ram.v
module ram(clk, load, addr, d, q
);
parameter DWIDTH=16, AWIDTH=12, WORDS=4096;
input clk, load;
input [AWIDTH-1:0] addr;
input [DWIDTH-1:0] d;
output [DWIDTH-1:0] q;
reg [DWIDTH-1:0] q;
reg [DWIDTH-1:0] mem [WORDS-1:0];
always @(posedge clk)
begin
if(load) mem[addr] <= d;
q <= mem[addr];
end
integer i;
initial begin
for(i=0; i<WORDS; i=i+1)
mem[i]=12'h000;
/*
// i2c light sensor test main
main_loop: pushi main_light_val
pushi main_1
jmp getLight
main_1: jz main_2
pushi 0x03
out
halt
jmp main_loop
main_2: push main_light_val
pushi 0x03
bor
out
pushi 0x100
pushi main_3
jmp waitLoop // wait
main_3: jz main_loop
pushi 0x07
out
halt
jmp main_loop
main_light_val: 0x00
//
// getLight
// get light strength value from the i2c light sensor, grove
// arg 0: return address, arg 1: address for the received value
getLight: push getLight_jmp
bor
pop getLight_rtn
pop getLight_valAddr
//
pushi 0x03 // power up
pushi 0x80 // command, register 0
push lightSensorAddr //lightSensor
pushi getLight_a1 // push return addr
jmp wi2c1 // call wi2c1
getLight_a1: pop getLightRtnCode
push getLightRtnCode
jz getLight_a1_1
pushi 1 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a1_1: pushi 0x00 //
pushi 0x81
push lightSensorAddr
pushi getLight_a2
jmp wi2c1
getLight_a2: pop getLightRtnCode
push getLightRtnCode
jz getLight_a2_1
pushi 2 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a2_1: pushi 0x00 // scale
pushi 0x86 // register to set the scale
push lightSensorAddr // lightSensor
pushi getLight_a3
jmp wi2c1
getLight_a3: pop getLightRtnCode
push getLightRtnCode
jz getLight_a3_1
pushi 3 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a3_1: pushi 0x00 // power down
pushi 0x80
push lightSensorAddr
pushi getLight_a4
jmp wi2c1
getLight_a4: pop getLightRtnCode
push getLightRtnCode
jz getLight_a4_1
pushi 4 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a4_1: pushi 0x03 // power up again
pushi 0x80
push lightSensorAddr
pushi getLight_a5
jmp wi2c1
getLight_a5: pop getLightRtnCode
push getLightRtnCode
jz getLight_a5_1
pushi 5 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a5_1: PUSHI lightSensorCh0l // push arg1... the address for receiving the result(temprature)
PUSHi 0x8c // push the register no. 0
push lightSensorAddr // push the I2C light sensor address, 0x4b
pushi getLight_a6 // push the return address
JMP ri2c1 // call the ri2c1 ... read 1 byte data from the i2c device,
getLight_a6: pop getLightRtnCode
push getLightRtnCode
jz getLight_a6_1
pushi 6 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a6_1: PUSHI lightSensorCh0h // push arg1... the address for receiving the result(temprature)
PUSHi 0x8d // push the register no. 0
push lightSensorAddr // push the I2C light sensor address, 0x4b
pushi getLight_a7 // push the return address
JMP ri2c1 // call the ri2c1 ... read 1 byte data from the i2c device,
getLight_a7: pop getLightRtnCode
push getLightRtnCode
jz getLight_a7_1
pushi 7 // error to read the ack of the i2c address
jmp getLight_rtn
//
getLight_a7_1: push getLight_valAddr
push lightSensorCh0h
pushi 0x08
shr
push lightSensorCh0l
bor
st
pushi 0
getLight_rtn: jmp 0x0000
getLight_err: 0x0000
getLight_valAddr: 0x0000
getLightRtnCode: 0x0000
getLight_jmp: 0x4000
getLight_rtnval: 0x0000
getLight_valAddr: 0x0000
lightSensorCh0l: 0x0000
lightSensorCh0h: 0x0000
lightSensorRC0h: 0x008c // read 1 byte from the register d, IR+visible
lightSensorRC0l: 0x008d
lightSensorRC1h: 0x008e
lightSensorRC1l: 0x008f
lightSensorAddr: 0x0029 // grove i2c light sensor
lightReadReg: 0x008d // read 1 byte from the register d, IR+visible
lightAddr: 0x0029 // grove i2c light sensor
//
// waitLoop
// wait for the arg1 times
// arg0: return address, arg1: repeat times
waitLoop: push waitLoop_jmp
bor
pop waitLoop_rtn
pop waitLoop_times
waitLoop_a0: push waitLoop_times
pushi 1
sub
pop waitLoop_times
push waitLoop_times
jnz waitLoop_a0
pushi 0
waitLoop_rtn: 0x0000
waitLoop_jmp: 0x4000
waitLoop_times: 0x000
//
// wi2c1
// Write 1 byte to an i2c device
// arg 0: return address, arg1:device address, arg2:register no, arg3:1 byte value
// return ... if 0: normal return, else: return with error.
//
wi2c1: PUSH wi2c1_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP wi2c1_rtn // save the return instruction
POP wi2c1_addr // save the arg1, the i2c slave address
pop wi2c1_reg // save the arg2, destination register address
pop wi2c1_val // save the value which will be assiinged to the destination register.
//
PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI wi2c1_a1 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c1_a1: push wi2c1_addr
pushi 1
shl // make the i2c device address with the write flag
//
pushi wi2c1_a2
jmp si2c1
//
wi2c1_a2: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c1_a3 //
JMP SubI2C1 // call the subroutine
//
wi2c1_a3: in // input the ack
pushi 0x01
band
jz wi2c1_a3_1
pushi 1 // error to read the ack of the i2c address
jmp wi2c1_err
wi2c1_a3_1: push wi2c1_reg
pushi wi2c1_a4
jmp si2c1
//
wi2c1_a4: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c1_a5 //
JMP SubI2C1 // call the subroutine
//
wi2c1_a5: in // input the ack
pushi 0x01
band
jz wi2c1_a5_1
pushi 2 // error to read the ack of the i2c register no.
jmp wi2c1_err
wi2c1_a5_1: push wi2c1_val
pushi wi2c1_a6
jmp si2c1
//
wi2c1_a6: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c1_a7 //
JMP SubI2C1 // call the subroutine
//
wi2c1_a7: in // input the ack
pushi 0x01
band
jz wi2c1_a7_1
pushi 3 // error to read the ack of the i2c register val.
jmp wi2c1_err
wi2c1_a7_1: PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c1_a8 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c1_a8: pushI 0
wi2c1_rtn: jmp 0x000 // return
wi2c1_err: pop wi2c1_ercode
PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c1_a9 // push the return address
JMP SubI2C1 // call the subroutine
wi2c1_a9: push wi2c1_ercode
jmp wi2c1_rtn
wi2c1_jmp: 0x4000
wi2c1_addr: 0x0000
wi2c1_reg: 0x0000
wi2c1_val: 0x0000
wi2c1\ercode: 0x0000
//
// wi2c2
// Write 2 byte to an i2c device
// arg 0: return address, arg1:device address, arg2:register no, arg3:two byte values
// return ... if 1: ok, 0: error
//
wi2c2: PUSH wi2c2_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP wi2c2_rtn // save the return instruction
POP wi2c2_addr // save the arg1, the i2c slave address
pop wi2c2_reg // save the arg2, destination register address
pop wi2c2_val // save the value which will be assiinged to the destination register.
//
PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI wi2c2_a1 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c2_a1: push wi2c2_addr
pushi 1
shl // make the i2c device address with the write flag
pop wi2c2_waddr
//
pushi wi2c2_a2
jmp si2c1
//
wi2c2_a2: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c2_a3 //
JMP SubI2C1 // call the subroutine
//
wi2c2_a3: in // input the ack
pushi 0x01
band
jz wi2c2_a3_1
pushi 1 // error to read the ack of the i2c address
jmp wi2c2_err
wi2c2_a3_1: push wi2c2_reg
pushi wi2c2_a4
jmp si2c1
//
wi2c2_a4: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c2_a5 //
JMP SubI2C1 // call the subroutine
//
wi2c2_a5: in // input the ack
pushi 0x01
band
jz wi2c2_a5_1
pushi 2 // error to read the ack of the i2c register no.
jmp wi2c2_err
wi2c_a5_1: push wi2c2_val
pushi 0x00ff
band
pushi wi2c2_a6
jmp si2c1
//
wi2c2_a6: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c2_a7 //
JMP SubI2C1 // call the subroutine
//
wi2c2_a7: in // input the ack
pushi 0x01
band
jz wi2c2_a7_1
pushi 3 // error to read the ack of the i2c register no.
