1 | // ========== Copyright Header Begin ========================================== |
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2 | // |
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3 | // OpenSPARC T1 Processor File: sparc_exu_alu.v |
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4 | // Copyright (c) 2006 Sun Microsystems, Inc. All Rights Reserved. |
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5 | // DO NOT ALTER OR REMOVE COPYRIGHT NOTICES. |
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6 | // |
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7 | // The above named program is free software; you can redistribute it and/or |
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8 | // modify it under the terms of the GNU General Public |
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9 | // License version 2 as published by the Free Software Foundation. |
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10 | // |
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11 | // The above named program is distributed in the hope that it will be |
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12 | // useful, but WITHOUT ANY WARRANTY; without even the implied warranty of |
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13 | // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
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14 | // General Public License for more details. |
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15 | // |
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16 | // You should have received a copy of the GNU General Public |
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17 | // License along with this work; if not, write to the Free Software |
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18 | // Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA. |
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19 | // |
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20 | // ========== Copyright Header End ============================================ |
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21 | //////////////////////////////////////////////////////////////////////// |
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22 | /* |
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23 | // Module Name: sparc_exu_alu |
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24 | */ |
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25 | |
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26 | module sparc_exu_alu |
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27 | ( |
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28 | /*AUTOARG*/ |
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29 | // Outputs |
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30 | so, alu_byp_rd_data_e, exu_ifu_brpc_e, exu_lsu_ldst_va_e, |
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31 | exu_lsu_early_va_e, exu_mmu_early_va_e, alu_ecl_add_n64_e, |
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32 | alu_ecl_add_n32_e, alu_ecl_log_n64_e, alu_ecl_log_n32_e, |
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33 | alu_ecl_zhigh_e, alu_ecl_zlow_e, exu_ifu_regz_e, exu_ifu_regn_e, |
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34 | alu_ecl_adderin2_63_e, alu_ecl_adderin2_31_e, |
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35 | alu_ecl_adder_out_63_e, alu_ecl_cout32_e, alu_ecl_cout64_e_l, |
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36 | alu_ecl_mem_addr_invalid_e_l, |
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37 | // Inputs |
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38 | rclk, se, si, byp_alu_rs1_data_e, byp_alu_rs2_data_e_l, |
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39 | byp_alu_rs3_data_e, byp_alu_rcc_data_e, ecl_alu_cin_e, |
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40 | ifu_exu_invert_d, ecl_alu_log_sel_and_e, ecl_alu_log_sel_or_e, |
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41 | ecl_alu_log_sel_xor_e, ecl_alu_log_sel_move_e, |
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42 | ecl_alu_out_sel_sum_e_l, ecl_alu_out_sel_rs3_e_l, |
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43 | ecl_alu_out_sel_shift_e_l, ecl_alu_out_sel_logic_e_l, |
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44 | shft_alu_shift_out_e, ecl_alu_sethi_inst_e, ifu_lsu_casa_e |
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45 | ); |
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46 | input rclk; |
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47 | input se; |
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48 | input si; |
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49 | input [63:0] byp_alu_rs1_data_e; // source operand 1 |
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50 | input [63:0] byp_alu_rs2_data_e_l; // source operand 2 |
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51 | input [63:0] byp_alu_rs3_data_e; // source operand 3 |
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52 | input [63:0] byp_alu_rcc_data_e; // source operand for reg condition codes |
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53 | input ecl_alu_cin_e; // cin for adder |
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54 | input ifu_exu_invert_d; |
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55 | input ecl_alu_log_sel_and_e;// These 4 wires are select lines for the logic |
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56 | input ecl_alu_log_sel_or_e;// block mux. They are active high and choose the |
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57 | input ecl_alu_log_sel_xor_e;// output they describe. |
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58 | input ecl_alu_log_sel_move_e; |
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59 | input ecl_alu_out_sel_sum_e_l;// The following 4 are select lines for |
