/*
* BRM driver
*
* COPYRIGHT (c) 2006.
* Gaisler Research.
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rtems.com/license/LICENSE.
*
*/
/********** Set defaults **********/
/* basic bus/interface of device,
* Default to direct accessed AMBA bus.
*/
#ifndef B1553BRM_NO_AMBA
#define B1553BRM_AMBA
#undef B1553BRM_PCI
#endif
/* default name to /dev/brm */
#if !defined(B1553BRM_DEVNAME) || !defined(B1553BRM_DEVNAME_NO)
#undef B1553BRM_DEVNAME
#undef B1553BRM_DEVNAME_NO
#define B1553BRM_DEVNAME "/dev/brm0"
#define B1553BRM_DEVNAME_NO(devstr,no) ((devstr)[8]='0'+(no))
#endif
#ifndef B1553BRM_PREFIX
#define B1553BRM_PREFIX(name) b1553brm##name
#endif
/* default to no translation */
#ifndef B1553BRM_ADR_TO
#define memarea_to_hw(x) ((unsigned int)(x))
#endif
#ifndef B1553BRM_REG_INT
#define B1553BRM_REG_INT(handler,irqno,arg) set_vector(handler,(irqno)+0x10,1)
#undef B1553BRM_DEFINE_INTHANDLER
#define B1553BRM_DEFINE_INTHANDLER
#endif
/* default to 128K memory layout */
#if !defined(DMA_MEM_16K)
#define DMA_MEM_128K
#endif
#include <bsp.h>
#include <rtems/libio.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <ctype.h>
#include <rtems/bspIo.h>
#include <b1553brm.h>
#include <ambapp.h>
/* Uncomment for debug output */
/*#define DEBUG 1
#define FUNCDEBUG 1*/
#undef DEBUG
#undef FUNCDEBUG
/* EVENT_QUEUE_SIZE sets the size of the event queue
*/
#define EVENT_QUEUE_SIZE 1024
#define INDEX(x) ( x&(EVENT_QUEUE_SIZE-1) )
#ifdef DEBUG
#define DBG(x...) printk(x)
#else
#define DBG(x...)
#endif
#ifdef FUNCDEBUG
#define FUNCDBG(x...) printk(x)
#else
#define FUNCDBG(x...)
#endif
#define READ_REG(address) _BRM_REG_READ16((unsigned int)address)
#define READ_DMA(address) _BRM_REG_READ16((unsigned int)address)
static __inline__ unsigned short _BRM_REG_READ16(unsigned int addr) {
unsigned short tmp;
__asm__ (" lduha [%1]1, %0 "
: "=r"(tmp)
: "r"(addr)
);
return tmp;
}
static rtems_device_driver brm_initialize(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
static rtems_device_driver brm_open(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
static rtems_device_driver brm_close(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
static rtems_device_driver brm_read(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
static rtems_device_driver brm_write(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
static rtems_device_driver brm_control(rtems_device_major_number major, rtems_device_minor_number minor, void *arg);
#define BRM_DRIVER_TABLE_ENTRY { brm_initialize, brm_open, brm_close, brm_read, brm_write, brm_control }
static rtems_driver_address_table brm_driver = BRM_DRIVER_TABLE_ENTRY;
struct msg {
unsigned short miw;
unsigned short time;
unsigned short data[32];
};
#if defined(DMA_MEM_128K)
struct circ_buf {
struct msg msgs[9];
};
#elif defined(DMA_MEM_16K)
/* two message queue */
struct circ_buf_2 {
struct msg msgs[2];
};
/* one message queue */
struct circ_buf_1 {
struct msg msgs[1];
};
#endif
struct irq_log_list {
volatile unsigned short iiw;
volatile unsigned short iaw;
};
typedef struct {
unsigned int memarea_base;
struct brm_reg *regs;
/* BRM descriptors */
struct desc_table {
volatile unsigned short ctrl;
volatile unsigned short top;
volatile unsigned short cur;
volatile unsigned short bot;
} *desc;
volatile unsigned short *mem;
/* bc mem struct */
struct {
/* BC Descriptors */
struct {
unsigned short ctrl; /* control */
unsigned short cw1; /* Command word 1*/
unsigned short cw2; /* Command word 1*/
unsigned short dptr; /* Data pointer in halfword offset from bcmem */
unsigned short tsw[2]; /* status word 1 & 2 */
unsigned short ba; /* branch address */
unsigned short timer; /* timer value */
} descs[128]; /* 2k (1024 half words) */
/* message data */
struct {
unsigned short data[32]; /* 1 message's data */
} msg_data[128]; /* 8k */
#if defined(DMA_MEM_128K)
/* offset to last 64bytes of 128k */
unsigned short unused[(64*1024-(128*8+128*32))-16*2];
#elif defined(DMA_MEM_16K)
unsigned short unused[(8*1024-(128*8+128*32))-16*2];
#endif
/* interrupt log at 64 bytes from end */
struct irq_log_list irq_logs[16];
} *bcmem;
#if defined(DMA_MEM_128K)
/* Memory structure of a RT being inited, just used
* for RT initialization.
*
* *mesgs[32] fit each minimally 8 messages per sub address.
*/
struct {
/* RX Sub Address descriptors */
struct desc_table rxsubs[32];
/* TX Sub Address descriptors */
struct desc_table txsubs[32];
/* RX mode code descriptors */
struct desc_table rxmodes[32];
/* TX mode code descriptors */
struct desc_table txmodes[32];
/* RX Sub Address messages */
struct circ_buf rxsuba_msgs[32];
/* TX Sub Address messages */
struct circ_buf txsuba_msgs[32];
/* RX Mode Code messages */
struct circ_buf rxmode_msgs[32];
/* RX Mode Code messages */
struct circ_buf txmode_msgs[32];
/* offset to last 64bytes of 128k: tot-used-needed */
unsigned short unused[(64*1024-(4*32*4+4*32*9*34))-16*2];
/* interrupt log at 64 bytes from end */
struct irq_log_list irq_logs[16];
} *rtmem;
#elif defined(DMA_MEM_16K)
/* Memory structure of a RT being inited, just used
* for RT initialization.
