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floo_nw_chimney.sv
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floo_nw_chimney.sv
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// Copyright 2022 ETH Zurich and University of Bologna.
// Solderpad Hardware License, Version 0.51, see LICENSE for details.
// SPDX-License-Identifier: SHL-0.51
//
// Tim Fischer <[email protected]>
`include "common_cells/registers.svh"
`include "common_cells/assertions.svh"
`include "axi/typedef.svh"
`include "floo_noc/typedef.svh"
/// A bidirectional network interface for connecting narrow & wide AXI Buses to the multi-link NoC
module floo_nw_chimney #(
/// Config of the narrow AXI interfaces (see floo_pkg::axi_cfg_t for details)
parameter floo_pkg::axi_cfg_t AxiCfgN = '0,
/// Config of the wide AXI interfaces (see floo_pkg::axi_cfg_t for details)
parameter floo_pkg::axi_cfg_t AxiCfgW = '0,
/// Config of the narrow data path in the chimney (see floo_pkg::chimney_cfg_t for details)
parameter floo_pkg::chimney_cfg_t ChimneyCfgN = floo_pkg::ChimneyDefaultCfg,
/// Config of the wide data path in the chimney (see floo_pkg::chimney_cfg_t for details)
parameter floo_pkg::chimney_cfg_t ChimneyCfgW = floo_pkg::ChimneyDefaultCfg,
/// Config for routing information (see floo_pkg::route_cfg_t for details)
parameter floo_pkg::route_cfg_t RouteCfg = floo_pkg::RouteDefaultCfg,
/// Atomic operation support, currently only implemented for
/// the narrow network!
parameter bit AtopSupport = 1'b1,
/// Maximum number of oustanding Atomic transactions,
/// must be smaller or equal to 2**`AxiCfgN.OutIdWidth`-1 since
/// Every atomic transactions needs to have a unique ID
/// and one ID is reserved for non-atomic transactions
parameter int unsigned MaxAtomicTxns = 1,
/// Node ID type for routing
parameter type id_t = logic,
/// RoB index type for reordering.
// (can be ignored if `RoBType == NoRoB`)
parameter type rob_idx_t = logic,
/// Route type for source-based routing
/// (only used if `RouteCfg.RouteAlgo == SourceRouting`)
parameter type route_t = logic,
/// Destination ID type for routing
/// The destination ID type is usually the same as the node ID type,
/// except for the case of source-based routing, where the destination
/// ID is the actual route to the destination i.e. `route_t`
parameter type dst_t = id_t,
/// Header type for the flits
parameter type hdr_t = logic,
/// Rule type for the System Address Map
/// (only used if `RouteCfg.UseIdTable == 1'b1`)
parameter type sam_rule_t = logic,
/// The System Address Map (SAM) rules
/// (only used if `RouteCfg.UseIdTable == 1'b1`)
parameter sam_rule_t [RouteCfg.NumSamRules-1:0] Sam = '0,
/// Narrow AXI manager request channel type
parameter type axi_narrow_in_req_t = logic,
/// Narrow AXI manager response channel type
parameter type axi_narrow_in_rsp_t = logic,
/// Narrow AXI subordinate request channel type
parameter type axi_narrow_out_req_t = logic,
/// Narrow AXI subordinate response channel type
parameter type axi_narrow_out_rsp_t = logic,
/// Wide AXI manager request channel type
parameter type axi_wide_in_req_t = logic,
/// Wide AXI manager response channel type
parameter type axi_wide_in_rsp_t = logic,
/// Wide AXI subordinate request channel type
parameter type axi_wide_out_req_t = logic,
/// Wide AXI subordinate response channel type
parameter type axi_wide_out_rsp_t = logic,
/// Floo `req` link type
parameter type floo_req_t = logic,
/// Floo `rsp` link type
parameter type floo_rsp_t = logic,
/// Floo `wide` link type
parameter type floo_wide_t = logic,
/// SRAM configuration type `tc_sram_impl` in RoB
/// Only used if technology-dependent SRAM is used
parameter type sram_cfg_t = logic
) (
input logic clk_i,
input logic rst_ni,
input logic test_enable_i,
/// SRAM configuration
input sram_cfg_t sram_cfg_i,
/// Narrow AXI4 side interfaces
input axi_narrow_in_req_t axi_narrow_in_req_i,
output axi_narrow_in_rsp_t axi_narrow_in_rsp_o,
output axi_narrow_out_req_t axi_narrow_out_req_o,
input axi_narrow_out_rsp_t axi_narrow_out_rsp_i,
/// Wide AXI4 side interfaces
input axi_wide_in_req_t axi_wide_in_req_i,
output axi_wide_in_rsp_t axi_wide_in_rsp_o,
output axi_wide_out_req_t axi_wide_out_req_o,
input axi_wide_out_rsp_t axi_wide_out_rsp_i,
/// Coordinates/ID of the current tile
input id_t id_i,
/// Routing table for the current tile
input route_t [RouteCfg.NumRoutes-1:0] route_table_i,
/// Output links to NoC
output floo_req_t floo_req_o,
output floo_rsp_t floo_rsp_o,
output floo_wide_t floo_wide_o,
/// Input links from NoC
input floo_req_t floo_req_i,
input floo_rsp_t floo_rsp_i,
