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axilxbar.v
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axilxbar.v
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////////////////////////////////////////////////////////////////////////////////
//
// Filename: axilxbar.v
// {{{
// Project: WB2AXIPSP: bus bridges and other odds and ends
//
// Purpose: Create a full crossbar between NM AXI-lite sources (masters),
// and NS AXI-lite slaves. Every master can talk to any slave,
// provided it isn't already busy.
//
// Performance: This core has been designed with the goal of being able to push
// one transaction through the interconnect, from any master to
// any slave, per clock cycle. This may perhaps be its most unique
// feature. While throughput is good, latency is something else.
//
// The arbiter requires a clock to switch, then another clock to send data
// downstream. This creates a minimum two clock latency up front. The
// return path suffers another clock of latency as well, placing the
// minimum latency at four clocks. The minimum write latency is at
// least one clock longer, since the write data must wait for the write
// address before proceeeding.
//
// Usage: To use, you must first set NM and NS to the number of masters
// and the number of slaves you wish to connect to. You then need to
// adjust the addresses of the slaves, found SLAVE_ADDR array. Those
// bits that are relevant in SLAVE_ADDR to then also be set in SLAVE_MASK.
// Adjusting the data and address widths go without saying.
//
// Lower numbered masters are given priority in any "fight".
//
// Channel grants are given on the condition that 1) they are requested,
// 2) no other channel has a grant, 3) all of the responses have been
// received from the current channel, and 4) the internal counters are
// not overflowing.
//
// The core limits the number of outstanding transactions on any channel to
// 1<<LGMAXBURST-1.
//
// Channel grants are lost 1) after OPT_LINGER clocks of being idle, or
// 2) when another master requests an idle (but still lingering) channel
// assignment, or 3) once all the responses have been returned to the
// current channel, and the current master is requesting another channel.
//
// A special slave is allocated for the case of no valid address.
//
// Since the write channel has no address information, the write data
// channel always be delayed by at least one clock from the write address
// channel.
//
// If OPT_LOWPOWER is set, then unused values will be set to zero.
// This can also be used to help identify relevant values within any
// trace.
//
//
// Creator: Dan Gisselquist, Ph.D.
// Gisselquist Technology, LLC
//
////////////////////////////////////////////////////////////////////////////////
// }}}
// Copyright (C) 2019-2021, Gisselquist Technology, LLC
// {{{
// This file is part of the WB2AXIP project.
//
// The WB2AXIP project contains free software and gateware, licensed under the
// Apache License, Version 2.0 (the "License"). You may not use this project,
// or this file, except in compliance with the License. You may obtain a copy
// of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations
// under the License.
//
////////////////////////////////////////////////////////////////////////////////
//
//
`default_nettype none
// }}}
module axilxbar #(
// {{{
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_ADDR_WIDTH = 32,
//
// NM is the number of master interfaces this core supports
parameter NM = 4,
//
// NS is the number of slave interfaces
parameter NS = 8,
//
// AW, and DW, are short-hand abbreviations used locally.
localparam AW = C_AXI_ADDR_WIDTH,
localparam DW = C_AXI_DATA_WIDTH,
// SLAVE_ADDR is a bit vector containing AW bits for each of the
// slaves indicating the base address of the slave. This
// goes with SLAVE_MASK below.
parameter [NS*AW-1:0] SLAVE_ADDR = {
3'b111, {(AW-3){1'b0}},
3'b110, {(AW-3){1'b0}},
3'b101, {(AW-3){1'b0}},
3'b100, {(AW-3){1'b0}},
3'b011, {(AW-3){1'b0}},
3'b010, {(AW-3){1'b0}},
4'b0001, {(AW-4){1'b0}},
4'b0000, {(AW-4){1'b0}} },
//
// SLAVE_MASK indicates which bits in the SLAVE_ADDR bit vector
// need to be checked to determine if a given address request
// maps to the given slave or not
// Verilator lint_off WIDTH
parameter [NS*AW-1:0] SLAVE_MASK =
(NS <= 1) ? { 4'b1111, {(AW-4){1'b0}} }
: { {(NS-2){ 3'b111, {(AW-3){1'b0}} }},
{(2){ 4'b1111, {(AW-4){1'b0}} }} },
// Verilator lint_on WIDTH
//
// If set, OPT_LOWPOWER will set all unused registers, both
// internal and external, to zero anytime their corresponding
// *VALID bit is clear
parameter [0:0] OPT_LOWPOWER = 1,
//
// OPT_LINGER is the number of cycles to wait, following a
// transaction, before tearing down the bus grant.
