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[/] [funbase_ip_library/] [trunk/] [TUT/] [ip.hwp.storage/] [sdram2hibi/] [1.0/] [vhd/] [sdram_wr_port.vhd] - Blame information for rev 145

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-------------------------------------------------------------------------------
-- Title      : wr_port.vhd
-- Project    : 
-------------------------------------------------------------------------------
-- File       : wr_port.vhd
-- Author     : 
-- Company    : 
-- Created    : 2007-05-22
-- Last update: 2012-01-26
-- Platform   : 
-- Standard   : VHDL'87
-------------------------------------------------------------------------------
-- Description: Write port for sdram2hibi
-------------------------------------------------------------------------------
-- Copyright (c) 2007 
-------------------------------------------------------------------------------
-- Revisions  :
-- Date        Version  Author  Description
-- 2007-05-22  1.0      penttin5        Created
-- 2012-01-22  1.001    alhonen fixed names
-------------------------------------------------------------------------------
 
library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
 
entity sdram_wr_port is
 
  generic (
    fifo_depth_g    : integer;
    amountw_g       : integer;
    hibi_dataw_g    : integer;
    block_overlap_g : integer := 0;
    offsetw_g       : integer;
    mem_dataw_g     : integer;
    mem_addrw_g     : integer);
 
  port (
    clk            : in  std_logic;
    rst_n          : in  std_logic;
    conf_we_in     : in  std_logic;
    conf_data_in   : in  std_logic_vector(hibi_dataw_g - 1 downto 0);
    write_in       : in  std_logic;
    reserve_in     : in  std_logic;
    valid_out      : out std_logic;
    reserved_out   : out std_logic;
    end_addr_out   : out std_logic_vector(mem_addrw_g - 1 downto 0);
    dst_addr_out   : out std_logic_vector(mem_addrw_g - 1 downto 0);
    amount_out     : out std_logic_vector(amountw_g - 1 downto 0);
    fifo_we_in     : in  std_logic;
    fifo_re_in     : in  std_logic;
    fifo_data_in   : in  std_logic_vector(hibi_dataw_g - 1 downto 0);
    fifo_full_out  : out std_logic;
    fifo_empty_out : out std_logic;
    fifo_one_p_out : out std_logic;
    fifo_one_d_out : out std_logic;
    fifo_data_out  : out std_logic_vector(hibi_dataw_g - 1 downto 0);
    error_out      : out std_logic);
 
end sdram_wr_port;
 
architecture rtl of sdram_wr_port is
 
  component fifo
    generic (
      data_width_g : integer;
      depth_g      : integer);
    port (
      clk       : in  std_logic;
      rst_n     : in  std_logic;
      data_in   : in  std_logic_vector(data_width_g - 1 downto 0);
      we_in     : in  std_logic;
      one_p_out : out std_logic;
      full_out  : out std_logic;
      data_out  : out std_logic_vector(data_width_g - 1 downto 0);
      re_in     : in  std_logic;
      empty_out : out std_logic;
      one_d_out : out std_logic);
  end component;
 
  -- parameter numbers
  constant dst_addr_param_c : integer := 0;
  constant amount_param_c   : integer := 1;
  constant width_param_c    : integer := 1;
  constant height_param_c   : integer := 2;
  constant offset_param_c   : integer := 2;
  constant last_param_c     : integer := 2;
 
  signal reserved_r : std_logic;
  signal valid_r    : std_logic;
  signal dst_addr_r : std_logic_vector(mem_addrw_g - 1 downto 0);
  signal amount_r   : std_logic_vector(amountw_g - 1 downto 0);
  signal width_r    : std_logic_vector(amountw_g - 1 downto 0);
  signal height_r   : std_logic_vector(hibi_dataw_g - offsetw_g - 1 downto 0);
  signal offset_r   : std_logic_vector(offsetw_g - 1 downto 0);
  signal end_addr_r : std_logic_vector(mem_addrw_g - 1 downto 0);
 
  signal finish          : std_logic;
  signal param_cnt_r     : integer range last_param_c downto 0;
  signal end_addr_rdy_r  : std_logic;
  signal calc_end_addr_r : std_logic;
  signal h_times_o_r     : std_logic_vector(hibi_dataw_g - 1 downto 0);
 
begin  -- rtl
 
  -- drive outputs
  reserved_out <= reserved_r;
  valid_out    <= valid_r;
  dst_addr_out <= dst_addr_r;
  amount_out   <= amount_r;
  end_addr_out <= end_addr_r;
 
