void type(const char* s) {
INBUF_IN = INBUF_START;
for (int i = 0; s[i] != 0; ++i) {
byte_write(INBUF_IN++, s[i]);
}
byte_write(INBUF_IN, 0);
}
/*
==============
PM_CheckDuck
Sets mins, maxs, and pm->viewheight
==============
*/
void PM_CheckDuck (void)
{
trace_t trace;
pm->mins[0] = -16;
pm->mins[1] = -16;
pm->maxs[0] = 16;
pm->maxs[1] = 16;
if (pm->s.pm_type == PM_GIB)
{
pm->mins[2] = 0;
pm->maxs[2] = 16;
pm->viewheight = 8;
return;
}
pm->mins[2] = -24;
if (pm->s.pm_type == PM_DEAD)
{
// pm->s.pm_flags |= PMF_DUCKED;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_DUCKED);
}
else if (pm->cmd.upmove < 0 && (pm->s.pm_flags & PMF_ON_GROUND) )
{ // duck
// pm->s.pm_flags |= PMF_DUCKED;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_DUCKED);
}
else
{ // stand up if possible
if (pm->s.pm_flags & PMF_DUCKED)
{
// try to stand up
pm->maxs[2] = 32;
trace = pm->trace (pml.origin, pm->mins, pm->maxs, pml.origin);
if (!trace.allsolid)
// pm->s.pm_flags &= ~PMF_DUCKED;
byte_write(&pm->s.pm_flags, pm->s.pm_flags & ~PMF_DUCKED);
}
}
if (pm->s.pm_flags & PMF_DUCKED)
{
pm->maxs[2] = 4;
pm->viewheight = -2;
}
else
{
pm->maxs[2] = 32;
pm->viewheight = 22;
}
}
/*
=============
PM_CheckSpecialMovement
=============
*/
void PM_CheckSpecialMovement (void)
{
vec3_t spot;
int cont;
vec3_t flatforward;
trace_t trace;
if (pm->s.pm_time)
return;
// pml.ladder = false;
byte_write(&pml.ladder, false);
// check for ladder
flatforward[0] = pml.forward[0];
flatforward[1] = pml.forward[1];
flatforward[2] = 0;
VectorNormalize (flatforward);
VectorMA (pml.origin, 1, flatforward, spot);
trace = pm->trace (pml.origin, pm->mins, pm->maxs, spot);
if ((trace.fraction < 1) && (trace.contents & CONTENTS_LADDER))
// pml.ladder = true;
byte_write(&pml.ladder, true);
// check for water jump
if (pm->waterlevel != 2)
return;
VectorMA (pml.origin, 30, flatforward, spot);
spot[2] += 4;
cont = pm->pointcontents (spot);
if (!(cont & CONTENTS_SOLID))
return;
spot[2] += 16;
cont = pm->pointcontents (spot);
if (cont)
return;
// jump out of water
VectorScale (flatforward, 50, pml.velocity);
pml.velocity[2] = 350;
// pm->s.pm_flags |= PMF_TIME_WATERJUMP;
// pm->s.pm_time = 255;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_TIME_WATERJUMP);
byte_write(&pm->s.pm_time, 255);
}
/*
=============
PM_CheckJump
=============
*/
void PM_CheckJump (void)
{
if (pm->s.pm_flags & PMF_TIME_LAND)
{ // hasn't been long enough since landing to jump again
return;
}
if (pm->cmd.upmove < 10)
{ // not holding jump
// pm->s.pm_flags &= ~PMF_JUMP_HELD;
byte_write(&pm->s.pm_flags, pm->s.pm_flags & ~PMF_JUMP_HELD);
return;
}
// must wait for jump to be released
if (pm->s.pm_flags & PMF_JUMP_HELD)
return;
if (pm->s.pm_type == PM_DEAD)
return;
if (pm->waterlevel >= 2)
{ // swimming, not jumping
pm->groundentity = NULL;
if (pml.velocity[2] <= -300)
return;
if (pm->watertype == CONTENTS_WATER)
pml.velocity[2] = 100;
else if (pm->watertype == CONTENTS_SLIME)
pml.velocity[2] = 80;
else
pml.velocity[2] = 50;
return;
}
if (pm->groundentity == NULL)
return; // in air, so no effect
// pm->s.pm_flags |= PMF_JUMP_HELD;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_JUMP_HELD);
pm->groundentity = NULL;
pml.velocity[2] += 270;
if (pml.velocity[2] < 270)
pml.velocity[2] = 270;
}
/**
* Initialize the on-chip timer controller. We snag TMU channel 2 in its
* highest resolution mode, and start it counting down from max_int.
