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ericw |
/*
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--------------------------------------------------------------------------------
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Module : boot_code.h
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--------------------------------------------------------------------------------
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Function:
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- Boot code for a processor core.
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Instantiates:
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- Nothing.
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Notes:
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- For testing (@ core.v):
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CLR_BASE = 'h0;
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CLR_SPAN = 2; // gives 4 instructions
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INTR_BASE = 'h20; // 'd32
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INTR_SPAN = 2; // gives 4 instructions
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--------------------------------------------------------------------------------
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*/
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/*
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--------------------
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-- external stuff --
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--------------------
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*/
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`include "boot_code_defs.h"
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`include "op_encode.h"
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`include "reg_set_addr.h"
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/*
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----------------------------------------
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-- initialize: fill with default data --
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----------------------------------------
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*/
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integer i;
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initial begin
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/* // fill with nop (some compilers need this)
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for ( i = 0; i < CAPACITY; i = i+1 ) begin
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ram[i] = { `nop, `s0, `s0 };
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end
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*/
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/*
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---------------
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-- boot code --
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---------------
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*/
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/*
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------------
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-- TEST 0 --
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------------
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*/
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// Log base 2
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// Thread 0 : Get input 32 bit GPIO, calculate log2, output 32 bit GPIO.
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// Other threads : do nothing, loop forever
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///////////////
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// clr space //
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///////////////
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i='h0; ram[i] = { `lit_u, `__, `s1 }; // s1=addr
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i=i+1; ram[i] = 16'h0040 ; //
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i=i+1; ram[i] = { `gto, `P1, `__ }; // goto, pop s1 (addr)
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//
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i='h04; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h08; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h0c; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h10; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h14; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h18; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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i='h1c; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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////////////////
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// intr space //
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////////////////
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///////////////////////
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// code & data space //
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///////////////////////
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// read & write 32 bit GPIO data to & from s0
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i='h40; ram[i] = { `lit_u, `__, `s3 }; // s3=addr
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i=i+1; ram[i] = 16'h0080 ; //
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i=i+1; ram[i] = { `gsb, `P3, `s3 }; // gsb, pop s3 (addr)
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// do s0=exp2(s0)
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i=i+1; ram[i] = { `lit_u, `__, `s3 }; // s3=addr
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i=i+1; ram[i] = 16'h0090 ; //
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i=i+1; ram[i] = { `gsb, `P3, `s7 }; // gsb, pop s3 (addr)
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// write s0 data to 32 bit GPIO
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i=i+1; ram[i] = { `lit_u, `__, `s3 }; // s3=addr
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i=i+1; ram[i] = 16'h0070 ; //
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i=i+1; ram[i] = { `gsb, `P3, `s3 }; // gsb, pop s3 (addr)
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// loop forever
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i=i+1; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever
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// sub : read 32 bit GPIO => s0, return to (s3)
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i='h60; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_rs, `P1, `s0 }; // s0=(s1), pop s1
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i=i+1; ram[i] = { `dat_is, `IO_HI, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_rh, `P1, `P0 }; // s0=(s1), pop both
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i=i+1; ram[i] = { `gto, `P3, `__ }; // return, pop s3
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// sub : write s0 => 32 bit GPIO, return to (s3)
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i='h70; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_w, `P1, `s0 }; // (s1)=s0, pop s1
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i=i+1; ram[i] = { `dat_is, `IO_HI, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_wh, `P1, `s0 }; // (s1)=s0, pop s1
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i=i+1; ram[i] = { `gto, `P3, `__ }; // return, pop s3
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// sub : read & write 32 bit GPIO => s0, return to (s3)
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i='h80; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_rs, `s1, `s0 }; // s0=(s1)
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i=i+1; ram[i] = { `reg_w, `P1, `s0 }; // (s1)=s0, pop s1
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i=i+1; ram[i] = { `dat_is, `IO_HI, `s1 }; // s1=reg addr
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i=i+1; ram[i] = { `reg_rh, `s1, `P0 }; // s0=(s1), pop s0
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i=i+1; ram[i] = { `reg_wh, `P1, `s0 }; // (s1)=s0, pop s1
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i=i+1; ram[i] = { `gto, `P3, `__ }; // return, pop s3
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// sub : s0=exp2(s0), return to (s7)
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//
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// input is c[31:27].m[26:0] unsigned fixed decimal
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// output is out[31:0] an unsigned 32 bit integer
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//
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// s0 : input, output
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// s1 : running multiply
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// s2 : running root
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// s3 : fudge factor
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// s4 :
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// s5 :
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// s6 : loop index
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// s7 : sub return addr
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//
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// setup
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i='h90; ram[i] = { `flp, `s0, `P0 }; // flp(s0) (to examine lsbs via msb)
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i=i+1; ram[i] = { `psu_i, 6'd31, `s1 }; // s1=0x8000,0000 (starting value = 1)
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i=i+1; ram[i] = { `cpy, `s1, `s2 }; // s2=0x8000,000b (starting root = 2^2^-27)
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i=i+1; ram[i] = { `add_is, 6'hb, `P2 }; //
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i=i+1; ram[i] = { `lit_u, `__, `s3 }; // s3=0x173c,e500 (fudge factor bits)
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i=i+1; ram[i] = 16'he500 ; //
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i=i+1; ram[i] = { `lit_h, `__, `P3 }; //
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i=i+1; ram[i] = 16'h173c ; //
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i=i+1; ram[i] = { `dat_is, 6'd26, `s6 }; // s6=26 (loop index)
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// loop start
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// jump 0 start
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i=i+1; ram[i] = { `jmp_inlz, 6'd2, `s0 }; // (s0[31]==0) ? jump +2 (skip running mult)
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i=i+1; ram[i] = { `mul_xu, `s2, `P1 }; // s1*=s2
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i=i+1; ram[i] = { `shl_is, 6'd1, `P1 }; // s1<<=1 (so msb=1)
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// jump 0 end
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i=i+1; ram[i] = { `mul_xu, `s2, `P2 }; // s2*=s2 (square to get next root)
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i=i+1; ram[i] = { `shl_is, 6'd1, `P2 }; // s2<<=1 (so msb=1 & lsb=0)
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// jump 1 start
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i=i+1; ram[i] = { `jmp_inlz, 6'd1, `s3 }; // (s3[31]==0) ? jump +1 (no fudge bit)
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i=i+1; ram[i] = { `add_is, 6'd1, `P2 }; // s2++ (set lsb of running root)
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// jump 1 end
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i=i+1; ram[i] = { `shl_is, 6'd1, `P0 }; // s0<<=1 (get next input bit)
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i=i+1; ram[i] = { `shl_is, 6'd1, `P3 }; // s2<<=1 (get next fudge bit)
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i=i+1; ram[i] = { `add_is, -6'd1, `P6 }; // s6-- (loop index--)
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i=i+1; ram[i] = { `jmp_inlz, -6'd11, `s6 }; // (s6>=0) ? jump -11 (loop again)
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// loop end
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// final shift
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i=i+1; ram[i] = { `flp, `s0, `P0 }; // flp(s0) (flip remaining bits)
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i=i+1; ram[i] = { `add_is, -6'd31, `P0 }; // s0-=31
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i=i+1; ram[i] = { `shl_u, `P0, `P1 }; // s1<<=s0, pop s0
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// cleanup, return
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i=i+1; ram[i] = { `cpy, `P1, `s0 }; // s0=s1, pop s1 (move)
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i=i+1; ram[i] = { `pop, 8'b01000110 }; // pop s2, s3, s6
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i=i+1; ram[i] = { `gto, `P7, `__ }; // return, pop s7
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// end sub
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end
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