  -- purpose: Detect finished operation
  -- type   : combinational
  -- inputs : write_in, amount_r, height_r
  -- outputs: finish
  port_finishes : process (write_in, amount_r, height_r)
  begin  -- process port_finishes
    if write_in = '1'
      and to_integer(unsigned(amount_r)) = 1
      and (to_integer(unsigned(height_r)) = 1 or
           to_integer(unsigned(height_r)) = 0) then
      finish <= '1';
    else
      finish <= '0';
    end if;
  end process port_finishes;
 
  param_counter: process (clk, rst_n)
  begin  -- process param_counter
    if rst_n = '0' then                 -- asynchronous reset (active low)
      param_cnt_r <= 0;
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if conf_we_in = '1' and param_cnt_r = last_param_c then
        param_cnt_r <= 0;
      elsif conf_we_in = '1' then
        param_cnt_r <= param_cnt_r + 1;
      else
        param_cnt_r <= param_cnt_r;
      end if;
    end if;
  end process param_counter;
 
  reserved_proc : process (clk, rst_n)
  begin  -- process reserved_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      reserved_r <= '0';
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if finish = '1' then
        -- operation finishes
        reserved_r <= '0';
      elsif reserve_in = '1' then
        -- reserve from sdram2hibi
        reserved_r <= '1';
      else
        reserved_r <= reserved_r;
      end if;
    end if;
  end process reserved_proc;
 
  valid_proc : process (clk, rst_n)
  begin  -- process valid_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      valid_r <= '0';
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if finish = '1' then
        -- operation finishes
        valid_r <= '0';
      elsif block_overlap_g = 0
        and conf_we_in = '1' and param_cnt_r = last_param_c then
        -- without block overlap, configuration finishes on
        -- third paramater write
        valid_r <= '1';
      elsif block_overlap_g = 1 and end_addr_rdy_r = '1' then
        -- with block overlap, configuration finishes on
        -- end address calculation
        valid_r <= '1';
      else
        valid_r <= valid_r;
      end if;
    end if;
 
  end process valid_proc;
 
  dst_addr_proc : process (clk, rst_n)
  begin  -- process dst_addr_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      dst_addr_r <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then
        -- line finishes, jump to next line
        dst_addr_r <= std_logic_vector(unsigned(dst_addr_r) +
                                       unsigned(offset_r) + 1);
      elsif write_in = '1' then
        -- line continues, increase dst_addr
        dst_addr_r <= std_logic_vector(unsigned(dst_addr_r) + 1);
 
      elsif conf_we_in = '1' and param_cnt_r = dst_addr_param_c then
        -- configure from sdram2hibi
        dst_addr_r <= conf_data_in(mem_addrw_g - 1 downto 0);
      else
        dst_addr_r <= dst_addr_r;
      end if;
    end if;
  end process dst_addr_proc;
 
  width_proc : process (clk, rst_n)
  begin  -- process width_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      width_r <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if conf_we_in = '1' and param_cnt_r = width_param_c then
        width_r <= conf_data_in(amountw_g - 1 downto 0);
      else
        width_r <= width_r;
      end if;
    end if;
  end process width_proc;
 
 
  height_proc : process (clk, rst_n)
  begin  -- process height_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      height_r <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
      if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then
        height_r <= std_logic_vector(unsigned(height_r) - 1);
      elsif conf_we_in = '1' and param_cnt_r = height_param_c then
        height_r <= conf_data_in(conf_data_in'length - 1 downto offsetw_g);
      else
        height_r <= height_r;
      end if;
    end if;
  end process height_proc;
 
