abstractaccelerator/design/dma_ctrl.sv

698 lines
41 KiB
Systemverilog

// SPDX-License-Identifier: Apache-2.0
// Copyright 2019 Western Digital Corporation or its affiliates.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use 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.
//********************************************************************************
// $Id$
//
// Function: Top level SWERV core file
// Comments:
//
//********************************************************************************
module dma_ctrl (
input logic clk,
input logic free_clk,
input logic rst_l,
input logic dma_bus_clk_en, // slave bus clock enable
input logic clk_override,
// AXI signals
// AXI Write Channels
input logic dma_axi_awvalid,
output logic dma_axi_awready,
input logic [`RV_DMA_BUS_TAG-1:0] dma_axi_awid,
input logic [31:0] dma_axi_awaddr,
input logic [2:0] dma_axi_awsize,
input logic [2:0] dma_axi_awprot,
input logic [7:0] dma_axi_awlen,
input logic [1:0] dma_axi_awburst,
input logic dma_axi_wvalid,
output logic dma_axi_wready,
input logic [63:0] dma_axi_wdata,
input logic [7:0] dma_axi_wstrb,
input logic dma_axi_wlast,
output logic dma_axi_bvalid,
input logic dma_axi_bready,
output logic [1:0] dma_axi_bresp,
output logic [`RV_DMA_BUS_TAG-1:0] dma_axi_bid,
// AXI Read Channels
input logic dma_axi_arvalid,
output logic dma_axi_arready,
input logic [`RV_DMA_BUS_TAG-1:0] dma_axi_arid,
input logic [31:0] dma_axi_araddr,
input logic [2:0] dma_axi_arsize,
input logic [2:0] dma_axi_arprot,
input logic [7:0] dma_axi_arlen,
input logic [1:0] dma_axi_arburst,
output logic dma_axi_rvalid,
input logic dma_axi_rready,
output logic [`RV_DMA_BUS_TAG-1:0] dma_axi_rid,
output logic [63:0] dma_axi_rdata,
output logic [1:0] dma_axi_rresp,
output logic dma_axi_rlast,
output logic dma_slv_algn_err,
// Debug signals
input logic [31:0] dbg_cmd_addr,
input logic [31:0] dbg_cmd_wrdata,
input logic dbg_cmd_valid,
input logic dbg_cmd_write, // 1: write command, 0: read_command
input logic [1:0] dbg_cmd_type, // 0:gpr 1:csr 2: memory
input logic [1:0] dbg_cmd_size, // size of the abstract mem access debug command
input logic dbg_dma_bubble, // Debug needs a bubble to send a valid
output logic dma_dbg_ready, // DMA is ready to accept debug request
output logic dma_dbg_cmd_done,
output logic dma_dbg_cmd_fail,
output logic [31:0] dma_dbg_rddata,
// Core side signals
output logic dma_dccm_req, // DMA dccm request (only one of dccm/iccm will be set)
output logic dma_iccm_req, // DMA iccm request
output logic [31:0] dma_mem_addr, // DMA request address
output logic [2:0] dma_mem_sz, // DMA request size
output logic dma_mem_write, // DMA write to dccm/iccm
output logic [63:0] dma_mem_wdata, // DMA write data
input logic dccm_dma_rvalid, // dccm data valid for DMA read
input logic dccm_dma_ecc_error, // ECC error on DMA read
input logic [63:0] dccm_dma_rdata, // dccm data for DMA read
input logic iccm_dma_rvalid, // iccm data valid for DMA read
input logic iccm_dma_ecc_error, // ECC error on DMA read
input logic [63:0] iccm_dma_rdata, // iccm data for DMA read
output logic dma_dccm_stall_any, // stall dccm pipe (bubble) so that DMA can proceed
output logic dma_iccm_stall_any, // stall iccm pipe (bubble) so that DMA can proceed
input logic dccm_ready, // dccm ready to accept DMA request
input logic iccm_ready, // iccm ready to accept DMA request
input logic dec_tlu_stall_dma, // stall dma accesses, tlu is attempting to enter halt/debug mode
input logic [2:0] dec_tlu_dma_qos_prty, // DMA QoS priority coming from MFDC [18:15]
input logic scan_mode
);
`include "global.h"
localparam DEPTH = DMA_BUF_DEPTH;
localparam DEPTH_PTR = $clog2(DEPTH);
localparam NACK_COUNT = 7;
logic [DEPTH-1:0] fifo_valid;
logic [DEPTH-1:0][1:0] fifo_error;
logic [DEPTH-1:0] fifo_dccm_valid;
logic [DEPTH-1:0] fifo_iccm_valid;
logic [DEPTH-1:0] fifo_data_valid;
logic [DEPTH-1:0] fifo_data_bus_valid;
logic [DEPTH-1:0] fifo_error_bus;
logic [DEPTH-1:0] fifo_rpend;
logic [DEPTH-1:0] fifo_done; // DMA trxn is done in core
logic [DEPTH-1:0] fifo_done_bus; // DMA trxn is done in core synced to bus
logic [DEPTH-1:0] fifo_rsp_done; // DMA response sent to bus
logic [DEPTH-1:0][31:0] fifo_addr;
logic [DEPTH-1:0][2:0] fifo_sz;
logic [DEPTH-1:0] fifo_write;
logic [DEPTH-1:0] fifo_posted_write;
logic [DEPTH-1:0] fifo_dbg;
logic [DEPTH-1:0][63:0] fifo_data;
logic [DEPTH-1:0][DMA_BUS_TAG-1:0] fifo_tag;
