abstractaccelerator/design/ifu/ifu_bp_ctl.sv

1778 lines
97 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.
//********************************************************************************
//********************************************************************************
// Function: Branch predictor
// Comments:
//
//
// Bank3 : Bank2 : Bank1 : Bank0
// FA C 8 4 0
//********************************************************************************
module ifu_bp_ctl
import swerv_types::*;
(
input logic clk,
input logic active_clk,
input logic clk_override,
input logic rst_l,
input logic ic_hit_f2, // Icache hit, enables F2 address capture
input logic [31:1] ifc_fetch_addr_f1, // look up btb address
input logic [31:1] ifc_fetch_addr_f2, // to tgt calc
input logic ifc_fetch_req_f1, // F1 valid
input logic ifc_fetch_req_f2, // F2 valid
input br_tlu_pkt_t dec_tlu_br0_wb_pkt, // BP commit update packet, includes errors
input br_tlu_pkt_t dec_tlu_br1_wb_pkt, // BP commit update packet, includes errors
input logic dec_tlu_flush_lower_wb, // used to move EX4 RS to EX1 and F
input logic dec_tlu_flush_leak_one_wb, // don't hit for leak one fetches
input logic dec_tlu_bpred_disable, // disable all branch prediction
input logic exu_i0_br_ret_e4, // EX4 ret stack update
input logic exu_i1_br_ret_e4, // EX4 ret stack update
input logic exu_i0_br_call_e4, // EX4 ret stack update
input logic exu_i1_br_call_e4, // EX4 ret stack update
input predict_pkt_t exu_mp_pkt, // mispredict packet
input rets_pkt_t exu_rets_e1_pkt, // EX1 rets packet
input rets_pkt_t exu_rets_e4_pkt, // EX4 rets packet
`ifdef REAL_COMM_RS
input logic [31:1] exu_i0_pc_e1, // Used for RS computation
input logic [31:1] exu_i1_pc_e1, // Used for RS computation
input logic [31:1] dec_tlu_i0_pc_e4, // Used for RS computation
input logic [31:1] dec_tlu_i1_pc_e4, // Used for RS computation
`endif
input logic [`RV_BHT_GHR_RANGE] exu_mp_eghr, // execute ghr (for patching fghr)
input logic exu_flush_final, // all flushes
input logic exu_flush_upper_e2, // flush upper, either i0 or i1, cp EX1 RS to F RS
output logic ifu_bp_kill_next_f2, // kill next fetch, taken target found
output logic [31:1] ifu_bp_btb_target_f2, // predicted target PC
output logic [7:1] ifu_bp_inst_mask_f2, // tell ic which valids to kill because of a taken branch, right justified
output logic [`RV_BHT_GHR_RANGE] ifu_bp_fghr_f2, // fetch ghr
`ifdef RV_BTB_48
output logic [7:0][1:0] ifu_bp_way_f2, // way
`else
output logic [7:0] ifu_bp_way_f2, // way
`endif
output logic [7:0] ifu_bp_ret_f2, // predicted ret
output logic [7:0] ifu_bp_hist1_f2, // history counters for all 4 potential branches, bit 1, right justified
output logic [7:0] ifu_bp_hist0_f2, // history counters for all 4 potential branches, bit 0, right justified
output logic [11:0] ifu_bp_poffset_f2, // predicted target
output logic [7:0] ifu_bp_pc4_f2, // pc4 indication, right justified
output logic [7:0] ifu_bp_valid_f2, // branch valid, right justified
input logic scan_mode
);
`define TAG 16+`RV_BTB_BTAG_SIZE:17
localparam PC4=4;
localparam BOFF=3;
localparam CALL=2;
localparam RET=1;
localparam BV=0;
localparam LRU_SIZE=`RV_BTB_ARRAY_DEPTH;
localparam NUM_BHT_LOOP = (`RV_BHT_ARRAY_DEPTH > 16 ) ? 16 : `RV_BHT_ARRAY_DEPTH;
localparam NUM_BHT_LOOP_INNER_HI = (`RV_BHT_ARRAY_DEPTH > 16 ) ?`RV_BHT_ADDR_LO+3 : `RV_BHT_ADDR_HI;
localparam NUM_BHT_LOOP_OUTER_LO = (`RV_BHT_ARRAY_DEPTH > 16 ) ?`RV_BHT_ADDR_LO+4 : `RV_BHT_ADDR_LO;
localparam BHT_NO_ADDR_MATCH = ( `RV_BHT_ARRAY_DEPTH <= 16 );
logic exu_mp_valid_write;
logic exu_mp_ataken;
logic exu_mp_valid; // conditional branch mispredict
logic exu_mp_boffset; // branch offsett
logic exu_mp_pc4; // branch is a 4B inst
logic exu_mp_call; // branch is a call inst
logic exu_mp_ret; // branch is a ret inst
logic exu_mp_ja; // branch is a jump always
logic [1:0] exu_mp_hist; // new history
logic [11:0] exu_mp_tgt; // target offset
logic [`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] exu_mp_addr; // BTB/BHT address
logic [1:0] exu_mp_bank; // write bank; based on branch PC[3:2]
logic [`RV_BTB_BTAG_SIZE-1:0] exu_mp_btag; // branch tag
logic [`RV_BHT_GHR_RANGE] exu_mp_fghr; // original fetch ghr (for bht update)
logic dec_tlu_br0_v_wb; // WB stage history update
logic [1:0] dec_tlu_br0_hist_wb; // new history
logic [`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] dec_tlu_br0_addr_wb; // addr
logic [1:0] dec_tlu_br0_bank_wb; // write bank; based on branch PC[3:2]
logic dec_tlu_br0_error_wb; // error; invalidate bank
logic dec_tlu_br0_start_error_wb; // error; invalidate all 4 banks in fg
logic [`RV_BHT_GHR_RANGE] dec_tlu_br0_fghr_wb;
logic dec_tlu_br1_v_wb; // WB stage history update
logic [1:0] dec_tlu_br1_hist_wb; // new history
logic [`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] dec_tlu_br1_addr_wb; // addr
logic [1:0] dec_tlu_br1_bank_wb; // write bank; based on branch PC[3:2]
logic dec_tlu_br1_error_wb; // error
logic dec_tlu_br1_start_error_wb; // error; invalidate all 4 banks in fg
logic [`RV_BHT_GHR_RANGE] dec_tlu_br1_fghr_wb;
logic [3:0] use_mp_way;
logic [`RV_RET_STACK_SIZE-1:0][31:1] rets_out, rets_in, e1_rets_out, e1_rets_in, e4_rets_out, e4_rets_in;
logic [`RV_RET_STACK_SIZE-1:0] rsenable;
logic [11:0] btb_rd_tgt_f2;
logic btb_rd_pc4_f2, btb_rd_boffset_f2, btb_rd_call_f2, btb_rd_ret_f2;
logic [3:1] bp_total_branch_offset_f2;
logic [31:1] bp_btb_target_adder_f2;
logic [31:1] bp_rs_call_target_f2;
logic rs_push, rs_pop, rs_hold;
logic [`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] btb_rd_addr_f1, btb_wr_addr, btb_rd_addr_f2;
logic [`RV_BTB_BTAG_SIZE-1:0] btb_wr_tag, fetch_rd_tag_f1, fetch_rd_tag_f2;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_wr_data;
logic [3:0] btb_wr_en_way0, btb_wr_en_way1;
logic dec_tlu_error_wb, dec_tlu_all_banks_error_wb, btb_valid, dec_tlu_br0_middle_wb, dec_tlu_br1_middle_wb;
logic [`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] btb_error_addr_wb;
logic [1:0] dec_tlu_error_bank_wb;
logic branch_error_collision_f1, fetch_mp_collision_f1, fetch_mp_collision_f2;
logic [6:0] fgmask_f2;
logic [3:0] branch_error_bank_conflict_f1, branch_error_bank_conflict_f2;
logic [`RV_BHT_GHR_RANGE] merged_ghr, fghr_ns, fghr;
logic [3:0] num_valids;
logic [LRU_SIZE-1:0] btb_lru_b0_f, btb_lru_b0_hold, btb_lru_b0_ns, btb_lru_b1_f, btb_lru_b1_hold, btb_lru_b1_ns,
btb_lru_b2_f, btb_lru_b2_hold, btb_lru_b2_ns, btb_lru_b3_f, btb_lru_b3_hold, btb_lru_b3_ns,
fetch_wrindex_dec, fetch_wrlru_b0, fetch_wrlru_b1, fetch_wrlru_b2, fetch_wrlru_b3,
mp_wrindex_dec, mp_wrlru_b0, mp_wrlru_b1, mp_wrlru_b2, mp_wrlru_b3;
logic [3:0] btb_lru_rd_f2, mp_bank_decoded, mp_bank_decoded_f, lru_update_valid_f2;
logic [3:0] tag_match_way0_f2, tag_match_way1_f2;
logic [7:0] way_raw, bht_dir_f2, btb_sel_f2, wayhit_f2;
logic [7:0] btb_sel_mask_f2, bht_valid_f2, bht_force_taken_f2;
logic leak_one_f1, leak_one_f2, ifc_fetch_req_f2_raw;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way0_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way0_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way0_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way0_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way1_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way1_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way1_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way1_out ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way0_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way0_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way0_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way0_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way1_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way1_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way1_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way1_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way0_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way0_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way0_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way0_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way1_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way1_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way1_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way1_f2 ;
logic final_h;
logic btb_fg_crossing_f2;
logic rs_correct;
logic middle_of_bank;
`ifdef RV_BTB_48
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way2_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way2_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way2_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way2_f2_in ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way2_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way2_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way2_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way2_f2 ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank0_rd_data_way2_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank1_rd_data_way2_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank2_rd_data_way2_out ;
logic [LRU_SIZE-1:0][16+`RV_BTB_BTAG_SIZE:0] btb_bank3_rd_data_way2_out ;
logic [3:0] btb_wr_en_way2, tag_match_way2_f2, fetch_lru_bank_hit_f2;
logic [7:0] tag_match_way2_expanded_f2;
logic [1:0] exu_mp_way, exu_mp_way_f, dec_tlu_br0_way_wb, dec_tlu_br1_way_wb, dec_tlu_way_wb, dec_tlu_way_wb_f;
`else // !`ifdef RV_BTB_48
logic exu_mp_way, exu_mp_way_f, dec_tlu_br0_way_wb, dec_tlu_br1_way_wb, dec_tlu_way_wb, dec_tlu_way_wb_f;
`endif
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0e_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1e_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2e_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3e_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank0o_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank1o_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank2o_rd_data_f2 ;
logic [16+`RV_BTB_BTAG_SIZE:0] btb_bank3o_rd_data_f2 ;
logic [7:0] tag_match_way0_expanded_f2, tag_match_way1_expanded_f2;
logic [1:0] bht_bank0_rd_data_f2 ;
logic [1:0] bht_bank1_rd_data_f2 ;
logic [1:0] bht_bank2_rd_data_f2 ;
logic [1:0] bht_bank3_rd_data_f2 ;
logic [1:0] bht_bank4_rd_data_f2 ;
logic [1:0] bht_bank5_rd_data_f2 ;
logic [1:0] bht_bank6_rd_data_f2 ;
logic [1:0] bht_bank7_rd_data_f2 ;
assign exu_mp_valid = exu_mp_pkt.misp & ~leak_one_f2; // conditional branch mispredict
assign exu_mp_boffset = exu_mp_pkt.boffset; // branch offset
assign exu_mp_pc4 = exu_mp_pkt.pc4; // branch is a 4B inst
assign exu_mp_call = exu_mp_pkt.pcall; // branch is a call inst
assign exu_mp_ret = exu_mp_pkt.pret; // branch is a ret inst
assign exu_mp_ja = exu_mp_pkt.pja; // branch is a jump always
assign exu_mp_way = exu_mp_pkt.way; // repl way
assign exu_mp_hist[1:0] = exu_mp_pkt.hist[1:0]; // new history
assign exu_mp_tgt[11:0] = exu_mp_pkt.toffset[11:0] ; // target offset
assign exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] = exu_mp_pkt.index[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] ; // BTB/BHT address
assign exu_mp_bank[1:0] = exu_mp_pkt.bank[1:0] ; // write bank = exu_mp_pkt.; based on branch PC[3:2]
assign exu_mp_btag[`RV_BTB_BTAG_SIZE-1:0] = exu_mp_pkt.btag[`RV_BTB_BTAG_SIZE-1:0] ; // branch tag
