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[/] [neorv32/] [trunk/] [rtl/] [core/] [neorv32_spi.vhd] - Blame information for rev 73

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1 2 zero_gravi 
-- #################################################################################################
2 6 zero_gravi 
-- # << NEORV32 - Serial Peripheral Interface Controller (SPI) >>                                  #
3 2 zero_gravi 
-- # ********************************************************************************************* #
4 36 zero_gravi 
-- # Frame format: 8/16/24/32-bit receive/transmit data, always MSB first, 2 clock modes,          #
5 50 zero_gravi 
-- # 8 pre-scaled clocks (derived from system clock), 8 dedicated chip-select lines (low-active).  #
6 68 zero_gravi 
-- # Interrupt: "transfer done"                                                                    #
7 2 zero_gravi 
-- # ********************************************************************************************* #
8 
-- # BSD 3-Clause License                                                                          #
9 
-- #                                                                                               #
10 70 zero_gravi 
-- # Copyright (c) 2022, Stephan Nolting. All rights reserved.                                     #
11 2 zero_gravi 
-- #                                                                                               #
12 
-- # Redistribution and use in source and binary forms, with or without modification, are          #
13 
-- # permitted provided that the following conditions are met:                                     #
14 
-- #                                                                                               #
15 
-- # 1. Redistributions of source code must retain the above copyright notice, this list of        #
16 
-- #    conditions and the following disclaimer.                                                   #
17 
-- #                                                                                               #
18 
-- # 2. Redistributions in binary form must reproduce the above copyright notice, this list of     #
19 
-- #    conditions and the following disclaimer in the documentation and/or other materials        #
20 
-- #    provided with the distribution.                                                            #
21 
-- #                                                                                               #
22 
-- # 3. Neither the name of the copyright holder nor the names of its contributors may be used to  #
23 
-- #    endorse or promote products derived from this software without specific prior written      #
24 
-- #    permission.                                                                                #
25 
-- #                                                                                               #
26 
-- # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS   #
27 
-- # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF               #
28 
-- # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE    #
29 
-- # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,     #
30 
-- # EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE #
31 
-- # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED    #
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-- # AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING     #
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-- # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED  #
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-- # OF THE POSSIBILITY OF SUCH DAMAGE.                                                            #
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-- # ********************************************************************************************* #
36 
-- # The NEORV32 Processor - https://github.com/stnolting/neorv32              (c) Stephan Nolting #
37 
-- #################################################################################################
38 
 
39 
library ieee;
40 
use ieee.std_logic_1164.all;
41 
use ieee.numeric_std.all;
42 
 
43 
library neorv32;
44 
use neorv32.neorv32_package.all;
45 
 
46 
entity neorv32_spi is
47 
  port (
48 
    -- host access --
49 
    clk_i       : in  std_ulogic; -- global clock line
50 
    addr_i      : in  std_ulogic_vector(31 downto 0); -- address
51 
    rden_i      : in  std_ulogic; -- read enable
52 
    wren_i      : in  std_ulogic; -- write enable
53 
    data_i      : in  std_ulogic_vector(31 downto 0); -- data in
54 
    data_o      : out std_ulogic_vector(31 downto 0); -- data out
55 
    ack_o       : out std_ulogic; -- transfer acknowledge
56 
    -- clock generator --
57 
    clkgen_en_o : out std_ulogic; -- enable clock generator
58 
    clkgen_i    : in  std_ulogic_vector(07 downto 0);
59 
    -- com lines --
60 6 zero_gravi 
    spi_sck_o   : out std_ulogic; -- SPI serial clock
61 
    spi_sdo_o   : out std_ulogic; -- controller data out, peripheral data in
62 
    spi_sdi_i   : in  std_ulogic; -- controller data in, peripheral data out
63 2 zero_gravi 
    spi_csn_o   : out std_ulogic_vector(07 downto 0); -- SPI CS
64 
    -- interrupt --
65 48 zero_gravi 
    irq_o       : out std_ulogic -- transmission done interrupt
66 2 zero_gravi 
  );
67 
end neorv32_spi;
68 
 