  offset_proc : process (clk, rst_n)
  begin  -- process offset_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      offset_r <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
      if conf_we_in = '1' and param_cnt_r = offset_param_c then
        offset_r <= conf_data_in(offsetw_g - 1 downto 0);
      else
        offset_r <= offset_r;
      end if;
    end if;
  end process offset_proc;
 
  end_addr_proc : process (clk, rst_n)
    variable h_times_o_v : integer;
  begin  -- process end_addr_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      end_addr_r      <= (others => '0');
      end_addr_rdy_r  <= '0';
      calc_end_addr_r <= '0';
      h_times_o_r     <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      h_times_o_r <= h_times_o_r;
 
      if finish = '1' then
        -- opertation finishes
        end_addr_rdy_r  <= '0';
        calc_end_addr_r <= '0';
 
      elsif conf_we_in = '1' and param_cnt_r = 0 then
        -- calculate end address in seperate steps
        -- if block_overlap_g = 0:
        --    final end_addr_r = dst_addr_r + width_r
        -- if block_overlap_g = 1:
        --    final end_addr_r = dst_addr_r + width_r + (height_r-1)*offset_r
 
        -- 1) end_addr_r = dst_addr
        end_addr_r      <= conf_data_in(mem_addrw_g - 1 downto 0);
        end_addr_rdy_r  <= '0';
        calc_end_addr_r <= '0';
 
      elsif conf_we_in = '1' and param_cnt_r = 1 then
 
        -- 2) end_addr_r = dst_addr + width
        end_addr_r <= std_logic_vector(unsigned(end_addr_r) +
                                       unsigned(conf_data_in(mem_addrw_g - 1
                                                             downto 0)));
        if block_overlap_g = 0 then
          -- If no block overlap, this is the final result
          end_addr_rdy_r  <= '1';
        else
          -- Otherwise we have to calculate more
          end_addr_rdy_r  <= '0';
        end if;
        calc_end_addr_r <= '0';
 
      elsif block_overlap_g = 1 and
        conf_we_in = '1' and param_cnt_r = 2 then
 
        -- 3) end_addr_r = dst_addr + width
        --    h_times_o_r = height * offset
 
        h_times_o_v :=
          to_integer(unsigned(conf_data_in(conf_data_in'length - 1
                                           downto offsetw_g))) *
          to_integer(unsigned(conf_data_in(offsetw_g - 1
                                           downto 0)));
 
        h_times_o_r <= std_logic_vector(to_unsigned(h_times_o_v, hibi_dataw_g));
 
        end_addr_rdy_r  <= '0';
        calc_end_addr_r <= '1';
 
      elsif calc_end_addr_r = '1' then
        -- 4) end_addr_r = dst_addr_r + width_r + height_r*offset_r - height_r
        --               = dst_addr_r + amount_r + (height_r-1)*offset_r
        end_addr_r      <= std_logic_vector(
          unsigned(end_addr_r) + unsigned(h_times_o_r(end_addr_r'length - 1 downto 0))
          - unsigned(height_r));
 
        end_addr_rdy_r  <= '1';
        calc_end_addr_r <= '0';
      else
        calc_end_addr_r <= calc_end_addr_r;
        end_addr_rdy_r  <= end_addr_rdy_r;
      end if;
 
    end if;
  end process end_addr_proc;
 
  amount_proc : process (clk, rst_n)
  begin  -- process amount_proc
    if rst_n = '0' then                 -- asynchronous reset (active low)
      amount_r <= (others => '0');
    elsif clk'event and clk = '1' then  -- rising clock edge
 
      if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then
        -- next line on block transfer or transfer finishes
        amount_r <= width_r;
      elsif write_in = '1' then
        -- transfer continues on the same line
        amount_r <= std_logic_vector(unsigned(amount_r) - 1);
      elsif conf_we_in = '1' and param_cnt_r = amount_param_c then
        -- param write from sdram2hibi
        amount_r <= conf_data_in(amountw_g - 1 downto 0);
      end if;
    end if;
  end process amount_proc;
 
 
  wr_data : fifo
    generic map (
      data_width_g => hibi_dataw_g,
      depth_g      => fifo_depth_g)
    port map (
      clk       => clk,
      rst_n     => rst_n,
      data_in   => fifo_data_in,
      we_in     => fifo_we_in,
      one_p_out => fifo_one_p_out,
      full_out  => fifo_full_out,
      data_out  => fifo_data_out,
      re_in     => fifo_re_in,
      empty_out => fifo_empty_out,
      one_d_out => fifo_one_d_out);
end rtl;

