[qemu.git] / hw / tc58128.c

#include "hw.h"
#include "sh.h"
#include "loader.h"

#define CE1  0x0100
#define CE2  0x0200
#define RE   0x0400
#define WE   0x0800
#define ALE  0x1000
#define CLE  0x2000
#define RDY1 0x4000
#define RDY2 0x8000
#define RDY(n) ((n) == 0 ? RDY1 : RDY2)

typedef enum { WAIT, READ1, READ2, READ3 } state_t;

typedef struct {
    uint8_t *flash_contents;
    state_t state;
    uint32_t address;
    uint8_t address_cycle;
} tc58128_dev;

static tc58128_dev tc58128_devs[2];

#define FLASH_SIZE (16*1024*1024)

static void init_dev(tc58128_dev * dev, const char *filename)
{
    int ret, blocks;

    dev->state = WAIT;
    dev->flash_contents = qemu_mallocz(FLASH_SIZE);
    memset(dev->flash_contents, 0xff, FLASH_SIZE);
    if (!dev->flash_contents) {
	fprintf(stderr, "could not alloc memory for flash\n");
	exit(1);
    }
    if (filename) {
	/* Load flash image skipping the first block */
	ret = load_image(filename, dev->flash_contents + 528 * 32);
	if (ret < 0) {
	    fprintf(stderr, "ret=%d\n", ret);
	    fprintf(stderr, "qemu: could not load flash image %s\n",
		    filename);
	    exit(1);
	} else {
	    /* Build first block with number of blocks */
	    blocks = (ret + 528 * 32 - 1) / (528 * 32);
	    dev->flash_contents[0] = blocks & 0xff;
	    dev->flash_contents[1] = (blocks >> 8) & 0xff;
	    dev->flash_contents[2] = (blocks >> 16) & 0xff;
	    dev->flash_contents[3] = (blocks >> 24) & 0xff;
	    fprintf(stderr, "loaded %d bytes for %s into flash\n", ret,
		    filename);
	}
    }
}

static void handle_command(tc58128_dev * dev, uint8_t command)
{
    switch (command) {
    case 0xff:
	fprintf(stderr, "reset flash device\n");
	dev->state = WAIT;
	break;
    case 0x00:
	fprintf(stderr, "read mode 1\n");
	dev->state = READ1;
	dev->address_cycle = 0;
	break;
    case 0x01:
	fprintf(stderr, "read mode 2\n");
	dev->state = READ2;
	dev->address_cycle = 0;
	break;
    case 0x50:
	fprintf(stderr, "read mode 3\n");
	dev->state = READ3;
	dev->address_cycle = 0;
	break;
    default:
	fprintf(stderr, "unknown flash command 0x%02x\n", command);
        abort();
    }
}

static void handle_address(tc58128_dev * dev, uint8_t data)
{
    switch (dev->state) {
    case READ1:
    case READ2:
    case READ3:
	switch (dev->address_cycle) {
	case 0:
	    dev->address = data;
	    if (dev->state == READ2)
		dev->address |= 0x100;
	    else if (dev->state == READ3)
		dev->address |= 0x200;
	    break;
	case 1:
	    dev->address += data * 528 * 0x100;
	    break;
	case 2:
	    dev->address += data * 528;
	    fprintf(stderr, "address pointer in flash: 0x%08x\n",
		    dev->address);
	    break;
	default:
	    /* Invalid data */
            abort();
	}
	dev->address_cycle++;
	break;
    default:
        abort();
    }
}

static uint8_t handle_read(tc58128_dev * dev)
{
#if 0
    if (dev->address % 0x100000 == 0)
	fprintf(stderr, "reading flash at address 0x%08x\n", dev->address);
#endif
    return dev->flash_contents[dev->address++];
}