*
* circ_buf_2 *mesgs[32] fit each minimally 2 messages per queue.
* circ_buf_1 *mesgs[32] fit each minimally 1 messages per queue.
*/
struct {
/* RX Sub Address descriptors */
struct desc_table rxsubs[32];
/* TX Sub Address descriptors */
struct desc_table txsubs[32];
/* RX mode code descriptors */
struct desc_table rxmodes[32];
/* TX mode code descriptors */
struct desc_table txmodes[32];
/* RX Sub Address messages */
struct circ_buf_2 rxsuba_msgs[32];
/* TX Sub Address messages */
struct circ_buf_2 txsuba_msgs[32];
/* RX Mode Code messages */
struct circ_buf_2 rxmode_msgs[32];
/* RX Mode Code messages */
struct circ_buf_1 txmode_msgs[32];
/* offset to last 64bytes of 16k: tot-used-needed */
unsigned short unused[8*1024 -(4*32*4 +3*32*2*34 +1*32*1*34) -16*2];
/* interrupt log at 64 bytes from end */
struct irq_log_list irq_logs[16];
} *rtmem;
#else
#error You must define one DMA_MEM_???K
#endif
/* Interrupt log list */
struct irq_log_list *irq_log;
unsigned int irq;
/* Received events waiting to be read */
struct rt_msg *rt_event;
struct bm_msg *bm_event;
unsigned int head, tail;
unsigned int last_read[128];
unsigned int written[32];
struct bc_msg *cur_list;
int tx_blocking, rx_blocking;
rtems_id rx_sem, tx_sem, dev_sem;
int minor;
int irqno;
unsigned int mode;
#ifdef DEBUG
unsigned int log[EVENT_QUEUE_SIZE*4];
unsigned int log_i;
#endif
rtems_id event_id; /* event that may be signalled upon errors, needs to be set through ioctl command BRM_SET_EVENTID */
unsigned int status;
int bc_list_fail;
} brm_priv;
static int brm_cores;
static unsigned int allbrm_memarea;
static brm_priv *brms;
static struct ambapp_bus *amba_bus;
static unsigned int allbrm_cfg_clksel;
static unsigned int allbrm_cfg_clkdiv;
static unsigned int allbrm_cfg_freq;
static void brm_interrupt(brm_priv *brm);
#ifdef B1553BRM_DEFINE_INTHANDLER
static void b1553brm_interrupt_handler(rtems_vector_number v);
#endif
#define OFS(ofs) (((unsigned int)&ofs & 0x1ffff)>>1)
static int odd_parity(unsigned int data) {
unsigned int i=0;
while(data)
{
i++;
data &= (data - 1);
}
return !(i&1);
}
static void start_operation(brm_priv *brm) {
unsigned int ctrl = READ_REG(&brm->regs->ctrl);
brm->regs->ctrl = ctrl | 0x8000;
}
static void stop_operation(brm_priv *brm) {
unsigned int ctrl = READ_REG(&brm->regs->ctrl);
brm->regs->ctrl = ctrl & ~0x8000;
}
static int is_executing(brm_priv *brm) {
unsigned int ctrl = READ_REG(&brm->regs->ctrl);
return ((ctrl>>15) & 1);
}
#ifdef LEON3
#ifndef DONT_DEF_RAMON
int brm_register_leon3_ramon_fpga(void){
/* Clock div & Clock sel is NOT available.
* The BRM is always clocked with 24MHz.
* 3 in BRM enhanced register will select 24MHz
*/
return b1553brm_register(&ambapp_plb, 0, 0, 3);
}
int brm_register_leon3_ramon_asic(void){
/* Clock div & Clock sel is available.
* Clkdiv only matter when clksel is 1.
* clksel=2, clkdiv=don't care, brm_frq=24MHz
*
* 3 in BRM enhanced register will select 24MHz
*/
return b1553brm_register(&ambapp_plb, 2, 0, 3);
}
#endif
#endif
int B1553BRM_PREFIX(_register)(struct ambapp_bus *bus, unsigned int clksel, unsigned int clkdiv, unsigned int brm_freq)
{
rtems_status_code r;
rtems_device_major_number m;
FUNCDBG("brm_register:\n\r");
/* save amba bus pointer */
amba_bus = bus;
if ( !bus ){
printk("brm_register: bus is NULL\n\r");
return 1;
}
#ifdef B1553BRM_LOCAL_MEM
allbrm_memarea = B1553BRM_LOCAL_MEM_ADR;
#else
allbrm_memarea = 0;
#endif
/* Save clksel, clkdiv and brm_freq for later use */
allbrm_cfg_clksel = clksel & CLKSEL_MASK;
allbrm_cfg_clkdiv = clkdiv & CLKDIV_MASK;
allbrm_cfg_freq = brm_freq & BRM_FREQ_MASK;
if ((r = rtems_io_register_driver(0, &brm_driver, &m)) == RTEMS_SUCCESSFUL) {
DBG("BRM: driver successfully registered, major: %d\n",m);
} else {
switch(r) {
case RTEMS_TOO_MANY:
printk("BRM rtems_io_register_driver failed: RTEMS_TOO_MANY\n"); break;
case RTEMS_INVALID_NUMBER:
printk("BRM rtems_io_register_driver failed: RTEMS_INVALID_NUMBER\n"); break;
case RTEMS_RESOURCE_IN_USE:
printk("BRM rtems_io_register_driver failed: RTEMS_RESOURCE_IN_USE\n"); break;