input floo_wide_t floo_wide_i
);
import floo_pkg::*;
typedef logic [AxiCfgN.AddrWidth-1:0] axi_addr_t;
typedef logic [AxiCfgN.InIdWidth-1:0] axi_narrow_in_id_t;
typedef logic [AxiCfgN.UserWidth-1:0] axi_narrow_user_t;
typedef logic [AxiCfgN.DataWidth-1:0] axi_narrow_data_t;
typedef logic [AxiCfgN.DataWidth/8-1:0] axi_narrow_strb_t;
typedef logic [AxiCfgW.InIdWidth-1:0] axi_wide_in_id_t;
typedef logic [AxiCfgW.UserWidth-1:0] axi_wide_user_t;
typedef logic [AxiCfgW.DataWidth-1:0] axi_wide_data_t;
typedef logic [AxiCfgW.DataWidth/8-1:0] axi_wide_strb_t;
// (Re-) definitons of `axi_in` and `floo` types, for transport
`AXI_TYPEDEF_ALL_CT(axi_narrow, axi_narrow_req_t, axi_narrow_rsp_t, axi_addr_t,
axi_narrow_in_id_t, axi_narrow_data_t, axi_narrow_strb_t, axi_narrow_user_t)
`AXI_TYPEDEF_ALL_CT(axi_wide, axi_wide_req_t, axi_wide_rsp_t, axi_addr_t,
axi_wide_in_id_t, axi_wide_data_t, axi_wide_strb_t, axi_wide_user_t)
`FLOO_TYPEDEF_NW_CHAN_ALL(axi, req, rsp, wide, axi_narrow, axi_wide, AxiCfgN, AxiCfgW, hdr_t)
// Duplicate AXI port signals to degenerate ports
// in case they are not used
axi_narrow_req_t axi_narrow_req_in;
axi_narrow_rsp_t axi_narrow_rsp_out;
axi_wide_req_t axi_wide_req_in;
axi_wide_rsp_t axi_wide_rsp_out;
// AX queue
axi_narrow_aw_chan_t axi_narrow_aw_queue;
axi_narrow_ar_chan_t axi_narrow_ar_queue;
axi_wide_aw_chan_t axi_wide_aw_queue;
axi_wide_ar_chan_t axi_wide_ar_queue;
logic axi_narrow_aw_queue_valid_out, axi_narrow_aw_queue_ready_in;
logic axi_narrow_ar_queue_valid_out, axi_narrow_ar_queue_ready_in;
logic axi_wide_aw_queue_valid_out, axi_wide_aw_queue_ready_in;
logic axi_wide_ar_queue_valid_out, axi_wide_ar_queue_ready_in;
floo_req_chan_t [WideAr:NarrowAw] floo_req_arb_in;
floo_rsp_chan_t [WideB:NarrowB] floo_rsp_arb_in;
floo_wide_chan_t [WideR:WideAw] floo_wide_arb_in;
logic [WideAr:NarrowAw] floo_req_arb_req_in, floo_req_arb_gnt_out;
logic [WideB:NarrowB] floo_rsp_arb_req_in, floo_rsp_arb_gnt_out;
logic [WideR:WideAw] floo_wide_arb_req_in, floo_wide_arb_gnt_out;
// flit queue
floo_req_chan_t floo_req_in;
floo_rsp_chan_t floo_rsp_in;
floo_wide_chan_t floo_wide_in;
logic floo_req_in_valid, floo_rsp_in_valid, floo_wide_in_valid;
logic floo_req_out_ready, floo_rsp_out_ready, floo_wide_out_ready;
logic [NumNWAxiChannels-1:0] axi_valid_in, axi_ready_out;
// Flit packing
floo_axi_narrow_aw_flit_t floo_narrow_aw;
floo_axi_narrow_ar_flit_t floo_narrow_ar;
floo_axi_narrow_w_flit_t floo_narrow_w;
floo_axi_narrow_b_flit_t floo_narrow_b;
floo_axi_narrow_r_flit_t floo_narrow_r;
floo_axi_wide_aw_flit_t floo_wide_aw;
floo_axi_wide_ar_flit_t floo_wide_ar;
floo_axi_wide_w_flit_t floo_wide_w;
floo_axi_wide_b_flit_t floo_wide_b;
floo_axi_wide_r_flit_t floo_wide_r;
// Flit arbitration
typedef enum logic {SelAw, SelW} aw_w_sel_e;
aw_w_sel_e narrow_aw_w_sel_q, narrow_aw_w_sel_d;
aw_w_sel_e wide_aw_w_sel_q, wide_aw_w_sel_d;
// Flit unpacking
axi_narrow_aw_chan_t axi_narrow_unpack_aw;
axi_narrow_w_chan_t axi_narrow_unpack_w;
axi_narrow_b_chan_t axi_narrow_unpack_b;
axi_narrow_ar_chan_t axi_narrow_unpack_ar;
axi_narrow_r_chan_t axi_narrow_unpack_r;
axi_wide_aw_chan_t axi_wide_unpack_aw;
axi_wide_w_chan_t axi_wide_unpack_w;
axi_wide_b_chan_t axi_wide_unpack_b;
axi_wide_ar_chan_t axi_wide_unpack_ar;
axi_wide_r_chan_t axi_wide_unpack_r;
floo_req_generic_flit_t floo_req_unpack_generic;
floo_rsp_generic_flit_t floo_rsp_unpack_generic;
floo_wide_generic_flit_t floo_wide_unpack_generic;
// Meta Buffers
axi_narrow_in_req_t axi_narrow_meta_buf_req_in;
axi_narrow_in_rsp_t axi_narrow_meta_buf_rsp_out;
axi_wide_in_req_t axi_wide_meta_buf_req_in;
axi_wide_in_rsp_t axi_wide_meta_buf_rsp_out;
// ID tracking
typedef struct packed {
axi_narrow_in_id_t id;
hdr_t hdr;
} narrow_meta_buf_t;
typedef struct packed {
axi_wide_in_id_t id;
hdr_t hdr;
} wide_meta_buf_t;
// Routing
dst_t [NumNWAxiChannels-1:0] dst_id;
dst_t narrow_aw_id_q, wide_aw_id_q;
route_t [NumNWAxiChannels-1:0] route_out;
id_t [NumNWAxiChannels-1:0] id_out;
narrow_meta_buf_t narrow_aw_buf_hdr_in, narrow_aw_buf_hdr_out;
narrow_meta_buf_t narrow_ar_buf_hdr_in, narrow_ar_buf_hdr_out;
wide_meta_buf_t wide_aw_buf_hdr_in, wide_aw_buf_hdr_out;
wide_meta_buf_t wide_ar_buf_hdr_in, wide_ar_buf_hdr_out;
///////////////////////
// Spill registers //
///////////////////////
if (ChimneyCfgN.EnMgrPort) begin : gen_narrow_sbr_port
assign axi_narrow_req_in = axi_narrow_in_req_i;
assign axi_narrow_in_rsp_o = axi_narrow_rsp_out;
if (ChimneyCfgN.CutAx) begin : gen_ax_cuts
spill_register #(
.T ( axi_narrow_aw_chan_t )
) i_narrow_aw_queue (
.clk_i,
.rst_ni,
.data_i ( axi_narrow_in_req_i.aw ),