assign exu_mp_fghr[`RV_BHT_GHR_RANGE] = exu_mp_pkt.fghr[`RV_BHT_GHR_RANGE] ; // original fetch ghr (for bht update)
assign exu_mp_ataken = exu_mp_pkt.ataken;
assign dec_tlu_br0_v_wb = dec_tlu_br0_wb_pkt.valid;
assign dec_tlu_br0_hist_wb[1:0] = dec_tlu_br0_wb_pkt.hist[1:0];
assign dec_tlu_br0_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] = dec_tlu_br0_wb_pkt.index[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
assign dec_tlu_br0_bank_wb[1:0] = dec_tlu_br0_wb_pkt.bank[1:0];
assign dec_tlu_br0_error_wb = dec_tlu_br0_wb_pkt.br_error;
assign dec_tlu_br0_middle_wb = dec_tlu_br0_wb_pkt.middle;
assign dec_tlu_br0_way_wb = dec_tlu_br0_wb_pkt.way;
assign dec_tlu_br0_start_error_wb = dec_tlu_br0_wb_pkt.br_start_error;
assign dec_tlu_br0_fghr_wb[`RV_BHT_GHR_RANGE] = dec_tlu_br0_wb_pkt.fghr[`RV_BHT_GHR_RANGE];
assign dec_tlu_br1_v_wb = dec_tlu_br1_wb_pkt.valid;
assign dec_tlu_br1_hist_wb[1:0] = dec_tlu_br1_wb_pkt.hist[1:0];
assign dec_tlu_br1_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] = dec_tlu_br1_wb_pkt.index[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
assign dec_tlu_br1_bank_wb[1:0] = dec_tlu_br1_wb_pkt.bank[1:0];
assign dec_tlu_br1_middle_wb = dec_tlu_br1_wb_pkt.middle;
assign dec_tlu_br1_error_wb = dec_tlu_br1_wb_pkt.br_error;
assign dec_tlu_br1_way_wb = dec_tlu_br1_wb_pkt.way;
assign dec_tlu_br1_start_error_wb = dec_tlu_br1_wb_pkt.br_start_error;
assign dec_tlu_br1_fghr_wb[`RV_BHT_GHR_RANGE] = dec_tlu_br1_wb_pkt.fghr[`RV_BHT_GHR_RANGE];
// ----------------------------------------------------------------------
// READ
// ----------------------------------------------------------------------
// hash the incoming fetch PC, first guess at hashing algorithm
rvbtb_addr_hash f1hash(.pc(ifc_fetch_addr_f1[31:1]), .hash(btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]));
rvbtb_addr_hash f2hash(.pc(ifc_fetch_addr_f2[31:1]), .hash(btb_rd_addr_f2[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]));
// based on the fetch group offset(PC[3:2]) and direction bits, findfirst from fetchPC
// this sel is zero/onehot
// Put the table below in a file and run espresso to generate the btb_sel_f2 and btb_vmask_raw_f2 equations
// espresso -oeqntott -eeat <file> | addassign
//
// .i 11
// .o 15
// .ilb ifc_fetch_addr_f2[3] ifc_fetch_addr_f2[2] ifc_fetch_addr_f2[1] bht_dir_f2[7] bht_dir_f2[6] bht_dir_f2[5] bht_dir_f2[4] bht_dir_f2[3] bht_dir_f2[2] bht_dir_f2[1] bht_dir_f2[0]
// .ob btb_sel_f2[7] btb_sel_f2[6] btb_sel_f2[5] btb_sel_f2[4] btb_sel_f2[3] btb_sel_f2[2] btb_sel_f2[1] btb_sel_f2[0] btb_vmask_raw_f2[7] btb_vmask_raw_f2[6] btb_vmask_raw_f2[5] btb_vmask_raw_f2[4] btb_vmask_raw_f2[3] btb_vmask_raw_f2[2] btb_vmask_raw_f2[1]
// .type fr
// ##faddress[3:1] dir[7:0] sel[7:0] mask[7:1]
// 000 -------1 00000001 0000000
// 000 ------10 00000010 0000001
// 000 -----100 00000100 0000010
// 000 ----1000 00001000 0000100
// 000 ---10000 00010000 0001000
// 000 --100000 00100000 0010000
// 000 -1000000 01000000 0100000
// 000 10000000 10000000 1000000
//
// 001 ------1- 00000010 0000000
// 001 -----10- 00000100 0000001
// 001 ----100- 00001000 0000010
// 001 ---1000- 00010000 0000100
// 001 --10000- 00100000 0001000
// 001 -100000- 01000000 0010000
// 001 1000000- 10000000 0110000
//
// 010 -----1-- 00000100 0000000
// 010 ----10-- 00001000 0000001
// 010 ---100-- 00010000 0000010
// 010 --1000-- 00100000 0000100
// 010 -10000-- 01000000 0001000
// 010 100000-- 10000000 0010000
//
// 011 ----1--- 00001000 0000000
// 011 ---10--- 00010000 0000001
// 011 --100--- 00100000 0000010
// 011 -1000--- 01000000 0000100
// 011 10000--- 10000000 0001000
//
// 100 ---1---- 00010000 0000000
// 100 --10---- 00100000 0000001
// 100 -100---- 01000000 0000010
// 100 1000---- 10000000 0000100
//
// 101 --1----- 00100000 0000000
// 101 -10----- 01000000 0000001
// 101 100----- 10000000 0000010
//
// 110 -1------ 01000000 0000000
// 110 10------ 10000000 0000001
//
// 111 1------- 10000000 0000000
assign btb_sel_f2[7] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6]
& ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]) | (
ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]) | (
ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& ~bht_dir_f2[6] & ~bht_dir_f2[5]) | (ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6]) | (
ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]);
assign btb_sel_f2[6] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2]) | (~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3]) | (ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]) | (
ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5]) | (ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & bht_dir_f2[6]);
assign btb_sel_f2[5] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]
& ~bht_dir_f2[1]) | (~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2]) | (~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]) | (
ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4]) | (ifc_fetch_addr_f2[3]
& ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1] & bht_dir_f2[5]);
assign btb_sel_f2[4] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]
& ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (~ifc_fetch_addr_f2[3]
& ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1] & bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[4] & ~bht_dir_f2[3]) | (ifc_fetch_addr_f2[3]
& ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & bht_dir_f2[4]);
assign btb_sel_f2[3] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]
& ~bht_dir_f2[0]) | (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[3] & ~bht_dir_f2[2]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1] & bht_dir_f2[3]);
assign btb_sel_f2[2] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[2] & ~bht_dir_f2[1]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & bht_dir_f2[2]);
assign btb_sel_f2[1] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[1]);
assign btb_sel_f2[0] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[0]);
// vmask[0] is always 1
logic [7:0] btb_vmask_raw_f2;
assign btb_vmask_raw_f2[7] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]);
assign btb_vmask_raw_f2[6] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]);
assign btb_vmask_raw_f2[5] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]
& ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6]
& ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]
& ~bht_dir_f2[1] & ~bht_dir_f2[0]);
assign btb_vmask_raw_f2[4] = (~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]
& ~bht_dir_f2[3]) | (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]
& ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1] & bht_dir_f2[6]
& ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]
& ~bht_dir_f2[1]);
assign btb_vmask_raw_f2[3] = (ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]);
assign btb_vmask_raw_f2[2] = (ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ifc_fetch_addr_f2[1] & ~bht_dir_f2[6] & ~bht_dir_f2[5]) | (
ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[6] & ~bht_dir_f2[5] & ~bht_dir_f2[4]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[2] & ~bht_dir_f2[1] & ~bht_dir_f2[0]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[5] & ~bht_dir_f2[4] & ~bht_dir_f2[3]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[3] & ~bht_dir_f2[2] & ~bht_dir_f2[1]) | (
~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[4] & ~bht_dir_f2[3] & ~bht_dir_f2[2]);
assign btb_vmask_raw_f2[1] = (ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & ~bht_dir_f2[6]) | (ifc_fetch_addr_f2[3]
& ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1] & bht_dir_f2[6]
& ~bht_dir_f2[5]) | (ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[5] & ~bht_dir_f2[4]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]
& bht_dir_f2[1] & ~bht_dir_f2[0]) | (~ifc_fetch_addr_f2[3]
& ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1] & bht_dir_f2[4]
& ~bht_dir_f2[3]) | (~ifc_fetch_addr_f2[3] & ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1] & bht_dir_f2[3] & ~bht_dir_f2[2]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2] & ifc_fetch_addr_f2[1]
& bht_dir_f2[2] & ~bht_dir_f2[1]);
// end of espresso generated equations
logic[7:1] btb_vmask_f2;
assign btb_vmask_f2[7:1] = {btb_vmask_raw_f2[7],
|btb_vmask_raw_f2[7:6],
|btb_vmask_raw_f2[7:5],
|btb_vmask_raw_f2[7:4],
|btb_vmask_raw_f2[7:3],
|btb_vmask_raw_f2[7:2],
|btb_vmask_raw_f2[7:1]};
// Errors colliding with fetches must kill the btb/bht hit.
assign branch_error_collision_f1 = dec_tlu_error_wb & (btb_error_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]);
assign branch_error_bank_conflict_f1[3:0] = {4{branch_error_collision_f1}} & (decode2_4(dec_tlu_error_bank_wb[1:0]) | {4{dec_tlu_all_banks_error_wb}});
assign fetch_mp_collision_f1 = ( (exu_mp_btag[`RV_BTB_BTAG_SIZE-1:0] == fetch_rd_tag_f1[`RV_BTB_BTAG_SIZE-1:0]) &
exu_mp_valid & ifc_fetch_req_f1 &
(exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO])
);
// set on leak one, hold until next flush without leak one
assign leak_one_f1 = (dec_tlu_flush_leak_one_wb & dec_tlu_flush_lower_wb) | (leak_one_f2 & ~dec_tlu_flush_lower_wb);
`ifdef RV_BTB_48
rvdff #(15) coll_ff (.*, .clk(active_clk),
`else
rvdff #(13) coll_ff (.*, .clk(active_clk),
`endif
.din({branch_error_bank_conflict_f1[3:0], fetch_mp_collision_f1, mp_bank_decoded[3:0], exu_mp_way, dec_tlu_way_wb, leak_one_f1, ifc_fetch_req_f1}),
.dout({branch_error_bank_conflict_f2[3:0], fetch_mp_collision_f2, mp_bank_decoded_f[3:0], exu_mp_way_f, dec_tlu_way_wb_f, leak_one_f2, ifc_fetch_req_f2_raw}));
`ifdef RV_BTB_48
// 2 -way SA, figure out the way hit and mux accordingly
assign tag_match_way0_f2[3:0] = {btb_bank3_rd_data_way0_f2[BV] & (btb_bank3_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank2_rd_data_way0_f2[BV] & (btb_bank2_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank1_rd_data_way0_f2[BV] & (btb_bank1_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank0_rd_data_way0_f2[BV] & (btb_bank0_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0])} &
~({4{dec_tlu_way_wb_f==2'b0}} & branch_error_bank_conflict_f2[3:0]) & {4{ifc_fetch_req_f2_raw & ~leak_one_f2}};
assign tag_match_way1_f2[3:0] = {btb_bank3_rd_data_way1_f2[BV] & (btb_bank3_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank2_rd_data_way1_f2[BV] & (btb_bank2_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank1_rd_data_way1_f2[BV] & (btb_bank1_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank0_rd_data_way1_f2[BV] & (btb_bank0_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0])} &
~({4{dec_tlu_way_wb_f[0]}} & branch_error_bank_conflict_f2[3:0]) & {4{ifc_fetch_req_f2_raw & ~leak_one_f2}};
assign tag_match_way2_f2[3:0] = {btb_bank3_rd_data_way2_f2[BV] & (btb_bank3_rd_data_way2_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank2_rd_data_way2_f2[BV] & (btb_bank2_rd_data_way2_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank1_rd_data_way2_f2[BV] & (btb_bank1_rd_data_way2_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank0_rd_data_way2_f2[BV] & (btb_bank0_rd_data_way2_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0])} &
~({4{dec_tlu_way_wb_f[1]}} & branch_error_bank_conflict_f2[3:0]) & {4{ifc_fetch_req_f2_raw & ~leak_one_f2}};
`else
