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[/] [pss/] [trunk/] [pss/] [hdl/] [pss/] [zpu_uc/] [zpu_core/] [zpu_core.vhd] - Rev 7

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-- ZPU
--
-- Copyright 2004-2008 oharboe - Øyvind Harboe - oyvind.harboe@zylin.com
-- Copyright 2008 alvieboy - Álvaro Lopes - alvieboy@alvie.com
-- 
-- The FreeBSD license
-- 
-- Redistribution and use in source and binary forms, with or without
-- modification, are permitted provided that the following conditions
-- are met:
-- 
-- 1. Redistributions of source code must retain the above copyright
--    notice, this list of conditions and the following disclaimer.
-- 2. Redistributions in binary form must reproduce the above
--    copyright notice, this list of conditions and the following
--    disclaimer in the documentation and/or other materials
--    provided with the distribution.
-- 
-- THIS SOFTWARE IS PROVIDED BY THE ZPU PROJECT ``AS IS'' AND ANY
-- EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
-- THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
-- PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
-- ZPU PROJECT OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
-- INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
-- (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
-- OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
-- HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
-- STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
-- ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
-- ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
-- 
-- The views and conclusions contained in the software and documentation
-- are those of the authors and should not be interpreted as representing
-- official policies, either expressed or implied, of the ZPU Project.
 
library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use IEEE.STD_LOGIC_UNSIGNED.ALL;
use IEEE.STD_LOGIC_arith.ALL;
use ieee.numeric_std.all;
 
library work;
use work.zpu_config.all;
use work.zpupkg.all;
 
 
-- mem_writeEnable - set to '1' for a single cycle to send off a write request.
--                   mem_write is valid only while mem_writeEnable='1'.
-- mem_readEnable - set to '1' for a single cycle to send off a read request.
-- 
-- mem_busy - It is illegal to send off a read/write request when mem_busy='1'.
--            Set to '0' when mem_read  is valid after a read request.
--            If it goes to '1'(busy), it is on the cycle after mem_read/writeEnable
--            is '1'.
-- mem_addr - address for read/write request
-- mem_read - read data. Valid only on the cycle after mem_busy='0' after 
--            mem_readEnable='1' for a single cycle.
-- mem_write - data to write
-- mem_writeMask - set to '1' for those bits that are to be written to memory upon
--                 write request
-- break - set to '1' when CPU hits break instruction
-- interrupt - set to '1' until interrupts are cleared by CPU. 
 
 
 
entity zpu_core is
	generic (
		stack_address			: integer := 1016
	);
    Port ( clk : in std_logic;
	 		  sreset : in std_logic;
	 		  enable : in std_logic; 
	 		  cpu_present : out std_logic;
	 		  pc_bo	 : out std_logic_vector(31 downto 0);
 
	 		  mem_req : out std_logic;
	 		  mem_we : out std_logic;
	 		  mem_ack : in std_logic; 
	 		  mem_read : in std_logic_vector(wordSize-1 downto 0);
	 		  mem_write : out std_logic_vector(wordSize-1 downto 0);
			  out_mem_addr : out std_logic_vector(maxAddrBitIncIO downto 0);
	 		  mem_writeMask: out std_logic_vector(wordBytes-1 downto 0);
 
	 		  interrupt : in std_logic;
	 		  interrupt_ack : out std_logic;
	 		  break_o : out std_logic;
	 		  zpu_status : out std_logic_vector(63 downto 0));
end zpu_core;
 
architecture behave of zpu_core is
 
type InsnType is 
(
State_AddTop,
State_Dup,
State_DupStackB,
State_Pop,
State_Popdown,
State_Add,
State_Or,
State_And,
State_Store,
State_AddSP,
State_Shift,
State_Nop,
State_Im,
State_LoadSP,
State_StoreSP,
State_Emulate,
State_Load,
State_PushPC,
State_PushSP,
State_PopPC,
State_PopPCRel,
State_Not,
State_Flip,
State_PopSP,
State_Neqbranch,
State_Eq,
State_Loadb,
State_Mult,
State_Lessthan,
State_Lessthanorequal,
State_Ulessthanorequal,
State_Ulessthan,
State_Pushspadd,
State_Call,
State_Callpcrel,
State_Sub,
State_Break,
State_Storeb,
State_Interrupt,
State_InsnFetch
);
 
type StateType is 
(
State_Idle, -- using first state first on the list out of paranoia 
State_Load2,
State_Popped,
State_LoadSP2,
State_LoadSP3,
State_AddSP2,
State_Fetch,
State_Execute,
State_Decode,
State_Decode2,
State_Resync,
 
