proxmark3/fpga/hi_flite.v
iceman1001 f3ebfcb9a0 chg: reverting old @satsuoni felica changes.
chg: applied @pwpiwi 's fixes for iso 14B / 15
2017-10-23 21:56:47 +02:00

416 lines
13 KiB
Verilog

//this code demodulates and modulates signal as described in ISO/IEC 18092. That includes packets used for Felica, NFC Tag 3, etc. (which do overlap)
//simple envelope following algorithm is used (modification of fail0verflow LF one) is used to combat some nasty aliasing effect with testing phone (envelope looked like sine wave)
// only 212 kbps (fc/64) for now 414 is relatively straightforward... though for reader, the selection has to come from ARM
// modulation waits for
//market sprocket -doesn't really mean anything ;)
//redefining mod_type: bits 210: bit 2 - reader drive/power on/off, bit 1 - speed bit, 0:212, 1 -424 bit 0: listen or modulate
module hi_flite(
pck0, ck_1356meg, ck_1356megb,
pwr_lo, pwr_hi, pwr_oe1, pwr_oe2, pwr_oe3, pwr_oe4,
adc_d, adc_clk,
ssp_frame, ssp_din, ssp_dout, ssp_clk,
cross_hi, cross_lo,
dbg,
mod_type // used
);
input pck0, ck_1356meg, ck_1356megb;
output pwr_lo, pwr_hi, pwr_oe1, pwr_oe2, pwr_oe3, pwr_oe4;
input [7:0] adc_d;
output adc_clk;
input ssp_dout;
output ssp_frame, ssp_din, ssp_clk;
input cross_hi, cross_lo;
output dbg;
input [2:0] mod_type; // used.
assign dbg=0;
wire power= mod_type[2];
wire speed= mod_type[1];
wire disabl= mod_type[0];
// Most off, oe4 for modulation;
// Trying reader emulation (would presumably just require switching power on, but I am not sure)
//;// 1'b0;
assign pwr_lo = 1'b0;
//512x64/fc -wait before ts0, 32768 ticks
//tslot: 256*64/fc
assign adc_clk = ck_1356meg;
///heuristic values for initial thresholds. seem to work OK
`define imin 70//(13'd256)
`define imax 180//(-13'd256)
`define ithrmin 91//-13'd8
`define ithrmax 160// 13'd8
`define min_bitdelay_212 8
//minimum values and corresponding thresholds
reg [8:0] curmin=`imin;
reg [8:0] curminthres=`ithrmin;
reg [8:0] curmaxthres=`ithrmax;
reg [8:0] curmax=`imax;
//signal state, 1-not modulated, 0 -modulated
reg after_hysteresis = 1'b1;
//state machine for envelope tracking
reg [1:0] state=1'd0;
//lower edge detected, trying to detect first bit of SYNC (b24d, 1011001001001101)
reg try_sync=1'b0;
//detected first sync bit, phase frozen
reg did_sync=0;
`define bithalf_212 32 //half-bit length for 212 kbit
`define bitmlen_212 63 //bit transition edge
`define bithalf_424 16 //half-bit length for 212 kbit
`define bitmlen_424 31 //bit transition edge
wire [7:0]bithalf= speed ? `bithalf_424 : `bithalf_212;
wire [7:0]bitmlen= speed ? `bitmlen_424 : `bitmlen_212;
//ssp clock and current values
reg ssp_clk;
reg ssp_frame;
reg curbit=1'b0;
reg [7:0] fccount=8'd0; // in-bit tick counter. Counts carrier cycles from the first lower edge detected, reset on every manchester bit detected
reg [7:0] tsinceedge=8'd0;// ticks from last edge, desync if the valye is too large
reg zero=1'b0; // Manchester first halfbit low second high corresponds to this value. It has been known to change. SYNC is used to set it
//ssp counter for transfer and framing
reg [8:0] ssp_cnt=9'd0;
always @(posedge adc_clk)
ssp_cnt <= (ssp_cnt + 1);
//maybe change it so that ARM sends preamble as well.