default:
printk("BRM rtems_io_register_driver failed\n");
}
return 1;
}
return 0;
}
static void clr_int_logs(struct irq_log_list *logs){
int i;
for(i=0; i<16; i++){
logs[i].iiw = 0xffff;
logs[i].iaw = 0x0;
}
}
static rtems_device_driver rt_init(brm_priv *brm) {
unsigned int i;
brm->head = brm->tail = 0;
brm->rx_blocking = brm->tx_blocking = 1;
if ( brm->bm_event )
free(brm->bm_event);
brm->bm_event = NULL;
if ( brm->rt_event )
free(brm->rt_event);
brm->bcmem = NULL;
brm->rtmem = (void *)brm->mem;
brm->rt_event = (struct rt_msg *) malloc(EVENT_QUEUE_SIZE*sizeof(struct rt_msg));
if (brm->rt_event == NULL) {
DBG("BRM driver failed to allocated memory.");
return RTEMS_NO_MEMORY;
}
brm->irq_log = (struct irq_log_list *)&brm->rtmem->irq_logs[0];
brm->regs->ctrl = 0x1912; /* enable both buses, circular 1 bufmode, broadcast, interrupt log */
brm->regs->oper = 0x0900; /* configure as RT, with addr 1 */
brm->regs->imask = BRM_RT_ILLCMD_IRQ|BRM_SUBAD_IRQ|BRM_TAPF_IRQ|BRM_DMAF_IRQ|BRM_WRAPF_IRQ|BRM_MERR_IRQ;
brm->regs->dpoint = 0;
brm->regs->ipoint = OFS(brm->rtmem->irq_logs[0]);
brm->regs->enhanced = 0x0000 | allbrm_cfg_freq; /* BRM clocked with freq = 12,16,20 or 24MHz */
brm->regs->w_ctrl = (allbrm_cfg_clksel<<9) | (allbrm_cfg_clkdiv<<5) | 1;
brm->regs->w_irqctrl = 6;
brm->regs->w_ahbaddr = (unsigned int) memarea_to_hw(brm->memarea_base);
clr_int_logs(brm->irq_log);
/* Legalize all commands */
for (i = 0; i < 16; i++) {
brm->regs->rt_cmd_leg[i] = 0;
}
/* Init descriptor table
*
* Each circular buffer has room for 8 messages with up to 34 (32 data + miw + time) words (16b) in each.
* The buffers must separated by 34 words.
*/
/* RX Sub-address 0 - 31 */
for (i = 0; i < 32; i++) {
brm->rtmem->rxsubs[i].ctrl = 0x00E0; /* Interrupt: INTX, IWA, and IBRD */
brm->rtmem->rxsubs[i].top = OFS(brm->rtmem->rxsuba_msgs[i]); /* Top address */
brm->rtmem->rxsubs[i].cur = OFS(brm->rtmem->rxsuba_msgs[i]); /* Current address */
brm->rtmem->rxsubs[i].bot = OFS(brm->rtmem->rxsuba_msgs[i+1]) - sizeof(struct msg)/2; /* Bottom address */
brm->last_read[i] = OFS(brm->rtmem->rxsuba_msgs[i]);
}
/* TX Sub-address 0 - 31 */
for (i = 0; i < 32; i++) {
brm->rtmem->txsubs[i].ctrl = 0x0060; /* Interrupt: IWA and IBRD */
brm->rtmem->txsubs[i].top = OFS(brm->rtmem->txsuba_msgs[i]); /* Top address */
brm->rtmem->txsubs[i].cur = OFS(brm->rtmem->txsuba_msgs[i]); /* Current address */
brm->rtmem->txsubs[i].bot = OFS(brm->rtmem->txsuba_msgs[i+1]) - sizeof(struct msg)/2; /* Bottom address */
brm->last_read[i+32] = OFS(brm->rtmem->txsuba_msgs[i]);
brm->written[i] = OFS(brm->rtmem->txsuba_msgs[i]);
}
/* RX mode code 0 - 31 */
for (i = 0; i < 32; i++) {
brm->rtmem->rxmodes[i].ctrl = 0x00E0; /* Interrupt: INTX, IWA, and IBRD */
brm->rtmem->rxmodes[i].top = OFS(brm->rtmem->rxmode_msgs[i]); /* Top address */
brm->rtmem->rxmodes[i].cur = OFS(brm->rtmem->rxmode_msgs[i]); /* Current address */
brm->rtmem->rxmodes[i].bot = OFS(brm->rtmem->rxmode_msgs[i+1]) - sizeof(struct msg)/2; /* Bottom address */
brm->last_read[i+64] = OFS(brm->rtmem->rxmode_msgs[i]);
}
/* TX mode code 0 - 31 */
for (i = 0; i < 32; i++) {
brm->rtmem->txmodes[i].ctrl = 0x0060; /* Interrupt: IWA and IBRD */
brm->rtmem->txmodes[i].top = OFS(brm->rtmem->txmode_msgs[i]); /* Top address */
brm->rtmem->txmodes[i].cur = OFS(brm->rtmem->txmode_msgs[i]); /* Current address */
brm->rtmem->txmodes[i].bot = OFS(brm->rtmem->txmode_msgs[i+1]) - sizeof(struct msg)/2; /* Bottom address */
brm->last_read[i+96] = OFS(brm->rtmem->txmode_msgs[i]);
}
brm->mode = BRM_MODE_RT;
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver bc_init(brm_priv *brm){
if ( brm->bm_event )
free(brm->bm_event);
brm->bm_event = NULL;
if ( brm->rt_event )
free(brm->rt_event);
brm->rt_event = NULL;
brm->bcmem = (void *)brm->mem;
brm->rtmem = NULL;
brm->irq_log = (struct irq_log_list *)&brm->bcmem->irq_logs[0];
brm->head = brm->tail = 0;
brm->rx_blocking = brm->tx_blocking = 1;
brm->regs->ctrl = 0x0006; /* ping pong enable and enable interrupt log */
brm->regs->oper = 0x0800; /* configure as BC */
