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[/] [zipcpu/] [trunk/] [rtl/] [aux/] [wbdblpriarb.v] - Rev 152
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/////////////////////////////////////////////////////////////////////////// // // Filename: wbdblpriarb.v // // Project: Zip CPU -- a small, lightweight, RISC CPU soft core // // Purpose: This should almost be identical to the priority arbiter, save // for a simple diffence: it allows the arbitration of two // separate wishbone buses. The purpose of this is to push the address // resolution back one cycle, so that by the first clock visible to this // core, it is known which of two parts of the bus the desired address // will be on, save that we still use the arbiter since the underlying // device doesn't know that there are two wishbone buses. // // So at this point we've deviated from the WB spec somewhat, by allowing // two CYC and two STB lines. Everything else is the same. This allows // (in this case the Zip CPU) to determine whether or not the access // will be to the local ZipSystem bus or the external WB bus on the clock // before the local bus access, otherwise peripherals were needing to do // multiple device selection comparisons/test within a clock: 1) is this // for the local or external bus, and 2) is this referencing me as a // peripheral. This then caused the ZipCPU to fail all timing specs. // By creating the two pairs of lines, CYC_A/STB_A and CYC_B/STB_B, the // determination of local vs external can be made one clock earlier // where there's still time for the logic, and the second comparison // now has time to complete. // // So let me try to explain this again. To use this arbiter, one of the // two masters sets CYC and STB before, only the master determines which // of two address spaces the CYC and STB apply to before the clock and // only sets the appropriate CYC and STB lines. Then, on the clock tick, // the arbiter determines who gets *both* busses, as they both share every // other WB line. Thus, only one of CYC_A and CYC_B going out will ever // be high at a given time. // // Hopefully this makes more sense than it sounds. If not, check out the // code below for a better explanation. // // 20150919 -- Added supported for the WB error signal. // // // 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 // // /////////////////////////////////////////////////////////////////////////// // module wbdblpriarb(i_clk, i_rst, // Bus A i_a_cyc_a,i_a_cyc_b,i_a_stb_a,i_a_stb_b,i_a_we,i_a_adr, i_a_dat, o_a_ack, o_a_stall, o_a_err, // Bus B i_b_cyc_a,i_b_cyc_b,i_b_stb_a,i_b_stb_b,i_b_we,i_b_adr, i_b_dat, o_b_ack, o_b_stall, o_b_err, // Both buses o_cyc_a, o_cyc_b, o_stb_a, o_stb_b, o_we, o_adr, o_dat, i_ack, i_stall, i_err); parameter DW=32, AW=32; // Wishbone doesn't use an i_ce signal. While it could, they dislike // what it would (might) do to the synchronous reset signal, i_rst. input i_clk, i_rst; // Bus A input i_a_cyc_a, i_a_cyc_b, i_a_stb_a, i_a_stb_b, i_a_we; input [(AW-1):0] i_a_adr; input [(DW-1):0] i_a_dat; output wire o_a_ack, o_a_stall, o_a_err; // Bus B input i_b_cyc_a, i_b_cyc_b, i_b_stb_a, i_b_stb_b, i_b_we; input [(AW-1):0] i_b_adr; input [(DW-1):0] i_b_dat; output wire o_b_ack, o_b_stall, o_b_err; // output wire o_cyc_a,o_cyc_b, o_stb_a, o_stb_b, o_we; output wire [(AW-1):0] o_adr; output wire [(DW-1):0] o_dat; input i_ack, i_stall, i_err; // All of our logic is really captured in the 'r_a_owner' register. // This register determines who owns the bus. If no one is requesting // the bus, ownership goes to A on the next clock. Otherwise, if B is // requesting the bus and A is not, then ownership goes to not A on // the next clock. (Sounds simple ...) // // The CYC logic is here to make certain that, by the time we determine // who the bus owner is, we can do so based upon determined criteria. assign o_cyc_a = (~i_rst)&&((r_a_owner) ? i_a_cyc_a : i_b_cyc_a); assign o_cyc_b = (~i_rst)&&((r_a_owner) ? i_a_cyc_b : i_b_cyc_b); reg r_a_owner; initial r_a_owner = 1'b1; always @(posedge i_clk) if (i_rst) r_a_owner <= 1'b1; else if ((~o_cyc_a)&&(~o_cyc_b)) r_a_owner <= ((i_b_cyc_a)||(i_b_cyc_b))? 1'b0:1'b1; // Realistically, if neither master owns the bus, the output is a // don't care. Thus we trigger off whether or not 'A' owns the bus. // If 'B' owns it all we care is that 'A' does not. Likewise, if // neither owns the bus than the values on these various lines are // irrelevant. assign o_stb_a = (r_a_owner) ? i_a_stb_a : i_b_stb_a; assign o_stb_b = (r_a_owner) ? i_a_stb_b : i_b_stb_b; assign o_we = (r_a_owner) ? i_a_we : i_b_we; assign o_adr = (r_a_owner) ? i_a_adr : i_b_adr; assign o_dat = (r_a_owner) ? i_a_dat : i_b_dat; // We cannot allow the return acknowledgement to ever go high if // the master in question does not own the bus. Hence we force it // low if the particular master doesn't own the bus. assign o_a_ack = ( r_a_owner) ? i_ack : 1'b0; assign o_b_ack = (~r_a_owner) ? i_ack : 1'b0; // Stall must be asserted on the same cycle the input master asserts // the bus, if the bus isn't granted to him. assign o_a_stall = ( r_a_owner) ? i_stall : 1'b1; assign o_b_stall = (~r_a_owner) ? i_stall : 1'b1; // // These error lines will be implemented soon, as soon as the rest of // the Zip CPU is ready to support them. // assign o_a_err = ( r_a_owner) ? i_err : 1'b0; assign o_b_err = (~r_a_owner) ? i_err : 1'b0; endmodule
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