/* We never mark the device as busy, so interrupts cannot be triggered
   XXXXX */

static int tc58128_cb(uint16_t porta, uint16_t portb,
                      uint16_t * periph_pdtra, uint16_t * periph_portadir,
                      uint16_t * periph_pdtrb, uint16_t * periph_portbdir)
{
    int dev;

    if ((porta & CE1) == 0)
	dev = 0;
    else if ((porta & CE2) == 0)
	dev = 1;
    else
	return 0;		/* No device selected */

    if ((porta & RE) && (porta & WE)) {
	/* Nothing to do, assert ready and return to input state */
	*periph_portadir &= 0xff00;
	*periph_portadir |= RDY(dev);
	*periph_pdtra |= RDY(dev);
	return 1;
    }

    if (porta & CLE) {
	/* Command */
	assert((porta & WE) == 0);
	handle_command(&tc58128_devs[dev], porta & 0x00ff);
    } else if (porta & ALE) {
	assert((porta & WE) == 0);
	handle_address(&tc58128_devs[dev], porta & 0x00ff);
    } else if ((porta & RE) == 0) {
	*periph_portadir |= 0x00ff;
	*periph_pdtra &= 0xff00;
	*periph_pdtra |= handle_read(&tc58128_devs[dev]);
    } else {
        abort();
    }
    return 1;
}

static sh7750_io_device tc58128 = {
    RE | WE,			/* Port A triggers */
    0,				/* Port B triggers */
    tc58128_cb			/* Callback */
};