// 2 -way SA, figure out the way hit and mux accordingly
assign tag_match_way0_f2[3:0] = {btb_bank3_rd_data_way0_f2[BV] & (btb_bank3_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank2_rd_data_way0_f2[BV] & (btb_bank2_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank1_rd_data_way0_f2[BV] & (btb_bank1_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank0_rd_data_way0_f2[BV] & (btb_bank0_rd_data_way0_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0])} &
~({4{~dec_tlu_way_wb_f}} & branch_error_bank_conflict_f2[3:0]) & {4{ifc_fetch_req_f2_raw & ~leak_one_f2}};
assign tag_match_way1_f2[3:0] = {btb_bank3_rd_data_way1_f2[BV] & (btb_bank3_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank2_rd_data_way1_f2[BV] & (btb_bank2_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank1_rd_data_way1_f2[BV] & (btb_bank1_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]),
btb_bank0_rd_data_way1_f2[BV] & (btb_bank0_rd_data_way1_f2[`TAG] == fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0])} &
~({4{dec_tlu_way_wb_f}} & branch_error_bank_conflict_f2[3:0]) & {4{ifc_fetch_req_f2_raw & ~leak_one_f2}};
`endif
// Both ways could hit, use the offset bit to reorder
assign tag_match_way0_expanded_f2[7:0] = {tag_match_way0_f2[3] & (btb_bank3_rd_data_way0_f2[BOFF] ^ btb_bank3_rd_data_way0_f2[PC4]),
tag_match_way0_f2[3] & ~(btb_bank3_rd_data_way0_f2[BOFF] ^ btb_bank3_rd_data_way0_f2[PC4]),
tag_match_way0_f2[2] & (btb_bank2_rd_data_way0_f2[BOFF] ^ btb_bank2_rd_data_way0_f2[PC4]),
tag_match_way0_f2[2] & ~(btb_bank2_rd_data_way0_f2[BOFF] ^ btb_bank2_rd_data_way0_f2[PC4]),
tag_match_way0_f2[1] & (btb_bank1_rd_data_way0_f2[BOFF] ^ btb_bank1_rd_data_way0_f2[PC4]),
tag_match_way0_f2[1] & ~(btb_bank1_rd_data_way0_f2[BOFF] ^ btb_bank1_rd_data_way0_f2[PC4]),
tag_match_way0_f2[0] & (btb_bank0_rd_data_way0_f2[BOFF] ^ btb_bank0_rd_data_way0_f2[PC4]),
tag_match_way0_f2[0] & ~(btb_bank0_rd_data_way0_f2[BOFF] ^ btb_bank0_rd_data_way0_f2[PC4])};
assign tag_match_way1_expanded_f2[7:0] = {tag_match_way1_f2[3] & (btb_bank3_rd_data_way1_f2[BOFF] ^ btb_bank3_rd_data_way1_f2[PC4]),
tag_match_way1_f2[3] & ~(btb_bank3_rd_data_way1_f2[BOFF] ^ btb_bank3_rd_data_way1_f2[PC4]),
tag_match_way1_f2[2] & (btb_bank2_rd_data_way1_f2[BOFF] ^ btb_bank2_rd_data_way1_f2[PC4]),
tag_match_way1_f2[2] & ~(btb_bank2_rd_data_way1_f2[BOFF] ^ btb_bank2_rd_data_way1_f2[PC4]),
tag_match_way1_f2[1] & (btb_bank1_rd_data_way1_f2[BOFF] ^ btb_bank1_rd_data_way1_f2[PC4]),
tag_match_way1_f2[1] & ~(btb_bank1_rd_data_way1_f2[BOFF] ^ btb_bank1_rd_data_way1_f2[PC4]),
tag_match_way1_f2[0] & (btb_bank0_rd_data_way1_f2[BOFF] ^ btb_bank0_rd_data_way1_f2[PC4]),
tag_match_way1_f2[0] & ~(btb_bank0_rd_data_way1_f2[BOFF] ^ btb_bank0_rd_data_way1_f2[PC4])};
`ifdef RV_BTB_48
assign tag_match_way2_expanded_f2[7:0] = {tag_match_way2_f2[3] & (btb_bank3_rd_data_way2_f2[BOFF] ^ btb_bank3_rd_data_way2_f2[PC4]),
tag_match_way2_f2[3] & ~(btb_bank3_rd_data_way2_f2[BOFF] ^ btb_bank3_rd_data_way2_f2[PC4]),
tag_match_way2_f2[2] & (btb_bank2_rd_data_way2_f2[BOFF] ^ btb_bank2_rd_data_way2_f2[PC4]),
tag_match_way2_f2[2] & ~(btb_bank2_rd_data_way2_f2[BOFF] ^ btb_bank2_rd_data_way2_f2[PC4]),
tag_match_way2_f2[1] & (btb_bank1_rd_data_way2_f2[BOFF] ^ btb_bank1_rd_data_way2_f2[PC4]),
tag_match_way2_f2[1] & ~(btb_bank1_rd_data_way2_f2[BOFF] ^ btb_bank1_rd_data_way2_f2[PC4]),
tag_match_way2_f2[0] & (btb_bank0_rd_data_way2_f2[BOFF] ^ btb_bank0_rd_data_way2_f2[PC4]),
tag_match_way2_f2[0] & ~(btb_bank0_rd_data_way2_f2[BOFF] ^ btb_bank0_rd_data_way2_f2[PC4])};
assign wayhit_f2[7:0] = tag_match_way0_expanded_f2[7:0] | tag_match_way1_expanded_f2[7:0] | tag_match_way2_expanded_f2[7:0];
assign btb_bank3o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[7]}} & btb_bank3_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[7]}} & btb_bank3_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[7]}} & btb_bank3_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank3e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[6]}} & btb_bank3_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[6]}} & btb_bank3_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[6]}} & btb_bank3_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank2o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[5]}} & btb_bank2_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[5]}} & btb_bank2_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[5]}} & btb_bank2_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank2e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[4]}} & btb_bank2_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[4]}} & btb_bank2_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[4]}} & btb_bank2_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank1o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[3]}} & btb_bank1_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[3]}} & btb_bank1_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[3]}} & btb_bank1_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank1e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[2]}} & btb_bank1_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[2]}} & btb_bank1_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[2]}} & btb_bank1_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank0o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[1]}} & btb_bank0_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[1]}} & btb_bank0_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[1]}} & btb_bank0_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank0e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[0]}} & btb_bank0_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[0]}} & btb_bank0_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way2_expanded_f2[0]}} & btb_bank0_rd_data_way2_f2[16+`RV_BTB_BTAG_SIZE:0]) );
`else // !`ifdef RV_BTB_48
assign wayhit_f2[7:0] = tag_match_way0_expanded_f2[7:0] | tag_match_way1_expanded_f2[7:0];
assign btb_bank3o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[7]}} & btb_bank3_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[7]}} & btb_bank3_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank3e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[6]}} & btb_bank3_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[6]}} & btb_bank3_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank2o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[5]}} & btb_bank2_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[5]}} & btb_bank2_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank2e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[4]}} & btb_bank2_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[4]}} & btb_bank2_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank1o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[3]}} & btb_bank1_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[3]}} & btb_bank1_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank1e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[2]}} & btb_bank1_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[2]}} & btb_bank1_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank0o_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[1]}} & btb_bank0_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[1]}} & btb_bank0_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
assign btb_bank0e_rd_data_f2[16+`RV_BTB_BTAG_SIZE:0] = ( ({17+`RV_BTB_BTAG_SIZE{tag_match_way0_expanded_f2[0]}} & btb_bank0_rd_data_way0_f2[16+`RV_BTB_BTAG_SIZE:0]) |
({17+`RV_BTB_BTAG_SIZE{tag_match_way1_expanded_f2[0]}} & btb_bank0_rd_data_way1_f2[16+`RV_BTB_BTAG_SIZE:0]) );
`endif
// --------------------------------------------------------------------------------
// --------------------------------------------------------------------------------
// update lru
// mp
assign mp_bank_decoded[3:0] = decode2_4(exu_mp_bank[1:0]);
// create a onehot lru write vector
assign mp_wrindex_dec[LRU_SIZE-1:0] = {{LRU_SIZE-1{1'b0}},1'b1} << exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
// fetch
assign fetch_wrindex_dec[LRU_SIZE-1:0] = {{LRU_SIZE-1{1'b0}},1'b1} << btb_rd_addr_f2[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
assign mp_wrlru_b0[LRU_SIZE-1:0] = mp_wrindex_dec[LRU_SIZE-1:0] & {LRU_SIZE{mp_bank_decoded[0] & exu_mp_valid}};
assign mp_wrlru_b1[LRU_SIZE-1:0] = mp_wrindex_dec[LRU_SIZE-1:0] & {LRU_SIZE{mp_bank_decoded[1] & exu_mp_valid}};
assign mp_wrlru_b2[LRU_SIZE-1:0] = mp_wrindex_dec[LRU_SIZE-1:0] & {LRU_SIZE{mp_bank_decoded[2] & exu_mp_valid}};
assign mp_wrlru_b3[LRU_SIZE-1:0] = mp_wrindex_dec[LRU_SIZE-1:0] & {LRU_SIZE{mp_bank_decoded[3] & exu_mp_valid}};
genvar j, i;
`ifdef BTB_ROUND_ROBIN
assign fetch_wrlru_b0[LRU_SIZE-1:0] = {LRU_SIZE-1{1'b0}};
assign fetch_wrlru_b1[LRU_SIZE-1:0] = {LRU_SIZE-1{1'b0}};
assign fetch_wrlru_b2[LRU_SIZE-1:0] = {LRU_SIZE-1{1'b0}};
assign fetch_wrlru_b3[LRU_SIZE-1:0] = {LRU_SIZE-1{1'b0}};
assign lru_update_valid_f2[3:0] = 4'b0;
`else
assign lru_update_valid_f2[3:0] = {((bht_valid_f2[6] & btb_sel_mask_f2[6]) | (bht_valid_f2[7] & btb_sel_mask_f2[7])) & ifc_fetch_req_f2 & ~leak_one_f2,
((bht_valid_f2[4] & btb_sel_mask_f2[4]) | (bht_valid_f2[5] & btb_sel_mask_f2[5])) & ifc_fetch_req_f2 & ~leak_one_f2,
((bht_valid_f2[2] & btb_sel_mask_f2[2]) | (bht_valid_f2[3] & btb_sel_mask_f2[3])) & ifc_fetch_req_f2 & ~leak_one_f2,
((bht_valid_f2[0] & btb_sel_mask_f2[0]) | (bht_valid_f2[1] & btb_sel_mask_f2[1])) & ifc_fetch_req_f2 & ~leak_one_f2};
assign fetch_wrlru_b0[LRU_SIZE-1:0] = fetch_wrindex_dec[LRU_SIZE-1:0] &
{LRU_SIZE{lru_update_valid_f2[0]}};
assign fetch_wrlru_b1[LRU_SIZE-1:0] = fetch_wrindex_dec[LRU_SIZE-1:0] &
{LRU_SIZE{lru_update_valid_f2[1]}};
assign fetch_wrlru_b2[LRU_SIZE-1:0] = fetch_wrindex_dec[LRU_SIZE-1:0] &
{LRU_SIZE{lru_update_valid_f2[2]}};
assign fetch_wrlru_b3[LRU_SIZE-1:0] = fetch_wrindex_dec[LRU_SIZE-1:0] &
{LRU_SIZE{lru_update_valid_f2[3]}};
`endif
assign btb_lru_b0_hold[LRU_SIZE-1:0] = ~mp_wrlru_b0[LRU_SIZE-1:0] & ~fetch_wrlru_b0[LRU_SIZE-1:0];
assign btb_lru_b1_hold[LRU_SIZE-1:0] = ~mp_wrlru_b1[LRU_SIZE-1:0] & ~fetch_wrlru_b1[LRU_SIZE-1:0];
assign btb_lru_b2_hold[LRU_SIZE-1:0] = ~mp_wrlru_b2[LRU_SIZE-1:0] & ~fetch_wrlru_b2[LRU_SIZE-1:0];
assign btb_lru_b3_hold[LRU_SIZE-1:0] = ~mp_wrlru_b3[LRU_SIZE-1:0] & ~fetch_wrlru_b3[LRU_SIZE-1:0];
// Forward the mp lru information to the fetch, avoids multiple way hits later
assign use_mp_way[3:0] = {4{fetch_mp_collision_f2}} & mp_bank_decoded_f[3:0];
`ifdef RV_BTB_48
logic [3:0][3:0] [2:0] lru_bank_wr_data ;
logic [3:0][3:0] lru_bank_sel ;
logic [3:0] [1:0] hitway_enc;
logic [3:0] [2:0] fetch_new_lru;
logic [2:0] lru_bank0_rd_data_f2_in, lru_bank1_rd_data_f2_in, lru_bank2_rd_data_f2_in, lru_bank3_rd_data_f2_in;
logic [2:0] lru_bank0_rd_data_f2, lru_bank1_rd_data_f2, lru_bank2_rd_data_f2, lru_bank3_rd_data_f2;
logic [1:0] lru_bank0_next_way, lru_bank1_next_way, lru_bank2_next_way, lru_bank3_next_way,
fetch_replway_bank0_enc, fetch_replway_bank1_enc, fetch_replway_bank2_enc, fetch_replway_bank3_enc,
fetch_replway_bank4_enc, fetch_replway_bank5_enc, fetch_replway_bank6_enc, fetch_replway_bank7_enc;
logic [3:0][3:0] [2:0] lru_bank_rd_data_out;
// // could have 2 ways hit for case where same bank, different offset hit. Update LRU accordingly
logic [3:0] two_hits;