State_StoreSP2,
State_Resync2,
State_Resync3,
State_Loadb2,
State_Storeb2,
State_Mult2,
State_Mult3,
State_Mult5,
State_Mult6,
State_Mult4,
State_BinaryOpResult
); 
 
signal sp_address_default 		: std_logic_vector(31 downto 0);
 
signal	pc				: std_logic_vector(maxAddrBitIncIO downto 0);
signal	sp				: std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal	incSp			: std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal	incIncSp			: std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal	decSp			: std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal  stackA   		: std_logic_vector(wordSize-1 downto 0);
signal  binaryOpResult		: std_logic_vector(wordSize-1 downto 0);
signal  multResult2  		: std_logic_vector(wordSize-1 downto 0);
signal  multResult3  		: std_logic_vector(wordSize-1 downto 0);
signal  multResult  		: std_logic_vector(wordSize-1 downto 0);
signal  multA 		: std_logic_vector(wordSize-1 downto 0);
signal  multB  		: std_logic_vector(wordSize-1 downto 0);
signal  stackB  		: std_logic_vector(wordSize-1 downto 0);
signal	idim_flag			: std_logic;
signal	busy 				: std_logic;
signal mem_readEnable : std_logic;
signal mem_addr : std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal mem_delayAddr : std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal mem_delayReadEnable : std_logic;
signal mem_busy : std_logic;
signal decodeWord : std_logic_vector(wordSize-1 downto 0);
 
 
signal state : StateType;
signal insn : InsnType;
type InsnArray is array(0 to wordBytes-1) of InsnType;
signal decodedOpcode : InsnArray;
 
type OpcodeArray is array(0 to wordBytes-1) of std_logic_vector(7 downto 0);
 
signal opcode : OpcodeArray;
 
 
 
 
signal	begin_inst			: std_logic;
signal trace_opcode		: std_logic_vector(7 downto 0);
signal	trace_pc				: std_logic_vector(maxAddrBitIncIO downto 0);
signal	trace_sp				: std_logic_vector(maxAddrBitIncIO downto minAddrBit);
signal	trace_topOfStack				: std_logic_vector(wordSize-1 downto 0);
signal	trace_topOfStackB				: std_logic_vector(wordSize-1 downto 0);
 
signal	out_mem_req : std_logic;
 
signal inInterrupt : std_logic;
 
-- state machine.
 
begin
	cpu_present <= '1';
	sp_address_default <= std_logic_vector(to_unsigned(stack_address, 32));
 
	pc_bo <= pc;
	interrupt_ack <= inInterrupt;
 
	zpu_status(maxAddrBitIncIO downto 0) <= trace_pc;
	--zpu_status(31) <= '1';
	--zpu_status(39 downto 32) <= trace_opcode;
	--zpu_status(40) <= '1' when (state = State_Idle) else '0';
	--zpu_status(62) <= '1';
 
	--traceFileGenerate:
   --if Generate_Trace generate
	--trace_file: trace port map (
    --   	clk => clk,
    --   	begin_inst => begin_inst,
    --   	pc => trace_pc,
	--	opcode => trace_opcode,
	--	sp => trace_sp,
	--	memA => trace_topOfStack,
	--	memB => trace_topOfStackB,
	--	busy => busy,
	--	intsp => (others => 'U')
    --    );
	--end generate;
 
 
	-- the memory subsystem will tell us one cycle later whether or 
	-- not it is busy
	out_mem_addr(maxAddrBitIncIO downto minAddrBit) <= mem_addr;
	out_mem_addr(minAddrBit-1 downto 0) <= (others => '0');
	mem_req <= out_mem_req;
 
	incSp <= sp + 1;
	incIncSp <= sp + 2;
	decSp <= sp - 1;
 
