hw/display/tc6393xb.c - qemu - Git at Google

 /*
  * Toshiba TC6393XB I/O Controller.
  * Found in Sharp Zaurus SL-6000 (tosa) or some
  * Toshiba e-Series PDAs.
  *
  * Most features are currently unsupported!!!
  *
  * This code is licensed under the GNU GPL v2.
  *
  * Contributions after 2012-01-13 are licensed under the terms of the
  * GNU GPL, version 2 or (at your option) any later version.
  */

 #include "qemu/osdep.h"
 #include "qapi/error.h"
 #include "qemu/host-utils.h"
 #include "hw/irq.h"
 #include "hw/display/tc6393xb.h"
 #include "exec/memory.h"
 #include "hw/block/flash.h"
 #include "ui/console.h"
 #include "ui/pixel_ops.h"
 #include "sysemu/blockdev.h"

 #define IRQ_TC6393_NAND		0
 #define IRQ_TC6393_MMC		1
 #define IRQ_TC6393_OHCI		2
 #define IRQ_TC6393_SERIAL	3
 #define IRQ_TC6393_FB		4

 #define	TC6393XB_NR_IRQS	8

 #define TC6393XB_GPIOS  16

 #define SCR_REVID	0x08		/* b Revision ID	*/
 #define SCR_ISR		0x50		/* b Interrupt Status	*/
 #define SCR_IMR		0x52		/* b Interrupt Mask	*/
 #define SCR_IRR		0x54		/* b Interrupt Routing	*/
 #define SCR_GPER	0x60		/* w GP Enable		*/
 #define SCR_GPI_SR(i)	(0x64 + (i))	/* b3 GPI Status	*/
 #define SCR_GPI_IMR(i)	(0x68 + (i))	/* b3 GPI INT Mask	*/
 #define SCR_GPI_EDER(i)	(0x6c + (i))	/* b3 GPI Edge Detect Enable */
 #define SCR_GPI_LIR(i)	(0x70 + (i))	/* b3 GPI Level Invert	*/
 #define SCR_GPO_DSR(i)	(0x78 + (i))	/* b3 GPO Data Set	*/
 #define SCR_GPO_DOECR(i) (0x7c + (i))	/* b3 GPO Data OE Control */
 #define SCR_GP_IARCR(i)	(0x80 + (i))	/* b3 GP Internal Active Register Control */
 #define SCR_GP_IARLCR(i) (0x84 + (i))	/* b3 GP INTERNAL Active Register Level Control */
 #define SCR_GPI_BCR(i)	(0x88 + (i))	/* b3 GPI Buffer Control */
 #define SCR_GPA_IARCR	0x8c		/* w GPa Internal Active Register Control */
 #define SCR_GPA_IARLCR	0x90		/* w GPa Internal Active Register Level Control */
 #define SCR_GPA_BCR	0x94		/* w GPa Buffer Control */
 #define SCR_CCR		0x98		/* w Clock Control	*/
 #define SCR_PLL2CR	0x9a		/* w PLL2 Control	*/
 #define SCR_PLL1CR	0x9c		/* l PLL1 Control	*/
 #define SCR_DIARCR	0xa0		/* b Device Internal Active Register Control */
 #define SCR_DBOCR	0xa1		/* b Device Buffer Off Control */
 #define SCR_FER		0xe0		/* b Function Enable	*/
 #define SCR_MCR		0xe4		/* w Mode Control	*/
 #define SCR_CONFIG	0xfc		/* b Configuration Control */
 #define SCR_DEBUG	0xff		/* b Debug		*/

 #define NAND_CFG_COMMAND    0x04    /* w Command        */
 #define NAND_CFG_BASE       0x10    /* l Control Base Address */
 #define NAND_CFG_INTP       0x3d    /* b Interrupt Pin  */
 #define NAND_CFG_INTE       0x48    /* b Int Enable     */
 #define NAND_CFG_EC         0x4a    /* b Event Control  */
 #define NAND_CFG_ICC        0x4c    /* b Internal Clock Control */
 #define NAND_CFG_ECCC       0x5b    /* b ECC Control    */
 #define NAND_CFG_NFTC       0x60    /* b NAND Flash Transaction Control */
 #define NAND_CFG_NFM        0x61    /* b NAND Flash Monitor */
 #define NAND_CFG_NFPSC      0x62    /* b NAND Flash Power Supply Control */
 #define NAND_CFG_NFDC       0x63    /* b NAND Flash Detect Control */

 #define NAND_DATA   0x00        /* l Data       */
 #define NAND_MODE   0x04        /* b Mode       */
 #define NAND_STATUS 0x05        /* b Status     */
 #define NAND_ISR    0x06        /* b Interrupt Status */
 #define NAND_IMR    0x07        /* b Interrupt Mask */

 #define NAND_MODE_WP        0x80
 #define NAND_MODE_CE        0x10
 #define NAND_MODE_ALE       0x02
 #define NAND_MODE_CLE       0x01
 #define NAND_MODE_ECC_MASK  0x60
 #define NAND_MODE_ECC_EN    0x20
 #define NAND_MODE_ECC_READ  0x40
 #define NAND_MODE_ECC_RST   0x60

 struct TC6393xbState {
     MemoryRegion iomem;
     qemu_irq irq;
     qemu_irq *sub_irqs;
     struct {
         uint8_t ISR;
         uint8_t IMR;
         uint8_t IRR;
         uint16_t GPER;
         uint8_t GPI_SR[3];
         uint8_t GPI_IMR[3];
         uint8_t GPI_EDER[3];
         uint8_t GPI_LIR[3];
         uint8_t GP_IARCR[3];
         uint8_t GP_IARLCR[3];
         uint8_t GPI_BCR[3];
         uint16_t GPA_IARCR;
         uint16_t GPA_IARLCR;
         uint16_t CCR;
         uint16_t PLL2CR;
         uint32_t PLL1CR;
         uint8_t DIARCR;
         uint8_t DBOCR;
         uint8_t FER;
         uint16_t MCR;
         uint8_t CONFIG;
         uint8_t DEBUG;
     } scr;
     uint32_t gpio_dir;
     uint32_t gpio_level;
     uint32_t prev_level;
     qemu_irq handler[TC6393XB_GPIOS];
     qemu_irq *gpio_in;

     struct {
         uint8_t mode;
         uint8_t isr;
         uint8_t imr;
     } nand;
     int nand_enable;
     uint32_t nand_phys;
     DeviceState *flash;
     ECCState ecc;

