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[/] [hive/] [trunk/] [v04.05/] [boot_code.h] - Rev 4
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/* -------------------------------------------------------------------------------- Module : boot_code.h -------------------------------------------------------------------------------- Function: - Boot code for a processor core. Instantiates: - Nothing. Notes: - For testing (@ core.v): CLR_BASE = 'h0; CLR_SPAN = 2; // gives 4 instructions INTR_BASE = 'h20; // 'd32 INTR_SPAN = 2; // gives 4 instructions -------------------------------------------------------------------------------- */ /* -------------------- -- external stuff -- -------------------- */ `include "boot_code_defs.h" /* ---------------------------------------- -- initialize: fill with default data -- ---------------------------------------- */ integer i; initial begin /* // fill with nop (some compilers need this) for ( i = 0; i < CAPACITY; i = i+1 ) begin ram[i] = { `nop, `__, `__ }; end */ /* --------------- -- boot code -- --------------- */ // Thread 0 : do LED PWM action // All other threads : loop forever /////////////// // clr space // /////////////// // thread 0 i='h00; ram[i] = { `lit_u, `__, `s2 }; // s2=dat i=i+1; ram[i] = 16'h0100 ; // addr i=i+1; ram[i] = { `gto, `P2, `__ }; // goto, pop s2 (addr) // and the rest i='h04; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h08; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h0c; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h10; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h14; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h18; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever i='h1c; ram[i] = { `jmp_ie, -4'd1, `s0, `s0 }; // loop forever //////////////// // intr space // //////////////// /////////////////////// // code & data space // /////////////////////// /* // simple binary count LED display i='h100; ram[i] = { `dat_is, 6'd0, `s0 }; // s0=0 i=i+1; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr // loop start i=i+1; ram[i] = { `add_is, 6'd1, `P0 }; // s0++ i=i+1; ram[i] = { `psu_i, -6'd20, `s0 }; // s0=s0>>20 i=i+1; ram[i] = { `reg_w, `s1, `P0 }; // (s1)=s0, pop s0 i=i+1; ram[i] = { `jmp_ie, -4'd4, `s0, `s0 }; // loop forever // loop end */ /* // simple sequential LED display i='h100; ram[i] = { `dat_is, 6'd0, `s0 }; // s0=0 i=i+1; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr // loop start i=i+1; ram[i] = { `add_is, 6'd1, `P0 }; // s0++ i=i+1; ram[i] = { `shl_is, 6'd10, `s0 }; // s0=s0<<10 i=i+1; ram[i] = { `psu_i, -6'd30, `P0 }; // s0=s0>>30, pop s0 i=i+1; ram[i] = { `pow, `P0, `s0 }; // s0=1<<s0, pop s0 i=i+1; ram[i] = { `reg_w, `s1, `P0 }; // (s1)=s0, pop s0 i=i+1; ram[i] = { `jmp_ie, -4'd6, `s0, `s0 }; // loop forever // loop end */ /* // sequential LED display w/ PWM - moving "dark spot" i='h100; ram[i] = { `dat_is, 6'd0, `s0 }; // s0=0 i=i+1; ram[i] = { `dat_is, `IO_LO, `s1 }; // s1=reg addr i=i+1; ram[i] = { `dat_is, 6'd0, `s2 }; // s2=pwm // loop start i=i+1; ram[i] = { `shl_is, 6'd13, `s0 }; // s0=s0<<13 - isolate decimal i=i+1; ram[i] = { `add, `P0, `P2 }; // s2+=s0, pop s0 - add to pwm counter i=i+1; ram[i] = { `add_is, 6'd1, `P0 }; // s0++ - get next value i=i+1; ram[i] = { `shl_is, 6'd13, `s0 }; // s0=s0<<13 - isolate decimal i=i+1; ram[i] = { `add_xu, `P0, `s2 }; // s2=s2+s0, pop s0 - see if it will cause pwm counter overflow i=i+1; ram[i] = { `shl_is, 6'd19, `P2 }; // s2<<=19 - shift up to ones place i=i+1; ram[i] = { `add, `P2, `s0 }; // s0+=s2, pop s2 - add pwm bit i=i+1; ram[i] = { `shl_is, 6'd11, `P0 }; // s0<<=11 - isolate integer i=i+1; ram[i] = { `psu_i, -6'd30, `P0 }; // s0>>=30 i=i+1; ram[i] = { `pow, `s0, `P0 }; // s0=1<<s0, pop s0 - do one hot i=i+1; ram[i] = { `not, `s0, `P0 }; // s0~=s0 - invert i=i+1; ram[i] = { `reg_w, `s1, `P0 }; // (s1)=s0, pop s0 i=i+1; ram[i] = { `jmp_inz, -6'd13, `s1 }; // loop forever // loop end */ // "bouncing ball" 4 LED display w/ PWM // // s0 : sin // s1 : cos // s2 : alpha (attenuation factor = speed) // s3 : rectified sin, val, one-hot(val) // s4 : // s5 : pwm counter // s6 : // s7 : i/o register address i='h100; ram[i] = { `dat_is, 6'd0, `s0 }; // s0=0 (sin init) i=i+1; ram[i] = { `lit_u, `__, `s1 }; // s1=0x3000,0000 (cos init) i=i+1; ram[i] = 16'h3000 ; // i=i+1; ram[i] = { `shl_is, 6'd16, `P1 }; // i=i+1; ram[i] = { `lit_u, `__, `s2 }; // s2=0x3000 (alpha init) i=i+1; ram[i] = 16'h3000 ; // i=i+1; ram[i] = { `dat_is, 6'd0, `s5 }; // s5=0 (pwm init) i=i+1; ram[i] = { `dat_is, `IO_LO, `s7 }; // s7=reg addr // loop start // sin & cos i=i+1; ram[i] = { `mul_xs, `s2, `s0 }; // s0=s0*s2 (sin*alpha) i=i+1; ram[i] = { `sub, `P0, `P1 }; // s1-=s0 (cos-=sin*alpha) i=i+1; ram[i] = { `mul_xs, `s2, `s1 }; // s1=s1*s2 (cos*alpha) i=i+1; ram[i] = { `add, `P1, `P0 }; // s0-=s1 (sin+=cos*alpha) // |sin| i=i+1; ram[i] = { `cpy, `s0, `s3 }; // s3=s0 i=i+1; ram[i] = { `jmp_inlz, 6'd1, `s3 }; // (s3!<0) ? jmp +1 i=i+1; ram[i] = { `not, `s3, `P3 }; // s3~=s3 // decimal( |sin| ) + pwm to update, + pwm to get ofl i=i+1; ram[i] = { `shl_is, 6'd4, `s3 }; // s3=s3<<4 i=i+1; ram[i] = { `add, `s3, `P5 }; // s5+=s3 (update pwm count) i=i+1; ram[i] = { `add_xu, `P3, `s5 }; // s5=s5+s3, pop s3 (get pwm ofl) // one-hot( int( |sin| ) + pwm ofl ) i=i+1; ram[i] = { `shl_is, -6'd28, `P3 }; // s3>>=28 i=i+1; ram[i] = { `add, `P5, `P3 }; // s3+=s5, pop s5 (add pwm ofl) i=i+1; ram[i] = { `pow, `s3, `P3 }; // s3=1<<s3, pop s3 (one-hot) // output i=i+1; ram[i] = { `reg_w, `s7, `P3 }; // (s7)=s3, pop s3 i=i+1; ram[i] = { `jmp_inz, -6'd15, `s7 }; // loop forever // loop end end