jonathan 				    key == LK_INPUT_ERROR ||
 1.1  jonathan 				    key == LK_OUTPUT_ERROR) {
 1.4  christos 					printf(
 1.1  jonathan 				    "qd%d: qdiint: keyboard error, code = %x\n",
 1.1  jonathan 					qd,key);
 1.1  jonathan 					return;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				if (key < LK_LOWEST)
 1.1  jonathan 				    return;
 1.1  jonathan
 1.1  jonathan 				++do_wakeup;  /* request a select wakeup call */
 1.1  jonathan
 1.1  jonathan 				event = PUTBEGIN(eqh);
 1.1  jonathan 				PUTEND(eqh);
 1.1  jonathan
 1.1  jonathan 				event->vse_key = key;
 1.1  jonathan 				event->vse_key &= 0x00FF;
 1.1  jonathan 				event->vse_x = eqh->curs_pos.x;
 1.1  jonathan 				event->vse_y = eqh->curs_pos.y;
 1.1  jonathan 				event->vse_time = TOY;
 1.1  jonathan 				event->vse_type = VSE_BUTTON;
 1.1  jonathan 				event->vse_direction = VSE_KBTRAW;
 1.1  jonathan 				event->vse_device = VSE_DKB;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* pick up the mouse input (if any)  */
 1.1  jonathan
 1.1  jonathan 			if ((status = duart->statusB) & RCV_RDY  &&
 1.1  jonathan 			    qdflags[qd].pntr_id == MOUSE_ID) {
 1.1  jonathan
 1.1  jonathan 				if (status & 0x70) {
 1.1  jonathan 					duart->cmdB = 0x40;
 1.1  jonathan 					continue;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/* event queue full now? (overflow condition) */
 1.1  jonathan
 1.1  jonathan 				if (ISFULL(eqh) == TRUE) {
 1.4  christos 					printf(
 1.1  jonathan 					"qd%d: qdiint: event queue overflow\n",
 1.1  jonathan 					     qd);
 1.1  jonathan 					break;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				data = duart->dataB;      /* get report byte */
 1.1  jonathan 				++new_rep->bytcnt; /* bump report byte count */
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 1st byte of report.. */
 1.1  jonathan
 1.1  jonathan 				if ( data & START_FRAME) {
 1.1  jonathan 					new_rep->state = data;
 1.1  jonathan 					if (new_rep->bytcnt > 1) {
 1.1  jonathan 						/* start of new frame */
 1.1  jonathan 						new_rep->bytcnt = 1;
 1.1  jonathan 						/* ..continue looking */
 1.1  jonathan 						continue;
 1.1  jonathan 					}
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 2nd byte of report.. */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 2) {
 1.1  jonathan 					new_rep->dx = data & 0x00FF;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 3rd byte of report, load input event queue */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 3) {
 1.1  jonathan
 1.1  jonathan 					new_rep->dy = data & 0x00FF;
 1.1  jonathan 					new_rep->bytcnt = 0;
 1.1  jonathan
 1.1  jonathan 					/*
 1.1  jonathan 					* if mouse position has changed.. */
 1.1  jonathan
 1.1  jonathan 					if (new_rep->dx != 0  ||  new_rep->dy != 0) {
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* calculate acceleration factor, if needed	*/
 1.1  jonathan
 1.1  jonathan 						if (qdflags[qd].curs_acc > ACC_OFF) {
 1.1  jonathan
 1.1  jonathan 							if (qdflags[qd].curs_thr <= new_rep->dx)
 1.1  jonathan 							    new_rep->dx +=
 1.1  jonathan 							    (new_rep->dx - qdflags[qd].curs_thr)
 1.1  jonathan 							    * qdflags[qd].curs_acc;
 1.1  jonathan
 1.1  jonathan 							if (qdflags[qd].curs_thr <= new_rep->dy)
 1.1  jonathan 							    new_rep->dy +=
 1.1  jonathan 							    (new_rep->dy - qdflags[qd].curs_thr)
 1.1  jonathan 							    * qdflags[qd].curs_acc;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* update cursor position coordinates */
 1.1  jonathan
 1.1  jonathan 						if (new_rep->state & X_SIGN) {
 1.1  jonathan 							eqh->curs_pos.x += new_rep->dx;
 1.1  jonathan 							if (eqh->curs_pos.x > 1023)
 1.1  jonathan 							    eqh->curs_pos.x = 1023;
 1.1  jonathan 						}
 1.1  jonathan 						else {
 1.1  jonathan 							eqh->curs_pos.x -= new_rep->dx;
 1.1  jonathan 							if (eqh->curs_pos.x < -15)
 1.1  jonathan 							    eqh->curs_pos.x = -15;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						if (new_rep->state & Y_SIGN) {
 1.1  jonathan 							eqh->curs_pos.y -= new_rep->dy;
 1.1  jonathan 							if (eqh->curs_pos.y < -15)
 1.1  jonathan 							    eqh->curs_pos.y = -15;
 1.1  jonathan 						}
 1.1  jonathan 						else {
 1.1  jonathan 							eqh->curs_pos.y += new_rep->dy;
 1.1  jonathan 							if (eqh->curs_pos.y > 863)
 1.1  jonathan 							    eqh->curs_pos.y = 863;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* update cursor screen position */
 1.1  jonathan
 1.1  jonathan 						dga = (struct dga *) qdmap[qd].dga;
 1.1  jonathan 						dga->x_cursor = TRANX(eqh->curs_pos.x);
 1.1  jonathan 						dga->y_cursor = TRANY(eqh->curs_pos.y);
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* if cursor is in the box, no event report */
 1.1  jonathan
 1.1  jonathan 						if (eqh->curs_pos.x <= eqh->curs_box.right	&&
 1.1  jonathan 						    eqh->curs_pos.x >= eqh->curs_box.left  &&
 1.1  jonathan 						    eqh->curs_pos.y >= eqh->curs_box.top  &&
 1.1  jonathan 						    eqh->curs_pos.y <= eqh->curs_box.bottom ) {
 1.1  jonathan 							goto GET_MBUTTON;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* report the mouse motion event */
 1.1  jonathan
 1.1  jonathan 						event = PUTBEGIN(eqh);
 1.1  jonathan 						PUTEND(eqh);
 1.1  jonathan
 1.1  jonathan 						++do_wakeup;   /* request a select wakeup call */
 1.1  jonathan
 1.1  jonathan 						event->vse_x = eqh->curs_pos.x;
 1.1  jonathan 						event->vse_y = eqh->curs_pos.y;
 1.1  jonathan
 1.1  jonathan 						event->vse_device = VSE_MOUSE;  /* mouse */
 1.1  jonathan 						event->vse_type = VSE_MMOTION;  /* pos changed */
 1.1  jonathan 						event->vse_key = 0;
 1.1  jonathan 						event->vse_direction = 0;
 1.1  jonathan 						event->vse_time = TOY;	/* time stamp */
 1.1  jonathan 					}
 1.1  jonathan
 1.1  jonathan GET_MBUTTON:
 1.1  jonathan 					/*
 1.1  jonathan 					* if button state has changed */
 1.1  jonathan
 1.1  jonathan 					a = new_rep->state & 0x07;    /*mask nonbutton bits */
 1.1  jonathan 					b = last_rep[qd].state & 0x07;
 1.1  jonathan
 1.1  jonathan 					if (a ^ b) {
 1.1  jonathan
 1.1  jonathan 						for ( c = 1;  c < 8; c <<= 1) {
 1.1  jonathan
 1.1  jonathan 							if (!( c & (a ^ b))) /* this button change? */
 1.1  jonathan 							    continue;
 1.1  jonathan
 1.1  jonathan 							/* event queue full? (overflow condition) */
 1.1  jonathan
 1.1  jonathan 							if (ISFULL(eqh) == TRUE) {
 1.4  christos 								printf("qd%d: qdiint: event queue overflow\n", qd);
 1.1  jonathan 								break;
 1.1  jonathan 							}
 1.1  jonathan
 1.1  jonathan 							event = PUTBEGIN(eqh);	/* get new event */
 1.1  jonathan 							PUTEND(eqh);
 1.1  jonathan
 1.1  jonathan 							++do_wakeup;   /* request select wakeup */
 1.1  jonathan
 1.1  jonathan 							event->vse_x = eqh->curs_pos.x;
 1.1  jonathan 							event->vse_y = eqh->curs_pos.y;
 1.1  jonathan
 1.1  jonathan 							event->vse_device = VSE_MOUSE;	/* mouse */
 1.1  jonathan 							event->vse_type = VSE_BUTTON; /* new button */
 1.1  jonathan 							event->vse_time = TOY;	      /* time stamp */
 1.1  jonathan
 1.1  jonathan 							/* flag changed button and if up or down */
 1.1  jonathan
 1.1  jonathan 							if (c == RIGHT_BUTTON)
 1.1  jonathan 							    event->vse_key = VSE_RIGHT_BUTTON;
 1.1  jonathan 							else if (c == MIDDLE_BUTTON)
 1.1  jonathan 							    event->vse_key = VSE_MIDDLE_BUTTON;
 1.1  jonathan 							else if (c == LEFT_BUTTON)
 1.1  jonathan 							    event->vse_key = VSE_LEFT_BUTTON;
 1.1  jonathan
 1.1  jonathan 							/* set bit = button depressed */
 1.1  jonathan
 1.1  jonathan 							if (c & a)
 1.1  jonathan 							    event->vse_direction = VSE_KBTDOWN;
 1.1  jonathan 							else
 1.1  jonathan 								event->vse_direction = VSE_KBTUP;
 1.1  jonathan 						}
 1.1  jonathan 					}
 1.1  jonathan
 1.1  jonathan 					/* refresh last report */
 1.1  jonathan