     QemuConsole *con;
     MemoryRegion vram;
     uint16_t *vram_ptr;
     uint32_t scr_width, scr_height; /* in pixels */
     qemu_irq l3v;
     unsigned blank : 1,
              blanked : 1;
 };

 static void tc6393xb_gpio_set(void *opaque, int line, int level)
 {
 //    TC6393xbState *s = opaque;

     if (line > TC6393XB_GPIOS) {
         printf("%s: No GPIO pin %i\n", __func__, line);
         return;
     }

     // FIXME: how does the chip reflect the GPIO input level change?
 }

 static void tc6393xb_gpio_handler_update(TC6393xbState *s)
 {
     uint32_t level, diff;
     int bit;

     level = s->gpio_level & s->gpio_dir;
     level &= MAKE_64BIT_MASK(0, TC6393XB_GPIOS);

     for (diff = s->prev_level ^ level; diff; diff ^= 1 << bit) {
         bit = ctz32(diff);
         qemu_set_irq(s->handler[bit], (level >> bit) & 1);
     }

     s->prev_level = level;
 }

 qemu_irq tc6393xb_l3v_get(TC6393xbState *s)
 {
     return s->l3v;
 }

 static void tc6393xb_l3v(void *opaque, int line, int level)
 {
     TC6393xbState *s = opaque;
     s->blank = !level;
     fprintf(stderr, "L3V: %d\n", level);
 }

 static void tc6393xb_sub_irq(void *opaque, int line, int level) {
     TC6393xbState *s = opaque;
     uint8_t isr = s->scr.ISR;
     if (level)
         isr |= 1 << line;
     else
         isr &= ~(1 << line);
     s->scr.ISR = isr;
     qemu_set_irq(s->irq, isr & s->scr.IMR);
 }

 #define SCR_REG_B(N)                            \
     case SCR_ ##N: return s->scr.N
 #define SCR_REG_W(N)                            \
     case SCR_ ##N: return s->scr.N;             \
     case SCR_ ##N + 1: return s->scr.N >> 8;
 #define SCR_REG_L(N)                            \
     case SCR_ ##N: return s->scr.N;             \
     case SCR_ ##N + 1: return s->scr.N >> 8;    \
     case SCR_ ##N + 2: return s->scr.N >> 16;   \
     case SCR_ ##N + 3: return s->scr.N >> 24;
 #define SCR_REG_A(N)                            \
     case SCR_ ##N(0): return s->scr.N[0];       \
     case SCR_ ##N(1): return s->scr.N[1];       \
     case SCR_ ##N(2): return s->scr.N[2]

 static uint32_t tc6393xb_scr_readb(TC6393xbState *s, hwaddr addr)
 {
     switch (addr) {
         case SCR_REVID:
             return 3;
         case SCR_REVID+1:
             return 0;
         SCR_REG_B(ISR);
         SCR_REG_B(IMR);
         SCR_REG_B(IRR);
         SCR_REG_W(GPER);
         SCR_REG_A(GPI_SR);
         SCR_REG_A(GPI_IMR);
         SCR_REG_A(GPI_EDER);
         SCR_REG_A(GPI_LIR);
         case SCR_GPO_DSR(0):
         case SCR_GPO_DSR(1):
         case SCR_GPO_DSR(2):
             return (s->gpio_level >> ((addr - SCR_GPO_DSR(0)) * 8)) & 0xff;
         case SCR_GPO_DOECR(0):
         case SCR_GPO_DOECR(1):
         case SCR_GPO_DOECR(2):
             return (s->gpio_dir >> ((addr - SCR_GPO_DOECR(0)) * 8)) & 0xff;
         SCR_REG_A(GP_IARCR);
         SCR_REG_A(GP_IARLCR);
         SCR_REG_A(GPI_BCR);
         SCR_REG_W(GPA_IARCR);
         SCR_REG_W(GPA_IARLCR);
         SCR_REG_W(CCR);
         SCR_REG_W(PLL2CR);
         SCR_REG_L(PLL1CR);
         SCR_REG_B(DIARCR);
         SCR_REG_B(DBOCR);
         SCR_REG_B(FER);
         SCR_REG_W(MCR);
         SCR_REG_B(CONFIG);
         SCR_REG_B(DEBUG);
     }
     fprintf(stderr, "tc6393xb_scr: unhandled read at %08x\n", (uint32_t) addr);
     return 0;
 }
 #undef SCR_REG_B
 #undef SCR_REG_W
 #undef SCR_REG_L
 #undef SCR_REG_A