brm->regs->imask = BRM_EOL_IRQ|BRM_BC_ILLCMD_IRQ|BRM_ILLOP_IRQ|BRM_DMAF_IRQ|BRM_WRAPF_IRQ|BRM_MERR_IRQ;
brm->regs->dpoint = 0;
printk("Set BC interrupt log: 0x%lx, 0x%lx, 0x%lx\n",OFS(brm->bcmem->irq_logs[0]),&brm->bcmem->irq_logs[0],brm->bcmem);
brm->regs->ipoint = OFS(brm->bcmem->irq_logs[0]);
brm->regs->enhanced = 0x0000 | (allbrm_cfg_freq&0x3); /* freq = 24 */
brm->regs->w_ctrl = (allbrm_cfg_clksel<<9) | (allbrm_cfg_clkdiv<<5) | 1;
brm->regs->w_irqctrl = 6;
brm->regs->w_ahbaddr = (unsigned int) memarea_to_hw(brm->memarea_base);
clr_int_logs(brm->irq_log);
brm->mode = BRM_MODE_BC;
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver bm_init(brm_priv *brm) {
brm->head = brm->tail = 0;
brm->rx_blocking = brm->tx_blocking = 1;
if ( brm->rt_event )
free(brm->rt_event);
brm->rt_event = NULL;
if ( brm->bm_event )
free(brm->bm_event);
brm->bcmem = NULL;
brm->rtmem = NULL;
brm->bm_event = (struct bm_msg *) malloc(EVENT_QUEUE_SIZE*sizeof(struct bm_msg));
if (brm->bm_event == NULL) {
DBG("BRM driver failed to allocated memory.");
return RTEMS_NO_MEMORY;
}
/* end of 16K, fits all current modes (128K, 16K) */
brm->irq_log = (struct irq_log_list *)&brm->mem[8*1024-16*2];
brm->regs->ctrl = 0x0006; /* ping pong enable and enable interrupt log */
brm->regs->oper = 0x0A00; /* configure as BM */
brm->regs->imask = BRM_MBC_IRQ|BRM_MERR_IRQ|BRM_DMAF_IRQ|BRM_MERR_IRQ;
brm->regs->dpoint = 0;
brm->regs->ipoint = OFS(brm->mem[8*1024-16*2]);
brm->regs->mcpoint = 0; /* Command pointer */
brm->regs->mdpoint = 0x100; /* Data pointer */
brm->regs->mbc = 1; /* Block count */
brm->regs->enhanced = 0x0000 | (allbrm_cfg_freq&0x3); /* freq = 24 */
brm->regs->w_ctrl = (allbrm_cfg_clksel<<9) | (allbrm_cfg_clkdiv<<5) | 1;
brm->regs->w_irqctrl = 6;
brm->regs->w_ahbaddr = (unsigned int) memarea_to_hw(brm->memarea_base);
clr_int_logs(brm->irq_log);
brm->mode = BRM_MODE_BM;
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver brm_initialize(rtems_device_major_number major, rtems_device_minor_number minor, void *arg)
{
rtems_status_code status;
int dev_cnt;
char fs_name[20];
brm_priv *brm;
struct ambapp_ahb_info ambadev;
char *mem;
FUNCDBG("brm_initialize\n");
brm_cores = 0;
strcpy(fs_name,B1553BRM_DEVNAME);
/* Find all BRM devices */
dev_cnt = ambapp_get_number_ahbslv_devices(amba_bus, VENDOR_GAISLER, GAISLER_B1553BRM);
if ( dev_cnt < 1 ){
/* Failed to find any CAN cores! */
printk("BRM: Failed to find any BRM cores\n\r");
return -1;
}
/* allocate & zero memory for the brm devices */
brms = (brm_priv *)malloc(sizeof(*brms)*dev_cnt);
if ( !brms ){
printk("BRM: Failed to allocate SW memory\n\r");
return -1;
}
memset(brms,0,sizeof(*brms)*dev_cnt);
/* Allocate memory for all device's descriptors,
* they must be aligned to a XXX byte boundary.
*/
#define BRM_DESCS_PER_CTRL 128
if ( allbrm_memarea ){
mem = (char *)allbrm_memarea;
}else{
/* sizeof(struct desc_table) * BRM_DESCS_PER_CTRL * dev_cnt */
mem = (char *)malloc( (128*1024) * (dev_cnt+1)); /* 128k per core + 128k for alignment */
if ( !mem ){
free(brms);
printk("BRM: Failed to allocate HW memory\n\r");
return -1;
}
/* align memory to 128k boundary */
mem = (char *)(((unsigned int)mem+0x1ffff) & ~0x1ffff);
}
/* clear the used memory */
memset(mem,0,(128*1024) * dev_cnt);
/* initialize each brm device, one at a time */
for(minor=0; minor<dev_cnt; minor++){
brm = &brms[minor];
/* Get AMBA AHB device info from Plug&Play */
ambapp_find_ahbslv_next(amba_bus, VENDOR_GAISLER,
GAISLER_B1553BRM, &ambadev, minor);
/* Copy Basic HW info */
brm->regs = (void *)ambadev.start[0];
brm->irqno = ambadev.irq;
brm->minor = minor;
brm->irq = 0;
#ifdef DEBUG
brm->log_i = 0;
memset(brm->log,0,sizeof(brm->log));
#endif
/* Set unique name */
B1553BRM_DEVNAME_NO(fs_name,minor);
DBG("Registering BRM core at [0x%x] irq %d, minor %d as %s\n",brm->regs,brm->irqno,minor,fs_name);
/* Bind filesystem name to device number (minor) */
status = rtems_io_register_name(fs_name, major, minor);
if (status != RTEMS_SUCCESSFUL)
rtems_fatal_error_occurred(status);