 1.1  jonathan 					last_rep[qd] = current_rep[qd];
 1.1  jonathan
 1.1  jonathan 				}  /* get last byte of report */
 1.1  jonathan 			} else if ((status = duart->statusB)&RCV_RDY &&
1.13     ragge 				   qdflags[qd].pntr_id == TABLET_ID) {
 1.1  jonathan 				/*
 1.1  jonathan 				* pickup tablet input, if any
 1.1  jonathan 				*/
 1.1  jonathan 				if (status&0x70) {
 1.1  jonathan 					duart->cmdB = 0x40;
 1.1  jonathan 					continue;
 1.1  jonathan 				}
 1.1  jonathan 				/*
 1.1  jonathan 				 * event queue full now? (overflow condition)
 1.1  jonathan 				 */
 1.1  jonathan 				if (ISFULL(eqh) == TRUE) {
 1.4  christos 					printf("qd%d: qdiint: event queue overflow\n", qd);
 1.1  jonathan 					break;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				data = duart->dataB;      /* get report byte */
 1.1  jonathan 				++new_rep->bytcnt;	      /* bump report byte count */
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 1st byte of report.. */
 1.1  jonathan
 1.1  jonathan 				if (data & START_FRAME) {
 1.1  jonathan 					new_rep->state = data;
 1.1  jonathan 					if (new_rep->bytcnt > 1) {
 1.1  jonathan 						new_rep->bytcnt = 1;    /* start of new frame */
 1.1  jonathan 						continue;		    /* ..continue looking */
 1.1  jonathan 					}
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 2nd byte of report.. */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 2) {
 1.1  jonathan 					new_rep->dx = data & 0x3F;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 3rd byte of report.. */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 3) {
 1.1  jonathan 					new_rep->dx |= (data & 0x3F) << 6;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 4th byte of report.. */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 4) {
 1.1  jonathan 					new_rep->dy = data & 0x3F;
 1.1  jonathan 				}
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* if 5th byte of report, load input event queue */
 1.1  jonathan
 1.1  jonathan 				else if (new_rep->bytcnt == 5) {
 1.1  jonathan
 1.1  jonathan 					new_rep->dy |= (data & 0x3F) << 6;
 1.1  jonathan 					new_rep->bytcnt = 0;
 1.1  jonathan
 1.1  jonathan 					/*
 1.1  jonathan 					* update cursor position coordinates */
 1.1  jonathan
 1.1  jonathan 					new_rep->dx /= qdflags[qd].tab_res;
 1.1  jonathan 					new_rep->dy = (2200 - new_rep->dy)
 1.1  jonathan 					    / qdflags[qd].tab_res;
 1.1  jonathan
 1.1  jonathan 					if (new_rep->dx > 1023) {
 1.1  jonathan 						new_rep->dx = 1023;
 1.1  jonathan 					}
 1.1  jonathan 					if (new_rep->dy > 863) {
 1.1  jonathan 						new_rep->dy = 863;
 1.1  jonathan 					}
 1.1  jonathan
 1.1  jonathan 					/*
 1.1  jonathan 					* report an event if the puck/stylus has moved
 1.1  jonathan 					*/
 1.1  jonathan
 1.1  jonathan 					if (eqh->curs_pos.x != new_rep->dx ||
 1.1  jonathan 					    eqh->curs_pos.y != new_rep->dy) {
 1.1  jonathan
 1.1  jonathan 						eqh->curs_pos.x = new_rep->dx;
 1.1  jonathan 						eqh->curs_pos.y = new_rep->dy;
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* update cursor screen position */
 1.1  jonathan
 1.1  jonathan 						dga = (struct dga *) qdmap[qd].dga;
 1.1  jonathan 						dga->x_cursor = TRANX(eqh->curs_pos.x);
 1.1  jonathan 						dga->y_cursor = TRANY(eqh->curs_pos.y);
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* if cursor is in the box, no event report
 1.1  jonathan 						*/
 1.1  jonathan
 1.1  jonathan 						if (eqh->curs_pos.x <= eqh->curs_box.right	&&
 1.1  jonathan 						    eqh->curs_pos.x >= eqh->curs_box.left  &&
 1.1  jonathan 						    eqh->curs_pos.y >= eqh->curs_box.top  &&
 1.1  jonathan 						    eqh->curs_pos.y <= eqh->curs_box.bottom ) {
 1.1  jonathan 							goto GET_TBUTTON;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						/*
 1.1  jonathan 						* report the tablet motion event */
 1.1  jonathan
 1.1  jonathan 						event = PUTBEGIN(eqh);
 1.1  jonathan 						PUTEND(eqh);
 1.1  jonathan
 1.1  jonathan 						++do_wakeup;   /* request a select wakeup call */
 1.1  jonathan
 1.1  jonathan 						event->vse_x = eqh->curs_pos.x;
 1.1  jonathan 						event->vse_y = eqh->curs_pos.y;
 1.1  jonathan
 1.1  jonathan 						event->vse_device = VSE_TABLET;  /* tablet */
 1.1  jonathan 						/*
 1.1  jonathan 						* right now, X handles tablet motion the same
 1.1  jonathan 						* as mouse motion
 1.1  jonathan 						*/
 1.1  jonathan 						event->vse_type = VSE_MMOTION;   /* pos changed */
 1.1  jonathan 						event->vse_key = 0;
 1.1  jonathan 						event->vse_direction = 0;
 1.1  jonathan 						event->vse_time = TOY;	/* time stamp */
 1.1  jonathan 					}
 1.1  jonathan GET_TBUTTON:
 1.1  jonathan 					/*
 1.1  jonathan 					* if button state has changed */
 1.1  jonathan
 1.1  jonathan 					a = new_rep->state & 0x1E;   /* mask nonbutton bits */
 1.1  jonathan 					b = last_rep[qd].state & 0x1E;
 1.1  jonathan
 1.1  jonathan 					if (a ^ b) {
 1.1  jonathan
 1.1  jonathan 						/* event queue full now? (overflow condition) */
 1.1  jonathan
 1.1  jonathan 						if (ISFULL(eqh) == TRUE) {
 1.4  christos 							printf("qd%d: qdiint: event queue overflow\n",qd);
 1.1  jonathan 							break;
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						event = PUTBEGIN(eqh);  /* get new event */
 1.1  jonathan 						PUTEND(eqh);
 1.1  jonathan
 1.1  jonathan 						++do_wakeup;   /* request a select wakeup call */
 1.1  jonathan
 1.1  jonathan 						event->vse_x = eqh->curs_pos.x;
 1.1  jonathan 						event->vse_y = eqh->curs_pos.y;
 1.1  jonathan
 1.1  jonathan 						event->vse_device = VSE_TABLET;  /* tablet */
 1.1  jonathan 						event->vse_type = VSE_BUTTON; /* button changed */
 1.1  jonathan 						event->vse_time = TOY;	   /* time stamp */
 1.1  jonathan
 1.1  jonathan 						/* define the changed button and if up or down */
 1.1  jonathan
 1.1  jonathan 						for ( c = 1;  c <= 0x10; c <<= 1) {
 1.1  jonathan 							if (c & (a ^ b)) {
 1.1  jonathan 								if (c == T_LEFT_BUTTON)
 1.1  jonathan 								    event->vse_key = VSE_T_LEFT_BUTTON;
 1.1  jonathan 								else if (c == T_FRONT_BUTTON)
 1.1  jonathan 								    event->vse_key = VSE_T_FRONT_BUTTON;
 1.1  jonathan 								else if (c == T_RIGHT_BUTTON)
 1.1  jonathan 								    event->vse_key = VSE_T_RIGHT_BUTTON;
 1.1  jonathan 								else if (c == T_BACK_BUTTON)
 1.1  jonathan 								    event->vse_key = VSE_T_BACK_BUTTON;
 1.1  jonathan 								break;
 1.1  jonathan 							}
 1.1  jonathan 						}
 1.1  jonathan
 1.1  jonathan 						/* set bit = button depressed */
 1.1  jonathan
 1.1  jonathan 						if (c & a)
 1.1  jonathan 						    event->vse_direction = VSE_KBTDOWN;
 1.1  jonathan 						else
 1.1  jonathan 							event->vse_direction = VSE_KBTUP;
 1.1  jonathan 					}
 1.1  jonathan
 1.1  jonathan 					/* refresh last report */
 1.1  jonathan
 1.1  jonathan 					last_rep[qd] = current_rep[qd];
 1.1  jonathan
 1.1  jonathan 				} /* get last byte of report */
 1.1  jonathan 			} /* pick up tablet input */
 1.1  jonathan
 1.1  jonathan 		} /* while input available.. */
 1.1  jonathan
 1.1  jonathan 		/*
 1.1  jonathan 		* do select wakeup
 1.1  jonathan 		*/
 1.5     ragge 		if (qdrsel[qd].si_pid && do_wakeup && qdflags[qd].selmask & SEL_READ) {
 1.5     ragge 			selwakeup(&qdrsel[qd]);
 1.5     ragge 			qdrsel[qd].si_pid = 0;
 1.1  jonathan 			qdflags[qd].selmask &= ~SEL_READ;
 1.1  jonathan 			do_wakeup = 0;
 1.1  jonathan 		}
 1.1  jonathan 	} else {
 1.1  jonathan 		/*
 1.1  jonathan 		 * if the graphic device is not turned on, this is console input
 1.1  jonathan 		 */
 1.1  jonathan 		if (qdpolling)
 1.1  jonathan 			return;
 1.5     ragge
1.13     ragge 		if (qd >= qd_cd.cd_ndevs || qd_cd.cd_devs[qd] == NULL)
1.13     ragge 			return;		/* no such device or address */
 1.1  jonathan
1.13     ragge 		tp = qd_tty[qd << 2];
 1.1  jonathan
 1.1  jonathan 		/*
 1.1  jonathan 		 * Get a character from the keyboard.
