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[/] [xulalx25soc/] [trunk/] [rtl/] [wbucompress.v] - Rev 45
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//////////////////////////////////////////////////////////////////////////////// // // Filename: wbucompress.v // // Project: XuLA2 board // // Purpose: When reading many words that are identical, it makes no sense // to spend the time transmitting the same thing over and over // again, especially on a slow channel. Hence this routine uses a table // lookup to see if the word to be transmitted was one from the recent // past. If so, the word is replaced with an address of the recently // transmitted word. Mind you, the table lookup takes one clock per table // entry, so even if a word is in the table it might not be found in time. // If the word is not in the table, or if it isn't found due to a lack of // time, the word is placed into the table while incrementing every other // table address. // // Oh, and on a new address--the table is reset and starts over. This way, // any time the host software changes, the host software will always start // by issuing a new address--hence the table is reset for every new piece // of software that may wish to communicate. // // // Creator: Dan Gisselquist, Ph.D. // Gisselquist Technology, LLC // //////////////////////////////////////////////////////////////////////////////// // // Copyright (C) 2015, Gisselquist Technology, LLC // // This program is free software (firmware): you can redistribute it and/or // modify it under the terms of the GNU General Public License as published // by the Free Software Foundation, either version 3 of the License, or (at // your option) any later version. // // This program is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // License: GPL, v3, as defined and found on www.gnu.org, // http://www.gnu.org/licenses/gpl.html // // //////////////////////////////////////////////////////////////////////////////// // // // All input words are valid codewords. If we can, we make them // better here. module wbucompress(i_clk, i_stb, i_codword, o_stb, o_cword, i_busy); parameter DW=32, CW=36, TBITS=10; input i_clk, i_stb; input [(CW-1):0] i_codword; output wire o_stb; output wire [(CW-1):0] o_cword; input i_busy; // // // First stage is to compress the address. // This stage requires one clock. // // ISTB,ICODWORD // ISTB2,IWRD2 ASTB,AWORD // ISTB3,IWRD3 ASTB2,AWRD2 I_BUSY(1) // ISTB3,IWRD3 ASTB2,AWRD2 I_BUSY(1) // ISTB3,IWRD3 ASTB2,AWRD2 I_BUSY(1) // ISTB3,IWRD3 ASTB2,AWRD2 // ISTB4,IWRD4 ASTB3,AWRD3 I_BUSY(2) // ISTB4,IWRD4 ASTB3,AWRD3 I_BUSY(2) // ISTB4,IWRD4 ASTB3,AWRD3 I_BUSY(2) reg a_stb; reg [35:0] a_addrword; wire [31:0] w_addr; assign w_addr = i_codword[31:0]; always @(posedge i_clk) if ((i_stb)&&(~a_stb)) begin if (i_codword[35:32] != 4'h2) begin a_addrword <= i_codword; end else if (w_addr[31:6] == 26'h00) a_addrword <= { 6'hc, w_addr[ 5:0], 24'h00 }; else if (w_addr[31:12] == 20'h00) a_addrword <= { 6'hd, w_addr[11:0], 18'h00 }; else if (w_addr[31:18] == 14'h00) a_addrword <= { 6'he, w_addr[17:0], 12'h00 }; else if (w_addr[31:24] == 8'h00) a_addrword <= { 6'hf, w_addr[23:0], 6'h00 }; else begin a_addrword <= i_codword; end end initial a_stb = 1'b0; always @(posedge i_clk) if ((i_stb)&&(~a_stb)) a_stb <= i_stb; else if (~i_busy) a_stb <= 1'b0; // // // The next stage attempts to replace data codewords with previous // codewords that may have been sent. The memory is only allowed // to be as old as the last new address command. In this fashion, // any program that wishes to talk to the device can start with a // known compression table by simply setting the address and then // reading from the device. // // We start over any time a new value shows up, and // the follow-on isn't busy and can take it. Likewise, // we reset the writer on the compression any time a // i_clr value comes through (i.e., ~i_cyc or new // address) wire w_accepted; assign w_accepted = (a_stb)&&(~i_busy); reg r_stb; always @(posedge i_clk) r_stb <= a_stb; wire [35:0] r_word; assign