jmp wi2c2_err
wi2c2_a7_1: push wi2c2_val
pushi 8
shr
pushi wi2c2_a8
jmp si2c1
//
wi2c2_a8: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c2_a9 //
JMP SubI2C1 // call the subroutine
//
wi2c2_a9: in // input the ack
pushi 0x01
band
jz wi2c2_a9_1
pushi 4 // error to read the ack of the i2c register no.
jmp wi2c2_err
wi2c2_a9_1: PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c2_a10 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c2_a10: pushI 0
wi2c2_rtn: jmp 0x000 // return
wi2c2_err: pop wi2c2_ercode
PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c2_a11 // push the return address
JMP SubI2C1 // call the subroutine
wi2c2_a11: push wi2c2_ercode
jmp wi2c2_rtn
wi2c2_jmp: 0x4000
wi2c2_addr: 0x0000
wi2c2_reg: 0x0000
wi2c2_val: 0x0000
wi2c2_ercode: 0x0000
//
// wi2c4
// Write 4 byte to an i2c device
// arg 0: return address, arg1:device address, arg2:register no, arg3:1st 2 byte, arg4: 2nd 2byte,
// return ... if 1: ok, 0: error
//
wi2c4: PUSH wi2c4_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP wi2c4_rtn // save the return instruction
POP wi2c4_addr // save the arg1, the i2c slave address
pop wi2c4_reg // save the arg2, destination register address
pop wi2c4_val2 // save the 1st value which will be assiinged to the destination registers.
pop wi2c4_val1 // save the 2nd value which will be assiinged to the destination register2.
//
PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI wi2c4_a1 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c4_a1: push wi2c4_addr
pushi 1
shl // make the i2c device address with the write flag
pushi wi2c4_a2
jmp si2c1
//
wi2c4_a2: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a3 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a3: in // input the ack
pushi 0x01
band
jz wi2c4_a3_1
pushi 1 // error to read the ack of the i2c address
jmp wi2c4_err
wi2c4_a3_1: push wi2c4_reg
pushi wi2c4_a4
jmp si2c1
//
wi2c4_a4: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a5 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a5: in // input the ack
pushi 0x01
band
jz wi2c4_a5_1
pushi 2 // error to read the ack of the i2c register no.
jmp wi2c4_err
wi2c4_a5_1: push wi2c4_val1
pushi 0x00ff
band
pushi wi2c4_a6
jmp si2c1
//
wi2c4_a6: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a7 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a7: in // input the ack
pushi 0x01
band
jz wi2c4_a7_1
pushi 3 // error to read the ack of the lsb of the val1
jmp wi2c4_err
wi2c4_a7_1: push wi2c4_val1
pushi 8
shr
pushi wi2c4_a8
jmp si2c1
//
wi2c4_a8: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a9 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a9: in // input the ack
pushi 0x01
band
jz wi2c4_a9_1
pushi 4 // error to read the ack of the msb of the val1
jmp wi2c4_err
wi2c4_a9_1: push wi2c4_val2
pushi 0x00ff
band
pushi wi2c4_a10
jmp si2c1
//
wi2c4_a10: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a11 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a11: in // input the ack
pushi 0x01
band
jz wi2c4_a11_1
pushi 5 // error to read the ack of the lsb of the val1
jmp wi2c4_err
wi2c4_a11_1: push wi2c4_val2
pushi 8
shr
pushi wi2c4_a12
jmp si2c1
//
wi2c4_a12: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI wi2c4_a13 //
JMP SubI2C1 // call the subroutine
//
wi2c4_a13: in // input the ack
pushi 0x01
band
jz wi2c4_a13_1
pushi 6 // error to read the ack of the lsb of the val1
jmp wi2c4_err
wi2c4_a13_1: PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c4_a14 // push the return address
JMP SubI2C1 // call the subroutine
//
wi2c4_a14: pushI 0
wi2c4_rtn: jmp 0x000 // return
wi2c4_err: pop wi2c4_ercode
PUSHI i2cStop // push arg1 .... write the ack
PUSHI wi2c4_a15 // push the return address
JMP SubI2C1 // call the subroutine
wi2c4_a15: push wi2c4_ercode
jmp wi2c4_rtn
wi2c4_jmp: 0x4000
wi2c4_addr: 0x0000
wi2c4_reg: 0x0000
wi2c4_val1: 0x0000
wi2c4_val2: 0x0000
wi2c4_ercode: 0x0000
//
// si2c1
// Write 1 byte series to an i2c device
// ... arg1 ... device address, arg1... register no. arg2... 1 byte value
// return ... if 1: ok, 0: error
//
si2c1: PUSH si2c1_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP si2c1_rtn // save the return instruction
POP si2c1_val
PUSHI 8
POP si2c1_i
si2c1_a3: push si2c1_val
pushi 0x0080
band
JNZ si2c1_a1
pushi 0x0000
out
pushi 0x0002
out
pushi 0x0000
out
jmp si2c1_a2
si2c1_a1: pushi 0x0001
out
pushi 0x0003
out
pushi 0x0001
out
si2c1_a2: push si2c1_val
pushi 1
shl
pop si2c1_val
push si2c1_i
pushi 1
sub
pop si2c1_i
push si2c1_i
jnz si2c1_a3
si2c1_rtn: jmp 0x000
si2c1_jmp: 0x4000
si2c1_val: 0x0000
si2c1_i: 0x0000
//
// ri2c1
// Read 1 byte from an i2c device
// ... arg1 ... device address, arg2 ... register number, arg3 .... the address for receiving the data
// return ... if 1:ok, 0:error
//
ri2c1: PUSH ri2c1_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP ri2c1_rtn // save the return instruction
POP ri2c1_addr // save the arg1, the i2c slave address
pop ri2c1_reg // save the arg2, destination register address
pop ri2c1_raddr // save the address which receives the value of the destination register.
//
PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI ri2c1_a1 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c1_a1: push ri2c1_addr
pushi 1
shl // make the i2c device address with the write flag
pushi ri2c1_a2
jmp si2c1
//
ri2c1_a2: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c1_a3 //
JMP SubI2C1 // call the subroutine
//
ri2c1_a3: in // input the ack
pushi 0x01
band
jz ri2c1_a3_1
pushi 1 // error to read the ack of the i2c address
jmp ri2c1_err
ri2c1_a3_1: push ri2c1_reg
pushi ri2c1_a4
jmp si2c1
//
ri2c1_a4: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c1_a5 //
JMP SubI2C1 // call the subroutine
//
ri2c1_a5: in // input the ack
pushi 0x01
band
jz ri2c1_a5_1
pushi 2 // error to read the ack of the i2c register no.
jmp ri2c1_err
ri2c1_a5_1: PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI ri2c1_a6 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c1_a6: push ri2c1_addr
pushi 1
shl // make the i2c device address with the read flag
pushi 0x0001
BOR
pushi ri2c1_a7
jmp si2c1
//
ri2c1_a7: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c1_a8 //
JMP SubI2C1 // call the subroutine
//
ri2c1_a8: in // input the ack
pushi 0x01
band
jz ri2c1_a8_1
pushi 3 // error to read the ack of the i2c address again.
jmp ri2c1_err
ri2c1_a8_1: pushi i2cRead
pushi ri2c1_a9
jmp SubI2C1
//
ri2c1_a9: push ri2c1_raddr
in
st
//
PUSHI i2cNAck // push arg1 .... Ack
PUSHI ri2c1_a10 //
JMP SubI2C1 // call the subroutine
//
ri2c1_a10: PUSHI i2cStop // push arg1 .... write the ack
PUSHI ri2c1_a11 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c1_a11: pushI 0
ri2c1_rtn: jmp 0x000 // return
ri2c1_err: pop ri2c1_ercode
PUSHI i2cStop // push arg1 .... write the ack
PUSHI ri2c1_a12 // push the return address
JMP SubI2C1 // call the subroutine
ri2c1_a12: push ri2c1_ercode
jmp ri2c1_rtn
ri2c1_jmp: 0x4000
ri2c1_addr: 0x0000
ri2c1_reg: 0x0000
ri2c1_raddr: 0x0000
ri2c1_ercode: 0x0000
//
// ri2c2
// Read 2 byte series from an i2c device
// ... arg1 ... device address, arg2 ... register number, arg3 ... the address for receiving the data
// return ... if 1: ok, 0:error
//
ri2c2: PUSH ri2c2_jmp // subroutine. the 1st step to make the return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP ri2c2_rtn // save the return instruction
POP ri2c2_addr // save the arg1, the i2c slave address
pop ri2c2_reg // save the arg2, destination register address
pop ri2c2_raddr // save the address which receives the value of the destination register.