.valid_i ( axi_narrow_in_req_i.aw_valid ),
.ready_o ( axi_narrow_rsp_out.aw_ready ),
.data_o ( axi_narrow_aw_queue ),
.valid_o ( axi_narrow_aw_queue_valid_out ),
.ready_i ( axi_narrow_aw_queue_ready_in )
);
spill_register #(
.T ( axi_narrow_ar_chan_t )
) i_narrow_ar_queue (
.clk_i,
.rst_ni,
.data_i ( axi_narrow_in_req_i.ar ),
.valid_i ( axi_narrow_in_req_i.ar_valid ),
.ready_o ( axi_narrow_rsp_out.ar_ready ),
.data_o ( axi_narrow_ar_queue ),
.valid_o ( axi_narrow_ar_queue_valid_out ),
.ready_i ( axi_narrow_ar_queue_ready_in )
);
end else begin : gen_ax_no_cuts
assign axi_narrow_aw_queue = axi_narrow_in_req_i.aw;
assign axi_narrow_aw_queue_valid_out = axi_narrow_in_req_i.aw_valid;
assign axi_narrow_rsp_out.aw_ready = axi_narrow_aw_queue_ready_in;
assign axi_narrow_ar_queue = axi_narrow_in_req_i.ar;
assign axi_narrow_ar_queue_valid_out = axi_narrow_in_req_i.ar_valid;
assign axi_narrow_rsp_out.ar_ready = axi_narrow_ar_queue_ready_in;
end
end else begin : gen_narrow_err_slv_port
axi_err_slv #(
.AxiIdWidth ( AxiCfgN.InIdWidth ),
.ATOPs ( AtopSupport ),
.axi_req_t ( axi_narrow_in_req_t ),
.axi_resp_t ( axi_narrow_in_rsp_t )
) i_axi_err_slv (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.test_i ( test_enable_i ),
.slv_req_i ( axi_narrow_in_req_i ),
.slv_resp_o ( axi_narrow_in_rsp_o )
);
assign axi_narrow_req_in = '0;
assign axi_narrow_aw_queue = '0;
assign axi_narrow_ar_queue = '0;
assign axi_narrow_aw_queue_valid_out = 1'b0;
assign axi_narrow_ar_queue_valid_out = 1'b0;
end
if (ChimneyCfgW.EnMgrPort) begin : gen_wide_sbr_port
assign axi_wide_req_in = axi_wide_in_req_i;
assign axi_wide_in_rsp_o = axi_wide_rsp_out;
if (ChimneyCfgW.CutAx) begin : gen_ax_cuts
spill_register #(
.T ( axi_wide_aw_chan_t )
) i_wide_aw_queue (
.clk_i,
.rst_ni,
.data_i ( axi_wide_in_req_i.aw ),
.valid_i ( axi_wide_in_req_i.aw_valid ),
.ready_o ( axi_wide_rsp_out.aw_ready ),
.data_o ( axi_wide_aw_queue ),
.valid_o ( axi_wide_aw_queue_valid_out ),
.ready_i ( axi_wide_aw_queue_ready_in )
);
spill_register #(
.T ( axi_wide_ar_chan_t )
) i_wide_ar_queue (
.clk_i,
.rst_ni,
.data_i ( axi_wide_in_req_i.ar ),
.valid_i ( axi_wide_in_req_i.ar_valid ),
.ready_o ( axi_wide_rsp_out.ar_ready ),
.data_o ( axi_wide_ar_queue ),
.valid_o ( axi_wide_ar_queue_valid_out ),
.ready_i ( axi_wide_ar_queue_ready_in )
);
end else begin : gen_ax_no_cuts
assign axi_wide_aw_queue = axi_wide_in_req_i.aw;
assign axi_wide_aw_queue_valid_out = axi_wide_in_req_i.aw_valid;
assign axi_wide_rsp_out.aw_ready = axi_wide_aw_queue_ready_in;
assign axi_wide_ar_queue = axi_wide_in_req_i.ar;
assign axi_wide_ar_queue_valid_out = axi_wide_in_req_i.ar_valid;
assign axi_wide_rsp_out.ar_ready = axi_wide_ar_queue_ready_in;
end
end else begin : gen_wide_err_slv_port
axi_err_slv #(
.AxiIdWidth ( AxiCfgW.InIdWidth ),
.ATOPs ( AtopSupport ),
.axi_req_t ( axi_wide_in_req_t ),
.axi_resp_t ( axi_wide_in_rsp_t )
) i_axi_err_slv (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.test_i ( test_enable_i ),
.slv_req_i ( axi_wide_in_req_i ),
.slv_resp_o ( axi_wide_in_rsp_o )
);
assign axi_wide_req_in = '0;
assign axi_wide_aw_queue = '0;
assign axi_wide_ar_queue = '0;
assign axi_wide_aw_queue_valid_out = 1'b0;
assign axi_wide_ar_queue_valid_out = 1'b0;
end
if (ChimneyCfgN.CutRsp && ChimneyCfgW.CutRsp) begin : gen_rsp_cuts
spill_register #(
.T ( floo_req_chan_t )
) i_narrow_data_req_arb (
.clk_i,
.rst_ni,
.data_i ( floo_req_i.req ),
.valid_i ( floo_req_i.valid ),
.ready_o ( floo_req_o.ready ),
.data_o ( floo_req_in ),
.valid_o ( floo_req_in_valid ),
.ready_i ( floo_req_out_ready )
);
spill_register #(
.T ( floo_rsp_chan_t )
) i_narrow_data_rsp_arb (
.clk_i,
.rst_ni,
.data_i ( floo_rsp_i.rsp ),
.valid_i ( floo_rsp_i.valid ),
.ready_o ( floo_rsp_o.ready ),
.data_o ( floo_rsp_in ),
.valid_o ( floo_rsp_in_valid ),
.ready_i ( floo_rsp_out_ready )
);
spill_register #(
.T ( floo_wide_chan_t )
) i_wide_data_req_arb (
.clk_i,
.rst_ni,
.data_i ( floo_wide_i.wide ),
.valid_i ( floo_wide_i.valid ),
.ready_o ( floo_wide_o.ready ),
.data_o ( floo_wide_in ),
.valid_o ( floo_wide_in_valid ),
.ready_i ( floo_wide_out_ready )
);
end else begin : gen_no_rsp_cuts
assign floo_req_in = floo_req_i.req;
assign floo_rsp_in = floo_rsp_i.rsp;
assign floo_wide_in = floo_wide_i.wide;
assign floo_req_in_valid = floo_req_i.valid;
assign floo_rsp_in_valid = floo_rsp_i.valid;
assign floo_wide_in_valid = floo_wide_i.valid;
assign floo_req_o.ready = floo_req_out_ready;
assign floo_rsp_o.ready = floo_rsp_out_ready;
assign floo_wide_o.ready = floo_wide_out_ready;
end
///////////////////////
// Reorder Buffers //