	mem_busy <= out_mem_req and not mem_ack; -- '1' when the memory is busy
 
	opcodeControl:
	process(clk)
		variable tOpcode : std_logic_vector(OpCode_Size-1 downto 0);
		variable spOffset : std_logic_vector(4 downto 0);
		variable tSpOffset : std_logic_vector(4 downto 0);
		variable nextPC : std_logic_vector(maxAddrBitIncIO downto 0);
		variable tNextState : InsnType;
		variable tDecodedOpcode : InsnArray;
		variable tMultResult : std_logic_vector(wordSize*2-1 downto 0);
	begin
 
		if (clk'event and clk = '1') then
			if sreset = '1' then
				state <= State_Idle;
				break_o <= '0';
				sp <= sp_address_default(31 downto 2);
 
				pc <= (others => '0');
				idim_flag <= '0';
				begin_inst <= '0';
				mem_we <= '0';
				multA <= (others => '0');
				multB <= (others => '0');
				mem_writeMask <= (others => '1');
				out_mem_req <= '0';
				mem_addr <= (others => DontCareValue);
				mem_write <= (others => DontCareValue);
				inInterrupt <= '0';
			else
				-- we must multiply unconditionally to get pipelined multiplication
	        	tMultResult := multA * multB;
	    		multResult3 <= multResult2;
	    		multResult2 <= multResult;
	    		multResult <= tMultResult(wordSize-1 downto 0);
 
 
				spOffset(4):=not opcode(conv_integer(pc(byteBits-1 downto 0)))(4);
				spOffset(3 downto 0):=opcode(conv_integer(pc(byteBits-1 downto 0)))(3 downto 0);
				nextPC := pc + 1;
 
				-- prepare trace snapshot
				trace_opcode <= opcode(conv_integer(pc(byteBits-1 downto 0)));
				--trace_pc <= pc;
				trace_sp <=	sp;
				trace_topOfStack <= stackA;
				trace_topOfStackB <= stackB;
				begin_inst <= '0';
 
				-- we terminate the requeset as soon as we get acknowledge
				if mem_ack = '1' then
					out_mem_req <= '0';
					mem_we <= '0';
				end if;
 
				if interrupt='0' then
					inInterrupt <= '0'; -- no longer in an interrupt
				end if;
 
				case state is
					when State_Idle =>
						if enable='1' then
							state <= State_Resync; 
						end if;
					-- Initial state of ZPU, fetch top of stack + first instruction 
					when State_Resync =>
						if mem_busy='0' then
							mem_addr <= sp;
							out_mem_req <= '1';
							state <= State_Resync2;
						end if;
					when State_Resync2 =>
						if mem_busy='0' then
							stackA <= mem_read;
							mem_addr <= incSp;
							out_mem_req <= '1';
							state <= State_Resync3;
						end if;
					when State_Resync3 =>
						if mem_busy='0' then
							stackB <= mem_read;
							mem_addr <= pc(maxAddrBitIncIO downto minAddrBit);
							out_mem_req <= '1';
							state <= State_Decode;
						end if;
					when State_Decode =>
						if mem_busy='0' then
							decodeWord <= mem_read;
							state <= State_Decode2;
						end if;
					when State_Decode2 =>
						-- decode 4 instructions in parallel
						for i in 0 to wordBytes-1 loop
							tOpcode := decodeWord((wordBytes-1-i+1)*8-1 downto (wordBytes-1-i)*8);
 
							tSpOffset(4):=not tOpcode(4);
							tSpOffset(3 downto 0):=tOpcode(3 downto 0);
 
