;; Pipeline descriptions of Andes NDS32 cpu for GNU compiler ;; Copyright (C) 2012-2018 Free Software Foundation, Inc. ;; Contributed by Andes Technology Corporation. ;; ;; 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 N9 2R1W pipeline settings. ;; ------------------------------------------------------------------------
(define_automaton “nds32_n9_2r1w_machine”)
;; ------------------------------------------------------------------------ ;; Pipeline Stages ;; ------------------------------------------------------------------------ ;; IF - Instruction Fetch ;; II - Instruction Issue / Instruction Decode ;; EX - Instruction Execution ;; MM - Memory Execution ;; WB - Instruction Retire / Result Write-Back
(define_cpu_unit “n9_2r1w_ii” “nds32_n9_2r1w_machine”) (define_cpu_unit “n9_2r1w_ex” “nds32_n9_2r1w_machine”) (define_cpu_unit “n9_2r1w_mm” “nds32_n9_2r1w_machine”) (define_cpu_unit “n9_2r1w_wb” “nds32_n9_2r1w_machine”)
(define_insn_reservation “nds_n9_2r1w_unknown” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “unknown”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_misc” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “misc”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_mmu” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “mmu”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_alu” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “alu”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_alu_shift” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “alu_shift”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_pbsad” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “pbsad”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex*3, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_pbsada” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “pbsada”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex*3, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (match_test “nds32::load_single_p (insn)”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (match_test “nds32::store_single_p (insn)”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_1” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “1”)))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_2” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (ior (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “2”)) (match_test “nds32::load_double_p (insn)”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_3” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “3”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_4” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “4”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_5” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “5”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*2, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_6” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “6”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*3, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_7” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “7”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*4, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_8” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “8”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*5, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_load_multiple_12” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “load_multiple”) (eq_attr “combo” “12”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*9, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_1” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “1”)))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_2” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (ior (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “2”)) (match_test “nds32::store_double_p (insn)”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_3” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “3”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_4” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “4”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_5” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “5”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*2, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_6” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “6”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*3, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_7” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “7”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*4, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_8” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “8”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*5, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_store_multiple_12” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “pipeline_model” “n9”) (and (eq_attr “type” “store_multiple”) (eq_attr “combo” “12”)))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm, (n9_2r1w_ii+n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb)*9, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_mul_fast” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W && nds32_mul_config != MUL_TYPE_SLOW”) (and (eq_attr “type” “mul”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_mul_slow” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W && nds32_mul_config == MUL_TYPE_SLOW”) (and (eq_attr “type” “mul”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex*17, n9_2r1w_mm, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_mac_fast” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W && nds32_mul_config != MUL_TYPE_SLOW”) (and (eq_attr “type” “mac”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ii+n9_2r1w_ex, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_mac_slow” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W && nds32_mul_config == MUL_TYPE_SLOW”) (and (eq_attr “type” “mac”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, (n9_2r1w_ii+n9_2r1w_ex)*17, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_ex+n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_div” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “div”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, (n9_2r1w_ii+n9_2r1w_ex)*34, n9_2r1w_ex+n9_2r1w_mm, n9_2r1w_mm+n9_2r1w_wb, n9_2r1w_wb”)
(define_insn_reservation “nds_n9_2r1w_branch” 1 (and (match_test “nds32_register_ports_config == REG_PORT_2R1W”) (and (eq_attr “type” “branch”) (eq_attr “pipeline_model” “n9”))) “n9_2r1w_ii, n9_2r1w_ex, n9_2r1w_mm, n9_2r1w_wb”)
;; ------------------------------------------------------------------------ ;; Comment Notations and Bypass Rules ;; ------------------------------------------------------------------------ ;; Producers (LHS) ;; LD_!bi ;; Load data from the memory (without updating the base register) and ;; produce the loaded data. The result is ready at MM. Because the register ;; port is 2R1W, two micro-operations are required if the base register ;; should be updated. In this case, the base register is updated by the ;; second micro-operation, and the updated result is ready at EX. ;; LMW(N, M) ;; There are N micro-operations within an instruction that loads multiple ;; words. The result produced by the M-th micro-operation is sent to ;; consumers. The result is ready at MM. If the base register should be ;; updated, an extra micro-operation is apppended to the end of the ;; sequence, and the result is ready at EX. ;; MUL, MAC ;; Compute data in the multiply-adder and produce the data. The result ;; is ready at MM. ;; DIV ;; Compute data in the divider and produce the data. The result is ready ;; at MM. ;; ;; Consumers (RHS) ;; ALU, PBSAD, PBSADA_RaRb, MUL, MAC, DIV, MMU ;; Require operands at EX. ;; ALU_SHIFT_Rb ;; An ALU-SHIFT instruction consists of a shift micro-operation followed ;; by an arithmetic micro-operation. The operand Rb is used by the first ;; micro-operation, and there are some latencies if data dependency occurs. ;; MOVD44_E ;; A double-word move instruction needs two micro-operations because the ;; reigster ports is 2R1W. The first micro-operation writes an even number ;; register, and the second micro-operation writes an odd number register. ;; Each input operand is required at EX for each micro-operation. MOVD44_E ;; stands for the first micro-operation. ;; MAC_RaRb, M2R ;; MAC instructions do multiplication at EX and do accumulation at MM, but ;; MAC instructions which operate on general purpose registers always ;; require operands at EX because MM stage cannot be forwarded in 2R1W mode. ;; ADDR_IN ;; If an instruction requires an address as its input operand, the address ;; is required at EX. ;; ST_bi ;; A post-increment store instruction requires its data at EX because MM ;; cannot be forwarded in 2R1W mode. ;; ST_!bi_RI ;; A store instruction with an immediate offset requires its data at EX ;; because MM cannot be forwarded in 2R1W mode. If the offset field is a ;; register (ST_!bi_RR), the instruction will be separated into two micro- ;; operations, and the second one requires the input operand at EX in order ;; to store it to the memory. ;; SMW(N, M) ;; There are N micro-operations within an instruction that stores multiple ;; words. Each M-th micro-operation requires its data at MM. ;; BR ;; If a branch instruction is conditional, its input data is required at EX.