 1.1  jonathan 		 */
 1.1  jonathan 		while (duart->statusA&RCV_RDY) {
 1.1  jonathan 			key = duart->dataA;
 1.1  jonathan 			key &= 0xFF;
 1.1  jonathan 			/*
 1.1  jonathan 			* Check for various keyboard errors
 1.1  jonathan 			*/
 1.1  jonathan 			if (key == LK_POWER_ERROR || key == LK_KDOWN_ERROR ||
 1.1  jonathan 			    key == LK_INPUT_ERROR || key == LK_OUTPUT_ERROR) {
 1.4  christos 				printf("qd%d: qdiint: Keyboard error, code = %x\n",qd,key);
 1.1  jonathan 				return;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			if (key < LK_LOWEST)
 1.1  jonathan 			    return;
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* See if its a state change key */
 1.1  jonathan
 1.1  jonathan 			switch (key) {
 1.1  jonathan
 1.1  jonathan 			case LOCK:
 1.1  jonathan 				q_keyboard.lock ^= 0xffff;	/* toggle */
 1.1  jonathan 				if (q_keyboard.lock)
 1.6     ragge 					led_control(qd, LK_LED_ENABLE,
 1.1  jonathan 							  LK_LED_LOCK);
 1.1  jonathan 				else
 1.6     ragge 					led_control(qd, LK_LED_DISABLE,
 1.1  jonathan 							  LK_LED_LOCK);
 1.1  jonathan 				return;
 1.1  jonathan
 1.1  jonathan 			case SHIFT:
 1.1  jonathan 				q_keyboard.shift ^= 0xFFFF;
 1.1  jonathan 				return;
 1.1  jonathan
 1.1  jonathan 			case CNTRL:
 1.1  jonathan 				q_keyboard.cntrl ^= 0xFFFF;
 1.1  jonathan 				return;
 1.1  jonathan
 1.1  jonathan 			case ALLUP:
 1.1  jonathan 				q_keyboard.cntrl = 0;
 1.1  jonathan 				q_keyboard.shift = 0;
 1.1  jonathan 				return;
 1.1  jonathan
 1.1  jonathan 			case REPEAT:
 1.1  jonathan 				chr = q_keyboard.last;
 1.1  jonathan 				break;
 1.1  jonathan
 1.1  jonathan 				/*
 1.1  jonathan 				* Test for cntrl characters. If set, see if the character
 1.1  jonathan 				* is elligible to become a control character. */
 1.1  jonathan
 1.1  jonathan 			default:
 1.1  jonathan
 1.1  jonathan 				if (q_keyboard.cntrl) {
 1.1  jonathan 					chr = q_key[key];
 1.1  jonathan 					if (chr >= ' ' && chr <= '~')
 1.1  jonathan 					    chr &= 0x1F;
 1.1  jonathan 					else if (chr >= 0xA1 && chr <= 0xFE)
 1.1  jonathan 					    chr &= 0x9F;
 1.1  jonathan 				}
 1.1  jonathan 				else if( q_keyboard.lock || q_keyboard.shift )
 1.1  jonathan 				    chr = q_shift_key[key];
 1.1  jonathan 				else
 1.1  jonathan 					chr = q_key[key];
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan
 1.1  jonathan 			q_keyboard.last = chr;
 1.1  jonathan
 1.1  jonathan 			/*
 1.1  jonathan 			* Check for special function keys */
 1.1  jonathan
 1.1  jonathan 			if (chr & 0x100) {
 1.1  jonathan 				char *string;
 1.1  jonathan 				string = q_special[chr & 0x7F];
 1.1  jonathan 				while(*string)
 1.1  jonathan 				    (*linesw[tp->t_line].l_rint)(*string++, tp);
 1.1  jonathan 			}
 1.1  jonathan 			else {
 1.5     ragge #ifdef DDB
1.13     ragge 				/* Check for kernel debugger escape here */
1.13     ragge 				int j;
 1.5     ragge
 1.5     ragge 				j = kdbrint(chr&0177);
 1.5     ragge
1.13     ragge 				if (j == 1)  /* Escape received, just return */
1.13     ragge 				    return;
 1.5     ragge
1.13     ragge 				if (j == 2)  /* Second char wasn't 'D' */
1.13     ragge 				    (*linesw[tp->t_line].l_rint)(27, tp);
 1.1  jonathan #endif
 1.1  jonathan 				(*linesw[tp->t_line].l_rint)(chr&0177, tp);
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan } /* qdiint */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *
 1.1  jonathan  * Clear the QDSS screen
 1.1  jonathan  *
 1.1  jonathan  *			     >>> NOTE <<<
 1.1  jonathan  *
 1.1  jonathan  *   This code requires that certain adder initialization be valid.  To
 1.1  jonathan  *   assure that this requirement is satisfied, this routine should be
 1.1  jonathan  *   called only after calling the "setup_dragon()" function.