logic [DEPTH-1:0] fifo_cmd_en;
logic [DEPTH-1:0] fifo_valid_en;
logic [DEPTH-1:0] fifo_data_en;
logic [DEPTH-1:0] fifo_data_bus_en;
logic [DEPTH-1:0] fifo_pend_en;
logic [DEPTH-1:0] fifo_done_en;
logic [DEPTH-1:0] fifo_done_bus_en;
logic [DEPTH-1:0] fifo_error_en;
logic [DEPTH-1:0] fifo_error_bus_en;
//logic [DEPTH-1:0] fifo_rsp_done_en;
logic [DEPTH-1:0] fifo_reset;
logic [DEPTH-1:0][1:0] fifo_error_in;
logic [DEPTH-1:0][63:0] fifo_data_in;
logic fifo_write_in;
logic fifo_posted_write_in;
logic fifo_dbg_in;
logic [31:0] fifo_addr_in;
logic [2:0] fifo_sz_in;
logic [DEPTH_PTR-1:0] RspPtr, PrevRspPtr, NxtRspPtr;
logic [DEPTH_PTR-1:0] WrPtr, NxtWrPtr;
logic [DEPTH_PTR-1:0] RdPtr, NxtRdPtr;
logic [DEPTH_PTR-1:0] RdPtr_Q1, RdPtr_Q2, RdPtr_Q3;
logic WrPtrEn, RdPtrEn, RspPtrEn;
logic dma_dbg_cmd_error_in;
logic dma_dbg_cmd_done_q;
logic fifo_full, fifo_full_spec, fifo_empty;
logic dma_address_error, dma_alignment_error;
logic [3:0] num_fifo_vld;
logic dma_mem_req;
logic dma_addr_in_dccm;
logic dma_addr_in_iccm;
logic dma_addr_in_pic;
logic dma_addr_in_pic_region_nc;
logic dma_addr_in_dccm_region_nc;
logic dma_addr_in_iccm_region_nc;
logic [2:0] dma_nack_count_csr;
logic [2:0] dma_nack_count, dma_nack_count_d;
logic dma_buffer_c1_clken;
logic dma_free_clken;
logic dma_buffer_c1_clk;
logic dma_free_clk;
logic dma_bus_clk;
logic wrbuf_en, wrbuf_data_en;
logic wrbuf_cmd_sent, wrbuf_rst, wrbuf_data_rst;
logic wrbuf_vld;
logic wrbuf_data_vld;
logic wrbuf_posted;
logic [DMA_BUS_TAG-1:0] wrbuf_tag;
logic [2:0] wrbuf_size;
logic [31:0] wrbuf_addr;
logic [63:0] wrbuf_data;
logic [7:0] wrbuf_byteen;
logic rdbuf_en;
logic rdbuf_cmd_sent, rdbuf_rst;
logic rdbuf_vld;
logic [DMA_BUS_TAG-1:0] rdbuf_tag;
logic [2:0] rdbuf_size;
logic [31:0] rdbuf_addr;
logic axi_mstr_valid, axi_mstr_valid_q;
logic axi_mstr_write;
logic axi_mstr_posted_write;
logic [DMA_BUS_TAG-1:0] axi_mstr_tag;
logic [31:0] axi_mstr_addr;
logic [2:0] axi_mstr_size;
logic [63:0] axi_mstr_wdata;
logic [7:0] axi_mstr_wstrb;
logic axi_mstr_prty_in, axi_mstr_prty_en;
logic axi_mstr_priority;
logic axi_mstr_sel;
logic axi_slv_valid;
logic axi_slv_sent, axi_slv_sent_q;
logic axi_slv_write;
logic axi_slv_posted_write;
logic [DMA_BUS_TAG-1:0] axi_slv_tag;
logic [1:0] axi_slv_error;
logic [63:0] axi_slv_rdata;
logic dma_bus_clk_en_q;
logic fifo_full_spec_bus;
logic dbg_dma_bubble_bus;
logic dec_tlu_stall_dma_bus;
logic dma_fifo_ready;
//------------------------LOGIC STARTS HERE---------------------------------
// FIFO inputs
assign fifo_addr_in[31:0] = dbg_cmd_valid ? dbg_cmd_addr[31:0] : axi_mstr_addr[31:0];
assign fifo_sz_in[2:0] = dbg_cmd_valid ? {1'b0,dbg_cmd_size[1:0]} : axi_mstr_size[2:0];
assign fifo_write_in = dbg_cmd_valid ? dbg_cmd_write : axi_mstr_write;
assign fifo_posted_write_in = axi_mstr_valid & axi_mstr_posted_write;
assign fifo_dbg_in = dbg_cmd_valid;
//assign fifo_error_in[1:0] = dccm_dma_rvalid ? {1'b0,dccm_dma_ecc_error} : iccm_dma_rvalid ? {1'b0,iccm_dma_ecc_error} : {(dma_address_error | dma_alignment_error | dma_dbg_cmd_error_in), dma_alignment_error};
//assign fifo_data_in[63:0] = dccm_dma_rvalid ? dccm_dma_rdata[63:0] : (iccm_dma_rvalid ? iccm_dma_rdata[63:0] :
// (dbg_cmd_valid ? {2{dbg_cmd_wrdata[31:0]}} : axi_mstr_wdata[63:0]));
for (genvar i=0 ;i<DEPTH; i++) begin: GenFifo
assign fifo_valid_en[i] = axi_mstr_valid & (i == WrPtr[DEPTH_PTR-1:0]);
assign fifo_cmd_en[i] = ((axi_mstr_valid & dma_bus_clk_en) | (dbg_cmd_valid & dbg_cmd_type[1])) &
(i == WrPtr[DEPTH_PTR-1:0]);
assign fifo_data_en[i] = (((axi_mstr_valid & (axi_mstr_write | dma_address_error | dma_alignment_error) & dma_bus_clk_en) |
(dbg_cmd_valid & dbg_cmd_type[1] & dbg_cmd_write)) & (i == WrPtr[DEPTH_PTR-1:0])) |
((dccm_dma_rvalid & (i == RdPtr_Q3[DEPTH_PTR-1:0]))| (iccm_dma_rvalid & (i == RdPtr_Q2[DEPTH_PTR-1:0])));
assign fifo_data_bus_en[i] = (fifo_data_en[i] | fifo_data_valid[i]) & dma_bus_clk_en;
assign fifo_pend_en[i] = (dma_dccm_req | dma_iccm_req) & ~dma_mem_write & (i == RdPtr[DEPTH_PTR-1:0]);
assign fifo_error_en[i] = fifo_cmd_en[i] | (((dccm_dma_rvalid & dccm_dma_ecc_error & (i == RdPtr_Q3[DEPTH_PTR-1:0])) | (iccm_dma_rvalid & iccm_dma_ecc_error & (i == RdPtr_Q2[DEPTH_PTR-1:0]))));
assign fifo_error_bus_en[i] = (((|fifo_error_in[i][1:0]) & fifo_error_en[i]) | (|fifo_error[i])) & dma_bus_clk_en;
assign fifo_done_en[i] = (((|fifo_error[i]) | ((dma_dccm_req | dma_iccm_req) & dma_mem_write)) & (i == RdPtr[DEPTH_PTR-1:0])) |
