/* * This file is part of the MicroPython project, https://micropython.org/ * * The MIT License (MIT) * * Copyright (c) 2024 Alessandro Gatti * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #ifndef MICROPY_INCLUDED_PY_ASMRV32_H #define MICROPY_INCLUDED_PY_ASMRV32_H #include #include "py/asmbase.h" #include "py/emit.h" #include "py/misc.h" #include "py/persistentcode.h" #define ASM_RV32_REG_X0 (0) // Zero #define ASM_RV32_REG_X1 (1) // RA #define ASM_RV32_REG_X2 (2) // SP #define ASM_RV32_REG_X3 (3) // GP #define ASM_RV32_REG_X4 (4) // TP #define ASM_RV32_REG_X5 (5) // T0 #define ASM_RV32_REG_X6 (6) // T1 #define ASM_RV32_REG_X7 (7) // T2 #define ASM_RV32_REG_X8 (8) // S0 #define ASM_RV32_REG_X9 (9) // S1 #define ASM_RV32_REG_X10 (10) // A0 #define ASM_RV32_REG_X11 (11) // A1 #define ASM_RV32_REG_X12 (12) // A2 #define ASM_RV32_REG_X13 (13) // A3 #define ASM_RV32_REG_X14 (14) // A4 #define ASM_RV32_REG_X15 (15) // A5 #define ASM_RV32_REG_X16 (16) // A6 #define ASM_RV32_REG_X17 (17) // A7 #define ASM_RV32_REG_X18 (18) // S2 #define ASM_RV32_REG_X19 (19) // S3 #define ASM_RV32_REG_X20 (20) // S4 #define ASM_RV32_REG_X21 (21) // S5 #define ASM_RV32_REG_X22 (22) // S6 #define ASM_RV32_REG_X23 (23) // S7 #define ASM_RV32_REG_X24 (24) // S8 #define ASM_RV32_REG_X25 (25) // S9 #define ASM_RV32_REG_X26 (26) // S10 #define ASM_RV32_REG_X27 (27) // S11 #define ASM_RV32_REG_X28 (28) // T3 #define ASM_RV32_REG_X29 (29) // T4 #define ASM_RV32_REG_X30 (30) // T5 #define ASM_RV32_REG_X31 (31) // T6 // Alternate register names. #define ASM_RV32_REG_ZERO (ASM_RV32_REG_X0) #define ASM_RV32_REG_RA (ASM_RV32_REG_X1) #define ASM_RV32_REG_SP (ASM_RV32_REG_X2) #define ASM_RV32_REG_GP (ASM_RV32_REG_X3) #define ASM_RV32_REG_TP (ASM_RV32_REG_X4) #define ASM_RV32_REG_T0 (ASM_RV32_REG_X5) #define ASM_RV32_REG_T1 (ASM_RV32_REG_X6) #define ASM_RV32_REG_T2 (ASM_RV32_REG_X7) #define ASM_RV32_REG_A0 (ASM_RV32_REG_X10) #define ASM_RV32_REG_A1 (ASM_RV32_REG_X11) #define ASM_RV32_REG_A2 (ASM_RV32_REG_X12) #define ASM_RV32_REG_A3 (ASM_RV32_REG_X13) #define ASM_RV32_REG_A4 (ASM_RV32_REG_X14) #define ASM_RV32_REG_A5 (ASM_RV32_REG_X15) #define ASM_RV32_REG_A6 (ASM_RV32_REG_X16) #define ASM_RV32_REG_A7 (ASM_RV32_REG_X17) #define ASM_RV32_REG_T3 (ASM_RV32_REG_X28) #define ASM_RV32_REG_T4 (ASM_RV32_REG_X29) #define ASM_RV32_REG_T5 (ASM_RV32_REG_X30) #define ASM_RV32_REG_T6 (ASM_RV32_REG_X31) #define ASM_RV32_REG_FP (ASM_RV32_REG_X8) #define ASM_RV32_REG_S0 (ASM_RV32_REG_X8) #define ASM_RV32_REG_S1 (ASM_RV32_REG_X9) #define ASM_RV32_REG_S2 (ASM_RV32_REG_X18) #define ASM_RV32_REG_S3 (ASM_RV32_REG_X19) #define ASM_RV32_REG_S4 (ASM_RV32_REG_X20) #define ASM_RV32_REG_S5 (ASM_RV32_REG_X21) #define ASM_RV32_REG_S6 (ASM_RV32_REG_X22) #define ASM_RV32_REG_S7 (ASM_RV32_REG_X23) #define ASM_RV32_REG_S8 (ASM_RV32_REG_X24) #define ASM_RV32_REG_S9 (ASM_RV32_REG_X25) #define ASM_RV32_REG_S10 (ASM_RV32_REG_X26) #define ASM_RV32_REG_S11 (ASM_RV32_REG_X27) typedef struct _asm_rv32_t { // Opaque emitter state. mp_asm_base_t base; // Which registers are tainted and need saving/restoring. mp_uint_t saved_registers_mask; // How many locals must be stored on the stack. mp_uint_t locals_count; // The computed function stack size. mp_uint_t stack_size; // The stack offset where stack-based locals start to be stored. mp_uint_t locals_stack_offset; } asm_rv32_t; void asm_rv32_entry(asm_rv32_t *state, mp_uint_t locals); void asm_rv32_exit(asm_rv32_t *state); void asm_rv32_end_pass(asm_rv32_t *state); //////////////////////////////////////////////////////////////////////////////// #define RV32_ENCODE_TYPE_B(op, ft3, rs1, rs2, imm) \ ((op & 0x7F) | ((ft3 & 0x07) << 12) | ((imm & 0x800) >> 4) | \ ((imm & 0x1E) << 7) | ((rs1 & 0x1F) << 15) | ((rs2 & 0x1F) << 20) | \ ((imm & 0x7E0) << 20) | ((imm & 0x1000) << 19)) #define RV32_ENCODE_TYPE_I(op, ft3, rd, rs, imm) \ ((op & 0x7F) | ((rd & 0x1F) << 7) | ((ft3 & 0x07) << 12) | \ ((rs & 0x1F) << 15) | ((imm & 0xFFF) << 20)) #define RV32_ENCODE_TYPE_J(op, rd, imm) \ ((op & 0x7F) | ((rd & 0x1F) << 7) | (imm & 0xFF000) | \ ((imm & 0x800) << 9) | ((imm & 0x7FE) << 20) | ((imm & 0x100000) << 11)) #define RV32_ENCODE_TYPE_R(op, ft3, ft7, rd, rs1, rs2) \ ((op & 0x7F) | ((rd & 0x1F) << 7) | ((ft3 & 0x07) << 12) | \ ((rs1 & 0x1F) << 15) | ((rs2 & 0x1F) << 20) | ((ft7 & 0x7F) << 25)) #define RV32_ENCODE_TYPE_S(op, ft3, rs1, rs2, imm) \ ((op & 0x7F) | ((imm & 0x1F) << 7) | ((ft3 & 0x07) << 12) | \ ((rs1 & 0x1F) << 15) | ((rs2 & 0x1F) << 20) | ((imm & 0xFE0) << 20)) #define RV32_ENCODE_TYPE_U(op, rd, imm) \ ((op & 0x7F) | ((rd & 0x1F) << 7) | (imm & 0xFFFFF000)) #define RV32_ENCODE_TYPE_CB(op, ft3, rs, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((rs & 0x07) << 7) | \ (((imm) & 0x100) << 4) | (((imm) & 0xC0) >> 1) | (((imm) & 0x20) >> 3) | \ (((imm) & 0x18) << 7) | (((imm) & 0x06) << 2)) #define RV32_ENCODE_TYPE_CI(op, ft3, rd, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((rd & 0x1F) << 7) | \ (((imm) & 0x20) << 7) | (((imm) & 0x1F) << 2)) #define RV32_ENCODE_TYPE_CIW(op, ft3, rd, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((rd & 0x07) << 2) | \ ((imm & 0x3C0) << 1) | ((imm & 0x30) << 7) | \ ((imm & 0x08) << 2) | ((imm & 0x04) << 4)) #define RV32_ENCODE_TYPE_CJ(op, ft3, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((imm & 0x0E) << 2) | \ ((imm & 0x300) << 1) | ((imm & 0x800) << 1) | ((imm & 0x400) >> 2) | \ ((imm & 0x80) >> 1) | ((imm & 0x40) << 1) | ((imm & 0x20) >> 3) | \ ((imm & 0x10) << 7)) #define RV32_ENCODE_TYPE_CL(op, ft3, rd, rs, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((rd & 0x07) << 2) | \ ((rs & 0x07) << 7) | ((imm & 0x40) >> 1) | ((imm & 0x38) << 7) | \ ((imm & 0x04) << 4)) #define RV32_ENCODE_TYPE_CR(op, ft4, rs1, rs2) \ ((op & 0x03) | ((rs2 & 0x1F) << 2) | ((rs1 & 0x1F) << 7) | ((ft4 & 0x0F) << 12)) #define RV32_ENCODE_TYPE_CSS(op, ft3, rs, imm) \ ((op & 0x03) | ((ft3 & 0x07) << 13) | ((rs & 0x1F) << 2) | ((imm) & 0x3F) << 7) void asm_rv32_emit_word_opcode(asm_rv32_t *state, mp_uint_t opcode); void asm_rv32_emit_halfword_opcode(asm_rv32_t *state, mp_uint_t opcode); // ADD RD, RS1, RS2 static inline void asm_rv32_opcode_add(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 000 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x00, 0x00, rd, rs1, rs2)); } // ADDI RD, RS, IMMEDIATE static inline void asm_rv32_opcode_addi(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t immediate) { // I: ............ ..... 000 ..... 0010011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x13, 0x00, rd, rs, immediate)); } // AND RD, RS1, RS2 static inline void asm_rv32_opcode_and(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 111 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x07, 0x00, rd, rs1, rs2)); } // AUIPC RD, offset static inline void asm_rv32_opcode_auipc(asm_rv32_t *state, mp_uint_t rd, mp_int_t offset) { // U: .................... ..... 