countzero: Reorganize to have fewer levels of logic and fewer LUTs

By using 4:1 multiplexers rather than 2:1, this cuts the number of levels of multiplexing from 4 to 2 and also reduces the total number of slice LUTs required. Because we are now handling 4 bits at each level, including the bottom level, the logic to do the priority encoding can be factored out into a function that is used at each level. This rearranges the logic so that the encoding and selection of bits is done whether or not the input operand is zero, and the if statement testing whether the input is zero only affects what is assigned to result. With this we don't get the inferred latches and we can go back to using signals rather than variables. Also add some comments about what is being done. Signed-off-by: Paul Mackerras <paulus@ozlabs.org>
5 years ago · e527e3a9b7
parent 0a0fe03767
commit e527e3a9b7
1 changed files with 85 additions and 82 deletions
--- a/countzero.vhdl
+++ b/countzero.vhdl
@ -14,98 +14,101 @@ entity zero_counter is
 end entity zero_counter;
 architecture behaviour of zero_counter is
-begin
+    signal y, z     : std_ulogic_vector(3 downto 0);
-    zerocounter0: process(all)
+    signal v16      : std_ulogic_vector(15 downto 0);
-        variable l32, r32 : std_ulogic;
+    signal v4       : std_ulogic_vector(3 downto 0);
-        variable v32      : std_ulogic_vector(31 downto 0);
+    signal sel      : std_ulogic_vector(5 downto 0);
        variable v16      : std_ulogic_vector(15 downto 0);
        variable v8       : std_ulogic_vector(7 downto 0);
        variable v4       : std_ulogic_vector(3 downto 0);
        variable sel      : std_ulogic_vector(5 downto 0);
    begin
        l32 := '0';
        r32 := '0';
        v32 := (others => '0');
        v16 := (others => '0');
        v8  := (others => '0');
        v4  := (others => '0');
        sel := (others => '0');
-	l32 := or (rs(63 downto 32));
+    -- Return the index of the leftmost or rightmost 1 in a set of 4 bits.
-	r32 := or (rs(31 downto 0));
+    -- Assumes v is not "0000"; if it is, return (right ? "11" : "00").
-	if (l32 = '0' or is_32bit = '1') and r32 = '0' then
+    function encoder(v: std_ulogic_vector(3 downto 0); right: std_ulogic) return std_ulogic_vector is
-	    -- operand is zero, return 32 for 32-bit, else 64
+    begin
-	    result <= x"00000000000000" & '0' & not is_32bit & is_32bit & "00000";
+	if right = '0' then
-	else
+	    if v(3) = '1' then
-
+		return "11";
-	    if count_right = '0' then
+	    elsif v(2) = '1' then
-		sel(5) := l32 and (not is_32bit);
+		return "10";
 	    elsif v(1) = '1' then
 		return "01";
 	    else
-		sel(5) := (not r32) and (not is_32bit);
+		return "00";
 	    end if;
 	    if sel(5) = '1' then
 		v32 := rs(63 downto 32);
 	else
-		v32 := rs(31 downto 0);
+	    if v(0) = '1' then
-	    end if;
+		return "00";
-
+	    elsif v(1) = '1' then
-	    if count_right = '0' then
+		return "01";
-		sel(4) := or (v32(31 downto 16));
+	    elsif v(2) = '1' then
 		return "10";
 	    else
-		sel(4) := not (or (v32(15 downto 0)));
+		return "11";
 	    end if;
 	    if sel(4) = '1' then
 		v16 := v32(31 downto 16);
 	    else
 		v16 := v32(15 downto 0);
 	end if;
    end;
-	    if count_right = '0' then
+begin
-		sel(3) := or (v16(15 downto 8));
+    zerocounter0: process(all)
-	    else
+    begin
-		sel(3) := not (or (v16(7 downto 0)));
+	-- Test 4 groups of 16 bits each.
-	    end if;
+	-- The top 2 groups are considered to be zero in 32-bit mode.
-	    if sel(3) = '1' then
+	z(0) <= or (rs(15 downto 0));
-		v8 := v16(15 downto 8);
+	z(1) <= or (rs(31 downto 16));
 	z(2) <= or (rs(47 downto 32));
 	z(3) <= or (rs(63 downto 48));
        if is_32bit = '0' then
            sel(5 downto 4) <= encoder(z, count_right);
        else
-		v8 := v16(7 downto 0);
+            sel(5) <= '0';
 	    end if;
            if count_right = '0' then
-		sel(2) := or (v8(7 downto 4));
+                sel(4) <= z(1);
            else
-		sel(2) := not (or (v8(3 downto 0)));
+                sel(4) <= not z(0);
            end if;
 	    if sel(2) = '1' then
 		v4 := v8(7 downto 4);
 	    else
 		v4 := v8(3 downto 0);
        end if;
-	    if count_right = '0' then
+	-- Select the leftmost/rightmost non-zero group of 16 bits
-		if v4(3) = '1' then
+	case sel(5 downto 4) is
-		    sel(1 downto 0) := "11";
+	    when "00" =>
-		elsif v4(2) = '1' then
+		v16 <= rs(15 downto 0);
-		    sel(1 downto 0) := "10";
+	    when "01" =>
-		elsif v4(1) = '1' then
+		v16 <= rs(31 downto 16);
-		    sel(1 downto 0) := "01";
+	    when "10" =>
-		else
+		v16 <= rs(47 downto 32);
-		    sel(1 downto 0) := "00";
+	    when others =>
-		end if;
+		v16 <= rs(63 downto 48);
 	end case;
 	-- Test 4 groups of 4 bits
 	y(0) <= or (v16(3 downto 0));
 	y(1) <= or (v16(7 downto 4));
 	y(2) <= or (v16(11 downto 8));
 	y(3) <= or (v16(15 downto 12));
 	sel(3 downto 2) <= encoder(y, count_right);
 	-- Select the leftmost/rightmost non-zero group of 4 bits
 	case sel(3 downto 2) is
 	    when "00" =>
 		v4 <= v16(3 downto 0);
 	    when "01" =>
 		v4 <= v16(7 downto 4);
 	    when "10" =>
 		v4 <= v16(11 downto 8);
 	    when others =>
 		v4 <= v16(15 downto 12);
 	end case;
 	sel(1 downto 0) <= encoder(v4, count_right);
 	-- sel is now the index of the leftmost/rightmost 1 bit in rs
 	if v4 = "0000" then
 	    -- operand is zero, return 32 for 32-bit, else 64
 	    result <= x"00000000000000" & '0' & not is_32bit & is_32bit & "00000";
 	elsif count_right = '0' then
 	    -- return (63 - sel), trimmed to 5 bits in 32-bit mode
 	    result <= x"00000000000000" & "00" & (not sel(5) and not is_32bit) & not sel(4 downto 0);
 	else
 		if v4(0) = '1' then
 		    sel(1 downto 0) := "00";
 		elsif v4(1) = '1' then
 		    sel(1 downto 0) := "01";
 		elsif v4(2) = '1' then
 		    sel(1 downto 0) := "10";
 		else
 		    sel(1 downto 0) := "11";
 		end if;
 	    result <= x"00000000000000" & "00" & sel;
 	end if;
 	end if;
    end process;
 end behaviour;