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SEm-Labos/Libs/NanoBlaze/hdl/rom_mapped.vhd
github-classroom[bot] d212040c30
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2024-02-23 13:01:05 +00:00

432 lines
32 KiB
VHDL
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ARCHITECTURE mapped OF programRom IS
subtype opCodeType is std_ulogic_vector(5 downto 0);
constant opLoadC : opCodeType := "000000";
constant opLoadR : opCodeType := "000001";
constant opInputC : opCodeType := "000100";
constant opInputR : opCodeType := "000101";
constant opFetchC : opCodeType := "000110";
constant opFetchR : opCodeType := "000111";
constant opAndC : opCodeType := "001010";
constant opAndR : opCodeType := "001011";
constant opOrC : opCodeType := "001100";
constant opOrR : opCodeType := "001101";
constant opXorC : opCodeType := "001110";
constant opXorR : opCodeType := "001111";
constant opTestC : opCodeType := "010010";
constant opTestR : opCodeType := "010011";
constant opCompC : opCodeType := "010100";
constant opCompR : opCodeType := "010101";
constant opAddC : opCodeType := "011000";
constant opAddR : opCodeType := "011001";
constant opAddCyC : opCodeType := "011010";
constant opAddCyR : opCodeType := "011011";
constant opSubC : opCodeType := "011100";
constant opSubR : opCodeType := "011101";
constant opSubCyC : opCodeType := "011110";
constant opSubCyR : opCodeType := "011111";
constant opShRot : opCodeType := "100000";
constant opOutputC : opCodeType := "101100";
constant opOutputR : opCodeType := "101101";
constant opStoreC : opCodeType := "101110";
constant opStoreR : opCodeType := "101111";
subtype shRotCinType is std_ulogic_vector(2 downto 0);
constant shRotLdC : shRotCinType := "00-";
constant shRotLdM : shRotCinType := "01-";
constant shRotLdL : shRotCinType := "10-";
constant shRotLd0 : shRotCinType := "110";
constant shRotLd1 : shRotCinType := "111";
constant registerAddressBitNb : positive := 4;
constant shRotPadLength : positive
:= dataOut'length - opCodeType'length - registerAddressBitNb
- 1 - shRotCinType'length;
subtype shRotDirType is std_ulogic_vector(1+shRotPadLength-1 downto 0);
constant shRotL : shRotDirType := (0 => '0', others => '-');
constant shRotR : shRotDirType := (0 => '1', others => '-');
subtype branchCodeType is std_ulogic_vector(4 downto 0);
constant brRet : branchCodeType := "10101";
constant brCall : branchCodeType := "11000";
constant brJump : branchCodeType := "11010";
constant brReti : branchCodeType := "11100";
constant brEni : branchCodeType := "11110";
subtype branchConditionType is std_ulogic_vector(2 downto 0);
constant brDo : branchConditionType := "000";
constant brZ : branchConditionType := "100";
constant brNZ : branchConditionType := "101";
constant brC : branchConditionType := "110";
constant brNC : branchConditionType := "111";
subtype memoryWordType is std_ulogic_vector(dataOut'range);
type memoryArrayType is array (0 to 2**address'length-1) of memoryWordType;
signal memoryArray : memoryArrayType := (
--===============================================================
-- 1) Test logical operations with direct values
-----------------------------------------------------------------
16#000# => opLoadC & "0111" & "00000001", -- LOAD s7, 01
-----------------------------------------------------------------
-- Test "LOAD", "AND"
-----------------------------------------------------------------
16#001# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#002# => opAndC & "0000" & "00110011", -- AND s0, 33
16#003# => opCompC & "0000" & "00000011", -- COMPARE s0, 03
16#004# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "OR"
-----------------------------------------------------------------
16#005# => opLoadC & "0001" & "00001111", -- LOAD s1, 0F
16#006# => opOrC & "0001" & "00110011", -- OR s1, 33
16#007# => opCompC & "0001" & "00111111", -- COMPARE s1, 3F