0010111 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_U(0x17, rd, offset)); } // BEQ RS1, RS2, OFFSET static inline void asm_rv32_opcode_beq(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_int_t offset) { // B: . ...... ..... ..... 000 .... . 1100011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_B(0x63, 0x00, rs1, rs2, offset)); } // BNE RS1, RS2, OFFSET static inline void asm_rv32_opcode_bne(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_int_t offset) { // B: . ...... ..... ..... 001 .... . 1100011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_B(0x63, 0x01, rs1, rs2, offset)); } // C.ADD RD, RS static inline void asm_rv32_opcode_cadd(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs) { // CR: 1001 ..... ..... 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CR(0x02, 0x09, rd, rs)); } // C.ADDI RD, IMMEDIATE static inline void asm_rv32_opcode_caddi(asm_rv32_t *state, mp_uint_t rd, mp_int_t immediate) { // CI: 000 . ..... ..... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CI(0x01, 0x00, rd, immediate)); } // C.ADDI4SPN RD', IMMEDIATE static inline void asm_rv32_opcode_caddi4spn(asm_rv32_t *state, mp_uint_t rd, mp_uint_t immediate) { // CIW: 000 ........ ... 00 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CIW(0x00, 0x00, rd, immediate)); } // C.BEQZ RS', IMMEDIATE static inline void asm_rv32_opcode_cbeqz(asm_rv32_t *state, mp_uint_t rs, mp_int_t offset) { // CB: 110 ... ... ..... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CB(0x01, 0x06, rs, offset)); } // C.BNEZ RS', IMMEDIATE static inline void asm_rv32_opcode_cbnez(asm_rv32_t *state, mp_uint_t rs, mp_int_t offset) { // CB: 111 ... ... ..... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CB(0x01, 0x07, rs, offset)); } // C.J OFFSET static inline void asm_rv32_opcode_cj(asm_rv32_t *state, mp_int_t offset) { // CJ: 101 ........... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CJ(0x01, 0x05, offset)); } // C.JALR RS static inline void asm_rv32_opcode_cjalr(asm_rv32_t *state, mp_uint_t rs) { // CR: 1001 ..... 00000 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CR(0x02, 0x09, rs, 0)); } // C.JR RS static inline void asm_rv32_opcode_cjr(asm_rv32_t *state, mp_uint_t rs) { // CR: 1000 ..... 00000 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CR(0x02, 0x08, rs, 0)); } // C.LI RD, IMMEDIATE static inline void asm_rv32_opcode_cli(asm_rv32_t *state, mp_uint_t rd, mp_int_t immediate) { // CI: 010 . ..... ..... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CI(0x01, 0x02, rd, immediate)); } // C.LUI RD, IMMEDIATE static inline void asm_rv32_opcode_clui(asm_rv32_t *state, mp_uint_t rd, mp_int_t immediate) { // CI: 011 . ..... ..... 01 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CI(0x01, 0x03, rd, immediate >> 12)); } // C.LW RD', OFFSET(RS') static inline void asm_rv32_opcode_clw(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset) { // CL: 010 ... ... .. ... 00 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CL(0x00, 0x02, rd, rs, offset)); } // C.LWSP RD, OFFSET static inline void asm_rv32_opcode_clwsp(asm_rv32_t *state, mp_uint_t rd, mp_uint_t offset) { // CI: 010 . ..... ..... 