//
PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI ri2c2_a1 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c2_a1: push ri2c2_addr
pushi 1
shl // make the i2c device address with the write flag
//
pushi ri2c2_a2
jmp si2c1
//
ri2c2_a2: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c2_a3 //
JMP SubI2C1 // call the subroutine
//
ri2c2_a3: in // input the ack
pushi 0x01
band
jz ri2c2_a3_1
pushi 1 // error to read the ack of the i2c address
jmp ri2c2_err
ri2c2_a3_1: push ri2c2_reg
pushi ri2c2_a4
jmp si2c1
//
ri2c2_a4: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c2_a5 //
JMP SubI2C1 // call the subroutine
//
ri2c2_a5: in // input the ack
pushi 0x01
band
jz ri2c2_a5_1
pushi 2 // error to read the ack of the i2c register no.
jmp ri2c2_err
ri2c2_a5_1: PUSHI i2cStart // push arg1... the i2c slave Addr
PUSHI ri2c2_a6 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c2_a6: push ri2c2_addr
pushi 1
shl // make the i2c device address with the read flag
pushi 0x0001
BOR
pushi ri2c2_a7
jmp si2c1
//
ri2c2_a7: PUSHI i2cRAck // push arg1 .... read the ack
PUSHI ri2c2_a8 //
JMP SubI2C1 // call the subroutine
//
ri2c2_a8: in // input the ack
pushi 0x01
band
jz ri2c2_a8_1
pushi 3 // error to read the ack of the i2c address again.
jmp ri2c2_err
ri2c2_a8_1: pushi i2cRead
pushi ri2c2_l9
jmp SubI2C1
//
ri2c2_l9: in
pushi 8
shl
pop ri2c2_val1
//
PUSHI i2cWAck // push arg1 .... write the ack
PUSHI ri2c2_a10 //
JMP SubI2C1 // call the subroutine
//
ri2c2_a10: pushi i2cRead
pushi ri2c2_a11
jmp SubI2C1
//
ri2c2_a11: push ri2c2_raddr
in
push ri2c2_val1
bor
st
//
PUSHI i2cNAck // push arg1 .... Ack
PUSHI ri2c2_a12 //
JMP SubI2C1 // call the subroutine
//
ri2c2_a12: PUSHI i2cStop // push arg1 .... write the ack
PUSHI ri2c2_a13 // push the return address
JMP SubI2C1 // call the subroutine
//
ri2c2_a13: pushI 0 // no error
ri2c2_rtn: jmp 0x000 // return
ri2c2_err: pop ri2c2_ercode
PUSHI i2cStop // push arg1 .... write the ack
PUSHI ri2c2_a14 // push the return address
JMP SubI2C1 // call the subroutine
ri2c2_a14: push ri2c2_ercode
jmp ri2c2_rtn
ri2c2_jmp: 0x4000
ri2c2_addr: 0x0000
ri2c2_reg: 0x0000
ri2c2_raddr: 0x0000
ri2c2_val1: 0x0000
ri2c2_ercode: 0x0000
//
// SubI2C1 ... send the [arg1] steps of I2C [scl,sda] sequence after the address of [arg1 +1] to the i2c bus.
//
SubI2C1: PUSH LblJMP // subroutine. the 1st step to return instruction
BOR // make the return instruction using arg1 and the previous instruction
POP RtnSub1 // save the return instruction
POP Sub1Data2 // save the arg1
PUSH Sub1Data2
LD
POP N
PUSH Sub1Data2
PUSHI 1
ADD
POP Sub1SA
PUSHI 0
POP i
L1: PUSH i
PUSH Sub1SA
ADD
LD //... Sub1S[i];
OUT //... print(Sub1S[i]) ;
PUSH i
PUSHI 1
ADD
POP i
PUSH i
PUSH N
SUB
JNZ L1 // if(i<n) goto L1;
RtnSub1: JMP 0x000 // return
LblJMP: 0x4000
Sub1Data2: 0x0000
Sub1SA: 0x0000
i: 0x0000
N: 0x0000
//
// data for controlling i2c
// (MSB) ...... scl, sda (LSB)
//
// I2C start
i2cStart: 3
1 //01
3 //11
2 //10
0 //00
//
// I2C AddrWrite
i2cAddrW: 3
0 // 00
2 // 10 send 0 ... write
0 // 00
//
// I2C AddrRead
i2cAddrR: 3
1 // 01
3 // 11 ... read
1 // 01
//
// I2C
i2cRAck: 3
1 // 01
3 // 11 read ack
1 // 01
//
// I2C Write Ack
i2cWAck: 3
0 // 00
2 // 10 send 0 ... write
0 // 00
//
// I2C NAck
i2cNAck: 3
1 //01
3 // ... read
1 //
//
//
// stop
i2cStop: 3
2 // 10
3 // 11 stop the transfering
3 // 11
//
// I2C read 1byte
i2cRead: 0x0011
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
3 // 11
1 // 01
*/
mem[12'h000]=16'h1014 ; //main_loop: pushi main_light_val
mem[12'h001]=16'h1003 ; // pushi main_1
mem[12'h002]=16'h4015 ; // jmp getLight
mem[12'h003]=16'h5008 ; //main_1: jz main_2
mem[12'h004]=16'h1003 ; // pushi 0x03
mem[12'h005]=16'he000 ; // out
mem[12'h006]=16'h0000 ; // halt
mem[12'h007]=16'h4000 ; // jmp main_loop
mem[12'h008]=16'h2014 ; //main_2: push main_light_val
mem[12'h009]=16'h1003 ; // pushi 0x03
mem[12'h00a]=16'hf006 ; // bor
mem[12'h00b]=16'he000 ; // out
mem[12'h00c]=16'h1100 ; // pushi 0x100
mem[12'h00d]=16'h100f ; // pushi main_3
mem[12'h00e]=16'h4077 ; // jmp waitLoop
mem[12'h00f]=16'h5000 ; //main_3: jz main_loop
mem[12'h010]=16'h1007 ; // pushi 0x07
mem[12'h011]=16'he000 ; // out
mem[12'h012]=16'h0000 ; // halt
mem[12'h013]=16'h4000 ; // jmp main_loop
mem[12'h014]=16'h0000 ; //main_light_val: 0x00
mem[12'h015]=16'h206b ; //getLight: push getLight_jmp
mem[12'h016]=16'hf006 ; // bor
mem[12'h017]=16'h3067 ; // pop getLight_rtn
mem[12'h018]=16'h3069 ; // pop getLight_valAddr
mem[12'h019]=16'h1003 ; // pushi 0x03
mem[12'h01a]=16'h1080 ; // pushi 0x80
mem[12'h01b]=16'h2074 ; // push lightSensorAddr
mem[12'h01c]=16'h101e ; // pushi getLight_a1
mem[12'h01d]=16'h4085 ; // jmp wi2c1
mem[12'h01e]=16'h306a ; //getLight_a1: pop getLightRtnCode
mem[12'h01f]=16'h206a ; // push getLightRtnCode
mem[12'h020]=16'h5023 ; // jz getLight_a1_1
mem[12'h021]=16'h1001 ; // pushi 1
mem[12'h022]=16'h4067 ; // jmp getLight_rtn
mem[12'h023]=16'h1000 ; //getLight_a1_1: pushi 0x00
mem[12'h024]=16'h1081 ; // pushi 0x81
mem[12'h025]=16'h2074 ; // push lightSensorAddr
mem[12'h026]=16'h1028 ; // pushi getLight_a2
mem[12'h027]=16'h4085 ; // jmp wi2c1