*/
void timer_init() {
unsigned int val = byte_read(TSTR);
byte_write( TSTR, val & (~(1<<TMU_CHANNEL)) ); /* Stop counter */
long_write( TCOR(TMU_CHANNEL), 0xFFFFFFFF );
long_write( TCNT(TMU_CHANNEL), 0xFFFFFFFF );
word_write( TCR(TMU_CHANNEL), 0x00000000 );
}
int bitSWrite(BitStream *bs,char * file)
{
FILE * fp;
int nw,i;
DListE *e;
fp=fopen(file,"wt");
assert(fp);
assert(0==bs->nu);
byte_write(fp,bs->nu);
assert(bs->pe==0xb7);
byte_write(fp,bs->pe);
assert(get_cr(28)==0);//reserved==0
for(i=0;i<4;i++)
{
byte_write(fp,bs->cregs[i]);
}
// byte_write(fp,bs->idunno);
nw=dlistCount(&bs->windows);
byte_write(fp,(nw>>8)&0x0ff);
byte_write(fp,nw&0x0ff);
e=dlistFirst(&bs->windows);
while(e)
{
BitSWindow * w=(BitSWindow *)e;
window_write(fp,w);
e=dlistENext(e);
}
assert(bs->po==0xe7);
byte_write(fp,bs->po);
fclose(fp);
return 0;
}
bool fwh_write_address(FWH *fwh, uint32_t addr, uint8_t byte)
{
fwh_start(fwh, FWH_START_WRITE);
fwh_nibble_write(fwh, 0); /* IDSEL hardwired */
fwh_send_imaddr(fwh, addr);
fwh_nibble_write(fwh, 0); /* IMSIZE single byte */
byte_write(fwh->clock, fwh->nibble, byte);
nibble_write(fwh->nibble, 0xf);
nibble_set_dir(fwh->nibble, INPUT);
clock_cycle(fwh->clock);
clock_cycle(fwh->clock);
if (!nibble_ready_sync(fwh->clock, fwh->nibble))
return false;
clock_cycle(fwh->clock);
return true;
}
static void window_write(FILE *fp,BitSWindow *w)
{
int nbytes,i;
byte_write(fp,w->sa[0]);
byte_write(fp,w->sa[1]);
byte_write(fp,w->sa[2]);
byte_write(fp,w->ea[0]);
byte_write(fp,w->ea[1]);
byte_write(fp,w->ea[2]);
nbytes=a2nb(w->sa,w->ea);
for(i=0;i<nbytes;i++)
{
byte_write(fp,w->bytes[i]);
}
}
/***********************************************************************
[function]:
callback: burn the FW to ctpm.
[parameters]:
pbt_buf[in]: point to Head+FW ;
dw_lenth[in]: the length of the FW + 6(the Head length);
[return]:
ERR_OK: no error;
ERR_MODE: fail to switch to UPDATE mode;
ERR_READID: read id fail;
ERR_ERASE: erase chip fail;
ERR_STATUS: status error;
ERR_ECC: ecc error.