 #define SCR_REG_B(N)                                \
     case SCR_ ##N: s->scr.N = value; return;
 #define SCR_REG_W(N)                                \
     case SCR_ ##N: s->scr.N = (s->scr.N & ~0xff) | (value & 0xff); return; \
     case SCR_ ##N + 1: s->scr.N = (s->scr.N & 0xff) | (value << 8); return
 #define SCR_REG_L(N)                                \
     case SCR_ ##N: s->scr.N = (s->scr.N & ~0xff) | (value & 0xff); return;   \
     case SCR_ ##N + 1: s->scr.N = (s->scr.N & ~(0xff << 8)) | (value & (0xff << 8)); return;     \
     case SCR_ ##N + 2: s->scr.N = (s->scr.N & ~(0xff << 16)) | (value & (0xff << 16)); return;   \
     case SCR_ ##N + 3: s->scr.N = (s->scr.N & ~(0xff << 24)) | (value & (0xff << 24)); return;
 #define SCR_REG_A(N)                                \
     case SCR_ ##N(0): s->scr.N[0] = value; return;   \
     case SCR_ ##N(1): s->scr.N[1] = value; return;   \
     case SCR_ ##N(2): s->scr.N[2] = value; return

 static void tc6393xb_scr_writeb(TC6393xbState *s, hwaddr addr, uint32_t value)
 {
     switch (addr) {
         SCR_REG_B(ISR);
         SCR_REG_B(IMR);
         SCR_REG_B(IRR);
         SCR_REG_W(GPER);
         SCR_REG_A(GPI_SR);
         SCR_REG_A(GPI_IMR);
         SCR_REG_A(GPI_EDER);
         SCR_REG_A(GPI_LIR);
         case SCR_GPO_DSR(0):
         case SCR_GPO_DSR(1):
         case SCR_GPO_DSR(2):
             s->gpio_level = (s->gpio_level & ~(0xff << ((addr - SCR_GPO_DSR(0))*8))) | ((value & 0xff) << ((addr - SCR_GPO_DSR(0))*8));
             tc6393xb_gpio_handler_update(s);
             return;
         case SCR_GPO_DOECR(0):
         case SCR_GPO_DOECR(1):
         case SCR_GPO_DOECR(2):
             s->gpio_dir = (s->gpio_dir & ~(0xff << ((addr - SCR_GPO_DOECR(0))*8))) | ((value & 0xff) << ((addr - SCR_GPO_DOECR(0))*8));
             tc6393xb_gpio_handler_update(s);
             return;
         SCR_REG_A(GP_IARCR);
         SCR_REG_A(GP_IARLCR);
         SCR_REG_A(GPI_BCR);
         SCR_REG_W(GPA_IARCR);
         SCR_REG_W(GPA_IARLCR);
         SCR_REG_W(CCR);
         SCR_REG_W(PLL2CR);
         SCR_REG_L(PLL1CR);
         SCR_REG_B(DIARCR);
         SCR_REG_B(DBOCR);
         SCR_REG_B(FER);
         SCR_REG_W(MCR);
         SCR_REG_B(CONFIG);
         SCR_REG_B(DEBUG);
     }
     fprintf(stderr, "tc6393xb_scr: unhandled write at %08x: %02x\n",
                                         (uint32_t) addr, value & 0xff);
 }
 #undef SCR_REG_B
 #undef SCR_REG_W
 #undef SCR_REG_L
 #undef SCR_REG_A

 static void tc6393xb_nand_irq(TC6393xbState *s) {
     qemu_set_irq(s->sub_irqs[IRQ_TC6393_NAND],
             (s->nand.imr & 0x80) && (s->nand.imr & s->nand.isr));
 }

 static uint32_t tc6393xb_nand_cfg_readb(TC6393xbState *s, hwaddr addr) {
     switch (addr) {
         case NAND_CFG_COMMAND:
             return s->nand_enable ? 2 : 0;
         case NAND_CFG_BASE:
         case NAND_CFG_BASE + 1:
         case NAND_CFG_BASE + 2:
         case NAND_CFG_BASE + 3:
             return s->nand_phys >> (addr - NAND_CFG_BASE);
     }
     fprintf(stderr, "tc6393xb_nand_cfg: unhandled read at %08x\n", (uint32_t) addr);
     return 0;
 }
 static void tc6393xb_nand_cfg_writeb(TC6393xbState *s, hwaddr addr, uint32_t value) {
     switch (addr) {
         case NAND_CFG_COMMAND:
             s->nand_enable = (value & 0x2);
             return;
         case NAND_CFG_BASE:
         case NAND_CFG_BASE + 1:
         case NAND_CFG_BASE + 2:
         case NAND_CFG_BASE + 3:
             s->nand_phys &= ~(0xff << ((addr - NAND_CFG_BASE) * 8));
             s->nand_phys |= (value & 0xff) << ((addr - NAND_CFG_BASE) * 8);
             return;
     }
     fprintf(stderr, "tc6393xb_nand_cfg: unhandled write at %08x: %02x\n",
                                         (uint32_t) addr, value & 0xff);
 }

 static uint32_t tc6393xb_nand_readb(TC6393xbState *s, hwaddr addr) {
     switch (addr) {
         case NAND_DATA + 0:
         case NAND_DATA + 1:
         case NAND_DATA + 2:
         case NAND_DATA + 3:
             return nand_getio(s->flash);
         case NAND_MODE:
             return s->nand.mode;
         case NAND_STATUS:
             return 0x14;
         case NAND_ISR:
             return s->nand.isr;
         case NAND_IMR:
             return s->nand.imr;
     }
     fprintf(stderr, "tc6393xb_nand: unhandled read at %08x\n", (uint32_t) addr);
     return 0;
 }
 static void tc6393xb_nand_writeb(TC6393xbState *s, hwaddr addr, uint32_t value) {
 //    fprintf(stderr, "tc6393xb_nand: write at %08x: %02x\n",
 //					(uint32_t) addr, value & 0xff);
     switch (addr) {
         case NAND_DATA + 0:
         case NAND_DATA + 1:
         case NAND_DATA + 2:
         case NAND_DATA + 3:
             nand_setio(s->flash, value);
             s->nand.isr |= 1;
             tc6393xb_nand_irq(s);
             return;
         case NAND_MODE:
             s->nand.mode = value;
             nand_setpins(s->flash,
                     value & NAND_MODE_CLE,
                     value & NAND_MODE_ALE,
                     !(value & NAND_MODE_CE),
                     value & NAND_MODE_WP,
                     0); // FIXME: gnd
             switch (value & NAND_MODE_ECC_MASK) {
                 case NAND_MODE_ECC_RST:
                     ecc_reset(&s->ecc);
                     break;
                 case NAND_MODE_ECC_READ:
                     // FIXME
                     break;
                 case NAND_MODE_ECC_EN:
                     ecc_reset(&s->ecc);
             }
             return;
         case NAND_ISR:
             s->nand.isr = value;
             tc6393xb_nand_irq(s);
             return;
         case NAND_IMR:
             s->nand.imr = value;
             tc6393xb_nand_irq(s);
             return;
     }
     fprintf(stderr, "tc6393xb_nand: unhandled write at %08x: %02x\n",
                                         (uint32_t) addr, value & 0xff);
 }