((dccm_dma_rvalid & (i == RdPtr_Q3[DEPTH_PTR-1:0])) | (iccm_dma_rvalid & (i == RdPtr_Q2[DEPTH_PTR-1:0])));
assign fifo_done_bus_en[i] = (fifo_done_en[i] | fifo_done[i]) & dma_bus_clk_en;
//assign fifo_rsp_done_en[i] = fifo_valid[i] & ((axi_slv_sent & dma_bus_clk_en) | dma_dbg_cmd_done) & (i == RspPtr[DEPTH_PTR-1:0]);
//assign fifo_reset[i] = (fifo_done[i] | fifo_done_en[i]) & (fifo_rsp_done[i] | fifo_rsp_done_en[i]);
assign fifo_reset[i] = ((axi_slv_sent & dma_bus_clk_en) | dma_dbg_cmd_done) & (i == RspPtr[DEPTH_PTR-1:0]);
assign fifo_error_in[i] = (dccm_dma_rvalid & (i == RdPtr_Q3[DEPTH_PTR-1:0])) ? {1'b0,dccm_dma_ecc_error} : (iccm_dma_rvalid & (i == RdPtr_Q2[DEPTH_PTR-1:0])) ? {1'b0,iccm_dma_ecc_error} :
{(dma_address_error | dma_alignment_error | dma_dbg_cmd_error_in), dma_alignment_error};
assign fifo_data_in[i] = (fifo_error_en[i] & (|fifo_error_in[i])) ? (fifo_cmd_en[i] ? {32'b0,axi_mstr_addr[31:0]} : {32'b0,fifo_addr[i]}) :
((dccm_dma_rvalid & (i == RdPtr_Q3[DEPTH_PTR-1:0])) ? dccm_dma_rdata[63:0] : (iccm_dma_rvalid & (i == RdPtr_Q2[DEPTH_PTR-1:0])) ? iccm_dma_rdata[63:0] :
(dbg_cmd_valid ? {2{dbg_cmd_wrdata[31:0]}} : axi_mstr_wdata[63:0]));
rvdffsc #(1) fifo_valid_dff (.din(1'b1), .dout(fifo_valid[i]), .en(fifo_cmd_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(2) fifo_error_dff (.din(fifo_error_in[i]), .dout(fifo_error[i]), .en(fifo_error_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(1) fifo_error_bus_dff (.din(1'b1), .dout(fifo_error_bus[i]), .en(fifo_error_bus_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffs #(1) fifo_dccm_valid_dff (.din((dma_addr_in_dccm | dma_addr_in_pic)), .dout(fifo_dccm_valid[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffs #(1) fifo_iccm_valid_dff (.din(dma_addr_in_iccm), .dout(fifo_iccm_valid[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffsc #(1) fifo_data_valid_dff (.din(1'b1), .dout(fifo_data_valid[i]), .en(fifo_data_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(1) fifo_data_bus_valid_dff (.din(1'b1), .dout(fifo_data_bus_valid[i]), .en(fifo_data_bus_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(1) fifo_rpend_dff (.din(1'b1), .dout(fifo_rpend[i]), .en(fifo_pend_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(1) fifo_done_dff (.din(1'b1), .dout(fifo_done[i]), .en(fifo_done_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffsc #(1) fifo_done_bus_dff (.din(1'b1), .dout(fifo_done_bus[i]), .en(fifo_done_bus_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
//rvdffsc #(1) fifo_rsp_done_dff (.din(1'b1), .dout(fifo_rsp_done[i]), .en(fifo_rsp_done_en[i]), .clear(fifo_reset[i]), .clk(dma_free_clk), .*);
rvdffe #(32) fifo_addr_dff (.din(fifo_addr_in[31:0]), .dout(fifo_addr[i]), .en(fifo_cmd_en[i]), .*);
rvdffs #(3) fifo_sz_dff (.din(fifo_sz_in[2:0]), .dout(fifo_sz[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffs #(1) fifo_write_dff (.din(fifo_write_in), .dout(fifo_write[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffs #(1) fifo_posted_write_dff (.din(fifo_posted_write_in), .dout(fifo_posted_write[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffs #(1) fifo_dbg_dff (.din(fifo_dbg_in), .dout(fifo_dbg[i]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
rvdffe #(64) fifo_data_dff (.din(fifo_data_in[i]), .dout(fifo_data[i]), .en(fifo_data_en[i]), .*);
rvdffs #(DMA_BUS_TAG) fifo_tag_dff(.din(axi_mstr_tag[DMA_BUS_TAG-1:0]), .dout(fifo_tag[i][DMA_BUS_TAG-1:0]), .en(fifo_cmd_en[i]), .clk(dma_buffer_c1_clk), .*);
end
// Pointer logic
assign NxtWrPtr[DEPTH_PTR-1:0] = WrPtr[DEPTH_PTR-1:0] + 1'b1;
assign NxtRdPtr[DEPTH_PTR-1:0] = RdPtr[DEPTH_PTR-1:0] + 1'b1;
assign NxtRspPtr[DEPTH_PTR-1:0] = RspPtr[DEPTH_PTR-1:0] + 1'b1;
// Don't increment the ptr for posted writes if 1)fifo error (it will increment only with response) 2) response done (this is the full case)
//assign RspPtr[DEPTH_PTR-1:0] = (dma_dbg_cmd_done_q | axi_slv_sent_q) ? (PrevRspPtr[DEPTH_PTR-1:0] + 1'b1) : PrevRspPtr[DEPTH_PTR-1:0];
//assign RspPtr[DEPTH_PTR-1:0] = (dma_dbg_cmd_done_q | axi_slv_sent_q |
// (fifo_valid[PrevRspPtr] & fifo_write[PrevRspPtr] & fifo_posted_write[PrevRspPtr] & ~(|fifo_error[PrevRspPtr]) & ~fifo_rsp_done[PrevRspPtr])) ? (PrevRspPtr[DEPTH_PTR-1:0] + 1'b1) : PrevRspPtr[DEPTH_PTR-1:0];
assign WrPtrEn = |fifo_cmd_en[DEPTH-1:0];
assign RdPtrEn = (dma_dccm_req | dma_iccm_req) | ((|fifo_error[RdPtr]) & ~fifo_done[RdPtr]);
