Modbus: fixed typo in ctype typing.
#include <pthread.h>
#include <errno.h>
#include "iec_types_all.h"
#include "POUS.h"
#include "config.h"
#include "beremiz.h"
#define DEFAULT_REFRESH_PERIOD_MS 100
#define HMI_BUFFER_SIZE %(buffer_size)d
#define HMI_ITEM_COUNT %(item_count)d
#define HMI_HASH_SIZE 8
static uint8_t hmi_hash[HMI_HASH_SIZE] = {%(hmi_hash_ints)s};
/* PLC reads from that buffer */
static char rbuf[HMI_BUFFER_SIZE];
/* PLC writes to that buffer */
static char wbuf[HMI_BUFFER_SIZE];
/* TODO change that in case of multiclient... */
/* worst biggest send buffer. FIXME : use dynamic alloc ? */
static char sbuf[HMI_HASH_SIZE + HMI_BUFFER_SIZE + (HMI_ITEM_COUNT * sizeof(uint32_t))];
static unsigned int sbufidx;
%(extern_variables_declarations)s
#define ticktime_ns %(PLC_ticktime)d
static uint16_t ticktime_ms = (ticktime_ns>1000000)?
ticktime_ns/1000000:
1;
typedef enum {
buf_free = 0,
buf_new,
buf_set,
buf_tosend
} buf_state_t;
static int global_write_dirty = 0;
typedef struct {
void *ptr;
__IEC_types_enum type;
uint32_t buf_index;
/* publish/write/send */
long wlock;
buf_state_t wstate;
/* zero means not subscribed */
uint16_t refresh_period_ms;
uint16_t age_ms;
/* retrieve/read/recv */
long rlock;
buf_state_t rstate;
} hmi_tree_item_t;
static hmi_tree_item_t hmi_tree_item[] = {
%(variable_decl_array)s
};
typedef int(*hmi_tree_iterator)(uint32_t, hmi_tree_item_t*);
static int traverse_hmi_tree(hmi_tree_iterator fp)
{
unsigned int i;
for(i = 0; i < sizeof(hmi_tree_item)/sizeof(hmi_tree_item_t); i++){
hmi_tree_item_t *dsc = &hmi_tree_item[i];
int res = (*fp)(i, dsc);
if(res != 0){
return res;
}
}
return 0;
}
#define __Unpack_desc_type hmi_tree_item_t
%(var_access_code)s
static int write_iterator(uint32_t index, hmi_tree_item_t *dsc)
{
if(AtomicCompareExchange(&dsc->wlock, 0, 1) == 0)
{
if(dsc->wstate == buf_set){
/* if being subscribed */
if(dsc->refresh_period_ms){
if(dsc->age_ms + ticktime_ms < dsc->refresh_period_ms){
dsc->age_ms += ticktime_ms;
}else{
dsc->wstate = buf_tosend;
global_write_dirty = 1;
}
}
}
void *dest_p = &wbuf[dsc->buf_index];
void *real_value_p = NULL;
char flags = 0;
void *visible_value_p = UnpackVar(dsc, &real_value_p, &flags);
/* if new value differs from previous one */
USINT sz = __get_type_enum_size(dsc->type);
if(__Is_a_string(dsc)){
sz = ((STRING*)visible_value_p)->len + 1;
}
if(dsc->wstate == buf_new /* just subscribed
or already subscribed having value change */
|| (dsc->refresh_period_ms > 0 && memcmp(dest_p, visible_value_p, sz) != 0)){
/* copy and flag as set */
memcpy(dest_p, visible_value_p, sz);
/* if not already marked/signaled, do it */
if(dsc->wstate != buf_set && dsc->wstate != buf_tosend) {
if(dsc->wstate == buf_new || ticktime_ms > dsc->refresh_period_ms){
dsc->wstate = buf_tosend;
global_write_dirty = 1;
} else {
dsc->wstate = buf_set;
}
dsc->age_ms = 0;
}
}
AtomicCompareExchange(&dsc->wlock, 1, 0);
}
// else ... : PLC can't wait, variable will be updated next turn
return 0;
}
static int send_iterator(uint32_t index, hmi_tree_item_t *dsc)
{
while(AtomicCompareExchange(&dsc->wlock, 0, 1)) sched_yield();
if(dsc->wstate == buf_tosend)
{
uint32_t sz = __get_type_enum_size(dsc->type);
if(sbufidx + sizeof(uint32_t) + sz <= sizeof(sbuf))
{
void *src_p = &wbuf[dsc->buf_index];
void *dst_p = &sbuf[sbufidx];
if(__Is_a_string(dsc)){
sz = ((STRING*)src_p)->len + 1;
}
/* TODO : force into little endian */
memcpy(dst_p, &index, sizeof(uint32_t));
memcpy(dst_p + sizeof(uint32_t), src_p, sz);
dsc->wstate = buf_free;
sbufidx += sizeof(uint32_t) /* index */ + sz;
}
else
{
printf("BUG!!! %%d + %%ld + %%d > %%ld \n", sbufidx, sizeof(uint32_t), sz, sizeof(sbuf));
AtomicCompareExchange(&dsc->wlock, 1, 0);
return EOVERFLOW;
}
}
AtomicCompareExchange(&dsc->wlock, 1, 0);
return 0;
}