///////////////////////
// AW/B RoB
axi_narrow_b_chan_t axi_narrow_b_rob_out, axi_narrow_b_rob_in;
logic narrow_aw_rob_req_out;
rob_idx_t narrow_aw_rob_idx_out;
logic narrow_aw_rob_valid_out, narrow_aw_rob_ready_in;
logic narrow_aw_rob_valid_in, narrow_aw_rob_ready_out;
logic narrow_b_rob_valid_in, narrow_b_rob_ready_out;
logic narrow_b_rob_valid_out, narrow_b_rob_ready_in;
axi_wide_b_chan_t axi_wide_b_rob_out, axi_wide_b_rob_in;
logic wide_aw_rob_req_out;
rob_idx_t wide_aw_rob_idx_out;
logic wide_aw_rob_valid_out, wide_aw_rob_ready_in;
logic wide_b_rob_valid_in, wide_b_rob_ready_out;
logic wide_b_rob_valid_out, wide_b_rob_ready_in;
// AR/R RoB
axi_narrow_r_chan_t axi_narrow_r_rob_out, axi_narrow_r_rob_in;
logic narrow_ar_rob_req_out;
rob_idx_t narrow_ar_rob_idx_out;
logic narrow_ar_rob_valid_out, narrow_ar_rob_ready_in;
logic narrow_r_rob_valid_in, narrow_r_rob_ready_out;
logic narrow_r_rob_valid_out, narrow_r_rob_ready_in;
axi_wide_r_chan_t axi_wide_r_rob_out, axi_wide_r_rob_in;
logic wide_ar_rob_req_out;
rob_idx_t wide_ar_rob_idx_out;
logic wide_ar_rob_valid_out, wide_ar_rob_ready_in;
logic wide_r_rob_valid_in, wide_r_rob_ready_out;
logic wide_r_rob_valid_out, wide_r_rob_ready_in;
logic narrow_b_rob_rob_req;
logic narrow_b_rob_last;
rob_idx_t narrow_b_rob_rob_idx;
assign narrow_b_rob_rob_req = floo_rsp_in.narrow_b.hdr.rob_req;
assign narrow_b_rob_rob_idx = floo_rsp_in.narrow_b.hdr.rob_idx;
assign narrow_b_rob_last = floo_rsp_in.narrow_b.hdr.last;
if (AtopSupport) begin : gen_atop_support
// Bypass AW/B RoB
assign narrow_aw_rob_valid_in = axi_narrow_aw_queue_valid_out &&
(axi_narrow_aw_queue.atop == axi_pkg::ATOP_NONE);
assign axi_narrow_aw_queue_ready_in = (axi_narrow_aw_queue.atop == axi_pkg::ATOP_NONE)?
narrow_aw_rob_ready_out : narrow_aw_rob_ready_in;
end else begin : gen_no_atop_support
assign narrow_aw_rob_valid_in = axi_narrow_aw_queue_valid_out;
assign axi_narrow_aw_queue_ready_in = narrow_aw_rob_ready_in;
`ASSERT(NoAtopSupport, !(axi_narrow_aw_queue_valid_out &&
(axi_narrow_aw_queue.atop != axi_pkg::ATOP_NONE)))
end
floo_rob_wrapper #(
.RoBType ( ChimneyCfgN.BRoBType ),
.RoBSize ( ChimneyCfgN.BRoBSize ),
.MaxRoTxnsPerId ( ChimneyCfgN.MaxTxnsPerId ),
.OnlyMetaData ( 1'b1 ),
.ax_len_t ( axi_pkg::len_t ),
.ax_id_t ( axi_narrow_in_id_t ),
.rsp_chan_t ( axi_narrow_b_chan_t ),
.rsp_meta_t ( axi_narrow_b_chan_t ),
.rob_idx_t ( rob_idx_t ),
.dest_t ( id_t ),
.sram_cfg_t ( sram_cfg_t )
) i_narrow_b_rob (
.clk_i,
.rst_ni,
.sram_cfg_i,
.ax_valid_i ( narrow_aw_rob_valid_in ),
.ax_ready_o ( narrow_aw_rob_ready_out ),
.ax_len_i ( axi_narrow_aw_queue.len ),
.ax_id_i ( axi_narrow_aw_queue.id ),
.ax_dest_i ( id_out[NarrowAw] ),
.ax_valid_o ( narrow_aw_rob_valid_out ),
.ax_ready_i ( narrow_aw_rob_ready_in ),
.ax_rob_req_o ( narrow_aw_rob_req_out ),
.ax_rob_idx_o ( narrow_aw_rob_idx_out ),
.rsp_valid_i ( narrow_b_rob_valid_in ),
.rsp_ready_o ( narrow_b_rob_ready_out ),
.rsp_i ( axi_narrow_b_rob_in ),
.rsp_rob_req_i ( narrow_b_rob_rob_req ),
.rsp_rob_idx_i ( narrow_b_rob_rob_idx ),
.rsp_last_i ( narrow_b_rob_last ),
.rsp_valid_o ( narrow_b_rob_valid_out ),
.rsp_ready_i ( narrow_b_rob_ready_in ),
.rsp_o ( axi_narrow_b_rob_out )
);
logic wide_b_rob_rob_req;
logic wide_b_rob_last;
rob_idx_t wide_b_rob_rob_idx;
assign wide_b_rob_rob_req = floo_rsp_in.wide_b.hdr.rob_req;
assign wide_b_rob_rob_idx = floo_rsp_in.wide_b.hdr.rob_idx;
assign wide_b_rob_last = floo_rsp_in.wide_b.hdr.last;
floo_rob_wrapper #(
.RoBType ( ChimneyCfgW.BRoBType ),
.RoBSize ( ChimneyCfgW.BRoBSize ),
.MaxRoTxnsPerId ( ChimneyCfgW.MaxTxnsPerId ),
.OnlyMetaData ( 1'b1 ),
.ax_len_t ( axi_pkg::len_t ),
.ax_id_t ( axi_wide_in_id_t ),
.rsp_chan_t ( axi_wide_b_chan_t ),
.rsp_meta_t ( axi_wide_b_chan_t ),
.rob_idx_t ( rob_idx_t ),
.dest_t ( id_t ),
.sram_cfg_t ( sram_cfg_t )
) i_wide_b_rob (
.clk_i,
.rst_ni,
.sram_cfg_i,
.ax_valid_i ( axi_wide_aw_queue_valid_out ),
.ax_ready_o ( axi_wide_aw_queue_ready_in ),
.ax_len_i ( axi_wide_aw_queue.len ),
.ax_id_i ( axi_wide_aw_queue.id ),
.ax_dest_i ( id_out[WideAw] ),
.ax_valid_o ( wide_aw_rob_valid_out ),
.ax_ready_i ( wide_aw_rob_ready_in ),
.ax_rob_req_o ( wide_aw_rob_req_out ),
.ax_rob_idx_o ( wide_aw_rob_idx_out ),
.rsp_valid_i ( wide_b_rob_valid_in ),
.rsp_ready_o ( wide_b_rob_ready_out ),
.rsp_i ( axi_wide_b_rob_in ),
.rsp_rob_req_i ( wide_b_rob_rob_req ),
.rsp_rob_idx_i ( wide_b_rob_rob_idx ),
.rsp_last_i ( wide_b_rob_last ),
.rsp_valid_o ( wide_b_rob_valid_out ),
.rsp_ready_i ( wide_b_rob_ready_in ),
.rsp_o ( axi_wide_b_rob_out )
);
typedef struct packed {
axi_narrow_in_id_t id;
axi_narrow_user_t user;