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60 | input ecl_alu_out_sel_rs3_e_l;// the output stage mux. They are active high |
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61 | input ecl_alu_out_sel_shift_e_l;// and choose the output of the respective block. |
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62 | input ecl_alu_out_sel_logic_e_l; |
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63 | input [63:0] shft_alu_shift_out_e;// result from shifter |
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64 | input ecl_alu_sethi_inst_e; |
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65 | input ifu_lsu_casa_e; |
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66 | |
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67 | output so; |
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68 | output [63:0] alu_byp_rd_data_e; // alu result |
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69 | output [47:0] exu_ifu_brpc_e;// branch pc output |
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70 | output [47:0] exu_lsu_ldst_va_e; // address for lsu |
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71 | output [10:3] exu_lsu_early_va_e; // faster bits for cache |
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72 | output [7:0] exu_mmu_early_va_e; |
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73 | output alu_ecl_add_n64_e; |
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74 | output alu_ecl_add_n32_e; |
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75 | output alu_ecl_log_n64_e; |
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76 | output alu_ecl_log_n32_e; |
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77 | output alu_ecl_zhigh_e; |
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78 | output alu_ecl_zlow_e; |
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79 | output exu_ifu_regz_e; // rs1_data == 0 |
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80 | output exu_ifu_regn_e; |
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81 | output alu_ecl_adderin2_63_e; |
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82 | output alu_ecl_adderin2_31_e; |
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83 | output alu_ecl_adder_out_63_e; |
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84 | output alu_ecl_cout32_e; // To ecl of sparc_exu_ecl.v |
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85 | output alu_ecl_cout64_e_l; // To ecl of sparc_exu_ecl.v |
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86 | output alu_ecl_mem_addr_invalid_e_l;// adder_out[63:48] not all 1 or all 0 |
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87 | |
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88 | wire clk; |
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89 | wire [63:0] logic_out; // result of logic block |
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90 | wire [63:0] adder_out; // result of adder |
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91 | wire [63:0] spr_out; // result of sum predict |
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92 | wire [63:0] zcomp_in; // result going to zcompare |
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93 | wire [63:0] va_e; // complete va |
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94 | wire [63:0] byp_alu_rs2_data_e; |
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95 | wire invert_e; |
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96 | wire ecl_alu_out_sel_sum_e; |
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97 | wire ecl_alu_out_sel_rs3_e; |
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98 | wire ecl_alu_out_sel_shift_e; |
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99 | wire ecl_alu_out_sel_logic_e; |
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100 | assign clk = rclk; |
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101 | assign byp_alu_rs2_data_e[63:0] = ~byp_alu_rs2_data_e_l[63:0]; |
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102 | assign ecl_alu_out_sel_sum_e = ~ecl_alu_out_sel_sum_e_l; |
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103 | assign ecl_alu_out_sel_rs3_e = ~ecl_alu_out_sel_rs3_e_l; |
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104 | assign ecl_alu_out_sel_shift_e = ~ecl_alu_out_sel_shift_e_l; |
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105 | assign ecl_alu_out_sel_logic_e = ~ecl_alu_out_sel_logic_e_l; |
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106 | |
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107 | // Zero comparison for exu_ifu_regz_e |
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108 | sparc_exu_aluzcmp64 regzcmp(.in(byp_alu_rcc_data_e[63:0]), .zero64(exu_ifu_regz_e)); |
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109 | assign exu_ifu_regn_e = byp_alu_rcc_data_e[63]; |
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110 | |
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111 | // mux between adder output and rs1 (for casa) for lsu va |
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112 | dp_mux2es #(64) lsu_va_mux(.dout(va_e[63:0]), |
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113 | .in0(adder_out[63:0]), |
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114 | .in1(byp_alu_rs1_data_e[63:0]), |
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115 | .sel(ifu_lsu_casa_e)); |
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116 | assign exu_lsu_ldst_va_e[47:0] = va_e[47:0]; |
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117 | // for bits 10:4 we have a separate bus that is not used for cas |
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118 | assign exu_lsu_early_va_e[10:3] = adder_out[10:3]; |
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119 | // mmu needs bits 7:0 |
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120 | assign exu_mmu_early_va_e[7:0] = adder_out[7:0]; |
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121 | |
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122 | |