mem[12'h028]=16'h306a ; //getLight_a2: pop getLightRtnCode
mem[12'h029]=16'h206a ; // push getLightRtnCode
mem[12'h02a]=16'h502d ; // jz getLight_a2_1
mem[12'h02b]=16'h1002 ; // pushi 2
mem[12'h02c]=16'h4067 ; // jmp getLight_rtn
mem[12'h02d]=16'h1000 ; //getLight_a2_1: pushi 0x00
mem[12'h02e]=16'h1086 ; // pushi 0x86
mem[12'h02f]=16'h2074 ; // push lightSensorAddr
mem[12'h030]=16'h1032 ; // pushi getLight_a3
mem[12'h031]=16'h4085 ; // jmp wi2c1
mem[12'h032]=16'h306a ; //getLight_a3: pop getLightRtnCode
mem[12'h033]=16'h206a ; // push getLightRtnCode
mem[12'h034]=16'h5037 ; // jz getLight_a3_1
mem[12'h035]=16'h1003 ; // pushi 3
mem[12'h036]=16'h4067 ; // jmp getLight_rtn
mem[12'h037]=16'h1000 ; //getLight_a3_1: pushi 0x00
mem[12'h038]=16'h1080 ; // pushi 0x80
mem[12'h039]=16'h2074 ; // push lightSensorAddr
mem[12'h03a]=16'h103c ; // pushi getLight_a4
mem[12'h03b]=16'h4085 ; // jmp wi2c1
mem[12'h03c]=16'h306a ; //getLight_a4: pop getLightRtnCode
mem[12'h03d]=16'h206a ; // push getLightRtnCode
mem[12'h03e]=16'h5041 ; // jz getLight_a4_1
mem[12'h03f]=16'h1004 ; // pushi 4
mem[12'h040]=16'h4067 ; // jmp getLight_rtn
mem[12'h041]=16'h1003 ; //getLight_a4_1: pushi 0x03
mem[12'h042]=16'h1080 ; // pushi 0x80
mem[12'h043]=16'h2074 ; // push lightSensorAddr
mem[12'h044]=16'h1046 ; // pushi getLight_a5
mem[12'h045]=16'h4085 ; // jmp wi2c1
mem[12'h046]=16'h306a ; //getLight_a5: pop getLightRtnCode
mem[12'h047]=16'h206a ; // push getLightRtnCode
mem[12'h048]=16'h504b ; // jz getLight_a5_1
mem[12'h049]=16'h1005 ; // pushi 5
mem[12'h04a]=16'h4067 ; // jmp getLight_rtn
mem[12'h04b]=16'h106e ; //getLight_a5_1: PUSHI lightSensorCh0l
mem[12'h04c]=16'h108c ; // PUSHi 0x8c
mem[12'h04d]=16'h2074 ; // push lightSensorAddr
mem[12'h04e]=16'h1050 ; // pushi getLight_a6
mem[12'h04f]=16'h41a6 ; // JMP ri2c1
mem[12'h050]=16'h306a ; //getLight_a6: pop getLightRtnCode
mem[12'h051]=16'h206a ; // push getLightRtnCode
mem[12'h052]=16'h5055 ; // jz getLight_a6_1
mem[12'h053]=16'h1006 ; // pushi 6
mem[12'h054]=16'h4067 ; // jmp getLight_rtn
mem[12'h055]=16'h106f ; //getLight_a6_1: PUSHI lightSensorCh0h
mem[12'h056]=16'h108d ; // PUSHi 0x8d
mem[12'h057]=16'h2074 ; // push lightSensorAddr
mem[12'h058]=16'h105a ; // pushi getLight_a7
mem[12'h059]=16'h41a6 ; // JMP ri2c1
mem[12'h05a]=16'h306a ; //getLight_a7: pop getLightRtnCode
mem[12'h05b]=16'h206a ; // push getLightRtnCode
mem[12'h05c]=16'h505f ; // jz getLight_a7_1
mem[12'h05d]=16'h1007 ; // pushi 7
mem[12'h05e]=16'h4067 ; // jmp getLight_rtn
mem[12'h05f]=16'h2069 ; //getLight_a7_1: push getLight_valAddr
mem[12'h060]=16'h206f ; // push lightSensorCh0h
mem[12'h061]=16'h1008 ; // pushi 0x08
mem[12'h062]=16'hf004 ; // shr
mem[12'h063]=16'h206e ; // push lightSensorCh0l
mem[12'h064]=16'hf006 ; // bor
mem[12'h065]=16'h8000 ; // st
mem[12'h066]=16'h1000 ; // pushi 0
mem[12'h067]=16'h4000 ; //getLight_rtn: jmp 0x0000
mem[12'h068]=16'h0000 ; //getLight_err: 0x0000
mem[12'h069]=16'h0000 ; //getLight_valAddr: 0x0000
mem[12'h06a]=16'h0000 ; //getLightRtnCode: 0x0000
mem[12'h06b]=16'h4000 ; //getLight_jmp: 0x4000
mem[12'h06c]=16'h0000 ; //getLight_rtnval: 0x0000
mem[12'h06d]=16'h0000 ; //getLight_valAddr: 0x0000
mem[12'h06e]=16'h0000 ; //lightSensorCh0l: 0x0000
mem[12'h06f]=16'h0000 ; //lightSensorCh0h: 0x0000
mem[12'h070]=16'h008c ; //lightSensorRC0h: 0x008c
mem[12'h071]=16'h008d ; //lightSensorRC0l: 0x008d
mem[12'h072]=16'h008e ; //lightSensorRC1h: 0x008e
mem[12'h073]=16'h008f ; //lightSensorRC1l: 0x008f
mem[12'h074]=16'h0029 ; //lightSensorAddr: 0x0029
mem[12'h075]=16'h008d ; //lightReadReg: 0x008d
mem[12'h076]=16'h0029 ; //lightAddr: 0x0029
mem[12'h077]=16'h2083 ; //waitLoop: push waitLoop_jmp
mem[12'h078]=16'hf006 ; // bor
mem[12'h079]=16'h3082 ; // pop waitLoop_rtn
mem[12'h07a]=16'h3084 ; // pop waitLoop_times
mem[12'h07b]=16'h2084 ; //waitLoop_a0: push waitLoop_times
mem[12'h07c]=16'h1001 ; // pushi 1
mem[12'h07d]=16'hf001 ; // sub
mem[12'h07e]=16'h3084 ; // pop waitLoop_times
mem[12'h07f]=16'h2084 ; // push waitLoop_times
mem[12'h080]=16'h607b ; // jnz waitLoop_a0
mem[12'h081]=16'h1000 ; // pushi 0
mem[12'h082]=16'h0000 ; //waitLoop_rtn: 0x0000
mem[12'h083]=16'h4000 ; //waitLoop_jmp: 0x4000
mem[12'h084]=16'h0000 ; //waitLoop_times: 0x000
mem[12'h085]=16'h20bf ; //wi2c1: PUSH wi2c1_jmp
mem[12'h086]=16'hf006 ; // BOR
mem[12'h087]=16'h30b8 ; // POP wi2c1_rtn
mem[12'h088]=16'h30c0 ; // POP wi2c1_addr
mem[12'h089]=16'h30c1 ; // pop wi2c1_reg
mem[12'h08a]=16'h30c2 ; // pop wi2c1_val
mem[12'h08b]=16'h1271 ; // PUSHI i2cStart
mem[12'h08c]=16'h108e ; // PUSHI wi2c1_a1
mem[12'h08d]=16'h4251 ; // JMP SubI2C1
mem[12'h08e]=16'h20c0 ; //wi2c1_a1: push wi2c1_addr
mem[12'h08f]=16'h1001 ; // pushi 1
mem[12'h090]=16'hf003 ; // shl
mem[12'h091]=16'h1093 ; // pushi wi2c1_a2
mem[12'h092]=16'h4181 ; // jmp si2c1
mem[12'h093]=16'h127e ; //wi2c1_a2: PUSHI i2cRAck
mem[12'h094]=16'h1096 ; // PUSHI wi2c1_a3
mem[12'h095]=16'h4251 ; // JMP SubI2C1
mem[12'h096]=16'hd000 ; //wi2c1_a3: in
mem[12'h097]=16'h1001 ; // pushi 0x01
mem[12'h098]=16'hf005 ; // band
mem[12'h099]=16'h509c ; // jz wi2c1_a3_1
mem[12'h09a]=16'h1001 ; // pushi 1
mem[12'h09b]=16'h40b9 ; // jmp wi2c1_err