int tc58128_init(struct SH7750State *s, const char *zone1, const char *zone2)
{
    init_dev(&tc58128_devs[0], zone1);
    init_dev(&tc58128_devs[1], zone2);
    return sh7750_register_io_device(s, &tc58128);
}
Commit	Line	Data
87ecb68b PB	1	#include "hw.h"
87ecb68b PB	2	#include "sh.h"
ca20cf32	3	#include "loader.h"
27c7ca7e FB	4
	5	#define CE1 0x0100
	6	#define CE2 0x0200
	7	#define RE 0x0400
	8	#define WE 0x0800
	9	#define ALE 0x1000
	10	#define CLE 0x2000
	11	#define RDY1 0x4000
	12	#define RDY2 0x8000
	13	#define RDY(n) ((n) == 0 ? RDY1 : RDY2)
	14
c227f099	15	typedef enum { WAIT, READ1, READ2, READ3 } state_t;
27c7ca7e FB	16
	17	typedef struct {
	18	uint8_t *flash_contents;
c227f099	19	state_t state;
27c7ca7e FB	20	uint32_t address;
	21	uint8_t address_cycle;
	22	} tc58128_dev;
	23
	24	static tc58128_dev tc58128_devs[2];
	25
	26	#define FLASH_SIZE (1610241024)
	27
7ccfb2eb	28	static void init_dev(tc58128_dev * dev, const char *filename)
27c7ca7e FB	29	{
	30	int ret, blocks;
	31
	32	dev->state = WAIT;
	33	dev->flash_contents = qemu_mallocz(FLASH_SIZE);
	34	memset(dev->flash_contents, 0xff, FLASH_SIZE);
	35	if (!dev->flash_contents) {
	36	fprintf(stderr, "could not alloc memory for flash\n");
	37	exit(1);
	38	}
	39	if (filename) {
	40	/* Load flash image skipping the first block */
	41	ret = load_image(filename, dev->flash_contents + 528 * 32);
	42	if (ret < 0) {
	43	fprintf(stderr, "ret=%d\n", ret);
	44	fprintf(stderr, "qemu: could not load flash image %s\n",
	45	filename);
	46	exit(1);
	47	} else {
	48	/* Build first block with number of blocks */
	49	blocks = (ret + 528 * 32 - 1) / (528 * 32);
	50	dev->flash_contents[0] = blocks & 0xff;
	51	dev->flash_contents[1] = (blocks >> 8) & 0xff;
	52	dev->flash_contents[2] = (blocks >> 16) & 0xff;
	53	dev->flash_contents[3] = (blocks >> 24) & 0xff;
	54	fprintf(stderr, "loaded %d bytes for %s into flash\n", ret,
	55	filename);
	56	}
	57	}
	58	}
	59
b1d8e52e	60	static void handle_command(tc58128_dev * dev, uint8_t command)
27c7ca7e FB	61	{
	62	switch (command) {
	63	case 0xff:
	64	fprintf(stderr, "reset flash device\n");
	65	dev->state = WAIT;
	66	break;
	67	case 0x00:
	68	fprintf(stderr, "read mode 1\n");
	69	dev->state = READ1;
	70	dev->address_cycle = 0;
	71	break;
	72	case 0x01:
	73	fprintf(stderr, "read mode 2\n");
	74	dev->state = READ2;
	75	dev->address_cycle = 0;
	76	break;
	77	case 0x50:
	78	fprintf(stderr, "read mode 3\n");
	79	dev->state = READ3;
	80	dev->address_cycle = 0;
	81	break;
	82	default:
	83	fprintf(stderr, "unknown flash command 0x%02x\n", command);
43dc2a64	84	abort();
27c7ca7e FB	85	}
	86	}
	87
b1d8e52e	88	static void handle_address(tc58128_dev * dev, uint8_t data)
27c7ca7e FB	89	{
	90	switch (dev->state) {
	91	case READ1:
	92	case READ2:
	93	case READ3:
	94	switch (dev->address_cycle) {
	95	case 0:
	96	dev->address = data;
	97	if (dev->state == READ2)
	98	dev->address \|= 0x100;
	99	else if (dev->state == READ3)
	100	dev->address \|= 0x200;
	101	break;
	102	case 1:
	103	dev->address += data * 528 * 0x100;
	104	break;
	105	case 2:
	106	dev->address += data * 528;
	107	fprintf(stderr, "address pointer in flash: 0x%08x\n",
	108	dev->address);
	109	break;
	110	default:
	111	/* Invalid data */
43dc2a64	112	abort();
27c7ca7e FB	113	}
	114	dev->address_cycle++;
	115	break;
	116	default:
43dc2a64	117	abort();
27c7ca7e FB	118	}
	119	}
	120
b1d8e52e	121	static uint8_t handle_read(tc58128_dev * dev)
27c7ca7e FB	122	{
	123	#if 0
	124	if (dev->address % 0x100000 == 0)
	125	fprintf(stderr, "reading flash at address 0x%08x\n", dev->address);
	126	#endif
	127	return dev->flash_contents[dev->address++];
	128	}
	129
	130	/* We never mark the device as busy, so interrupts cannot be triggered
	131	XXXXX */
	132
b1d8e52e BS	133	static int tc58128_cb(uint16_t porta, uint16_t portb,
	134	uint16_t * periph_pdtra, uint16_t * periph_portadir,
	135	uint16_t * periph_pdtrb, uint16_t * periph_portbdir)
27c7ca7e FB	136	{
	137	int dev;
	138
	139	if ((porta & CE1) == 0)
	140	dev = 0;
	141	else if ((porta & CE2) == 0)
	142	dev = 1;
	143	else
	144	return 0; /* No device selected */
	145
	146	if ((porta & RE) && (porta & WE)) {
	147	/* Nothing to do, assert ready and return to input state */
	148	*periph_portadir &= 0xff00;
	149	*periph_portadir \|= RDY(dev);
	150	*periph_pdtra \|= RDY(dev);
	151	return 1;
	152	}
	153
	154	if (porta & CLE) {
	155	/* Command */
	156	assert((porta & WE) == 0);
	157	handle_command(&tc58128_devs[dev], porta & 0x00ff);
	158	} else if (porta & ALE) {
	159	assert((porta & WE) == 0);
	160	handle_address(&tc58128_devs[dev], porta & 0x00ff);
	161	} else if ((porta & RE) == 0) {
	162	*periph_portadir \|= 0x00ff;
	163	*periph_pdtra &= 0xff00;
	164	*periph_pdtra \|= handle_read(&tc58128_devs[dev]);
	165	} else {
43dc2a64	166	abort();
27c7ca7e FB	167	}
	168	return 1;
	169	}
	170
	171	static sh7750_io_device tc58128 = {
	172	RE \| WE, /* Port A triggers */
	173	0, /* Port B triggers */
	174	tc58128_cb /* Callback */
	175	};
	176
7ccfb2eb	177	int tc58128_init(struct SH7750State s, const char zone1, const char *zone2)
27c7ca7e FB	178	{
	179	init_dev(&tc58128_devs[0], zone1);
	180	init_dev(&tc58128_devs[1], zone2);
	181	return sh7750_register_io_device(s, &tc58128);
	182	}