/* RX Semaphore created with count = 0 */
if ( rtems_semaphore_create(rtems_build_name('B', 'M', 'R', '0'+minor),
0,
RTEMS_FIFO|RTEMS_SIMPLE_BINARY_SEMAPHORE|RTEMS_NO_INHERIT_PRIORITY|RTEMS_LOCAL|RTEMS_NO_PRIORITY_CEILING,
0,
&brm->rx_sem) != RTEMS_SUCCESSFUL ){
printk("BRM: Failed to create rx semaphore\n");
return RTEMS_INTERNAL_ERROR;
}
/* TX Semaphore created with count = 1 */
if ( rtems_semaphore_create(rtems_build_name('B', 'M', 'T', '0'+minor),
1,
RTEMS_FIFO|RTEMS_SIMPLE_BINARY_SEMAPHORE|RTEMS_NO_INHERIT_PRIORITY|RTEMS_LOCAL|RTEMS_NO_PRIORITY_CEILING,
0,
&brm->tx_sem) != RTEMS_SUCCESSFUL ){
printk("BRM: Failed to create tx semaphore\n");
return RTEMS_INTERNAL_ERROR;
}
/* Device Semaphore created with count = 1 */
if ( rtems_semaphore_create(rtems_build_name('B', 'M', 'D', '0'+minor),
1,
RTEMS_FIFO|RTEMS_SIMPLE_BINARY_SEMAPHORE|RTEMS_NO_INHERIT_PRIORITY|RTEMS_LOCAL|RTEMS_NO_PRIORITY_CEILING,
0,
&brm->dev_sem) != RTEMS_SUCCESSFUL ){
printk("BRM: Failed to create device semaphore\n");
return RTEMS_INTERNAL_ERROR;
}
/* Set base address of all descriptors */
brm->memarea_base = (unsigned int)&mem[(128*1024) * minor];
brm->desc = (struct desc_table *) brm->memarea_base;
brm->mem = (volatile unsigned short *) brm->memarea_base;
brm->irq_log = (struct irq_log_list *)(brm->memarea_base + (0xFFE0<<1)); /* last 64byte */
brm->bm_event = NULL;
brm->rt_event = NULL;
/* Sel clock so that we can write to BRM's registers */
brm->regs->w_ctrl = (allbrm_cfg_clksel<<9) | (allbrm_cfg_clkdiv<<5);
/* Reset BRM core */
brm->regs->w_ctrl = 1<<10 | READ_REG(&brm->regs->w_ctrl);
/* Register interrupt handler */
B1553BRM_REG_INT(B1553BRM_PREFIX(_interrupt_handler), brm->irqno, brm);
rt_init(brm);
DBG("BRM: LOG: 0x%lx, 0x%lx\n\r",brm->log,brm);
}
/* save number of BRM cores found */
brm_cores = dev_cnt;
DBG("BRM initialisation done.\n");
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver brm_open(rtems_device_major_number major, rtems_device_minor_number minor, void *arg) {
brm_priv *brm;
FUNCDBG("brm_open\n");
if (minor >= brm_cores) {
DBG("Wrong minor %d\n", minor);
return RTEMS_UNSATISFIED; /* ENODEV */
}
brm = &brms[minor];
if (rtems_semaphore_obtain(brm->dev_sem, RTEMS_NO_WAIT, RTEMS_NO_TIMEOUT) != RTEMS_SUCCESSFUL) {
DBG("brm_open: resource in use\n");
return RTEMS_RESOURCE_IN_USE; /* EBUSY */
}
/* Set defaults */
brm->event_id = 0;
start_operation(brm);
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver brm_close(rtems_device_major_number major, rtems_device_minor_number minor, void *arg)
{
brm_priv *brm = &brms[minor];
FUNCDBG("brm_close");
stop_operation(brm);
rtems_semaphore_release(brm->dev_sem);
return RTEMS_SUCCESSFUL;
}
static int get_rt_messages(brm_priv *brm, void *buf, unsigned int msg_count) {
struct rt_msg *dest = (struct rt_msg *) buf;
int count = 0;
if (brm->head == brm->tail) {
return 0;
}
do {
DBG("rt read - head: %d, tail: %d\n", brm->head, brm->tail);
dest[count++] = brm->rt_event[INDEX(brm->tail++)];
} while (brm->head != brm->tail && count < msg_count);
return count;
}
static int get_bm_messages(brm_priv *brm, void *buf, unsigned int msg_count) {
struct bm_msg *dest = (struct bm_msg *) buf;
int count = 0;
if (brm->head == brm->tail) {
return 0;
}
do {
DBG("bm read - head: %d, tail: %d\n", brm->head, brm->tail);
dest[count++] = brm->bm_event[INDEX(brm->tail++)];
} while (brm->head != brm->tail && count < msg_count);
return count;
}
static rtems_device_driver brm_read(rtems_device_major_number major, rtems_device_minor_number minor, void *arg)
{
rtems_libio_rw_args_t *rw_args;
int count = 0;
brm_priv *brm = &brms[minor];
int (*get_messages)(brm_priv *brm, void *buf, unsigned int count);
if ( ! (brm->mode & (BRM_MODE_RT | BRM_MODE_BM)) ){
return RTEMS_INVALID_NAME;
}
rw_args = (rtems_libio_rw_args_t *) arg;
if ( ((READ_REG(&brm->regs->oper)>>8) & 3) == 1 ) { /* RT */
get_messages = get_rt_messages;
}
else { /* BM */
get_messages = get_bm_messages;
}
FUNCDBG("brm_read [%i,%i]: buf: 0x%x len: %i\n",major, minor, (unsigned int)rw_args->buffer,rw_args->count);