mem[12'h09c]=16'h20c1 ; //wi2c1_a3_1: push wi2c1_reg
mem[12'h09d]=16'h109f ; // pushi wi2c1_a4
mem[12'h09e]=16'h4181 ; // jmp si2c1
mem[12'h09f]=16'h127e ; //wi2c1_a4: PUSHI i2cRAck
mem[12'h0a0]=16'h10a2 ; // PUSHI wi2c1_a5
mem[12'h0a1]=16'h4251 ; // JMP SubI2C1
mem[12'h0a2]=16'hd000 ; //wi2c1_a5: in
mem[12'h0a3]=16'h1001 ; // pushi 0x01
mem[12'h0a4]=16'hf005 ; // band
mem[12'h0a5]=16'h50a8 ; // jz wi2c1_a5_1
mem[12'h0a6]=16'h1002 ; // pushi 2
mem[12'h0a7]=16'h40b9 ; // jmp wi2c1_err
mem[12'h0a8]=16'h20c2 ; //wi2c1_a5_1: push wi2c1_val
mem[12'h0a9]=16'h10ab ; // pushi wi2c1_a6
mem[12'h0aa]=16'h4181 ; // jmp si2c1
mem[12'h0ab]=16'h127e ; //wi2c1_a6: PUSHI i2cRAck
mem[12'h0ac]=16'h10ae ; // PUSHI wi2c1_a7
mem[12'h0ad]=16'h4251 ; // JMP SubI2C1
mem[12'h0ae]=16'hd000 ; //wi2c1_a7: in
mem[12'h0af]=16'h1001 ; // pushi 0x01
mem[12'h0b0]=16'hf005 ; // band
mem[12'h0b1]=16'h50b4 ; // jz wi2c1_a7_1
mem[12'h0b2]=16'h1003 ; // pushi 3
mem[12'h0b3]=16'h40b9 ; // jmp wi2c1_err
mem[12'h0b4]=16'h128a ; //wi2c1_a7_1: PUSHI i2cStop
mem[12'h0b5]=16'h10b7 ; // PUSHI wi2c1_a8
mem[12'h0b6]=16'h4251 ; // JMP SubI2C1
mem[12'h0b7]=16'h1000 ; //wi2c1_a8: pushI 0
mem[12'h0b8]=16'h4000 ; //wi2c1_rtn: jmp 0x000
mem[12'h0b9]=16'h3000 ; //wi2c1_err: pop wi2c1_ercode
mem[12'h0ba]=16'h128a ; // PUSHI i2cStop
mem[12'h0bb]=16'h10bd ; // PUSHI wi2c1_a9
mem[12'h0bc]=16'h4251 ; // JMP SubI2C1
mem[12'h0bd]=16'h2000 ; //wi2c1_a9: push wi2c1_ercode
mem[12'h0be]=16'h40b8 ; // jmp wi2c1_rtn
mem[12'h0bf]=16'h4000 ; //wi2c1_jmp: 0x4000
mem[12'h0c0]=16'h0000 ; //wi2c1_addr: 0x0000
mem[12'h0c1]=16'h0000 ; //wi2c1_reg: 0x0000
mem[12'h0c2]=16'h0000 ; //wi2c1_val: 0x0000
mem[12'h0c3]=16'h0000 ; //wi2c1\ercode: 0x0000
mem[12'h0c4]=16'h210f ; //wi2c2: PUSH wi2c2_jmp
mem[12'h0c5]=16'hf006 ; // BOR
mem[12'h0c6]=16'h3108 ; // POP wi2c2_rtn
mem[12'h0c7]=16'h3110 ; // POP wi2c2_addr
mem[12'h0c8]=16'h3111 ; // pop wi2c2_reg
mem[12'h0c9]=16'h3112 ; // pop wi2c2_val
mem[12'h0ca]=16'h1271 ; // PUSHI i2cStart
mem[12'h0cb]=16'h10cd ; // PUSHI wi2c2_a1
mem[12'h0cc]=16'h4251 ; // JMP SubI2C1
mem[12'h0cd]=16'h2110 ; //wi2c2_a1: push wi2c2_addr
mem[12'h0ce]=16'h1001 ; // pushi 1
mem[12'h0cf]=16'hf003 ; // shl
mem[12'h0d0]=16'h3000 ; // pop wi2c2_waddr
mem[12'h0d1]=16'h10d3 ; // pushi wi2c2_a2
mem[12'h0d2]=16'h4181 ; // jmp si2c1
mem[12'h0d3]=16'h127e ; //wi2c2_a2: PUSHI i2cRAck
mem[12'h0d4]=16'h10d6 ; // PUSHI wi2c2_a3
mem[12'h0d5]=16'h4251 ; // JMP SubI2C1
mem[12'h0d6]=16'hd000 ; //wi2c2_a3: in
mem[12'h0d7]=16'h1001 ; // pushi 0x01
mem[12'h0d8]=16'hf005 ; // band
mem[12'h0d9]=16'h50dc ; // jz wi2c2_a3_1
mem[12'h0da]=16'h1001 ; // pushi 1
mem[12'h0db]=16'h4109 ; // jmp wi2c2_err
mem[12'h0dc]=16'h2111 ; //wi2c2_a3_1: push wi2c2_reg
mem[12'h0dd]=16'h10df ; // pushi wi2c2_a4
mem[12'h0de]=16'h4181 ; // jmp si2c1
mem[12'h0df]=16'h127e ; //wi2c2_a4: PUSHI i2cRAck
mem[12'h0e0]=16'h10e2 ; // PUSHI wi2c2_a5
mem[12'h0e1]=16'h4251 ; // JMP SubI2C1
mem[12'h0e2]=16'hd000 ; //wi2c2_a5: in
mem[12'h0e3]=16'h1001 ; // pushi 0x01
mem[12'h0e4]=16'hf005 ; // band
mem[12'h0e5]=16'h5000 ; // jz wi2c2_a5_1
mem[12'h0e6]=16'h1002 ; // pushi 2
mem[12'h0e7]=16'h4109 ; // jmp wi2c2_err
mem[12'h0e8]=16'h2112 ; //wi2c_a5_1: push wi2c2_val
mem[12'h0e9]=16'h10ff ; // pushi 0x00ff
mem[12'h0ea]=16'hf005 ; // band
mem[12'h0eb]=16'h10ed ; // pushi wi2c2_a6
mem[12'h0ec]=16'h4181 ; // jmp si2c1
mem[12'h0ed]=16'h127e ; //wi2c2_a6: PUSHI i2cRAck
mem[12'h0ee]=16'h10f0 ; // PUSHI wi2c2_a7
mem[12'h0ef]=16'h4251 ; // JMP SubI2C1
mem[12'h0f0]=16'hd000 ; //wi2c2_a7: in
mem[12'h0f1]=16'h1001 ; // pushi 0x01
mem[12'h0f2]=16'hf005 ; // band
mem[12'h0f3]=16'h50f6 ; // jz wi2c2_a7_1
mem[12'h0f4]=16'h1003 ; // pushi 3
mem[12'h0f5]=16'h4109 ; // jmp wi2c2_err
mem[12'h0f6]=16'h2112 ; //wi2c2_a7_1: push wi2c2_val
mem[12'h0f7]=16'h1008 ; // pushi 8
mem[12'h0f8]=16'hf004 ; // shr
mem[12'h0f9]=16'h10fb ; // pushi wi2c2_a8
mem[12'h0fa]=16'h4181 ; // jmp si2c1
mem[12'h0fb]=16'h127e ; //wi2c2_a8: PUSHI i2cRAck
mem[12'h0fc]=16'h10fe ; // PUSHI wi2c2_a9
mem[12'h0fd]=16'h4251 ; // JMP SubI2C1
mem[12'h0fe]=16'hd000 ; //wi2c2_a9: in
mem[12'h0ff]=16'h1001 ; // pushi 0x01
mem[12'h100]=16'hf005 ; // band
mem[12'h101]=16'h5104 ; // jz wi2c2_a9_1
mem[12'h102]=16'h1004 ; // pushi 4
mem[12'h103]=16'h4109 ; // jmp wi2c2_err
mem[12'h104]=16'h128a ; //wi2c2_a9_1: PUSHI i2cStop
mem[12'h105]=16'h1107 ; // PUSHI wi2c2_a10
mem[12'h106]=16'h4251 ; // JMP SubI2C1
mem[12'h107]=16'h1000 ; //wi2c2_a10: pushI 0
mem[12'h108]=16'h4000 ; //wi2c2_rtn: jmp 0x000
mem[12'h109]=16'h3113 ; //wi2c2_err: pop wi2c2_ercode
mem[12'h10a]=16'h128a ; // PUSHI i2cStop
mem[12'h10b]=16'h110d ; // PUSHI wi2c2_a11
mem[12'h10c]=16'h4251 ; // JMP SubI2C1
mem[12'h10d]=16'h2113 ; //wi2c2_a11: push wi2c2_ercode
mem[12'h10e]=16'h4108 ; // jmp wi2c2_rtn
mem[12'h10f]=16'h4000 ; //wi2c2_jmp: 0x4000
mem[12'h110]=16'h0000 ; //wi2c2_addr: 0x0000
mem[12'h111]=16'h0000 ; //wi2c2_reg: 0x0000
mem[12'h112]=16'h0000 ; //wi2c2_val: 0x0000
mem[12'h113]=16'h0000 ; //wi2c2_ercode: 0x0000
mem[12'h114]=16'h217b ; //wi2c4: PUSH wi2c4_jmp
mem[12'h115]=16'hf006 ; // BOR
mem[12'h116]=16'h3174 ; // POP wi2c4_rtn
mem[12'h117]=16'h317c ; // POP wi2c4_addr