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CI(0x02, 0x02, rd, ((offset & 0xC0) >> 6) | (offset & 0x3C))); } // C.MV RD, RS static inline void asm_rv32_opcode_cmv(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs) { // CR: 1000 ..... ..... 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CR(0x02, 0x08, rd, rs)); } // C.SWSP RS, OFFSET static inline void asm_rv32_opcode_cswsp(asm_rv32_t *state, mp_uint_t rs, mp_uint_t offset) { // CSS: 010 ...... ..... 10 asm_rv32_emit_halfword_opcode(state, RV32_ENCODE_TYPE_CSS(0x02, 0x06, rs, ((offset & 0xC0) >> 6) | (offset & 0x3C))); } // JALR RD, RS, offset static inline void asm_rv32_opcode_jalr(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset) { // I: ............ ..... 000 ..... 1100111 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x67, 0x00, rd, rs, offset)); } // LBU RD, OFFSET(RS) static inline void asm_rv32_opcode_lbu(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset) { // I: ............ ..... 100 ..... 0000011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x03, 0x04, rd, rs, offset)); } // LHU RD, OFFSET(RS) static inline void asm_rv32_opcode_lhu(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset) { // I: ............ ..... 101 ..... 0000011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x03, 0x05, rd, rs, offset)); } // LUI RD, immediate static inline void asm_rv32_opcode_lui(asm_rv32_t *state, mp_uint_t rd, mp_int_t immediate) { // U: .................... ..... 0110111 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_U(0x37, rd, immediate)); } // LW RD, OFFSET(RS) static inline void asm_rv32_opcode_lw(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset) { // I: ............ ..... 010 ..... 0000011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x03, 0x02, rd, rs, offset)); } // MUL RD, RS1, RS2 static inline void asm_rv32_opcode_mul(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000001 ..... ..... 000 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x00, 0x01, rd, rs1, rs2)); } // OR RD, RS1, RS2 static inline void asm_rv32_opcode_or(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 110 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x06, 0x00, rd, rs1, rs2)); } // SLL RD, RS1, RS2 static inline void asm_rv32_opcode_sll(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 001 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x01, 0x00, rd, rs1, rs2)); } // SLLI RD, RS, IMMEDIATE static inline void asm_rv32_opcode_slli(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_uint_t immediate) { // I: 0000000..... ..... 001 ..... 0010011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x13, 0x01, rd, rs, immediate & 0x1F)); } // SRL RD, RS1, RS2 static inline void asm_rv32_opcode_srl(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 101 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x05, 0x00, rd, rs1, rs2)); } // SLT RD, RS1, RS2 static inline void asm_rv32_opcode_slt(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 010 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x02, 0x00, rd, rs1, rs2)); } // SLTU RD, RS1, RS2 static inline void asm_rv32_opcode_sltu(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 011 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x03, 0x00, rd, rs1, rs2)); } // SRA RD, RS1, RS2 static inline void asm_rv32_opcode_sra(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0100000 ..... ..... 