I've been working on coding a simple stack memory. It has 4 address bits and thus can store 16 elements. Everything works fine, but the problem is that when all 16 memory elements have been written to, the counter that keeps track of the memory location overflows and resets it to 0000. I cannot find out the reason for this. All my registers are of correct width.
reg_pop are incremented and decremented together, and these are the registers that keep track of the memory location.
Here is the simulation showing the overflow.
Here is the code:
module stack # (parameter dbits = 3, abits = 4)( input clock, input reset, input push, input pop, input [dbits-1:0] din, output [dbits-1:0] dout, output full, output empty ); reg [dbits-1:0] regarray[2**abits-1:0]; //number of words in fifo = 2^(number of address bits) reg [abits-1:0] reg_push, reg_pop, next_push, next_pop; reg full_reg, empty_reg, full_next, empty_next; reg [dbits-1:0] out; wire wr_en; wire db_push, db_pop; reg dffpop1, dffpop2, dffpush1, dffpush2; always @ (posedge clock) dffpush1 <= push; always @ (posedge clock) dffpush2 <= dffpush1; assign db_push = ~dffpush2 & dffpush1; //monostable multivibrator to detect only one pulse of the button always @ (posedge clock) dffpop1 <= pop; always @ (posedge clock) dffpop2 <= dffpop1; assign db_pop = ~dffpop2 & dffpop1; //monostable multivibrator to detect only one pulse of the button assign wr_en = db_push & ~full; //only push if write signal is high and stack is not full //always block for write operation always @ (posedge clock) if(wr_en) regarray[reg_push] = din; //always block for read operation always @ (posedge clock) begin if(db_pop) out <= regarray[reg_pop]; end always @ (posedge clock or posedge reset) begin if(reset) begin full_reg <= 0; empty_reg <= 1; reg_push <= 0; reg_pop <= 0; end else begin full_reg <= full_next;//created the next registers to avoid the error of mixing blocking and non blocking assignment to the same signal empty_reg <= empty_next; reg_push <= next_push; reg_pop <= next_pop; end end always @ (*) begin full_next = full_reg; //default values stay the same empty_next = empty_reg; next_push = reg_push; next_pop = reg_pop; if(db_push) begin if(~full) //if stack is not full continue begin empty_next = 0; next_push = reg_push + 1; next_pop = reg_pop + 1; if(reg_push == (2**abits - 1)) full_next = 1; //all registers have been written to end end else if (db_pop) begin if(~empty) //if stack is not empty continue begin full_next = 0; next_pop = reg_pop - 1; next_push = reg_push - 1; if(reg_pop == 0) empty_next = 1; //all data has been read end end end assign full = full_reg; assign empty = empty_reg; assign dout = out; endmodule
Now if I use this stack without making it reach its full capacity, it will work perfectly. It's only when I store all 16 elements into it that the problem arises.