axi_pkg::resp_t resp;
logic last;
} narrow_r_rob_meta_t;
typedef struct packed {
axi_wide_in_id_t id;
axi_wide_user_t user;
axi_pkg::resp_t resp;
logic last;
} wide_r_rob_meta_t;
logic narrow_r_rob_rob_req;
logic narrow_r_rob_last;
rob_idx_t narrow_r_rob_rob_idx;
assign narrow_r_rob_rob_req = floo_rsp_in.narrow_r.hdr.rob_req;
assign narrow_r_rob_rob_idx = floo_rsp_in.narrow_r.hdr.rob_idx;
assign narrow_r_rob_last = floo_rsp_in.narrow_r.payload.last;
floo_rob_wrapper #(
.RoBType ( ChimneyCfgN.RRoBType ),
.RoBSize ( ChimneyCfgN.RRoBSize ),
.MaxRoTxnsPerId ( ChimneyCfgN.MaxTxnsPerId ),
.OnlyMetaData ( 1'b0 ),
.ax_len_t ( axi_pkg::len_t ),
.ax_id_t ( axi_narrow_in_id_t ),
.rsp_chan_t ( axi_narrow_r_chan_t ),
.rsp_data_t ( axi_narrow_data_t ),
.rsp_meta_t ( narrow_r_rob_meta_t ),
.rob_idx_t ( rob_idx_t ),
.dest_t ( id_t ),
.sram_cfg_t ( sram_cfg_t )
) i_narrow_r_rob (
.clk_i,
.rst_ni,
.sram_cfg_i,
.ax_valid_i ( axi_narrow_ar_queue_valid_out ),
.ax_ready_o ( axi_narrow_ar_queue_ready_in ),
.ax_len_i ( axi_narrow_ar_queue.len ),
.ax_id_i ( axi_narrow_ar_queue.id ),
.ax_dest_i ( id_out[NarrowAr] ),
.ax_valid_o ( narrow_ar_rob_valid_out ),
.ax_ready_i ( narrow_ar_rob_ready_in ),
.ax_rob_req_o ( narrow_ar_rob_req_out ),
.ax_rob_idx_o ( narrow_ar_rob_idx_out ),
.rsp_valid_i ( narrow_r_rob_valid_in ),
.rsp_ready_o ( narrow_r_rob_ready_out ),
.rsp_i ( axi_narrow_r_rob_in ),
.rsp_rob_req_i ( narrow_r_rob_rob_req ),
.rsp_rob_idx_i ( narrow_r_rob_rob_idx ),
.rsp_last_i ( narrow_r_rob_last ),
.rsp_valid_o ( narrow_r_rob_valid_out ),
.rsp_ready_i ( narrow_r_rob_ready_in ),
.rsp_o ( axi_narrow_r_rob_out )
);
logic wide_r_rob_rob_req;
logic wide_r_rob_last;
rob_idx_t wide_r_rob_rob_idx;
assign wide_r_rob_rob_req = floo_wide_in.wide_r.hdr.rob_req;
assign wide_r_rob_rob_idx = floo_wide_in.wide_r.hdr.rob_idx;
assign wide_r_rob_last = floo_wide_in.wide_r.payload.last;
floo_rob_wrapper #(
.RoBType ( ChimneyCfgW.RRoBType ),
.RoBSize ( ChimneyCfgW.RRoBSize ),
.MaxRoTxnsPerId ( ChimneyCfgW.MaxTxnsPerId ),
.OnlyMetaData ( 1'b0 ),
.ax_len_t ( axi_pkg::len_t ),
.ax_id_t ( axi_wide_in_id_t ),
.rsp_chan_t ( axi_wide_r_chan_t ),
.rsp_data_t ( axi_wide_data_t ),
.rsp_meta_t ( wide_r_rob_meta_t ),
.rob_idx_t ( rob_idx_t ),
.dest_t ( id_t ),
.sram_cfg_t ( sram_cfg_t )
) i_wide_r_rob (
.clk_i,
.rst_ni,
.sram_cfg_i,
.ax_valid_i ( axi_wide_ar_queue_valid_out ),
.ax_ready_o ( axi_wide_ar_queue_ready_in ),
.ax_len_i ( axi_wide_ar_queue.len ),
.ax_id_i ( axi_wide_ar_queue.id ),
.ax_dest_i ( id_out[WideAr] ),
.ax_valid_o ( wide_ar_rob_valid_out ),
.ax_ready_i ( wide_ar_rob_ready_in ),
.ax_rob_req_o ( wide_ar_rob_req_out ),
.ax_rob_idx_o ( wide_ar_rob_idx_out ),
.rsp_valid_i ( wide_r_rob_valid_in ),
.rsp_ready_o ( wide_r_rob_ready_out ),
.rsp_i ( axi_wide_r_rob_in ),
.rsp_rob_req_i ( wide_r_rob_rob_req ),
.rsp_rob_idx_i ( wide_r_rob_rob_idx ),
.rsp_last_i ( wide_r_rob_last ),
.rsp_valid_o ( wide_r_rob_valid_out ),
.rsp_ready_i ( wide_r_rob_ready_in ),
.rsp_o ( axi_wide_r_rob_out )
);
/////////////////
// ROUTING //
/////////////////
axi_addr_t [NumNWAxiChannels-1:0] axi_req_addr;
id_t [NumNWAxiChannels-1:0] axi_rsp_src_id;
assign axi_req_addr[NarrowAw] = axi_narrow_aw_queue.addr;
assign axi_req_addr[NarrowAr] = axi_narrow_ar_queue.addr;
assign axi_req_addr[WideAw] = axi_wide_aw_queue.addr;
assign axi_req_addr[WideAr] = axi_wide_ar_queue.addr;
assign axi_rsp_src_id[NarrowB] = narrow_aw_buf_hdr_out.hdr.src_id;
assign axi_rsp_src_id[NarrowR] = narrow_ar_buf_hdr_out.hdr.src_id;
assign axi_rsp_src_id[WideB] = wide_aw_buf_hdr_out.hdr.src_id;
assign axi_rsp_src_id[WideR] = wide_ar_buf_hdr_out.hdr.src_id;
for (genvar ch = 0; ch < NumNWAxiChannels; ch++) begin : gen_route_comp
localparam nw_ch_e Ch = nw_ch_e'(ch);
if (Ch == NarrowAw || Ch == NarrowAr ||
Ch == WideAw || Ch == WideAr) begin : gen_req_route_comp
// Translate the address from AXI requests to a destination ID
// (or route if `SourceRouting` is used)
floo_route_comp #(
.RouteCfg ( RouteCfg ),
.id_t ( id_t ),
.addr_t ( axi_addr_t ),
.addr_rule_t ( sam_rule_t ),
.route_t ( route_t )
) i_floo_req_route_comp (
.clk_i,
.rst_ni,
.route_table_i,
.addr_map_i ( Sam ),
.id_i ( id_t'('0) ),
.addr_i ( axi_req_addr[ch] ),
.route_o ( route_out[ch] ),
.id_o ( id_out[ch] )
);
end else if (RouteCfg.RouteAlgo == floo_pkg::SourceRouting &&
(Ch == NarrowB || Ch == NarrowR ||
Ch == WideB || Ch == WideR)) begin : gen_rsp_route_comp
// Generally, the source ID from the request is used to route back
// the responses. However, in the case of `SourceRouting`, the source ID
// first needs to be translated into a route.