69 
architecture neorv32_spi_rtl of neorv32_spi is
70 
 
71 
  -- IO space: module base address --
72 
  constant hi_abb_c : natural := index_size_f(io_size_c)-1; -- high address boundary bit
73 
  constant lo_abb_c : natural := index_size_f(spi_size_c); -- low address boundary bit
74 
 
75 65 zero_gravi 
  -- control register --
76 70 zero_gravi 
  constant ctrl_cs0_c       : natural :=  0; -- r/w: spi CS 0
77 
  constant ctrl_cs1_c       : natural :=  1; -- r/w: spi CS 1
78 
  constant ctrl_cs2_c       : natural :=  2; -- r/w: spi CS 2
79 
  constant ctrl_cs3_c       : natural :=  3; -- r/w: spi CS 3
80 
  constant ctrl_cs4_c       : natural :=  4; -- r/w: spi CS 4
81 
  constant ctrl_cs5_c       : natural :=  5; -- r/w: spi CS 5
82 
  constant ctrl_cs6_c       : natural :=  6; -- r/w: spi CS 6
83 
  constant ctrl_cs7_c       : natural :=  7; -- r/w: spi CS 7
84 
  constant ctrl_en_c        : natural :=  8; -- r/w: spi enable
85 
  constant ctrl_cpha_c      : natural :=  9; -- r/w: spi clock phase
86 
  constant ctrl_prsc0_c     : natural := 10; -- r/w: spi prescaler select bit 0
87 
  constant ctrl_prsc1_c     : natural := 11; -- r/w: spi prescaler select bit 1
88 
  constant ctrl_prsc2_c     : natural := 12; -- r/w: spi prescaler select bit 2
89 
  constant ctrl_size0_c     : natural := 13; -- r/w: data size lsb (00:  8-bit, 01: 16-bit)
90 
  constant ctrl_size1_c     : natural := 14; -- r/w: data size msb (10: 24-bit, 11: 32-bit)
91 
  constant ctrl_cpol_c      : natural := 15; -- r/w: spi clock polarity
92 
  constant ctrl_highspeed_c : natural := 16; -- r/w: spi high-speed mode enable (ignoring ctrl_prsc)
93 2 zero_gravi 
  --
94 70 zero_gravi 
  constant ctrl_busy_c      : natural := 31; -- r/-: spi transceiver is busy
95 2 zero_gravi 
  --
96 70 zero_gravi 
  signal ctrl : std_ulogic_vector(16 downto 0);
97 2 zero_gravi 
 
98 
  -- access control --
99 
  signal acc_en : std_ulogic; -- module access enable
100 
  signal addr   : std_ulogic_vector(31 downto 0); -- access address
101 
  signal wren   : std_ulogic; -- word write enable
102 
  signal rden   : std_ulogic; -- read enable
103 
 
104 
  -- clock generator --
105 65 zero_gravi 
  signal spi_clk_en : std_ulogic;
106 2 zero_gravi 
 
107 
  -- spi transceiver --
108 65 zero_gravi 
  type rtx_engine_t is record
109 66 zero_gravi 
    state    : std_ulogic_vector(02 downto 0);
110 65 zero_gravi 
    busy     : std_ulogic;
111 66 zero_gravi 
    start    : std_ulogic;
112 
    sreg     : std_ulogic_vector(31 downto 0);
113 65 zero_gravi 
    bitcnt   : std_ulogic_vector(05 downto 0);
114 
    bytecnt  : std_ulogic_vector(02 downto 0);
115 70 zero_gravi 
    sdi_sync : std_ulogic;
116 65 zero_gravi 
  end record;
117 
  signal rtx_engine : rtx_engine_t;
118 2 zero_gravi 
 