//assign RdPtrEn = |(fifo_done_en[DEPTH-1:0] & ~fifo_done[DEPTH-1:0]);
assign RspPtrEn = (dma_dbg_cmd_done | (axi_slv_sent & dma_bus_clk_en));
//assign RspPtrEn = dma_bus_clk_en | dma_dbg_cmd_done_q;
rvdffs #(DEPTH_PTR) WrPtr_dff(.din(NxtWrPtr[DEPTH_PTR-1:0]), .dout(WrPtr[DEPTH_PTR-1:0]), .en(WrPtrEn), .clk(dma_free_clk), .*);
rvdffs #(DEPTH_PTR) RdPtr_dff(.din(NxtRdPtr[DEPTH_PTR-1:0]), .dout(RdPtr[DEPTH_PTR-1:0]), .en(RdPtrEn), .clk(dma_free_clk), .*);
rvdffs #(DEPTH_PTR) RspPtr_dff(.din(NxtRspPtr[DEPTH_PTR-1:0]), .dout(RspPtr[DEPTH_PTR-1:0]), .en(RspPtrEn), .clk(dma_free_clk), .*);
//rvdffs #(DEPTH_PTR) RspPtr_dff(.din(RspPtr[DEPTH_PTR-1:0]), .dout(PrevRspPtr[DEPTH_PTR-1:0]), .en(RspPtrEn), .clk(dma_free_clk), .*);
rvdff #(DEPTH_PTR) RdPtrQ1_dff(.din(RdPtr[DEPTH_PTR-1:0]), .dout(RdPtr_Q1[DEPTH_PTR-1:0]), .clk(dma_free_clk), .*);
rvdff #(DEPTH_PTR) RdPtrQ2_dff(.din(RdPtr_Q1[DEPTH_PTR-1:0]), .dout(RdPtr_Q2[DEPTH_PTR-1:0]), .clk(dma_free_clk), .*);
rvdff #(DEPTH_PTR) RdPtrQ3_dff(.din(RdPtr_Q2[DEPTH_PTR-1:0]), .dout(RdPtr_Q3[DEPTH_PTR-1:0]), .clk(dma_free_clk), .*);
// Miscellaneous signals
assign fifo_full = fifo_full_spec_bus;
always_comb begin
num_fifo_vld[3:0] = 4'b0;
for (int i=0; i<DEPTH; i++) begin
num_fifo_vld[3:0] += {3'b0,(fifo_valid_en[i] | fifo_valid[i])};
end
end
assign fifo_full_spec = ((num_fifo_vld[3:0] == DEPTH) & ~(|fifo_reset[DEPTH-1:0]));
assign dma_fifo_ready = ~(fifo_full | dbg_dma_bubble_bus | dec_tlu_stall_dma_bus);
// Error logic
assign dma_address_error = axi_mstr_valid & (~(dma_addr_in_dccm | dma_addr_in_iccm)); // request not for ICCM or DCCM
assign dma_alignment_error = axi_mstr_valid & ~dma_address_error &
(((axi_mstr_size[2:0] == 3'h1) & (axi_mstr_addr[0] | (axi_mstr_write & (axi_mstr_wstrb[axi_mstr_addr[2:0]+:2] != 2'b11)))) | // HW size but unaligned
((axi_mstr_size[2:0] == 3'h2) & ((|axi_mstr_addr[1:0]) | (axi_mstr_write & (axi_mstr_wstrb[axi_mstr_addr[2:0]+:4] != 4'hf)))) | // W size but unaligned
((axi_mstr_size[2:0] == 3'h3) & ((|axi_mstr_addr[2:0]) | (axi_mstr_write & (axi_mstr_wstrb[7:0] != 8'hff)))) | // DW size but unaligned
(dma_addr_in_iccm & ~((axi_mstr_size[1:0] == 2'b10) | (axi_mstr_size[1:0] == 2'b11))) | // ICCM access not word size
(dma_addr_in_dccm & axi_mstr_write & ~((axi_mstr_size[1:0] == 2'b10) | (axi_mstr_size[1:0] == 2'b11)))); // DCCM write not word size
//Dbg outputs
assign dma_dbg_ready = fifo_empty & dbg_dma_bubble;
assign dma_dbg_cmd_done = (fifo_valid[RspPtr] & fifo_dbg[RspPtr] & (fifo_write[RspPtr] | fifo_data_valid[RspPtr] | (|fifo_error[RspPtr])));
assign dma_dbg_rddata[31:0] = fifo_addr[RspPtr][2] ? fifo_data[RspPtr][63:32] : fifo_data[RspPtr][31:0];
assign dma_dbg_cmd_fail = |fifo_error[RspPtr];
assign dma_dbg_cmd_error_in = dbg_cmd_valid & (dbg_cmd_type[1:0] == 2'b10) &
((~(dma_addr_in_dccm | dma_addr_in_iccm | dma_addr_in_pic)) | (dbg_cmd_size[1:0] != 2'b10)); // Only word accesses allowed
//(dma_addr_in_iccm & ~((dbg_cmd_size[1:0] == 2'b10) | (dbg_cmd_size[1:0] == 2'b11))));
// Block the decode if fifo full
assign dma_dccm_stall_any = dma_mem_req & fifo_dccm_valid[RdPtr] & (dma_nack_count >= dma_nack_count_csr);
assign dma_iccm_stall_any = dma_mem_req & fifo_iccm_valid[RdPtr] & (dma_nack_count >= dma_nack_count_csr);
// Used to indicate ready to debug
assign fifo_empty = ~(|(fifo_valid_en[DEPTH-1:0] | fifo_valid[DEPTH-1:0]) | axi_mstr_valid | axi_slv_sent_q); // We want RspPtr to settle before accepting debug command
// Nack counter, stall the lsu pipe if 7 nacks
assign dma_nack_count_csr[2:0] = dec_tlu_dma_qos_prty[2:0];
assign dma_nack_count_d[2:0] = (dma_nack_count[2:0] >= dma_nack_count_csr[2:0]) ? ({3{~(dma_dccm_req | dma_iccm_req)}} & dma_nack_count[2:0]) :
(dma_mem_req & ~(dma_dccm_req | dma_iccm_req)) ? (dma_nack_count[2:0] + 1'b1) : 3'b0;
rvdffs #(3) nack_count_dff(.din(dma_nack_count_d[2:0]), .dout(dma_nack_count[2:0]), .en(dma_mem_req), .clk(dma_free_clk), .*);
// Core outputs
assign dma_mem_req = fifo_valid[RdPtr] & ~fifo_rpend[RdPtr] & ~fifo_done[RdPtr] & ~(|fifo_error[RdPtr]) & (~fifo_write[RdPtr] | fifo_data_valid[RdPtr]);
assign dma_dccm_req = dma_mem_req & fifo_dccm_valid[RdPtr] & dccm_ready;
assign dma_iccm_req = dma_mem_req & fifo_iccm_valid[RdPtr] & iccm_ready;
assign dma_mem_addr[31:0] = fifo_addr[RdPtr];
assign dma_mem_sz[2:0] = fifo_sz[RdPtr];
assign dma_mem_write = fifo_write[RdPtr];
assign dma_mem_wdata[63:0] = fifo_data[RdPtr];
