[LSD] BasicWatch added (pratica05 | part4)

2023-04-05 12:24:35 +01:00 · 2023-04-05 12:24:35 +01:00 · 21266306fa
parent 5e40befd64
commit 21266306fa
6 changed files with 315 additions and 0 deletions
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/BasicWatch.vhd
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/BasicWatch.vhd
@ -0,0 +1,176 @@
 library IEEE;
 use IEEE.STD_LOGIC_1164.all;
 use IEEE.NUMERIC_STD.all;
 entity BasicWatch is
 	port(SW        : in  std_logic_vector(0 downto 0);
 		  CLOCK_50	: in  std_logic;
 		  KEY			: in  std_logic_vector(3 downto 0);
 		  HEX2		: out std_logic_vector(6 downto 0);
 		  HEX3		: out std_logic_vector(6 downto 0);
 		  HEX4		: out std_logic_vector(6 downto 0);
 		  HEX5		: out std_logic_vector(6 downto 0);
 		  HEX6		: out std_logic_vector(6 downto 0);
 		  HEX7		: out std_logic_vector(6 downto 0);
 		  LEDG		: out std_logic_vector(8 downto 8));
 end BasicWatch;
 architecture Structural of BasicWatch is
 	-- Global enable signal
 	signal s_enable : std_logic;
 	-- Global reset signal 
 	signal s_globalRst : std_logic;
 	-- Individual reset for the seconds counters ('1' while setting min/hours)
 	signal s_sReset : std_logic;
 	-- Control signals
 	signal s_mode : std_logic; -- s_mode='0'-normal operation; s_mode='1'-set min/hours
 	signal s_hSet : std_logic; -- s_hSet='1'-set (fast increment) hours
 	signal s_mSet : std_logic; -- s_mSet='1'-set (fast increment) minutes
 	-- Base 4 Hz clock signal
 	signal s_clk4Hz : std_logic;
 	-- Global enable (always '1' while setting min/hours;
 	-- otherwise always repeating '1', '0', '0', '0')
 	signal s_globalEnb : std_logic;
 	-- Binary values of each counter
 	signal s_sUnitsBin, s_sTensBin	: std_logic_vector(3 downto 0);
 	signal s_mUnitsBin, s_mTensBin	: std_logic_vector(3 downto 0);
 	signal s_hUnitsBin, s_hTensBin	: std_logic_vector(3 downto 0);
 	signal s_hUnitsMax : natural := 9;
 	-- Terminal count flags of each counter
 	signal s_sUnitsTerm, s_sTensTerm	: std_logic;
 	signal s_mUnitsTerm, s_mTensTerm	: std_logic;
 	signal s_hUnitsTerm					: std_logic;
 	-- Enable signals of each counter
 	signal s_sUnitsEnb, s_sTensEnb	: std_logic;
 	signal s_mUnitsEnb, s_mTensEnb	: std_logic;
 	signal s_hUnitsEnb, s_hTensEnb	: std_logic;
 begin
 	s_globalRst	<= not KEY(3);
 	s_sReset		<= s_globalRst or s_mode;
 	s_enable    <= SW(0);
 	s_mode <= not KEY(2); 
 	s_hSet <= not KEY(1);
 	s_mSet <= not KEY(0);
 	clk_div_4hz : entity work.ClkDividerN(RTL)
 							generic map(k			=> 12500000)
 							port map(clkIn			=> CLOCK_50,
 										clkOut		=> s_clk4Hz);
 	clk_enb_gen : entity work.ClkEnableGenerator(RTL)
 							port map(clkIn4Hz		=> s_clk4Hz,
 										mode			=> s_mode,
 										clkEnable	=> s_globalEnb,
 										tick1Hz		=> LEDG(8));
 	s_sUnitsEnb	<= '1'; 
 	s_units_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX	=> 9,
 										reset		=> s_sReset,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_sUnitsEnb,
 										valOut	=> s_sUnitsBin,
 										termCnt	=> s_sUnitsTerm);
 	s_sTensEnb <= s_sUnitsTerm;
 	s_tens_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX	=> 5,
 										reset		=> s_sReset,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_sTensEnb,
 										valOut	=> s_sTensBin,
 										termCnt	=> s_sTensTerm);
 	s_mUnitsEnb <= ((s_sTensTerm and s_sUnitsTerm) and not s_mode) or
 						(s_mode and s_mSet);
 	m_units_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX => 9,
 										reset		=> s_globalRst,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_mUnitsEnb,
 										valOut	=> s_mUnitsBin,
 										termCnt	=> s_mUnitsTerm);
 	s_mTensEnb <= (s_mUnitsTerm and s_mUnitsEnb);
 	m_tens_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX	=> 5,
 										reset		=> s_globalRst,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_mTensEnb,
 										valOut	=> s_mTensBin,
 										termCnt	=> s_mTensTerm);
 	s_hUnitsEnb <= ((s_mTensTerm and s_mTensEnb) and not s_mode) or
 						(s_mode and s_hSet);
 	s_hUnitsMax <= 3 when (s_hTensBin = "0010") else 9;
 	h_units_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX	=> s_hUnitsMax,
 										reset		=> s_globalRst,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_hUnitsEnb,
 										valOut	=> s_hUnitsBin,
 										termCnt	=> s_hUnitsTerm);
 	s_hTensEnb <= (s_hUnitsTerm and s_hUnitsEnb);
 	h_tens_cnt : entity work.Counter4Bits(RTL)
 							port map(MAX	=> 2,
 										reset		=> s_globalRst,
 										clk		=> s_clk4Hz,
 										enable1	=> s_globalEnb,
 										enable2	=> s_hTensEnb,
 										valOut	=> s_hTensBin,
 										termCnt	=> open);