assign two_hits[3:0] = (tag_match_way0_f2[3:0] & tag_match_way1_f2[3:0]) |
(tag_match_way0_f2[3:0] & tag_match_way2_f2[3:0]) |
(tag_match_way1_f2[3:0] & tag_match_way2_f2[3:0]) ;
logic [2:0] mp_new_lru;
assign mp_new_lru[2:0] = newlru(lru_bank_rd_data_out[exu_mp_bank[1:0]][exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]], exu_mp_way[1:0]);
assign fetch_lru_bank_hit_f2[3:0] = lru_update_valid_f2[3:0] & (tag_match_way0_f2[3:0] | tag_match_way1_f2[3:0] | tag_match_way2_f2[3:0]);
// banks
for ( i=0; i<4; i++) begin : LRUBANKS
// only 4 indices here
// encode the hit way in case the fetch hits
assign hitway_enc[i] = tag_match_way1_f2[i] ? 2'b01 : tag_match_way2_f2[i] ? 2'b10 : 'b0;
// update the lru assuming a hit
assign fetch_new_lru[i] = newlru(lru_bank_rd_data_out[i][btb_rd_addr_f2[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]], hitway_enc[i][1:0]);
// index
for (j=0 ; j<4 ; j++) begin : LRUFLOPS
// mux the write data
assign lru_bank_wr_data[i][j] = (exu_mp_valid & mp_bank_decoded[i]) ? mp_new_lru[2:0] : fetch_lru_bank_hit_f2[i] ? fetch_new_lru[i] : 'b0;
// bank enable if there was a fetch hit or a mispredict
// simul mp and fetch, mp has priority
assign lru_bank_sel[i][j] = (~exu_mp_valid & fetch_lru_bank_hit_f2[i] & (btb_rd_addr_f2[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j)) |
( exu_mp_valid & mp_bank_decoded[i] & (exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j));
rvdffs #(3) lru_bank (.*,
.clk (active_clk),
.en (lru_bank_sel[i][j]),
.din (lru_bank_wr_data[i][j]),
.dout (lru_bank_rd_data_out[i][j]));
end // block: LRUFLOPS
end // block: LRUBANKS
always_comb begin : LRU_rd_mux
lru_bank0_rd_data_f2_in[2:0] = '0 ;
lru_bank1_rd_data_f2_in[2:0] = '0 ;
lru_bank2_rd_data_f2_in[2:0] = '0 ;
lru_bank3_rd_data_f2_in[2:0] = '0 ;
for (int j=0; j<4; j++) begin
if (btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) begin
lru_bank0_rd_data_f2_in[2:0] = lru_bank_rd_data_out[0][j];
lru_bank1_rd_data_f2_in[2:0] = lru_bank_rd_data_out[1][j];
lru_bank2_rd_data_f2_in[2:0] = lru_bank_rd_data_out[2][j];
lru_bank3_rd_data_f2_in[2:0] = lru_bank_rd_data_out[3][j];
end
end
end // block: LRU_rd_mux
rvdffe #(12) lru_dataoutf (.*, .en (ifc_fetch_req_f1),
.din ({lru_bank0_rd_data_f2_in[2:0],
lru_bank1_rd_data_f2_in[2:0],
lru_bank2_rd_data_f2_in[2:0],
lru_bank3_rd_data_f2_in[2:0]
}),
.dout ({lru_bank0_rd_data_f2 [2:0],
lru_bank1_rd_data_f2 [2:0],
lru_bank2_rd_data_f2 [2:0],
lru_bank3_rd_data_f2 [2:0]
}));
// Create the replacement way to send down the pipe. First is hitway, then consider invalid ways first, then lru way
assign lru_bank0_next_way[1:0] = use_mp_way[0] ? exu_mp_way_f[1:0] : lru2way(lru_bank0_rd_data_f2[2:0], {btb_bank0_rd_data_way2_f2[BV],btb_bank0_rd_data_way1_f2[BV],btb_bank0_rd_data_way0_f2[BV]});
assign lru_bank1_next_way[1:0] = use_mp_way[1] ? exu_mp_way_f[1:0] : lru2way(lru_bank1_rd_data_f2[2:0], {btb_bank1_rd_data_way2_f2[BV],btb_bank1_rd_data_way1_f2[BV],btb_bank1_rd_data_way0_f2[BV]});
assign lru_bank2_next_way[1:0] = use_mp_way[2] ? exu_mp_way_f[1:0] : lru2way(lru_bank2_rd_data_f2[2:0], {btb_bank2_rd_data_way2_f2[BV],btb_bank2_rd_data_way1_f2[BV],btb_bank2_rd_data_way0_f2[BV]});
assign lru_bank3_next_way[1:0] = use_mp_way[3] ? exu_mp_way_f[1:0] : lru2way(lru_bank3_rd_data_f2[2:0], {btb_bank3_rd_data_way2_f2[BV],btb_bank3_rd_data_way1_f2[BV],btb_bank3_rd_data_way0_f2[BV]});
assign fetch_replway_bank0_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[0]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[0] & ~tag_match_way0_expanded_f2[0]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[0] & ~tag_match_way1_expanded_f2[0] & ~tag_match_way0_expanded_f2[0]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[0] & ~tag_match_way1_expanded_f2[0] & ~tag_match_way0_expanded_f2[0]}} & lru_bank0_next_way[1:0]));
assign fetch_replway_bank1_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[1]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[1] & ~tag_match_way0_expanded_f2[1]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[1] & ~tag_match_way1_expanded_f2[1] & ~tag_match_way0_expanded_f2[1]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[1] & ~tag_match_way1_expanded_f2[1] & ~tag_match_way0_expanded_f2[1]}} & lru_bank0_next_way[1:0]));
assign fetch_replway_bank2_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[2]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[2] & ~tag_match_way0_expanded_f2[2]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[2] & ~tag_match_way1_expanded_f2[2] & ~tag_match_way0_expanded_f2[2]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[2] & ~tag_match_way1_expanded_f2[2] & ~tag_match_way0_expanded_f2[2]}} & lru_bank1_next_way[1:0]));
assign fetch_replway_bank3_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[3]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[3] & ~tag_match_way0_expanded_f2[3]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[3] & ~tag_match_way1_expanded_f2[3] & ~tag_match_way0_expanded_f2[3]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[3] & ~tag_match_way1_expanded_f2[3] & ~tag_match_way0_expanded_f2[3]}} & lru_bank1_next_way[1:0]));
assign fetch_replway_bank4_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[4]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[4] & ~tag_match_way0_expanded_f2[4]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[4] & ~tag_match_way1_expanded_f2[4] & ~tag_match_way0_expanded_f2[4]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[4] & ~tag_match_way1_expanded_f2[4] & ~tag_match_way0_expanded_f2[4]}} & lru_bank2_next_way[1:0]));
assign fetch_replway_bank5_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[5]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[5] & ~tag_match_way0_expanded_f2[5]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[5] & ~tag_match_way1_expanded_f2[5] & ~tag_match_way0_expanded_f2[5]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[5] & ~tag_match_way1_expanded_f2[5] & ~tag_match_way0_expanded_f2[5]}} & lru_bank2_next_way[1:0]));
assign fetch_replway_bank6_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[6]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[6] & ~tag_match_way0_expanded_f2[6]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[6] & ~tag_match_way1_expanded_f2[6] & ~tag_match_way0_expanded_f2[6]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[6] & ~tag_match_way1_expanded_f2[6] & ~tag_match_way0_expanded_f2[6]}} & lru_bank3_next_way[1:0]));
assign fetch_replway_bank7_enc[1:0] = ( ({2{tag_match_way0_expanded_f2[7]}} & 2'b00) |
({2{tag_match_way1_expanded_f2[7] & ~tag_match_way0_expanded_f2[7]}} & 2'b01) |
({2{tag_match_way2_expanded_f2[7] & ~tag_match_way1_expanded_f2[7] & ~tag_match_way0_expanded_f2[7]}} & 2'b10) |
({2{~tag_match_way2_expanded_f2[7] & ~tag_match_way1_expanded_f2[7] & ~tag_match_way0_expanded_f2[7]}} & lru_bank3_next_way[1:0]));
`else
assign btb_lru_b0_ns[LRU_SIZE-1:0] = ( (btb_lru_b0_hold[LRU_SIZE-1:0] & btb_lru_b0_f[LRU_SIZE-1:0]) |
(mp_wrlru_b0[LRU_SIZE-1:0] & {LRU_SIZE{~exu_mp_way}}) |
(fetch_wrlru_b0[LRU_SIZE-1:0] & {LRU_SIZE{tag_match_way0_f2[0]}}) );
assign btb_lru_b1_ns[LRU_SIZE-1:0] = ( (btb_lru_b1_hold[LRU_SIZE-1:0] & btb_lru_b1_f[LRU_SIZE-1:0]) |
(mp_wrlru_b1[LRU_SIZE-1:0] & {LRU_SIZE{~exu_mp_way}}) |
(fetch_wrlru_b1[LRU_SIZE-1:0] & {LRU_SIZE{tag_match_way0_f2[1]}}) );
assign btb_lru_b2_ns[LRU_SIZE-1:0] = ( (btb_lru_b2_hold[LRU_SIZE-1:0] & btb_lru_b2_f[LRU_SIZE-1:0]) |
(mp_wrlru_b2[LRU_SIZE-1:0] & {LRU_SIZE{~exu_mp_way}}) |
(fetch_wrlru_b2[LRU_SIZE-1:0] & {LRU_SIZE{tag_match_way0_f2[2]}}) );
assign btb_lru_b3_ns[LRU_SIZE-1:0] = ( (btb_lru_b3_hold[LRU_SIZE-1:0] & btb_lru_b3_f[LRU_SIZE-1:0]) |
(mp_wrlru_b3[LRU_SIZE-1:0] & {LRU_SIZE{~exu_mp_way}}) |
(fetch_wrlru_b3[LRU_SIZE-1:0] & {LRU_SIZE{tag_match_way0_f2[3]}}) );
assign btb_lru_rd_f2[0] = use_mp_way[0] ? exu_mp_way_f : |(fetch_wrindex_dec[LRU_SIZE-1:0] & btb_lru_b0_f[LRU_SIZE-1:0]);
assign btb_lru_rd_f2[1] = use_mp_way[1] ? exu_mp_way_f : |(fetch_wrindex_dec[LRU_SIZE-1:0] & btb_lru_b1_f[LRU_SIZE-1:0]);
assign btb_lru_rd_f2[2] = use_mp_way[2] ? exu_mp_way_f : |(fetch_wrindex_dec[LRU_SIZE-1:0] & btb_lru_b2_f[LRU_SIZE-1:0]);
assign btb_lru_rd_f2[3] = use_mp_way[3] ? exu_mp_way_f : |(fetch_wrindex_dec[LRU_SIZE-1:0] & btb_lru_b3_f[LRU_SIZE-1:0]);
assign way_raw[7:0] = tag_match_way1_expanded_f2[7:0] | (~wayhit_f2[7:0] & {{2{btb_lru_rd_f2[3]}}, {2{btb_lru_rd_f2[2]}}, {2{btb_lru_rd_f2[1]}}, {2{btb_lru_rd_f2[0]}}});
rvdffe #(LRU_SIZE*4) btb_lru_ff (.*, .en(ifc_fetch_req_f2 | exu_mp_valid),
.din({btb_lru_b0_ns[(LRU_SIZE)-1:0],
btb_lru_b1_ns[(LRU_SIZE)-1:0],
btb_lru_b2_ns[(LRU_SIZE)-1:0],
btb_lru_b3_ns[(LRU_SIZE)-1:0]}),
.dout({btb_lru_b0_f[(LRU_SIZE)-1:0],
btb_lru_b1_f[(LRU_SIZE)-1:0],
btb_lru_b2_f[(LRU_SIZE)-1:0],
btb_lru_b3_f[(LRU_SIZE)-1:0]}));
`endif // !`ifdef RV_BTB_48
// --------------------------------------------------------------------------------
// --------------------------------------------------------------------------------
// mux out critical hit bank for pc computation
// This is only useful for the first taken branch in the fetch group
logic [16:1] btb_sel_data_f2;
assign {
btb_rd_tgt_f2[11:0],
btb_rd_pc4_f2,
btb_rd_boffset_f2,
btb_rd_call_f2,
btb_rd_ret_f2} = btb_sel_data_f2[16:1];
assign btb_sel_data_f2[16:1] = ( ({16{btb_sel_f2[7]}} & btb_bank3o_rd_data_f2[16:1]) |
({16{btb_sel_f2[6]}} & btb_bank3e_rd_data_f2[16:1]) |
({16{btb_sel_f2[5]}} & btb_bank2o_rd_data_f2[16:1]) |
({16{btb_sel_f2[4]}} & btb_bank2e_rd_data_f2[16:1]) |
({16{btb_sel_f2[3]}} & btb_bank1o_rd_data_f2[16:1]) |
({16{btb_sel_f2[2]}} & btb_bank1e_rd_data_f2[16:1]) |
({16{btb_sel_f2[1]}} & btb_bank0o_rd_data_f2[16:1]) |
({16{btb_sel_f2[0]}} & btb_bank0e_rd_data_f2[16:1]) );
logic [7:0] bp_valid_f2, bp_hist1_f2;
// a valid taken target needs to kill the next fetch as we compute the target address
assign ifu_bp_kill_next_f2 = |(bp_valid_f2[7:0] & bp_hist1_f2[7:0]) & ifc_fetch_req_f2 & ~leak_one_f2 & ~dec_tlu_bpred_disable;
// Don't put calls/rets/ja in the predictor, force the bht taken instead
assign bht_force_taken_f2[7:0] = {(btb_bank3o_rd_data_f2[CALL] | btb_bank3o_rd_data_f2[RET]),
(btb_bank3e_rd_data_f2[CALL] | btb_bank3e_rd_data_f2[RET]),
(btb_bank2o_rd_data_f2[CALL] | btb_bank2o_rd_data_f2[RET]),
(btb_bank2e_rd_data_f2[CALL] | btb_bank2e_rd_data_f2[RET]),
(btb_bank1o_rd_data_f2[CALL] | btb_bank1o_rd_data_f2[RET]),
(btb_bank1e_rd_data_f2[CALL] | btb_bank1e_rd_data_f2[RET]),
(btb_bank0o_rd_data_f2[CALL] | btb_bank0o_rd_data_f2[RET]),
(btb_bank0e_rd_data_f2[CALL] | btb_bank0e_rd_data_f2[RET])};
// taken and valid, otherwise, branch errors must clear the bht
assign bht_valid_f2[7:0] = wayhit_f2[7:0];
assign bht_dir_f2[7:0] = {(bht_force_taken_f2[7] | bht_bank7_rd_data_f2[1]) & bht_valid_f2[7],
(bht_force_taken_f2[6] | bht_bank6_rd_data_f2[1]) & bht_valid_f2[6],
(bht_force_taken_f2[5] | bht_bank5_rd_data_f2[1]) & bht_valid_f2[5],
(bht_force_taken_f2[4] | bht_bank4_rd_data_f2[1]) & bht_valid_f2[4],
(bht_force_taken_f2[3] | bht_bank3_rd_data_f2[1]) & bht_valid_f2[3],
(bht_force_taken_f2[2] | bht_bank2_rd_data_f2[1]) & bht_valid_f2[2],
(bht_force_taken_f2[1] | bht_bank1_rd_data_f2[1]) & bht_valid_f2[1],
(bht_force_taken_f2[0] | bht_bank0_rd_data_f2[1]) & bht_valid_f2[0]};
// final inst_valid_mask.