 static void tc6393xb_draw_graphic(TC6393xbState *s, int full_update)
 {
     DisplaySurface *surface = qemu_console_surface(s->con);
     int i;
     uint16_t *data_buffer;
     uint8_t *data_display;

     data_buffer = s->vram_ptr;
     data_display = surface_data(surface);
     for (i = 0; i < s->scr_height; i++) {
         int j;
         for (j = 0; j < s->scr_width; j++, data_display += 4, data_buffer++) {
             uint16_t color = *data_buffer;
             uint32_t dest_color = rgb_to_pixel32(
                            ((color & 0xf800) * 0x108) >> 11,
                            ((color & 0x7e0) * 0x41) >> 9,
                            ((color & 0x1f) * 0x21) >> 2
                            );
             *(uint32_t *)data_display = dest_color;
         }
     }
     dpy_gfx_update_full(s->con);
 }

 static void tc6393xb_draw_blank(TC6393xbState *s, int full_update)
 {
     DisplaySurface *surface = qemu_console_surface(s->con);
     int i, w;
     uint8_t *d;

     if (!full_update)
         return;

     w = s->scr_width * surface_bytes_per_pixel(surface);
     d = surface_data(surface);
     for(i = 0; i < s->scr_height; i++) {
         memset(d, 0, w);
         d += surface_stride(surface);
     }

     dpy_gfx_update_full(s->con);
 }

 static void tc6393xb_update_display(void *opaque)
 {
     TC6393xbState *s = opaque;
     DisplaySurface *surface = qemu_console_surface(s->con);
     int full_update;

     if (s->scr_width == 0 || s->scr_height == 0)
         return;

     full_update = 0;
     if (s->blanked != s->blank) {
         s->blanked = s->blank;
         full_update = 1;
     }
     if (s->scr_width != surface_width(surface) ||
         s->scr_height != surface_height(surface)) {
         qemu_console_resize(s->con, s->scr_width, s->scr_height);
         full_update = 1;
     }
     if (s->blanked)
         tc6393xb_draw_blank(s, full_update);
     else
         tc6393xb_draw_graphic(s, full_update);
 }


 static uint64_t tc6393xb_readb(void *opaque, hwaddr addr,
                                unsigned size)
 {
     TC6393xbState *s = opaque;

     switch (addr >> 8) {
         case 0:
             return tc6393xb_scr_readb(s, addr & 0xff);
         case 1:
             return tc6393xb_nand_cfg_readb(s, addr & 0xff);
     };

     if ((addr &~0xff) == s->nand_phys && s->nand_enable) {
 //        return tc6393xb_nand_readb(s, addr & 0xff);
         uint8_t d = tc6393xb_nand_readb(s, addr & 0xff);
 //        fprintf(stderr, "tc6393xb_nand: read at %08x: %02hhx\n", (uint32_t) addr, d);
         return d;
     }

 //    fprintf(stderr, "tc6393xb: unhandled read at %08x\n", (uint32_t) addr);
     return 0;
 }

 static void tc6393xb_writeb(void *opaque, hwaddr addr,
                             uint64_t value, unsigned size) {
     TC6393xbState *s = opaque;

     switch (addr >> 8) {
         case 0:
             tc6393xb_scr_writeb(s, addr & 0xff, value);
             return;
         case 1:
             tc6393xb_nand_cfg_writeb(s, addr & 0xff, value);
             return;
     };

     if ((addr &~0xff) == s->nand_phys && s->nand_enable)
         tc6393xb_nand_writeb(s, addr & 0xff, value);
     else
         fprintf(stderr, "tc6393xb: unhandled write at %08x: %02x\n",
                 (uint32_t) addr, (int)value & 0xff);
 }

 static const GraphicHwOps tc6393xb_gfx_ops = {
     .gfx_update  = tc6393xb_update_display,
 };

 TC6393xbState *tc6393xb_init(MemoryRegion *sysmem, uint32_t base, qemu_irq irq)
 {
     TC6393xbState *s;
     DriveInfo *nand;
     static const MemoryRegionOps tc6393xb_ops = {
         .read = tc6393xb_readb,
         .write = tc6393xb_writeb,
         .endianness = DEVICE_NATIVE_ENDIAN,
         .impl = {
             .min_access_size = 1,
             .max_access_size = 1,
         },
     };

     s = g_new0(TC6393xbState, 1);
     s->irq = irq;
     s->gpio_in = qemu_allocate_irqs(tc6393xb_gpio_set, s, TC6393XB_GPIOS);

     s->l3v = qemu_allocate_irq(tc6393xb_l3v, s, 0);
     s->blanked = 1;

     s->sub_irqs = qemu_allocate_irqs(tc6393xb_sub_irq, s, TC6393XB_NR_IRQS);

     nand = drive_get(IF_MTD, 0, 0);
     s->flash = nand_init(nand ? blk_by_legacy_dinfo(nand) : NULL,
                          NAND_MFR_TOSHIBA, 0x76);

     memory_region_init_io(&s->iomem, NULL, &tc6393xb_ops, s, "tc6393xb", 0x10000);
     memory_region_add_subregion(sysmem, base, &s->iomem);

     memory_region_init_ram(&s->vram, NULL, "tc6393xb.vram", 0x100000,
                            &error_fatal);
     s->vram_ptr = memory_region_get_ram_ptr(&s->vram);
     memory_region_add_subregion(sysmem, base + 0x100000, &s->vram);
     s->scr_width = 480;
     s->scr_height = 640;
     s->con = graphic_console_init(NULL, 0, &tc6393xb_gfx_ops, s);

     return s;
 }
	/*
	* Toshiba TC6393XB I/O Controller.
	* Found in Sharp Zaurus SL-6000 (tosa) or some
	* Toshiba e-Series PDAs.
	*
	* Most features are currently unsupported!!!
	*
	* This code is licensed under the GNU GPL v2.
	*
	* Contributions after 2012-01-13 are licensed under the terms of the
	* GNU GPL, version 2 or (at your option) any later version.
	*/