 1.1  jonathan  *
 1.1  jonathan  *   Clear the bitmap a piece at a time. Since the fast scroll clear
 1.1  jonathan  *   only clears the current displayed portion of the bitmap put a
 1.1  jonathan  *   temporary value in the y limit register so we can access whole
 1.1  jonathan  *   bitmap
 1.1  jonathan  *
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan clear_qd_screen(unit)
 1.1  jonathan 	int unit;
 1.1  jonathan {
 1.5     ragge 	volatile register struct adder *adder;
 1.1  jonathan 	adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan
 1.1  jonathan 	adder->x_limit = 1024;
 1.1  jonathan 	adder->y_limit = 2048 - CHAR_HEIGHT;
 1.1  jonathan 	adder->y_offset_pending = 0;
 1.1  jonathan #define WSV  (void)wait_status(adder, VSYNC); (void)wait_status(adder, VSYNC)
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_scroll_constant = SCROLL_ERASE;
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_offset_pending = 864;
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_scroll_constant = SCROLL_ERASE;
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_offset_pending = 1728;
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_scroll_constant = SCROLL_ERASE;
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->y_offset_pending = 0;	 /* back to normal */
 1.1  jonathan 	WSV;
 1.1  jonathan 	adder->x_limit = MAX_SCREEN_X;
 1.1  jonathan 	adder->y_limit = MAX_SCREEN_Y + FONT_HEIGHT;
 1.1  jonathan #undef WSV
 1.1  jonathan
 1.1  jonathan } /* clear_qd_screen */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  kernel console output to the glass tty
 1.1  jonathan  */
 1.6     ragge void
 1.5     ragge qdcnputc(dev, chr)
1.13     ragge 	dev_t dev;
 1.5     ragge 	int chr;
 1.1  jonathan {
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * if system is now physical, forget it (ie: crash DUMP)
 1.1  jonathan 	 */
 1.5     ragge 	if ((mfpr(PR_MAPEN) & 1) == 0)
 1.1  jonathan 		return;
 1.1  jonathan
 1.1  jonathan 	blitc(0, (u_char)(chr & 0xff));
 1.1  jonathan 	if ((chr & 0177) == '\n')
 1.1  jonathan 		blitc(0, '\r');
 1.1  jonathan
 1.1  jonathan } /* qdputc */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  load the mouse cursor's template RAM bitmap
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan ldcursor(unit, bitmap)
 1.1  jonathan 	int unit;
1.13     ragge 	short *bitmap;
 1.1  jonathan {
 1.5     ragge 	volatile register struct dga *dga;
 1.5     ragge 	volatile register short *temp;
 1.1  jonathan 	register int i;
 1.1  jonathan 	int curs;
 1.1  jonathan
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 	temp = (short *) qdmap[unit].template;
 1.1  jonathan
 1.1  jonathan 	if (dga->csr & CURS_ENB) {	/* if the cursor is enabled.. */
 1.1  jonathan 		curs = -1;		/* ..note that.. */
 1.1  jonathan 		dga->csr &= ~CURS_ENB;	/* ..and shut it off */
 1.1  jonathan 	} else
 1.1  jonathan 		curs = 0;
 1.1  jonathan
 1.1  jonathan 	dga->csr &= ~CURS_ENB;		/* shut off the cursor */
 1.1  jonathan
 1.1  jonathan 	temp += (8 * 1024) - 32;	/* cursor is 32 WORDS from the end */
 1.1  jonathan 	/* ..of the 8k WORD template space */
 1.1  jonathan 	for (i = 0; i < 32; ++i)
 1.1  jonathan 		*temp++ = *bitmap++;
 1.1  jonathan
 1.1  jonathan 	if (curs) {			/* if cursor was enabled.. */
 1.1  jonathan 		dga->csr |= CURS_ENB;	/* ..turn it back on */
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan } /* ldcursor */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  Put the console font in the QDSS off-screen memory
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan ldfont(unit)
 1.1  jonathan 	int unit;
 1.1  jonathan {
 1.5     ragge 	volatile register struct adder *adder;
 1.1  jonathan
 1.9     ragge 	register int i, j, k, max_chars_line;
 1.1  jonathan 	register short packed;
 1.1  jonathan
 1.1  jonathan 	adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* setup VIPER operand control registers
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, MASK_1, 0xFFFF);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | FOREGROUND_COLOR_Z, 255);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | BACKGROUND_COLOR_Z, 0);
 1.1  jonathan
 1.1  jonathan 	write_ID(adder, SRC1_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_NONE | ID | BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, SRC2_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_NONE | ID | BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, DST_OCR_B,
 1.1  jonathan 	EXT_SOURCE | INT_NONE | NO_ID | NO_BAR_SHIFT_DELAY);
 1.1  jonathan
 1.1  jonathan 	adder->rasterop_mode = DST_WRITE_ENABLE | DST_INDEX_ENABLE | NORMAL;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* load destination data
 1.1  jonathan 	*/
 1.1  jonathan 	(void)wait_status(adder, RASTEROP_COMPLETE);
 1.1  jonathan
 1.1  jonathan 	adder->destination_x = FONT_X;
 1.1  jonathan 	adder->destination_y = FONT_Y;
 1.1  jonathan #if FONT_WIDTH > MAX_SCREEN_X
 1.1  jonathan 	adder->fast_dest_dx = MAX_SCREEN_X;
 1.1  jonathan #else
 1.1  jonathan 	adder->fast_dest_dx = FONT_WIDTH;
 1.1  jonathan #endif
 1.1  jonathan 	adder->slow_dest_dy = CHAR_HEIGHT;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* setup for processor to bitmap xfer  */
 1.1  jonathan
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0001);
 1.1  jonathan 	adder->cmd = PBT | OCRB | 2 | DTE | 2;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* Figure out how many characters can be stored on one "line" of
 1.1  jonathan 	* offscreen memory.
 1.1  jonathan 	*/
 1.1  jonathan 	max_chars_line = MAX_SCREEN_X/(CHAR_WIDTH*2);
 1.1  jonathan 	if ((CHARS/2 + CHARS%2) < max_chars_line)
 1.1  jonathan 	    max_chars_line = CHARS/2 + CHARS%2;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* iteratively do the processor to bitmap xfer */
 1.1  jonathan
 1.1  jonathan 	for (i = 0; i < ROWS; ++i) {
 1.1  jonathan
 1.1  jonathan 		/* PTOB a scan line */
 1.1  jonathan
 1.1  jonathan 		for (j = 0, k = i; j < max_chars_line; ++j) {
 1.1  jonathan 			/* PTOB one scan of a char cell */
 1.1  jonathan
 1.1  jonathan 			packed = q_font[k];
 1.1  jonathan 			k += ROWS;
 1.1  jonathan 			packed |= ((short)q_font[k] << 8);
 1.1  jonathan 			k += ROWS;
 1.1  jonathan
 1.1  jonathan 			(void)wait_status(adder, TX_READY);
 1.1  jonathan 			adder->id_data = packed;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * (XXX XXX XXX - should remove)
 1.1  jonathan 	 *
 1.1  jonathan 	 * Copy the second row of characters.  Subtract the first
 1.1  jonathan 	 * row from the total number.  Divide this quantity by 2
 1.1  jonathan 	 * because 2 chars are stored in a short in the PTOB loop
 1.1  jonathan 	 * below.  Figure out how many characters can be stored on
 1.1  jonathan 	 * one "line" of offscreen memory
 1.1  jonathan 	 */
 1.1  jonathan
 1.1  jonathan 	max_chars_line = MAX_SCREEN_X/(CHAR_WIDTH*2);
 1.1  jonathan 	if ((CHARS/2 + CHARS%2) < max_chars_line)
 1.1  jonathan 	    return;
 1.1  jonathan 	max_chars_line = (CHARS/2 + CHARS%2) - max_chars_line; /* 95 - 64 */
 1.1  jonathan 	/* Paranoia check to see if 3rd row may be needed */
 1.1  jonathan 	if (max_chars_line > (MAX_SCREEN_X/(CHAR_WIDTH*2)))
 1.1  jonathan 	    max_chars_line = MAX_SCREEN_X/(CHAR_WIDTH*2);
 1.1  jonathan
 1.1  jonathan 	adder->destination_x = FONT_X;
 1.1  jonathan 	adder->destination_y = FONT_Y - CHAR_HEIGHT;
 1.1  jonathan 	adder->fast_dest_dx = max_chars_line * CHAR_WIDTH * 2;
 1.1  jonathan 	adder->slow_dest_dy = CHAR_HEIGHT;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* setup for processor to bitmap xfer
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0001);
 1.1  jonathan 	adder->cmd = PBT | OCRB | 2 | DTE | 2;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* iteratively do the processor to bitmap xfer
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 0; i < ROWS; ++i) {
 1.1  jonathan 		/*
 1.1  jonathan 		 * PTOB a scan line
 1.1  jonathan 		 */
 1.1  jonathan 		for (j = 0, k = i; j < max_chars_line; ++j) {
 1.1  jonathan 			/*
 1.1  jonathan 			 * PTOB one scan of a char cell
 1.1  jonathan 			 */
 1.1  jonathan 			packed = q_font[k + FONT_OFFSET];
 1.1  jonathan 			k += ROWS;
 1.1  jonathan 			packed |= ((short)q_font[k + FONT_OFFSET] << 8);
 1.1  jonathan 			k += ROWS;
 1.1  jonathan 			(void)wait_status(adder, TX_READY);
 1.1  jonathan 			adder->id_data = packed;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan }  /* ldfont */
 1.1  jonathan
 1.5     ragge
 1.5     ragge /*
 1.5     ragge  * Disable or enable polling.  This is used when entering or leaving the
 1.5     ragge  * kernel debugger.
 1.5     ragge  */
 1.6     ragge void
 1.5     ragge qdcnpollc(dev, onoff)
1.13     ragge 	dev_t dev;
1.13     ragge 	int onoff;
 1.1  jonathan {
 1.5     ragge      qdpolling = onoff;
 1.1  jonathan }
 1.1  jonathan
 1.5     ragge
 1.1  jonathan /*
 1.1  jonathan  *  Get a character from the LK201 (polled)
 1.1  jonathan  */
 1.6     ragge int
 1.5     ragge qdcngetc(dev)
1.13     ragge 	dev_t dev;
 1.1  jonathan {
 1.1  jonathan 	register short key;
 1.1  jonathan 	register char chr;
 1.5     ragge 	volatile register struct duart *duart;
 1.1  jonathan
 1.1  jonathan 	duart = (struct duart *) qdmap[0].duart;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* Get a character from the keyboard.