************************************************************************/
E_UPGRADE_ERR_TYPE fts_ctpm_fw_upgrade(u8* pbt_buf, int dw_lenth)
{
u8 cmd,reg_val[2] = {0};
u8 buffer[2] = {0};
u8 packet_buf[FTS_PACKET_LENGTH + 6];
u8 auc_i2c_write_buf[10];
u8 bt_ecc;
int j,temp,lenght,i_ret,packet_number, i = 0;
int i_is_new_protocol = 0;
/******write 0xaa to register 0xfc******/
cmd=0xaa;
fts_register_write(0xfc,&cmd);
mdelay(50);
/******write 0x55 to register 0xfc******/
cmd=0x55;
fts_register_write(0xfc,&cmd);
printk("[TSP] Step 1: Reset CTPM test\n");
mdelay(10);
/*******Step 2:Enter upgrade mode ****/
printk("\n[TSP] Step 2:enter new update mode\n");
auc_i2c_write_buf[0] = 0x55;
auc_i2c_write_buf[1] = 0xaa;
do
{
i ++;
i_ret = fts_i2c_txdata(auc_i2c_write_buf, 2);
mdelay(5);
} while(i_ret <= 0 && i < 10 );
if (i > 1)
{
i_is_new_protocol = 1;
}
/********Step 3:check READ-ID********/
cmd_write(0x90,0x00,0x00,0x00,4);
byte_read(reg_val,2);
if (reg_val[0] == 0x79 && reg_val[1] == 0x3)
{
printk("[TSP] Step 3: CTPM ID,ID1 = 0x%x,ID2 = 0x%x\n",reg_val[0],reg_val[1]);
}
else
{
return ERR_READID;
//i_is_new_protocol = 1;
}
/*********Step 4:erase app**********/
if (i_is_new_protocol)
{
cmd_write(0x61,0x00,0x00,0x00,1);
}
else
{
cmd_write(0x60,0x00,0x00,0x00,1);
}
mdelay(1500);
printk("[TSP] Step 4: erase. \n");
/*Step 5:write firmware(FW) to ctpm flash*/
bt_ecc = 0;
printk("[TSP] Step 5: start upgrade. \n");
dw_lenth = dw_lenth - 8;
packet_number = (dw_lenth) / FTS_PACKET_LENGTH;
packet_buf[0] = 0xbf;
packet_buf[1] = 0x00;
for (j=0; j<packet_number; j++)
{
temp = j * FTS_PACKET_LENGTH;
packet_buf[2] = (u8)(temp>>8);
packet_buf[3] = (u8)temp;
lenght = FTS_PACKET_LENGTH;
packet_buf[4] = (u8)(lenght>>8);
packet_buf[5] = (u8)lenght;
for (i=0; i<FTS_PACKET_LENGTH; i++)
{
packet_buf[6+i] = pbt_buf[j*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(&packet_buf[0],FTS_PACKET_LENGTH + 6);
mdelay(FTS_PACKET_LENGTH/6 + 1);
if ((j * FTS_PACKET_LENGTH % 1024) == 0)
{
printk("[TSP] upgrade the 0x%x th byte.\n", ((unsigned int)j) * FTS_PACKET_LENGTH);
}
}
if ((dw_lenth) % FTS_PACKET_LENGTH > 0)
{
temp = packet_number * FTS_PACKET_LENGTH;
packet_buf[2] = (u8)(temp>>8);
packet_buf[3] = (u8)temp;
temp = (dw_lenth) % FTS_PACKET_LENGTH;
packet_buf[4] = (u8)(temp>>8);
packet_buf[5] = (u8)temp;
for (i=0; i<temp; i++)
{
packet_buf[6+i] = pbt_buf[ packet_number*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(&packet_buf[0],temp+6);
mdelay(20);
}
E_UPGRADE_ERR_TYPE fts_ctpm_fw_upgrade(struct i2c_client *client,FTS_BYTE* pbt_buf, FTS_DWRD dw_lenth)
{
// FTS_BYTE cmd_len = 0;
FTS_BYTE reg_val[2] = {0};
FTS_DWRD i = 0;
// FTS_BYTE ecc = 0;
FTS_DWRD packet_number;
FTS_DWRD j;
FTS_DWRD temp;
FTS_DWRD lenght;
FTS_BYTE packet_buf[FTS_PACKET_LENGTH + 6];
FTS_BYTE auc_i2c_write_buf[10];
FTS_BYTE bt_ecc;
/*********Step 1:Reset CTPM *****/
/*write 0xaa to register 0xfc*/
Fts_i2c_write(client,0xfc,0xaa);
delay_ms(50);
/*write 0x55 to register 0xfc*/
Fts_i2c_write(client,0xfc,0x55);
pr_info("Step 1: Reset CTPM test\n");
delay_ms(40);
/*********Step 2:Enter upgrade mode *****/
auc_i2c_write_buf[0] = 0x55;