	#include "qemu/osdep.h"
	#include "qapi/error.h"
	#include "qemu/host-utils.h"
	#include "hw/irq.h"
	#include "hw/display/tc6393xb.h"
	#include "exec/memory.h"
	#include "hw/block/flash.h"
	#include "ui/console.h"
	#include "ui/pixel_ops.h"
	#include "sysemu/blockdev.h"

	#define IRQ_TC6393_NAND 0
	#define IRQ_TC6393_MMC 1
	#define IRQ_TC6393_OHCI 2
	#define IRQ_TC6393_SERIAL 3
	#define IRQ_TC6393_FB 4

	#define TC6393XB_NR_IRQS 8

	#define TC6393XB_GPIOS 16

	#define SCR_REVID 0x08 /* b Revision ID */
	#define SCR_ISR 0x50 /* b Interrupt Status */
	#define SCR_IMR 0x52 /* b Interrupt Mask */
	#define SCR_IRR 0x54 /* b Interrupt Routing */
	#define SCR_GPER 0x60 /* w GP Enable */
	#define SCR_GPI_SR(i) (0x64 + (i)) /* b3 GPI Status */
	#define SCR_GPI_IMR(i) (0x68 + (i)) /* b3 GPI INT Mask */
	#define SCR_GPI_EDER(i) (0x6c + (i)) /* b3 GPI Edge Detect Enable */
	#define SCR_GPI_LIR(i) (0x70 + (i)) /* b3 GPI Level Invert */
	#define SCR_GPO_DSR(i) (0x78 + (i)) /* b3 GPO Data Set */
	#define SCR_GPO_DOECR(i) (0x7c + (i)) /* b3 GPO Data OE Control */
	#define SCR_GP_IARCR(i) (0x80 + (i)) /* b3 GP Internal Active Register Control */
	#define SCR_GP_IARLCR(i) (0x84 + (i)) /* b3 GP INTERNAL Active Register Level Control */
	#define SCR_GPI_BCR(i) (0x88 + (i)) /* b3 GPI Buffer Control */
	#define SCR_GPA_IARCR 0x8c /* w GPa Internal Active Register Control */
	#define SCR_GPA_IARLCR 0x90 /* w GPa Internal Active Register Level Control */
	#define SCR_GPA_BCR 0x94 /* w GPa Buffer Control */
	#define SCR_CCR 0x98 /* w Clock Control */
	#define SCR_PLL2CR 0x9a /* w PLL2 Control */
	#define SCR_PLL1CR 0x9c /* l PLL1 Control */
	#define SCR_DIARCR 0xa0 /* b Device Internal Active Register Control */
	#define SCR_DBOCR 0xa1 /* b Device Buffer Off Control */
	#define SCR_FER 0xe0 /* b Function Enable */
	#define SCR_MCR 0xe4 /* w Mode Control */
	#define SCR_CONFIG 0xfc /* b Configuration Control */
	#define SCR_DEBUG 0xff /* b Debug */

	#define NAND_CFG_COMMAND 0x04 /* w Command */
	#define NAND_CFG_BASE 0x10 /* l Control Base Address */
	#define NAND_CFG_INTP 0x3d /* b Interrupt Pin */
	#define NAND_CFG_INTE 0x48 /* b Int Enable */
	#define NAND_CFG_EC 0x4a /* b Event Control */
	#define NAND_CFG_ICC 0x4c /* b Internal Clock Control */
	#define NAND_CFG_ECCC 0x5b /* b ECC Control */
	#define NAND_CFG_NFTC 0x60 /* b NAND Flash Transaction Control */
	#define NAND_CFG_NFM 0x61 /* b NAND Flash Monitor */
	#define NAND_CFG_NFPSC 0x62 /* b NAND Flash Power Supply Control */
	#define NAND_CFG_NFDC 0x63 /* b NAND Flash Detect Control */

	#define NAND_DATA 0x00 /* l Data */
	#define NAND_MODE 0x04 /* b Mode */
	#define NAND_STATUS 0x05 /* b Status */
	#define NAND_ISR 0x06 /* b Interrupt Status */
	#define NAND_IMR 0x07 /* b Interrupt Mask */

	#define NAND_MODE_WP 0x80
	#define NAND_MODE_CE 0x10
	#define NAND_MODE_ALE 0x02
	#define NAND_MODE_CLE 0x01
	#define NAND_MODE_ECC_MASK 0x60
	#define NAND_MODE_ECC_EN 0x20
	#define NAND_MODE_ECC_READ 0x40
	#define NAND_MODE_ECC_RST 0x60

	struct TC6393xbState {
	MemoryRegion iomem;
	qemu_irq irq;
	qemu_irq *sub_irqs;
	struct {
	uint8_t ISR;
	uint8_t IMR;
	uint8_t IRR;
	uint16_t GPER;
	uint8_t GPI_SR[3];
	uint8_t GPI_IMR[3];
	uint8_t GPI_EDER[3];
	uint8_t GPI_LIR[3];
	uint8_t GP_IARCR[3];
	uint8_t GP_IARLCR[3];
	uint8_t GPI_BCR[3];
	uint16_t GPA_IARCR;
	uint16_t GPA_IARLCR;
	uint16_t CCR;
	uint16_t PLL2CR;
	uint32_t PLL1CR;
	uint8_t DIARCR;
	uint8_t DBOCR;
	uint8_t FER;
	uint16_t MCR;
	uint8_t CONFIG;
	uint8_t DEBUG;
	} scr;
	uint32_t gpio_dir;
	uint32_t gpio_level;
	uint32_t prev_level;
	qemu_irq handler[TC6393XB_GPIOS];
	qemu_irq *gpio_in;

	struct {
	uint8_t mode;
	uint8_t isr;
	uint8_t imr;
	} nand;
	int nand_enable;
	uint32_t nand_phys;
	DeviceState *flash;
	ECCState ecc;