 1.1  jonathan 	*/
 1.1  jonathan LOOP:
 1.1  jonathan 	while (!(duart->statusA&RCV_RDY))
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	key = duart->dataA;
 1.1  jonathan 	key &= 0xFF;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* Check for various keyboard errors  */
 1.1  jonathan
 1.1  jonathan 	if (key == LK_POWER_ERROR || key == LK_KDOWN_ERROR ||
 1.1  jonathan 	    key == LK_INPUT_ERROR || key == LK_OUTPUT_ERROR) {
 1.4  christos 		printf("Keyboard error, code = %x\n", key);
 1.1  jonathan 		return(0);
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (key < LK_LOWEST)
 1.1  jonathan 		return(0);
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	 * See if its a state change key
 1.1  jonathan 	 */
 1.1  jonathan 	switch (key) {
 1.1  jonathan
 1.1  jonathan 	case LOCK:
 1.1  jonathan 		q_keyboard.lock ^= 0xffff;	/* toggle */
 1.1  jonathan 		if (q_keyboard.lock)
 1.6     ragge 			led_control(0, LK_LED_ENABLE, LK_LED_LOCK);
 1.1  jonathan 		else
 1.6     ragge 			led_control(0, LK_LED_DISABLE, LK_LED_LOCK);
 1.1  jonathan 		goto LOOP;
 1.1  jonathan
 1.1  jonathan 	case SHIFT:
 1.1  jonathan 		q_keyboard.shift ^= 0xFFFF;
 1.1  jonathan 		goto LOOP;
 1.1  jonathan
 1.1  jonathan 	case CNTRL:
 1.1  jonathan 		q_keyboard.cntrl ^= 0xFFFF;
 1.1  jonathan 		goto LOOP;
 1.1  jonathan
 1.1  jonathan 	case ALLUP:
 1.1  jonathan 		q_keyboard.cntrl = 0;
 1.1  jonathan 		q_keyboard.shift = 0;
 1.1  jonathan 		goto LOOP;
 1.1  jonathan
 1.1  jonathan 	case REPEAT:
 1.1  jonathan 		chr = q_keyboard.last;
 1.1  jonathan 		break;
 1.1  jonathan
 1.1  jonathan 		/*
 1.1  jonathan 		* Test for cntrl characters. If set, see if the character
 1.1  jonathan 		* is elligible to become a control character.
 1.1  jonathan 		*/
 1.1  jonathan 	default:
 1.1  jonathan
 1.1  jonathan 		if (q_keyboard.cntrl) {
 1.1  jonathan 			chr = q_key[key];
 1.1  jonathan 			if (chr >= ' ' && chr <= '~')
 1.1  jonathan 			    chr &= 0x1F;
 1.1  jonathan 		}
 1.1  jonathan 		else if ( q_keyboard.lock || q_keyboard.shift )
 1.1  jonathan 		    chr = q_shift_key[key];
 1.1  jonathan 		else
 1.1  jonathan 			chr = q_key[key];
 1.1  jonathan 		break;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (chr < ' ' && chr > '~')	/* if input is non-displayable */
 1.1  jonathan 		return(0);		/* ..then pitch it! */
 1.1  jonathan
 1.1  jonathan 	q_keyboard.last = chr;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* Check for special function keys */
 1.1  jonathan
 1.1  jonathan 	if (chr & 0x80) 		/* pitch the function keys */
 1.1  jonathan 		return(0);
 1.1  jonathan 	else
 1.1  jonathan 		return(chr);
 1.1  jonathan
 1.1  jonathan } /* qdgetc */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  led_control()... twiddle LK-201 LED's
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan led_control(unit, cmd, led_mask)
 1.1  jonathan 	int unit, cmd, led_mask;
 1.1  jonathan {
 1.9     ragge 	register int i;
 1.5     ragge 	volatile register struct duart *duart;
 1.1  jonathan
 1.1  jonathan 	duart = (struct duart *)qdmap[unit].duart;
 1.1  jonathan
 1.1  jonathan 	for (i = 1000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusA&XMT_RDY) {
 1.1  jonathan 			duart->dataA = cmd;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan 	for (i = 1000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusA&XMT_RDY) {
 1.1  jonathan 			duart->dataA = led_mask;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.6     ragge 	return;
 1.1  jonathan
 1.1  jonathan } /* led_control */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  scroll_up()... move the screen up one character height
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan scroll_up(adder)
 1.5     ragge 	volatile struct adder *adder;
 1.1  jonathan {
 1.1  jonathan 	/*
 1.1  jonathan 	* setup VIPER operand control registers
 1.1  jonathan 	*/
 1.1  jonathan 	(void)wait_status(adder, ADDRESS_COMPLETE);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x00FF);  /* select all planes */
 1.1  jonathan 	write_ID(adder, MASK_1, 0xFFFF);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | FOREGROUND_COLOR_Z, 255);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | BACKGROUND_COLOR_Z, 0);
 1.1  jonathan 	write_ID(adder, SRC1_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_SOURCE | ID | BAR_SHIFT_DELAY);
 1.1  jonathan 	write_ID(adder, DST_OCR_B,
 1.1  jonathan 	EXT_NONE | INT_NONE | NO_ID | NO_BAR_SHIFT_DELAY);
 1.1  jonathan 	/*
 1.1  jonathan 	 * load DESTINATION origin and vectors
 1.1  jonathan 	 */
 1.1  jonathan 	adder->fast_dest_dy = 0;
 1.1  jonathan 	adder->slow_dest_dx = 0;
 1.1  jonathan 	adder->error_1 = 0;
 1.1  jonathan 	adder->error_2 = 0;
 1.1  jonathan 	adder->rasterop_mode = DST_WRITE_ENABLE | NORMAL;
 1.1  jonathan 	adder->destination_x = 0;
 1.1  jonathan 	adder->fast_dest_dx = 1024;
 1.1  jonathan 	adder->destination_y = 0;
 1.1  jonathan 	adder->slow_dest_dy = 864 - CHAR_HEIGHT;
 1.1  jonathan 	/*
 1.1  jonathan 	 * load SOURCE origin and vectors
 1.1  jonathan 	 */
 1.1  jonathan 	adder->source_1_x = 0;
 1.1  jonathan 	adder->source_1_dx = 1024;
 1.1  jonathan 	adder->source_1_y = 0 + CHAR_HEIGHT;
 1.1  jonathan 	adder->source_1_dy = 864 - CHAR_HEIGHT;
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R1, FULL_SRC_RESOLUTION | LF_SOURCE);
 1.1  jonathan 	adder->cmd = RASTEROP | OCRB | 0 | S1E | DTE;
 1.1  jonathan 	/*
 1.1  jonathan 	 * do a rectangle clear of last screen line
 1.1  jonathan 	 */
 1.1  jonathan 	write_ID(adder, MASK_1, 0xffff);
 1.1  jonathan 	write_ID(adder, SOURCE, 0xffff);
 1.1  jonathan 	write_ID(adder,DST_OCR_B,
 1.1  jonathan 	(EXT_NONE | INT_NONE | NO_ID | NO_BAR_SHIFT_DELAY));
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | FOREGROUND_COLOR_Z, 0);
 1.1  jonathan 	adder->error_1 = 0;
 1.1  jonathan 	adder->error_2 = 0;
 1.1  jonathan 	adder->slow_dest_dx = 0;		/* set up the width of	*/
 1.1  jonathan 	adder->slow_dest_dy = CHAR_HEIGHT;	/* rectangle */
 1.1  jonathan 	adder->rasterop_mode = (NORMAL | DST_WRITE_ENABLE) ;
 1.1  jonathan 	(void)wait_status(adder, RASTEROP_COMPLETE);
 1.1  jonathan 	adder->destination_x = 0;
 1.1  jonathan 	adder->destination_y = 864 - CHAR_HEIGHT;
 1.1  jonathan 	adder->fast_dest_dx = 1024;	/* set up the height	*/
 1.1  jonathan 	adder->fast_dest_dy = 0;	/* of rectangle 	*/
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R2, (FULL_SRC_RESOLUTION | LF_SOURCE));
 1.1  jonathan 	adder->cmd = (RASTEROP | OCRB | LF_R2 | DTE ) ;
 1.1  jonathan
 1.1  jonathan } /* scroll_up */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  *  init shared memory pointers and structures
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan init_shared(unit)
1.13     ragge 	int unit;
 1.1  jonathan {
 1.5     ragge 	volatile register struct dga *dga;
 1.1  jonathan
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* initialize the event queue pointers and header */
 1.1  jonathan
 1.1  jonathan 	eq_header[unit] = (struct qdinput *)
 1.1  jonathan 	    ((((int)event_shared & ~(0x01FF)) + 512)
 1.1  jonathan 		+ (EVENT_BUFSIZE * unit));
 1.1  jonathan 	eq_header[unit]->curs_pos.x = 0;
 1.1  jonathan 	eq_header[unit]->curs_pos.y = 0;
 1.1  jonathan 	dga->x_cursor = TRANX(eq_header[unit]->curs_pos.x);
 1.1  jonathan 	dga->y_cursor = TRANY(eq_header[unit]->curs_pos.y);
 1.1  jonathan 	eq_header[unit]->curs_box.left = 0;
 1.1  jonathan 	eq_header[unit]->curs_box.right = 0;
 1.1  jonathan 	eq_header[unit]->curs_box.top = 0;
 1.1  jonathan 	eq_header[unit]->curs_box.bottom = 0;
 1.1  jonathan 	/*
 1.1  jonathan 	 * assign a pointer to the DMA I/O buffer for this QDSS.