							opcode(i) <= tOpcode;
							if (tOpcode(7 downto 7)=OpCode_Im) then
								tNextState:=State_Im;
							elsif (tOpcode(7 downto 5)=OpCode_StoreSP) then
								if tSpOffset = 0 then
									tNextState := State_Pop;
								elsif tSpOffset=1 then
									tNextState := State_PopDown;
								else
									tNextState :=State_StoreSP;
								end if;
							elsif (tOpcode(7 downto 5)=OpCode_LoadSP) then
								if tSpOffset = 0 then
									tNextState :=State_Dup;
								elsif tSpOffset = 1 then
									tNextState :=State_DupStackB;
								else
									tNextState :=State_LoadSP;
								end if;
							elsif (tOpcode(7 downto 5)=OpCode_Emulate) then
								tNextState :=State_Emulate;
								if tOpcode(5 downto 0)=OpCode_Neqbranch then
									tNextState :=State_Neqbranch;
								elsif tOpcode(5 downto 0)=OpCode_Eq then
									tNextState :=State_Eq;
								elsif tOpcode(5 downto 0)=OpCode_Lessthan then
									tNextState :=State_Lessthan;
								elsif tOpcode(5 downto 0)=OpCode_Lessthanorequal then
									--tNextState :=State_Lessthanorequal;
								elsif tOpcode(5 downto 0)=OpCode_Ulessthan then
									tNextState :=State_Ulessthan;
								elsif tOpcode(5 downto 0)=OpCode_Ulessthanorequal then
									--tNextState :=State_Ulessthanorequal;
								elsif tOpcode(5 downto 0)=OpCode_Loadb then
									tNextState :=State_Loadb;
								elsif tOpcode(5 downto 0)=OpCode_Mult then
									tNextState :=State_Mult;
								elsif tOpcode(5 downto 0)=OpCode_Storeb then
									tNextState :=State_Storeb;
								elsif tOpcode(5 downto 0)=OpCode_Pushspadd then
									tNextState :=State_Pushspadd;
								elsif tOpcode(5 downto 0)=OpCode_Callpcrel then
									tNextState :=State_Callpcrel;
								elsif tOpcode(5 downto 0)=OpCode_Call then
									--tNextState :=State_Call;
								elsif tOpcode(5 downto 0)=OpCode_Sub then
									tNextState :=State_Sub;
								elsif tOpcode(5 downto 0)=OpCode_PopPCRel then
									--tNextState :=State_PopPCRel;
								end if;								
							elsif (tOpcode(7 downto 4)=OpCode_AddSP) then
								if tSpOffset = 0 then
									tNextState := State_Shift;
								elsif tSpOffset = 1 then
									tNextState := State_AddTop;
								else
									tNextState :=State_AddSP;
								end if;
							else
								case tOpcode(3 downto 0) is
									when OpCode_Nop =>
										tNextState :=State_Nop;
									when OpCode_PushSP =>
										tNextState :=State_PushSP;
									when OpCode_PopPC =>
										tNextState :=State_PopPC;
									when OpCode_Add =>
										tNextState :=State_Add;
									when OpCode_Or =>
										tNextState :=State_Or;
									when OpCode_And =>
										tNextState :=State_And;
									when OpCode_Load =>
										tNextState :=State_Load;
									when OpCode_Not =>
										tNextState :=State_Not;
									when OpCode_Flip =>
										tNextState :=State_Flip;
									when OpCode_Store =>
										tNextState :=State_Store;
									when OpCode_PopSP =>
										tNextState :=State_PopSP;
									when others =>
										tNextState := State_Break;
 
								end case;
							end if;
							tDecodedOpcode(i) := tNextState;
 
						end loop;
 
						insn <= tDecodedOpcode(conv_integer(pc(byteBits-1 downto 0)));
 
						-- once we wrap, we need to fetch
						tDecodedOpcode(0) := State_InsnFetch;
 
						decodedOpcode <= tDecodedOpcode;
						state <= State_Execute;
 
 
 
						-- Each instruction must:
						--
						-- 1. set idim_flag
						-- 2. increase pc if applicable
						-- 3. set next state if appliable
						-- 4. do it's operation
 
					when State_Execute =>
						insn <= decodedOpcode(conv_integer(nextPC(byteBits-1 downto 0)));
 
						case insn is
							when State_InsnFetch =>
								state <= State_Fetch;
							when State_Im =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '1';
									pc <= pc + 1;
 
									if idim_flag='1' then 
										stackA(wordSize-1 downto 7) <= stackA(wordSize-8 downto 0);
										stackA(6 downto 0) <= opcode(conv_integer(pc(byteBits-1 downto 0)))(6 downto 0);
									else
										out_mem_req <= '1';
										mem_we <= '1';
										mem_addr <= incSp;
										mem_write <= stackB;
										stackB <= stackA;
										sp <= decSp;
										for i in wordSize-1 downto 7 loop
											stackA(i) <= opcode(conv_integer(pc(byteBits-1 downto 0)))(6);
										end loop;
										stackA(6 downto 0) <= opcode(conv_integer(pc(byteBits-1 downto 0)))(6 downto 0);
									end if;
								else	
									insn <= insn;
								end if;
							when State_StoreSP =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_StoreSP2;
 