	QemuConsole *con;
	MemoryRegion vram;
	uint16_t *vram_ptr;
	uint32_t scr_width, scr_height; /* in pixels */
	qemu_irq l3v;
	unsigned blank : 1,
	blanked : 1;
	};

	static void tc6393xb_gpio_set(void *opaque, int line, int level)
	{
	// TC6393xbState *s = opaque;

	if (line > TC6393XB_GPIOS) {
	printf("%s: No GPIO pin %i\n", __func__, line);
	return;
	}

	// FIXME: how does the chip reflect the GPIO input level change?
	}

	static void tc6393xb_gpio_handler_update(TC6393xbState *s)
	{
	uint32_t level, diff;
	int bit;

	level = s->gpio_level & s->gpio_dir;
	level &= MAKE_64BIT_MASK(0, TC6393XB_GPIOS);

	for (diff = s->prev_level ^ level; diff; diff ^= 1 << bit) {
	bit = ctz32(diff);
	qemu_set_irq(s->handler[bit], (level >> bit) & 1);
	}

	s->prev_level = level;
	}

	qemu_irq tc6393xb_l3v_get(TC6393xbState *s)
	{
	return s->l3v;
	}

	static void tc6393xb_l3v(void *opaque, int line, int level)
	{
	TC6393xbState *s = opaque;
	s->blank = !level;
	fprintf(stderr, "L3V: %d\n", level);
	}

	static void tc6393xb_sub_irq(void *opaque, int line, int level) {
	TC6393xbState *s = opaque;
	uint8_t isr = s->scr.ISR;
	if (level)
	isr \|= 1 << line;
	else
	isr &= ~(1 << line);
	s->scr.ISR = isr;
	qemu_set_irq(s->irq, isr & s->scr.IMR);
	}

	#define SCR_REG_B(N) \
	case SCR_ ##N: return s->scr.N
	#define SCR_REG_W(N) \
	case SCR_ ##N: return s->scr.N; \
	case SCR_ ##N + 1: return s->scr.N >> 8;
	#define SCR_REG_L(N) \
	case SCR_ ##N: return s->scr.N; \
	case SCR_ ##N + 1: return s->scr.N >> 8; \
	case SCR_ ##N + 2: return s->scr.N >> 16; \
	case SCR_ ##N + 3: return s->scr.N >> 24;
	#define SCR_REG_A(N) \
	case SCR_ ##N(0): return s->scr.N[0]; \
	case SCR_ ##N(1): return s->scr.N[1]; \
	case SCR_ ##N(2): return s->scr.N[2]

	static uint32_t tc6393xb_scr_readb(TC6393xbState *s, hwaddr addr)
	{
	switch (addr) {
	case SCR_REVID:
	return 3;
	case SCR_REVID+1:
	return 0;
	SCR_REG_B(ISR);
	SCR_REG_B(IMR);
	SCR_REG_B(IRR);
	SCR_REG_W(GPER);
	SCR_REG_A(GPI_SR);
	SCR_REG_A(GPI_IMR);
	SCR_REG_A(GPI_EDER);
	SCR_REG_A(GPI_LIR);
	case SCR_GPO_DSR(0):
	case SCR_GPO_DSR(1):
	case SCR_GPO_DSR(2):
	return (s->gpio_level >> ((addr - SCR_GPO_DSR(0)) * 8)) & 0xff;
	case SCR_GPO_DOECR(0):
	case SCR_GPO_DOECR(1):
	case SCR_GPO_DOECR(2):
	return (s->gpio_dir >> ((addr - SCR_GPO_DOECR(0)) * 8)) & 0xff;
	SCR_REG_A(GP_IARCR);
	SCR_REG_A(GP_IARLCR);
	SCR_REG_A(GPI_BCR);
	SCR_REG_W(GPA_IARCR);
	SCR_REG_W(GPA_IARLCR);
	SCR_REG_W(CCR);
	SCR_REG_W(PLL2CR);
	SCR_REG_L(PLL1CR);
	SCR_REG_B(DIARCR);
	SCR_REG_B(DBOCR);
	SCR_REG_B(FER);
	SCR_REG_W(MCR);
	SCR_REG_B(CONFIG);
	SCR_REG_B(DEBUG);
	}
	fprintf(stderr, "tc6393xb_scr: unhandled read at %08x\n", (uint32_t) addr);
	return 0;
	}
	#undef SCR_REG_B
	#undef SCR_REG_W
	#undef SCR_REG_L
	#undef SCR_REG_A

	#define SCR_REG_B(N) \
	case SCR_ ##N: s->scr.N = value; return;
	#define SCR_REG_W(N) \
	case SCR_ ##N: s->scr.N = (s->scr.N & ~0xff) \| (value & 0xff); return; \
	case SCR_ ##N + 1: s->scr.N = (s->scr.N & 0xff) \| (value << 8); return
	#define SCR_REG_L(N) \
	case SCR_ ##N: s->scr.N = (s->scr.N & ~0xff) \| (value & 0xff); return; \
	case SCR_ ##N + 1: s->scr.N = (s->scr.N & ~(0xff << 8)) \| (value & (0xff << 8)); return; \
	case SCR_ ##N + 2: s->scr.N = (s->scr.N & ~(0xff << 16)) \| (value & (0xff << 16)); return; \
	case SCR_ ##N + 3: s->scr.N = (s->scr.N & ~(0xff << 24)) \| (value & (0xff << 24)); return;
	#define SCR_REG_A(N) \
	case SCR_ ##N(0): s->scr.N[0] = value; return; \
	case SCR_ ##N(1): s->scr.N[1] = value; return; \
	case SCR_ ##N(2): s->scr.N[2] = value; return