16#008# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "XOR"
-----------------------------------------------------------------
16#009# => opLoadC & "0010" & "00001111", -- LOAD s2, 0F
16#00A# => opXorC & "0010" & "00110011", -- XOR s2, 33
16#00B# => opCompC & "0010" & "00111100", -- COMPARE s2, 3C
16#00C# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 2) Test logical operations with registers
-----------------------------------------------------------------
16#00D# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "LOAD"
-----------------------------------------------------------------
16#00E# => opLoadC & "0000" & "00110011", -- LOAD s0, 33
16#00F# => opLoadR & "0011" & "0000----", -- LOAD s3, s0
16#010# => opCompC & "0011" & "00110011", -- COMPARE s3, 33
16#011# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "AND"
-----------------------------------------------------------------
16#012# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#013# => opAndR & "0000" & "0011----", -- AND s0, s3
16#014# => opCompC & "0000" & "00000011", -- COMPARE s0, 03
16#015# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "OR"
-----------------------------------------------------------------
16#016# => opLoadC & "0001" & "00001111", -- LOAD s1, 0F
16#017# => opOrR & "0001" & "0011----", -- OR s1, s3
16#018# => opCompC & "0001" & "00111111", -- COMPARE s1, 3F
16#019# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "XOR"
-----------------------------------------------------------------
16#01A# => opLoadC & "0010" & "00001111", -- LOAD s2, 0F
16#01B# => opXorR & "0010" & "0011----", -- XOR s2, s3
16#01C# => opCompC & "0010" & "00111100", -- COMPARE s2, 3C
16#01D# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 3) Test arithmetic operations with constants
-----------------------------------------------------------------
16#01E# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "ADD" and "ADDCY"
-----------------------------------------------------------------
16#01F# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#020# => opAddC & "0000" & "00110001", -- ADD s0, 31 ; 40
16#021# => opAddCyC & "0000" & "11110000", -- ADDCY s0, F0 ; 130
16#022# => opAddCyC & "0000" & "11110000", -- ADDCY s0, F0 ; 121
16#023# => opAddC & "0000" & "00001111", -- ADD s0, 0F ; 30
16#024# => opCompC & "0000" & "00110000", -- COMPARE s0, 30
16#025# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "SUB" and "SUBCY"
-----------------------------------------------------------------
16#026# => opLoadC & "0001" & "00001111", -- LOAD s1, 0F
16#027# => opSubC & "0001" & "00001100", -- SUB s1, 0C ; 03
16#028# => opSubCyC & "0001" & "11110000", -- SUBCY s1, F0 ; 113
16#029# => opSubCyC & "0001" & "11110000", -- SUBCY s1, F0 ; 22
16#02A# => opSubC & "0001" & "00000001", -- SUB s1, 01 ; 21
16#02B# => opCompC & "0001" & "00100001", -- COMPARE s1, 21
16#02C# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 4) Test arithmetic operations with registers
-----------------------------------------------------------------
16#02D# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "ADD" and "ADDCY"
-----------------------------------------------------------------
16#02E# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#02F# => opLoadC & "0001" & "00110001", -- LOAD s1, 31
16#030# => opLoadC & "0010" & "11110000", -- LOAD s2, F0
16#031# => opLoadC & "0011" & "00001111", -- LOAD s3, 0F
16#032# => opAddR & "0000" & "0001----", -- ADD s0, s1 ; 40
16#033# => opAddCyR & "0000" & "0010----", -- ADDCY s0, s2 ; 130
16#034# => opAddCyR & "0000" & "0010----", -- ADDCY s0, s2 ; 121
16#035# => opAddR & "0000" & "0011----", -- ADD s0, s3 ; 30
16#036# => opCompC & "0000" & "00110000", -- COMPARE s0, 30
16#037# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "SUB" and "SUBCY"