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= sp+spOffset;
									mem_write <= stackA;
									stackA <= stackB;
									sp <= incSp;
								else	
									insn <= insn;
								end if;
 
 
							when State_LoadSP =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_LoadSP2;
 
									sp <= decSp;
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= incSp;
									mem_write <= stackB;
								else	
									insn <= insn;
								end if;
							when State_Emulate =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									sp <= decSp;
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= incSp;
									mem_write <= stackB;
									stackA <= (others => DontCareValue);
									stackA(maxAddrBitIncIO downto 0) <= pc + 1;
									stackB <= stackA;
 
									-- The emulate address is:
									--        98 7654 3210
									-- 0000 00aa aaa0 0000
									pc <= (others => '0');
									pc(9 downto 5) <= opcode(conv_integer(pc(byteBits-1 downto 0)))(4 downto 0);
									state <= State_Fetch;
								else	
									insn <= insn;
								end if;
							when State_Callpcrel =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									stackA <= (others => DontCareValue);
									stackA(maxAddrBitIncIO downto 0) <= pc + 1;
 
									pc <= pc + stackA(maxAddrBitIncIO downto 0);
									state <= State_Fetch;
								else	
									insn <= insn;
								end if;
							when State_Call =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									stackA <= (others => DontCareValue);
									stackA(maxAddrBitIncIO downto 0) <= pc + 1;
									pc <= stackA(maxAddrBitIncIO downto 0);
									state <= State_Fetch;
								else	
									insn <= insn;
								end if;
							when State_AddSP =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_AddSP2;
 
									out_mem_req <= '1';
									mem_addr <= sp+spOffset;
								else	
									insn <= insn;
								end if;
							when State_PushSP =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= pc + 1;
 
									sp <= decSp;
									stackA <= (others => '0');
									stackA(maxAddrBitIncIO downto minAddrBit) <= sp;
									stackB <= stackA;
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= incSp;
									mem_write <= stackB;
								else	
									insn <= insn;
								end if;
							when State_PopPC =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= stackA(maxAddrBitIncIO downto 0);
									sp <= incSp;
 
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= incSp;
									mem_write <= stackB;
									state <= State_Resync;
								else	
									insn <= insn;
								end if;
							when State_PopPCRel =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= stackA(maxAddrBitIncIO downto 0) + pc;
									sp <= incSp;
 
									out_mem_req <= '1';
									mem_we <= '1';
									mem_addr <= incSp;
									mem_write <= stackB;
									state <= State_Resync;
								else	
									insn <= insn;
								end if;
							when State_Add =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									stackA <= stackA + stackB;
 
									out_mem_req <= '1';
									mem_addr <= incIncSp;
									sp <= incSp;
									state <= State_Popped;
								else	
									insn <= insn;
								end if;
							when State_Sub =>
								begin_inst <= '1';
								idim_flag <= '0';
								binaryOpResult <= stackB - stackA;
								state <= State_BinaryOpResult;
							when State_Pop =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									mem_addr <= incIncSp;
									out_mem_req <= '1';
									sp <= incSp;
									stackA <= stackB;
									state <= State_Popped;						
								else	
									insn <= insn;
								end if;
							when State_PopDown =>
								if mem_busy='0' then
									-- PopDown leaves top of stack unchanged
									begin_inst <= '1';
									idim_flag <= '0';
									mem_addr <= incIncSp;
									out_mem_req <= '1';
									sp <= incSp;
									state <= State_Popped;						
								else	
									insn <= insn;
								end if;
							when State_Or =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									stackA <= stackA or stackB;
									out_mem_req <= '1';
									mem_addr <= incIncSp;
									sp <= incSp;
									state <= State_Popped;
								else	
									insn <= insn;
								end if;
							when State_And =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
 
									stackA <= stackA and stackB;
									out_mem_req <= '1';
									mem_addr <= incIncSp;
									sp <= incSp;
									state <= State_Popped;
								else	
									insn <= insn;
								end if;
							when State_Eq =>
								begin_inst <= '1';
								idim_flag <= '0';
 
			            		binaryOpResult <= (others => '0');
			                	if (stackA=stackB) then
			                		binaryOpResult(0) <= '1';
			                	end if;
								state <= State_BinaryOpResult;
			                when State_Ulessthan =>
								begin_inst <= '1';
								idim_flag <= '0';
 