mem[12'h118]=16'h317d ; // pop wi2c4_reg
mem[12'h119]=16'h317f ; // pop wi2c4_val2
mem[12'h11a]=16'h317e ; // pop wi2c4_val1
mem[12'h11b]=16'h1271 ; // PUSHI i2cStart
mem[12'h11c]=16'h111e ; // PUSHI wi2c4_a1
mem[12'h11d]=16'h4251 ; // JMP SubI2C1
mem[12'h11e]=16'h217c ; //wi2c4_a1: push wi2c4_addr
mem[12'h11f]=16'h1001 ; // pushi 1
mem[12'h120]=16'hf003 ; // shl
mem[12'h121]=16'h1123 ; // pushi wi2c4_a2
mem[12'h122]=16'h4181 ; // jmp si2c1
mem[12'h123]=16'h127e ; //wi2c4_a2: PUSHI i2cRAck
mem[12'h124]=16'h1126 ; // PUSHI wi2c4_a3
mem[12'h125]=16'h4251 ; // JMP SubI2C1
mem[12'h126]=16'hd000 ; //wi2c4_a3: in
mem[12'h127]=16'h1001 ; // pushi 0x01
mem[12'h128]=16'hf005 ; // band
mem[12'h129]=16'h512c ; // jz wi2c4_a3_1
mem[12'h12a]=16'h1001 ; // pushi 1
mem[12'h12b]=16'h4175 ; // jmp wi2c4_err
mem[12'h12c]=16'h217d ; //wi2c4_a3_1: push wi2c4_reg
mem[12'h12d]=16'h112f ; // pushi wi2c4_a4
mem[12'h12e]=16'h4181 ; // jmp si2c1
mem[12'h12f]=16'h127e ; //wi2c4_a4: PUSHI i2cRAck
mem[12'h130]=16'h1132 ; // PUSHI wi2c4_a5
mem[12'h131]=16'h4251 ; // JMP SubI2C1
mem[12'h132]=16'hd000 ; //wi2c4_a5: in
mem[12'h133]=16'h1001 ; // pushi 0x01
mem[12'h134]=16'hf005 ; // band
mem[12'h135]=16'h5138 ; // jz wi2c4_a5_1
mem[12'h136]=16'h1002 ; // pushi 2
mem[12'h137]=16'h4175 ; // jmp wi2c4_err
mem[12'h138]=16'h217e ; //wi2c4_a5_1: push wi2c4_val1
mem[12'h139]=16'h10ff ; // pushi 0x00ff
mem[12'h13a]=16'hf005 ; // band
mem[12'h13b]=16'h113d ; // pushi wi2c4_a6
mem[12'h13c]=16'h4181 ; // jmp si2c1
mem[12'h13d]=16'h127e ; //wi2c4_a6: PUSHI i2cRAck
mem[12'h13e]=16'h1140 ; // PUSHI wi2c4_a7
mem[12'h13f]=16'h4251 ; // JMP SubI2C1
mem[12'h140]=16'hd000 ; //wi2c4_a7: in
mem[12'h141]=16'h1001 ; // pushi 0x01
mem[12'h142]=16'hf005 ; // band
mem[12'h143]=16'h5146 ; // jz wi2c4_a7_1
mem[12'h144]=16'h1003 ; // pushi 3
mem[12'h145]=16'h4175 ; // jmp wi2c4_err
mem[12'h146]=16'h217e ; //wi2c4_a7_1: push wi2c4_val1
mem[12'h147]=16'h1008 ; // pushi 8
mem[12'h148]=16'hf004 ; // shr
mem[12'h149]=16'h114b ; // pushi wi2c4_a8
mem[12'h14a]=16'h4181 ; // jmp si2c1
mem[12'h14b]=16'h127e ; //wi2c4_a8: PUSHI i2cRAck
mem[12'h14c]=16'h114e ; // PUSHI wi2c4_a9
mem[12'h14d]=16'h4251 ; // JMP SubI2C1
mem[12'h14e]=16'hd000 ; //wi2c4_a9: in
mem[12'h14f]=16'h1001 ; // pushi 0x01
mem[12'h150]=16'hf005 ; // band
mem[12'h151]=16'h5154 ; // jz wi2c4_a9_1
mem[12'h152]=16'h1004 ; // pushi 4
mem[12'h153]=16'h4175 ; // jmp wi2c4_err
mem[12'h154]=16'h217f ; //wi2c4_a9_1: push wi2c4_val2
mem[12'h155]=16'h10ff ; // pushi 0x00ff
mem[12'h156]=16'hf005 ; // band
mem[12'h157]=16'h1159 ; // pushi wi2c4_a10
mem[12'h158]=16'h4181 ; // jmp si2c1
mem[12'h159]=16'h127e ; //wi2c4_a10: PUSHI i2cRAck
mem[12'h15a]=16'h115c ; // PUSHI wi2c4_a11
mem[12'h15b]=16'h4251 ; // JMP SubI2C1
mem[12'h15c]=16'hd000 ; //wi2c4_a11: in
mem[12'h15d]=16'h1001 ; // pushi 0x01
mem[12'h15e]=16'hf005 ; // band
mem[12'h15f]=16'h5162 ; // jz wi2c4_a11_1
mem[12'h160]=16'h1005 ; // pushi 5
mem[12'h161]=16'h4175 ; // jmp wi2c4_err
mem[12'h162]=16'h217f ; //wi2c4_a11_1: push wi2c4_val2
mem[12'h163]=16'h1008 ; // pushi 8
mem[12'h164]=16'hf004 ; // shr
mem[12'h165]=16'h1167 ; // pushi wi2c4_a12
mem[12'h166]=16'h4181 ; // jmp si2c1
mem[12'h167]=16'h127e ; //wi2c4_a12: PUSHI i2cRAck
mem[12'h168]=16'h116a ; // PUSHI wi2c4_a13
mem[12'h169]=16'h4251 ; // JMP SubI2C1
mem[12'h16a]=16'hd000 ; //wi2c4_a13: in
mem[12'h16b]=16'h1001 ; // pushi 0x01
mem[12'h16c]=16'hf005 ; // band
mem[12'h16d]=16'h5170 ; // jz wi2c4_a13_1
mem[12'h16e]=16'h1006 ; // pushi 6
mem[12'h16f]=16'h4175 ; // jmp wi2c4_err
mem[12'h170]=16'h128a ; //wi2c4_a13_1: PUSHI i2cStop
mem[12'h171]=16'h1173 ; // PUSHI wi2c4_a14
mem[12'h172]=16'h4251 ; // JMP SubI2C1
mem[12'h173]=16'h1000 ; //wi2c4_a14: pushI 0
mem[12'h174]=16'h4000 ; //wi2c4_rtn: jmp 0x000
mem[12'h175]=16'h3180 ; //wi2c4_err: pop wi2c4_ercode
mem[12'h176]=16'h128a ; // PUSHI i2cStop
mem[12'h177]=16'h1179 ; // PUSHI wi2c4_a15
mem[12'h178]=16'h4251 ; // JMP SubI2C1
mem[12'h179]=16'h2180 ; //wi2c4_a15: push wi2c4_ercode
mem[12'h17a]=16'h4174 ; // jmp wi2c4_rtn
mem[12'h17b]=16'h4000 ; //wi2c4_jmp: 0x4000
mem[12'h17c]=16'h0000 ; //wi2c4_addr: 0x0000
mem[12'h17d]=16'h0000 ; //wi2c4_reg: 0x0000
mem[12'h17e]=16'h0000 ; //wi2c4_val1: 0x0000
mem[12'h17f]=16'h0000 ; //wi2c4_val2: 0x0000
mem[12'h180]=16'h0000 ; //wi2c4_ercode: 0x0000
mem[12'h181]=16'h21a3 ; //si2c1: PUSH si2c1_jmp
mem[12'h182]=16'hf006 ; // BOR
mem[12'h183]=16'h31a2 ; // POP si2c1_rtn
mem[12'h184]=16'h31a4 ; // POP si2c1_val
mem[12'h185]=16'h1008 ; // PUSHI 8
mem[12'h186]=16'h31a5 ; // POP si2c1_i
mem[12'h187]=16'h21a4 ; //si2c1_a3: push si2c1_val
mem[12'h188]=16'h1080 ; // pushi 0x0080
mem[12'h189]=16'hf005 ; // band
mem[12'h18a]=16'h6192 ; // JNZ si2c1_a1
mem[12'h18b]=16'h1000 ; // pushi 0x0000
mem[12'h18c]=16'he000 ; // out
mem[12'h18d]=16'h1002 ; // pushi 0x0002
mem[12'h18e]=16'he000 ; // out
mem[12'h18f]=16'h1000 ; // pushi 0x0000
mem[12'h190]=16'he000 ; // out
mem[12'h191]=16'h4198 ; // jmp si2c1_a2
mem[12'h192]=16'h1001 ; //si2c1_a1: pushi 0x0001
mem[12'h193]=16'he000 ; // out
mem[12'h194]=16'h1003 ; // pushi 0x0003
mem[12'h195]=16'he000 ; // out