 1.1  jonathan 	 */
 1.1  jonathan 	DMAheader[unit] = (struct DMAreq_header *)
 1.1  jonathan 	    (((int)(&DMA_shared[0] + 512) & ~0x1FF)
 1.1  jonathan 		+ (DMAbuf_size * unit));
 1.1  jonathan 	DMAheader[unit]->DMAreq = (struct DMAreq *) ((int)DMAheader[unit]
 1.1  jonathan 	    + sizeof(struct DMAreq_header));
 1.1  jonathan 	DMAheader[unit]->QBAreg = 0;
 1.1  jonathan 	DMAheader[unit]->status = 0;
 1.1  jonathan 	DMAheader[unit]->shared_size = DMAbuf_size;
 1.1  jonathan 	DMAheader[unit]->used = 0;
 1.1  jonathan 	DMAheader[unit]->size = 10;	/* default = 10 requests */
 1.1  jonathan 	DMAheader[unit]->oldest = 0;
 1.1  jonathan 	DMAheader[unit]->newest = 0;
 1.1  jonathan 	/*
 1.1  jonathan 	* assign a pointer to the scroll structure for this QDSS.
 1.1  jonathan 	*/
 1.1  jonathan 	scroll[unit] = (struct scroll *)
 1.1  jonathan 	    (((int)(&scroll_shared[0] + 512) & ~0x1FF)
 1.1  jonathan 		+ (sizeof(struct scroll) * unit));
 1.1  jonathan 	scroll[unit]->status = 0;
 1.1  jonathan 	scroll[unit]->viper_constant = 0;
 1.1  jonathan 	scroll[unit]->y_scroll_constant = 0;
 1.1  jonathan 	scroll[unit]->y_offset = 0;
 1.1  jonathan 	scroll[unit]->x_index_pending = 0;
 1.1  jonathan 	scroll[unit]->y_index_pending = 0;
 1.1  jonathan 	/*
 1.1  jonathan 	* assign a pointer to the color map write buffer for this QDSS
 1.1  jonathan 	*/
 1.1  jonathan 	color_buf[unit] = (struct color_buf *)
 1.1  jonathan 	    (((int)(&color_shared[0] + 512) & ~0x1FF)
 1.1  jonathan 		+ (COLOR_BUFSIZ * unit));
 1.1  jonathan 	color_buf[unit]->status = 0;
 1.1  jonathan 	color_buf[unit]->count = 0;
 1.1  jonathan
 1.1  jonathan } /* init_shared */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * init the ADDER, VIPER, bitmaps, & color map
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan setup_dragon(unit)
 1.1  jonathan 	int unit;
 1.1  jonathan {
 1.1  jonathan
 1.5     ragge 	volatile register struct adder *adder;
 1.5     ragge 	volatile register struct dga *dga;
 1.5     ragge 	volatile short *memcsr;
 1.9     ragge 	register int i;
 1.1  jonathan 	short top;		/* clipping/scrolling boundaries */
 1.1  jonathan 	short bottom;
 1.1  jonathan 	short right;
 1.1  jonathan 	short left;
 1.5     ragge 	volatile short *red;		/* color map pointers */
 1.5     ragge 	volatile short *green;
 1.5     ragge 	volatile short *blue;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init for setup
 1.1  jonathan 	*/
 1.1  jonathan 	adder = (struct adder *) qdmap[unit].adder;
 1.1  jonathan 	dga = (struct dga *) qdmap[unit].dga;
 1.1  jonathan 	memcsr = (short *) qdmap[unit].memcsr;
 1.1  jonathan 	dga->csr &= ~(DMA_IE | 0x700);	/* halt DMA and kill the intrpts */
 1.1  jonathan 	*memcsr = SYNC_ON;		/* blank screen and turn off LED's */
 1.1  jonathan 	adder->command = CANCEL;
 1.1  jonathan 	/*
 1.1  jonathan 	* set monitor timing
 1.1  jonathan 	*/
 1.1  jonathan 	adder->x_scan_count_0 = 0x2800;
 1.1  jonathan 	adder->x_scan_count_1 = 0x1020;
 1.1  jonathan 	adder->x_scan_count_2 = 0x003A;
 1.1  jonathan 	adder->x_scan_count_3 = 0x38F0;
 1.1  jonathan 	adder->x_scan_count_4 = 0x6128;
 1.1  jonathan 	adder->x_scan_count_5 = 0x093A;
 1.1  jonathan 	adder->x_scan_count_6 = 0x313C;
 1.1  jonathan 	adder->sync_phase_adj = 0x0100;
 1.1  jonathan 	adder->x_scan_conf = 0x00C8;
 1.1  jonathan 	/*
 1.1  jonathan 	 * got a bug in secound pass ADDER! lets take care of it
 1.1  jonathan 	 *
 1.1  jonathan 	 * normally, just use the code in the following bug fix code, but to
 1.1  jonathan 	 * make repeated demos look pretty, load the registers as if there was
 1.1  jonathan 	 * no bug and then test to see if we are getting sync
 1.1  jonathan 	 */
 1.1  jonathan 	adder->y_scan_count_0 = 0x135F;
 1.1  jonathan 	adder->y_scan_count_1 = 0x3363;
 1.1  jonathan 	adder->y_scan_count_2 = 0x2366;
 1.1  jonathan 	adder->y_scan_count_3 = 0x0388;
 1.1  jonathan 	/*
 1.1  jonathan 	 * if no sync, do the bug fix code
 1.1  jonathan 	 */
 1.1  jonathan 	if (wait_status(adder, VSYNC) == BAD) {
 1.1  jonathan 		/* first load all Y scan registers with very short frame and
 1.1  jonathan 		 * wait for scroll service.  This guarantees at least one SYNC
 1.1  jonathan 		 * to fix the pass 2 Adder initialization bug (synchronizes
 1.1  jonathan 		 * XCINCH with DMSEEDH)
 1.1  jonathan 		 */
 1.1  jonathan 		adder->y_scan_count_0 = 0x01;
 1.1  jonathan 		adder->y_scan_count_1 = 0x01;
 1.1  jonathan 		adder->y_scan_count_2 = 0x01;
 1.1  jonathan 		adder->y_scan_count_3 = 0x01;
 1.1  jonathan 		/*
 1.1  jonathan 		 * delay at least 1 full frame time
 1.1  jonathan 		 */
 1.1  jonathan 		(void)wait_status(adder, VSYNC);
 1.1  jonathan 		(void)wait_status(adder, VSYNC);
 1.1  jonathan 		/*
 1.1  jonathan 		 * now load the REAL sync values (in reverse order just to
 1.1  jonathan 		 * be safe.