;; LD_!bi, MUL, MAC ;; -> ALU, ALU_SHIFT_Rb, PBSAD, PBSADA_RaRb, MOVD44_E, MUL, MAC_RaRb, M2R, DIV, ADDR_IN_!bi, ADDR_IN_bi_Ra, ST_bi, ST_!bi_RI, BR, MMU (define_bypass 2 “nds_n9_2r1w_load,
nds_n9_2r1w_mul_fast, nds_n9_2r1w_mul_slow,
nds_n9_2r1w_mac_fast, nds_n9_2r1w_mac_slow” “nds_n9_2r1w_alu, nds_n9_2r1w_alu_shift,
nds_n9_2r1w_pbsad, nds_n9_2r1w_pbsada,
nds_n9_2r1w_mul_fast, nds_n9_2r1w_mul_slow,
nds_n9_2r1w_mac_fast, nds_n9_2r1w_mac_slow,
nds_n9_2r1w_branch,
nds_n9_2r1w_div,
nds_n9_2r1w_load,nds_n9_2r1w_store,
nds_n9_2r1w_load_multiple_1,nds_n9_2r1w_load_multiple_2, nds_n9_2r1w_load_multiple_3,
nds_n9_2r1w_load_multiple_4,nds_n9_2r1w_load_multiple_5, nds_n9_2r1w_load_multiple_6,
nds_n9_2r1w_load_multiple_7,nds_n9_2r1w_load_multiple_8, nds_n9_2r1w_load_multiple_12,
nds_n9_2r1w_store_multiple_1,nds_n9_2r1w_store_multiple_2, nds_n9_2r1w_store_multiple_3,
nds_n9_2r1w_store_multiple_4,nds_n9_2r1w_store_multiple_5, nds_n9_2r1w_store_multiple_6,
nds_n9_2r1w_store_multiple_7,nds_n9_2r1w_store_multiple_8, nds_n9_2r1w_store_multiple_12,
nds_n9_2r1w_mmu” “nds32_n9_2r1w_mm_to_ex_p” )
;; LMW(N, N) ;; -> ALU, ALU_SHIFT_Rb, PBSAD, PBSADA_RaRb, MOVD44_E, MUL, MAC_RaRb, M2R, DIV, ADDR_IN_!bi, ADDR_IN_bi_Ra, ST_bi, ST_!bi_RI, BR, MMU (define_bypass 2 “nds_n9_2r1w_load_multiple_1,nds_n9_2r1w_load_multiple_2, nds_n9_2r1w_load_multiple_3,
nds_n9_2r1w_load_multiple_4,nds_n9_2r1w_load_multiple_5, nds_n9_2r1w_load_multiple_6,
nds_n9_2r1w_load_multiple_7,nds_n9_2r1w_load_multiple_8, nds_n9_2r1w_load_multiple_12” “nds_n9_2r1w_alu, nds_n9_2r1w_alu_shift,
nds_n9_2r1w_pbsad, nds_n9_2r1w_pbsada,
nds_n9_2r1w_mul_fast, nds_n9_2r1w_mul_slow,
nds_n9_2r1w_mac_fast, nds_n9_2r1w_mac_slow,
nds_n9_2r1w_branch,
nds_n9_2r1w_div,
nds_n9_2r1w_load,nds_n9_2r1w_store,
nds_n9_2r1w_load_multiple_1,nds_n9_2r1w_load_multiple_2, nds_n9_2r1w_load_multiple_3,
nds_n9_2r1w_load_multiple_4,nds_n9_2r1w_load_multiple_5, nds_n9_2r1w_load_multiple_6,
nds_n9_2r1w_load_multiple_7,nds_n9_2r1w_load_multiple_8, nds_n9_2r1w_load_multiple_12,
nds_n9_2r1w_store_multiple_1,nds_n9_2r1w_store_multiple_2, nds_n9_2r1w_store_multiple_3,
nds_n9_2r1w_store_multiple_4,nds_n9_2r1w_store_multiple_5, nds_n9_2r1w_store_multiple_6,
nds_n9_2r1w_store_multiple_7,nds_n9_2r1w_store_multiple_8, nds_n9_2r1w_store_multiple_12,
nds_n9_2r1w_mmu” “nds32_n9_last_load_to_ex_p” )