101 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x05, 0x20, rd, rs1, rs2)); } // SUB RD, RS1, RS2 static inline void asm_rv32_opcode_sub(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0100000 ..... ..... 000 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x00, 0x20, rd, rs1, rs2)); } // SB RS2, OFFSET(RS1) static inline void asm_rv32_opcode_sb(asm_rv32_t *state, mp_uint_t rs2, mp_uint_t rs1, mp_int_t offset) { // S: ....... ..... ..... 000 ..... 0100011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_S(0x23, 0x00, rs1, rs2, offset)); } // SH RS2, OFFSET(RS1) static inline void asm_rv32_opcode_sh(asm_rv32_t *state, mp_uint_t rs2, mp_uint_t rs1, mp_int_t offset) { // S: ....... ..... ..... 001 ..... 0100011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_S(0x23, 0x01, rs1, rs2, offset)); } // SW RS2, OFFSET(RS1) static inline void asm_rv32_opcode_sw(asm_rv32_t *state, mp_uint_t rs2, mp_uint_t rs1, mp_int_t offset) { // S: ....... ..... ..... 010 ..... 0100011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_S(0x23, 0x02, rs1, rs2, offset)); } // XOR RD, RS1, RS2 static inline void asm_rv32_opcode_xor(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs1, mp_uint_t rs2) { // R: 0000000 ..... ..... 100 ..... 0110011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_R(0x33, 0x04, 0x00, rd, rs1, rs2)); } // XORI RD, RS, IMMEDIATE static inline void asm_rv32_opcode_xori(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t immediate) { // I: ............ ..... 100 ..... 0010011 asm_rv32_emit_word_opcode(state, RV32_ENCODE_TYPE_I(0x13, 0x04, rd, rs, immediate)); } #define ASM_WORD_SIZE (4) #define ASM_HALFWORD_SIZE (2) #define REG_RET ASM_RV32_REG_A0 #define REG_ARG_1 ASM_RV32_REG_A0 #define REG_ARG_2 ASM_RV32_REG_A1 #define REG_ARG_3 ASM_RV32_REG_A2 #define REG_ARG_4 ASM_RV32_REG_A3 #define REG_TEMP0 ASM_RV32_REG_T1 #define REG_TEMP1 ASM_RV32_REG_T2 #define REG_TEMP2 ASM_RV32_REG_T3 #define REG_FUN_TABLE ASM_RV32_REG_S1 #define REG_LOCAL_1 ASM_RV32_REG_S3 #define REG_LOCAL_2 ASM_RV32_REG_S4 #define REG_LOCAL_3 ASM_RV32_REG_S5 void asm_rv32_meta_comparison_eq(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_uint_t rd); void asm_rv32_meta_comparison_ne(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_uint_t rd); void asm_rv32_meta_comparison_lt(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_uint_t rd, bool unsigned_comparison); void asm_rv32_meta_comparison_le(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_uint_t rd, bool unsigned_comparison); #ifdef GENERIC_ASM_API void asm_rv32_emit_call_ind(asm_rv32_t *state, mp_uint_t index); void asm_rv32_emit_jump(asm_rv32_t *state, mp_uint_t label); void asm_rv32_emit_jump_if_reg_eq(asm_rv32_t *state, mp_uint_t rs1, mp_uint_t rs2, mp_uint_t label); void asm_rv32_emit_jump_if_reg_nonzero(asm_rv32_t *state, mp_uint_t rs, mp_uint_t label); void asm_rv32_emit_load16_reg_reg_offset(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset); void asm_rv32_emit_load_reg_reg_offset(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs, mp_int_t offset); void asm_rv32_emit_mov_local_reg(asm_rv32_t *state, mp_uint_t local, mp_uint_t rs); void asm_rv32_emit_mov_reg_local(asm_rv32_t *state, mp_uint_t rd, mp_uint_t local); void asm_rv32_emit_mov_reg_local_addr(asm_rv32_t *state, mp_uint_t rd, mp_uint_t local); void asm_rv32_emit_mov_reg_pcrel(asm_rv32_t *state, mp_uint_t rd, mp_uint_t label); void