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[/] [funbase_ip_library/] [trunk/] [TUT/] [ip.hwp.storage/] [sdram2hibi/] [1.0/] [vhd/] [sdram_wr_port.vhd] - Blame information for rev 145

Line No.	Rev	Author	Line
1	145	lanttu	`-------------------------------------------------------------------------------`
2			`-- Title : wr_port.vhd`
3			`-- Project :`
4			`-------------------------------------------------------------------------------`
5			`-- File : wr_port.vhd`
6			`-- Author :`
7			`-- Company :`
8			`-- Created : 2007-05-22`
9			`-- Last update: 2012-01-26`
10			`-- Platform :`
11			`-- Standard : VHDL'87`
12			`-------------------------------------------------------------------------------`
13			`-- Description: Write port for sdram2hibi`
14			`-------------------------------------------------------------------------------`
15			`-- Copyright (c) 2007`
16			`-------------------------------------------------------------------------------`
17			`-- Revisions :`
18			`-- Date Version Author Description`
19			`-- 2007-05-22 1.0 penttin5 Created`
20			`-- 2012-01-22 1.001 alhonen fixed names`
21			`-------------------------------------------------------------------------------`
22
23			`library ieee;`
24			`use ieee.std_logic_1164.all;`
25			`use ieee.numeric_std.all;`
26
27			`entity sdram_wr_port is`
28
29			`generic (`
30			`fifo_depth_g : integer;`
31			`amountw_g : integer;`
32			`hibi_dataw_g : integer;`
33			`block_overlap_g : integer := 0;`
34			`offsetw_g : integer;`
35			`mem_dataw_g : integer;`
36			`mem_addrw_g : integer);`
37
38			`port (`
39			`clk : in std_logic;`
40			`rst_n : in std_logic;`
41			`conf_we_in : in std_logic;`
42			`conf_data_in : in std_logic_vector(hibi_dataw_g - 1 downto 0);`
43			`write_in : in std_logic;`
44			`reserve_in : in std_logic;`
45			`valid_out : out std_logic;`
46			`reserved_out : out std_logic;`
47			`end_addr_out : out std_logic_vector(mem_addrw_g - 1 downto 0);`
48			`dst_addr_out : out std_logic_vector(mem_addrw_g - 1 downto 0);`
49			`amount_out : out std_logic_vector(amountw_g - 1 downto 0);`
50			`fifo_we_in : in std_logic;`
51			`fifo_re_in : in std_logic;`
52			`fifo_data_in : in std_logic_vector(hibi_dataw_g - 1 downto 0);`
53			`fifo_full_out : out std_logic;`
54			`fifo_empty_out : out std_logic;`
55			`fifo_one_p_out : out std_logic;`
56			`fifo_one_d_out : out std_logic;`
57			`fifo_data_out : out std_logic_vector(hibi_dataw_g - 1 downto 0);`
58			`error_out : out std_logic);`
59
60			`end sdram_wr_port;`
61
62			`architecture rtl of sdram_wr_port is`
63
64			`component fifo`
65			`generic (`
66			`data_width_g : integer;`
67			`depth_g : integer);`
68			`port (`
69			`clk : in std_logic;`
70			`rst_n : in std_logic;`
71			`data_in : in std_logic_vector(data_width_g - 1 downto 0);`
72			`we_in : in std_logic;`
73			`one_p_out : out std_logic;`
74			`full_out : out std_logic;`
75			`data_out : out std_logic_vector(data_width_g - 1 downto 0);`
76			`re_in : in std_logic;`
77			`empty_out : out std_logic;`
78			`one_d_out : out std_logic);`
79			`end component;`
80
81			`-- parameter numbers`
82			`constant dst_addr_param_c : integer := 0;`
83			`constant amount_param_c : integer := 1;`
84			`constant width_param_c : integer := 1;`
85			`constant height_param_c : integer := 2;`