 1.1  jonathan 		 */
 1.1  jonathan 		adder->y_scan_count_3 = 0x0388;
 1.1  jonathan 		adder->y_scan_count_2 = 0x2366;
 1.1  jonathan 		adder->y_scan_count_1 = 0x3363;
 1.1  jonathan 		adder->y_scan_count_0 = 0x135F;
 1.1  jonathan 	}
 1.1  jonathan 	*memcsr = SYNC_ON | UNBLANK;	/* turn off leds and turn on video */
 1.1  jonathan 	/*
 1.1  jonathan 	 * zero the index registers
 1.1  jonathan 	 */
 1.1  jonathan 	adder->x_index_pending = 0;
 1.1  jonathan 	adder->y_index_pending = 0;
 1.1  jonathan 	adder->x_index_new = 0;
 1.1  jonathan 	adder->y_index_new = 0;
 1.1  jonathan 	adder->x_index_old = 0;
 1.1  jonathan 	adder->y_index_old = 0;
 1.1  jonathan 	adder->pause = 0;
 1.1  jonathan 	/*
 1.1  jonathan 	 * set rasterop mode to normal pen down
 1.1  jonathan 	 */
 1.1  jonathan 	adder->rasterop_mode = DST_WRITE_ENABLE | DST_INDEX_ENABLE | NORMAL;
 1.1  jonathan 	/*
 1.1  jonathan 	 * set the rasterop registers to a default values
 1.1  jonathan 	 */
 1.1  jonathan 	adder->source_1_dx = 1;
 1.1  jonathan 	adder->source_1_dy = 1;
 1.1  jonathan 	adder->source_1_x = 0;
 1.1  jonathan 	adder->source_1_y = 0;
 1.1  jonathan 	adder->destination_x = 0;
 1.1  jonathan 	adder->destination_y = 0;
 1.1  jonathan 	adder->fast_dest_dx = 1;
 1.1  jonathan 	adder->fast_dest_dy = 0;
 1.1  jonathan 	adder->slow_dest_dx = 0;
 1.1  jonathan 	adder->slow_dest_dy = 1;
 1.1  jonathan 	adder->error_1 = 0;
 1.1  jonathan 	adder->error_2 = 0;
 1.1  jonathan 	/*
 1.1  jonathan 	 * scale factor = UNITY
 1.1  jonathan 	 */
 1.1  jonathan 	adder->fast_scale = UNITY;
 1.1  jonathan 	adder->slow_scale = UNITY;
 1.1  jonathan 	/*
 1.1  jonathan 	 * set the source 2 parameters
 1.1  jonathan 	 */
 1.1  jonathan 	adder->source_2_x = 0;
 1.1  jonathan 	adder->source_2_y = 0;
 1.1  jonathan 	adder->source_2_size = 0x0022;
 1.1  jonathan 	/*
 1.1  jonathan 	* initialize plane addresses for eight vipers
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0001);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0000);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0002);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0001);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0004);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0002);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0008);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0003);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0010);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0004);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0020);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0005);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0040);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0006);
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x0080);
 1.1  jonathan 	write_ID(adder, PLANE_ADDRESS, 0x0007);
 1.1  jonathan 	/*
 1.1  jonathan 	 * initialize the external registers.
 1.1  jonathan 	 */
 1.1  jonathan 	write_ID(adder, CS_UPDATE_MASK, 0x00FF);
 1.1  jonathan 	write_ID(adder, CS_SCROLL_MASK, 0x00FF);
 1.1  jonathan 	/*
 1.1  jonathan 	 * initialize resolution mode
 1.1  jonathan 	 */
 1.1  jonathan 	write_ID(adder, MEMORY_BUS_WIDTH, 0x000C);     /* bus width = 16 */
 1.1  jonathan 	write_ID(adder, RESOLUTION_MODE, 0x0000);      /* one bit/pixel */
 1.1  jonathan 	/*
 1.1  jonathan 	 * initialize viper registers
 1.1  jonathan 	 */
 1.1  jonathan 	write_ID(adder, SCROLL_CONSTANT, SCROLL_ENABLE|VIPER_LEFT|VIPER_UP);
 1.1  jonathan 	write_ID(adder, SCROLL_FILL, 0x0000);
 1.1  jonathan 	/*
 1.1  jonathan 	 * set clipping and scrolling limits to full screen
 1.1  jonathan 	 */
 1.1  jonathan 	for (i = 1000, adder->status = 0;
 1.1  jonathan 	     i > 0 && !(adder->status&ADDRESS_COMPLETE); --i)
 1.1  jonathan 		;
 1.1  jonathan 	if (i == 0)
 1.4  christos 	    printf("qd%d: setup_dragon: timeout on ADDRESS_COMPLETE\n",unit);
 1.1  jonathan 	top = 0;
 1.1  jonathan 	bottom = 2048;
 1.1  jonathan 	left = 0;
 1.1  jonathan 	right = 1024;
 1.1  jonathan 	adder->x_clip_min = left;
 1.1  jonathan 	adder->x_clip_max = right;
 1.1  jonathan 	adder->y_clip_min = top;
 1.1  jonathan 	adder->y_clip_max = bottom;
 1.1  jonathan 	adder->scroll_x_min = left;
 1.1  jonathan 	adder->scroll_x_max = right;
 1.1  jonathan 	adder->scroll_y_min = top;
 1.1  jonathan 	adder->scroll_y_max = bottom;
 1.1  jonathan 	(void)wait_status(adder, VSYNC);	/* wait at LEAST 1 full frame */
 1.1  jonathan 	(void)wait_status(adder, VSYNC);
 1.1  jonathan 	adder->x_index_pending = left;
 1.1  jonathan 	adder->y_index_pending = top;
 1.1  jonathan 	adder->x_index_new = left;
 1.1  jonathan 	adder->y_index_new = top;
 1.1  jonathan 	adder->x_index_old = left;
 1.1  jonathan 	adder->y_index_old = top;
 1.1  jonathan
 1.1  jonathan 	for (i = 1000, adder->status = 0; i > 0 &&
 1.1  jonathan 	     !(adder->status&ADDRESS_COMPLETE) ; --i)
 1.1  jonathan 		;
 1.1  jonathan 	if (i == 0)
 1.4  christos 	       printf("qd%d: setup_dragon: timeout on ADDRESS_COMPLETE\n",unit);
 1.1  jonathan
 1.1  jonathan 	write_ID(adder, LEFT_SCROLL_MASK, 0x0000);
 1.1  jonathan 	write_ID(adder, RIGHT_SCROLL_MASK, 0x0000);
 1.1  jonathan 	/*
 1.1  jonathan 	* set source and the mask register to all ones (ie: white) o
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, SOURCE, 0xFFFF);
 1.1  jonathan 	write_ID(adder, MASK_1, 0xFFFF);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | FOREGROUND_COLOR_Z, 255);
 1.1  jonathan 	write_ID(adder, VIPER_Z_LOAD | BACKGROUND_COLOR_Z, 0);
 1.1  jonathan 	/*
 1.1  jonathan 	* initialize Operand Control Register banks for fill command
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, SRC1_OCR_A, EXT_NONE | INT_M1_M2  | NO_ID | WAIT);
 1.1  jonathan 	write_ID(adder, SRC2_OCR_A, EXT_NONE | INT_SOURCE | NO_ID | NO_WAIT);
 1.1  jonathan 	write_ID(adder, DST_OCR_A, EXT_NONE | INT_NONE	 | NO_ID | NO_WAIT);
 1.1  jonathan 	write_ID(adder, SRC1_OCR_B, EXT_NONE | INT_SOURCE | NO_ID | WAIT);
 1.1  jonathan 	write_ID(adder, SRC2_OCR_B, EXT_NONE | INT_M1_M2  | NO_ID | NO_WAIT);
 1.1  jonathan 	write_ID(adder, DST_OCR_B, EXT_NONE | INT_NONE | NO_ID | NO_WAIT);
 1.1  jonathan 	/*
 1.1  jonathan 	* init Logic Unit Function registers, (these are just common values,
 1.1  jonathan 	* and may be changed as required).