floo_route_comp #(
.RouteCfg ( RouteCfg ),
.UseIdTable ( 1'b0 ), // Overwrite `RouteCfg`
.id_t ( id_t ),
.addr_t ( axi_addr_t ),
.addr_rule_t ( sam_rule_t ),
.route_t ( route_t )
) i_floo_rsp_route_comp (
.clk_i,
.rst_ni,
.route_table_i,
.addr_i ( '0 ),
.addr_map_i ( '0 ),
.id_i ( axi_rsp_src_id[ch] ),
.route_o ( route_out[ch] ),
.id_o ( id_out[ch] )
);
end
end
if (RouteCfg.RouteAlgo == floo_pkg::SourceRouting) begin : gen_route_field
assign route_out[NarrowW] = narrow_aw_id_q;
assign route_out[WideW] = wide_aw_id_q;
assign dst_id = route_out;
end else begin : gen_dst_field
assign dst_id[NarrowAw] = id_out[NarrowAw];
assign dst_id[NarrowAr] = id_out[NarrowAr];
assign dst_id[WideAw] = id_out[WideAw];
assign dst_id[WideAr] = id_out[WideAr];
assign dst_id[NarrowB] = narrow_aw_buf_hdr_out.hdr.src_id;
assign dst_id[NarrowR] = narrow_ar_buf_hdr_out.hdr.src_id;
assign dst_id[WideB] = wide_aw_buf_hdr_out.hdr.src_id;
assign dst_id[WideR] = wide_ar_buf_hdr_out.hdr.src_id;
assign dst_id[NarrowW] = narrow_aw_id_q;
assign dst_id[WideW] = wide_aw_id_q;
end
`FFL(narrow_aw_id_q, dst_id[NarrowAw], axi_narrow_aw_queue_valid_out &&
axi_narrow_aw_queue_ready_in, '0)
`FFL(wide_aw_id_q, dst_id[WideAw], axi_wide_aw_queue_valid_out &&
axi_wide_aw_queue_ready_in, '0)
///////////////////
// FLIT PACKING //
///////////////////
always_comb begin
floo_narrow_aw = '0;
floo_narrow_aw.hdr.rob_req = narrow_aw_rob_req_out;
floo_narrow_aw.hdr.rob_idx = rob_idx_t'(narrow_aw_rob_idx_out);
floo_narrow_aw.hdr.dst_id = dst_id[NarrowAw];
floo_narrow_aw.hdr.src_id = id_i;
floo_narrow_aw.hdr.last = 1'b0; // AW and W need to be sent together
floo_narrow_aw.hdr.axi_ch = NarrowAw;
floo_narrow_aw.hdr.atop = axi_narrow_aw_queue.atop != axi_pkg::ATOP_NONE;
floo_narrow_aw.payload = axi_narrow_aw_queue;
end
always_comb begin
floo_narrow_w = '0;
floo_narrow_w.hdr.rob_req = narrow_aw_rob_req_out;
floo_narrow_w.hdr.rob_idx = rob_idx_t'(narrow_aw_rob_idx_out);
floo_narrow_w.hdr.dst_id = dst_id[NarrowW];
floo_narrow_w.hdr.src_id = id_i;
floo_narrow_w.hdr.last = axi_narrow_req_in.w.last;
floo_narrow_w.hdr.axi_ch = NarrowW;
floo_narrow_w.payload = axi_narrow_req_in.w;
end
always_comb begin
floo_narrow_ar = '0;
floo_narrow_ar.hdr.rob_req = narrow_ar_rob_req_out;
floo_narrow_ar.hdr.rob_idx = rob_idx_t'(narrow_ar_rob_idx_out);
floo_narrow_ar.hdr.dst_id = dst_id[NarrowAr];
floo_narrow_ar.hdr.src_id = id_i;
floo_narrow_ar.hdr.last = 1'b1;
floo_narrow_ar.hdr.axi_ch = NarrowAr;
floo_narrow_ar.payload = axi_narrow_ar_queue;
end
always_comb begin
floo_narrow_b = '0;
floo_narrow_b.hdr.rob_req = narrow_aw_buf_hdr_out.hdr.rob_req;
floo_narrow_b.hdr.rob_idx = rob_idx_t'(narrow_aw_buf_hdr_out.hdr.rob_idx);
floo_narrow_b.hdr.dst_id = dst_id[NarrowB];
floo_narrow_b.hdr.src_id = id_i;
floo_narrow_b.hdr.last = 1'b1;
floo_narrow_b.hdr.axi_ch = NarrowB;
floo_narrow_b.hdr.atop = narrow_aw_buf_hdr_out.hdr.atop;
floo_narrow_b.payload = axi_narrow_meta_buf_rsp_out.b;
floo_narrow_b.payload.id = narrow_aw_buf_hdr_out.id;
end
always_comb begin
floo_narrow_r = '0;
floo_narrow_r.hdr.rob_req = narrow_ar_buf_hdr_out.hdr.rob_req;
floo_narrow_r.hdr.rob_idx = rob_idx_t'(narrow_ar_buf_hdr_out.hdr.rob_idx);
floo_narrow_r.hdr.dst_id = dst_id[NarrowR];
floo_narrow_r.hdr.src_id = id_i;
floo_narrow_r.hdr.axi_ch = NarrowR;
floo_narrow_r.hdr.last = 1'b1; // There is no reason to do wormhole routing for R bursts
floo_narrow_r.hdr.atop = narrow_ar_buf_hdr_out.hdr.atop;
floo_narrow_r.payload = axi_narrow_meta_buf_rsp_out.r;
floo_narrow_r.payload.id = narrow_ar_buf_hdr_out.id;
end
always_comb begin
floo_wide_aw = '0;
floo_wide_aw.hdr.rob_req = wide_aw_rob_req_out;
floo_wide_aw.hdr.rob_idx = rob_idx_t'(wide_aw_rob_idx_out);
floo_wide_aw.hdr.dst_id = dst_id[WideAw];
floo_wide_aw.hdr.src_id = id_i;
floo_wide_aw.hdr.last = 1'b0; // AW and W need to be sent together