// Address check dccm
rvrangecheck #(.CCM_SADR(`RV_DCCM_SADR),
.CCM_SIZE(`RV_DCCM_SIZE)) addr_dccm_rangecheck (
.addr(fifo_addr_in[31:0]),
.in_range(dma_addr_in_dccm),
.in_region(dma_addr_in_dccm_region_nc)
);
// Address check iccm
`ifdef RV_ICCM_ENABLE
rvrangecheck #(.CCM_SADR(`RV_ICCM_SADR),
.CCM_SIZE(`RV_ICCM_SIZE)) addr_iccm_rangecheck (
.addr(fifo_addr_in[31:0]),
.in_range(dma_addr_in_iccm),
.in_region(dma_addr_in_iccm_region_nc)
);
`else
assign dma_addr_in_iccm = '0;
assign dma_addr_in_iccm_region_nc = '0;
`endif
// PIC memory address check
rvrangecheck #(.CCM_SADR(`RV_PIC_BASE_ADDR),
.CCM_SIZE(`RV_PIC_SIZE)) addr_pic_rangecheck (
.addr(fifo_addr_in[31:0]),
.in_range(dma_addr_in_pic),
.in_region(dma_addr_in_pic_region_nc)
);
// Inputs
rvdff #(1) ahbs_bus_clken_ff (.din(dma_bus_clk_en), .dout(dma_bus_clk_en_q), .clk(free_clk), .*);
rvdff #(1) fifo_full_bus_ff (.din(fifo_full_spec), .dout(fifo_full_spec_bus), .clk(dma_bus_clk), .*);
rvdff #(1) dbg_dma_bubble_ff (.din(dbg_dma_bubble), .dout(dbg_dma_bubble_bus), .clk(dma_bus_clk), .*);
rvdff #(1) dec_tlu_stall_dma_ff (.din(dec_tlu_stall_dma), .dout(dec_tlu_stall_dma_bus), .clk(dma_bus_clk), .*);
rvdff #(1) dma_dbg_cmd_doneff (.din(dma_dbg_cmd_done), .dout(dma_dbg_cmd_done_q), .clk(free_clk), .*);
// Clock Gating logic
assign dma_buffer_c1_clken = (axi_mstr_valid & dma_bus_clk_en) | dbg_cmd_valid | dec_tlu_stall_dma | clk_override;
assign dma_free_clken = (axi_mstr_valid | axi_mstr_valid_q | axi_slv_valid | axi_slv_sent_q | dbg_cmd_valid | dma_dbg_cmd_done | dma_dbg_cmd_done_q | (|fifo_valid[DEPTH-1:0]) | wrbuf_vld | rdbuf_vld | dec_tlu_stall_dma | clk_override);
rvclkhdr dma_buffer_c1cgc ( .en(dma_buffer_c1_clken), .l1clk(dma_buffer_c1_clk), .* );
rvclkhdr dma_free_cgc (.en(dma_free_clken), .l1clk(dma_free_clk), .*);
rvclkhdr dma_bus_cgc (.en(dma_bus_clk_en), .l1clk(dma_bus_clk), .*);
// Write channel buffer
assign wrbuf_en = dma_axi_awvalid & dma_axi_awready;
assign wrbuf_data_en = dma_axi_wvalid & dma_axi_wready;
assign wrbuf_cmd_sent = axi_mstr_valid & axi_mstr_write;
assign wrbuf_rst = wrbuf_cmd_sent & ~wrbuf_en;
assign wrbuf_data_rst = wrbuf_cmd_sent & ~wrbuf_data_en;
rvdffsc #(.WIDTH(1)) wrbuf_vldff(.din(1'b1), .dout(wrbuf_vld), .en(wrbuf_en), .clear(wrbuf_rst), .clk(dma_bus_clk), .*);
rvdffsc #(.WIDTH(1)) wrbuf_data_vldff(.din(1'b1), .dout(wrbuf_data_vld), .en(wrbuf_data_en), .clear(wrbuf_data_rst), .clk(dma_bus_clk), .*);
rvdffs #(.WIDTH(1)) wrbuf_postedff(.din(1'b0), .dout(wrbuf_posted), .en(wrbuf_en), .clk(dma_bus_clk), .*);
rvdffs #(.WIDTH(DMA_BUS_TAG)) wrbuf_tagff(.din(dma_axi_awid[DMA_BUS_TAG-1:0]), .dout(wrbuf_tag[DMA_BUS_TAG-1:0]), .en(wrbuf_en), .clk(dma_bus_clk), .*);
rvdffs #(.WIDTH(3)) wrbuf_sizeff(.din(dma_axi_awsize[2:0]), .dout(wrbuf_size[2:0]), .en(wrbuf_en), .clk(dma_bus_clk), .*);
rvdffe #(.WIDTH(32)) wrbuf_addrff(.din(dma_axi_awaddr[31:0]), .dout(wrbuf_addr[31:0]), .en(wrbuf_en & dma_bus_clk_en), .*);
rvdffe #(.WIDTH(64)) wrbuf_dataff(.din(dma_axi_wdata[63:0]), .dout(wrbuf_data[63:0]), .en(wrbuf_data_en & dma_bus_clk_en), .*);
rvdffs #(.WIDTH(8)) wrbuf_byteenff(.din(dma_axi_wstrb[7:0]), .dout(wrbuf_byteen[7:0]), .en(wrbuf_data_en), .clk(dma_bus_clk), .*);
// Read channel buffer
assign rdbuf_en = dma_axi_arvalid & dma_axi_arready;
assign rdbuf_cmd_sent = axi_mstr_valid & ~axi_mstr_write & dma_fifo_ready;
assign rdbuf_rst = rdbuf_cmd_sent & ~rdbuf_en;
rvdffsc #(.WIDTH(1)) rdbuf_vldff(.din(1'b1), .dout(rdbuf_vld), .en(rdbuf_en), .clear(rdbuf_rst), .clk(dma_bus_clk), .*);
rvdffs #(.WIDTH(DMA_BUS_TAG)) rdbuf_tagff(.din(dma_axi_arid[DMA_BUS_TAG-1:0]), .dout(rdbuf_tag[DMA_BUS_TAG-1:0]), .en(rdbuf_en), .clk(dma_bus_clk), .*);
rvdffs #(.WIDTH(3)) rdbuf_sizeff(.din(dma_axi_arsize[2:0]), .dout(rdbuf_size[2:0]), .en(rdbuf_en), .clk(dma_bus_clk), .*);
rvdffe #(.WIDTH(32)) rdbuf_addrff(.din(dma_axi_araddr[31:0]), .dout(rdbuf_addr[31:0]), .en(rdbuf_en & dma_bus_clk_en), .*);
assign dma_axi_awready = ~(wrbuf_vld & ~wrbuf_cmd_sent);
assign dma_axi_wready = ~(wrbuf_data_vld & ~wrbuf_cmd_sent);
assign dma_axi_arready = ~(rdbuf_vld & ~rdbuf_cmd_sent);
//Generate a single request from read/write channel
assign axi_mstr_valid = ((wrbuf_vld & wrbuf_data_vld) | rdbuf_vld) & dma_fifo_ready;
assign axi_mstr_tag[DMA_BUS_TAG-1:0] = axi_mstr_sel ? wrbuf_tag[DMA_BUS_TAG-1:0] : rdbuf_tag[DMA_BUS_TAG-1:0];
assign axi_mstr_write = axi_mstr_sel;
assign axi_mstr_posted_write = axi_mstr_sel & wrbuf_posted;