parameter OPT_LINGER = 4,
//
// LGMAXBURST is the log (base two) of the maximum number of
// requests that can be outstanding on any given channel at any
// given time. It is used within this core to control the
// counters that are used to determine if a particular channel
// grant must stay open, or if it may be closed.
parameter LGMAXBURST = 5
// }}}
) (
// {{{
input wire S_AXI_ACLK,
input wire S_AXI_ARESETN,
// Incoming AXI4-lite slave port(s)
// {{{
input wire [NM*C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [NM*3-1:0] S_AXI_AWPROT,
input wire [NM-1:0] S_AXI_AWVALID,
output wire [NM-1:0] S_AXI_AWREADY,
//
input wire [NM*C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA,
input wire [NM*C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB,
input wire [NM-1:0] S_AXI_WVALID,
output wire [NM-1:0] S_AXI_WREADY,
//
output wire [NM*2-1:0] S_AXI_BRESP,
output wire [NM-1:0] S_AXI_BVALID,
input wire [NM-1:0] S_AXI_BREADY,
//
input wire [NM*C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR,
input wire [NM*3-1:0] S_AXI_ARPROT,
input wire [NM-1:0] S_AXI_ARVALID,
output wire [NM-1:0] S_AXI_ARREADY,
//
output wire [NM*C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA,
output wire [NM*2-1:0] S_AXI_RRESP,
output wire [NM-1:0] S_AXI_RVALID,
input wire [NM-1:0] S_AXI_RREADY,
// }}}
// Outgoing AXI4-lite master port(s)
// {{{
output wire [NS*C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [NS*3-1:0] M_AXI_AWPROT,
output wire [NS-1:0] M_AXI_AWVALID,
input wire [NS-1:0] M_AXI_AWREADY,
//
output wire [NS*C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA,
output wire [NS*C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB,
output wire [NS-1:0] M_AXI_WVALID,
input wire [NS-1:0] M_AXI_WREADY,
//
input wire [NS*2-1:0] M_AXI_BRESP,
input wire [NS-1:0] M_AXI_BVALID,
output wire [NS-1:0] M_AXI_BREADY,
//
output wire [NS*C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR,
output wire [NS*3-1:0] M_AXI_ARPROT,
output wire [NS-1:0] M_AXI_ARVALID,
input wire [NS-1:0] M_AXI_ARREADY,
//
input wire [NS*C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA,
input wire [NS*2-1:0] M_AXI_RRESP,
input wire [NS-1:0] M_AXI_RVALID,
output wire [NS-1:0] M_AXI_RREADY
// }}}
// }}}
);
//
// Local parameters, derived from those above
// {{{
localparam LGLINGER = (OPT_LINGER>1) ? $clog2(OPT_LINGER+1) : 1;
//
localparam LGNM = (NM>1) ? $clog2(NM) : 1;
localparam LGNS = (NS>1) ? $clog2(NS+1) : 1;
//
// In order to use indexes, and hence fully balanced mux trees, it helps
// to make certain that we have a power of two based lookup. NMFULL
// is the number of masters in this lookup, with potentially some
// unused extra ones. NSFULL is defined similarly.