119 
begin
120 
 
121 
  -- Access Control -------------------------------------------------------------------------
122 
  -- -------------------------------------------------------------------------------------------
123 
  acc_en <= '1' when (addr_i(hi_abb_c downto lo_abb_c) = spi_base_c(hi_abb_c downto lo_abb_c)) else '0';
124 
  addr   <= spi_base_c(31 downto lo_abb_c) & addr_i(lo_abb_c-1 downto 2) & "00"; -- word aligned
125 
  wren   <= acc_en and wren_i;
126 
  rden   <= acc_en and rden_i;
127 
 
128 
 
129 
  -- Read/Write Access ----------------------------------------------------------------------
130 
  -- -------------------------------------------------------------------------------------------
131 
  rw_access: process(clk_i)
132 
  begin
133 
    if rising_edge(clk_i) then
134 65 zero_gravi 
      -- bus access acknowledge --
135 
      ack_o <= rden or wren;
136 
 
137 36 zero_gravi 
      -- write access --
138 2 zero_gravi 
      if (wren = '1') then
139 65 zero_gravi 
        if (addr = spi_ctrl_addr_c) then -- control register
140 70 zero_gravi 
          ctrl(ctrl_cs0_c)       <= data_i(ctrl_cs0_c);
141 
          ctrl(ctrl_cs1_c)       <= data_i(ctrl_cs1_c);
142 
          ctrl(ctrl_cs2_c)       <= data_i(ctrl_cs2_c);
143 
          ctrl(ctrl_cs3_c)       <= data_i(ctrl_cs3_c);
144 
          ctrl(ctrl_cs4_c)       <= data_i(ctrl_cs4_c);
145 
          ctrl(ctrl_cs5_c)       <= data_i(ctrl_cs5_c);
146 
          ctrl(ctrl_cs6_c)       <= data_i(ctrl_cs6_c);
147 
          ctrl(ctrl_cs7_c)       <= data_i(ctrl_cs7_c);
148 
          ctrl(ctrl_en_c)        <= data_i(ctrl_en_c);
149 
          ctrl(ctrl_cpha_c)      <= data_i(ctrl_cpha_c);
150 
          ctrl(ctrl_prsc0_c)     <= data_i(ctrl_prsc0_c);
151 
          ctrl(ctrl_prsc1_c)     <= data_i(ctrl_prsc1_c);
152 
          ctrl(ctrl_prsc2_c)     <= data_i(ctrl_prsc2_c);
153 
          ctrl(ctrl_size0_c)     <= data_i(ctrl_size0_c);
154 
          ctrl(ctrl_size1_c)     <= data_i(ctrl_size1_c);
155 
          ctrl(ctrl_cpol_c)      <= data_i(ctrl_cpol_c);
156 
          ctrl(ctrl_highspeed_c) <= data_i(ctrl_highspeed_c);
157 2 zero_gravi 
        end if;
158 
      end if;
159 65 zero_gravi 
 
