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--===========================================================================-- -- -- S Y N T H E Z I A B L E Real Time Trace C O R E -- -- www.OpenCores.Org - May 2003 -- This core adheres to the GNU public license -- -- File name : trace.vhd -- -- entity name : trace -- -- Purpose : Implements a trace buffer -- -- Dependencies : ieee.Std_Logic_1164 -- ieee.std_logic_unsigned -- -- Author : John E. Kent -- --===========================================================================---- -- -- Revision History: -- -- Date: Revision Author -- 19 June 2004 0.1 John Kent -- --===========================================================================---- -- -- Register Memory Map -- -- $00 - Address Comparitor High Byte -- $01 - Address Comparitor Low byte -- $02 - Data Comparitor -- $03 - Control Comparitor -- $04 - Address Qualifier High Byte -- $05 - Address Qualifier Low byte -- $06 - Data Qualifier -- $07 - Control Qualifier -- -- Address, Data and Control signals must match in the Comparitor registers -- Matches are qualified by setting a bit in the Qualifier registers -- -- Control Comparitor / Qualify (write) -- b0 - r/w 1=read 0=write -- b1 - vma 1=valid 0=invalid -- b5 - trace 1=enable 0=disable -- b6 - pre/post 1=before 0=after -- b7 - irq output 1=match 0=mismatch -- -- Control Qualifier Read -- b7 - match flag -- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity trace is port ( clk : in std_logic; rst : in std_logic; rs : in std_logic; -- register select bs : in std_logic; -- bank select rw : in std_logic; vma : in std_logic; addr : in std_logic_vector(15 downto 0); data_in : in std_logic_vector(7 downto 0); reg_data_out : out std_logic_vector(7 downto 0); buff_data_out : out std_logic_vector(7 downto 0); cpu_data_in : in std_logic_vector(7 downto 0); irq : out std_logic ); end; architecture trace_arch of trace is signal clk_n : std_logic; signal irq_out : std_logic; signal qual_write : std_logic; signal qual_read : std_logic; -- -- bank select -- signal bank_reg : std_logic_vector(7 downto 0); -- -- Trigger registers -- signal comp_addr_hi : std_logic_vector(7 downto 0); signal comp_addr_lo : std_logic_vector(7 downto 0); signal qual_addr_hi : std_logic_vector(7 downto 0); signal qual_addr_lo : std_logic_vector(7 downto 0); signal comp_data : std_logic_vector(7 downto 0); signal qual_data : std_logic_vector(7 downto 0); signal comp_ctrl : std_logic_vector(7 downto 0); signal qual_ctrl : std_logic_vector(7 downto 0); signal match_flag : std_logic; -- -- Trace counter -- signal trace_clk : std_logic; signal trace_rst : std_logic; signal trace_stb : std_logic; signal trace_we : std_logic; signal trace_count : std_logic_vector(9 downto 0); signal trace_offset : std_logic_vector(9 downto 0); signal trace_data_out_0 : std_logic_vector(7 downto 0); signal trace_data_out_1 : std_logic_vector(7 downto 0); signal trace_data_out_2 : std_logic_vector(7 downto 0); signal trace_data_out_3 : std_logic_vector(7 downto 0); signal trace_data_out_4 : std_logic_vector(7 downto 0); signal trace_data_out_5 : std_logic_vector(7 downto 0); signal buff_stb : std_logic_vector(5 downto 0); signal buff_we : std_logic; signal buff_addr : std_logic_vector(9 downto 0); signal buff_data_out_0 : std_logic_vector(7 downto 0); signal buff_data_out_1 : std_logic_vector(7 downto 0); signal buff_data_out_2 : std_logic_vector(7 downto 0); signal buff_data_out_3 : std_logic_vector(7 downto 0); signal buff_data_out_4 : std_logic_vector(7 downto 0); signal buff_data_out_5 : std_logic_vector(7 downto 0); signal mux_stb : std_logic_vector(5 downto 0); signal mux_we : std_logic; signal mux_addr : std_logic_vector(9 downto 0); signal ctrl_in : std_logic_vector(7 downto 0); signal trigger : std_logic; component ram1k Port ( -- Port A is 8 bit WB_CLK_I : in std_logic; WB_RST_I : in std_logic; WB_ADR_I : in std_logic_vector (9 downto 0); WB_DAT_O : out std_logic_vector (7 downto 0); WB_DAT_I : in std_logic_vector (7 downto 0); WB_WE_I : in std_logic; WB_STB_I : in std_logic ); end component; component BUFG port ( i: in std_logic; o: out std_logic ); end component; begin -- -- Bank 1 = Trace buffer cpu control out -- my_trace_buffer_1 : ram1k port map ( WB_CLK_I => clk, WB_RST_I => rst, WB_ADR_I => mux_addr, WB_DAT_O => buff_data_out_1, WB_DAT_I => ctrl_in(7 downto 0), WB_WE_I => mux_we, WB_STB_I => mux_stb(1) ); -- -- Trace buffer 2 is cpu address out high -- my_trace_buffer_2 : ram1k port map ( WB_CLK_I => clk, WB_RST_I => rst, WB_ADR_I => mux_addr, WB_DAT_O => buff_data_out_2, WB_DAT_I => addr(15 downto 8), WB_WE_I => mux_we, WB_STB_I => mux_stb(2) ); -- -- Trace buffer 3 is cpu address out low -- my_trace_buffer_3 : ram1k port map ( WB_CLK_I => clk, WB_RST_I => rst, WB_ADR_I => mux_addr, WB_DAT_O => buff_data_out_3, WB_DAT_I => addr(7 downto 0), WB_WE_I => mux_we, WB_STB_I => mux_stb(3) ); -- -- Trace buffer 4 is cpu data out -- my_trace_buffer_4 : ram1k port map ( WB_CLK_I => clk, WB_RST_I => rst, WB_ADR_I => mux_addr, WB_DAT_O => buff_data_out_4, WB_DAT_I => data_in(7 downto 0), WB_WE_I => mux_we, WB_STB_I => mux_stb(4) ); -- -- Trace buffer 5 is cpu data in -- my_trace_buffer_5 : ram1k port map ( WB_CLK_I => clk, WB_RST_I => rst, WB_ADR_I => mux_addr, WB_DAT_O => buff_data_out_5, WB_DAT_I => cpu_data_in(7 downto 0), WB_WE_I => mux_we, WB_STB_I => mux_stb(5) ); --clk_buffer : BUFG port map( -- i => clk_n, -- o => trace_clk -- ); -------------------------------- -- -- write page bank register -- -------------------------------- bank_reg_write : process( clk, rst, rs, rw, data_in, bank_reg) begin if clk'event and clk = '0' then if rst = '1' then bank_reg <= "00000000"; else if rs='1' and rw='0' then bank_reg <= data_in; else bank_reg <= bank_reg; end if; end if; end if; end process; -------------------------------- -- -- read page buffers -- -------------------------------- buffer_read : process( bs, bank_reg, buff_data_out_0, buff_data_out_1, buff_data_out_2, buff_data_out_3, buff_data_out_4, buff_data_out_5 ) variable count : integer; begin for count in 0 to 5 loop buff_stb(count) <= '0'; end loop; case bank_reg(2 downto 0) is when "000" => buff_stb(0) <= bs; buff_data_out <= buff_data_out_0; when "001" => buff_stb(1) <= bs; buff_data_out <= buff_data_out_1; when "010" => buff_stb(2) <= bs; buff_data_out <= buff_data_out_2; when "011" => buff_stb(3) <= bs; buff_data_out <= buff_data_out_3; when "100" => buff_stb(4) <= bs; buff_data_out <= buff_data_out_4; when "101" => buff_stb(5) <= bs; buff_data_out <= buff_data_out_5; when others => buff_data_out <= "00000000"; end case; reg_data_out <= bank_reg; end process; -------------------------------- -- -- write control registers -- -------------------------------- trace_write : process( clk, rst, bs, rw, addr, data_in, qual_write, comp_addr_hi, comp_addr_lo, comp_data, comp_ctrl, qual_addr_hi, qual_addr_lo, qual_data, qual_ctrl ) begin if clk'event and clk = '0' then if rst = '1' then comp_addr_hi <= "00000000"; comp_addr_lo <= "00000000"; comp_data <= "00000000"; comp_ctrl <= "00000000"; qual_addr_hi <= "00000000"; qual_addr_lo <= "00000000"; qual_data <= "00000000"; qual_ctrl <= "00000000"; qual_write <= '0'; elsif buff_stb(0) = '1' and rw = '0' then case addr(2 downto 0) is when "000" => comp_addr_hi <= data_in; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "001" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= data_in; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "010" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= data_in; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "011" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= data_in; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "100" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= data_in; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "101" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= data_in; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; when "110" => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= data_in; qual_ctrl <= qual_ctrl; qual_write <= '0'; -- when "111" => when others => comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= data_in; qual_write <= '1'; end case; else comp_addr_hi <= comp_addr_hi; comp_addr_lo <= comp_addr_lo; comp_data <= comp_data; comp_ctrl <= comp_ctrl; qual_addr_hi <= qual_addr_hi; qual_addr_lo <= qual_addr_lo; qual_data <= qual_data; qual_ctrl <= qual_ctrl; qual_write <= '0'; end if; end if; end process; -- -- trap data output mux -- trace_read : process( buff_stb, rw, addr, qual_read, comp_addr_hi, comp_addr_lo, comp_data, comp_ctrl, qual_addr_hi, qual_addr_lo, qual_data, qual_ctrl, match_flag ) begin case addr(2 downto 0) is when "000" => buff_data_out_0 <= comp_addr_hi; qual_read <= '0'; when "001" => buff_data_out_0 <= comp_addr_lo; qual_read <= '0'; when "010" => buff_data_out_0 <= comp_data; qual_read <= '0'; when "011" => buff_data_out_0 <= comp_ctrl; qual_read <= '0'; when "100" => buff_data_out_0 <= qual_addr_hi; qual_read <= '0'; when "101" => buff_data_out_0 <= qual_addr_lo; qual_read <= '0'; when "110" => buff_data_out_0 <= qual_data; qual_read <= '0'; -- when "111" => when others => qual_read <= buff_stb(0) and rw; buff_data_out_0(6 downto 0) <= qual_ctrl(6 downto 0); buff_data_out_0(7) <= match_flag; end case; end process; mux_proc : process( bs, rw, trace_count, buff_addr, trace_we, buff_we, trace_stb, buff_stb ) begin if bs='0' and rw='1' then mux_addr <= trace_count; mux_we <= trace_we; mux_stb <= trace_stb & trace_stb & trace_stb & trace_stb & trace_stb & trace_stb; else mux_addr <= buff_addr; mux_we <= buff_we; mux_stb <= buff_stb; end if; end process; -- -- Trigger hardware -- trace_match : process( Clk, rst, rw, buff_stb, addr, vma, match_flag, data_in, comp_addr_hi, comp_addr_lo, comp_data, comp_ctrl, qual_addr_hi, qual_addr_lo, qual_data, qual_ctrl) variable match : std_logic; variable match_addr_hi : std_logic; variable match_addr_lo : std_logic; variable match_data : std_logic; variable match_ctrl : std_logic; begin match_addr_hi := ((comp_addr_hi(7) xor addr(15) ) and qual_addr_hi(7) ) or ((comp_addr_hi(6) xor addr(14) ) and qual_addr_hi(6) ) or ((comp_addr_hi(5) xor