86			`constant offset_param_c : integer := 2;`
87			`constant last_param_c : integer := 2;`
88
89			`signal reserved_r : std_logic;`
90			`signal valid_r : std_logic;`
91			`signal dst_addr_r : std_logic_vector(mem_addrw_g - 1 downto 0);`
92			`signal amount_r : std_logic_vector(amountw_g - 1 downto 0);`
93			`signal width_r : std_logic_vector(amountw_g - 1 downto 0);`
94			`signal height_r : std_logic_vector(hibi_dataw_g - offsetw_g - 1 downto 0);`
95			`signal offset_r : std_logic_vector(offsetw_g - 1 downto 0);`
96			`signal end_addr_r : std_logic_vector(mem_addrw_g - 1 downto 0);`
97
98			`signal finish : std_logic;`
99			`signal param_cnt_r : integer range last_param_c downto 0;`
100			`signal end_addr_rdy_r : std_logic;`
101			`signal calc_end_addr_r : std_logic;`
102			`signal h_times_o_r : std_logic_vector(hibi_dataw_g - 1 downto 0);`
103
104			`begin -- rtl`
105
106			`-- drive outputs`
107			`reserved_out <= reserved_r;`
108			`valid_out <= valid_r;`
109			`dst_addr_out <= dst_addr_r;`
110			`amount_out <= amount_r;`
111			`end_addr_out <= end_addr_r;`
112
113			`-- purpose: Detect finished operation`
114			`-- type : combinational`
115			`-- inputs : write_in, amount_r, height_r`
116			`-- outputs: finish`
117			`port_finishes : process (write_in, amount_r, height_r)`
118			`begin -- process port_finishes`
119			`if write_in = '1'`
120			`and to_integer(unsigned(amount_r)) = 1`
121			`and (to_integer(unsigned(height_r)) = 1 or`
122			`to_integer(unsigned(height_r)) = 0) then`
123			`finish <= '1';`
124			`else`
125			`finish <= '0';`
126			`end if;`
127			`end process port_finishes;`
128
129			`param_counter: process (clk, rst_n)`
130			`begin -- process param_counter`
131			`if rst_n = '0' then -- asynchronous reset (active low)`
132			`param_cnt_r <= 0;`
133			`elsif clk'event and clk = '1' then -- rising clock edge`
134
135			`if conf_we_in = '1' and param_cnt_r = last_param_c then`
136			`param_cnt_r <= 0;`
137			`elsif conf_we_in = '1' then`
138			`param_cnt_r <= param_cnt_r + 1;`
139			`else`
140			`param_cnt_r <= param_cnt_r;`
141			`end if;`
142			`end if;`
143			`end process param_counter;`
144
145			`reserved_proc : process (clk, rst_n)`
146			`begin -- process reserved_proc`
147			`if rst_n = '0' then -- asynchronous reset (active low)`
148			`reserved_r <= '0';`
149			`elsif clk'event and clk = '1' then -- rising clock edge`
150
151			`if finish = '1' then`
152			`-- operation finishes`
153			`reserved_r <= '0';`
154			`elsif reserve_in = '1' then`
155			`-- reserve from sdram2hibi`
156			`reserved_r <= '1';`
157			`else`
158			`reserved_r <= reserved_r;`
159			`end if;`
160			`end if;`
161			`end process reserved_proc;`
162
163			`valid_proc : process (clk, rst_n)`
164			`begin -- process valid_proc`
165			`if rst_n = '0' then -- asynchronous reset (active low)`
166			`valid_r <= '0';`
167			`elsif clk'event and clk = '1' then -- rising clock edge`
168
169			`if finish = '1' then`
170			`-- operation finishes`
171			`valid_r <= '0';`
172			`elsif block_overlap_g = 0`
173			`and conf_we_in = '1' and param_cnt_r = last_param_c then`
174			`-- without block overlap, configuration finishes on`
175			`-- third paramater write`
176			`valid_r <= '1';`
177			`elsif block_overlap_g = 1 and end_addr_rdy_r = '1' then`