 	s_units_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_sUnitsBin,
 										decOut_n	=> HEX2);
 	s_tens_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_sTensBin,
 										decOut_n	=> HEX3);
 	m_units_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_mUnitsBin,
 										decOut_n	=> HEX4);
 	m_tens_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_mTensBin,
 										decOut_n	=> HEX5);
 	h_units_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_hUnitsBin,
 										decOut_n	=> HEX6);
 	h_tens_decod : entity work.Bin7SegDecoder(RTL)
 							port map(enable	=> s_enable,
 										binInput	=> s_hTensBin,
 										decOut_n	=> HEX7);
 end Structural;
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/Bin7SegDecoder.vhd
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/Bin7SegDecoder.vhd
@ -0,0 +1,35 @@
 library IEEE;
 use IEEE.STD_LOGIC_1164.all;
 entity Bin7SegDecoder is
 	port(enable		: in  std_logic;
 		 binInput	: in  std_logic_vector(3 downto 0);
 		 decOut_n	: out std_logic_vector(6 downto 0));
 end Bin7SegDecoder;
 architecture RTL of Bin7SegDecoder is
 	signal s_decOut_n : std_logic_vector(6 downto 0);
 begin
 	with binInput select
 		s_decOut_n <= "1111001" when "0001",   --1
 						  "0100100" when "0010",   --2
 						  "0110000" when "0011",   --3
 						  "0011001" when "0100",   --4
 						  "0010010" when "0101",   --5
 						  "0000010" when "0110",   --6
 						  "1111000" when "0111",   --7
 						  "0000000" when "1000",   --8
 						  "0010000" when "1001",   --9
 						  "0001000" when "1010",   --A
 						  "0000011" when "1011",   --b
 						  "1000110" when "1100",   --C
 						  "0100001" when "1101",   --d
 						  "0000110" when "1110",   --E
 						  "0001110" when "1111",   --F
 						  "1000000" when others;   --0
 	decOut_n <= s_decOut_n when (enable = '1') else
 				"0111111";
 end RTL;
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/ClkDividerN.vhd
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/ClkDividerN.vhd
@ -0,0 +1,32 @@
 library IEEE;
 use IEEE.STD_LOGIC_1164.all;
 use IEEE.NUMERIC_STD.all;
 entity ClkDividerN is
 	generic(k 	: natural);
 	port(clkIn	: in  std_logic;
 		  clkOut	: out std_logic);
 end ClkDividerN;
 architecture RTL of ClkDividerN is
 	signal s_divCounter : natural;
 begin
 	assert(K >= 2);
 	process(clkIn)
 	begin
 		if (rising_edge(clkIn)) then
 			if (s_divCounter = k - 1) then
 				clkOut		 <= '0';
 				s_divCounter <= 0;
 			else
 				if (s_divCounter = (k / 2 - 1)) then
 					clkOut	 <= '1';
 				end if;
 				s_divCounter <= s_divCounter + 1;
 			end if;
 		end if;
 	end process;
 end RTL;
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/ClkEnableGenerator.vhd
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/ClkEnableGenerator.vhd
@ -0,0 +1,29 @@
 library IEEE;
 use IEEE.STD_LOGIC_1164.all;
 use IEEE.NUMERIC_STD.all;
 entity ClkEnableGenerator is
 	port(clkIn4Hz	: in  std_logic;
 		  mode		: in  std_logic;
 		  clkEnable	: out std_logic;
 		  tick1Hz	: out std_logic);
 end ClkEnableGenerator;
 architecture RTL of ClkEnableGenerator is
 	signal s_counter : unsigned(1 downto 0);
 begin
 	process(clkIn4Hz)
 	begin
 		if (rising_edge(clkIn4Hz)) then
 			s_counter <= s_counter + 1;
 		end if;
 	end process;
 	clkEnable <= '1' when (mode ='1') else
 					 '1' when (mode ='0') and (s_counter = "00") else
 					 '0';
 	tick1Hz	<= s_counter(1);
 end RTL;
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/Counter4Bits.vhd
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/Counter4Bits.vhd
@ -0,0 +1,43 @@
 library IEEE;
 use IEEE.STD_LOGIC_1164.all;
 use IEEE.NUMERIC_STD.all;
 entity Counter4Bits is
 	port(MAX		: natural := 9;
 		  reset		: in  std_logic;
 		  clk			: in  std_logic;
 		  enable1	: in  std_logic;
 		  enable2	: in  std_logic;
 		  valOut		: out std_logic_vector(3 downto 0);
 		  termCnt	: out std_logic);
 end Counter4Bits;
 architecture RTL of Counter4Bits is
 	signal s_value : unsigned(3 downto 0);
 begin
 	process(reset, clk)
 	begin	
 		if (rising_edge(clk)) then
 			if (reset = '1') then
 				s_value <= (others => '0');
 				termCnt <= '0';
 			elsif ((enable1 = '1') and (enable2 = '1')) then
 				if (to_integer(s_value) = MAX) then
 					s_value <= (others => '0');
 					termCnt <= '0';
 				else
 					s_value <= s_value + 1;
 					if (to_integer(s_value) = MAX - 1) then
 						termCnt <= '1';
 					else
 						termCnt <= '0';
 					end if;
 				end if;
 			end if;
 		end if;
 	end process;
 	valOut <= std_logic_vector(s_value);
 end RTL;
--- a/1ano/2semestre/lsd/pratica05/BasicWatch/output_files/BasicWatch.sof
+++ b/1ano/2semestre/lsd/pratica05/BasicWatch/output_files/BasicWatch.sof