assign axi_mstr_addr[31:0] = axi_mstr_sel ? wrbuf_addr[31:0] : rdbuf_addr[31:0];
assign axi_mstr_size[2:0] = axi_mstr_sel ? wrbuf_size[2:0] : rdbuf_size[2:0];
assign axi_mstr_wdata[63:0] = wrbuf_data[63:0];
assign axi_mstr_wstrb[7:0] = wrbuf_byteen[7:0];
// Sel=1 -> write has higher priority
assign axi_mstr_sel = (wrbuf_vld & wrbuf_data_vld & rdbuf_vld) ? axi_mstr_priority : (wrbuf_vld & wrbuf_data_vld);
assign axi_mstr_prty_in = ~axi_mstr_priority;
assign axi_mstr_prty_en = axi_mstr_valid;
rvdffs #(.WIDTH(1)) mstr_prtyff(.din(axi_mstr_prty_in), .dout(axi_mstr_priority), .en(axi_mstr_prty_en), .clk(dma_bus_clk), .*);
rvdff #(.WIDTH(1)) axi_mstr_validff (.din(axi_mstr_valid), .dout(axi_mstr_valid_q), .clk(dma_bus_clk), .*);
rvdff #(.WIDTH(1)) axi_slv_sentff (.din(axi_slv_sent), .dout(axi_slv_sent_q), .clk(dma_bus_clk), .*);
//assign axi_slv_valid = fifo_valid[RspPtr] & ~fifo_rsp_done[RspPtr] & ~fifo_dbg[RspPtr] &
// ((fifo_write[RspPtr] & fifo_done_bus[RspPtr]) | (~fifo_write[RspPtr] & fifo_data_bus_valid[RspPtr]) | fifo_error_bus[RspPtr]);
assign axi_slv_valid = fifo_valid[RspPtr] & ~fifo_dbg[RspPtr] & fifo_done_bus[RspPtr];
assign axi_slv_tag[DMA_BUS_TAG-1:0] = fifo_tag[RspPtr];
//assign axi_slv_rdata[63:0] = (|fifo_error[RspPtr]) ? {32'b0,fifo_addr[RspPtr]} : fifo_data[RspPtr];
assign axi_slv_rdata[63:0] = fifo_data[RspPtr];
assign axi_slv_write = fifo_write[RspPtr];
assign axi_slv_posted_write = axi_slv_write & fifo_posted_write[RspPtr];
assign axi_slv_error[1:0] = fifo_error[RspPtr][0] ? 2'b10 : (fifo_error[RspPtr][1] ? 2'b11 : 2'b0);
// AXI response channel signals
assign dma_axi_bvalid = axi_slv_valid & axi_slv_write;
assign dma_axi_bresp[1:0] = axi_slv_error[1:0];
assign dma_axi_bid[DMA_BUS_TAG-1:0] = axi_slv_tag[DMA_BUS_TAG-1:0];
assign dma_axi_rvalid = axi_slv_valid & ~axi_slv_write;
assign dma_axi_rresp[1:0] = axi_slv_error;
assign dma_axi_rid[DMA_BUS_TAG-1:0] = axi_slv_tag[DMA_BUS_TAG-1:0];
assign dma_axi_rdata[63:0] = axi_slv_rdata[63:0];
assign dma_axi_rlast = 1'b1;
assign axi_slv_sent = (dma_axi_bvalid & dma_axi_bready) | (dma_axi_rvalid & dma_axi_rready);
assign dma_slv_algn_err = fifo_error[RspPtr][1];
`ifdef ASSERT_ON
//assert_nack_count: assert #0 (dma_nack_count[2:0] < 3'h4);
for (genvar i=0; i<DEPTH; i++) begin
//assert_picm_rspdone_and_novalid: assert #0 (~fifo_rsp_done[i] | fifo_valid[i]);
assert_done_and_novalid: assert #0 (~fifo_done[i] | fifo_valid[i]);
end
// Assertion to check AXI write address is aligned to size
property dma_axi_write_trxn_aligned;
@(posedge dma_bus_clk) dma_axi_awvalid |-> ((dma_axi_awsize[2:0] == 3'h0) |
((dma_axi_awsize[2:0] == 3'h1) & (dma_axi_awaddr[0] == 1'b0)) |
((dma_axi_awsize[2:0] == 3'h2) & (dma_axi_awaddr[1:0] == 2'b0)) |
((dma_axi_awsize[2:0] == 3'h3) & (dma_axi_awaddr[2:0] == 3'b0)));
endproperty
// assert_dma_write_trxn_aligned: assert property (dma_axi_write_trxn_aligned) else
// $display("Assertion dma_axi_write_trxn_aligned failed: dma_axi_awvalid=1'b%b, dma_axi_awsize=3'h%h, dma_axi_awaddr=32'h%h",dma_axi_awvalid, dma_axi_awsize[2:0], dma_axi_awaddr[31:0]);
// Assertion to check AXI read address is aligned to size
property dma_axi_read_trxn_aligned;
@(posedge dma_bus_clk) dma_axi_arvalid |-> ((dma_axi_arsize[2:0] == 3'h0) |
((dma_axi_arsize[2:0] == 3'h1) & (dma_axi_araddr[0] == 1'b0)) |
((dma_axi_arsize[2:0] == 3'h2) & (dma_axi_araddr[1:0] == 2'b0)) |
((dma_axi_arsize[2:0] == 3'h3) & (dma_axi_araddr[2:0] == 3'b0)));
endproperty
// assert_dma_read_trxn_aligned: assert property (dma_axi_read_trxn_aligned) else
// $display("Assertion dma_axi_read_trxn_aligned failed: dma_axi_arvalid=1'b%b, dma_axi_arsize=3'h%h, dma_axi_araddr=32'h%h",dma_axi_arvalid, dma_axi_arsize[2:0], dma_axi_araddr[31:0]);
// Assertion to check write size is 8 byte or less
property dma_axi_awsize_check;
@(posedge dma_bus_clk) disable iff(~rst_l) (dma_axi_awvalid & dma_axi_awready) |-> (dma_axi_awsize[2] == 1'b0);
endproperty
assert_dma_axi_awsize_check: assert property (dma_axi_awsize_check) else
$display("DMA AXI awsize is illegal. Size greater than 8B not supported");
// Assertion to check there are no burst commands
property dma_axi_awlen_check;
@(posedge dma_bus_clk) disable iff(~rst_l) (dma_axi_awvalid & dma_axi_awready) |-> (dma_axi_awlen[7:0] == 8'b0);
endproperty
assert_dma_axi_awlen_check: assert property (dma_axi_awlen_check) else
$display("DMA AXI awlen is illegal. Length greater than 0 not supported");