auc_i2c_write_buf[1] = 0xaa;
i2c_master_send(client, auc_i2c_write_buf, 2);
pr_info("Step 2: Enter update mode. \n");
/*********Step 3:check READ-ID***********************/
/*send the opration head*/
do{
if(i > 3)
{
return ERR_READID;
}
/*read out the CTPM ID*/
cmd_write(client,0x90,0x00,0x00,0x00,4);
byte_read(client,reg_val,2);
i++;
pr_info("Step 3: CTPM ID,ID1 = 0x%x,ID2 = 0x%x\n",reg_val[0],reg_val[1]);
}while(reg_val[0] != 0x79 || reg_val[1] != 0x03);
/*********Step 4:erase app*******************************/
cmd_write(client,0x61,0x00,0x00,0x00,1);
delay_ms(1500);
pr_info("Step 4: erase. \n");
/*********Step 5:write firmware(FW) to ctpm flash*********/
bt_ecc = 0;
pr_info("Step 5: start upgrade. \n");
dw_lenth = dw_lenth - 8;
packet_number = (dw_lenth) / FTS_PACKET_LENGTH;
packet_buf[0] = 0xbf;
packet_buf[1] = 0x00;
for (j=0;j<packet_number;j++)
{
temp = j * FTS_PACKET_LENGTH;
packet_buf[2] = (FTS_BYTE)(temp>>8);
packet_buf[3] = (FTS_BYTE)temp;
lenght = FTS_PACKET_LENGTH;
packet_buf[4] = (FTS_BYTE)(lenght>>8);
packet_buf[5] = (FTS_BYTE)lenght;
for (i=0;i<FTS_PACKET_LENGTH;i++)
{
packet_buf[6+i] = pbt_buf[j*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(client,&packet_buf[0],FTS_PACKET_LENGTH + 6);
delay_ms(FTS_PACKET_LENGTH/6 + 1);
if ((j * FTS_PACKET_LENGTH % 1024) == 0)
{
pr_info("upgrade the 0x%x th byte.\n", ((unsigned int)j) * FTS_PACKET_LENGTH);
}
}
if ((dw_lenth) % FTS_PACKET_LENGTH > 0)
{
temp = packet_number * FTS_PACKET_LENGTH;
packet_buf[2] = (FTS_BYTE)(temp>>8);
packet_buf[3] = (FTS_BYTE)temp;
temp = (dw_lenth) % FTS_PACKET_LENGTH;
packet_buf[4] = (FTS_BYTE)(temp>>8);
packet_buf[5] = (FTS_BYTE)temp;
for (i=0;i<temp;i++)
{
packet_buf[6+i] = pbt_buf[ packet_number*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(client,&packet_buf[0],temp+6);
delay_ms(20);
}
/*
=============
PM_CatagorizePosition
=============
*/
void PM_CatagorizePosition (void)
{
vec3_t point;
int cont;
trace_t trace;
int sample1;
int sample2;
// if the player hull point one unit down is solid, the player
// is on ground
// see if standing on something solid
point[0] = pml.origin[0];
point[1] = pml.origin[1];
point[2] = pml.origin[2] - 0.25;
if (pml.velocity[2] > 180) //!!ZOID changed from 100 to 180 (ramp accel)
{
// pm->s.pm_flags &= ~PMF_ON_GROUND;
byte_write(&pm->s.pm_flags, pm->s.pm_flags & ~PMF_ON_GROUND);
pm->groundentity = NULL;
}
else
{
trace = pm->trace (pml.origin, pm->mins, pm->maxs, point);
pml.groundplane = trace.plane;
pml.groundsurface = trace.surface;
pml.groundcontents = trace.contents;
if (!trace.ent || (trace.plane.normal[2] < 0.7 && !trace.startsolid) )
{
pm->groundentity = NULL;
// pm->s.pm_flags &= ~PMF_ON_GROUND;
byte_write(&pm->s.pm_flags, pm->s.pm_flags & ~PMF_ON_GROUND);
}
else
{
pm->groundentity = trace.ent;
// hitting solid ground will end a waterjump
if (pm->s.pm_flags & PMF_TIME_WATERJUMP)
{
// pm->s.pm_flags &= ~(PMF_TIME_WATERJUMP | PMF_TIME_LAND | PMF_TIME_TELEPORT);
// pm->s.pm_time = 0;
byte_write(&pm->s.pm_flags, pm->s.pm_flags & ~(PMF_TIME_WATERJUMP | PMF_TIME_LAND | PMF_TIME_TELEPORT));
byte_write(&pm->s.pm_time, 0);