// vmask[7] is a 0, vmask[0] is a 1, initially
// (assumes pc2 with boffset 0)
//
logic minus1, plus1;
assign plus1 = ( (~btb_rd_pc4_f2 & btb_rd_boffset_f2 & ~ifc_fetch_addr_f2[1]) |
( btb_rd_pc4_f2 & ~btb_rd_boffset_f2 & ~ifc_fetch_addr_f2[1]) );
assign minus1 = ( (~btb_rd_pc4_f2 & ~btb_rd_boffset_f2 & ifc_fetch_addr_f2[1]) |
( btb_rd_pc4_f2 & btb_rd_boffset_f2 & ifc_fetch_addr_f2[1]) );
assign ifu_bp_inst_mask_f2[7:1] = ( ({7{ ifu_bp_kill_next_f2}} & btb_vmask_f2[7:1]) |
({7{~ifu_bp_kill_next_f2}} & 7'b1111111) );
logic [7:0] hist0_raw, hist1_raw, pc4_raw, pret_raw;
// Branch prediction info is sent with the 2byte lane associated with the end of the branch.
// Cases
// BANK1 BANK0
// -------------------------------
// | : | : |
// -------------------------------
// <------------> : PC4 branch, offset, should be in B1 (indicated on [2])
// <------------> : PC4 branch, no offset, indicate PC4, VALID, HIST on [1]
// <------------> : PC4 branch, offset, indicate PC4, VALID, HIST on [0]
// <------> : PC2 branch, offset, indicate VALID, HIST on [1]
// <------> : PC2 branch, no offset, indicate VALID, HIST on [0]
//
assign hist1_raw[7:0] = bht_force_taken_f2[7:0] | {bht_bank7_rd_data_f2[1],
bht_bank6_rd_data_f2[1],
bht_bank5_rd_data_f2[1],
bht_bank4_rd_data_f2[1],
bht_bank3_rd_data_f2[1],
bht_bank2_rd_data_f2[1],
bht_bank1_rd_data_f2[1],
bht_bank0_rd_data_f2[1]};
assign hist0_raw[7:0] = {bht_bank7_rd_data_f2[0],
bht_bank6_rd_data_f2[0],
bht_bank5_rd_data_f2[0],
bht_bank4_rd_data_f2[0],
bht_bank3_rd_data_f2[0],
bht_bank2_rd_data_f2[0],
bht_bank1_rd_data_f2[0],
bht_bank0_rd_data_f2[0]};
assign pc4_raw[7:0] = {wayhit_f2[7] & btb_bank3o_rd_data_f2[PC4],
wayhit_f2[6] & btb_bank3e_rd_data_f2[PC4],
wayhit_f2[5] & btb_bank2o_rd_data_f2[PC4],
wayhit_f2[4] & btb_bank2e_rd_data_f2[PC4],
wayhit_f2[3] & btb_bank1o_rd_data_f2[PC4],
wayhit_f2[2] & btb_bank1e_rd_data_f2[PC4],
wayhit_f2[1] & btb_bank0o_rd_data_f2[PC4],
wayhit_f2[0] & btb_bank0e_rd_data_f2[PC4]};
assign pret_raw[7:0] = {wayhit_f2[3] & ~btb_bank3o_rd_data_f2[CALL] & btb_bank3o_rd_data_f2[RET],
wayhit_f2[3] & ~btb_bank3e_rd_data_f2[CALL] & btb_bank3e_rd_data_f2[RET],
wayhit_f2[2] & ~btb_bank2o_rd_data_f2[CALL] & btb_bank2o_rd_data_f2[RET],
wayhit_f2[2] & ~btb_bank2e_rd_data_f2[CALL] & btb_bank2e_rd_data_f2[RET],
wayhit_f2[1] & ~btb_bank1o_rd_data_f2[CALL] & btb_bank1o_rd_data_f2[RET],
wayhit_f2[1] & ~btb_bank1e_rd_data_f2[CALL] & btb_bank1e_rd_data_f2[RET],
wayhit_f2[0] & ~btb_bank0o_rd_data_f2[CALL] & btb_bank0o_rd_data_f2[RET],
wayhit_f2[0] & ~btb_bank0e_rd_data_f2[CALL] & btb_bank0e_rd_data_f2[RET]};
// GHR
// Figure out how many valid branches are in the fetch group
assign fgmask_f2[6] = (~ifc_fetch_addr_f2[1]) | (~ifc_fetch_addr_f2[2]) | (
~ifc_fetch_addr_f2[3]);
assign fgmask_f2[5] = (~ifc_fetch_addr_f2[2]) | (~ifc_fetch_addr_f2[3]);
assign fgmask_f2[4] = (~ifc_fetch_addr_f2[2] & ~ifc_fetch_addr_f2[1]) | (
~ifc_fetch_addr_f2[3]);
assign fgmask_f2[3] = (~ifc_fetch_addr_f2[3]);
assign fgmask_f2[2] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[1]) | (
~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]);
assign fgmask_f2[1] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]);
assign fgmask_f2[0] = (~ifc_fetch_addr_f2[3] & ~ifc_fetch_addr_f2[2]
& ~ifc_fetch_addr_f2[1]);
assign btb_sel_mask_f2[7:0] = {btb_sel_f2[7],
|btb_sel_f2[7:6] & fgmask_f2[6],
|btb_sel_f2[7:5] & fgmask_f2[5],
|btb_sel_f2[7:4] & fgmask_f2[4],
|btb_sel_f2[7:3] & fgmask_f2[3],
|btb_sel_f2[7:2] & fgmask_f2[2],
|btb_sel_f2[7:1] & fgmask_f2[1],
|btb_sel_f2[7:0] & fgmask_f2[0]};
// count the valids with masking based on first taken
assign num_valids[3:0] = countones(bht_valid_f2[7:0] & btb_sel_mask_f2[7:0]);
// Note that the following property holds
// P: prior ghr, H: history bit of last valid branch in line (could be 1 or 0)
// Num valid branches What new GHR must be
// >=4 000H
// 3 P00H
// 2 PP0H
// 1 PPPH
// 0 PPPP
assign final_h = |(btb_sel_f2[7:0] & bht_dir_f2[7:0]);
assign merged_ghr[`RV_BHT_GHR_RANGE] = ( ({`RV_BHT_GHR_SIZE{num_valids[3:0] >= 4'h4}} & {`RV_BHT_GHR_PAD, final_h }) | // 000H
({`RV_BHT_GHR_SIZE{num_valids[3:0] == 4'h3}} & {`RV_BHT_GHR_PAD2, final_h}) | // P00H
`ifdef RV_BHT_GHR_SIZE_2
({`RV_BHT_GHR_SIZE{num_valids[3:0] == 4'h2}} & { 1'b0, final_h}) | // PP0H
`else
({`RV_BHT_GHR_SIZE{num_valids[3:0] == 4'h2}} & {fghr[`RV_BHT_GHR_SIZE-3:0], 1'b0, final_h}) | // PP0H
`endif
({`RV_BHT_GHR_SIZE{num_valids[3:0] == 4'h1}} & {fghr[`RV_BHT_GHR_SIZE-2:0], final_h}) | // PPPH
({`RV_BHT_GHR_SIZE{num_valids[3:0] == 4'h0}} & {fghr[`RV_BHT_GHR_RANGE]}) ); // PPPP
logic [`RV_BHT_GHR_RANGE] exu_flush_ghr;
assign exu_flush_ghr[`RV_BHT_GHR_RANGE] = exu_mp_fghr[`RV_BHT_GHR_RANGE];
assign fghr_ns[`RV_BHT_GHR_RANGE] = ( ({`RV_BHT_GHR_SIZE{exu_flush_final}} & exu_flush_ghr[`RV_BHT_GHR_RANGE]) |
({`RV_BHT_GHR_SIZE{~exu_flush_final & ifc_fetch_req_f2_raw & ~leak_one_f2}} & merged_ghr[`RV_BHT_GHR_RANGE]) |
({`RV_BHT_GHR_SIZE{~exu_flush_final & ~(ifc_fetch_req_f2_raw & ~leak_one_f2)}} & fghr[`RV_BHT_GHR_RANGE]));
rvdff #(`RV_BHT_GHR_SIZE) fetchghr (.*, .clk(active_clk), .din(fghr_ns[`RV_BHT_GHR_RANGE]), .dout(fghr[`RV_BHT_GHR_RANGE]));
assign ifu_bp_fghr_f2[`RV_BHT_GHR_RANGE] = fghr[`RV_BHT_GHR_RANGE];
`ifdef RV_BTB_48
assign ifu_bp_way_f2 = {fetch_replway_bank7_enc[1:0],
fetch_replway_bank6_enc[1:0],
fetch_replway_bank5_enc[1:0],
fetch_replway_bank4_enc[1:0],
fetch_replway_bank3_enc[1:0],
fetch_replway_bank2_enc[1:0],
fetch_replway_bank1_enc[1:0],
fetch_replway_bank0_enc[1:0]};
`else
assign ifu_bp_way_f2[7:0] = way_raw[7:0];
`endif
assign ifu_bp_hist1_f2[7:0] = hist1_raw[7:0];
assign ifu_bp_hist0_f2[7:0] = hist0_raw[7:0];
assign ifu_bp_pc4_f2[7:0] = pc4_raw[7:0];
assign ifu_bp_valid_f2[7:0] = wayhit_f2[7:0] & ~{8{dec_tlu_bpred_disable}};
assign ifu_bp_ret_f2[7:0] = pret_raw[7:0];
// Truncate taken and valid, used for detecting a taken branch in the fetch group
always_comb begin
casez(ifc_fetch_addr_f2[3:1])
3'b000 : begin
bp_hist1_f2[7:0] = hist1_raw[7:0];
bp_valid_f2[7:0] = wayhit_f2[7:0];
end
3'b001 : begin
bp_hist1_f2[7:0] = {1'b0, hist1_raw[7:1]};
bp_valid_f2[7:0] = {1'b0, wayhit_f2[7:1]};
end
3'b010 : begin
bp_hist1_f2[7:0] = {2'b0, hist1_raw[7:2]};
bp_valid_f2[7:0] = {2'b0, wayhit_f2[7:2]};
end
3'b011 : begin
bp_hist1_f2[7:0] = {3'b0, hist1_raw[7:3]};
bp_valid_f2[7:0] = {3'b0, wayhit_f2[7:3]};
end
3'b100 : begin
bp_hist1_f2[7:0] = {4'b0, hist1_raw[7:4]};
bp_valid_f2[7:0] = {4'b0, wayhit_f2[7:4]};
end
3'b101 : begin
bp_hist1_f2[7:0] = {5'b0, hist1_raw[7:5]};
bp_valid_f2[7:0] = {5'b0, wayhit_f2[7:5]};
end
3'b110 : begin
bp_hist1_f2[7:0] = {6'b0, hist1_raw[7:6]};
bp_valid_f2[7:0] = {6'b0, wayhit_f2[7:6]};
end
3'b111 : begin
bp_hist1_f2[7:0] = {7'b0, hist1_raw[7]};
bp_valid_f2[7:0] = {7'b0, wayhit_f2[7]};
end
default: begin
bp_hist1_f2[7:0] = hist1_raw[7:0];
bp_valid_f2[7:0] = wayhit_f2[7:0];
end
endcase // casex (ifc_fetch_addr_f1[3:2])
end
// compute target
// Form the fetch group offset based on the btb hit location and the location of the branch within the 4 byte chunk