while ( (count=get_messages(brm,rw_args->buffer, rw_args->count)) == 0 ) {
if (brm->rx_blocking) {
rtems_semaphore_obtain(brm->rx_sem, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
}
else {
/* Translates to EBUSY */
return RTEMS_RESOURCE_IN_USE;
}
}
rw_args->bytes_moved = count;
return RTEMS_SUCCESSFUL;
}
static rtems_device_driver brm_write(rtems_device_major_number major, rtems_device_minor_number minor, void *arg)
{
rtems_libio_rw_args_t *rw_args;
struct rt_msg *source;
unsigned int count=0, current, next, descriptor, wc, suba;
brm_priv *brm = &brms[minor];
if ( ! (brm->mode & BRM_MODE_RT) ){
return RTEMS_INVALID_NAME;
}
rw_args = (rtems_libio_rw_args_t *) arg;
source = (struct rt_msg *) rw_args->buffer;
FUNCDBG("brm_write [%i,%i]: buf: 0x%x len: %i\n",major, minor, (unsigned int)rw_args->buffer,rw_args->count);
do {
descriptor = source[count].desc & 0x7F;
suba = descriptor-32;
wc = source[count].miw >> 11;
wc = wc ? wc : 32;
/* Only subaddress transmission is allowed with write */
if (descriptor < 32 || descriptor >= 64)
return RTEMS_INVALID_NAME;
current = brm->desc[descriptor].cur;
next = brm->written[suba] + 2 + wc;
if (brm->written[suba] < current) {
if (next > current) {
/* No room in transmission buffer */
if (brm->tx_blocking && count == 0) {
rtems_semaphore_obtain(brm->tx_sem, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
}
else if ( brm->tx_blocking && (count != 0) ){
/* return the number of messages sent so far */
break;
}
else {
/* Translates to posix EBUSY */
return RTEMS_RESOURCE_IN_USE;
}
}
}
memcpy((void *)&brm->mem[brm->written[suba]], &source[count], (2+wc)*2);
count++;
if (next >= brm->desc[descriptor].bot) {
next = brm->desc[descriptor].top;
}
brm->written[suba] = next;
} while (count < rw_args->count);
rw_args->bytes_moved = count;
if (count >= 0) {
return RTEMS_SUCCESSFUL;
}
return RTEMS_UNSATISFIED;
}
static rtems_device_driver brm_control(rtems_device_major_number major, rtems_device_minor_number minor, void *arg)
{
unsigned int i=0;
unsigned short ctrl, oper, cw1, cw2;
rtems_libio_ioctl_args_t *ioarg = (rtems_libio_ioctl_args_t *) arg;
unsigned int *data = ioarg->buffer;
struct bc_msg *cmd_list = (struct bc_msg *) ioarg->buffer;
brm_priv *brm = &brms[minor];
rtems_device_driver ret;
int len;
FUNCDBG("brm_control[%d]: [%i,%i]\n",minor,major, minor);
if (!ioarg) {
DBG("brm_control: invalid argument\n");
return RTEMS_INVALID_NAME;
}
ioarg->ioctl_return = 0;
switch(ioarg->command) {
case BRM_SET_MODE:
if ( data[0] > 2 )
return RTEMS_INVALID_NAME;
stop_operation(brm);
if (data[0] == 0) {
ret = bc_init(brm);
}
else if (data[0] == 1) {
ret = rt_init(brm);
}
else if (data[0] == 2) {
ret = bm_init(brm);
}else
ret = RTEMS_INVALID_NAME;
if ( ret != RTEMS_SUCCESSFUL)
return ret;
if ( brm->mode & (BRM_MODE_RT | BRM_MODE_BM ) )
start_operation(brm);
break;
case BRM_SET_BUS:
stop_operation(brm);
ctrl = READ_REG(&brm->regs->ctrl);
ctrl &= 0xE7FF; /* Clear bit 12-11 ... */
ctrl |= (data[0]&0x3)<<11; /* ... OR in new bus status */
brm->regs->ctrl = ctrl;
start_operation(brm);
break;
case BRM_SET_MSGTO:
stop_operation(brm);
ctrl = READ_REG(&brm->regs->ctrl);
ctrl &= 0xFDFF; /* Clear bit 9 ... */
ctrl |= (data[0]&1)<<9; /* ... OR in new MSGTO */
brm->regs->ctrl = ctrl;
start_operation(brm);
break;
case BRM_SET_RT_ADDR:
stop_operation(brm);
oper = READ_REG(&brm->regs->oper);
oper &= 0x03FF; /* Clear bit 15-10 ... */
oper |= (data[0]&0x1f)<<11; /* ... OR in new address */
oper |= odd_parity(data[0]&0x1f)<<10; /* ... OR in parity */
brm->regs->oper = oper;
start_operation(brm);
break;
case BRM_SET_STD:
stop_operation(brm);
ctrl = READ_REG(&brm->regs->ctrl);
ctrl &= 0xFF7F; /* Clear bit 7 ... */
ctrl |= (data[0]&1)<<7; /* ... OR in new ABSTD (1=A) */
brm->regs->ctrl = ctrl;
start_operation(brm);
break;
case BRM_SET_BCE:
stop_operation(brm);
ctrl = READ_REG(&brm->regs->ctrl);
ctrl &= 0xFFEF; /* Clear bit 4 ... */
ctrl |= (data[0]&1)<<4; /* ... OR in new BCE */
brm->regs->ctrl = ctrl;
start_operation(brm);
break;
case BRM_TX_BLOCK:
brm->tx_blocking = data[0];
break;
case BRM_RX_BLOCK:
brm->rx_blocking = data[0];
break;
case BRM_DO_LIST:
if ( brm->mode != BRM_MODE_BC ){
return RTEMS_INVALID_NAME;
}
/* Check if we are bus controller */
if ( ((READ_REG(&brm->regs->oper)>>8) & 3) != 0 ) {
return RTEMS_INVALID_NAME;
}
/* Already processing list? */
if (is_executing(brm)) {
return RTEMS_RESOURCE_IN_USE;
}
/* clear any earlier releases */
rtems_semaphore_obtain(brm->tx_sem, RTEMS_NO_WAIT, RTEMS_NO_TIMEOUT);
brm->bc_list_fail = 0;
brm->cur_list = cmd_list;
brm->regs->dpoint = 0;
i = 0;
while ( (cmd_list[i].ctrl & BC_EOL) == 0) {
ctrl = (4<<12) | (((cmd_list[i].ctrl&BC_BUSA)==BC_BUSA)<<9) | (((cmd_list[i].ctrl&BC_RTRT)==BC_RTRT)<<8);
if (cmd_list[i].ctrl&BC_RTRT) {
cw1 = (cmd_list[i].rtaddr[0]<<11) | (0<<10) | (cmd_list[i].subaddr[0]<<5) | (cmd_list[i].wc & 0x1f); /* receive cw */
cw2 = (cmd_list[i].rtaddr[1]<<11) | (1<<10) | (cmd_list[i].subaddr[1]<<5) | (cmd_list[i].wc & 0x1f); /* transmit cw */
}
else {
cw1 = (cmd_list[i].rtaddr[0]<<11) | (((cmd_list[i].ctrl&BC_TR)==BC_TR)<<10) | (cmd_list[i].subaddr[0]<<5) | (cmd_list[i].wc&0x1f);
cw2 = 0;
}
/* Set up command block */
brm->bcmem->descs[i].ctrl = ctrl;
brm->bcmem->descs[i].cw1 = cw1;
brm->bcmem->descs[i].cw2 = cw2;
/* data pointer:
* (&brm->bcmem->msg_data[i].data[0] & 0x1ffff) / 2
*/
brm->bcmem->descs[i].dptr = 1024+i*32; /* data pointer */
brm->bcmem->descs[i].tsw[0] = 0;
brm->bcmem->descs[i].tsw[1] = 0;
brm->bcmem->descs[i].ba = 0;
brm->bcmem->descs[i].timer = 0;
memcpy((void *)&brm->bcmem->msg_data[i].data[0], &cmd_list[i].data[0], cmd_list[i].wc*2);
i++;
}
brm->bcmem->descs[i].ctrl = 0; /* end of list */
start_operation(brm);
break;
case BRM_LIST_DONE:
if ( brm->mode != BRM_MODE_BC ){
return RTEMS_INVALID_NAME;
}
/* Check if we are bus controller */
if ( ((READ_REG(&brm->regs->oper)>>8) & 3) != 0 ) {
return RTEMS_INVALID_NAME;
}
if (is_executing(brm)) {
data[0] = 0;
if (brm->tx_blocking) {
rtems_semaphore_obtain(brm->tx_sem, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
data[0] = 1;
if ( brm->bc_list_fail ){
return RTEMS_INVALID_NAME;
}
}else{
return RTEMS_RESOURCE_IN_USE;
}
}
else {
data[0] = 1; /* done */
}
/* copy finished list results back into bc_msg array */
i = 0;
while ( (brm->cur_list[i].ctrl & BC_EOL) == 0) {
if (READ_DMA(&brm->bcmem->descs[i].ctrl) & 1) {
brm->cur_list[i].ctrl |= 0x8000; /* Set BAME */
}
if (brm->cur_list[i].ctrl & BC_TR) {
/* RT Transmit command, copy received data */
len = brm->cur_list[i].wc;
while( len-- > 0){
brm->cur_list[i].data[len] = READ_DMA(&brm->bcmem->msg_data[i].data[len]);
}
}
brm->cur_list[i].tsw[0] = READ_DMA(&brm->bcmem->descs[i].tsw[0]);
brm->cur_list[i].tsw[1] = READ_DMA(&brm->bcmem->descs[i].tsw[1]);
i++;
}
break;
case BRM_CLR_STATUS:
brm->status = 0;
break;
case BRM_GET_STATUS: /* copy status */
if ( !ioarg->buffer )
return RTEMS_INVALID_NAME;
*(unsigned int *)ioarg->buffer = brm->status;
break;
case BRM_SET_EVENTID:
brm->event_id = (rtems_id)ioarg->buffer;
break;
default:
return RTEMS_NOT_DEFINED;
}
return RTEMS_SUCCESSFUL;
}
#ifdef B1553BRM_DEFINE_INTHANDLER
static void b1553brm_interrupt_handler(rtems_vector_number v){
int i;
/* find minor */
for(i=0; i<brm_cores; i++){
if ( (brms[i].irqno+0x10) == v ){
brm_interrupt(&brms[i]);
return;
}
}
}
#endif
static void brm_interrupt(brm_priv *brm) {
unsigned short descriptor, current, pending, miw, wc, tmp;
unsigned short msgadr, iaw, iiw;
int len;
int signal_event=0;
unsigned int event_status=0;
#define SET_ERROR_DESCRIPTOR(descriptor) (event_status = (event_status & 0x0000ffff) | descriptor<<16)
while( (iiw=READ_REG(&brm->irq_log[brm->irq].iiw)) != 0xffff ){
iaw=READ_REG(&brm->irq_log[brm->irq].iaw);
/* indicate that the interrupt log entry has been processed */
brm->irq_log[brm->irq].iiw = 0xffff;
/* Interpret interrupt log entry */
descriptor = iaw >> 2;
pending = iiw;
brm->irq = (brm->irq + 1) % 16;
/* Clear the log so that we */
/* Subaddress accessed irq (RT only)
*
* Can be either a receive or transmit command
* as well as a mode code.