static int read_iterator(uint32_t index, hmi_tree_item_t *dsc)
{
if(AtomicCompareExchange(&dsc->rlock, 0, 1) == 0)
{
if(dsc->rstate == buf_set)
{
void *src_p = &rbuf[dsc->buf_index];
void *real_value_p = NULL;
char flags = 0;
void *visible_value_p = UnpackVar(dsc, &real_value_p, &flags);
memcpy(real_value_p, src_p, __get_type_enum_size(dsc->type));
dsc->rstate = buf_free;
}
AtomicCompareExchange(&dsc->rlock, 1, 0);
}
// else ... : PLC can't wait, variable will be updated next turn
return 0;
}
void update_refresh_period(hmi_tree_item_t *dsc, uint16_t refresh_period_ms)
{
while(AtomicCompareExchange(&dsc->wlock, 0, 1)) sched_yield();
if(refresh_period_ms) {
if(!dsc->refresh_period_ms)
{
dsc->wstate = buf_new;
}
} else {
dsc->wstate = buf_free;
}
dsc->refresh_period_ms = refresh_period_ms;
AtomicCompareExchange(&dsc->wlock, 1, 0);
}
static int reset_iterator(uint32_t index, hmi_tree_item_t *dsc)
{
update_refresh_period(dsc, 0);
return 0;
}
void SVGHMI_SuspendFromPythonThread(void);
void SVGHMI_WakeupFromRTThread(void);
static int continue_collect;
int __init_svghmi()
{
bzero(rbuf,sizeof(rbuf));
bzero(wbuf,sizeof(wbuf));
continue_collect = 1;
return 0;
}
void __cleanup_svghmi()
{
continue_collect = 0;
SVGHMI_WakeupFromRTThread();
}
void __retrieve_svghmi()
{
traverse_hmi_tree(read_iterator);
}
void __publish_svghmi()
{
global_write_dirty = 0;
traverse_hmi_tree(write_iterator);
if(global_write_dirty) {
SVGHMI_WakeupFromRTThread();
}
}
/* PYTHON CALLS */
int svghmi_send_collect(uint32_t *size, char **ptr){
SVGHMI_SuspendFromPythonThread();
if(continue_collect) {
int res;
sbufidx = HMI_HASH_SIZE;
if((res = traverse_hmi_tree(send_iterator)) == 0)
{
if(sbufidx > HMI_HASH_SIZE){
memcpy(&sbuf[0], &hmi_hash[0], HMI_HASH_SIZE);
*ptr = &sbuf[0];
*size = sbufidx;
return 0;
}
return ENODATA;
}
// printf("collected BAD result %%d\n", res);
return res;
}
else
{
return EINTR;
}
}
typedef enum {
setval = 0,
reset = 1,
subscribe = 2
} cmd_from_JS;
// Returns :
// 0 is OK, <0 is error, 1 is heartbeat
int svghmi_recv_dispatch(uint32_t size, const uint8_t *ptr){
const uint8_t* cursor = ptr + HMI_HASH_SIZE;
const uint8_t* end = ptr + size;
int was_hearbeat = 0;
/* match hmitree fingerprint */
if(size <= HMI_HASH_SIZE || memcmp(ptr, hmi_hash, HMI_HASH_SIZE) != 0)
{
printf("svghmi_recv_dispatch MISMATCH !!\n");
return -EINVAL;
}
while(cursor < end)
{
uint32_t progress;
cmd_from_JS cmd = *(cursor++);
switch(cmd)
{
case setval:
{
uint32_t index = *(uint32_t*)(cursor);
uint8_t const *valptr = cursor + sizeof(uint32_t);
if(index == heartbeat_index)
was_hearbeat = 1;
if(index < HMI_ITEM_COUNT)
{
hmi_tree_item_t *dsc = &hmi_tree_item[index];
void *real_value_p = NULL;
char flags = 0;
void *visible_value_p = UnpackVar(dsc, &real_value_p, &flags);
void *dst_p = &rbuf[dsc->buf_index];
uint32_t sz = __get_type_enum_size(dsc->type);
if(__Is_a_string(dsc)){
sz = ((STRING*)valptr)->len + 1;
}
if((valptr + sz) <= end)
{
// rescheduling spinlock until free
while(AtomicCompareExchange(&dsc->rlock, 0, 1)) sched_yield();
memcpy(dst_p, valptr, sz);
dsc->rstate = buf_set;
AtomicCompareExchange(&dsc->rlock, 1, 0);
progress = sz + sizeof(uint32_t) /* index */;
}
else
{
return -EINVAL;
}
}
else
{
return -EINVAL;
}
}
break;
case reset:
{
progress = 0;
traverse_hmi_tree(reset_iterator);
}
break;
case subscribe:
{
uint32_t index = *(uint32_t*)(cursor);
uint16_t refresh_period_ms = *(uint32_t*)(cursor + sizeof(uint32_t));
if(index < HMI_ITEM_COUNT)
{
hmi_tree_item_t *dsc = &hmi_tree_item[index];
update_refresh_period(dsc, refresh_period_ms);
}
else
{
return -EINVAL;
}
progress = sizeof(uint32_t) /* index */ +
sizeof(uint16_t) /* refresh period */;
}
break;
default:
printf("svghmi_recv_dispatch unknown %%d\n",cmd);
}
cursor += progress;
}
return was_hearbeat;
}