floo_wide_aw.hdr.axi_ch = WideAw;
floo_wide_aw.payload = axi_wide_aw_queue;
end
always_comb begin
floo_wide_w = '0;
floo_wide_w.hdr.rob_req = wide_aw_rob_req_out;
floo_wide_w.hdr.rob_idx = rob_idx_t'(wide_aw_rob_idx_out);
floo_wide_w.hdr.dst_id = dst_id[WideW];
floo_wide_w.hdr.src_id = id_i;
floo_wide_w.hdr.last = axi_wide_req_in.w.last;
floo_wide_w.hdr.axi_ch = WideW;
floo_wide_w.payload = axi_wide_req_in.w;
end
always_comb begin
floo_wide_ar = '0;
floo_wide_ar.hdr.rob_req = wide_ar_rob_req_out;
floo_wide_ar.hdr.rob_idx = rob_idx_t'(wide_ar_rob_idx_out);
floo_wide_ar.hdr.dst_id = dst_id[WideAr];
floo_wide_ar.hdr.src_id = id_i;
floo_wide_ar.hdr.last = 1'b1;
floo_wide_ar.hdr.axi_ch = WideAr;
floo_wide_ar.payload = axi_wide_ar_queue;
end
always_comb begin
floo_wide_b = '0;
floo_wide_b.hdr.rob_req = wide_aw_buf_hdr_out.hdr.rob_req;
floo_wide_b.hdr.rob_idx = rob_idx_t'(wide_aw_buf_hdr_out.hdr.rob_idx);
floo_wide_b.hdr.dst_id = dst_id[WideB];
floo_wide_b.hdr.src_id = id_i;
floo_wide_b.hdr.last = 1'b1;
floo_wide_b.hdr.axi_ch = WideB;
floo_wide_b.payload = axi_wide_meta_buf_rsp_out.b;
floo_wide_b.payload.id = wide_aw_buf_hdr_out.id;
end
always_comb begin
floo_wide_r = '0;
floo_wide_r.hdr.rob_req = wide_ar_buf_hdr_out.hdr.rob_req;
floo_wide_r.hdr.rob_idx = rob_idx_t'(wide_ar_buf_hdr_out.hdr.rob_idx);
floo_wide_r.hdr.dst_id = dst_id[WideR];
floo_wide_r.hdr.src_id = id_i;
floo_wide_r.hdr.axi_ch = WideR;
floo_wide_r.hdr.last = 1'b1; // There is no reason to do wormhole routing for R bursts
floo_wide_r.payload = axi_wide_meta_buf_rsp_out.r;
floo_wide_r.payload.id = wide_ar_buf_hdr_out.id;
end
always_comb begin
narrow_aw_w_sel_d = narrow_aw_w_sel_q;
wide_aw_w_sel_d = wide_aw_w_sel_q;
if (axi_narrow_aw_queue_valid_out && axi_narrow_aw_queue_ready_in) begin
narrow_aw_w_sel_d = SelW;
end
if (axi_narrow_req_in.w_valid && axi_narrow_rsp_out.w_ready &&
axi_narrow_req_in.w.last) begin
narrow_aw_w_sel_d = SelAw;
end
if (axi_wide_aw_queue_valid_out && axi_wide_aw_queue_ready_in) begin
wide_aw_w_sel_d = SelW;
end
if (axi_wide_req_in.w_valid && axi_wide_rsp_out.w_ready && axi_wide_req_in.w.last) begin
wide_aw_w_sel_d = SelAw;
end
end
`FF(narrow_aw_w_sel_q, narrow_aw_w_sel_d, SelAw)
`FF(wide_aw_w_sel_q, wide_aw_w_sel_d, SelAw)
assign floo_req_arb_req_in[NarrowW] = (narrow_aw_w_sel_q == SelAw) &&
(narrow_aw_rob_valid_out ||
((axi_narrow_aw_queue.atop != axi_pkg::ATOP_NONE) &&
axi_narrow_aw_queue_valid_out)) ||
(narrow_aw_w_sel_q == SelW) &&
axi_narrow_req_in.w_valid;
assign floo_req_arb_req_in[NarrowAw] = 1'b0; // AW and W need to be sent together
assign floo_req_arb_req_in[NarrowAr] = narrow_ar_rob_valid_out;
assign floo_req_arb_req_in[WideAr] = wide_ar_rob_valid_out;
assign floo_rsp_arb_req_in[NarrowB] = axi_narrow_meta_buf_rsp_out.b_valid;
assign floo_rsp_arb_req_in[NarrowR] = axi_narrow_meta_buf_rsp_out.r_valid;
assign floo_rsp_arb_req_in[WideB] = axi_wide_meta_buf_rsp_out.b_valid;
assign floo_wide_arb_req_in[WideW] = (wide_aw_w_sel_q == SelAw) &&
wide_aw_rob_valid_out ||
(wide_aw_w_sel_q == SelW) &&
axi_wide_req_in.w_valid;
assign floo_wide_arb_req_in[WideAw] = 1'b0; // AW and W need to be sent together
assign floo_wide_arb_req_in[WideR] = axi_wide_meta_buf_rsp_out.r_valid;
assign narrow_aw_rob_ready_in = floo_req_arb_gnt_out[NarrowW] &&
(narrow_aw_w_sel_q == SelAw);
assign axi_narrow_rsp_out.w_ready = floo_req_arb_gnt_out[NarrowW] &&
(narrow_aw_w_sel_q == SelW);
assign narrow_ar_rob_ready_in = floo_req_arb_gnt_out[NarrowAr];
assign wide_aw_rob_ready_in = floo_wide_arb_gnt_out[WideW] &&
(wide_aw_w_sel_q == SelAw);
assign axi_wide_rsp_out.w_ready = floo_wide_arb_gnt_out[WideW] &&
(wide_aw_w_sel_q == SelW);
assign wide_ar_rob_ready_in = floo_req_arb_gnt_out[WideAr];
assign floo_req_arb_in[NarrowAw] = '0;
assign floo_req_arb_in[NarrowW] = (narrow_aw_w_sel_q == SelAw)?