 1.1  jonathan 	*/
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R1, FULL_SRC_RESOLUTION | LF_SOURCE);
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R2, FULL_SRC_RESOLUTION | LF_SOURCE |
 1.1  jonathan 		 INV_M1_M2);
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R3, FULL_SRC_RESOLUTION | LF_D_OR_S);
 1.1  jonathan 	write_ID(adder, LU_FUNCTION_R4, FULL_SRC_RESOLUTION | LF_D_XOR_S);
 1.1  jonathan 	/*
 1.1  jonathan 	* load the color map for black & white
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 0, adder->status = 0; i < 10000 && !(adder->status&VSYNC); ++i)
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	if (i == 0)
 1.4  christos 		printf("qd%d: setup_dragon: timeout on VSYNC\n", unit);
 1.1  jonathan
 1.1  jonathan 	red = (short *) qdmap[unit].red;
 1.1  jonathan 	green = (short *) qdmap[unit].green;
 1.1  jonathan 	blue = (short *) qdmap[unit].blue;
 1.1  jonathan
 1.1  jonathan 	*red++ = 0x00;			/* black */
 1.1  jonathan 	*green++ = 0x00;
 1.1  jonathan 	*blue++ = 0x00;
 1.1  jonathan
 1.1  jonathan 	*red-- = 0xFF;			/* white */
 1.1  jonathan 	*green-- = 0xFF;
 1.1  jonathan 	*blue-- = 0xFF;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* set color map for mouse cursor
 1.1  jonathan 	*/
 1.1  jonathan
 1.1  jonathan 	red += 254;
 1.1  jonathan 	green += 254;
 1.1  jonathan 	blue += 254;
 1.1  jonathan
 1.1  jonathan 	*red++ = 0x00;			/* black */
 1.1  jonathan 	*green++ = 0x00;
 1.1  jonathan 	*blue++ = 0x00;
 1.1  jonathan
 1.1  jonathan 	*red = 0xFF;			/* white */
 1.1  jonathan 	*green = 0xFF;
 1.1  jonathan 	*blue = 0xFF;
 1.1  jonathan
 1.1  jonathan } /* setup_dragon */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * Init the DUART and set defaults in input
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan setup_input(unit)
 1.1  jonathan 	int unit;
 1.1  jonathan {
 1.5     ragge 	volatile register struct duart *duart;	/* DUART register structure pointer */
 1.9     ragge 	register int i, bits;
 1.1  jonathan 	char id_byte;
 1.1  jonathan
 1.1  jonathan 	duart = (struct duart *) qdmap[unit].duart;
 1.1  jonathan 	duart->imask = 0;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* setup the DUART for kbd & pointing device
 1.1  jonathan 	*/
 1.1  jonathan 	duart->cmdA = RESET_M;	/* reset mode reg ptr for kbd */
 1.1  jonathan 	duart->modeA = 0x13;	/* 8 bits, no parity, rcv IE, */
 1.1  jonathan 				/* no RTS control,char error mode */
 1.1  jonathan 	duart->modeA = 0x07;	/* 1 stop bit,CTS does not IE XMT */
 1.1  jonathan 				/* no RTS control,no echo or loop */
 1.1  jonathan 	duart->cmdB = RESET_M;	/* reset mode reg pntr for host */
 1.1  jonathan 	duart->modeB = 0x07;	/* 8 bits, odd parity, rcv IE.. */
 1.1  jonathan 				/* ..no RTS cntrl, char error mode */
 1.1  jonathan 	duart->modeB = 0x07;	/* 1 stop bit,CTS does not IE XMT */
 1.1  jonathan 				/* no RTS control,no echo or loop */
 1.1  jonathan 	duart->auxctl = 0x00;	/* baud rate set 1 */
 1.1  jonathan 	duart->clkselA = 0x99;	/* 4800 baud for kbd */
 1.1  jonathan 	duart->clkselB = 0x99;	/* 4800 baud for mouse */
 1.1  jonathan
 1.1  jonathan 	/* reset everything for keyboard */
 1.1  jonathan
 1.1  jonathan 	for (bits = RESET_M; bits < START_BREAK; bits += 0x10)
 1.1  jonathan 		duart->cmdA = bits;
 1.1  jonathan
 1.1  jonathan 	/* reset everything for host */
 1.1  jonathan
 1.1  jonathan 	for (bits = RESET_M; bits < START_BREAK; bits += 0x10)
 1.1  jonathan 		duart->cmdB = bits;
 1.1  jonathan
 1.1  jonathan 	duart->cmdA = EN_RCV | EN_XMT; /* enbl xmt & rcv for kbd */
 1.1  jonathan 	duart->cmdB = EN_RCV | EN_XMT; /* enbl xmt & rcv for pointer device */
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* init keyboard defaults (DUART channel A)
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 500; i > 0; --i) {
 1.1  jonathan 		if (duart->statusA&XMT_RDY) {
 1.1  jonathan 			duart->dataA = LK_DEFAULTS;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	for (i = 100000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusA&RCV_RDY) {
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (duart->dataA)	/* flush the ACK */
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* identify the pointing device
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 500; i > 0; --i) {
 1.1  jonathan 		if (duart->statusB&XMT_RDY) {
 1.1  jonathan 			duart->dataB = SELF_TEST;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* wait for 1st byte of self test report */
 1.1  jonathan
 1.1  jonathan 	for (i = 100000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusB&RCV_RDY) {
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (i == 0) {
 1.4  christos 		printf("qd[%d]: setup_input: timeout on 1st byte of self test\n"
 1.1  jonathan 		       ,unit);
 1.1  jonathan 		goto OUT;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (duart->dataB)
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* wait for ID byte of self test report
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 100000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusB&RCV_RDY) {
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	if (i == 0) {
 1.4  christos 		printf("qd[%d]: setup_input: timeout on 2nd byte of self test\n", unit);
 1.1  jonathan 		goto OUT;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	id_byte = duart->dataB;
 1.1  jonathan
 1.1  jonathan 	/*
 1.1  jonathan 	* wait for other bytes to come in
 1.1  jonathan 	*/
 1.1  jonathan 	for (i = 100000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusB & RCV_RDY) {
 1.1  jonathan 			if (duart->dataB)
 1.1  jonathan 				;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan 	if (i == 0) {
 1.4  christos 		printf("qd[%d]: setup_input: timeout on 3rd byte of self test\n", unit);
 1.1  jonathan 		goto OUT;
 1.1  jonathan 	}
 1.1  jonathan 	for (i = 100000; i > 0; --i) {
 1.1  jonathan 		if (duart->statusB&RCV_RDY) {
 1.1  jonathan 			if (duart->dataB)
 1.1  jonathan 				;
 1.1  jonathan 			break;
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan 	if (i == 0) {
 1.4  christos 		printf("qd[%d]: setup_input: timeout on 4th byte of self test\n", unit);
 1.1  jonathan 		goto OUT;
 1.1  jonathan 	}
 1.1  jonathan 	/*
 1.1  jonathan 	* flag pointing device type and set defaults
 1.1  jonathan 	*/
 1.1  jonathan 	for (i=100000; i>0; --i)
 1.1  jonathan 		;		/*XXX*/
 1.1  jonathan
 1.1  jonathan 	if ((id_byte & 0x0F) != TABLET_ID) {
 1.1  jonathan 		qdflags[unit].pntr_id = MOUSE_ID;
 1.1  jonathan
 1.1  jonathan 		for (i = 500; i > 0; --i) {
 1.1  jonathan 			if (duart->statusB&XMT_RDY) {
 1.1  jonathan 				duart->dataB = INC_STREAM_MODE;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan 	else {
 1.1  jonathan 		qdflags[unit].pntr_id = TABLET_ID;
 1.1  jonathan
 1.1  jonathan 		for (i = 500; i > 0; --i) {
 1.1  jonathan 			if (duart->statusB&XMT_RDY) {
 1.1  jonathan 				duart->dataB = T_STREAM;
 1.1  jonathan 				break;
 1.1  jonathan 			}
 1.1  jonathan 		}
 1.1  jonathan 	}
 1.1  jonathan OUT:
 1.1  jonathan 	duart->imask = qdflags[unit].duart_imask;
 1.1  jonathan
 1.1  jonathan } /* setup_input */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * delay for at least one display frame time
 1.1  jonathan  *
 1.1  jonathan  *	return: BAD means that we timed out without ever seeing the
 1.1  jonathan  *		      vertical sync status bit
 1.1  jonathan  *		GOOD otherwise
 1.1  jonathan  */
 1.6     ragge int
 1.1  jonathan wait_status(adder, mask)
 1.5     ragge 	volatile struct adder *adder;
1.13     ragge 	int mask;
 1.1  jonathan {
 1.9     ragge 	register int i;
 1.1  jonathan
 1.1  jonathan 	for (i = 10000, adder->status = 0 ; i > 0  &&
 1.1  jonathan 	     !(adder->status&mask) ; --i)
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	if (i == 0) {
 1.4  christos 		printf("wait_status: timeout polling for 0x%x in adder->status\n", mask);
 1.1  jonathan 		return(BAD);
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan 	return(GOOD);
 1.1  jonathan
 1.1  jonathan } /* wait_status */
 1.1  jonathan
 1.1  jonathan /*
 1.1  jonathan  * write out onto the ID bus
 1.1  jonathan  */
 1.6     ragge void
 1.1  jonathan write_ID(adder, adrs, data)
1.13     ragge 	volatile struct adder *adder;
 1.5     ragge 	short adrs;
 1.5     ragge 	short data;
 1.1  jonathan {
 1.9     ragge 	register int i;
 1.1  jonathan
 1.1  jonathan 	for (i = 100000, adder->status = 0 ;
 1.1  jonathan 	      i > 0  &&  !(adder->status&ADDRESS_COMPLETE) ; --i)
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	if (i == 0)
 1.1  jonathan 		goto ERR;
 1.1  jonathan
 1.1  jonathan 	for (i = 100000, adder->status = 0 ;
 1.1  jonathan 	      i > 0  &&  !(adder->status&TX_READY) ; --i)
 1.1  jonathan 		;
 1.1  jonathan
 1.1  jonathan 	if (i > 0) {
 1.1  jonathan 		adder->id_data = data;
 1.1  jonathan 		adder->command = ID_LOAD | adrs;
 1.1  jonathan 		return ;
 1.1  jonathan 	}
 1.1  jonathan
 1.1  jonathan ERR:
 1.4  christos 	printf("write_ID: timeout trying to write to VIPER\n");
 1.1  jonathan 	return ;
 1.1  jonathan
 1.1  jonathan } /* write_ID */