	static void tc6393xb_scr_writeb(TC6393xbState *s, hwaddr addr, uint32_t value)
	{
	switch (addr) {
	SCR_REG_B(ISR);
	SCR_REG_B(IMR);
	SCR_REG_B(IRR);
	SCR_REG_W(GPER);
	SCR_REG_A(GPI_SR);
	SCR_REG_A(GPI_IMR);
	SCR_REG_A(GPI_EDER);
	SCR_REG_A(GPI_LIR);
	case SCR_GPO_DSR(0):
	case SCR_GPO_DSR(1):
	case SCR_GPO_DSR(2):
	s->gpio_level = (s->gpio_level & ~(0xff << ((addr - SCR_GPO_DSR(0))8))) \| ((value & 0xff) << ((addr - SCR_GPO_DSR(0))8));
	tc6393xb_gpio_handler_update(s);
	return;
	case SCR_GPO_DOECR(0):
	case SCR_GPO_DOECR(1):
	case SCR_GPO_DOECR(2):
	s->gpio_dir = (s->gpio_dir & ~(0xff << ((addr - SCR_GPO_DOECR(0))8))) \| ((value & 0xff) << ((addr - SCR_GPO_DOECR(0))8));
	tc6393xb_gpio_handler_update(s);
	return;
	SCR_REG_A(GP_IARCR);
	SCR_REG_A(GP_IARLCR);
	SCR_REG_A(GPI_BCR);
	SCR_REG_W(GPA_IARCR);
	SCR_REG_W(GPA_IARLCR);
	SCR_REG_W(CCR);
	SCR_REG_W(PLL2CR);
	SCR_REG_L(PLL1CR);
	SCR_REG_B(DIARCR);
	SCR_REG_B(DBOCR);
	SCR_REG_B(FER);
	SCR_REG_W(MCR);
	SCR_REG_B(CONFIG);
	SCR_REG_B(DEBUG);
	}
	fprintf(stderr, "tc6393xb_scr: unhandled write at %08x: %02x\n",
	(uint32_t) addr, value & 0xff);
	}
	#undef SCR_REG_B
	#undef SCR_REG_W
	#undef SCR_REG_L
	#undef SCR_REG_A

	static void tc6393xb_nand_irq(TC6393xbState *s) {
	qemu_set_irq(s->sub_irqs[IRQ_TC6393_NAND],
	(s->nand.imr & 0x80) && (s->nand.imr & s->nand.isr));
	}

	static uint32_t tc6393xb_nand_cfg_readb(TC6393xbState *s, hwaddr addr) {
	switch (addr) {
	case NAND_CFG_COMMAND:
	return s->nand_enable ? 2 : 0;
	case NAND_CFG_BASE:
	case NAND_CFG_BASE + 1:
	case NAND_CFG_BASE + 2:
	case NAND_CFG_BASE + 3:
	return s->nand_phys >> (addr - NAND_CFG_BASE);
	}
	fprintf(stderr, "tc6393xb_nand_cfg: unhandled read at %08x\n", (uint32_t) addr);
	return 0;
	}
	static void tc6393xb_nand_cfg_writeb(TC6393xbState *s, hwaddr addr, uint32_t value) {
	switch (addr) {
	case NAND_CFG_COMMAND:
	s->nand_enable = (value & 0x2);
	return;
	case NAND_CFG_BASE:
	case NAND_CFG_BASE + 1:
	case NAND_CFG_BASE + 2:
	case NAND_CFG_BASE + 3:
	s->nand_phys &= ~(0xff << ((addr - NAND_CFG_BASE) * 8));
	s->nand_phys \|= (value & 0xff) << ((addr - NAND_CFG_BASE) * 8);
	return;
	}
	fprintf(stderr, "tc6393xb_nand_cfg: unhandled write at %08x: %02x\n",
	(uint32_t) addr, value & 0xff);
	}

	static uint32_t tc6393xb_nand_readb(TC6393xbState *s, hwaddr addr) {
	switch (addr) {
	case NAND_DATA + 0:
	case NAND_DATA + 1:
	case NAND_DATA + 2:
	case NAND_DATA + 3:
	return nand_getio(s->flash);
	case NAND_MODE:
	return s->nand.mode;
	case NAND_STATUS:
	return 0x14;
	case NAND_ISR:
	return s->nand.isr;
	case NAND_IMR:
	return s->nand.imr;
	}
	fprintf(stderr, "tc6393xb_nand: unhandled read at %08x\n", (uint32_t) addr);
	return 0;
	}
	static void tc6393xb_nand_writeb(TC6393xbState *s, hwaddr addr, uint32_t value) {
	// fprintf(stderr, "tc6393xb_nand: write at %08x: %02x\n",
	// (uint32_t) addr, value & 0xff);
	switch (addr) {
	case NAND_DATA + 0:
	case NAND_DATA + 1:
	case NAND_DATA + 2:
	case NAND_DATA + 3:
	nand_setio(s->flash, value);
	s->nand.isr \|= 1;
	tc6393xb_nand_irq(s);
	return;
	case NAND_MODE:
	s->nand.mode = value;
	nand_setpins(s->flash,
	value & NAND_MODE_CLE,
	value & NAND_MODE_ALE,
	!(value & NAND_MODE_CE),
	value & NAND_MODE_WP,
	0); // FIXME: gnd
	switch (value & NAND_MODE_ECC_MASK) {
	case NAND_MODE_ECC_RST:
	ecc_reset(&s->ecc);
	break;
	case NAND_MODE_ECC_READ:
	// FIXME
	break;
	case NAND_MODE_ECC_EN:
	ecc_reset(&s->ecc);
	}
	return;
	case NAND_ISR:
	s->nand.isr = value;
	tc6393xb_nand_irq(s);
	return;
	case NAND_IMR:
	s->nand.imr = value;
	tc6393xb_nand_irq(s);
	return;
	}
	fprintf(stderr, "tc6393xb_nand: unhandled write at %08x: %02x\n",
	(uint32_t) addr, value & 0xff);
	}