			            		binaryOpResult <= (others => '0');
			                	if (stackA<stackB) then
			                		binaryOpResult(0) <= '1';
			                	end if;
								state <= State_BinaryOpResult;
			                when State_Ulessthanorequal =>
								begin_inst <= '1';
								idim_flag <= '0';
 
			            		binaryOpResult <= (others => '0');
			                	if (stackA<=stackB) then
			                		binaryOpResult(0) <= '1';
			                	end if;
								state <= State_BinaryOpResult;
			                when State_Lessthan =>
								begin_inst <= '1';
								idim_flag <= '0';
 
			            		binaryOpResult <= (others => '0');
			                	if (ieee.std_logic_arith.signed(stackA)<ieee.std_logic_arith.signed(stackB)) then
			                		binaryOpResult(0) <= '1';
			                	end if;
								state <= State_BinaryOpResult;
			                when State_Lessthanorequal =>
								begin_inst <= '1';
								idim_flag <= '0';
 
			            		binaryOpResult <= (others => '0');
			                	if (ieee.std_logic_arith.signed(stackA)<=ieee.std_logic_arith.signed(stackB)) then
			                		binaryOpResult(0) <= '1';
			                	end if;
								state <= State_BinaryOpResult;
							when State_Load =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_Load2;
 
									mem_addr <= stackA(maxAddrBitIncIO downto minAddrBit);
									out_mem_req <= '1';
								else	
									insn <= insn;
								end if;
 
							when State_Dup =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= pc + 1; 
 
									sp <= decSp;
									stackB <= stackA;
									mem_write <= stackB;
									mem_addr <= incSp;
									out_mem_req <= '1';
									mem_we <= '1';
								else	
									insn <= insn;
								end if;
							when State_DupStackB =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= pc + 1; 
 
									sp <= decSp;
									stackA <= stackB;
									stackB <= stackA;
									mem_write <= stackB;
									mem_addr <= incSp;
									out_mem_req <= '1';
									mem_we <= '1';
								else	
									insn <= insn;
								end if;
							when State_Store =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= pc + 1;
									mem_addr <= stackA(maxAddrBitIncIO downto minAddrBit);
									mem_write <= stackB;
									out_mem_req <= '1';
									mem_we <= '1';
									sp <= incIncSp;
									state <= State_Resync;
								else	
									insn <= insn;
								end if;
							when State_PopSP =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									pc <= pc + 1;
 
									mem_write <= stackB;
									mem_addr <= incSp;
									out_mem_req <= '1';
									mem_we <= '1';
									sp <= stackA(maxAddrBitIncIO downto minAddrBit);
									state <= State_Resync;
								else	
									insn <= insn;
								end if;
							when State_Nop =>	
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1;
							when State_Not =>
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1; 
 
								stackA <= not stackA;
							when State_Flip =>
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1; 
 
								for i in 0 to wordSize-1 loop
									stackA(i) <= stackA(wordSize-1-i);
					  			end loop;
							when State_AddTop =>
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1; 
 
								stackA <= stackA + stackB;
							when State_Shift =>
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1; 
 
								stackA(wordSize-1 downto 1) <= stackA(wordSize-2 downto 0);
								stackA(0) <= '0';
							when State_Pushspadd =>
								begin_inst <= '1';
								idim_flag <= '0';
								pc <= pc + 1; 
 
								stackA <= (others => '0');
								stackA(maxAddrBitIncIO downto minAddrBit) <= stackA(maxAddrBitIncIO-minAddrBit downto 0)+sp;
							when State_Neqbranch =>
								-- branches are almost always taken as they form loops
								begin_inst <= '1';
								idim_flag <= '0';
								sp <= incIncSp;
			                	if (stackB/=0) then
			                		pc <= stackA(maxAddrBitIncIO downto 0) + pc;
			                	else
			                		pc <= pc + 1;
			                	end if;		
			                	-- need to fetch stack again.				
								state <= State_Resync;
			                when State_Mult =>
								begin_inst <= '1';
								idim_flag <= '0';
 
								multA <= stackA;
								multB <= stackB;
								state <= State_Mult2;
							when State_Break =>
								report "Break instruction encountered" severity failure;
								break_o <= '1';
 
							when State_Loadb =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_Loadb2;
 
									mem_addr <= stackA(maxAddrBitIncIO downto minAddrBit);
									out_mem_req <= '1';
								else	
									insn <= insn;
								end if;
							when State_Storeb =>
								if mem_busy='0' then
									begin_inst <= '1';
									idim_flag <= '0';
									state <= State_Storeb2;
 