assign btb_fg_crossing_f2 = btb_sel_f2[0] & btb_rd_pc4_f2;
wire [2:0] btb_sel_f2_enc, btb_sel_f2_enc_shift;
assign btb_sel_f2_enc[2:0] = encode8_3(btb_sel_f2[7:0]);
assign btb_sel_f2_enc_shift[2:0] = encode8_3({1'b0,btb_sel_f2[7:1]});
assign bp_total_branch_offset_f2[3:1] = (({3{ btb_rd_pc4_f2}} & btb_sel_f2_enc_shift[2:0]) |
({3{~btb_rd_pc4_f2}} & btb_sel_f2_enc[2:0]) |
({3{btb_fg_crossing_f2}}));
logic [31:4] adder_pc_in_f2, ifc_fetch_adder_prior;
rvdffe #(28) faddrf2_ff (.*, .en(ifc_fetch_req_f2 & ~ifu_bp_kill_next_f2 & ic_hit_f2), .din(ifc_fetch_addr_f2[31:4]), .dout(ifc_fetch_adder_prior[31:4]));
assign ifu_bp_poffset_f2[11:0] = btb_rd_tgt_f2[11:0];
assign adder_pc_in_f2[31:4] = ( ({28{ btb_fg_crossing_f2}} & ifc_fetch_adder_prior[31:4]) |
({28{~btb_fg_crossing_f2}} & ifc_fetch_addr_f2[31:4]));
rvbradder predtgt_addr (.pc({adder_pc_in_f2[31:4], bp_total_branch_offset_f2[3:1]}),
.offset(btb_rd_tgt_f2[11:0]),
.dout(bp_btb_target_adder_f2[31:1])
);
// mux in the return stack address here for a predicted return
assign ifu_bp_btb_target_f2[31:1] = btb_rd_ret_f2 & ~btb_rd_call_f2 ? rets_out[0][31:1] : bp_btb_target_adder_f2[31:1];
// ----------------------------------------------------------------------
// Return Stack
// ----------------------------------------------------------------------
rvbradder rs_addr (.pc({adder_pc_in_f2[31:4], bp_total_branch_offset_f2[3:1]}),
.offset({10'b0, btb_rd_pc4_f2, ~btb_rd_pc4_f2}),
.dout(bp_rs_call_target_f2[31:1])
);
// Calls/Rets are always taken, so there shouldn't be a push and pop in the same fetch group
logic rs_overpop_correct, rsoverpop_valid_ns, rsoverpop_valid_f;
logic [31:1] rsoverpop_ns, rsoverpop_f;
logic rsunderpop_valid_ns, rsunderpop_valid_f, rs_underpop_correct;
`ifdef RS_COMMIT_EN
assign rs_overpop_correct = rsoverpop_valid_f & exu_flush_final & ~exu_mp_ret;
assign rs_underpop_correct = rsunderpop_valid_f & exu_flush_final & ~exu_mp_call;
assign rsunderpop_valid_ns = (rs_push | (rsunderpop_valid_f & ~(exu_i0_br_call_e4 | exu_i1_br_call_e4))) & ~exu_flush_final;
assign rsoverpop_valid_ns = (rs_pop | (rsoverpop_valid_f & ~(exu_i0_br_ret_e4 | exu_i1_br_ret_e4))) & ~exu_flush_final;
assign rsoverpop_ns[31:1] = ( ({31{rs_pop}} & rets_out[0][31:1]) |
({31{~rs_pop}} & rsoverpop_f[31:1]) );
rvdff #(33) retoverpop_ff (.*, .clk(active_clk), .din({rsunderpop_valid_ns, rsoverpop_valid_ns, rsoverpop_ns[31:1]}), .dout({rsunderpop_valid_f, rsoverpop_valid_f, rsoverpop_f[31:1]}));
`else
assign rs_overpop_correct = 1'b0;
assign rs_underpop_correct = 1'b0;
assign rsoverpop_f[31:1] = 'b0;
`endif // !`ifdef RS_COMMIT_EN
logic e4_rs_correct;
`ifdef REAL_COMM_RS
assign rs_correct = exu_flush_upper_e2 & ~e4_rs_correct;
`else
assign e4_rs_correct = 1'b0;
assign rs_correct = 1'b0;
`endif
assign rs_push = ((btb_rd_call_f2 & ~btb_rd_ret_f2 & ifu_bp_kill_next_f2) | (rs_overpop_correct & ~rs_underpop_correct)) & ~rs_correct & ~e4_rs_correct;
assign rs_pop = ((btb_rd_ret_f2 & ~btb_rd_call_f2 & ifu_bp_kill_next_f2) | (rs_underpop_correct & ~rs_overpop_correct)) & ~rs_correct & ~e4_rs_correct;
assign rs_hold = ~rs_push & ~rs_pop & ~rs_overpop_correct & ~rs_underpop_correct & ~rs_correct & ~e4_rs_correct;
// Fetch based
assign rets_in[0][31:1] = ( ({31{rs_overpop_correct & rs_underpop_correct}} & rsoverpop_f[31:1]) |
({31{rs_push & rs_overpop_correct}} & rsoverpop_f[31:1]) |
({31{rs_push & ~rs_overpop_correct}} & bp_rs_call_target_f2[31:1]) |
`ifdef REAL_COMM_RS
({31{rs_correct}} & e1_rets_out[0][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[0][31:1]) |
`endif
({31{rs_pop}} & rets_out[1][31:1]) );
assign rsenable[0] = ~rs_hold;
for (i=0; i<`RV_RET_STACK_SIZE; i++) begin : retstack
// for the last entry in the stack, we don't have a pop position
if(i==`RV_RET_STACK_SIZE-1) begin
`ifdef REAL_COMM_RS
assign rets_in[i][31:1] = ( ({31{rs_push}} & rets_out[i-1][31:1]) |
({31{rs_correct}} & e1_rets_out[i][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[i][31:1]) );
`else
assign rets_in[i][31:1] = rets_out[i-1][31:1];
`endif
assign rsenable[i] = rs_push | rs_correct | e4_rs_correct;
end
else if(i>0) begin
`ifdef REAL_COMM_RS
assign rets_in[i][31:1] = ( ({31{rs_push}} & rets_out[i-1][31:1]) |
({31{rs_pop}} & rets_out[i+1][31:1]) |
({31{rs_correct}} & e1_rets_out[i][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[i][31:1]) );
`else
assign rets_in[i][31:1] = ( ({31{rs_push}} & rets_out[i-1][31:1]) |
({31{rs_pop}} & rets_out[i+1][31:1]) );
`endif
assign rsenable[i] = rs_push | rs_pop | rs_correct | e4_rs_correct;
end
rvdffe #(31) rets_ff (.*, .en(rsenable[i]), .din(rets_in[i][31:1]), .dout(rets_out[i][31:1]));
end : retstack
`ifdef REAL_COMM_RS
logic [31:1] e1_rs_call0_target_f2, e1_rs_call1_target_f2, e1_rs_call_target_f2, e4_rs_call0_target_f2, e4_rs_call1_target_f2, e4_rs_call_target_f2;
logic e1_null, e1_rs_push1, e1_rs_push2, e1_rs_pop1, e1_rs_pop2, e1_rs_hold;
logic e4_null, e4_rs_push1, e4_rs_push2, e4_rs_pop1, e4_rs_pop2, e4_rs_hold;
// E1 based
assign e4_rs_correct = dec_tlu_flush_lower_wb;
assign e1_null = exu_rets_e1_pkt.pc0_call & exu_rets_e1_pkt.pc1_ret;
assign e1_rs_push1 = (exu_rets_e1_pkt.pc0_call ^ exu_rets_e1_pkt.pc1_call) & ~e1_null & ~e4_rs_correct;
assign e1_rs_push2 = (exu_rets_e1_pkt.pc0_call & exu_rets_e1_pkt.pc1_call) & ~e4_rs_correct;
assign e1_rs_pop1 = (exu_rets_e1_pkt.pc0_ret ^ exu_rets_e1_pkt.pc1_ret) & ~e4_rs_correct;
assign e1_rs_pop2 = (exu_rets_e1_pkt.pc0_ret & exu_rets_e1_pkt.pc1_ret) & ~e4_rs_correct;
assign e1_rs_hold = (~e1_rs_push1 & ~e1_rs_push2 & ~e1_rs_pop1 & ~e1_rs_pop2 & ~e4_rs_correct);
rvbradder e1_rs_addr0 (.pc({exu_i0_pc_e1[31:1]}),
.offset({10'b0, exu_rets_e1_pkt.pc0_pc4, ~exu_rets_e1_pkt.pc0_pc4}),
.dout(e1_rs_call0_target_f2[31:1])
);
rvbradder e1_rs_addr1 (.pc({exu_i1_pc_e1[31:1]}),
.offset({10'b0, exu_rets_e1_pkt.pc1_pc4, ~exu_rets_e1_pkt.pc1_pc4}),
.dout(e1_rs_call1_target_f2[31:1])
);
assign e1_rs_call_target_f2[31:1] = exu_rets_e1_pkt.pc0_call ? e1_rs_call0_target_f2[31:1] : e1_rs_call1_target_f2[31:1];
assign e1_rets_in[0][31:1] = ( ({31{e1_rs_push1}} & e1_rs_call_target_f2[31:1]) |
({31{e1_rs_push2}} & e1_rs_call1_target_f2[31:1]) |
({31{e1_rs_pop1}} & e1_rets_out[1][31:1]) |
({31{e1_rs_pop2}} & e1_rets_out[2][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[0][31:1]) |
({31{e1_rs_hold}} & e1_rets_out[0][31:1]) );
assign e1_rets_in[1][31:1] = ( ({31{e1_rs_push1}} & e1_rets_out[0][31:1]) |
({31{e1_rs_push2}} & e1_rs_call0_target_f2[31:1]) |
({31{e1_rs_pop1}} & e1_rets_out[2][31:1]) |
({31{e1_rs_pop2}} & e1_rets_out[3][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[1][31:1]) |
({31{e1_rs_hold}} & e1_rets_out[0][31:1]) );
for (i=0; i<`RV_RET_STACK_SIZE; i++) begin : e1_retstack
// for the last entry in the stack, we don't have a pop position
if(i==`RV_RET_STACK_SIZE-1)
assign e1_rets_in[i][31:1] = ( ({31{e1_rs_push1}} & e1_rets_out[i-1][31:1]) |
({31{e1_rs_push2}} & e1_rets_out[i-2][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[i][31:1]) |
({31{e1_rs_hold}} & e1_rets_out[i][31:1]) );
else if(i==`RV_RET_STACK_SIZE-2)