}
if (! (pm->s.pm_flags & PMF_ON_GROUND) )
{ // just hit the ground
// pm->s.pm_flags |= PMF_ON_GROUND;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_ON_GROUND);
// don't do landing time if we were just going down a slope
if (pml.velocity[2] < -200)
{
// pm->s.pm_flags |= PMF_TIME_LAND;
byte_write(&pm->s.pm_flags, pm->s.pm_flags | PMF_TIME_LAND);
// don't allow another jump for a little while
if (pml.velocity[2] < -400)
// pm->s.pm_time = 25;
byte_write(&pm->s.pm_time, 25);
else
// pm->s.pm_time = 18;
byte_write(&pm->s.pm_time, 18);
}
}
}
#if 0
if (trace.fraction < 1.0 && trace.ent && pml.velocity[2] < 0)
pml.velocity[2] = 0;
#endif
if (pm->numtouch < MAXTOUCH && trace.ent)
{
pm->touchents[pm->numtouch] = trace.ent;
pm->numtouch++;
}
}
//
// get waterlevel, accounting for ducking
//
pm->waterlevel = 0;
pm->watertype = 0;
sample2 = (int)(pm->viewheight - pm->mins[2]);
sample1 = sample2 / 2;
point[2] = pml.origin[2] + pm->mins[2] + 1;
cont = pm->pointcontents (point);
if (cont & MASK_WATER)
{
pm->watertype = cont;
pm->waterlevel = 1;
point[2] = pml.origin[2] + pm->mins[2] + sample1;
cont = pm->pointcontents (point);
if (cont & MASK_WATER)
{
pm->waterlevel = 2;
point[2] = pml.origin[2] + pm->mins[2] + sample2;
cont = pm->pointcontents (point);
if (cont & MASK_WATER)
pm->waterlevel = 3;
}
}
}
/*
================
Pmove
Can be called by either the server or the client
================
*/
void Pmove (pmove_t *pmove)
{
pm = pmove;
// clear results
pm->numtouch = 0;
VectorClear (pm->viewangles);
pm->viewheight = 0;
pm->groundentity = 0;
pm->watertype = 0;
pm->waterlevel = 0;
// clear all pmove local vars
memset (&pml, 0, sizeof(pml));
// convert origin and velocity to float values
pml.origin[0] = pm->s.origin[0]*0.125;
pml.origin[1] = pm->s.origin[1]*0.125;
pml.origin[2] = pm->s.origin[2]*0.125;
pml.velocity[0] = pm->s.velocity[0]*0.125;
pml.velocity[1] = pm->s.velocity[1]*0.125;
pml.velocity[2] = pm->s.velocity[2]*0.125;
// save old org in case we get stuck
VectorCopy (pm->s.origin, pml.previous_origin);
pml.frametime = pm->cmd.msec * 0.001;
PM_ClampAngles ();
if (pm->s.pm_type == PM_SPECTATOR)
{
PM_FlyMove (false);
PM_SnapPosition ();
return;
}
if (pm->s.pm_type >= PM_DEAD)
{
pm->cmd.forwardmove = 0;
pm->cmd.sidemove = 0;
pm->cmd.upmove = 0;
}
if (pm->s.pm_type == PM_FREEZE)
return; // no movement at all
// set mins, maxs, and viewheight
PM_CheckDuck ();
if (pm->snapinitial)
PM_InitialSnapPosition ();
// set groundentity, watertype, and waterlevel
PM_CatagorizePosition ();
if (pm->s.pm_type == PM_DEAD)
PM_DeadMove ();
PM_CheckSpecialMovement ();
// drop timing counter
if (pm->s.pm_time)
{
int msec;
msec = pm->cmd.msec >> 3;
if (!msec)
msec = 1;
if ( msec >= pm->s.pm_time)
{
// pm->s.pm_flags &= ~(PMF_TIME_WATERJUMP | PMF_TIME_LAND | PMF_TIME_TELEPORT);
// pm->s.pm_time = 0;
byte_write(&pm->s.pm_time, 0);
byte_write(&pm->s.pm_flags,
pm->s.pm_flags & ~(PMF_TIME_WATERJUMP | PMF_TIME_LAND | PMF_TIME_TELEPORT));
}
else
pm->s.pm_time -= msec;
}
void timer_run() {
byte_write( TSTR, byte_read(TSTR) | (1<<TMU_CHANNEL) );
}
/*
[function]:
burn the FW to ctpm.