*/
if (pending & BRM_SUBAD_IRQ) {
/* Pointer to next free message in circular buffer */
current = READ_DMA(&brm->desc[descriptor].cur);
while ( (msgadr=brm->last_read[descriptor]) != current) {
/* Get word count */
miw = READ_DMA(&brm->mem[msgadr]);
wc = miw >> 11;
/* Data received */
if (descriptor < 32) {
wc = wc ? wc : 32;
}
/* Data transmitted */
else if (descriptor < 64) {
wc = wc ? wc : 32;
rtems_semaphore_release(brm->tx_sem);
}
/* RX Mode code */
else if (descriptor < 96) {
wc = (wc>>4);
}
/* TX Mode code */
else if (descriptor < 128) {
wc = (wc>>4);
}
#ifdef DEBUG
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = (descriptor << 16) | wc;
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = current;
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = msgadr;
#endif
/* If there is room in the event queue, copy the event there */
if (brm->head - brm->tail != EVENT_QUEUE_SIZE) {
/* Copy to event queue */
brm->rt_event[INDEX(brm->head)].miw = READ_DMA(&brm->mem[msgadr]);
brm->rt_event[INDEX(brm->head)].time = READ_DMA(&brm->mem[msgadr+1]);
len = wc;
while( len-- > 0){
brm->rt_event[INDEX(brm->head)].data[len] = READ_DMA(&brm->mem[msgadr+2+len]);
}
brm->rt_event[INDEX(brm->head)].desc = descriptor;
brm->head++;
}
else {
/* Indicate overrun */
brm->rt_event[INDEX(brm->head)].desc |= 0x8000;
}
msgadr += (2+wc);
if (msgadr >= brm->desc[descriptor].bot) {
msgadr = brm->desc[descriptor].top;
}
brm->last_read[descriptor] = msgadr;
#ifdef DEBUG
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = msgadr;
#endif
/* Wake any blocked rx thread */
rtems_semaphore_release(brm->rx_sem);
}
}
if (pending & BRM_EOL_IRQ) {
rtems_semaphore_release(brm->tx_sem);
}
if (pending & BRM_BC_ILLCMD_IRQ) {
brm->bc_list_fail = 1;
rtems_semaphore_release(brm->tx_sem);
SET_ERROR_DESCRIPTOR(descriptor);
FUNCDBG("BRM: ILLCMD IRQ\n\r");
}
/* Monitor irq */
if (pending & BRM_MBC_IRQ) {
stop_operation(brm);
brm->regs->mbc = 1;
start_operation(brm);
/* If there is room in the event queue, copy the event there */
if (brm->head - brm->tail != EVENT_QUEUE_SIZE) {
/* Copy to event queue */
brm->bm_event[INDEX(brm->head)].miw = READ_DMA(&brm->mem[0]);
brm->bm_event[INDEX(brm->head)].cw1 = READ_DMA(&brm->mem[1]);
brm->bm_event[INDEX(brm->head)].cw2 = READ_DMA(&brm->mem[2]);
brm->bm_event[INDEX(brm->head)].sw1 = READ_DMA(&brm->mem[4]);
brm->bm_event[INDEX(brm->head)].sw2 = READ_DMA(&brm->mem[5]);
brm->bm_event[INDEX(brm->head)].time = READ_DMA(&brm->mem[6]);
len = 32;
while ( len-- ){
brm->bm_event[INDEX(brm->head)].data[len] = READ_DMA(&brm->mem[0x100+len]);
len--;
brm->bm_event[INDEX(brm->head)].data[len] = READ_DMA(&brm->mem[0x100+len]);
len--;
brm->bm_event[INDEX(brm->head)].data[len] = READ_DMA(&brm->mem[0x100+len]);
len--;
brm->bm_event[INDEX(brm->head)].data[len] = READ_DMA(&brm->mem[0x100+len]);
}
/* memcpy((void *)brm->bm_event[INDEX(brm->head)].data, &brm->mem[0x100], 32);*/
#ifdef DEBUG
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = READ_REG(&brm->regs->mbc);
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = READ_DMA(&brm->mem[0]);
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = READ_DMA(&brm->mem[1]);
brm->log[brm->log_i++ % EVENT_QUEUE_SIZE] = READ_DMA(&brm->mem[4]);
#endif
brm->head++;
}
else {
/* Indicate overrun */
brm->rt_event[INDEX(brm->head)].miw |= 0x8000;
}
/* Wake any blocking thread */
rtems_semaphore_release(brm->rx_sem);
}
/* The reset of the interrupts
* cause a event to be signalled
* so that user can handle error.
*/
if ( pending & BRM_RT_ILLCMD_IRQ){
FUNCDBG("BRM: BRM_RT_ILLCMD_IRQ\n\r");
brm->status |= BRM_RT_ILLCMD_IRQ;
event_status |= BRM_RT_ILLCMD_IRQ;
SET_ERROR_DESCRIPTOR(descriptor);
signal_event=1;
}
if ( pending & BRM_ILLOP_IRQ){
FUNCDBG("BRM: BRM_ILLOP_IRQ\n\r");
brm->bc_list_fail = 1;
rtems_semaphore_release(brm->tx_sem);
event_status |= BRM_ILLOP_IRQ;
SET_ERROR_DESCRIPTOR(descriptor);
signal_event=1;
}
if ( pending & BRM_MERR_IRQ){
FUNCDBG("BRM: BRM_MERR_IRQ\n\r");
event_status |= BRM_MERR_IRQ;
SET_ERROR_DESCRIPTOR(descriptor);
signal_event=1;
}
/* Clear Block Accessed Bit */
tmp = READ_REG(&brm->desc[descriptor].ctrl);
brm->desc[descriptor].ctrl = tmp & ~0x10;
} /* While */
/* clear interrupt flags & handle Hardware errors */
pending = READ_REG(&brm->regs->ipend);
if ( pending & BRM_DMAF_IRQ){
FUNCDBG("BRM: BRM_DMAF_IRQ\n\r");
event_status |= BRM_DMAF_IRQ;
signal_event=1;
}
if ( pending & BRM_WRAPF_IRQ){
FUNCDBG("BRM: BRM_WRAPF_IRQ\n\r");
event_status |= BRM_WRAPF_IRQ;
signal_event=1;
}
if ( pending & BRM_TAPF_IRQ){
FUNCDBG("BRM: BRM_TAPF_IRQ\n\r");
event_status |= BRM_TAPF_IRQ;
signal_event=1;
}
/* Copy current mask to status mask */
if ( event_status ){
if ( event_status & 0xffff0000 )
brm->status &= 0x0000ffff;
brm->status |= event_status;
}
/* signal event once */
if ( signal_event && (brm->event_id!=0) ){
rtems_event_send(brm->event_id, event_status);
}
}