// Assertion to check write size is 8 byte or less
property dma_axi_arsize_check;
@(posedge dma_bus_clk) disable iff(~rst_l) (dma_axi_arvalid & dma_axi_arready) |-> (dma_axi_arsize[2] == 1'b0);
endproperty
assert_dma_axi_arsize_check: assert property (dma_axi_arsize_check) else
$display("DMA AXI arsize is illegal, Size bigger than 8B not supported");
// Assertion to check there are no burst commands
property dma_axi_arlen_check;
@(posedge dma_bus_clk) disable iff(~rst_l) (dma_axi_arvalid & dma_axi_arready) |-> (dma_axi_arlen[7:0] == 8'b0);
endproperty
assert_dma_axi_arlen_check: assert property (dma_axi_arlen_check) else
$display("DMA AXI arlen greater than 0 not supported.");
// Assertion to check cmd valid stays stable during entire bus clock
property dma_axi_awvalid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_awvalid != $past(dma_axi_awvalid)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_awvalid_stable: assert property (dma_axi_awvalid_stable) else
$display("DMA AXI awvalid changed in middle of bus clock");
// Assertion to check cmd ready stays stable during entire bus clock
property dma_axi_awready_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_awready != $past(dma_axi_awready)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_awready_stable: assert property (dma_axi_awready_stable) else
$display("DMA AXI awready changed in middle of bus clock");
// Assertion to check cmd tag stays stable during entire bus clock
property dma_axi_awid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_awvalid & (dma_axi_awid[DMA_BUS_TAG-1:0] != $past(dma_axi_awid[DMA_BUS_TAG-1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_awid_stable: assert property (dma_axi_awid_stable) else
$display("DMA AXI awid changed in middle of bus clock");
// Assertion to check cmd addr stays stable during entire bus clock
property dma_axi_awaddr_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_awvalid & (dma_axi_awaddr[31:0] != $past(dma_axi_awaddr[31:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_awaddr_stable: assert property (dma_axi_awaddr_stable) else
$display("DMA AXI awaddr changed in middle of bus clock");
// Assertion to check cmd length stays stable during entire bus clock
property dma_axi_awsize_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_awvalid & (dma_axi_awsize[2:0] != $past(dma_axi_awsize[2:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_awsize_stable: assert property (dma_axi_awsize_stable) else
$display("DMA AXI awsize changed in middle of bus clock");
// Assertion to check cmd valid stays stable during entire bus clock
property dma_axi_wvalid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_wvalid != $past(dma_axi_wvalid)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_wvalid_stable: assert property (dma_axi_wvalid_stable) else
$display("DMA AXI wvalid changed in middle of bus clock");
// Assertion to check cmd ready stays stable during entire bus clock
property dma_axi_wready_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_wready != $past(dma_axi_wready)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_wready_stable: assert property (dma_axi_wready_stable) else
$display("DMA AXI wready changed in middle of bus clock");
// Assertion to check cmd wbe stays stable during entire bus clock
property dma_axi_wstrb_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_wvalid & (dma_axi_wstrb[7:0] != $past(dma_axi_wstrb[7:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_wstrb_stable: assert property (dma_axi_wstrb_stable) else
$display("DMA AXI wstrb changed in middle of bus clock");
// Assertion to check cmd wdata stays stable during entire bus clock
property dma_axi_wdata_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_wvalid & (dma_axi_wdata[63:0] != $past(dma_axi_wdata[63:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_wdata_stable: assert property (dma_axi_wdata_stable) else
$display("DMA AXI wdata changed in middle of bus clock");
// Assertion to check cmd valid stays stable during entire bus clock
property dma_axi_arvalid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_arvalid != $past(dma_axi_arvalid)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_arvalid_stable: assert property (dma_axi_arvalid_stable) else
$display("DMA AXI arvalid changed in middle of bus clock");
// Assertion to check cmd ready stays stable during entire bus clock