r_word = a_addrword; // // First step of the compression is keeping track of a compression // table. And the first part of that is keeping track of what address // to write into the compression table, and whether or not the entire // table is full or not. This logic follows: // reg [(TBITS-1):0] tbl_addr; reg r_compressed, tbl_filled; // First part, write the compression table always @(posedge i_clk) // If we send a new address, then reset the table to empty if (w_accepted) begin // Reset on new address (0010xx) and on new compressed // addresses (0011ll). if (o_cword[35:33]==3'h1) tbl_addr <= 0; // Otherwise, on any valid return result that wasn't // from our table, for whatever reason (such as didn't // have the clocks to find it, etc.), increment the // address to add another value into our table else if (o_cword[35:33] == 3'b111) tbl_addr <= tbl_addr + {{(TBITS-1){1'b0}},1'b1}; end always @(posedge i_clk) if ((w_accepted)&&(o_cword[35:33]==3'h1)) // on new address tbl_filled <= 1'b0; else if (tbl_addr == 10'h3ff) tbl_filled <= 1'b1; // Now that we know where we are writing into the table, and what // values of the table are valid, we need to actually write into // the table. // // We can keep this logic really simple by writing on every clock // and writing junk on many of those clocks, but we'll need to remember // that the value of the table at tbl_addr is unreliable until tbl_addr // changes. // reg [31:0] compression_tbl [0:((1<<TBITS)-1)]; // Write new values into the table always @(posedge i_clk) compression_tbl[tbl_addr] <= { r_word[32:31], r_word[29:0] }; // Now that we have a working table, can we use it? // On any new word, we'll start looking through our codewords. // If we find any that matches, we're there. We might (or might not) // make it through the table first. That's irrelevant. We just look // while we can. reg [(TBITS-1):0] rd_addr; wire [(TBITS-1):0] nxt_rd_addr; assign nxt_rd_addr = rd_addr - { {(TBITS-1){1'b0}}, 1'b1 }; initial rd_addr = 0; always @(posedge i_clk) if ((w_accepted)||(~a_stb)) // Keep in mind, if a write was just accepted, then // rd_addr will need to be reset on the next clock // when (~a_stb). Hence this must be a two clock // update rd_addr <= tbl_addr + {(TBITS){1'b1}}; else if ((nxt_rd_addr != tbl_addr)&&(~match) &&((~nxt_rd_addr[TBITS-1])||(tbl_filled))) rd_addr <= nxt_rd_addr; reg [(DW-1):0] cword; reg [(TBITS-1):0] caddr; always @(posedge i_clk) begin cword <= compression_tbl[rd_addr]; caddr <= rd_addr; end reg match; reg [9:0] matchaddr; always @(posedge i_clk) if((w_accepted)||(~a_stb)||(~r_stb))// Reset upon any write match <= 1'b0; else if (~match) begin // To be a match, the table must not be empty, match <= (({1'b0, caddr } < {tbl_filled, tbl_addr})) // the word we are matching to must be // in the form of a read command &&(r_word[35:33] == 3'b111) // And the word in the table must be // identical to the word we are about // to send. &&(cword == { r_word[32:31], r_word[29:0] }); matchaddr <= tbl_addr-caddr; end // Did we find something? wire [(TBITS-1):0] adr_diff; wire [9:0] adr_dbld; wire [2:0] adr_hlfd; assign adr_diff = matchaddr; assign adr_hlfd = matchaddr[2:0]- 3'd2; assign adr_dbld = matchaddr- 10'd10; initial r_compressed = 1'b0; reg [(CW-1):0] r_cword; // Record our result always @(posedge i_clk) begin if ((~a_stb)||(~r_stb)||(w_accepted))//Reset whenever word gets written r_compressed <= 1'b0; // to our output else if (r_compressed)//Already compressed, wait 'til sent ; else if ((match)&&(matchaddr < 10'd521)) // &&(r_word == a_addrword)) begin if (matchaddr == 10'h1) r_cword[35:30] <= { 5'h3, r_word[30] }; else if (adr_diff < 10'd10) r_cword[35:30] <= { 2'b10, adr_hlfd, r_word[30] }; else // if (adr_diff < 10'd521) r_cword[35:24] <= { 2'b01, adr_dbld[8:6], r_word[30], adr_dbld[5:0] }; r_compressed <= 1'b1; end else r_cword <= r_word; end // Can we do this without a clock delay? assign o_stb = a_stb; assign o_cword = (r_compressed)?(r_cword):(a_addrword); endmodule
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