178			`-- with block overlap, configuration finishes on`
179			`-- end address calculation`
180			`valid_r <= '1';`
181			`else`
182			`valid_r <= valid_r;`
183			`end if;`
184			`end if;`
185
186			`end process valid_proc;`
187
188			`dst_addr_proc : process (clk, rst_n)`
189			`begin -- process dst_addr_proc`
190			`if rst_n = '0' then -- asynchronous reset (active low)`
191			`dst_addr_r <= (others => '0');`
192			`elsif clk'event and clk = '1' then -- rising clock edge`
193
194			`if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then`
195			`-- line finishes, jump to next line`
196			`dst_addr_r <= std_logic_vector(unsigned(dst_addr_r) +`
197			`unsigned(offset_r) + 1);`
198			`elsif write_in = '1' then`
199			`-- line continues, increase dst_addr`
200			`dst_addr_r <= std_logic_vector(unsigned(dst_addr_r) + 1);`
201
202			`elsif conf_we_in = '1' and param_cnt_r = dst_addr_param_c then`
203			`-- configure from sdram2hibi`
204			`dst_addr_r <= conf_data_in(mem_addrw_g - 1 downto 0);`
205			`else`
206			`dst_addr_r <= dst_addr_r;`
207			`end if;`
208			`end if;`
209			`end process dst_addr_proc;`
210
211			`width_proc : process (clk, rst_n)`
212			`begin -- process width_proc`
213			`if rst_n = '0' then -- asynchronous reset (active low)`
214			`width_r <= (others => '0');`
215			`elsif clk'event and clk = '1' then -- rising clock edge`
216
217			`if conf_we_in = '1' and param_cnt_r = width_param_c then`
218			`width_r <= conf_data_in(amountw_g - 1 downto 0);`
219			`else`
220			`width_r <= width_r;`
221			`end if;`
222			`end if;`
223			`end process width_proc;`
224
225
226			`height_proc : process (clk, rst_n)`
227			`begin -- process height_proc`
228			`if rst_n = '0' then -- asynchronous reset (active low)`
229			`height_r <= (others => '0');`
230			`elsif clk'event and clk = '1' then -- rising clock edge`
231			`if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then`
232			`height_r <= std_logic_vector(unsigned(height_r) - 1);`
233			`elsif conf_we_in = '1' and param_cnt_r = height_param_c then`
234			`height_r <= conf_data_in(conf_data_in'length - 1 downto offsetw_g);`
235			`else`
236			`height_r <= height_r;`
237			`end if;`
238			`end if;`
239			`end process height_proc;`
240
241			`offset_proc : process (clk, rst_n)`
242			`begin -- process offset_proc`
243			`if rst_n = '0' then -- asynchronous reset (active low)`
244			`offset_r <= (others => '0');`
245			`elsif clk'event and clk = '1' then -- rising clock edge`
246			`if conf_we_in = '1' and param_cnt_r = offset_param_c then`
247			`offset_r <= conf_data_in(offsetw_g - 1 downto 0);`
248			`else`
249			`offset_r <= offset_r;`
250			`end if;`
251			`end if;`
252			`end process offset_proc;`
253
254			`end_addr_proc : process (clk, rst_n)`
255			`variable h_times_o_v : integer;`
256			`begin -- process end_addr_proc`
257			`if rst_n = '0' then -- asynchronous reset (active low)`
258			`end_addr_r <= (others => '0');`
259			`end_addr_rdy_r <= '0';`
260			`calc_end_addr_r <= '0';`
261			`h_times_o_r <= (others => '0');`
262			`elsif clk'event and clk = '1' then -- rising clock edge`
263
264			`h_times_o_r <= h_times_o_r;`
265
266			`if finish = '1' then`
267			`-- opertation finishes`
268			`end_addr_rdy_r <= '0';`
269			`calc_end_addr_r <= '0';`
270
271			`elsif conf_we_in = '1' and param_cnt_r = 0 then`