160 2 zero_gravi 
      -- read access --
161 
      data_o <= (others => '0');
162 
      if (rden = '1') then
163 65 zero_gravi 
        if (addr = spi_ctrl_addr_c) then -- control register
164 70 zero_gravi 
          data_o(ctrl_cs0_c)       <= ctrl(ctrl_cs0_c);
165 
          data_o(ctrl_cs1_c)       <= ctrl(ctrl_cs1_c);
166 
          data_o(ctrl_cs2_c)       <= ctrl(ctrl_cs2_c);
167 
          data_o(ctrl_cs3_c)       <= ctrl(ctrl_cs3_c);
168 
          data_o(ctrl_cs4_c)       <= ctrl(ctrl_cs4_c);
169 
          data_o(ctrl_cs5_c)       <= ctrl(ctrl_cs5_c);
170 
          data_o(ctrl_cs6_c)       <= ctrl(ctrl_cs6_c);
171 
          data_o(ctrl_cs7_c)       <= ctrl(ctrl_cs7_c);
172 
          data_o(ctrl_en_c)        <= ctrl(ctrl_en_c);
173 
          data_o(ctrl_cpha_c)      <= ctrl(ctrl_cpha_c);
174 
          data_o(ctrl_prsc0_c)     <= ctrl(ctrl_prsc0_c);
175 
          data_o(ctrl_prsc1_c)     <= ctrl(ctrl_prsc1_c);
176 
          data_o(ctrl_prsc2_c)     <= ctrl(ctrl_prsc2_c);
177 
          data_o(ctrl_size0_c)     <= ctrl(ctrl_size0_c);
178 
          data_o(ctrl_size1_c)     <= ctrl(ctrl_size1_c);
179 
          data_o(ctrl_cpol_c)      <= ctrl(ctrl_cpol_c);
180 
          data_o(ctrl_highspeed_c) <= ctrl(ctrl_highspeed_c);
181 2 zero_gravi 
          --
182 70 zero_gravi 
          data_o(ctrl_busy_c)      <= rtx_engine.busy;
183 65 zero_gravi 
        else -- data register (spi_rtx_addr_c)
184 66 zero_gravi 
          data_o <= rtx_engine.sreg;
185 2 zero_gravi 
        end if;
186 
      end if;
187 
    end if;
188 
  end process rw_access;
189 
 
190 65 zero_gravi 
  -- direct chip-select (CS), output is low-active --
191 66 zero_gravi 
  spi_csn_o(7 downto 0) <= not ctrl(ctrl_cs7_c downto ctrl_cs0_c);
192 2 zero_gravi 
 
193 66 zero_gravi 
  -- trigger new SPI transmission --
194 
  rtx_engine.start <= '1' when (wren = '1') and (addr = spi_rtx_addr_c) else '0';
195 2 zero_gravi 
 
196 66 zero_gravi 
 
197 
  -- Clock Selection ------------------------------------------------------------------------
198 
  -- -------------------------------------------------------------------------------------------
199 
  clkgen_en_o <= ctrl(ctrl_en_c); -- clock generator enable
200 70 zero_gravi 
  spi_clk_en  <= clkgen_i(to_integer(unsigned(ctrl(ctrl_prsc2_c downto ctrl_prsc0_c)))) or ctrl(ctrl_highspeed_c); -- clock select
201 66 zero_gravi 
 
202 
 
203 65 zero_gravi 
  -- Transmission Data Size -----------------------------------------------------------------
204 
  -- -------------------------------------------------------------------------------------------
205 
  data_size: process(ctrl)
206 
  begin
207 66 zero_gravi 
    case ctrl(ctrl_size1_c downto ctrl_size0_c) is
208 65 zero_gravi 
      when "00"   => rtx_engine.bytecnt <= "001"; -- 1-byte mode
209 
      when "01"   => rtx_engine.bytecnt <= "010"; -- 2-byte mode
210 
      when "10"   => rtx_engine.bytecnt <= "011"; -- 3-byte mode
211 
      when others => rtx_engine.bytecnt <= "100"; -- 4-byte mode
212 
    end case;
213 
  end process data_size;
214 
 
215 
 
216 2 zero_gravi 
  -- SPI Transceiver ------------------------------------------------------------------------
217 
  -- -------------------------------------------------------------------------------------------
218 
  spi_rtx_unit: process(clk_i)
219 
  begin
220 
    if rising_edge(clk_i) then
221 6 zero_gravi 
      -- input (sdi) synchronizer --
222 70 zero_gravi 
      rtx_engine.sdi_sync <= spi_sdi_i;
223 2 zero_gravi 
 
224 66 zero_gravi 
      -- defaults --
225 
      spi_sck_o <= ctrl(ctrl_cpol_c);
226 69 zero_gravi 
      irq_o     <= '0';
227 66 zero_gravi 
 