localparam NMFULL = (NM>1) ? (1<<LGNM) : 1;
localparam NSFULL = (NS>1) ? (1<<LGNS) : 2;
//
localparam [1:0] INTERCONNECT_ERROR = 2'b11;
localparam [0:0] OPT_SKID_INPUT = 0;
localparam [0:0] OPT_BUFFER_DECODER = 1;
genvar N,M;
integer iN, iM;
// }}}
// {{{
reg [NSFULL-1:0] wrequest [0:NM-1];
reg [NSFULL-1:0] rrequest [0:NM-1];
reg [NSFULL-1:0] wrequested [0:NM];
reg [NSFULL-1:0] rrequested [0:NM];
reg [NS:0] wgrant [0:NM-1];
reg [NS:0] rgrant [0:NM-1];
reg [NM-1:0] swgrant;
reg [NM-1:0] srgrant;
reg [NS-1:0] mwgrant;
reg [NS-1:0] mrgrant;
// verilator lint_off UNUSED
wire [LGMAXBURST-1:0] w_sawpending [0:NM-1];
wire [LGMAXBURST-1:0] w_swpending [0:NM-1];
wire [LGMAXBURST-1:0] w_srpending [0:NM-1];
// verilator lint_on UNUSED
reg [NM-1:0] swfull;
reg [NM-1:0] srfull;
reg [NM-1:0] swempty;
reg [NM-1:0] srempty;
//
wire [LGNS-1:0] swindex [0:NMFULL-1];
wire [LGNS-1:0] srindex [0:NMFULL-1];
wire [LGNM-1:0] mwindex [0:NSFULL-1];
wire [LGNM-1:0] mrindex [0:NSFULL-1];
wire [NM-1:0] wdata_expected;
// The shadow buffers
wire [NMFULL-1:0] m_awvalid, m_wvalid, m_arvalid;
wire [NM-1:0] dcd_awvalid, dcd_arvalid;
wire [C_AXI_ADDR_WIDTH-1:0] m_awaddr [0:NMFULL-1];
wire [2:0] m_awprot [0:NMFULL-1];
wire [C_AXI_DATA_WIDTH-1:0] m_wdata [0:NMFULL-1];
wire [C_AXI_DATA_WIDTH/8-1:0] m_wstrb [0:NMFULL-1];
wire [C_AXI_ADDR_WIDTH-1:0] m_araddr [0:NMFULL-1];
wire [2:0] m_arprot [0:NMFULL-1];
//
wire [NM-1:0] skd_awvalid, skd_awstall, skd_wvalid;
wire [NM-1:0] skd_arvalid, skd_arstall;
wire [AW-1:0] skd_awaddr [0:NM-1];
wire [3-1:0] skd_awprot [0:NM-1];
wire [AW-1:0] skd_araddr [0:NM-1];
wire [3-1:0] skd_arprot [0:NM-1];
reg r_bvalid [0:NM-1];
reg [1:0] r_bresp [0:NM-1];
reg [NSFULL-1:0] m_axi_awvalid;
reg [NSFULL-1:0] m_axi_awready;
reg [NSFULL-1:0] m_axi_wvalid;
reg [NSFULL-1:0] m_axi_wready;
reg [NSFULL-1:0] m_axi_bvalid;
`ifdef FORMAL
reg [NSFULL-1:0] m_axi_bready;
`endif
reg [1:0] m_axi_bresp [0:NSFULL-1];
reg [NSFULL-1:0] m_axi_arvalid;
// Verilator lint_off UNUSED
reg [NSFULL-1:0] m_axi_arready;
// Verilator lint_on UNUSED
reg [NSFULL-1:0] m_axi_rvalid;
// Verilator lint_off UNUSED
reg [NSFULL-1:0] m_axi_rready;
// Verilator lint_on UNUSED
reg r_rvalid [0:NM-1];
reg [1:0] r_rresp [0:NM-1];
reg [DW-1:0] r_rdata [0:NM-1];
reg [DW-1:0] m_axi_rdata [0:NSFULL-1];
reg [1:0] m_axi_rresp [0:NSFULL-1];
reg [NM-1:0] slave_awaccepts;
reg [NM-1:0] slave_waccepts;
reg [NM-1:0] slave_raccepts;
// }}}
// m_axi_[aw|w|b]*
// {{{
always @(*)
begin
m_axi_awvalid = -1;
m_axi_awready = -1;