272			`-- calculate end address in seperate steps`
273			`-- if block_overlap_g = 0:`
274			`-- final end_addr_r = dst_addr_r + width_r`
275			`-- if block_overlap_g = 1:`
276			`-- final end_addr_r = dst_addr_r + width_r + (height_r-1)*offset_r`
277
278			`-- 1) end_addr_r = dst_addr`
279			`end_addr_r <= conf_data_in(mem_addrw_g - 1 downto 0);`
280			`end_addr_rdy_r <= '0';`
281			`calc_end_addr_r <= '0';`
282
283			`elsif conf_we_in = '1' and param_cnt_r = 1 then`
284
285			`-- 2) end_addr_r = dst_addr + width`
286			`end_addr_r <= std_logic_vector(unsigned(end_addr_r) +`
287			`unsigned(conf_data_in(mem_addrw_g - 1`
288			`downto 0)));`
289			`if block_overlap_g = 0 then`
290			`-- If no block overlap, this is the final result`
291			`end_addr_rdy_r <= '1';`
292			`else`
293			`-- Otherwise we have to calculate more`
294			`end_addr_rdy_r <= '0';`
295			`end if;`
296			`calc_end_addr_r <= '0';`
297
298			`elsif block_overlap_g = 1 and`
299			`conf_we_in = '1' and param_cnt_r = 2 then`
300
301			`-- 3) end_addr_r = dst_addr + width`
302			`-- h_times_o_r = height * offset`
303
304			`h_times_o_v :=`
305			`to_integer(unsigned(conf_data_in(conf_data_in'length - 1`
306			`downto offsetw_g))) *`
307			`to_integer(unsigned(conf_data_in(offsetw_g - 1`
308			`downto 0)));`
309
310			`h_times_o_r <= std_logic_vector(to_unsigned(h_times_o_v, hibi_dataw_g));`
311
312			`end_addr_rdy_r <= '0';`
313			`calc_end_addr_r <= '1';`
314
315			`elsif calc_end_addr_r = '1' then`
316			`-- 4) end_addr_r = dst_addr_r + width_r + height_r*offset_r - height_r`
317			`-- = dst_addr_r + amount_r + (height_r-1)*offset_r`
318			`end_addr_r <= std_logic_vector(`
319			`unsigned(end_addr_r) + unsigned(h_times_o_r(end_addr_r'length - 1 downto 0))`
320			`- unsigned(height_r));`
321
322			`end_addr_rdy_r <= '1';`
323			`calc_end_addr_r <= '0';`
324			`else`
325			`calc_end_addr_r <= calc_end_addr_r;`
326			`end_addr_rdy_r <= end_addr_rdy_r;`
327			`end if;`
328
329			`end if;`
330			`end process end_addr_proc;`
331
332			`amount_proc : process (clk, rst_n)`
333			`begin -- process amount_proc`
334			`if rst_n = '0' then -- asynchronous reset (active low)`
335			`amount_r <= (others => '0');`
336			`elsif clk'event and clk = '1' then -- rising clock edge`
337
338			`if write_in = '1' and to_integer(unsigned(amount_r)) = 1 then`
339			`-- next line on block transfer or transfer finishes`
340			`amount_r <= width_r;`
341			`elsif write_in = '1' then`
342			`-- transfer continues on the same line`
343			`amount_r <= std_logic_vector(unsigned(amount_r) - 1);`
344			`elsif conf_we_in = '1' and param_cnt_r = amount_param_c then`
345			`-- param write from sdram2hibi`
346			`amount_r <= conf_data_in(amountw_g - 1 downto 0);`
347			`end if;`
348			`end if;`
349			`end process amount_proc;`
350
351
352			`wr_data : fifo`
353			`generic map (`
354			`data_width_g => hibi_dataw_g,`
355			`depth_g => fifo_depth_g)`
356			`port map (`
357			`clk => clk,`
358			`rst_n => rst_n,`
359			`data_in => fifo_data_in,`
360			`we_in => fifo_we_in,`
361			`one_p_out => fifo_one_p_out,`
362			`full_out => fifo_full_out,`
363			`data_out => fifo_data_out,`
364			`re_in => fifo_re_in,`
365			`empty_out => fifo_empty_out,`
366			`one_d_out => fifo_one_d_out);`
367			`end rtl;`