assign e1_rets_in[i][31:1] = ( ({31{e1_rs_push1}} & e1_rets_out[i-1][31:1]) |
({31{e1_rs_push2}} & e1_rets_out[i-2][31:1]) |
({31{e1_rs_pop1}} & e1_rets_out[i+1][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[i][31:1]) |
({31{e1_rs_hold}} & e1_rets_out[i][31:1]) );
else if(i>1)
assign e1_rets_in[i][31:1] = ( ({31{e1_rs_push1}} & e1_rets_out[i-1][31:1]) |
({31{e1_rs_push2}} & e1_rets_out[i-2][31:1]) |
({31{e1_rs_pop1}} & e1_rets_out[i+1][31:1]) |
({31{e1_rs_pop2}} & e1_rets_out[i+2][31:1]) |
({31{e4_rs_correct}} & e4_rets_out[i][31:1]) |
({31{e1_rs_hold}} & e1_rets_out[i][31:1]) );
rvdff #(31) e1_rets_ff (.*, .din(e1_rets_in[i][31:1]), .dout(e1_rets_out[i][31:1]));
end : e1_retstack
// E4 based
assign e4_null = exu_rets_e4_pkt.pc0_call & exu_rets_e4_pkt.pc1_ret;
assign e4_rs_push1 = (exu_rets_e4_pkt.pc0_call ^ exu_rets_e4_pkt.pc1_call) & ~e4_null;
assign e4_rs_push2 = (exu_rets_e4_pkt.pc0_call & exu_rets_e4_pkt.pc1_call);
assign e4_rs_pop1 = (exu_rets_e4_pkt.pc0_ret ^ exu_rets_e4_pkt.pc1_ret);
assign e4_rs_pop2 = (exu_rets_e4_pkt.pc0_ret & exu_rets_e4_pkt.pc1_ret);
assign e4_rs_hold = (~e4_rs_push1 & ~e4_rs_push2 & ~e4_rs_pop1 & ~e4_rs_pop2);
rvbradder e4_rs_addr0 (.pc({dec_tlu_i0_pc_e4[31:1]}),
.offset({10'b0, exu_rets_e4_pkt.pc0_pc4, ~exu_rets_e4_pkt.pc0_pc4}),
.dout(e4_rs_call0_target_f2[31:1])
);
rvbradder e4_rs_addr1 (.pc({dec_tlu_i1_pc_e4[31:1]}),
.offset({10'b0, exu_rets_e4_pkt.pc1_pc4, ~exu_rets_e4_pkt.pc1_pc4}),
.dout(e4_rs_call1_target_f2[31:1])
);
assign e4_rs_call_target_f2[31:1] = exu_rets_e4_pkt.pc0_call ? e4_rs_call0_target_f2[31:1] : e4_rs_call1_target_f2[31:1];
assign e4_rets_in[0][31:1] = ( ({31{e4_rs_push1}} & e4_rs_call_target_f2[31:1]) |
({31{e4_rs_push2}} & e4_rs_call1_target_f2[31:1]) |
({31{e4_rs_pop1}} & e4_rets_out[1][31:1]) |
({31{e4_rs_pop2}} & e4_rets_out[2][31:1]) |
({31{e4_rs_hold}} & e4_rets_out[0][31:1]) );
assign e4_rets_in[1][31:1] = ( ({31{e4_rs_push1}} & e4_rets_out[0][31:1]) |
({31{e4_rs_push2}} & e4_rs_call0_target_f2[31:1]) |
({31{e4_rs_pop1}} & e4_rets_out[2][31:1]) |
({31{e4_rs_pop2}} & e4_rets_out[3][31:1]) |
({31{e4_rs_hold}} & e4_rets_out[0][31:1]) );
for (i=0; i<`RV_RET_STACK_SIZE; i++) begin : e4_retstack
// for the last entry in the stack, we don't have a pop position
if(i==`RV_RET_STACK_SIZE-1)
assign e4_rets_in[i][31:1] = ( ({31{e4_rs_push1}} & e4_rets_out[i-1][31:1]) |
({31{e4_rs_push2}} & e4_rets_out[i-2][31:1]) |
({31{e4_rs_hold}} & e4_rets_out[i][31:1]) );
else if(i==`RV_RET_STACK_SIZE-2)
assign e4_rets_in[i][31:1] = ( ({31{e4_rs_push1}} & e4_rets_out[i-1][31:1]) |
({31{e4_rs_push2}} & e4_rets_out[i-2][31:1]) |
({31{e4_rs_pop1}} & e4_rets_out[i+1][31:1]) |
({31{e4_rs_hold}} & e4_rets_out[i][31:1]) );
else if(i>1)
assign e4_rets_in[i][31:1] = ( ({31{e4_rs_push1}} & e4_rets_out[i-1][31:1]) |
({31{e4_rs_push2}} & e4_rets_out[i-2][31:1]) |
({31{e4_rs_pop1}} & e4_rets_out[i+1][31:1]) |
({31{e4_rs_pop2}} & e4_rets_out[i+2][31:1]) |
({31{e4_rs_hold}} & e4_rets_out[i][31:1]) );
rvdff #(31) e4_rets_ff (.*, .din(e4_rets_in[i][31:1]), .dout(e4_rets_out[i][31:1]));
end : e4_retstack
`endif // `ifdef REAL_COMM_RS
// ----------------------------------------------------------------------
// WRITE
// ----------------------------------------------------------------------
assign dec_tlu_error_wb = dec_tlu_br0_start_error_wb | dec_tlu_br0_error_wb | dec_tlu_br1_start_error_wb | dec_tlu_br1_error_wb;
assign dec_tlu_all_banks_error_wb = dec_tlu_br0_start_error_wb | (~dec_tlu_br0_error_wb & dec_tlu_br1_start_error_wb);
assign dec_tlu_error_bank_wb[1:0] = (dec_tlu_br0_error_wb | dec_tlu_br0_start_error_wb) ? dec_tlu_br0_bank_wb[1:0] : dec_tlu_br1_bank_wb[1:0];
assign btb_error_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] = (dec_tlu_br0_error_wb | dec_tlu_br0_start_error_wb) ? dec_tlu_br0_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] : dec_tlu_br1_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
assign dec_tlu_way_wb = (dec_tlu_br0_error_wb | dec_tlu_br0_start_error_wb) ? dec_tlu_br0_way_wb : dec_tlu_br1_way_wb;
assign btb_valid = exu_mp_valid & ~dec_tlu_error_wb;
assign btb_wr_tag[`RV_BTB_BTAG_SIZE-1:0] = exu_mp_btag[`RV_BTB_BTAG_SIZE-1:0];
rvbtb_tag_hash rdtagf1(.hash(fetch_rd_tag_f1[`RV_BTB_BTAG_SIZE-1:0]), .pc({ifc_fetch_addr_f1[31:4], 3'b0}));
rvdff #(`RV_BTB_BTAG_SIZE) rdtagf (.*, .clk(active_clk), .din({fetch_rd_tag_f1[`RV_BTB_BTAG_SIZE-1:0]}), .dout({fetch_rd_tag_f2[`RV_BTB_BTAG_SIZE-1:0]}));
assign btb_wr_data[16+`RV_BTB_BTAG_SIZE:0] = {btb_wr_tag[`RV_BTB_BTAG_SIZE-1:0], exu_mp_tgt[11:0], exu_mp_pc4, exu_mp_boffset, exu_mp_call | exu_mp_ja, exu_mp_ret | exu_mp_ja, btb_valid} ;
assign exu_mp_valid_write = exu_mp_valid & exu_mp_ataken;
`ifdef RV_BTB_48
assign btb_wr_en_way0[3:0] = ( ({4{(exu_mp_way==2'b0) & exu_mp_valid_write & ~dec_tlu_error_wb}} & decode2_4(exu_mp_bank[1:0])) |
({4{(dec_tlu_way_wb==2'b0) & dec_tlu_error_wb & ~dec_tlu_all_banks_error_wb}} & decode2_4(dec_tlu_error_bank_wb[1:0])) |
({4{(dec_tlu_way_wb==2'b0) & dec_tlu_all_banks_error_wb}}));
assign btb_wr_en_way1[3:0] = ( ({4{exu_mp_way[0] & exu_mp_valid_write & ~dec_tlu_error_wb}} & decode2_4(exu_mp_bank[1:0])) |
({4{dec_tlu_way_wb[0] & dec_tlu_error_wb & ~dec_tlu_all_banks_error_wb}} & decode2_4(dec_tlu_error_bank_wb[1:0])) |
({4{dec_tlu_way_wb[0] & dec_tlu_all_banks_error_wb}}));
assign btb_wr_en_way2[3:0] = ( ({4{exu_mp_way[1] & exu_mp_valid_write & ~dec_tlu_error_wb}} & decode2_4(exu_mp_bank[1:0])) |
({4{dec_tlu_way_wb[1] & dec_tlu_error_wb & ~dec_tlu_all_banks_error_wb}} & decode2_4(dec_tlu_error_bank_wb[1:0])) |
({4{dec_tlu_way_wb[1] & dec_tlu_all_banks_error_wb}}));
`else // !`ifdef RV_BTB_48
assign btb_wr_en_way0[3:0] = ( ({4{~exu_mp_way & exu_mp_valid_write & ~dec_tlu_error_wb}} & decode2_4(exu_mp_bank[1:0])) |
({4{~dec_tlu_way_wb & dec_tlu_error_wb & ~dec_tlu_all_banks_error_wb}} & decode2_4(dec_tlu_error_bank_wb[1:0])) |
({4{~dec_tlu_way_wb & dec_tlu_all_banks_error_wb}}));
assign btb_wr_en_way1[3:0] = ( ({4{exu_mp_way & exu_mp_valid_write & ~dec_tlu_error_wb}} & decode2_4(exu_mp_bank[1:0])) |
({4{dec_tlu_way_wb & dec_tlu_error_wb & ~dec_tlu_all_banks_error_wb}} & decode2_4(dec_tlu_error_bank_wb[1:0])) |
({4{dec_tlu_way_wb & dec_tlu_all_banks_error_wb}}));
`endif
assign btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] = dec_tlu_error_wb ? btb_error_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] : exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO];
logic [1:0] bht_wr_data0, bht_wr_data1, bht_wr_data2;
logic [7:0] bht_wr_en0, bht_wr_en1, bht_wr_en2;
assign middle_of_bank = exu_mp_pc4 ^ exu_mp_boffset;
assign bht_wr_en0[7:0] = {8{exu_mp_valid & ~exu_mp_call & ~exu_mp_ret & ~exu_mp_ja}} & decode3_8({exu_mp_bank[1:0], middle_of_bank});
assign bht_wr_en1[7:0] = {8{dec_tlu_br1_v_wb}} & decode3_8({dec_tlu_br1_bank_wb[1:0], dec_tlu_br1_middle_wb});
assign bht_wr_en2[7:0] = {8{dec_tlu_br0_v_wb}} & decode3_8({dec_tlu_br0_bank_wb[1:0], dec_tlu_br0_middle_wb});
// Experiments show this is the best priority scheme for same bank/index writes at the same time.