m_axi_wvalid = -1;
m_axi_wready = -1;
m_axi_bvalid = 0;
m_axi_awvalid[NS-1:0] = M_AXI_AWVALID;
m_axi_awready[NS-1:0] = M_AXI_AWREADY;
m_axi_wvalid[NS-1:0] = M_AXI_WVALID;
m_axi_wready[NS-1:0] = M_AXI_WREADY;
m_axi_bvalid[NS-1:0] = M_AXI_BVALID;
for(iM=0; iM<NS; iM=iM+1)
begin
m_axi_bresp[iM] = M_AXI_BRESP[iM* 2 +: 2];
m_axi_rdata[iM] = M_AXI_RDATA[iM*DW +: DW];
m_axi_rresp[iM] = M_AXI_RRESP[iM* 2 +: 2];
end
for(iM=NS; iM<NSFULL; iM=iM+1)
begin
m_axi_bresp[iM] = INTERCONNECT_ERROR;
m_axi_rdata[iM] = 0;
m_axi_rresp[iM] = INTERCONNECT_ERROR;
end
`ifdef FORMAL
m_axi_bready = -1;
m_axi_bready[NS-1:0] = M_AXI_BREADY;
`endif
end
// }}}
generate for(N=0; N<NM; N=N+1)
begin : DECODE_WRITE_REQUEST
// {{{
wire [NS:0] wdecode;
// awskid
// {{{
skidbuffer #(
// {{{
.DW(AW+3), .OPT_OUTREG(OPT_SKID_INPUT)
) awskid(
// {{{
S_AXI_ACLK, !S_AXI_ARESETN,
S_AXI_AWVALID[N], S_AXI_AWREADY[N],
{ S_AXI_AWADDR[N*AW +: AW], S_AXI_AWPROT[N*3 +: 3] },
skd_awvalid[N], !skd_awstall[N],
{ skd_awaddr[N], skd_awprot[N] }
// }}}
);
// }}}
// write address decoding
// {{{
addrdecode #(
// {{{
.AW(AW), .DW(3), .NS(NS),
.SLAVE_ADDR(SLAVE_ADDR),
.SLAVE_MASK(SLAVE_MASK),
.OPT_REGISTERED(OPT_BUFFER_DECODER)
// }}}
) wraddr(
// {{{
.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_valid(skd_awvalid[N]), .o_stall(skd_awstall[N]),
.i_addr(skd_awaddr[N]), .i_data(skd_awprot[N]),
.o_valid(dcd_awvalid[N]),
.i_stall(!dcd_awvalid[N]||!slave_awaccepts[N]),
.o_decode(wdecode), .o_addr(m_awaddr[N]),
.o_data(m_awprot[N])
// }}}
);
// }}}
// wskid
// {{{
skidbuffer #(
// {{{
.DW(DW+DW/8), .OPT_OUTREG(OPT_SKID_INPUT)
) wskid
// {{{
(S_AXI_ACLK, !S_AXI_ARESETN,
S_AXI_WVALID[N], S_AXI_WREADY[N],
{ S_AXI_WDATA[N*DW +: DW], S_AXI_WSTRB[N*DW/8 +: DW/8]},
skd_wvalid[N], (m_wvalid[N] && slave_waccepts[N]),
{ m_wdata[N], m_wstrb[N] }
// }}}
);
// }}}
// slave_awaccepts
// {{{
always @(*)
begin
slave_awaccepts[N] = 1'b1;
if (!swgrant[N])
slave_awaccepts[N] = 1'b0;
if (swfull[N])
slave_awaccepts[N] = 1'b0;
if (!wrequest[N][swindex[N]])
slave_awaccepts[N] = 1'b0;
if (!wgrant[N][NS]&&(m_axi_awvalid[swindex[N]] && !m_axi_awready[swindex[N]]))
slave_awaccepts[N] = 1'b0;
// ERRORs are always accepted
// back pressure is handled in the write side
end
// }}}
// slave_waccepts
// {{{
always @(*)
begin
slave_waccepts[N] = 1'b1;
if (!swgrant[N])
slave_waccepts[N] = 1'b0;
if (!wdata_expected[N])
slave_waccepts[N] = 1'b0;
if (!wgrant[N][NS] &&(m_axi_wvalid[swindex[N]]
&& !m_axi_wready[swindex[N]]))
