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altera_devel
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fpu32
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mult.v

mult.v 6.4 KB
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  1. //IEEE Floating Point Multiplier (Single Precision)
    2. 

  2. //Copyright (C) Jonathan P Dawson 2013
    3. 

  3. //2013-12-12
    4. 

  4. 

  5. module multiplier(
    6. 

  6.         input_a,
    7. 

  7.         input_b,
    8. 

  8.         input_stb,
    9. 

  9.         output_z_ack,
    10. 

  10.         clk,
    11. 

  11.         rst,
    12. 

  12.         output_z,
    13. 

  13.         output_z_stb,
    14. 

  14.         input_ack);
    15. 

  15. 

  16.   input     clk;
    17. 

  17.   input     rst;
    18. 

  18. 

  19.   input     [31:0] input_a;
    20. 

  20.   input     [31:0] input_b;
    21. 

  21. 

  22.   input     input_stb;
    23. 

  23.   output    input_ack;
    24. 

  24. 

  25. 

  26.   output    [31:0] output_z;
    27. 

  27.   output    output_z_stb;
    28. 

  28.   input     output_z_ack;
    29. 

  29. 

  30.   reg       s_output_z_stb;
    31. 

  31.   reg       [31:0] s_output_z;
    32. 

  32.   reg       s_input_ack;
    33. 

  33. 

  34.   reg       [3:0] state;
    35. 

  35.   parameter get_a         = 4'd0,
    36. 

  36.             get_b         = 4'd1,
    37. 

  37.             unpack        = 4'd2,
    38. 

  38.             special_cases = 4'd3,
    39. 

  39.             normalise_a   = 4'd4,
    40. 

  40.             normalise_b   = 4'd5,
    41. 

  41.             multiply_0    = 4'd6,
    42. 

  42.             multiply_1    = 4'd7,
    43. 

  43.             normalise_1   = 4'd8,
    44. 

  44.             normalise_2   = 4'd9,
    45. 

  45.             round         = 4'd10,
    46. 

  46.             pack          = 4'd11,
    47. 

  47.             put_z         = 4'd12,
    48. 

  48.             get_input     = 4'd13;
    49. 

  49. 

  50.   reg       [31:0] a, b, z;
    51. 

  51.   reg       [23:0] a_m, b_m, z_m;
    52. 

  52.   reg       [9:0] a_e, b_e, z_e;
    53. 

  53.   reg       a_s, b_s, z_s;
    54. 

  54.   reg       guard, round_bit, sticky;
    55. 

  55.   reg       [49:0] product;
    56. 

  56. 

  57.   always @(posedge clk)
    58. 

  58.   begin
    59. 

  59. 

  60.     case(state)
    61. 

  61. 

  62. //      get_a:
    63. 

  63. //      begin
    64. 

  64. //        s_input_a_ack <= 1;
    65. 

  65. //        if (s_input_a_ack && input_a_stb) begin
    66. 

  66. //          a <= input_a;
    67. 

  67. //          s_input_a_ack <= 0;
    68. 

  68. //          state <= get_b;
    69. 

  69. //        end
    70. 

  70. //      end
    71. 

  71. //
    72. 

  72. //      get_b:
    73. 

  73. //      begin
    74. 

  74. //        s_input_b_ack <= 1;
    75. 

  75. //        if (s_input_b_ack && input_b_stb) begin
    76. 

  76. //          b <= input_b;
    77. 

  77. //          s_input_b_ack <= 0;
    78. 

  78. //          state <= unpack;
    79. 

  79. //        end
    80. 

  80. //      end
    81. 

  81. 

  82.       get_input:
    83. 

  83.       begin
    84. 

  84.         s_input_ack <= 1;
    85. 

  85.         if (s_input_ack && input_stb) begin
    86. 

  86.           a <= input_a;
    87. 

  87.           b <= input_b;
    88. 

  88.           s_input_ack <= 0;
    89. 

  89.           state <= unpack;
    90. 

  90.         end
    91. 

  91.       end
    92. 

  92. 

  93.       unpack:
    94. 

  94.       begin
    95. 

  95.         a_m <= a[22 : 0];
    96. 

  96.         b_m <= b[22 : 0];
    97. 