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123 | // Adder |
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124 | assign exu_ifu_brpc_e[47:0] = adder_out[47:0]; |
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125 | assign alu_ecl_adder_out_63_e = adder_out[63]; |
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126 | sparc_exu_aluaddsub addsub(.adder_out(adder_out[63:0]), |
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127 | /*AUTOINST*/ |
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128 | // Outputs |
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129 | .spr_out (spr_out[63:0]), |
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130 | .alu_ecl_cout64_e_l(alu_ecl_cout64_e_l), |
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131 | .alu_ecl_cout32_e(alu_ecl_cout32_e), |
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132 | .alu_ecl_adderin2_63_e(alu_ecl_adderin2_63_e), |
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133 | .alu_ecl_adderin2_31_e(alu_ecl_adderin2_31_e), |
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134 | // Inputs |
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135 | .clk (clk), |
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136 | .se (se), |
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137 | .byp_alu_rs1_data_e(byp_alu_rs1_data_e[63:0]), |
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138 | .byp_alu_rs2_data_e(byp_alu_rs2_data_e[63:0]), |
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139 | .ecl_alu_cin_e(ecl_alu_cin_e), |
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140 | .ifu_exu_invert_d(ifu_exu_invert_d)); |
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141 | |
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142 | // Logic/pass rs2_data |
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143 | dff_s invert_d2e(.din(ifu_exu_invert_d), .clk(clk), .q(invert_e), .se(se), .si(), .so()); |
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144 | sparc_exu_alulogic logic(.rs1_data(byp_alu_rs1_data_e[63:0]), |
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145 | .rs2_data(byp_alu_rs2_data_e[63:0]), |
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146 | .isand(ecl_alu_log_sel_and_e), |
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147 | .isor(ecl_alu_log_sel_or_e), |
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148 | .isxor(ecl_alu_log_sel_xor_e), |
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149 | .pass_rs2_data(ecl_alu_log_sel_move_e), |
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150 | .inv_logic(invert_e), .logic_out(logic_out[63:0]), |
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151 | .ifu_exu_sethi_inst_e(ecl_alu_sethi_inst_e)); |
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152 | |
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153 | // Mux between sum predict and logic outputs for zcc |
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154 | dp_mux2es #(64) zcompmux(.dout(zcomp_in[63:0]), |
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155 | .in0(logic_out[63:0]), |
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156 | .in1(spr_out[63:0]), |
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157 | .sel(ecl_alu_out_sel_sum_e)); |
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158 | |
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159 | // Zero comparison for zero cc |
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160 | // sparc_exu_aluzcmp64 zcccmp(.in(zcomp_in[63:0]), .zero64(alu_ecl_z64_e), |
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161 | // .zero32(alu_ecl_z32_e)); |
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162 | assign alu_ecl_zlow_e = ~(|zcomp_in[31:0]); |
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163 | assign alu_ecl_zhigh_e = ~(|zcomp_in[63:32]); |
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164 | |
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165 | // Get Negative ccs |
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166 | assign alu_ecl_add_n64_e = adder_out[63]; |
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167 | assign alu_ecl_add_n32_e = adder_out[31]; |
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168 | assign alu_ecl_log_n64_e = logic_out[63]; |
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169 | assign alu_ecl_log_n32_e = logic_out[31]; |
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170 | |
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171 | |
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172 | // Mux for output |
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173 | mux4ds #(64) output_mux(.dout(alu_byp_rd_data_e[63:0]), |
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174 | .in0(adder_out[63:0]), |
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175 | .in1(byp_alu_rs3_data_e[63:0]), |
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176 | .in2(shft_alu_shift_out_e[63:0]), |
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177 | .in3(logic_out[63:0]), |
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178 | .sel0(ecl_alu_out_sel_sum_e), |
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179 | .sel1(ecl_alu_out_sel_rs3_e), |
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180 | .sel2(ecl_alu_out_sel_shift_e), |
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181 | .sel3(ecl_alu_out_sel_logic_e)); |
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182 | |
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183 | // memory address checks |
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184 | sparc_exu_alu_16eql chk_mem_addr(.equal(alu_ecl_mem_addr_invalid_e_l), |
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185 | .in(va_e[63:47])); |
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186 | |
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187 | endmodule // sparc_exu_alu |
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