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// // Xilinx VHDL ROM generator // // Version : 0244 // // Copyright (c) 2001-2002 Daniel Wallner (jesus@opencores.org) // // All rights reserved // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // // Neither the name of the author nor the names of other contributors may // be used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, // THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR // PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE // POSSIBILITY OF SUCH DAMAGE. // // Please report bugs to the author, but before you do so, please // make sure that this is not a derivative work and that // you have the latest version of this file. // // The latest version of this file can be found at: // http://www.opencores.org/cvsweb.shtml/t51/ // // Limitations : // Not all address/data widths produce working code // Requires stl to compile // // File history : // // 0220 : Initial release // // 0221 : Fixed block ROMs with partial bytes // // 0241 : Updated for WebPack 5.1 // // 0244 : Added -n option and component declaration // #include <stdio.h> #include <string> #include <vector> #include <iostream> using namespace std; #if !(defined(max)) && _MSC_VER // VC fix #define max __max #endif int main (int argc, char *argv[]) { cerr << "Xilinx VHDL ROM generator by Daniel Wallner. Version 0244\n"; try { unsigned long aWidth; unsigned long dWidth; unsigned long select = 0; unsigned long length = 0; char z = 0; if (argc < 4) { cerr << "\nUsage: xrom <entity name> <address bits> <data bits> <options>\n"; cerr << "\nThe options can be:\n"; cerr << " -[decimal number] = SelectRAM usage in 1/16 parts\n"; cerr << " -z = use tri-state buses\n"; cerr << " -n [decimal size] = limit rom size\n"; cerr << "\nExample:\n"; cerr << " xrom Test_ROM 13 8 -6\n\n"; return -1; } int result; result = sscanf(argv[2], "%lu", &aWidth); if (result < 1) { throw "Error in address bits argument!\n"; } result = sscanf(argv[3], "%lu", &dWidth); if (result < 1) { throw "Error in data bits argument!\n"; } int argument = 4; while (argument < argc) { char tmpC = 0; unsigned long tmpL = 0; result = sscanf(argv[argument], "%c%lu", &tmpC, &tmpL); if (result < 1 || tmpC != '-' ) { throw "Error in options!\n"; } if (result < 2) { sscanf(argv[argument], "%c%c", &tmpC, &tmpC); if (tmpC != 'z' && tmpC != 'n') { throw "Unkown option!\n"; } if (tmpC == 'z') { z = tmpC; } else { argument++; if (argument == argc) { throw "No memory size argument!\n"; } result = sscanf(argv[argument], "%lu", &tmpL); if (!result) { throw "Memory size not a number!\n"; } length = tmpL; } } else { select = tmpL; } argument++; } unsigned long selectIter = 0; unsigned long blockIter = 0; unsigned long bytes = (dWidth + 7) / 8; if (!select) { blockIter = ((1UL << aWidth) + 511) / 512; if (length && length < blockIter * 512) { blockIter = (length + 511) / 512; } } else if (select == 16) { selectIter = ((1UL << aWidth) + 15) / 16; if (length && length < selectIter * 16) { selectIter = (length + 15) / 16; } } else { blockIter = ((1UL << aWidth) * (16 - select) / 16 + 511) / 512; selectIter = ((1UL << aWidth) - blockIter * 512 + 15) / 16; } unsigned long blockTotal = ((1UL << aWidth) + 511) / 512; if (length && length < blockTotal * 512) { blockTotal = (length + 511) / 512; } if (length) { if (length > selectIter * 16) { blockIter -= ((1UL << aWidth) + 511) / 512 - blockTotal; } else { blockIter = 0; } } if (length && !blockIter && length < selectIter * 16) { selectIter = (length + 15) / 16; } cerr << "Creating ROM with " << selectIter * bytes; cerr << " RAM16X1S and " << blockIter * bytes << " RAMB4_S8\n"; printf("-- This file was generated with xrom written by Daniel Wallner\n"); printf("\nlibrary IEEE;"); printf("\nuse IEEE.std_logic_1164.all;"); printf("\nuse IEEE.numeric_std.all;"); printf("\n\nentity %s is", argv[1]); printf("\n\tport("); printf("\n\t\tClk\t: in std_logic;"); printf("\n\t\tA\t: in std_logic_vector(%d downto 0);", aWidth - 1); printf("\n\t\tD\t: out std_logic_vector(%d downto 0)", dWidth - 1); printf("\n\t);"); printf("\nend %s;", argv[1]); printf("\n\narchitecture rtl of %s is", argv[1]); if (selectIter) { printf("\n\tcomponent RAM16X1S"); printf("\n\t\tport("); printf("\n\t\t\tO : out std_ulogic;"); printf("\n\t\t\tA0 : in std_ulogic;"); printf("\n\t\t\tA1 : in std_ulogic;"); printf("\n\t\t\tA2 : in std_ulogic;"); printf("\n\t\t\tA3 : in std_ulogic;"); printf("\n\t\t\tD : in std_ulogic;"); printf("\n\t\t\tWCLK : in std_ulogic;"); printf("\n\t\t\tWE : in std_ulogic);"); printf("\n\tend component;\n"); } if (blockIter) { printf("\n\tcomponent RAMB4_S8"); printf("\n\t\tport("); printf("\n\t\t\tDO : out std_logic_vector(7 downto 0);"); printf("\n\t\t\tADDR : in std_logic_vector(8 downto 0);"); printf("\n\t\t\tCLK : in std_ulogic;"); printf("\n\t\t\tDI : in std_logic_vector(7 downto 0);"); printf("\n\t\t\tEN : in std_ulogic;"); printf("\n\t\t\tRST : in std_ulogic;"); printf("\n\t\t\tWE : in std_ulogic);"); printf("\n\tend component;\n"); } if (selectIter > 0) { printf("\n\tsignal A_r: unsigned(A'range);"); } if (selectIter > 1) { printf("\n\ttype sRAMOut_a is array(0 to %d) of std_logic_vector(D'range);", selectIter - 1); printf("\n\tsignal sRAMOut : sRAMOut_a;"); printf("\n\tsignal siA_r : integer;"); } if (selectIter && blockIter) { printf("\n\tsignal sD : std_logic_vector(D'range);"); } if (blockIter == 1) { printf("\n\tsignal bRAMOut : std_logic_vector(%d downto 0);", bytes * 8 - 1); } if (blockIter > 1) { printf("\n\ttype bRAMOut_a is array(%d to %d) of std_logic_vector(%d downto 0);", blockTotal - blockIter, blockTotal - 1, bytes * 8 - 1); printf("\n\tsignal bRAMOut : bRAMOut_a;"); printf("\n\tsignal biA_r : integer;"); if (!selectIter) { printf("\n\tsignal A_r : unsigned(A'left downto 9);"); } } if (selectIter && blockIter) { printf("\n\tsignal bD : std_logic_vector(D'range);"); } printf("\nbegin"); if (selectIter > 0 || blockIter > 1) { printf("\n\tprocess (Clk)"); printf("\n\tbegin"); printf("\n\t\tif Clk'event and Clk = '1' then"); if (!selectIter) { printf("\n\t\t\tA_r <= unsigned(A(A'left downto 9));"); } else { printf("\n\t\t\tA_r <= unsigned(A);"); } printf("\n\t\tend if;"); printf("\n\tend process;"); } if (selectIter == 1) { printf("\n\n\tsG1: for I in 0 to %d generate", dWidth - 1); printf("\n\t\tS%s : RAM16X1S\n\t\t\tport map (", argv[1]); if (blockIter) { printf("s"); } printf("WE => '0', WCLK => '0', D => '0', O => D(I), A0 => A_r(0), A1 => A_r(1), A2 => A_r(2), A3 => A_r(3));"); printf("\n\tend generate;"); } if (selectIter > 1) { printf("\n\n\tsiA_r <= to_integer(A_r(A'left downto 4));"); printf("\n\n\tsG1: for I in 0 to %d generate", selectIter - 1); printf("\n\t\tsG2: for J in 0 to %d generate", dWidth - 1); printf("\n\t\t\tS%s : RAM16X1S\n\t\t\t\tport map (WE => '0', WCLK => '0', D => '0', O => sRAMOut(I)(J), A0 => A_r(0), A1 => A_r(1), A2 => A_r(2), A3 => A_r(3));", argv[1]); printf("\n\t\tend generate;"); if (z == 'z') { printf("\n\t\t"); if (blockIter) { printf("s"); } printf("D <= sRAMOut(I) when siA_r = I else (others => 'Z');"); } printf("\n\tend generate;"); if (z != 'z') { printf("\n\n\tprocess (siA_r, sRAMOut)\n\tbegin\n\t\t"); if (blockIter) { printf("s"); } printf("D <= sRAMOut(0);"); printf("\n\t\tfor I in 1 to %d loop", selectIter - 1); printf("\n\t\t\tif siA_r = I then\n\t\t\t\t"); if (blockIter) { printf("s"); } printf("D <= sRAMOut(I);\n\t\t\tend if;"); printf("\n\t\tend loop;\n\tend process;"); } } if (blockIter == 1) { printf("\n\n\tbG1: for J in 0 to %d generate", bytes - 1); printf("\n\t\tB%s : RAMB4_S8", argv[1]); printf("\n\t\t\tport map (DI => \"00000000\", EN => '1', RST => '0', WE => '0', CLK => Clk, ADDR => A(8 downto 0), DO => bRAMOut(7 + 8 * J downto 8 * J));", argv[1]); printf("\n\tend generate;"); printf("\n\n\t"); if (selectIter) { printf("b"); } printf("D <= bRAMOut(D'range);"); } if (blockIter > 1) { printf("\n\n\tbiA_r <= to_integer(A_r(A'left downto 9));"); printf("\n\n\tbG1: for I in %d to %d generate", blockTotal - blockIter, blockTotal - 1); printf("\n\t\tbG2: for J in 0 to %d generate", bytes - 1); printf("\n\t\t\tB%s : RAMB4_S8\n\t\t\t\tport map (DI => \"00000000\", EN => '1', RST => '0', WE => '0', CLK => Clk, ADDR => A(8 downto 0), DO => bRAMOut(I)(7 + 8 * J downto 8 * J));", argv[1]); printf("\n\t\tend generate;"); if (z == 'z') { printf("\n\t\t"); if (selectIter) { printf("b"); } printf("D <= bRAMOut(I) when biA_r = I else (others => 'Z');"); } printf("\n\tend generate;"); if (z != 'z') { printf("\n\n\tprocess (biA_r, bRAMOut)\n\tbegin\n\t\t"); if (selectIter) { printf("b"); } printf("D <= bRAMOut(%d)(D'range);", blockTotal - blockIter); printf("\n\t\tfor I in %d to %d loop", blockTotal - blockIter + 1, blockTotal - 1); printf("\n\t\t\tif biA_r = I then\n\t\t\t\t"); if (selectIter) { printf("b"); } printf("D <= bRAMOut(I)(D'range);\n\t\t\tend if;"); printf("\n\t\tend loop;\n\tend process;"); } } if (selectIter && blockIter) { printf("\n\n\tD <= bD when A_r(A'left downto 9) >= %d else sD;", blockTotal - blockIter); } printf("\nend;\n"); return 0; } catch (string error) { cerr << "Fatal: " << error; } catch (const char *error) { cerr << "Fatal: " << error; } return -1; }