	static void tc6393xb_draw_graphic(TC6393xbState *s, int full_update)
	{
	DisplaySurface *surface = qemu_console_surface(s->con);
	int i;
	uint16_t *data_buffer;
	uint8_t *data_display;

	data_buffer = s->vram_ptr;
	data_display = surface_data(surface);
	for (i = 0; i < s->scr_height; i++) {
	int j;
	for (j = 0; j < s->scr_width; j++, data_display += 4, data_buffer++) {
	uint16_t color = *data_buffer;
	uint32_t dest_color = rgb_to_pixel32(
	((color & 0xf800) * 0x108) >> 11,
	((color & 0x7e0) * 0x41) >> 9,
	((color & 0x1f) * 0x21) >> 2
	);
	(uint32_t )data_display = dest_color;
	}
	}
	dpy_gfx_update_full(s->con);
	}

	static void tc6393xb_draw_blank(TC6393xbState *s, int full_update)
	{
	DisplaySurface *surface = qemu_console_surface(s->con);
	int i, w;
	uint8_t *d;

	if (!full_update)
	return;

	w = s->scr_width * surface_bytes_per_pixel(surface);
	d = surface_data(surface);
	for(i = 0; i < s->scr_height; i++) {
	memset(d, 0, w);
	d += surface_stride(surface);
	}

	dpy_gfx_update_full(s->con);
	}

	static void tc6393xb_update_display(void *opaque)
	{
	TC6393xbState *s = opaque;
	DisplaySurface *surface = qemu_console_surface(s->con);
	int full_update;

	if (s->scr_width == 0 \|\| s->scr_height == 0)
	return;

	full_update = 0;
	if (s->blanked != s->blank) {
	s->blanked = s->blank;
	full_update = 1;
	}
	if (s->scr_width != surface_width(surface) \|\|
	s->scr_height != surface_height(surface)) {
	qemu_console_resize(s->con, s->scr_width, s->scr_height);
	full_update = 1;
	}
	if (s->blanked)
	tc6393xb_draw_blank(s, full_update);
	else
	tc6393xb_draw_graphic(s, full_update);
	}


	static uint64_t tc6393xb_readb(void *opaque, hwaddr addr,
	unsigned size)
	{
	TC6393xbState *s = opaque;

	switch (addr >> 8) {
	case 0:
	return tc6393xb_scr_readb(s, addr & 0xff);
	case 1:
	return tc6393xb_nand_cfg_readb(s, addr & 0xff);
	};

	if ((addr &~0xff) == s->nand_phys && s->nand_enable) {
	// return tc6393xb_nand_readb(s, addr & 0xff);
	uint8_t d = tc6393xb_nand_readb(s, addr & 0xff);
	// fprintf(stderr, "tc6393xb_nand: read at %08x: %02hhx\n", (uint32_t) addr, d);
	return d;
	}

	// fprintf(stderr, "tc6393xb: unhandled read at %08x\n", (uint32_t) addr);
	return 0;
	}

	static void tc6393xb_writeb(void *opaque, hwaddr addr,
	uint64_t value, unsigned size) {
	TC6393xbState *s = opaque;

	switch (addr >> 8) {
	case 0:
	tc6393xb_scr_writeb(s, addr & 0xff, value);
	return;
	case 1:
	tc6393xb_nand_cfg_writeb(s, addr & 0xff, value);
	return;
	};

	if ((addr &~0xff) == s->nand_phys && s->nand_enable)
	tc6393xb_nand_writeb(s, addr & 0xff, value);
	else
	fprintf(stderr, "tc6393xb: unhandled write at %08x: %02x\n",
	(uint32_t) addr, (int)value & 0xff);
	}

	static const GraphicHwOps tc6393xb_gfx_ops = {
	.gfx_update = tc6393xb_update_display,
	};

	TC6393xbState tc6393xb_init(MemoryRegion sysmem, uint32_t base, qemu_irq irq)
	{
	TC6393xbState *s;
	DriveInfo *nand;
	static const MemoryRegionOps tc6393xb_ops = {
	.read = tc6393xb_readb,
	.write = tc6393xb_writeb,
	.endianness = DEVICE_NATIVE_ENDIAN,
	.impl = {
	.min_access_size = 1,
	.max_access_size = 1,
	},
	};

	s = g_new0(TC6393xbState, 1);
	s->irq = irq;
	s->gpio_in = qemu_allocate_irqs(tc6393xb_gpio_set, s, TC6393XB_GPIOS);

	s->l3v = qemu_allocate_irq(tc6393xb_l3v, s, 0);
	s->blanked = 1;

	s->sub_irqs = qemu_allocate_irqs(tc6393xb_sub_irq, s, TC6393XB_NR_IRQS);

	nand = drive_get(IF_MTD, 0, 0);
	s->flash = nand_init(nand ? blk_by_legacy_dinfo(nand) : NULL,
	NAND_MFR_TOSHIBA, 0x76);

	memory_region_init_io(&s->iomem, NULL, &tc6393xb_ops, s, "tc6393xb", 0x10000);
	memory_region_add_subregion(sysmem, base, &s->iomem);

	memory_region_init_ram(&s->vram, NULL, "tc6393xb.vram", 0x100000,
	&error_fatal);
	s->vram_ptr = memory_region_get_ram_ptr(&s->vram);
	memory_region_add_subregion(sysmem, base + 0x100000, &s->vram);
	s->scr_width = 480;
	s->scr_height = 640;
	s->con = graphic_console_init(NULL, 0, &tc6393xb_gfx_ops, s);

	return s;
	}