228 2 zero_gravi 
      -- serial engine --
229 66 zero_gravi 
      rtx_engine.state(2) <= ctrl(ctrl_en_c);
230 
      case rtx_engine.state is
231 2 zero_gravi 
 
232 66 zero_gravi 
        when "100" => -- enabled but idle, waiting for new transmission trigger
233 
        -- ------------------------------------------------------------
234 
          rtx_engine.bitcnt <= (others => '0');
235 
          if (rtx_engine.start = '1') then -- trigger new transmission
236 
            rtx_engine.sreg <= data_i;
237 
            rtx_engine.state(1 downto 0) <= "01";
238 
          end if;
239 65 zero_gravi 
 
240 66 zero_gravi 
        when "101" => -- start with next new clock pulse
241 
        -- ------------------------------------------------------------
242 65 zero_gravi 
          if (spi_clk_en = '1') then
243 66 zero_gravi 
            rtx_engine.state(1 downto 0) <= "10";
244 
          end if;
245 
 
246 
        when "110" => -- first half of bit transmission
247 
        -- ------------------------------------------------------------
248 
          spi_sck_o <= ctrl(ctrl_cpha_c) xor ctrl(ctrl_cpol_c);
249 
          if (spi_clk_en = '1') then
250 65 zero_gravi 
            rtx_engine.bitcnt <= std_ulogic_vector(unsigned(rtx_engine.bitcnt) + 1);
251 66 zero_gravi 
            rtx_engine.state(1 downto 0) <= "11";
252 2 zero_gravi 
          end if;
253 36 zero_gravi 
 
254 66 zero_gravi 
        when "111" => -- second half of bit transmission
255 
        -- ------------------------------------------------------------
256 
          spi_sck_o <= ctrl(ctrl_cpha_c) xnor ctrl(ctrl_cpol_c);
257 65 zero_gravi 
          if (spi_clk_en = '1') then
258 70 zero_gravi 
            rtx_engine.sreg <= rtx_engine.sreg(30 downto 0) & rtx_engine.sdi_sync;
259 66 zero_gravi 
            if (rtx_engine.bitcnt(5 downto 3) = rtx_engine.bytecnt) then -- all bits transferred?
260 69 zero_gravi 
              irq_o <= '1'; -- interrupt!
261 68 zero_gravi 
              rtx_engine.state(1 downto 0) <= "00"; -- transmission done
262 66 zero_gravi 
            else
263 
              rtx_engine.state(1 downto 0) <= "10";
264 2 zero_gravi 
            end if;
265 
          end if;
266 65 zero_gravi 
 
267 66 zero_gravi 
        when others => -- "0--": SPI deactivated
268 
        -- ------------------------------------------------------------
269 
          rtx_engine.state(1 downto 0) <= "00";
270 
 
271 
      end case;
272 2 zero_gravi 
    end if;
273 
  end process spi_rtx_unit;
274 
 
275 66 zero_gravi 
  -- busy flag --
276 
  rtx_engine.busy <= '0' when (rtx_engine.state(1 downto 0) = "00") else '1';
277 36 zero_gravi 
 
278 70 zero_gravi 
  -- output bit select --
279 
  spi_output: process(ctrl, rtx_engine)
280 
  begin
281 
    case ctrl(ctrl_size1_c downto ctrl_size0_c) is
282 
      when "00"   => spi_sdo_o <= rtx_engine.sreg(07); -- 8-bit mode
283 
      when "01"   => spi_sdo_o <= rtx_engine.sreg(15); -- 16-bit mode
284 
      when "10"   => spi_sdo_o <= rtx_engine.sreg(23); -- 24-bit mode
285 
      when others => spi_sdo_o <= rtx_engine.sreg(31); -- 32-bit mode
286 
    end case;
287 
  end process spi_output;
288 66 zero_gravi 
 
289 70 zero_gravi 
 
290 2 zero_gravi 
end neorv32_spi_rtl;

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