slave_waccepts[N] = 1'b0;
if (wgrant[N][NS]&&(S_AXI_BVALID[N]&& !S_AXI_BREADY[N]))
slave_waccepts[N] = 1'b0;
end
// }}}
// {{{
reg r_mawvalid, r_mwvalid;
always @(*)
begin
r_mawvalid= dcd_awvalid[N] && !swfull[N];
r_mwvalid = skd_wvalid[N];
wrequest[N]= 0;
if (!swfull[N])
wrequest[N][NS:0] = wdecode;
end
assign m_awvalid[N] = r_mawvalid;
assign m_wvalid[N] = r_mwvalid;
// }}}
// }}}
end for (N=NM; N<NMFULL; N=N+1)
begin : UNUSED_WSKID_BUFFERS
// {{{
assign m_awvalid[N] = 0;
assign m_awaddr[N] = 0;
assign m_awprot[N] = 0;
assign m_wdata[N] = 0;
assign m_wstrb[N] = 0;
// }}}
end endgenerate
generate for(N=0; N<NM; N=N+1)
begin : DECODE_READ_REQUEST
// {{{
wire [NS:0] rdecode;
// arskid
// {{{
skidbuffer #(
// {{{
.DW(AW+3), .OPT_OUTREG(OPT_SKID_INPUT)
) arskid(
// {{{
S_AXI_ACLK, !S_AXI_ARESETN,
S_AXI_ARVALID[N], S_AXI_ARREADY[N],
{ S_AXI_ARADDR[N*AW +: AW], S_AXI_ARPROT[N*3 +: 3] },
skd_arvalid[N], !skd_arstall[N],
{ skd_araddr[N], skd_arprot[N] }
// }}}
);
// }}}
// Read address decoding
// {{{
addrdecode #(
// {{{
.AW(AW), .DW(3), .NS(NS),
.SLAVE_ADDR(SLAVE_ADDR), .SLAVE_MASK(SLAVE_MASK),
.OPT_REGISTERED(OPT_BUFFER_DECODER)
// }}}
) rdaddr(
// {{{
.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_valid(skd_arvalid[N]), .o_stall(skd_arstall[N]),
.i_addr(skd_araddr[N]), .i_data(skd_arprot[N]),
.o_valid(dcd_arvalid[N]),
.i_stall(!m_arvalid[N] || !slave_raccepts[N]),
.o_decode(rdecode), .o_addr(m_araddr[N]),
.o_data(m_arprot[N])
// }}}
);
// }}}
// m_arvalid[N]
// {{{
reg r_marvalid;
always @(*)
begin
r_marvalid = dcd_arvalid[N] && !srfull[N];
rrequest[N] = 0;
if (!srfull[N])
rrequest[N][NS:0] = rdecode;
end
assign m_arvalid[N] = r_marvalid;
// }}}
// slave_raccepts
// {{{
always @(*)
begin
slave_raccepts[N] = 1'b1;
if (!srgrant[N])
slave_raccepts[N] = 1'b0;
if (srfull[N])
slave_raccepts[N] = 1'b0;
// verilator lint_off WIDTH
if (!rrequest[N][srindex[N]])
slave_raccepts[N] = 1'b0;
// verilator lint_on WIDTH
if (!rgrant[N][NS])
begin
if (m_axi_arvalid[srindex[N]] && !m_axi_arready[srindex[N]])
slave_raccepts[N] = 1'b0;
end else if (S_AXI_RVALID[N] && !S_AXI_RREADY[N])
slave_raccepts[N] = 1'b0;
end
// }}}
// }}}
end for (N=NM; N<NMFULL; N=N+1)
begin : UNUSED_RSKID_BUFFERS
// {{{
assign m_arvalid[N] = 0;
assign m_araddr[N] = 0;
assign m_arprot[N] = 0;
// }}}
end endgenerate
// wrequested
// {{{
always @(*)
begin : DECONFLICT_WRITE_REQUESTS
for(iN=1; iN<NM ; iN=iN+1)
wrequested[iN] = 0;
// Vivado may complain about too many bits for wrequested.