-----------------------------------------------------------------
16#038# => opLoadC & "0001" & "00001111", -- LOAD s1, 0F
16#039# => opLoadC & "0000" & "00001100", -- LOAD s0, 0C
16#03A# => opLoadC & "0010" & "11110000", -- LOAD s2, F0
16#03B# => opLoadC & "0011" & "00000001", -- LOAD s3, 01
16#03C# => opSubR & "0001" & "0000----", -- SUB s1, s0 ; 03
16#03D# => opSubCyR & "0001" & "0010----", -- SUBCY s1, s2 ; 113
16#03E# => opSubCyR & "0001" & "0010----", -- SUBCY s1, s2 ; 22
16#03F# => opSubR & "0001" & "0011----", -- SUB s1, s3 ; 21
16#040# => opCompC & "0001" & "00100001", -- COMPARE s1, 21
16#041# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 5) Test shifts
-----------------------------------------------------------------
16#042# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test shift right
-----------------------------------------------------------------
16#043# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F ; 0F
16#044# => opShRot & "0000" & shRotR & shRotLd0,-- SR0 s0 ; 07
16#045# => opShRot & "0000" & shRotR & shRotLdM,-- SRX s0 ; 03
16#046# => opShRot & "0000" & shRotR & shRotLd1,-- SR1 s0 ; 81
16#047# => opShRot & "0000" & shRotR & shRotLdM,-- SRX s0 ; C0, C=1
16#048# => opShRot & "0000" & shRotR & shRotLdC,-- SRA s0 ; E0, C=0
16#049# => opShRot & "0000" & shRotR & shRotLdC,-- SRA s0 ; 70
16#04A# => opCompC & "0000" & "01110000", -- COMPARE s0, 70
16#04B# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test shift left
-----------------------------------------------------------------
16#04C# => opLoadC & "0001" & "11110000", -- LOAD s1, F0 ; FO
16#04D# => opShRot & "0001" & shRotL & shRotLd0,-- SL0 s1 ; E0
16#04E# => opShRot & "0001" & shRotL & shRotLdL,-- SLX s1 ; C0
16#04F# => opShRot & "0001" & shRotL & shRotLd1,-- SL1 s1 ; 81
16#050# => opShRot & "0001" & shRotL & shRotLdL,-- SLX s1 ; 03, C=1
16#051# => opShRot & "0001" & shRotL & shRotLdC,-- SLA s1 ; 07, C=0
16#052# => opShRot & "0001" & shRotL & shRotLdC,-- SLA s1 ; 0E
16#053# => opCompC & "0001" & "00001110", -- COMPARE s1, 0E
16#054# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 6) Test comparison operators
-----------------------------------------------------------------
16#055# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "COMPARE"
-----------------------------------------------------------------
16#056# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#057# => opCompC & "0000" & "11110000", -- COMPARE s0, F0 ; A < B => C=1
16#058# => brJump & brNC & "1111111101", -- JUMP NC, 3FD
16#059# => opCompC & "0000" & "11110000", -- COMPARE s0, F0 ; A < B => Z=0
16#05A# => brJump & brZ & "1111111101", -- JUMP Z, 3FD
16#05B# => opCompR & "0000" & "0000----", -- COMPARE s0, s0 ; A = B => Z=1
16#05C# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
16#05D# => opCompC & "0000" & "00001000", -- COMPARE s0, 08 ; A > B => C=0
16#05E# => brJump & brC & "1111111101", -- JUMP C, 3FD
16#05F# => opCompC & "0000" & "00001000", -- COMPARE s0, 08 ; A > B => Z=0
16#060# => brJump & brZ & "1111111101", -- JUMP Z, 3FD
-----------------------------------------------------------------
-- Test "TEST"
-----------------------------------------------------------------
16#061# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#062# => opTestC & "0000" & "11110000", -- TEST s0, F0 ; AND is 00 => Z=1
16#063# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
16#064# => opTestC & "0000" & "11111111", -- TEST s0, FF ; AND is 0F => Z=0
16#065# => brJump & brZ & "1111111101", -- JUMP Z, 3FD
--===============================================================
-- 7) Test INPUT and OUTPUT operators
-----------------------------------------------------------------
16#066# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "INPUT" and "OUTPUT" direct
--
-- The testbench should invert the word written at address FC.
