Mercurial > hg > CbC > CbC_gcc
view gcc/config/arm/exynos-m1.md @ 131:84e7813d76e9
gcc-8.2
| author | mir3636 |
|---|---|
| date | Thu, 25 Oct 2018 07:37:49 +0900 |
| parents | 04ced10e8804 |
| children | 1830386684a0 |
line wrap: on
line source
;; Samsung Exynos M1 pipeline description ;; Copyright (C) 2014-2018 Free Software Foundation, Inc. ;; ;; This file is part of GCC. ;; ;; GCC is free software; you can redistribute it and/or modify it ;; under the terms of the GNU General Public License as published by ;; the Free Software Foundation; either version 3, or (at your option) ;; any later version. ;; ;; GCC is distributed in the hope that it will be useful, but ;; WITHOUT ANY WARRANTY; without even the implied warranty of ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU ;; General Public License for more details. ;; ;; You should have received a copy of the GNU General Public License ;; along with GCC; see the file COPYING3. If not see ;; <http://www.gnu.org/licenses/>. (define_attr "exynos_m1_neon_type" "neon_arith_simple, neon_arith_basic, neon_arith_complex, neon_multiply, neon_mla, neon_mla_q, neon_mla_long, neon_sat_mla_long, neon_shift_acc, neon_shift_imm_basic, neon_shift_imm_complex, neon_shift_reg_basic, neon_shift_reg_basic_q, neon_shift_reg_complex, neon_shift_reg_complex_q, neon_fp_unary, neon_fp_add, neon_fp_abd, neon_fp_compare, neon_fp_reduc_minmax, neon_fp_reduc_add, neon_fp_round, neon_fp_cvt, neon_fp_minmax, neon_fp_mul, neon_fp_mul_q, neon_fp_mla, neon_fp_mla_q, neon_fp_estimate, neon_fp_estimatex, neon_fp_step, neon_bitops, neon_bitops_q, neon_bitins, neon_to_gp, neon_from_gp, neon_move, neon_tbl, neon_load1_1, neon_load1_2, neon_load1_3, neon_load1_4, neon_load1_one, neon_load1_all, neon_load2_2, neon_load2_one, neon_load2_all, neon_load3_3, neon_load3_one, neon_load3_all, neon_load4_4, neon_load4_one, neon_load4_all, neon_store, neon_store1_1, neon_store1_2, neon_store1_3, neon_store1_4, neon_store1_one, neon_store2_2, neon_store2_one, neon_store3_3, neon_store3_one, neon_store4_4, neon_store4_one, unknown" (cond [ (eq_attr "type" "neon_abd, neon_abd_q, neon_abd_long,\ neon_abs, neon_abs_q,\ neon_minmax, neon_minmax_q") (const_string "neon_arith_simple") (eq_attr "type" "neon_add, neon_add_q, neon_add_long,\ neon_neg, neon_neg_q,\ neon_sub, neon_sub_q, neon_sub_long, neon_sub_widen,\ neon_logic, neon_logic_q, neon_tst, neon_tst_q,\ neon_compare_zero, neon_compare_zero_q") (const_string "neon_arith_basic") (eq_attr "type" "neon_add_widen, neon_arith_acc, neon_arith_acc_q,\ neon_reduc_add, neon_reduc_add_q,\ neon_reduc_add_acc, neon_reduc_add_acc_q,\ neon_reduc_add_long, neon_add_halve_narrow_q,\ neon_add_halve, neon_add_halve_q,\ neon_sub_halve, neon_sub_halve_q, neon_qabs,\ neon_qabs_q, neon_qadd, neon_qadd_q, neon_qneg,\ neon_qneg_q, neon_qsub, neon_qsub_q,\ neon_sub_halve_narrow_q,\ neon_compare, neon_compare_q,\ neon_reduc_minmax, neon_reduc_minmax_q") (const_string "neon_arith_complex") (eq_attr "type" "neon_mul_b, neon_mul_b_q, neon_mul_h, neon_mul_h_q,\ neon_mul_s, neon_mul_s_q,\ neon_mul_h_scalar, neon_mul_h_scalar_q,\ neon_mul_s_scalar, neon_mul_s_scalar_q,\ neon_mul_h_scalar_long, neon_mul_s_scalar_long,\ neon_sat_mul_b, neon_sat_mul_b_q,\ neon_sat_mul_h, neon_sat_mul_h_q,\ neon_sat_mul_s, neon_sat_mul_s_q,\ neon_sat_mul_h_scalar, neon_sat_mul_h_scalar_q,\ neon_sat_mul_s_scalar, neon_sat_mul_s_scalar_q,\ neon_sat_mul_b_long, neon_sat_mul_h_long,\ neon_sat_mul_s_long, neon_sat_mul_h_scalar_long,\ neon_sat_mul_s_scalar_long, crypto_pmull") (const_string "neon_multiply") (eq_attr "type" "neon_mla_b, neon_mla_h, neon_mla_s,\ neon_mla_h_scalar, neon_mla_s_scalar,\ neon_mla_b_long, neon_mla_h_long,\ neon_mla_s_long,\ neon_mla_h_scalar_long, neon_mla_s_scalar_long,\ neon_mla_b_q, neon_mla_h_q, neon_mla_s_q,\ neon_mla_h_scalar_q, neon_mla_s_scalar_q") (const_string "neon_mla") (eq_attr "type" "neon_sat_mla_b_long, neon_sat_mla_h_long,\ neon_sat_mla_s_long, neon_sat_mla_h_scalar_long,\ neon_sat_mla_s_scalar_long") (const_string "neon_sat_mla_long") (eq_attr "type" "neon_shift_acc, neon_shift_acc_q") (const_string "neon_shift_acc") (eq_attr "type" "neon_shift_imm, neon_shift_imm_q,\ neon_shift_imm_narrow_q, neon_shift_imm_long") (const_string "neon_shift_imm_basic") (eq_attr "type" "neon_sat_shift_imm, neon_sat_shift_imm_q,\ neon_sat_shift_imm_narrow_q") (const_string "neon_shift_imm_complex") (eq_attr "type" "neon_shift_reg, neon_shift_reg_q") (const_string "neon_shift_reg_basic") (eq_attr "type" "neon_sat_shift_reg, neon_sat_shift_reg_q") (const_string "neon_shift_reg_complex") (eq_attr "type" "neon_fp_neg_s, neon_fp_neg_s_q,\ neon_fp_abs_s, neon_fp_abs_s_q,\ neon_fp_neg_d, neon_fp_neg_d_q,\ neon_fp_abs_d, neon_fp_abs_d_q") (const_string "neon_fp_unary") (eq_attr "type" "neon_fp_addsub_s, neon_fp_addsub_s_q,\ neon_fp_addsub_d, neon_fp_addsub_d_q") (const_string "neon_fp_add") (eq_attr "type" "neon_fp_abd_s, neon_fp_abd_s_q,\ neon_fp_abd_d, neon_fp_abd_d_q") (const_string "neon_fp_abd") (eq_attr "type" "neon_fp_compare_s, neon_fp_compare_s_q,\ neon_fp_compare_d, neon_fp_compare_d_q,\ neon_fp_minmax_s, neon_fp_minmax_s_q,\ neon_fp_minmax_d, neon_fp_minmax_d_q") (const_string "neon_fp_compare") (eq_attr "type" "neon_fp_reduc_minmax_s, neon_fp_reduc_minmax_s_q,\ neon_fp_reduc_minmax_d, neon_fp_reduc_minmax_d_q") (const_string "neon_fp_reduc_minmax") (eq_attr "type" "neon_fp_reduc_add_s, neon_fp_reduc_add_s_q,\ neon_fp_reduc_add_d, neon_fp_reduc_add_d_q") (const_string "neon_fp_reduc_add") (eq_attr "type" "neon_fp_round_s, neon_fp_round_s_q,\ neon_fp_round_d, neon_fp_round_d_q") (const_string "neon_fp_round") (eq_attr "type" "neon_fp_cvt_narrow_s_q, neon_fp_cvt_widen_h, neon_fp_to_int_s, neon_fp_to_int_s_q,\ neon_fp_to_int_d_q, neon_fp_to_int_d,\ neon_int_to_fp_s, neon_int_to_fp_s_q,\ neon_int_to_fp_d, neon_int_to_fp_d_q") (const_string "neon_fp_cvt") (eq_attr "type" "neon_fp_mul_s, neon_fp_mul_s_q,\ neon_fp_mul_s_scalar, neon_fp_mul_s_scalar_q,\ neon_fp_mul_d, neon_fp_mul_d_q,\ neon_fp_mul_d_scalar_q") (const_string "neon_fp_mul") (eq_attr "type" "neon_fp_mla_s, neon_fp_mla_s_q,\ neon_fp_mla_s_scalar,neon_fp_mla_s_scalar_q,\ neon_fp_mla_d, neon_fp_mla_d_q,\ neon_fp_mla_d_scalar_q") (const_string "neon_fp_mla") (eq_attr "type" "neon_fp_recpe_s, neon_fp_recpe_s_q,\ neon_fp_rsqrte_s, neon_fp_rsqrte_s_q,\ neon_fp_recpe_d, neon_fp_recpe_d_q,\ neon_fp_rsqrte_d, neon_fp_rsqrte_d_q") (const_string "neon_fp_estimate") (eq_attr "type" "neon_fp_recpx_s, neon_fp_recpx_s_q,\ neon_fp_recpx_d, neon_fp_recpx_d_q") (const_string "neon_fp_estimatex") (eq_attr "type" "neon_fp_recps_s, neon_fp_recps_s_q,\ neon_fp_rsqrts_s, neon_fp_rsqrts_s_q,\ neon_fp_recps_d, neon_fp_recps_d_q,\ neon_fp_rsqrts_d, neon_fp_rsqrts_d_q") (const_string "neon_fp_step") (eq_attr "type" "neon_rbit, neon_rbit_q,\ neon_cls, neon_cls_q, neon_cnt, neon_cnt_q,\ neon_dup, neon_dup_q,\ neon_rev, neon_rev_q,\ neon_move, neon_move_q, neon_ext, neon_permute, neon_zip") (const_string "neon_bitops") (eq_attr "type" "neon_ext_q, neon_permute_q, neon_zip_q") (const_string "neon_bitops_q") (eq_attr "type" "neon_bsl, neon_bsl_q") (const_string "neon_bitins") (eq_attr "type" "neon_tbl1, neon_tbl2, neon_tbl3, neon_tbl4") (const_string "neon_tbl") (eq_attr "type" "neon_from_gp, neon_from_gp_q, f_mcr, f_mcrr") (const_string "neon_from_gp") (eq_attr "type" "neon_to_gp, neon_to_gp_q, f_mrc, f_mrrc") (const_string "neon_to_gp") (eq_attr "type" "neon_load1_1reg, neon_load1_1reg_q") (const_string "neon_load1_1") (eq_attr "type" "neon_load1_2reg, neon_load1_2reg_q") (const_string "neon_load1_2") (eq_attr "type" "neon_load1_3reg, neon_load1_3reg_q") (const_string "neon_load1_3") (eq_attr "type" "neon_load1_4reg, neon_load1_4reg_q") (const_string "neon_load1_4") (eq_attr "type" "neon_load1_one_lane, neon_load1_one_lane_q") (const_string "neon_load1_one") (eq_attr "type" "neon_load1_all_lanes, neon_load1_all_lanes_q") (const_string "neon_load1_all") (eq_attr "type" "neon_load2_2reg, neon_load2_2reg_q,\ neon_load2_4reg, neon_load2_4reg_q") (const_string "neon_load2_2") (eq_attr "type" "neon_load2_one_lane, neon_load2_one_lane_q") (const_string "neon_load2_one") (eq_attr "type" "neon_load2_all_lanes, neon_load2_all_lanes_q") (const_string "neon_load2_all") (eq_attr "type" "neon_load3_3reg, neon_load3_3reg_q") (const_string "neon_load3_3") (eq_attr "type" "neon_load3_one_lane, neon_load3_one_lane_q") (const_string "neon_load3_one") (eq_attr "type" "neon_load3_all_lanes, neon_load3_all_lanes_q") (const_string "neon_load3_all") (eq_attr "type" "neon_load4_4reg, neon_load4_4reg_q") (const_string "neon_load4_4") (eq_attr "type" "neon_load4_one_lane, neon_load4_one_lane_q") (const_string "neon_load4_one") (eq_attr "type" "neon_load4_all_lanes, neon_load4_all_lanes_q") (const_string "neon_load4_all") (eq_attr "type" "neon_store1_1reg, neon_store1_1reg_q") (const_string "neon_store1_1") (eq_attr "type" "neon_store1_2reg, neon_store1_2reg_q") (const_string "neon_store1_2") (eq_attr "type" "neon_store1_3reg, neon_store1_3reg_q") (const_string "neon_store1_3") (eq_attr "type" "neon_store1_4reg, neon_store1_4reg_q") (const_string "neon_store1_4") (eq_attr "type" "neon_store1_one_lane, neon_store1_one_lane_q") (const_string "neon_store1_one") (eq_attr "type" "neon_store2_2reg, neon_store2_2reg_q,\ neon_store2_4reg, neon_store2_4reg_q") (const_string "neon_store2_2") (eq_attr "type" "neon_store2_one_lane, neon_store2_one_lane_q") (const_string "neon_store2_one") (eq_attr "type" "neon_store3_3reg, neon_store3_3reg_q") (const_string "neon_store3_3") (eq_attr "type" "neon_store3_one_lane, neon_store3_one_lane_q") (const_string "neon_store3_one") (eq_attr "type" "neon_store4_4reg, neon_store4_4reg_q") (const_string "neon_store4_4") (eq_attr "type" "neon_store4_one_lane, neon_store4_one_lane_q") (const_string "neon_store4_one")] (const_string "unknown"))) ;; The Exynos M1 core is modeled as a triple issue pipeline that has ;; the following functional units. (define_automaton "exynos_m1_gp") (define_automaton "exynos_m1_ls") (define_automaton "exynos_m1_fp") ;; 1. Two pipelines for simple integer operations: A, B ;; 2. One pipeline for simple or complex integer operations: C (define_cpu_unit "em1_xa, em1_xb, em1_xc" "exynos_m1_gp") (define_reservation "em1_alu" "(em1_xa | em1_xb | em1_xc)") (define_reservation "em1_c" "em1_xc") ;; 3. Two asymmetric pipelines for Neon and FP operations: F0, F1 (define_cpu_unit "em1_f0, em1_f1" "exynos_m1_fp") (define_reservation "em1_fmac" "em1_f0") (define_reservation "em1_fcvt" "em1_f0") (define_reservation "em1_nalu" "(em1_f0 | em1_f1)") (define_reservation "em1_nalu0" "em1_f0") (define_reservation "em1_nalu1" "em1_f1") (define_reservation "em1_nmisc" "em1_f0") (define_reservation "em1_ncrypt" "em1_f0") (define_reservation "em1_fadd" "em1_f1") (define_reservation "em1_fvar" "em1_f1") (define_reservation "em1_fst" "em1_f1") ;; 4. One pipeline for branch operations: BX (define_cpu_unit "em1_bx" "exynos_m1_gp") (define_reservation "em1_br" "em1_bx") ;; 5. One AGU for loads: L ;; One AGU for stores and one pipeline for stores: S, SD (define_cpu_unit "em1_lx" "exynos_m1_ls") (define_cpu_unit "em1_sx, em1_sd" "exynos_m1_ls") (define_reservation "em1_ld" "em1_lx") (define_reservation "em1_st" "(em1_sx + em1_sd)") ;; Common occurrences (define_reservation "em1_sfst" "(em1_fst + em1_st)") (define_reservation "em1_lfst" "(em1_fst + em1_ld)") ;; Branches ;; ;; No latency as there is no result ;; TODO: Unconditional branches use no units; ;; conditional branches add the BX unit; ;; indirect branches add the C unit. (define_insn_reservation "exynos_m1_branch" 0 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "branch")) "em1_br") (define_insn_reservation "exynos_m1_call" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "call")) "em1_alu") ;; Basic ALU ;; ;; Simple ALU without shift, non-predicated (define_insn_reservation "exynos_m1_alu" 1 (and (eq_attr "tune" "exynosm1") (and (not (eq_attr "predicated" "yes")) (eq_attr "type" "alu_imm, alus_imm, logic_imm, logics_imm,\ alu_sreg, alus_sreg, logic_reg, logics_reg,\ adc_imm, adcs_imm, adc_reg, adcs_reg,\ adr, bfm, bfx, clz, rbit, rev, csel, alu_dsp_reg,\ shift_imm, shift_reg, rotate_imm, extend,\ mov_imm, mov_reg,\ mvn_imm, mvn_reg,\ mrs, multiple"))) "em1_alu") ;; Simple ALU without shift, predicated (define_insn_reservation "exynos_m1_alu_p" 1 (and (eq_attr "tune" "exynosm1") (and (eq_attr "predicated" "yes") (eq_attr "type" "alu_imm, alus_imm, logic_imm, logics_imm,\ alu_sreg, alus_sreg, logic_reg, logics_reg,\ adc_imm, adcs_imm, adc_reg, adcs_reg,\ adr, bfm, bfx, clz, rbit, rev, alu_dsp_reg,\ shift_imm, shift_reg, rotate_imm, extend,\ mov_imm, mov_reg,\ mvn_imm, mvn_reg,\ mrs, multiple"))) "em1_c") ;; ALU ops with immediate shift ;; TODO: if the shift value is between 0 and 3, the latency is just 1 cycle; ;; otherwise it takes 2 cycles and the unit is blocked; ;; for now, assume the latter's latency and the former's units. (define_insn_reservation "exynos_m1_alu_shift" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "alu_ext, alus_ext,\ alu_shift_imm, alus_shift_imm,\ logic_shift_imm, logics_shift_imm,\ mov_shift, mvn_shift")) "(em1_alu)") ;; ALU ops with register controlled shift, non-predicated (define_insn_reservation "exynos_m1_alu_shift_reg" 2 (and (eq_attr "tune" "exynosm1") (and (not (eq_attr "predicated" "yes")) (eq_attr "type" "alu_shift_reg, alus_shift_reg,\ logic_shift_reg, logics_shift_reg,\ mov_shift_reg, mvn_shift_reg"))) "(em1_alu * 2)") ;; ALU ops with register controlled shift, predicated (define_insn_reservation "exynos_m1_alu_shift_reg_p" 2 (and (eq_attr "tune" "exynosm1") (and (eq_attr "predicated" "yes") (eq_attr "type" "alu_shift_reg, alus_shift_reg,\ logic_shift_reg, logics_shift_reg,\ mov_shift_reg, mvn_shift_reg"))) "(em1_alu, em1_c)") ;; Integer multiply (define_insn_reservation "exynos_m1_mla" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "mul32" "yes")) "em1_c") (define_insn_reservation "exynos_m1_mlal" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "mul64" "yes")) "em1_alu, em1_c") ;; Integer divide ;; TODO: assume the median latency; blocks other divisions (define_insn_reservation "exynos_m1_div" 13 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "udiv, sdiv")) "em1_c") ;; Load-store execution Unit ;; ;; Loads of up to 2 words. (define_insn_reservation "exynos_m1_load" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "load_byte, load_4, load_8")) "em1_ld") ;; Loads of 3 or 4 words. (define_insn_reservation "exynos_m1_loadm" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "load_12, load_16")) "(em1_ld * 3)") ;; Stores of up to 2 words. (define_insn_reservation "exynos_m1_store" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "store_4, store_8")) "em1_st") ;; Stores of 3 or 4 words. (define_insn_reservation "exynos_m1_storem" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "store_12, store_16")) "(em1_st * 3)") ;; Advanced SIMD Unit ;; ;; Integer Arithmetic Instructions. (define_insn_reservation "exynos_m1_arith_simple" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_arith_simple")) "em1_nmisc") (define_insn_reservation "exynos_m1_neon_arith_basic" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_arith_basic")) "em1_nalu") (define_insn_reservation "exynos_m1_neon_arith_complex" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_arith_complex")) "em1_nmisc") ;; Integer Multiply Instructions. (define_insn_reservation "exynos_m1_neon_multiply" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_multiply, neon_mla, neon_sat_mla_long")) "em1_nmisc") ;; Integer Shift Instructions. (define_insn_reservation "exynos_m1_neon_shift_acc" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_shift_acc")) "em1_nalu1") (define_insn_reservation "exynos_m1_neon_shift_basic" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_shift_imm_basic, neon_shift_reg_basic")) "em1_nalu") (define_insn_reservation "exynos_m1_neon_shift_complex" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_shift_imm_complex, neon_shift_reg_complex")) "em1_nalu1") ;; Floating Point Instructions. (define_insn_reservation "exynos_m1_neon_fp_unary" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_unary")) "em1_nalu") (define_insn_reservation "exynos_m1_neon_fp_add" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_add")) "em1_fadd") (define_insn_reservation "exynos_m1_neon_fp_abd" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_abd")) "em1_nmisc") (define_insn_reservation "exynos_m1_neon_fp_compare" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_compare")) "em1_nmisc") ;; TODO: the latency and throughput of reduce insns actually varies between ;; 3-5 and 1/4-1, but picked the median values. (define_insn_reservation "exynos_m1_neon_fp_reduc" 5 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_reduc_minmax")) "(em1_nmisc * 4)") (define_insn_reservation "exynos_m1_neon_fp_reduc_add" 10 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_reduc_add")) "((em1_nalu * 2), em1_fadd)") (define_insn_reservation "exynos_m1_neon_fp_round" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_round")) "em1_fcvt") (define_insn_reservation "exynos_m1_neon_fp_cvt" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_cvt")) "em1_fcvt") (define_insn_reservation "exynos_m1_neon_fp_mul" 5 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_mul")) "em1_fmac") (define_insn_reservation "exynos_m1_neon_fp_mla" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_mla")) "em1_fmac") (define_insn_reservation "exynos_m1_neon_fp_estimate" 5 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_estimate")) "em1_fcvt") (define_insn_reservation "exynos_m1_neon_fp_estimatex" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_estimatex")) "em1_nmisc") (define_insn_reservation "exynos_m1_neon_fp_step" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_fp_step")) "em1_fmac") ;; Miscellaneous Instructions. (define_insn_reservation "exynos_m1_neon_bitops" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_bitops")) "em1_nalu") (define_insn_reservation "exynos_m1_neon_bitops_q" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_bitops_q")) "(em1_nalu, em1_nalu)") (define_insn_reservation "exynos_m1_neon_bitins" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_bitins")) "em1_nalu1") ;; TODO: it is more complicated than this. (define_insn_reservation "exynos_m1_neon_tbl" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_tbl")) "em1_nalu1") (define_insn_reservation "exynos_m1_neon_from_gp" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_from_gp")) "em1_st") (define_insn_reservation "exynos_m1_neon_to_gp" 9 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_to_gp")) "em1_lfst") ;; Load Instructions. (define_insn_reservation "exynos_m1_neon_load" 5 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_loads, f_loadd, neon_ldp")) "em1_ld") (define_insn_reservation "exynos_m1_neon_load_q" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "neon_ldp_q")) "(em1_ld, em1_ld)") (define_insn_reservation "exynos_m1_neon_load1_1" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load1_1, neon_load1_all")) "em1_ld") (define_insn_reservation "exynos_m1_neon_load1_2" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load1_2")) "(em1_ld * 2)") (define_insn_reservation "exynos_m1_neon_load1_3" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load1_3")) "(em1_ld * 3)") (define_insn_reservation "exynos_m1_neon_load1_4" 8 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load1_4")) "(em1_ld * 4)") (define_insn_reservation "exynos_m1_neon_load1_one" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load1_one")) "((em1_ld * 2), em1_nalu)") (define_insn_reservation "exynos_m1_neon_load2_2" 10 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load2_2")) "(em1_ld * 5)") (define_insn_reservation "exynos_m1_neon_load2_one" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load2_one")) "((em1_ld * 2), (em1_nalu * 2))") (define_insn_reservation "exynos_m1_neon_load2_all" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load2_all")) "(em1_ld * 2)") (define_insn_reservation "exynos_m1_neon_load3_3" 12 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load3_3")) "(em1_ld * 6)") (define_insn_reservation "exynos_m1_neon_load3_one" 9 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load3_one")) "((em1_ld * 4), (em1_nalu * 3))") (define_insn_reservation "exynos_m1_neon_load3_all" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load3_all")) "(em1_ld * 3)") (define_insn_reservation "exynos_m1_neon_load4_4" 14 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load4_4")) "(em1_ld * 7)") (define_insn_reservation "exynos_m1_neon_load4_one" 9 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load4_one")) "((em1_ld * 4), (em1_nalu * 4))") (define_insn_reservation "exynos_m1_neon_load4_all" 8 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_load4_all")) "(em1_ld * 4)") ;; Store Instructions. (define_insn_reservation "exynos_m1_neon_store" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_stores, f_stored, neon_stp")) "em1_sfst") (define_insn_reservation "exynos_m1_neon_store_q" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "neon_stp_q")) "(em1_sfst * 2)") (define_insn_reservation "exynos_m1_neon_store1_1" 1 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store1_1")) "em1_sfst") (define_insn_reservation "exynos_m1_neon_store1_2" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store1_2")) "(em1_sfst * 2)") (define_insn_reservation "exynos_m1_neon_store1_3" 3 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store1_3")) "(em1_sfst * 3)") (define_insn_reservation "exynos_m1_neon_store1_4" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store1_4")) "(em1_sfst * 4)") (define_insn_reservation "exynos_m1_neon_store1_one" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store1_one")) "em1_sfst") (define_insn_reservation "exynos_m1_neon_store2" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store2_2, neon_store2_one")) "em1_sfst, em1_fst") (define_insn_reservation "exynos_m1_neon_store3" 16 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store3_3, neon_store3_one")) "((em1_sfst * 3), (em1_fst * 2), em1_nalu)") (define_insn_reservation "exynos_m1_neon_store4" 17 (and (eq_attr "tune" "exynosm1") (eq_attr "exynos_m1_neon_type" "neon_store4_4, neon_store4_one")) "((em1_sfst * 4), (em1_fst * 2), em1_nalu)") ;; Floating-Point Operations. (define_insn_reservation "exynos_m1_fp_const" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fconsts, fconstd")) "em1_nalu") (define_insn_reservation "exynos_m1_fp_add" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fadds, faddd")) "em1_fadd") (define_insn_reservation "exynos_m1_fp_mul" 5 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fmuls, fmuld")) "em1_fmac") (define_insn_reservation "exynos_m1_fp_mac" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fmacs, ffmas, fmacd, ffmad")) "em1_fmac") (define_insn_reservation "exynos_m1_fp_cvt" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_cvt, f_rints, f_rintd")) "em1_fcvt") (define_insn_reservation "exynos_m1_fp_cvt_i" 13 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_cvtf2i")) "(em1_fcvt, em1_lfst)") (define_insn_reservation "exynos_m1_i_cvt_fp" 9 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_cvti2f")) "(em1_st, em1_fcvt)") (define_insn_reservation "exynos_m1_fp_cmp" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fcmps, fcmpd")) "em1_nmisc") (define_insn_reservation "exynos_m1_fp_ccmp" 7 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fccmps, fccmpd")) "(em1_st, em1_nmisc)") (define_insn_reservation "exynos_m1_fp_sel" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fcsel")) "(em1_st + em1_nalu0)") (define_insn_reservation "exynos_m1_fp_arith" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "ffariths, ffarithd")) "em1_nalu") (define_insn_reservation "exynos_m1_fp_cpy" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fmov")) "em1_nalu") (define_insn_reservation "exynos_m1_fp_divs" 15 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fdivs, neon_fp_div_s, neon_fp_div_s_q,\ fsqrts, neon_fp_sqrt_s, neon_fp_sqrt_s_q")) "(em1_fvar * 9)") (define_insn_reservation "exynos_m1_fp_divd" 22 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "fdivd, neon_fp_div_d, neon_fp_div_d_q,\ fsqrtd, neon_fp_sqrt_d, neon_fp_sqrt_d_q")) "(em1_fvar * 9)") (define_insn_reservation "exynos_m1_fp_minmax" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "f_minmaxs, f_minmaxd")) "(em1_nmisc * 2)") ;; Crypto Operations. (define_insn_reservation "exynos_m1_crypto_simple" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "crypto_aese, crypto_aesmc,\ crypto_sha1_xor, crypto_sha1_fast, crypto_sha256_fast")) "em1_ncrypt") (define_insn_reservation "exynos_m1_crypto_complex" 6 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "crypto_sha1_slow, crypto_sha256_slow")) "em1_ncrypt") (define_insn_reservation "exynos_m1_crypto_poly" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "neon_mul_b_long, neon_mul_h_long, neon_mul_s_long")) "em1_ncrypt") (define_insn_reservation "exynos_m1_crypto_polyl" 4 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "neon_mul_d_long")) "em1_ncrypt") (define_insn_reservation "exynos_m1_crc" 2 (and (eq_attr "tune" "exynosm1") (eq_attr "type" "crc")) "em1_c") ;; Simple execution unit bypasses ;; Pre-decrement and post-increment addressing modes update the register quickly. ;; TODO: figure out how to tell the addressing mode register from the loaded one. (define_bypass 1 "exynos_m1_store*, exynos_m1_neon_store*" "exynos_m1_store*, exynos_m1_neon_store*, exynos_m1_load*, exynos_m1_neon_load*") ;; MLAs can feed other MLAs quickly. (define_bypass 1 "exynos_m1_mla*" "exynos_m1_mla*") ;; Insns in FMAC or FADD can feed other such insns quickly. (define_bypass 4 "exynos_m1_fp_mul" "exynos_m1_fp_add, exynos_m1_fp_mul, exynos_m1_fp_mac") (define_bypass 5 "exynos_m1_fp_mac" "exynos_m1_fp_add, exynos_m1_fp_mul, exynos_m1_fp_mac") (define_bypass 4 "exynos_m1_neon_fp_mul" "exynos_m1_neon_fp_add, exynos_m1_neon_fp_mul,\ exynos_m1_neon_fp_mla, exynos_m1_neon_fp_step") (define_bypass 5 "exynos_m1_neon_fp_mla, exynos_m1_neon_fp_step" "exynos_m1_neon_fp_add, exynos_m1_neon_fp_mul,\ exynos_m1_neon_fp_mla, exynos_m1_neon_fp_step") (define_bypass 3 "exynos_m1_fp_add" "exynos_m1_fp_add, exynos_m1_fp_mul, exynos_m1_fp_mac") (define_bypass 3 "exynos_m1_neon_fp_add" "exynos_m1_neon_fp_add, exynos_m1_neon_fp_mul,\ exynos_m1_neon_fp_mla, exynos_m1_neon_fp_step") ;; Insns in NALU can feed other such insns quickly. (define_bypass 1 "exynos_m1_fp_const, exynos_m1_fp_arith, exynos_m1_fp_cpy" "exynos_m1_fp_const, exynos_m1_fp_arith, exynos_m1_fp_cpy,\ exynos_m1_fp_sel") (define_bypass 3 "exynos_m1_fp_sel" "exynos_m1_fp_const, exynos_m1_fp_arith, exynos_m1_fp_cpy,\ exynos_m1_fp_sel") (define_bypass 1 "exynos_m1_neon_arith_basic, exynos_m1_neon_shift_basic,\ exynos_m1_neon_bitops, exynos_m1_neon_bitins,\ exynos_m1_neon_tbl" "exynos_m1_neon_arith_basic, exynos_m1_neon_shift_basic,\ exynos_m1_neon_shift_acc, exynos_m1_neon_shift_complex,\ exynos_m1_neon_bitops*, exynos_m1_neon_bitins,\ exynos_m1_neon_tbl") (define_bypass 3 "exynos_m1_neon_shift_acc, exynos_m1_neon_shift_complex" "exynos_m1_neon_arith_basic, exynos_m1_neon_shift_basic,\ exynos_m1_neon_shift_acc, exynos_m1_neon_shift_complex,\ exynos_m1_neon_bitops*, exynos_m1_neon_bitins,\ exynos_m1_neon_tbl") (define_bypass 1 "exynos_m1_neon_fp_unary" "exynos_m1_neon_fp_unary") ;; Insns in NCRYPT can feed other such insns quickly. (define_bypass 1 "exynos_m1_crypto_simple, exynos_m1_crypto_poly" "exynos_m1_crypto_simple, exynos_m1_crypto_complex,\ exynos_m1_crypto_poly*") (define_bypass 3 "exynos_m1_crypto_polyl" "exynos_m1_crypto_simple, exynos_m1_crypto_complex,\ exynos_m1_crypto_poly*") (define_bypass 5 "exynos_m1_crypto_complex" "exynos_m1_crypto_simple, exynos_m1_crypto_complex,\ exynos_m1_crypto_poly*") ;; AES{D,E}/AESMC pairs can feed each other instantly. (define_bypass 0 "exynos_m1_crypto_simple" "exynos_m1_crypto_simple" "aarch_crypto_can_dual_issue") ;; Predicted branches take no time, but mispredicted ones take forever anyway. (define_bypass 1 "exynos_m1_*" "exynos_m1_call, exynos_m1_branch")