// This is (currrently) expected. swindex is used to index
// into wrequested, and swindex has LGNS bits, where LGNS
// is $clog2(NS+1) rather than $clog2(NS). The extra bits
// are defined to be zeros, but the point is there are defined.
// Therefore, no matter what swindex is, it will always
// reference something valid.
wrequested[NM] = 0;
for(iM=0; iM<NS; iM=iM+1)
begin
wrequested[0][iM] = 1'b0;
for(iN=1; iN<NM ; iN=iN+1)
begin
// Continue to request any channel with
// a grant and pending operations
if (wrequest[iN-1][iM] && wgrant[iN-1][iM])
wrequested[iN][iM] = 1;
if (wrequest[iN-1][iM] && (!swgrant[iN-1]||swempty[iN-1]))
wrequested[iN][iM] = 1;
// Otherwise, if it's already claimed, then
// it can't be claimed again
if (wrequested[iN-1][iM])
wrequested[iN][iM] = 1;
end
wrequested[NM][iM] = wrequest[NM-1][iM] || wrequested[NM-1][iM];
end
end
// }}}
// rrequested
// {{{
always @(*)
begin : DECONFLICT_READ_REQUESTS
for(iN=0; iN<NM ; iN=iN+1)
rrequested[iN] = 0;
// See the note above for wrequested. This applies to
// rrequested as well.
rrequested[NM] = 0;
for(iM=0; iM<NS; iM=iM+1)
begin
rrequested[0][iM] = 0;
for(iN=1; iN<NM ; iN=iN+1)
begin
// Continue to request any channel with
// a grant and pending operations
if (rrequest[iN-1][iM] && rgrant[iN-1][iM])
rrequested[iN][iM] = 1;
if (rrequest[iN-1][iM] && (!srgrant[iN-1] || srempty[iN-1]))
rrequested[iN][iM] = 1;
// Otherwise, if it's already claimed, then
// it can't be claimed again
if (rrequested[iN-1][iM])
rrequested[iN][iM] = 1;
end
rrequested[NM][iM] = rrequest[NM-1][iM] || rrequested[NM-1][iM];
end
end
// }}}
// mwgrant, mrgrant
// {{{
generate for(M=0; M<NS; M=M+1)
begin
// {{{
always @(*)
begin
mwgrant[M] = 0;
for(iN=0; iN<NM; iN=iN+1)
if (wgrant[iN][M])
mwgrant[M] = 1;
end
always @(*)
begin
mrgrant[M] = 0;
for(iN=0; iN<NM; iN=iN+1)
if (rgrant[iN][M])
mrgrant[M] = 1;
end
// }}}
end endgenerate
// }}}
generate for(N=0; N<NM; N=N+1)
begin : ARBITRATE_WRITE_REQUESTS
// {{{
// Declarations
// {{{
reg stay_on_channel;
reg requested_channel_is_available;
reg leave_channel;
reg [LGNS-1:0] requested_index;
// }}}
// stay_on_channel
// {{{
always @(*)
begin
stay_on_channel = |(wrequest[N][NS:0] & wgrant[N]);
if (swgrant[N] && !swempty[N])
stay_on_channel = 1;
end
// }}}
// requested_channel_is_available
// {{{
always @(*)
begin
requested_channel_is_available =
|(wrequest[N][NS-1:0] & ~mwgrant
& ~wrequested[N][NS-1:0]);
if (wrequest[N][NS])
requested_channel_is_available = 1;
if (NM < 2)
requested_channel_is_available = m_awvalid[N];
end
// }}}
wire linger;
if (OPT_LINGER == 0)
begin
// {{{
assign linger = 0;
// }}}
end else begin : WRITE_LINGER
// {{{
reg [LGLINGER-1:0] linger_counter;
reg r_linger;
initial r_linger = 0;