-----------------------------------------------------------------
16#067# => opLoadC & "0000" & "10101010", -- LOAD s0, AA
16#068# => opOutputC & "0000" & "11111100", -- OUTPUT s0, FC
16#069# => opInputC & "0001" & "11111100", -- INPUT s1, FC
16#06A# => opCompC & "0001" & "01010101", -- COMPARE s1, 55
16#06B# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "INPUT" and "OUTPUT" indexed
-----------------------------------------------------------------
16#06C# => opLoadC & "0000" & "11001100", -- LOAD s0, CC
16#06D# => opLoadC & "0010" & "11111100", -- LOAD s2, FC
16#06E# => opOutputR & "0000" & "0010----", -- OUTPUT s0, (S2)
16#06F# => opInputR & "0001" & "0010----", -- INPUT s1, (S2)
16#070# => opCompC & "0001" & "00110011", -- COMPARE s1, 33
16#071# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 8) Test STORE and FETCH operators
-----------------------------------------------------------------
16#072# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "STORE" and "FETCH" direct
-----------------------------------------------------------------
16#073# => opLoadC & "0000" & "00001111", -- LOAD s0, 0F
16#074# => opStoreC & "0000" & "00000011", -- STORE s0, 03
16#075# => opFetchC & "0001" & "00000011", -- FETCH s1, 03
16#076# => opCompC & "0001" & "00001111", -- COMPARE s1, 0F
16#077# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
-----------------------------------------------------------------
-- Test "STORE" and "FETCH" indexed
-----------------------------------------------------------------
16#078# => opLoadC & "0000" & "11110000", -- LOAD s0, F0
16#079# => opLoadC & "0010" & "00000100", -- LOAD s2, 04
16#07A# => opStoreR & "0000" & "0010----", -- STORE s0, (S2)
16#07B# => opFetchR & "0001" & "0010----", -- FETCH s1, (S2)
16#07C# => opCompC & "0001" & "11110000", -- COMPARE s1, F0
16#07D# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 9) Test JUMP instructions
-----------------------------------------------------------------
16#07E# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- Test "JUMP NC"
-----------------------------------------------------------------
16#07F# => opLoadC & "0000" & "11110000", -- LOAD s0, F0
16#080# => opAddC & "0000" & "00000000", -- ADD s0, 00 ; s0=F0, C=0, Z=0
16#081# => brJump & brNC & "0010000011", -- JUMP NC, 083
16#082# => brJump & brDo & "1111111101", -- JUMP 3FD
-----------------------------------------------------------------
-- Test "JUMP NZ"
-----------------------------------------------------------------
-- _continue1_:
16#083# => opAddC & "0000" & "00000000", -- ADD s0, 00 ; s0=F0, C=0, Z=0
16#084# => brJump & brNZ & "0010000110", -- JUMP NZ, 086
16#085# => brJump & brDo & "1111111101", -- JUMP 3FD
-----------------------------------------------------------------
-- Test "JUMP C"
-----------------------------------------------------------------
-- _continue2_:
16#086# => opAddC & "0000" & "11110000", -- ADD s0, F0 ; s0=E0, C=1, Z=0
16#087# => brJump & brC & "0010001001", -- JUMP C, 089
16#088# => brJump & brDo & "1111111101", -- JUMP 3FD
-----------------------------------------------------------------
-- Test "JUMP Z"
-----------------------------------------------------------------
-- _continue3_:
16#089# => opSubC & "0000" & "11100000", -- SUB s0, E0 ; s0=00, C=0, Z=1
16#08A# => brJump & brZ & "0010001100", -- JUMP Z, 08C
16#08B# => brJump & brDo & "1111111101", -- JUMP 3FD
-- _continue4_:
16#08C# => opLoadR & "0000" & "0000----", -- NOP
--===============================================================
-- 10) Test call instructions
-----------------------------------------------------------------
16#08D# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- define subroutine
-----------------------------------------------------------------
16#08E# => brJump & brDo & "0010010010", -- JUMP 092
-- _subRetDo_:
16#08F# => opAddC & "0000" & "00000001", -- ADD s0, 01
16#090# => brRet & brDo & "----------", -- RETURN
16#091# => brJump & brDo & "1111111101", -- JUMP 3FD
-----------------------------------------------------------------
-- Test "CALL"
-----------------------------------------------------------------
-- _continue5_:
16#092# => opLoadC & "0000" & "00000000", -- LOAD s0, 00
16#093# => opLoadC & "0001" & "11110000", -- LOAD s1, F0
16#094# => brCall & brDo & "0010001111", -- CALL 08F ; s0=01
-----------------------------------------------------------------
-- Test "CALL NC"
-----------------------------------------------------------------
16#095# => opAddC & "0001" & "00000000", -- ADD s1, 00 ; s1=F0, C=0, Z=0