floo_narrow_aw : floo_narrow_w;
assign floo_req_arb_in[NarrowAr].narrow_ar = floo_narrow_ar;
assign floo_req_arb_in[WideAr].wide_ar = floo_wide_ar;
assign floo_rsp_arb_in[NarrowB].narrow_b = floo_narrow_b;
assign floo_rsp_arb_in[NarrowR].narrow_r = floo_narrow_r;
assign floo_rsp_arb_in[WideB].wide_b = floo_wide_b;
assign floo_wide_arb_in[WideAw] = '0;
assign floo_wide_arb_in[WideW] = (wide_aw_w_sel_q == SelAw)?
floo_wide_aw : floo_wide_w;
assign floo_wide_arb_in[WideR].wide_r = floo_wide_r;
///////////////////////
// FLIT ARBITRATION //
///////////////////////
floo_wormhole_arbiter #(
.NumRoutes ( 4 ),
.flit_t ( floo_req_generic_flit_t )
) i_req_wormhole_arbiter (
.clk_i,
.rst_ni,
.valid_i ( floo_req_arb_req_in ),
.data_i ( floo_req_arb_in ),
.ready_o ( floo_req_arb_gnt_out ),
.data_o ( floo_req_o.req ),
.ready_i ( floo_req_i.ready ),
.valid_o ( floo_req_o.valid )
);
floo_wormhole_arbiter #(
.NumRoutes ( 3 ),
.flit_t ( floo_rsp_generic_flit_t )
) i_rsp_wormhole_arbiter (
.clk_i,
.rst_ni,
.valid_i ( floo_rsp_arb_req_in ),
.data_i ( floo_rsp_arb_in ),
.ready_o ( floo_rsp_arb_gnt_out ),
.data_o ( floo_rsp_o.rsp ),
.ready_i ( floo_rsp_i.ready ),
.valid_o ( floo_rsp_o.valid )
);
floo_wormhole_arbiter #(
.NumRoutes ( 3 ),
.flit_t ( floo_wide_generic_flit_t )
) i_wide_wormhole_arbiter (
.clk_i,
.rst_ni,
.valid_i ( floo_wide_arb_req_in ),
.data_i ( floo_wide_arb_in ),
.ready_o ( floo_wide_arb_gnt_out ),
.data_o ( floo_wide_o.wide ),
.ready_i ( floo_wide_i.ready ),
.valid_o ( floo_wide_o.valid )
);
////////////////////
// FLIT UNPACKER //
////////////////////
logic is_atop_b_rsp, is_atop_r_rsp;
logic b_sel_atop, r_sel_atop;
logic b_rob_pending_q, r_rob_pending_q;
assign is_atop_b_rsp = AtopSupport && axi_valid_in[NarrowB] &&
floo_rsp_unpack_generic.hdr.atop;
assign is_atop_r_rsp = AtopSupport && axi_valid_in[NarrowR] &&
floo_rsp_unpack_generic.hdr.atop;
assign b_sel_atop = is_atop_b_rsp && !b_rob_pending_q;
assign r_sel_atop = is_atop_r_rsp && !r_rob_pending_q;
assign axi_narrow_unpack_aw = floo_req_in.narrow_aw.payload;
assign axi_narrow_unpack_w = floo_req_in.narrow_w.payload;
assign axi_narrow_unpack_ar = floo_req_in.narrow_ar.payload;
assign axi_narrow_unpack_r = floo_rsp_in.narrow_r.payload;
assign axi_narrow_unpack_b = floo_rsp_in.narrow_b.payload;
assign axi_wide_unpack_aw = floo_wide_in.wide_aw.payload;
assign axi_wide_unpack_w = floo_wide_in.wide_w.payload;
assign axi_wide_unpack_ar = floo_req_in.wide_ar.payload;
assign axi_wide_unpack_r = floo_wide_in.wide_r.payload;
assign axi_wide_unpack_b = floo_rsp_in.wide_b.payload;
assign floo_req_unpack_generic = floo_req_in.generic;
assign floo_rsp_unpack_generic = floo_rsp_in.generic;
assign floo_wide_unpack_generic = floo_wide_in.generic;
assign axi_valid_in[NarrowAw] = floo_req_in_valid &&
(floo_req_unpack_generic.hdr.axi_ch == NarrowAw);
assign axi_valid_in[NarrowW] = floo_req_in_valid &&
(floo_req_unpack_generic.hdr.axi_ch == NarrowW);
assign axi_valid_in[NarrowAr] = floo_req_in_valid &&
(floo_req_unpack_generic.hdr.axi_ch == NarrowAr);
assign axi_valid_in[WideAr] = floo_req_in_valid &&
(floo_req_unpack_generic.hdr.axi_ch == WideAr);
assign axi_valid_in[NarrowB] = ChimneyCfgN.EnMgrPort && floo_rsp_in_valid &&
(floo_rsp_unpack_generic.hdr.axi_ch == NarrowB);
assign axi_valid_in[NarrowR] = ChimneyCfgN.EnMgrPort && floo_rsp_in_valid &&
(floo_rsp_unpack_generic.hdr.axi_ch == NarrowR);
assign axi_valid_in[WideB] = ChimneyCfgW.EnMgrPort && floo_rsp_in_valid &&
(floo_rsp_unpack_generic.hdr.axi_ch == WideB);
assign axi_valid_in[WideAw] = floo_wide_in_valid &&
(floo_wide_unpack_generic.hdr.axi_ch == WideAw);
assign axi_valid_in[WideW] = floo_wide_in_valid &&
(floo_wide_unpack_generic.hdr.axi_ch == WideW);
assign axi_valid_in[WideR] = ChimneyCfgW.EnMgrPort && floo_wide_in_valid &&
(floo_wide_unpack_generic.hdr.axi_ch == WideR);
assign axi_ready_out[NarrowAw] = axi_narrow_meta_buf_rsp_out.aw_ready;