mem[12'h196]=16'h1001 ; // pushi 0x0001
mem[12'h197]=16'he000 ; // out
mem[12'h198]=16'h21a4 ; //si2c1_a2: push si2c1_val
mem[12'h199]=16'h1001 ; // pushi 1
mem[12'h19a]=16'hf003 ; // shl
mem[12'h19b]=16'h31a4 ; // pop si2c1_val
mem[12'h19c]=16'h21a5 ; // push si2c1_i
mem[12'h19d]=16'h1001 ; // pushi 1
mem[12'h19e]=16'hf001 ; // sub
mem[12'h19f]=16'h31a5 ; // pop si2c1_i
mem[12'h1a0]=16'h21a5 ; // push si2c1_i
mem[12'h1a1]=16'h6187 ; // jnz si2c1_a3
mem[12'h1a2]=16'h4000 ; //si2c1_rtn: jmp 0x000
mem[12'h1a3]=16'h4000 ; //si2c1_jmp: 0x4000
mem[12'h1a4]=16'h0000 ; //si2c1_val: 0x0000
mem[12'h1a5]=16'h0000 ; //si2c1_i: 0x0000
mem[12'h1a6]=16'h21f0 ; //ri2c1: PUSH ri2c1_jmp
mem[12'h1a7]=16'hf006 ; // BOR
mem[12'h1a8]=16'h31e9 ; // POP ri2c1_rtn
mem[12'h1a9]=16'h31f1 ; // POP ri2c1_addr
mem[12'h1aa]=16'h31f2 ; // pop ri2c1_reg
mem[12'h1ab]=16'h31f3 ; // pop ri2c1_raddr
mem[12'h1ac]=16'h1271 ; // PUSHI i2cStart
mem[12'h1ad]=16'h11af ; // PUSHI ri2c1_a1
mem[12'h1ae]=16'h4251 ; // JMP SubI2C1
mem[12'h1af]=16'h21f1 ; //ri2c1_a1: push ri2c1_addr
mem[12'h1b0]=16'h1001 ; // pushi 1
mem[12'h1b1]=16'hf003 ; // shl
mem[12'h1b2]=16'h11b4 ; // pushi ri2c1_a2
mem[12'h1b3]=16'h4181 ; // jmp si2c1
mem[12'h1b4]=16'h127e ; //ri2c1_a2: PUSHI i2cRAck
mem[12'h1b5]=16'h11b7 ; // PUSHI ri2c1_a3
mem[12'h1b6]=16'h4251 ; // JMP SubI2C1
mem[12'h1b7]=16'hd000 ; //ri2c1_a3: in
mem[12'h1b8]=16'h1001 ; // pushi 0x01
mem[12'h1b9]=16'hf005 ; // band
mem[12'h1ba]=16'h51bd ; // jz ri2c1_a3_1
mem[12'h1bb]=16'h1001 ; // pushi 1
mem[12'h1bc]=16'h41ea ; // jmp ri2c1_err
mem[12'h1bd]=16'h21f2 ; //ri2c1_a3_1: push ri2c1_reg
mem[12'h1be]=16'h11c0 ; // pushi ri2c1_a4
mem[12'h1bf]=16'h4181 ; // jmp si2c1
mem[12'h1c0]=16'h127e ; //ri2c1_a4: PUSHI i2cRAck
mem[12'h1c1]=16'h11c3 ; // PUSHI ri2c1_a5
mem[12'h1c2]=16'h4251 ; // JMP SubI2C1
mem[12'h1c3]=16'hd000 ; //ri2c1_a5: in
mem[12'h1c4]=16'h1001 ; // pushi 0x01
mem[12'h1c5]=16'hf005 ; // band
mem[12'h1c6]=16'h51c9 ; // jz ri2c1_a5_1
mem[12'h1c7]=16'h1002 ; // pushi 2
mem[12'h1c8]=16'h41ea ; // jmp ri2c1_err
mem[12'h1c9]=16'h1271 ; //ri2c1_a5_1: PUSHI i2cStart
mem[12'h1ca]=16'h11cc ; // PUSHI ri2c1_a6
mem[12'h1cb]=16'h4251 ; // JMP SubI2C1
mem[12'h1cc]=16'h21f1 ; //ri2c1_a6: push ri2c1_addr
mem[12'h1cd]=16'h1001 ; // pushi 1
mem[12'h1ce]=16'hf003 ; // shl
mem[12'h1cf]=16'h1001 ; // pushi 0x0001
mem[12'h1d0]=16'hf006 ; // BOR
mem[12'h1d1]=16'h11d3 ; // pushi ri2c1_a7
mem[12'h1d2]=16'h4181 ; // jmp si2c1
mem[12'h1d3]=16'h127e ; //ri2c1_a7: PUSHI i2cRAck
mem[12'h1d4]=16'h11d6 ; // PUSHI ri2c1_a8
mem[12'h1d5]=16'h4251 ; // JMP SubI2C1
mem[12'h1d6]=16'hd000 ; //ri2c1_a8: in
mem[12'h1d7]=16'h1001 ; // pushi 0x01
mem[12'h1d8]=16'hf005 ; // band
mem[12'h1d9]=16'h51dc ; // jz ri2c1_a8_1
mem[12'h1da]=16'h1003 ; // pushi 3
mem[12'h1db]=16'h41ea ; // jmp ri2c1_err
mem[12'h1dc]=16'h128e ; //ri2c1_a8_1: pushi i2cRead
mem[12'h1dd]=16'h11df ; // pushi ri2c1_a9
mem[12'h1de]=16'h4251 ; // jmp SubI2C1
mem[12'h1df]=16'h21f3 ; //ri2c1_a9: push ri2c1_raddr
mem[12'h1e0]=16'hd000 ; // in
mem[12'h1e1]=16'h8000 ; // st
mem[12'h1e2]=16'h1286 ; // PUSHI i2cNAck
mem[12'h1e3]=16'h11e5 ; // PUSHI ri2c1_a10
mem[12'h1e4]=16'h4251 ; // JMP SubI2C1
mem[12'h1e5]=16'h128a ; //ri2c1_a10: PUSHI i2cStop
mem[12'h1e6]=16'h11e8 ; // PUSHI ri2c1_a11
mem[12'h1e7]=16'h4251 ; // JMP SubI2C1
mem[12'h1e8]=16'h1000 ; //ri2c1_a11: pushI 0
mem[12'h1e9]=16'h4000 ; //ri2c1_rtn: jmp 0x000
mem[12'h1ea]=16'h31f4 ; //ri2c1_err: pop ri2c1_ercode
mem[12'h1eb]=16'h128a ; // PUSHI i2cStop
mem[12'h1ec]=16'h11ee ; // PUSHI ri2c1_a12
mem[12'h1ed]=16'h4251 ; // JMP SubI2C1
mem[12'h1ee]=16'h21f4 ; //ri2c1_a12: push ri2c1_ercode
mem[12'h1ef]=16'h41e9 ; // jmp ri2c1_rtn
mem[12'h1f0]=16'h4000 ; //ri2c1_jmp: 0x4000
mem[12'h1f1]=16'h0000 ; //ri2c1_addr: 0x0000
mem[12'h1f2]=16'h0000 ; //ri2c1_reg: 0x0000
mem[12'h1f3]=16'h0000 ; //ri2c1_raddr: 0x0000
mem[12'h1f4]=16'h0000 ; //ri2c1_ercode: 0x0000
mem[12'h1f5]=16'h224b ; //ri2c2: PUSH ri2c2_jmp
mem[12'h1f6]=16'hf006 ; // BOR
mem[12'h1f7]=16'h3244 ; // POP ri2c2_rtn
mem[12'h1f8]=16'h324c ; // POP ri2c2_addr
mem[12'h1f9]=16'h324d ; // pop ri2c2_reg
mem[12'h1fa]=16'h324e ; // pop ri2c2_raddr
mem[12'h1fb]=16'h1271 ; // PUSHI i2cStart
mem[12'h1fc]=16'h11fe ; // PUSHI ri2c2_a1
mem[12'h1fd]=16'h4251 ; // JMP SubI2C1
mem[12'h1fe]=16'h224c ; //ri2c2_a1: push ri2c2_addr
mem[12'h1ff]=16'h1001 ; // pushi 1
mem[12'h200]=16'hf003 ; // shl
mem[12'h201]=16'h1203 ; // pushi ri2c2_a2
mem[12'h202]=16'h4181 ; // jmp si2c1
mem[12'h203]=16'h127e ; //ri2c2_a2: PUSHI i2cRAck
mem[12'h204]=16'h1206 ; // PUSHI ri2c2_a3
mem[12'h205]=16'h4251 ; // JMP SubI2C1
mem[12'h206]=16'hd000 ; //ri2c2_a3: in
mem[12'h207]=16'h1001 ; // pushi 0x01
mem[12'h208]=16'hf005 ; // band
mem[12'h209]=16'h520c ; // jz ri2c2_a3_1
mem[12'h20a]=16'h1001 ; // pushi 1
mem[12'h20b]=16'h4245 ; // jmp ri2c2_err
mem[12'h20c]=16'h224d ; //ri2c2_a3_1: push ri2c2_reg
mem[12'h20d]=16'h120f ; // pushi ri2c2_a4
mem[12'h20e]=16'h4181 ; // jmp si2c1
mem[12'h20f]=16'h127e ; //ri2c2_a4: PUSHI i2cRAck
mem[12'h210]=16'h1212 ; // PUSHI ri2c2_a5
mem[12'h211]=16'h4251 ; // JMP SubI2C1
mem[12'h212]=16'hd000 ; //ri2c2_a5: in
mem[12'h213]=16'h1001 ; // pushi 0x01