addr(13) ) and qual_addr_hi(5) ) or ((comp_addr_hi(4) xor addr(12) ) and qual_addr_hi(4) ) or ((comp_addr_hi(3) xor addr(11) ) and qual_addr_hi(3) ) or ((comp_addr_hi(2) xor addr(10) ) and qual_addr_hi(2) ) or ((comp_addr_hi(1) xor addr( 9) ) and qual_addr_hi(1) ) or ((comp_addr_hi(0) xor addr( 8) ) and qual_addr_hi(0) ); match_addr_lo := ((comp_addr_lo(7) xor addr( 7) ) and qual_addr_lo(7) ) or ((comp_addr_lo(6) xor addr( 6) ) and qual_addr_lo(6) ) or ((comp_addr_lo(5) xor addr( 5) ) and qual_addr_lo(5) ) or ((comp_addr_lo(4) xor addr( 4) ) and qual_addr_lo(4) ) or ((comp_addr_lo(3) xor addr( 3) ) and qual_addr_lo(3) ) or ((comp_addr_lo(2) xor addr( 2) ) and qual_addr_lo(2) ) or ((comp_addr_lo(1) xor addr( 1) ) and qual_addr_lo(1) ) or ((comp_addr_lo(0) xor addr( 0) ) and qual_addr_lo(0) ); match_data := ((comp_data(7) xor data_in(7)) and qual_data(7) ) or ((comp_data(6) xor data_in(6)) and qual_data(6) ) or ((comp_data(5) xor data_in(5)) and qual_data(5) ) or ((comp_data(4) xor data_in(4)) and qual_data(4) ) or ((comp_data(3) xor data_in(3)) and qual_data(3) ) or ((comp_data(2) xor data_in(2)) and qual_data(2) ) or ((comp_data(1) xor data_in(1)) and qual_data(1) ) or ((comp_data(0) xor data_in(0)) and qual_data(0) ); match_ctrl := ((comp_ctrl(0) xor rw ) and qual_ctrl(0) ) or ((comp_ctrl(1) xor vma ) and qual_ctrl(1) ); match := not ( match_addr_hi or match_addr_lo or match_data or match_ctrl); if clk'event and clk = '0' then if rst = '1' then match_flag <= '0'; elsif buff_stb(0) = '1' and rw = '0' then match_flag <= '0'; else if match = comp_ctrl(7) then match_flag <= '1'; else match_flag <= match_flag; end if; end if; end if; trigger <= match_flag; end process; trace_capture : process( clk, rst, qual_read, qual_write, trigger, trace_stb, qual_ctrl, irq_out, trace_count, trace_offset ) variable irq_tmp : std_logic; begin if clk'event and clk = '1' then if rst = '1' then trace_count <= "0000000000"; trace_offset <= "0000000000"; trace_stb <= qual_ctrl(6); else -- -- zero in bit 6 of the qalifier control register -- means start capture after trigger point. -- if qual_ctrl(6) = '0' then if trace_stb = '0' then trace_stb <= trigger; irq_tmp := irq_out; trace_offset <= trace_count; else if trace_count = trace_offset then trace_stb <= '0'; irq_tmp := '1'; else trace_stb <= trace_stb; irq_tmp := irq_out; end if; trace_offset <= trace_offset; end if; if qual_read = '1' then irq_out <= '0'; else irq_out <= irq_tmp; end if; -- -- one in bit 6 of the qalifier control register -- means finish capture at trigger point. -- else if trace_stb = '0' then trace_stb <= qual_write; trace_offset <= trace_offset; irq_tmp := irq_out; else if trigger = '1' then trace_offset <= trace_count; trace_stb <= '0'; irq_tmp := '1'; else trace_offset <= trace_offset; trace_stb <= trace_stb; irq_tmp := irq_out; end if; end if; if qual_write = '1' then irq_out <= '0'; else irq_out <= irq_tmp; end if; end if; trace_count <= trace_count + 1; end if; end if; end process; -- -- Tie up a few signals -- process( clk, rst, addr, vma, rw, irq_out, trace_offset, qual_ctrl, trace_stb ) begin trace_clk <= clk; trace_rst <= rst; trace_we <= trace_stb; buff_addr <= addr(9 downto 0) + trace_offset; buff_we <= '0'; irq <= irq_out and qual_ctrl(7); ctrl_in(0) <= rw; ctrl_in(1) <= vma; ctrl_in(7 downto 2) <= "000000"; end process; end trace_arch;
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