[parameters]:(ref. SPEC)
pbt_buf[in] :point to Head+FW ;
dw_lenth[in]:the length of the FW + 6(the Head length);
bt_ecc[in] :the ECC of the FW
[return]:
ERR_OK :no error;
ERR_MODE :fail to switch to UPDATE mode;
ERR_READID :read id fail;
ERR_ERASE :erase chip fail;
ERR_STATUS :status error;
ERR_ECC :ecc error.
*/
static E_UPGRADE_ERR_TYPE ft5x0x_fw_upgrade(struct ft5x0x_data *ft5x0x, u8* pbt_buf, int dw_lenth)
{
int i = 0,j = 0,i_ret;
int packet_number;
int temp,lenght;
u8 packet_buf[FTS_PACKET_LENGTH + 6];
u8 auc_i2c_write_buf[10];
u8 reg_val[2] = {0};
u8 ctpm_id[2] = {0};
u8 cmd[4];
u8 bt_ecc;
/*********Step 1:Reset CTPM *****/
/*write 0xaa to register 0xfc*/
ft5x0x_write_reg(0xfc,0xaa);
msleep(50);
/*write 0x55 to register 0xfc*/
ft5x0x_write_reg(0xfc,0x55);
printk("[FTS] Step 1: Reset CTPM.\n");
msleep(30);
/*********Step 2:Enter upgrade mode *****/
auc_i2c_write_buf[0] = 0x55;
auc_i2c_write_buf[1] = 0xaa;
do{
i ++;
i_ret = byte_write(auc_i2c_write_buf, 2);
mdelay(5);
}while(i_ret <= 0 && i < 5 );
msleep(20);
/*********Step 3:check READ-ID**********/
if(ft5x0x->id == FT5606){
ctpm_id[0] = FT56_CTPM_ID_L;
ctpm_id[1] = FT56_CTPM_ID_H;
}else{
ctpm_id[0] = FT5X_CTPM_ID_L;
ctpm_id[1] = FT5X_CTPM_ID_H;
}
cmd[0] = 0x90;
cmd[1] = 0x00;
cmd[2] = 0x00;
cmd[3] = 0x00;
cmd_write(cmd,4);
byte_read(reg_val,2);
if (reg_val[0] == ctpm_id[0] && reg_val[1] == ctpm_id[1]){
printk("[FTS] Step 3: CTPM ID,ID1 = 0x%x,ID2 = 0x%x\n",reg_val[0],reg_val[1]);
}else{
printk("[FTS] ID_ERROR: CTPM ID,ID1 = 0x%x,ID2 = 0x%x\n",reg_val[0],reg_val[1]);
return ERR_READID;
}
cmd[0] = 0xcd;
cmd_write(cmd,1);
byte_read(reg_val,1);
printk("[FTS] bootloader version = 0x%x\n", reg_val[0]);
/******Step 4:erase app and panel paramenter area *********/
cmd[0] = 0x61;
cmd_write(cmd,1); //erase app area
msleep(1500);
cmd[0] = 0x63;
cmd_write(cmd,1); //erase panel parameter area
msleep(100);
printk("[FTS] Step 4: erase. \n");
/*********Step 5:write firmware(FW) to ctpm flash*********/
bt_ecc = 0;
printk("[FTS] Step 5: start upgrade. \n");
dw_lenth = dw_lenth - 8;
packet_number = (dw_lenth) / FTS_PACKET_LENGTH;
packet_buf[0] = 0xbf;
packet_buf[1] = 0x00;
for (j=0;j<packet_number;j++){
temp = j * FTS_PACKET_LENGTH;