16#096# => brCall & brNC & "0010001111", -- CALL NC, 08F ; s0=02
-----------------------------------------------------------------
-- Test "CALL NZ"
-----------------------------------------------------------------
16#097# => opAddC & "0001" & "00000000", -- ADD s1, 00 ; s1=F0, C=0, Z=0
16#098# => brCall & brNZ & "0010001111", -- CALL NZ, 08F ; s0=03
-----------------------------------------------------------------
-- Test "CALL C"
-----------------------------------------------------------------
16#099# => opAddC & "0001" & "11110000", -- ADD s1, F0 ; s0=E0, C=1, Z=0
16#09A# => brCall & brC & "0010001111", -- CALL C, 08F ; s0=04
-----------------------------------------------------------------
-- Test "CALL Z"
-----------------------------------------------------------------
16#09B# => opSubC & "0001" & "11100000", -- SUB s1, E0 ; s0=00, C=0, Z=1
16#09C# => brCall & brZ & "0010001111", -- CALL Z, 08F ; s0=05
16#09D# => opCompC & "0000" & "00000101", -- COMPARE s0, 05
16#09E# => brJump & brNZ & "1111111101", -- JUMP NZ, 3FD
--===============================================================
-- 11) Test call return instructions
-----------------------------------------------------------------
16#09F# => opAddC & "0111" & "00000001", -- ADD s7, 01
-----------------------------------------------------------------
-- define subroutines
-----------------------------------------------------------------
16#0A0# => brJump & brDo & "0010101101", -- JUMP 0AD
-- _subRetNC_:
16#0A1# => opAddC & "0000" & "00000001", -- ADD s0, 01
16#0A2# => brRet & brDo & "----------", -- RETURN NC
16#0A3# => brJump & brDo & "1111111101", -- JUMP 3FD
-- _subRetNZ_:
16#0A4# => opAddC & "0000" & "00000001", -- ADD s0, 01
16#0A5# => brRet & brDo & "----------", -- RETURN NZ
16#0A6# => brJump & brDo & "1111111101", -- JUMP 3FD
-- _subRetC_:
16#0A7# => opAddC & "0000" & "00000001", -- ADD s0, 01
16#0A8# => brRet & brDo & "----------", -- RETURN C
16#0A9# => brJump & brDo & "1111111101", -- JUMP 3FD
-- _subRetZ_:
16#0AA# => opAddC & "0000" & "00000001", -- ADD s0, 01
16#0AB# => brRet & brDo & "----------", -- RETURN Z
16#0AC# => brJump & brDo & "1111111101", -- JUMP 3FD
-----------------------------------------------------------------
-- Test "RETURN NC"
-----------------------------------------------------------------
-- _continue6_:
16#0AD# => opLoadC & "0000" & "00000000", -- LOAD s0, 00 ; increment will give C=0, Z=0
16#0AE# => brCall & brNC & "0010100001", -- CALL NC, 0A1
-----------------------------------------------------------------
-- Test "RETURN NZ"
-----------------------------------------------------------------
16#0AF# => opLoadC & "0000" & "00000000", -- LOAD s0, 00 ; increment will give C=0, Z=0
16#0B0# => brCall & brNZ & "0010100100", -- CALL NZ, 0A4
-----------------------------------------------------------------
-- Test "RETURN C"
-----------------------------------------------------------------
16#0B1# => opLoadC & "0000" & "11111111", -- LOAD s0, FF ; increment will give C=1, Z=1
16#0B2# => brCall & brC & "0010100111", -- CALL C, 0A7
-----------------------------------------------------------------
-- Test "RETURN Z"
-----------------------------------------------------------------
16#0B3# => opLoadC & "0000" & "11111111", -- LOAD s0, FF ; increment will give C=1, Z=1
16#0B4# => brCall & brZ & "0010101010", -- CALL Z, 0AA
--===============================================================
-- End of tests
--
-- The testbench should react if value 1 is written to address 00.
-----------------------------------------------------------------
16#0B5# => opLoadC & "0000" & "00000001", -- LOAD s0, 01
16#0B6# => opOutputC & "0000" & "00000000", -- OUTPUT s0, 00
16#0B7# => brJump & brDo & "1111111111", -- JUMP 3FF
--===============================================================
-- Assert error
--
-- The testbench should react if value 0 is written to address 00.
-----------------------------------------------------------------
-- _error_:
16#3FD# => opLoadC & "0000" & "00000000", -- LOAD s0, 00
16#3FE# => opOutputC & "0000" & "00000000", -- OUTPUT s0, 00
--===============================================================
-- End of instruction memory
-----------------------------------------------------------------
-- _endOfMemory_:
16#3FF# => brJump & brDo & "1111111111", -- JUMP 3FF
others => (others => '0')
);
BEGIN
process (clock)
begin
if rising_edge(clock) then
if en = '1' then
dataOut <= memoryArray(to_integer(address));
end if;
end if;
end process;
END ARCHITECTURE mapped;
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