initial linger_counter = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN || wgrant[N][NS])
begin
r_linger <= 0;
linger_counter <= 0;
end else if (!swempty[N] || S_AXI_BVALID[N])
begin
linger_counter <= OPT_LINGER;
r_linger <= 1;
end else if (linger_counter > 0)
begin
r_linger <= (linger_counter > 1);
linger_counter <= linger_counter - 1;
end else
r_linger <= 0;
assign linger = r_linger;
`ifdef FORMAL
// {{{
always @(*)
assert(linger == (linger_counter != 0));
// }}}
`endif
// }}}
end
// leave_channel
// {{{
always @(*)
begin
leave_channel = 0;
if (!m_awvalid[N]
&& (!linger || wrequested[NM][swindex[N]]))
// Leave the channel after OPT_LINGER counts
// of the channel being idle, or when someone
// else asks for the channel
leave_channel = 1;
if (m_awvalid[N] && !wrequest[N][swindex[N]])
// Need to leave this channel to connect
// to any other channel
leave_channel = 1;
end
// }}}
// wgrant, swgrant
// {{{
initial wgrant[N] = 0;
initial swgrant[N] = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
begin
wgrant[N] <= 0;
swgrant[N] <= 0;
end else if (!stay_on_channel)
begin
if (requested_channel_is_available)
begin
// Switching channels
swgrant[N] <= 1'b1;
wgrant[N] <= wrequest[N][NS:0];
end else if (leave_channel)
begin
swgrant[N] <= 1'b0;
wgrant[N] <= 0;
end
end
// }}}
// requested_index
// {{{
always @(wrequest[N])
begin
requested_index = 0;
for(iM=0; iM<=NS; iM=iM+1)
if (wrequest[N][iM])
requested_index= requested_index | iM[LGNS-1:0];
end
// }}}
// Now for swindex
// {{{
reg [LGNS-1:0] r_swindex;
initial r_swindex = 0;
always @(posedge S_AXI_ACLK)
if (!stay_on_channel && requested_channel_is_available)
r_swindex <= requested_index;
assign swindex[N] = r_swindex;
// }}}
// }}}
end for (N=NM; N<NMFULL; N=N+1)
begin
// {{{
assign swindex[N] = 0;
// }}}
end endgenerate
generate for(N=0; N<NM; N=N+1)
begin : ARBITRATE_READ_REQUESTS
// {{{
// Declarations
// {{{
reg stay_on_channel;
reg requested_channel_is_available;
reg leave_channel;
reg [LGNS-1:0] requested_index;
// }}}
// stay_on_channel
// {{{
always @(*)
begin
stay_on_channel = |(rrequest[N][NS:0] & rgrant[N]);
if (srgrant[N] && !srempty[N])
stay_on_channel = 1;
end
// }}}
// requested_channel_is_available
// {{{
always @(*)
begin
requested_channel_is_available =
|(rrequest[N][NS-1:0] & ~mrgrant
& ~rrequested[N][NS-1:0]);
if (rrequest[N][NS])
requested_channel_is_available = 1;
if (NM < 2)
requested_channel_is_available = m_arvalid[N];
end
// }}}
wire linger;
if (OPT_LINGER == 0)
begin
// {{{
assign linger = 0;
// }}}
end else begin : READ_LINGER
// {{{
reg [LGLINGER-1:0] linger_counter;
reg r_linger;
initial r_linger = 0;
initial linger_counter = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN || rgrant[N][NS])
begin