//then: ready bits sent to ARM, 8 bits sent from ARM (all ones), then preamble (all zeros, presumably) - which starts modulation
always @(negedge adc_clk)
begin
//count fc/64 - transfer bits to ARM at the rate they are received
if( ((~speed) && (ssp_cnt[5:0] == 6'b000000)) || (speed &&(ssp_cnt[4:0] == 5'b00000)))
begin
ssp_clk <= 1'b1;
// if(mod_type[2])
// begin
// ssp_din<=outp[0];//after_hysteresis;
//outp<={1'b0,outp[7:1]};
// end
// else
ssp_din <= curbit;
//sample ssp_dout
end
if( ( (~speed) && (ssp_cnt[5:0] == 6'b100000)) ||(speed && ssp_cnt[4:0] == 5'b10000))
ssp_clk <= 1'b0;
//create frame pulses. TBH, I still don't know what they do exactly, but they are crucial for ARM->FPGA transfer. If the frame is in the beginning of the byte, transfer slows to a crawl for some reason
// took me a day to figure THAT out.
if(( (~speed) && (ssp_cnt[8:0] == 9'd31))||(speed && ssp_cnt[7:0] == 8'd15))
begin
ssp_frame <= 1'b1;
end
if(( (~speed) && (ssp_cnt[8:0] == 9'b1011111))||(speed &&ssp_cnt[7:0] == 8'b101111) )
begin
ssp_frame <= 1'b0;
end
end
//send current bit (detected in SNIFF mode or the one being modulated in MOD mode, 0 otherwise)
reg ssp_din;//= outp[0];
//previous signal value, mostly to detect SYNC
reg prv =1'b1;
reg[7:0] mid=8'd128; //for simple error correction in mod/demod detection, use maximum of modded/demodded in given interval. Maybe 1 bit is extra? but better safe than sorry.
// set TAGSIM__MODULATE on ARM if we want to write... (frame would get lost if done mid-frame...)
// start sending over 1s on ssp->arm when we start sending preamble
reg counting_desync=1'b0; // are we counting bits since last frame?
reg sending=1'b0; // are we actively modulating?
reg [11:0] bit_counts=12'd0;///for timeslots... only support ts=0 for now, at 212 speed -512 fullbits from end of frame. One hopes. might remove those?
//reg [2:0]old_mod;
//always @(mod_type) //when moving from modulate_mode
//begin
//if (mod_type[2]==1&&old_mod[2]==0)
// bit_counts=0;
//old_mod=mod_type;
//end
//we need some way to flush bit_counts triggers on mod_type changes don't compile
reg dlay;
always @(negedge adc_clk) //every data ping?
begin
//envelope follow code...
////////////
//move the counter to the outside...
// if (adc_d>=curminthres||try_sync)
if(fccount==bitmlen)
begin
if((~try_sync)&&(adc_d<curminthres)&&disabl )
begin
fccount<=1;
end
else
begin
fccount<=0;
end
// if (counting_desync)
// begin
dlay<=ssp_dout;
if(bit_counts>768) // should be over ts0 now, without ARM interference... stop counting...
begin
bit_counts<=0;
// counting_desync<=0;
end
else
if((power))
bit_counts<=0;
else
bit_counts<=bit_counts+1;
// end
end
else
begin
if((~try_sync)&&(adc_d<curminthres) &&disabl)
begin
fccount<=1;
end
else
begin
fccount<=fccount+1;
end
end
if (adc_d>curmaxthres) //rising edge
begin
case (state)
0: begin
curmax <= adc_d>`imax? adc_d :`imax;
state <= 2;
end
1: begin
curminthres <= ( (curmin>>1)+(curmin>>2)+(curmin>>4)+(curmax>>3)+(curmax>>4)); //threshold: 0.1875 max + 0.8125 min
curmaxthres <= ( (curmax>>1)+(curmax>>2)+(curmax>>4)+(curmin>>3)+(curmin>>4));
curmax <= adc_d>155? adc_d :155; // to hopefully prevent overflow from spikes going up to 255
state <= 2;
end
2: begin
if (adc_d>curmax)
curmax <= adc_d;
end
default:
begin
end
endcase
after_hysteresis <=1'b1;
if(try_sync)
tsinceedge<=0;
end
else if (adc_d<curminthres) //falling edge
begin
case (state)
0: begin
curmin <=adc_d<`imin? adc_d :`imin;
state <=1;
end
1: begin
if (adc_d<curmin)
curmin <= adc_d;
end
2: begin
curminthres <= ( (curmin>>1)+(curmin>>2)+(curmin>>4)+(curmax>>3)+(curmax>>4));
curmaxthres <= ( (curmax>>1)+(curmax>>2)+(curmax>>4)+(curmin>>3)+(curmin>>4));
curmin <=adc_d<`imin? adc_d :`imin;
state <=1;
end
default:
begin
end
endcase
after_hysteresis <=0;
if (~try_sync ) //begin modulation, lower edge...