property dma_axi_arready_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_arready != $past(dma_axi_arready)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_arready_stable: assert property (dma_axi_arready_stable) else
$display("DMA AXI arready changed in middle of bus clock");
// Assertion to check cmd tag stays stable during entire bus clock
property dma_axi_arid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_arvalid & (dma_axi_arid[DMA_BUS_TAG-1:0] != $past(dma_axi_arid[DMA_BUS_TAG-1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_arid_stable: assert property (dma_axi_arid_stable) else
$display("DMA AXI arid changed in middle of bus clock");
// Assertion to check cmd addr stays stable during entire bus clock
property dma_axi_araddr_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_arvalid & (dma_axi_araddr[31:0] != $past(dma_axi_araddr[31:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_araddr_stable: assert property (dma_axi_araddr_stable) else
$display("DMA AXI araddr changed in middle of bus clock");
// Assertion to check cmd length stays stable during entire bus clock
property dma_axi_arsize_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_arvalid & (dma_axi_arsize[2:0] != $past(dma_axi_arsize[2:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_arsize_stable: assert property (dma_axi_arsize_stable) else
$display("DMA AXI arsize changed in middle of bus clock");
//Assertion to check write rsp valid stays stable during entire bus clock
property dma_axi_bvalid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_bvalid != $past(dma_axi_bvalid)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_bvalid_stable: assert property (dma_axi_bvalid_stable) else
$display("DMA AXI bvalid changed in middle of bus clock");
// //Assertion to check write rsp ready stays stable during entire bus clock
// property dma_axi_bready_stable;
// @(posedge clk) (dma_axi_bready != $past(dma_axi_bready)) |-> $past(dma_bus_clk_en);
// endproperty
// assert_dma_axi_bready_stable: assert property (dma_axi_bready_stable) else
// $display("DMA AXI bready changed in middle of bus clock");
//Assertion to check write rsp stays stable during entire bus clock
property dma_axi_bresp_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_bvalid & (dma_axi_bresp[1:0] != $past(dma_axi_bresp[1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_bresp_stable: assert property (dma_axi_bresp_stable) else
$display("DMA AXI bvalid changed in middle of bus clock");
// Assertion to check write rsp tag stays stable during entire bus clock
property dma_axi_bid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_bvalid & (dma_axi_bid[DMA_BUS_TAG-1:0] != $past(dma_axi_bid[DMA_BUS_TAG-1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_bid_stable: assert property (dma_axi_bid_stable) else
$display("DMA AXI bid changed in middle of bus clock");
//Assertion to check write rsp valid stays stable during entire bus clock
property dma_axi_rvalid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_rvalid != $past(dma_axi_rvalid)) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_rvalid_stable: assert property (dma_axi_rvalid_stable) else
$display("DMA AXI bvalid changed in middle of bus clock");
// //Assertion to check write rsp ready stays stable during entire bus clock
// property dma_axi_rready_stable;
// @(posedge clk) (dma_axi_rready != $past(dma_axi_rready)) |-> $past(dma_bus_clk_en);
// endproperty
// assert_dma_axi_rready_stable: assert property (dma_axi_rready_stable) else
// $display("DMA AXI bready changed in middle of bus clock");
//Assertion to check write rsp stays stable during entire bus clock
property dma_axi_rresp_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_rvalid & (dma_axi_rresp[1:0] != $past(dma_axi_rresp[1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_rresp_stable: assert property (dma_axi_rresp_stable) else
$display("DMA AXI bvalid changed in middle of bus clock");
// Assertion to check write rsp tag stays stable during entire bus clock
property dma_axi_rid_stable;
@(posedge clk) disable iff(~rst_l) (dma_axi_rvalid & (dma_axi_rid[DMA_BUS_TAG-1:0] != $past(dma_axi_rid[DMA_BUS_TAG-1:0]))) |-> $past(dma_bus_clk_en);
endproperty
assert_dma_axi_rid_stable: assert property (dma_axi_rid_stable) else
$display("DMA AXI bid changed in middle of bus clock");
`endif
endmodule // dma_ctrl