r_linger <= 0;
linger_counter <= 0;
end else if (!srempty[N] || S_AXI_RVALID[N])
begin
linger_counter <= OPT_LINGER;
r_linger <= 1;
end else if (linger_counter > 0)
begin
r_linger <= (linger_counter > 1);
linger_counter <= linger_counter - 1;
end else
r_linger <= 0;
assign linger = r_linger;
`ifdef FORMAL
// {{{
always @(*)
assert(linger == (linger_counter != 0));
// }}}
`endif
// }}}
end
// leave_channel
// {{{
always @(*)
begin
leave_channel = 0;
if (!m_arvalid[N]
&& (!linger || rrequested[NM][srindex[N]]))
// Leave the channel after OPT_LINGER counts
// of the channel being idle, or when someone
// else asks for the channel
leave_channel = 1;
if (m_arvalid[N] && !rrequest[N][srindex[N]])
// Need to leave this channel to connect
// to any other channel
leave_channel = 1;
end
// }}}
// rgrant, srgrant
// {{{
initial rgrant[N] = 0;
initial srgrant[N] = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
begin
rgrant[N] <= 0;
srgrant[N] <= 0;
end else if (!stay_on_channel)
begin
if (requested_channel_is_available)
begin
// Switching channels
srgrant[N] <= 1'b1;
rgrant[N] <= rrequest[N][NS:0];
end else if (leave_channel)
begin
srgrant[N] <= 1'b0;
rgrant[N] <= 0;
end
end
// }}}
// requested_index
// {{{
always @(rrequest[N])
begin
requested_index = 0;
for(iM=0; iM<=NS; iM=iM+1)
if (rrequest[N][iM])
requested_index = requested_index|iM[LGNS-1:0];
end
// }}}
// Now for srindex
// {{{
reg [LGNS-1:0] r_srindex;
initial r_srindex = 0;
always @(posedge S_AXI_ACLK)
if (!stay_on_channel && requested_channel_is_available)
r_srindex <= requested_index;
assign srindex[N] = r_srindex;
// }}}
// }}}
end for (N=NM; N<NMFULL; N=N+1)
begin
// {{{
assign srindex[N] = 0;
// }}}
end endgenerate
// Calculate mwindex
generate for (M=0; M<NS; M=M+1)
begin : SLAVE_WRITE_INDEX
// {{{
if (NM <= 1)
begin
// {{{
assign mwindex[M] = 0;
// }}}
end else begin : MULTIPLE_MASTERS
// {{{
reg [LGNM-1:0] reswindex;
reg [LGNM-1:0] r_mwindex;
always @(*)
begin
reswindex = 0;
for(iN=0; iN<NM; iN=iN+1)
if ((!swgrant[iN] || swempty[iN])
&&(wrequest[iN][M] && !wrequested[iN][M]))
reswindex = reswindex | iN[LGNM-1:0];
end
always @(posedge S_AXI_ACLK)
if (!mwgrant[M])
r_mwindex <= reswindex;
assign mwindex[M] = r_mwindex;
// }}}
end
// }}}
end for (M=NS; M<NSFULL; M=M+1)
begin
// {{{
assign mwindex[M] = 0;
// }}}
end endgenerate
// Calculate mrindex
generate for (M=0; M<NS; M=M+1)
begin : SLAVE_READ_INDEX
// {{{
if (NM <= 1)
begin
// {{{
assign mrindex[M] = 0;
// }}}
end else begin : MULTIPLE_MASTERS
// {{{
reg [LGNM-1:0] resrindex;
reg [LGNM-1:0] r_mrindex;
always @(*)
begin
resrindex = 0;
for(iN=0; iN<NM; iN=iN+1)
if ((!srgrant[iN] || srempty[iN])
&&(rrequest[iN][M] && !rrequested[iN][M]))
resrindex = resrindex | iN[LGNM-1:0];
end