  97.         a_e <= a[30 : 23] - 127;
    98. 

  98.         b_e <= b[30 : 23] - 127;
    99. 

  99.         a_s <= a[31];
    100. 

  100.         b_s <= b[31];
    101. 

  101.         state <= special_cases;
    102. 

  102.       end
    103. 

  103. 

  104.       special_cases:
    105. 

  105.       begin
    106. 

  106.         //if a is NaN or b is NaN return NaN
    107. 

  107.         if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
    108. 

  108.           z[31] <= 1;
    109. 

  109.           z[30:23] <= 255;
    110. 

  110.           z[22] <= 1;
    111. 

  111.           z[21:0] <= 0;
    112. 

  112.           state <= put_z;
    113. 

  113.         //if a is inf return inf
    114. 

  114.         end else if (a_e == 128) begin
    115. 

  115.           z[31] <= a_s ^ b_s;
    116. 

  116.           z[30:23] <= 255;
    117. 

  117.           z[22:0] <= 0;
    118. 

  118.           //if b is zero return NaN
    119. 

  119.           if (($signed(b_e) == -127) && (b_m == 0)) begin
    120. 

  120.             z[31] <= 1;
    121. 

  121.             z[30:23] <= 255;
    122. 

  122.             z[22] <= 1;
    123. 

  123.             z[21:0] <= 0;
    124. 

  124.           end
    125. 

  125.           state <= put_z;
    126. 

  126.         //if b is inf return inf
    127. 

  127.         end else if (b_e == 128) begin
    128. 

  128.           z[31] <= a_s ^ b_s;
    129. 

  129.           z[30:23] <= 255;
    130. 

  130.           z[22:0] <= 0;
    131. 

  131.           //if a is zero return NaN
    132. 

  132.           if (($signed(a_e) == -127) && (a_m == 0)) begin
    133. 

  133.             z[31] <= 1;
    134. 

  134.             z[30:23] <= 255;
    135. 

  135.             z[22] <= 1;
    136. 

  136.             z[21:0] <= 0;
    137. 

  137.           end
    138. 

  138.           state <= put_z;
    139. 

  139.         //if a is zero return zero
    140. 

  140.         end else if (($signed(a_e) == -127) && (a_m == 0)) begin
    141. 

  141.           z[31] <= a_s ^ b_s;
    142. 

  142.           z[30:23] <= 0;
    143. 

  143.           z[22:0] <= 0;
    144. 

  144.           state <= put_z;
    145. 

  145.         //if b is zero return zero
    146. 

  146.         end else if (($signed(b_e) == -127) && (b_m == 0)) begin
    147. 

  147.           z[31] <= a_s ^ b_s;
    148. 

  148.           z[30:23] <= 0;
    149. 

  149.           z[22:0] <= 0;
    150. 

  150.           state <= put_z;
    151. 

  151.         end else begin
    152. 

  152.           //Denormalised Number
    153. 

  153.           if ($signed(a_e) == -127) begin
    154. 

  154.             a_e <= -126;
    155. 

  155.           end else begin
    156. 

  156.             a_m[23] <= 1;
    157. 

  157.           end
    158. 

  158.           //Denormalised Number
    159. 

  159.           if ($signed(b_e) == -127) begin
    160. 

  160.             b_e <= -126;
    161. 

  161.           end else begin
    162. 

  162.             b_m[23] <= 1;
    163. 

  163.           end
    164. 

  164.           state <= normalise_a;
    165. 

  165.         end
    166. 

  166.       end
    167. 

  167. 

  168.       normalise_a:
    169. 

  169.       begin
    170. 

  170.         if (a_m[23]) begin
    171. 

  171.           state <= normalise_b;
    172. 

  172.         end else begin
    173. 

  173.           a_m <= a_m << 1;
    174. 

  174.           a_e <= a_e - 1;
    175. 

  175.         end
    176. 

  176.       end
    177. 

  177. 

  178.       normalise_b:
    179. 

  179.       begin
    180. 

  180.         if (b_m[23]) begin
    181. 

  181.           state <= multiply_0;
    182. 

  182.         end else begin
    183. 

  183.           b_m <= b_m << 1;
    184. 