									mem_addr <= stackA(maxAddrBitIncIO downto minAddrBit);
									out_mem_req <= '1';
								else	
									insn <= insn;
								end if;
 
							when others =>
	--							sp <= (others => DontCareValue);
								report "Illegal instruction" severity failure;
								break_o <= '1';
						end case;
 
 
					when State_StoreSP2 =>
						if mem_busy='0' then
							mem_addr <= incSp;
							out_mem_req <= '1';
							state <= State_Popped;
						end if;
					when State_LoadSP2 =>
						if mem_busy='0' then
							state <= State_LoadSP3;
							out_mem_req <= '1';
							mem_addr <= sp+spOffset+1;
						end if;
					when State_LoadSP3 =>
						if mem_busy='0' then
							pc <= pc + 1;
							state <= State_Execute;
							stackB <= stackA;
							stackA <= mem_read;
						end if;
					when State_AddSP2 =>
						if mem_busy='0' then
							pc <= pc + 1;
							state <= State_Execute;
							stackA <= stackA + mem_read;
						end if;
					when State_Load2 =>
						if mem_busy='0' then
							stackA <= mem_read;
							pc <= pc + 1;
							state <= State_Execute;
						end if;
					when State_Loadb2 =>
						if mem_busy='0' then
							stackA <= (others => '0');
							stackA(7 downto 0) <= mem_read(((wordBytes-1-conv_integer(stackA(byteBits-1 downto 0)))*8+7) downto (wordBytes-1-conv_integer(stackA(byteBits-1 downto 0)))*8);
							pc <= pc + 1;
							state <= State_Execute;
						end if;
					when State_Storeb2 =>
						if mem_busy='0' then
							mem_addr <= stackA(maxAddrBitIncIO downto minAddrBit);
							mem_write <= mem_read;
							mem_write(((wordBytes-1-conv_integer(stackA(byteBits-1 downto 0)))*8+7) downto (wordBytes-1-conv_integer(stackA(byteBits-1 downto 0)))*8) <= stackB(7 downto 0) ;
							out_mem_req <= '1';
							mem_we <= '1';
							pc <= pc + 1;
							sp <= incIncSp;
							state <= State_Resync;
						end if;
					when State_Fetch =>
						if mem_busy='0' then
							if interrupt='1' and inInterrupt='0' and idim_flag='0' then
								-- We got an interrupt
								inInterrupt <= '1';
 
								sp <= decSp;
								out_mem_req <= '1';
								mem_we <= '1';
								mem_addr <= incSp;
								mem_write <= stackB;
								stackA <= (others => DontCareValue);
								stackA(maxAddrBitIncIO downto 0) <= pc;
								stackB <= stackA;
 
								pc <= conv_std_logic_vector(32, maxAddrBitIncIo+1); -- interrupt address
 
				  				report "ZPU jumped to interrupt!" severity note;
							else
								mem_addr <= pc(maxAddrBitIncIO downto minAddrBit);
								out_mem_req <= '1';
								state <= State_Decode;
							end if;
						end if;
	                when State_Mult2 =>
						state <= State_Mult3;
	                when State_Mult3 =>
						state <= State_Mult4;
	                when State_Mult4 =>
						state <= State_Mult5;
	                when State_Mult5 =>
	            		stackA <= multResult3;
	                	state <= State_Mult6;
	                when State_Mult6 =>
						if mem_busy='0' then
							out_mem_req <= '1';
							mem_addr <= incIncSp;
							sp <= incSp;
							state <= State_Popped;
						end if;
					when State_BinaryOpResult =>
						if mem_busy='0' then
							-- NB!!!! we know that the memory isn't busy at this point!!!!
							out_mem_req <= '1';
							mem_addr <= incIncSp;
							sp <= incSp;
							stackA <= binaryOpResult;
							state <= State_Popped;
						end if;
					when State_Popped =>
						if mem_busy='0' then
							pc <= pc + 1;
							stackB <= mem_read;
							state <= State_Execute;
						end if;
					when others =>	
	--					sp <= (others => DontCareValue);
						report "Illegal state" severity failure;
						break_o <= '1';
				end case;
			end if;
		end if;
	end process;
 
 
 
end behave;
 

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