assign bht_wr_data0[1:0] = exu_mp_hist[1:0]; // lowest priority
assign bht_wr_data1[1:0] = dec_tlu_br1_hist_wb[1:0];
assign bht_wr_data2[1:0] = dec_tlu_br0_hist_wb[1:0]; // highest priority
logic [`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] bht_rd_addr_f1, bht_wr_addr0, bht_wr_addr1, bht_wr_addr2;
logic [`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] mp_hashed, br0_hashed_wb, br1_hashed_wb, bht_rd_addr_hashed_f1;
rvbtb_ghr_hash mpghrhs (.hashin(exu_mp_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]), .ghr(exu_mp_eghr[`RV_BHT_GHR_RANGE]), .hash(mp_hashed[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO]));
rvbtb_ghr_hash br0ghrhs (.hashin(dec_tlu_br0_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]), .ghr(dec_tlu_br0_fghr_wb[`RV_BHT_GHR_RANGE]), .hash(br0_hashed_wb[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO]));
rvbtb_ghr_hash br1ghrhs (.hashin(dec_tlu_br1_addr_wb[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]), .ghr(dec_tlu_br1_fghr_wb[`RV_BHT_GHR_RANGE]), .hash(br1_hashed_wb[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO]));
rvbtb_ghr_hash fghrhs (.hashin(btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO]), .ghr(fghr_ns[`RV_BHT_GHR_RANGE]), .hash(bht_rd_addr_hashed_f1[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO]));
assign bht_wr_addr0[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] = mp_hashed[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO];
assign bht_wr_addr1[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] = br1_hashed_wb[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO];
assign bht_wr_addr2[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] = br0_hashed_wb[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO];
assign bht_rd_addr_f1[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] = bht_rd_addr_hashed_f1[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO];
// ----------------------------------------------------------------------
// Structures. Using FLOPS
// ----------------------------------------------------------------------
// BTB
// Entry -> tag[`RV_BTB_BTAG_SIZE-1:0], toffset[11:0], pc4, boffset, call, ret, valid
for (j=0 ; j<LRU_SIZE ; j++) begin : BTB_FLOPS
// Way 0
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way0 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way0[0])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way0_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way0 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way0[1])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way0_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way0 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way0[2])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way0_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way0 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way0[3])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way0_out[j]));
// Way 1
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way1 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way1[0])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way1_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way1 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way1[1])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way1_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way1 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way1[2])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way1_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way1 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way1[3])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way1_out[j]));
`ifdef RV_BTB_48
// Way 2
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way2 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way2[0])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way2_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way2 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way2[1])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way2_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way2 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way2[2])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way2_out[j]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way2 (.*,
.en(((btb_wr_addr[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == j) & btb_wr_en_way2[3])),
.din (btb_wr_data[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way2_out[j]));
`endif
end
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way0_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank0_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way0_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way0_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank1_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way0_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way0_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank2_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way0_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way0_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank3_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way0_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way1_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank0_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way1_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way1_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank1_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way1_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way1_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank2_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way1_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way1_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank3_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way1_f2 [16+`RV_BTB_BTAG_SIZE:0]));
`ifdef RV_BTB_48
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank0_way2_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank0_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank0_rd_data_way2_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank1_way2_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank1_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank1_rd_data_way2_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank2_way2_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank2_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank2_rd_data_way2_f2 [16+`RV_BTB_BTAG_SIZE:0]));
rvdffe #(17+`RV_BTB_BTAG_SIZE) btb_bank3_way2_data_out (.*,
.en(ifc_fetch_req_f1),
.din (btb_bank3_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0]),
.dout (btb_bank3_rd_data_way2_f2 [16+`RV_BTB_BTAG_SIZE:0]));
`endif // `ifdef RV_BTB_48
always_comb begin : BTB_rd_mux
btb_bank0_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank1_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank2_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank3_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank0_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank1_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank2_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank3_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
`ifdef RV_BTB_48
btb_bank0_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank1_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank2_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
btb_bank3_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = '0 ;
`endif
for (int j=0; j< LRU_SIZE; j++) begin
if (btb_rd_addr_f1[`RV_BTB_ADDR_HI:`RV_BTB_ADDR_LO] == (`RV_BTB_ADDR_HI-`RV_BTB_ADDR_LO+1)'(j)) begin
btb_bank0_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank0_rd_data_way0_out[j];
btb_bank1_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank1_rd_data_way0_out[j];
btb_bank2_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank2_rd_data_way0_out[j];
btb_bank3_rd_data_way0_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank3_rd_data_way0_out[j];
btb_bank0_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank0_rd_data_way1_out[j];
btb_bank1_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank1_rd_data_way1_out[j];
btb_bank2_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank2_rd_data_way1_out[j];
btb_bank3_rd_data_way1_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank3_rd_data_way1_out[j];
`ifdef RV_BTB_48
btb_bank0_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank0_rd_data_way2_out[j];
btb_bank1_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank1_rd_data_way2_out[j];
btb_bank2_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank2_rd_data_way2_out[j];
btb_bank3_rd_data_way2_f2_in[16+`RV_BTB_BTAG_SIZE:0] = btb_bank3_rd_data_way2_out[j];
`endif
end
end
end
//-----------------------------------------------------------------------------
// BHT
// 2 bit Entry -> direction, strength
//
//-----------------------------------------------------------------------------
logic [7:0] [(`RV_BHT_ARRAY_DEPTH/NUM_BHT_LOOP)-1:0][NUM_BHT_LOOP-1:0][1:0] bht_bank_wr_data ;
logic [7:0] [`RV_BHT_ARRAY_DEPTH-1:0] [1:0] bht_bank_rd_data_out ;
logic [1:0] bht_bank0_rd_data_f2_in, bht_bank1_rd_data_f2_in, bht_bank2_rd_data_f2_in, bht_bank3_rd_data_f2_in;
logic [1:0] bht_bank4_rd_data_f2_in, bht_bank5_rd_data_f2_in, bht_bank6_rd_data_f2_in, bht_bank7_rd_data_f2_in;
logic [7:0] [(`RV_BHT_ARRAY_DEPTH/NUM_BHT_LOOP)-1:0] bht_bank_clken ;
logic [7:0] [(`RV_BHT_ARRAY_DEPTH/NUM_BHT_LOOP)-1:0] bht_bank_clk ;
logic [7:0] [(`RV_BHT_ARRAY_DEPTH/NUM_BHT_LOOP)-1:0][NUM_BHT_LOOP-1:0] bht_bank_sel ;
for ( i=0; i<8; i++) begin : BANKS
for (genvar k=0 ; k < (`RV_BHT_ARRAY_DEPTH)/NUM_BHT_LOOP ; k++) begin : BHT_CLK_GROUP
assign bht_bank_clken[i][k] = (bht_wr_en0[i] & ((bht_wr_addr0[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) |
(bht_wr_en1[i] & ((bht_wr_addr1[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) |
(bht_wr_en2[i] & ((bht_wr_addr2[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH));
rvclkhdr bht_bank_grp_cgc ( .en(bht_bank_clken[i][k]), .l1clk(bht_bank_clk[i][k]), .* );
for (j=0 ; j<NUM_BHT_LOOP ; j++) begin : BHT_FLOPS
assign bht_bank_sel[i][k][j] = (bht_wr_en0[i] & (bht_wr_addr0[NUM_BHT_LOOP_INNER_HI :`RV_BHT_ADDR_LO] == j) & ((bht_wr_addr0[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) |
(bht_wr_en1[i] & (bht_wr_addr1[NUM_BHT_LOOP_INNER_HI :`RV_BHT_ADDR_LO] == j) & ((bht_wr_addr1[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) |
(bht_wr_en2[i] & (bht_wr_addr2[NUM_BHT_LOOP_INNER_HI :`RV_BHT_ADDR_LO] == j) & ((bht_wr_addr2[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) ;
assign bht_bank_wr_data[i][k][j] = (bht_wr_en2[i] & (bht_wr_addr2[NUM_BHT_LOOP_INNER_HI:`RV_BHT_ADDR_LO] == j) & ((bht_wr_addr2[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) ? bht_wr_data2[1:0] :
(bht_wr_en1[i] & (bht_wr_addr1[NUM_BHT_LOOP_INNER_HI:`RV_BHT_ADDR_LO] == j) & ((bht_wr_addr1[`RV_BHT_ADDR_HI: NUM_BHT_LOOP_OUTER_LO]==k) | BHT_NO_ADDR_MATCH)) ? bht_wr_data1[1:0] :
bht_wr_data0[1:0] ;
rvdffs #(2) bht_bank (.*,
.clk (bht_bank_clk[i][k]),
.en (bht_bank_sel[i][k][j]),
.din (bht_bank_wr_data[i][k][j]),
.dout (bht_bank_rd_data_out[i][(16*k)+j]));
end // block: BHT_FLOPS
end // block: BHT_CLK_GROUP
end // block: BANKS
always_comb begin : BHT_rd_mux
bht_bank0_rd_data_f2_in[1:0] = '0 ;
bht_bank1_rd_data_f2_in[1:0] = '0 ;
bht_bank2_rd_data_f2_in[1:0] = '0 ;
bht_bank3_rd_data_f2_in[1:0] = '0 ;
bht_bank4_rd_data_f2_in[1:0] = '0 ;
bht_bank5_rd_data_f2_in[1:0] = '0 ;
bht_bank6_rd_data_f2_in[1:0] = '0 ;
bht_bank7_rd_data_f2_in[1:0] = '0 ;
for (int j=0; j< `RV_BHT_ARRAY_DEPTH; j++) begin
if (bht_rd_addr_f1[`RV_BHT_ADDR_HI:`RV_BHT_ADDR_LO] == (`RV_BHT_ADDR_HI-`RV_BHT_ADDR_LO+1)'(j)) begin
bht_bank0_rd_data_f2_in[1:0] = bht_bank_rd_data_out[0][j];
bht_bank1_rd_data_f2_in[1:0] = bht_bank_rd_data_out[1][j];
bht_bank2_rd_data_f2_in[1:0] = bht_bank_rd_data_out[2][j];
bht_bank3_rd_data_f2_in[1:0] = bht_bank_rd_data_out[3][j];
bht_bank4_rd_data_f2_in[1:0] = bht_bank_rd_data_out[4][j];
bht_bank5_rd_data_f2_in[1:0] = bht_bank_rd_data_out[5][j];
bht_bank6_rd_data_f2_in[1:0] = bht_bank_rd_data_out[6][j];
bht_bank7_rd_data_f2_in[1:0] = bht_bank_rd_data_out[7][j];
end
end
end // block: BHT_rd_mux
rvdffe #(16) bht_dataoutf (.*, .en (ifc_fetch_req_f1),
.din ({bht_bank0_rd_data_f2_in[1:0],
bht_bank1_rd_data_f2_in[1:0],
bht_bank2_rd_data_f2_in[1:0],
bht_bank3_rd_data_f2_in[1:0],
bht_bank4_rd_data_f2_in[1:0],
bht_bank5_rd_data_f2_in[1:0],
bht_bank6_rd_data_f2_in[1:0],
bht_bank7_rd_data_f2_in[1:0]
}),
.dout ({bht_bank0_rd_data_f2 [1:0],
bht_bank1_rd_data_f2 [1:0],
bht_bank2_rd_data_f2 [1:0],
bht_bank3_rd_data_f2 [1:0],
bht_bank4_rd_data_f2 [1:0],
bht_bank5_rd_data_f2 [1:0],
bht_bank6_rd_data_f2 [1:0],
bht_bank7_rd_data_f2 [1:0]
}));
function [2:0] encode8_3;
input [7:0] in;
encode8_3[2] = |in[7:4];
encode8_3[1] = in[7] | in[6] | in[3] | in[2];
encode8_3[0] = in[7] | in[5] | in[3] | in[1];
endfunction
function [7:0] decode3_8;
input [2:0] in;
decode3_8[7] = in[2] & in[1] & in[0];
decode3_8[6] = in[2] & in[1] & ~in[0];
decode3_8[5] = in[2] & ~in[1] & in[0];
decode3_8[4] = in[2] & ~in[1] & ~in[0];
decode3_8[3] = ~in[2] & in[1] & in[0];
decode3_8[2] = ~in[2] & in[1] & ~in[0];
decode3_8[1] = ~in[2] & ~in[1] & in[0];
decode3_8[0] = ~in[2] & ~in[1] & ~in[0];
endfunction
function [3:0] decode2_4;
input [1:0] in;
decode2_4[3] = in[1] & in[0];
decode2_4[2] = in[1] & ~in[0];
decode2_4[1] = ~in[1] & in[0];
decode2_4[0] = ~in[1] & ~in[0];
endfunction
function [3:0] countones;
input [7:0] valid;
begin
countones[3:0] = {3'b0, valid[7]} +
{3'b0, valid[6]} +
{3'b0, valid[5]} +
{3'b0, valid[4]} +
{3'b0, valid[3]} +
{3'b0, valid[2]} +
{3'b0, valid[1]} +
{3'b0, valid[0]};
end
endfunction
function [2:0] newlru; // updated lru
input [2:0] lru;// current lru
input [1:0] used;// hit way
begin
`ifdef BTB_ROUND_ROBIN
newlru[2] = 1'b0;
newlru[1:0] = (lru[1:0]==2'b10) ? 2'b0 : lru[1:0] + 2'b01;
`else
newlru[2] = (lru[2] & ~used[0]) | (~used[1] & ~used[0]);
newlru[1] = (~used[1] & ~used[0]) | (used[0]);
newlru[0] = (~lru[2] & lru[1] & ~used[1] & ~used[0]) | (~lru[1] & ~lru[0] & used[0]) | (
~lru[2] & lru[0] & used[0]) | (lru[0] & ~used[1] & ~used[0]);
`endif
end
endfunction //
function [1:0] lru2way; // new repl way taking invalid ways into account
input [2:0] lru; // current lru
input [2:0] v; // current way valids
begin
`ifdef BTB_ROUND_ROBIN
lru2way[1:0] = lru[1:0];
`else
lru2way[1] = (~lru[2] & lru[1] & ~lru[0] & v[1] & v[0]) | (lru[2] & lru[0] & v[1] & v[0]) | (~v[2] & v[1] & v[0]);
lru2way[0] = (lru[2] & ~lru[0] & v[2] & v[0]) | (~v[1] & v[0]);
`endif
end
endfunction
endmodule // ifu_bp_ctl