  184.           b_e <= b_e - 1;
    185. 

  185.         end
    186. 

  186.       end
    187. 

  187. 

  188.       multiply_0:
    189. 

  189.       begin
    190. 

  190.         z_s <= a_s ^ b_s;
    191. 

  191.         z_e <= a_e + b_e + 1;
    192. 

  192.         product <= a_m * b_m * 4;
    193. 

  193.         state <= multiply_1;
    194. 

  194.       end
    195. 

  195. 

  196.       multiply_1:
    197. 

  197.       begin
    198. 

  198.         z_m <= product[49:26];
    199. 

  199.         guard <= product[25];
    200. 

  200.         round_bit <= product[24];
    201. 

  201.         sticky <= (product[23:0] != 0);
    202. 

  202.         state <= normalise_1;
    203. 

  203.       end
    204. 

  204. 

  205.       normalise_1:
    206. 

  206.       begin
    207. 

  207.         if (z_m[23] == 0) begin
    208. 

  208.           z_e <= z_e - 1;
    209. 

  209.           z_m <= z_m << 1;
    210. 

  210.           z_m[0] <= guard;
    211. 

  211.           guard <= round_bit;
    212. 

  212.           round_bit <= 0;
    213. 

  213.         end else begin
    214. 

  214.           state <= normalise_2;
    215. 

  215.         end
    216. 

  216.       end
    217. 

  217. 

  218.       normalise_2:
    219. 

  219.       begin
    220. 

  220.         if ($signed(z_e) < -126) begin
    221. 

  221.           z_e <= z_e + 1;
    222. 

  222.           z_m <= z_m >> 1;
    223. 

  223.           guard <= z_m[0];
    224. 

  224.           round_bit <= guard;
    225. 

  225.           sticky <= sticky | round_bit;
    226. 

  226.         end else begin
    227. 

  227.           state <= round;
    228. 

  228.         end
    229. 

  229.       end
    230. 

  230. 

  231.       round:
    232. 

  232.       begin
    233. 

  233.         if (guard && (round_bit | sticky | z_m[0])) begin
    234. 

  234.           z_m <= z_m + 1;
    235. 

  235.           if (z_m == 24'hffffff) begin
    236. 

  236.             z_e <=z_e + 1;
    237. 

  237.           end
    238. 

  238.         end
    239. 

  239.         state <= pack;
    240. 

  240.       end
    241. 

  241. 

  242.       pack:
    243. 

  243.       begin
    244. 

  244.         z[22 : 0] <= z_m[22:0];
    245. 

  245.         z[30 : 23] <= z_e[7:0] + 127;
    246. 

  246.         z[31] <= z_s;
    247. 

  247.         if ($signed(z_e) == -126 && z_m[23] == 0) begin
    248. 

  248.           z[30 : 23] <= 0;
    249. 

  249.         end
    250. 

  250.         //if overflow occurs, return inf
    251. 

  251.         if ($signed(z_e) > 127) begin
    252. 

  252.           z[22 : 0] <= 0;
    253. 

  253.           z[30 : 23] <= 255;
    254. 

  254.           z[31] <= z_s;
    255. 

  255.         end
    256. 

  256.         state <= put_z;
    257. 

  257.       end
    258. 

  258. 

  259.       put_z:
    260. 

  260.       begin
    261. 

  261.         s_output_z_stb <= 1;
    262. 

  262.         s_output_z <= z;
    263. 

  263.         if (s_output_z_stb && output_z_ack) begin
    264. 

  264.           s_output_z_stb <= 0;
    265. 

  265.           state <= get_input;
    266. 

  266.         end
    267. 

  267.       end
    268. 

  268. 

  269.     endcase
    270. 

  270. 

  271.     if (rst == 1) begin
    272. 

  272.       state <= get_input;
    273. 

  273.       s_input_ack <= 0;
    274. 

  274.       s_output_z_stb <= 0;
    275. 

  275.     end
    276. 

  276. 

  277.   end
    278. 

  278.   assign input_ack = s_input_ack;
    279. 

  279.   assign output_z_stb = s_output_z_stb;
    280. 

  280.   assign output_z = s_output_z;
    281. 

  281. 

  282. endmodule
    283.