begin
try_sync <=1;
//counting_desync<=1'b0;
fccount <= 1;
did_sync<=0;
curbit<=0;
mid <=8'd127;
tsinceedge<=0;
prv <=1;
end
else
begin
tsinceedge<=0;
end
end
else //stable state, low or high
begin
curminthres <= ( (curmin>>1)+(curmin>>2)+(curmin>>4)+(curmax>>3)+(curmax>>4));
curmaxthres <= ( (curmax>>1)+(curmax>>2)+(curmax>>4)+(curmin>>3)+(curmin>>4));
state <=0;
if (try_sync )
begin
if (tsinceedge>=(128))
begin
//we might need to start counting... assuming ARM wants to reply to the frame.
// counting_desync<=1'b1;
bit_counts<=1;// i think? 128 is about 2 bits passed... but 1 also works
try_sync<=0;
did_sync<=0;//desync
curmin <=`imin; //reset envelope
curmax <=`imax;
curminthres <=`ithrmin;
curmaxthres <=`ithrmax;
prv <=1;
tsinceedge <=0;
after_hysteresis <=1'b1;
curbit <=0;
mid <=8'd128;
end
else
tsinceedge<=(tsinceedge+1);
end
end
if (try_sync && tsinceedge<128)
begin
//detect bits in their middle ssp sampling is in sync, so it would sample all bits in order
if (fccount==bithalf)
begin
if ((~did_sync) && ((prv==1&&(mid>128))||(prv==0&&(mid<=128))))
begin
//sync the Zero, and set curbit roperly
did_sync <=1'b1;
zero <= ~prv;// 1-prv
curbit <=1;
end
else
curbit <= (mid>128) ? (~zero):zero;
prv <=(mid>128) ?1:0;
if(adc_d>curmaxthres)
mid <=8'd129;
else if (adc_d<curminthres)
mid <=8'd127;
else
begin
if (after_hysteresis)
begin
mid <=8'd129;
end
else
begin
mid<=8'd127;
end
end
end
else
begin
if (fccount==bitmlen)
begin
// fccount <=0;
prv <=(mid>128)?1:0;
mid <=128;
end
else
begin
// minimum-maximum calc
if(adc_d>curmaxthres)
mid <=mid+1;
else if (adc_d<curminthres)
mid <=mid-1;
else
begin
if (after_hysteresis)
begin
mid <=mid+1;
end
else
begin
mid<=mid-1;
end
end
end
end
end
else
begin
end
sending <=0;
end
//put modulation here to maintain the correct clock. Seems that some readers are sensitive to that
reg pwr_hi;
reg pwr_oe1;
reg pwr_oe2;
reg pwr_oe3;
reg pwr_oe4;
wire mod=((fccount>=bithalf)^dlay)&(~disabl);
always @(ck_1356megb or ssp_dout or power or disabl or mod)
begin
if (power)
begin
pwr_hi <= ck_1356megb;
pwr_oe1 <= 1'b0;//mod;
pwr_oe2 <= 1'b0;//mod;
pwr_oe3 <= 1'b0;//mod;
pwr_oe4 <= mod;//1'b0;
end
else
begin
pwr_hi <= 1'b0;
pwr_oe1 <= 1'b0;
pwr_oe2 <= 1'b0;
pwr_oe3 <= 1'b0;
pwr_oe4 <= mod;
end
end
//assign pwr_oe4 = 1'b0;// mod_sig_coil & (modulate_mode)&sending & (~mod_type[2]);
//try shallow mod for reader?
//assign pwr_hi= (mod_type[2]) & ck_1356megb;
//assign pwr_oe1= 1'b0; //mod_sig_coil & (modulate_mode)&sending & (mod_type[2]);
//assign pwr_oe2 = 1'b0;// mod_sig_coil & (modulate_mode)&sending & (mod_type[2]);
//assign pwr_oe3 = 1'b0; //mod_sig_coil & (modulate_mode)&sending & (mod_type[2]);
endmodule