mem[12'h214]=16'hf005 ; // band
mem[12'h215]=16'h5218 ; // jz ri2c2_a5_1
mem[12'h216]=16'h1002 ; // pushi 2
mem[12'h217]=16'h4245 ; // jmp ri2c2_err
mem[12'h218]=16'h1271 ; //ri2c2_a5_1: PUSHI i2cStart
mem[12'h219]=16'h121b ; // PUSHI ri2c2_a6
mem[12'h21a]=16'h4251 ; // JMP SubI2C1
mem[12'h21b]=16'h224c ; //ri2c2_a6: push ri2c2_addr
mem[12'h21c]=16'h1001 ; // pushi 1
mem[12'h21d]=16'hf003 ; // shl
mem[12'h21e]=16'h1001 ; // pushi 0x0001
mem[12'h21f]=16'hf006 ; // BOR
mem[12'h220]=16'h1222 ; // pushi ri2c2_a7
mem[12'h221]=16'h4181 ; // jmp si2c1
mem[12'h222]=16'h127e ; //ri2c2_a7: PUSHI i2cRAck
mem[12'h223]=16'h1225 ; // PUSHI ri2c2_a8
mem[12'h224]=16'h4251 ; // JMP SubI2C1
mem[12'h225]=16'hd000 ; //ri2c2_a8: in
mem[12'h226]=16'h1001 ; // pushi 0x01
mem[12'h227]=16'hf005 ; // band
mem[12'h228]=16'h522b ; // jz ri2c2_a8_1
mem[12'h229]=16'h1003 ; // pushi 3
mem[12'h22a]=16'h4245 ; // jmp ri2c2_err
mem[12'h22b]=16'h128e ; //ri2c2_a8_1: pushi i2cRead
mem[12'h22c]=16'h122e ; // pushi ri2c2_l9
mem[12'h22d]=16'h4251 ; // jmp SubI2C1
mem[12'h22e]=16'hd000 ; //ri2c2_l9: in
mem[12'h22f]=16'h1008 ; // pushi 8
mem[12'h230]=16'hf003 ; // shl
mem[12'h231]=16'h324f ; // pop ri2c2_val1
mem[12'h232]=16'h1282 ; // PUSHI i2cWAck
mem[12'h233]=16'h1235 ; // PUSHI ri2c2_a10
mem[12'h234]=16'h4251 ; // JMP SubI2C1
mem[12'h235]=16'h128e ; //ri2c2_a10: pushi i2cRead
mem[12'h236]=16'h1238 ; // pushi ri2c2_a11
mem[12'h237]=16'h4251 ; // jmp SubI2C1
mem[12'h238]=16'h224e ; //ri2c2_a11: push ri2c2_raddr
mem[12'h239]=16'hd000 ; // in
mem[12'h23a]=16'h224f ; // push ri2c2_val1
mem[12'h23b]=16'hf006 ; // bor
mem[12'h23c]=16'h8000 ; // st
mem[12'h23d]=16'h1286 ; // PUSHI i2cNAck
mem[12'h23e]=16'h1240 ; // PUSHI ri2c2_a12
mem[12'h23f]=16'h4251 ; // JMP SubI2C1
mem[12'h240]=16'h128a ; //ri2c2_a12: PUSHI i2cStop
mem[12'h241]=16'h1243 ; // PUSHI ri2c2_a13
mem[12'h242]=16'h4251 ; // JMP SubI2C1
mem[12'h243]=16'h1000 ; //ri2c2_a13: pushI 0
mem[12'h244]=16'h4000 ; //ri2c2_rtn: jmp 0x000
mem[12'h245]=16'h3250 ; //ri2c2_err: pop ri2c2_ercode
mem[12'h246]=16'h128a ; // PUSHI i2cStop
mem[12'h247]=16'h1249 ; // PUSHI ri2c2_a14
mem[12'h248]=16'h4251 ; // JMP SubI2C1
mem[12'h249]=16'h2250 ; //ri2c2_a14: push ri2c2_ercode
mem[12'h24a]=16'h4244 ; // jmp ri2c2_rtn
mem[12'h24b]=16'h4000 ; //ri2c2_jmp: 0x4000
mem[12'h24c]=16'h0000 ; //ri2c2_addr: 0x0000
mem[12'h24d]=16'h0000 ; //ri2c2_reg: 0x0000
mem[12'h24e]=16'h0000 ; //ri2c2_raddr: 0x0000
mem[12'h24f]=16'h0000 ; //ri2c2_val1: 0x0000
mem[12'h250]=16'h0000 ; //ri2c2_ercode: 0x0000
mem[12'h251]=16'h226c ; //SubI2C1: PUSH LblJMP
mem[12'h252]=16'hf006 ; // BOR
mem[12'h253]=16'h326b ; // POP RtnSub1
mem[12'h254]=16'h326d ; // POP Sub1Data2
mem[12'h255]=16'h226d ; // PUSH Sub1Data2
mem[12'h256]=16'h7000 ; // LD
mem[12'h257]=16'h3270 ; // POP N
mem[12'h258]=16'h226d ; // PUSH Sub1Data2
mem[12'h259]=16'h1001 ; // PUSHI 1
mem[12'h25a]=16'hf000 ; // ADD
mem[12'h25b]=16'h326e ; // POP Sub1SA
mem[12'h25c]=16'h1000 ; // PUSHI 0
mem[12'h25d]=16'h326f ; // POP i
mem[12'h25e]=16'h226f ; //L1: PUSH i
mem[12'h25f]=16'h226e ; // PUSH Sub1SA
mem[12'h260]=16'hf000 ; // ADD
mem[12'h261]=16'h7000 ; // LD
mem[12'h262]=16'he000 ; // OUT
mem[12'h263]=16'h226f ; // PUSH i
mem[12'h264]=16'h1001 ; // PUSHI 1
mem[12'h265]=16'hf000 ; // ADD
mem[12'h266]=16'h326f ; // POP i
mem[12'h267]=16'h226f ; // PUSH i
mem[12'h268]=16'h2270 ; // PUSH N
mem[12'h269]=16'hf001 ; // SUB
mem[12'h26a]=16'h625e ; // JNZ L1
mem[12'h26b]=16'h4000 ; //RtnSub1: JMP 0x000
mem[12'h26c]=16'h4000 ; //LblJMP: 0x4000
mem[12'h26d]=16'h0000 ; //Sub1Data2: 0x0000
mem[12'h26e]=16'h0000 ; //Sub1SA: 0x0000
mem[12'h26f]=16'h0000 ; //i: 0x0000
mem[12'h270]=16'h0000 ; //N: 0x0000
mem[12'h271]=16'h0003 ; //i2cStart: 3
mem[12'h272]=16'h0001 ; // 1
mem[12'h273]=16'h0003 ; // 3
mem[12'h274]=16'h0002 ; // 2
mem[12'h275]=16'h0000 ; // 0
mem[12'h276]=16'h0003 ; //i2cAddrW: 3
mem[12'h277]=16'h0000 ; // 0
mem[12'h278]=16'h0002 ; // 2
mem[12'h279]=16'h0000 ; // 0
mem[12'h27a]=16'h0003 ; //i2cAddrR: 3
mem[12'h27b]=16'h0001 ; // 1
mem[12'h27c]=16'h0003 ; // 3
mem[12'h27d]=16'h0001 ; // 1
mem[12'h27e]=16'h0003 ; //i2cRAck: 3
mem[12'h27f]=16'h0001 ; // 1
mem[12'h280]=16'h0003 ; // 3
mem[12'h281]=16'h0001 ; // 1
mem[12'h282]=16'h0003 ; //i2cWAck: 3
mem[12'h283]=16'h0000 ; // 0
mem[12'h284]=16'h0002 ; // 2
mem[12'h285]=16'h0000 ; // 0
mem[12'h286]=16'h0003 ; //i2cNAck: 3
mem[12'h287]=16'h0001 ; // 1
mem[12'h288]=16'h0003 ; // 3
mem[12'h289]=16'h0001 ; // 1
mem[12'h28a]=16'h0003 ; //i2cStop: 3
mem[12'h28b]=16'h0002 ; // 2
mem[12'h28c]=16'h0003 ; // 3
mem[12'h28d]=16'h0003 ; // 3
mem[12'h28e]=16'h0011 ; //i2cRead: 0x0011
mem[12'h28f]=16'h0001 ; // 1
mem[12'h290]=16'h0003 ; // 3
mem[12'h291]=16'h0001 ; // 1
mem[12'h292]=16'h0003 ; // 3
mem[12'h293]=16'h0001 ; // 1
mem[12'h294]=16'h0003 ; // 3
mem[12'h295]=16'h0001 ; // 1
mem[12'h296]=16'h0003 ; // 3
mem[12'h297]=16'h0001 ; // 1
mem[12'h298]=16'h0003 ; // 3
mem[12'h299]=16'h0001 ; // 1
mem[12'h29a]=16'h0003 ; // 3
mem[12'h29b]=16'h0001 ; // 1
mem[12'h29c]=16'h0003 ; // 3
mem[12'h29d]=16'h0001 ; // 1
mem[12'h29e]=16'h0003 ; // 3
mem[12'h29f]=16'h0001 ; // 1
end
endmodule