packet_buf[2] = (u8)(temp>>8);
packet_buf[3] = (u8)temp;
lenght = FTS_PACKET_LENGTH;
packet_buf[4] = (u8)(lenght>>8);
packet_buf[5] = (u8)lenght;
for (i=0;i<FTS_PACKET_LENGTH;i++){
packet_buf[6+i] = pbt_buf[j*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(&packet_buf[0],FTS_PACKET_LENGTH + 6);
mdelay(FTS_PACKET_LENGTH/6 + 1);
if ((j * FTS_PACKET_LENGTH % 1024) == 0){
printk("[FTS] upgrade the 0x%x th byte.\n", ((unsigned int)j) * FTS_PACKET_LENGTH);
}
}
if ((dw_lenth) % FTS_PACKET_LENGTH > 0){
temp = packet_number * FTS_PACKET_LENGTH;
packet_buf[2] = (u8)(temp>>8);
packet_buf[3] = (u8)temp;
temp = (dw_lenth) % FTS_PACKET_LENGTH;
packet_buf[4] = (u8)(temp>>8);
packet_buf[5] = (u8)temp;
for (i=0;i<temp;i++){
packet_buf[6+i] = pbt_buf[ packet_number*FTS_PACKET_LENGTH + i];
bt_ecc ^= packet_buf[6+i];
}
byte_write(&packet_buf[0],temp+6);
mdelay(20);
}
void main()
{
uchar shujv[8];
uchar stop=0;
uchar cejv=1;
uchar flag=0;
uchar helpcejv=0;
init_io();
led0=1;led1=1;ledk=1;
while(NRF_Check())
{
led0=0;
delayms(1000);
led0=1;
delayms(1000);
}
TX_Mode(); //设置为发送模式
/*************自己加的***********************/
while(CNRF_Check()) //检查nrf是否存在
{
led0=0;
delayms(1000);
led0=1;
delayms(1000);
}
CTX_Mode();
/*************自己加的***********************/
stop=byte_read(0x2000); //读取上一次保留的值
while(1)
{
wenshi(shujv); //写入前4个数据
// yali(shujv);//写入第5个数据
// shache(shujv);//写入第六个数据
Get_weight();
if (weight_shiwu/1000<=5)
shujv[4]='0';
else shujv[4]='1';
if(stop==0)
shujv[5]='1';
if(stop==1)
shujv[5]='0';
if(out==0)
shujv[6]='1';
else
shujv[6]='0';
//////////////////////////////
if(NRF24L01_TxPacket(shujv)==TX_OK)
{
led1=0;
delayms(300);
led1=1;
delayms(10);
/////
flag=1;
}
else flag=0;
//////////////////////////////
if(flag==1)
{
if(CNRF24L01_TxPacket(shujv)==TX_OK)
{
led3=0;
delayms(300);
led3=1;
delayms(10);
cejv=0;
helpcejv=0;
}
else
{
helpcejv++;
delayms(100);
if(helpcejv>2)
{ led2=0;
delayms(300);
led2=1;
delayms(10);
cejv=0;
helpcejv=0;
}
}
/////////////////////////////////////////////////
if(shache(cejv,stop)==1)
{
led0=0;
delayms(300);
led0=1;
delayms(10);
stop=1;
SectorErase(0x2000);
byte_write(0x2000,stop);
}
if(checkbutton(cejv,stop)==0)
{stop=1;
SectorErase(0x2000);
byte_write(0x2000,stop);
}
}
}
}