asm_rv32_emit_optimised_load_immediate(asm_rv32_t *state, mp_uint_t rd, mp_int_t immediate); void asm_rv32_emit_optimised_xor(asm_rv32_t *state, mp_uint_t rd, mp_uint_t rs); void asm_rv32_emit_store_reg_reg_offset(asm_rv32_t *state, mp_uint_t source, mp_uint_t base, mp_int_t offset); #define ASM_T asm_rv32_t #define ASM_ENTRY(state, labels) asm_rv32_entry(state, labels) #define ASM_EXIT(state) asm_rv32_exit(state) #define ASM_END_PASS(state) asm_rv32_end_pass(state) #define ASM_ADD_REG_REG(state, rd, rs) asm_rv32_opcode_cadd(state, rd, rs) #define ASM_AND_REG_REG(state, rd, rs) asm_rv32_opcode_and(state, rd, rs, rd) #define ASM_ASR_REG_REG(state, rd, rs) asm_rv32_opcode_sra(state, rd, rd, rs) #define ASM_CALL_IND(state, index) asm_rv32_emit_call_ind(state, index) #define ASM_JUMP(state, label) asm_rv32_emit_jump(state, label) #define ASM_JUMP_IF_REG_EQ(state, rs1, rs2, label) asm_rv32_emit_jump_if_reg_eq(state, rs1, rs2, label) #define ASM_JUMP_IF_REG_NONZERO(state, rs, label, bool_test) asm_rv32_emit_jump_if_reg_nonzero(state, rs, label) #define ASM_JUMP_IF_REG_ZERO(state, rs, label, bool_test) asm_rv32_emit_jump_if_reg_eq(state, rs, ASM_RV32_REG_ZERO, label) #define ASM_JUMP_REG(state, rs) asm_rv32_opcode_cjr(state, rs) #define ASM_LOAD16_REG_REG_OFFSET(state, rd, rs, offset) asm_rv32_emit_load16_reg_reg_offset(state, rd, rs, offset) #define ASM_LOAD16_REG_REG(state, rd, rs) asm_rv32_opcode_lhu(state, rd, rs, 0) #define ASM_LOAD32_REG_REG(state, rd, rs) ASM_LOAD_REG_REG_OFFSET(state, rd, rs, 0) #define ASM_LOAD8_REG_REG(state, rd, rs) asm_rv32_opcode_lbu(state, rd, rs, 0) #define ASM_LOAD_REG_REG_OFFSET(state, rd, rs, offset) asm_rv32_emit_load_reg_reg_offset(state, rd, rs, offset) #define ASM_LOAD_REG_REG(state, rd, rs) ASM_LOAD32_REG_REG(state, rd, rs) #define ASM_LSL_REG_REG(state, rd, rs) asm_rv32_opcode_sll(state, rd, rd, rs) #define ASM_LSR_REG_REG(state, rd, rs) asm_rv32_opcode_srl(state, rd, rd, rs) #define ASM_MOV_LOCAL_REG(state, local, rs) asm_rv32_emit_mov_local_reg(state, local, rs) #define ASM_MOV_REG_IMM(state, rd, imm) asm_rv32_emit_optimised_load_immediate(state, rd, imm) #define ASM_MOV_REG_LOCAL_ADDR(state, rd, local) asm_rv32_emit_mov_reg_local_addr(state, rd, local) #define ASM_MOV_REG_LOCAL(state, rd, local) asm_rv32_emit_mov_reg_local(state, rd, local) #define ASM_MOV_REG_PCREL(state, rd, label) asm_rv32_emit_mov_reg_pcrel(state, rd, label) #define ASM_MOV_REG_REG(state, rd, rs) asm_rv32_opcode_cmv(state, rd, rs) #define ASM_MUL_REG_REG(state, rd, rs) asm_rv32_opcode_mul(state, rd, rd, rs) #define ASM_NEG_REG(state, rd) asm_rv32_opcode_sub(state, rd, ASM_RV32_REG_ZERO, rd) #define ASM_NOT_REG(state, rd) asm_rv32_opcode_xori(state, rd, rd, -1) #define ASM_OR_REG_REG(state, rd, rs) asm_rv32_opcode_or(state, rd, rd, rs) #define ASM_STORE16_REG_REG(state, rs1, rs2) asm_rv32_opcode_sh(state, rs1, rs2, 0) #define ASM_STORE32_REG_REG(state, rs1, rs2) ASM_STORE_REG_REG_OFFSET(state, rs1, rs2, 0) #define ASM_STORE8_REG_REG(state, rs1, rs2) asm_rv32_opcode_sb(state, rs1, rs2, 0) #define ASM_STORE_REG_REG_OFFSET(state, rd, rs, offset) asm_rv32_emit_store_reg_reg_offset(state, rd, rs, offset) #define ASM_STORE_REG_REG(state, rs1, rs2) ASM_STORE32_REG_REG(state, rs1, rs2) #define ASM_SUB_REG_REG(state, rd, rs) asm_rv32_opcode_sub(state, rd, rd, rs) #define ASM_XOR_REG_REG(state, rd, rs) asm_rv32_emit_optimised_xor(state, rd, rs) #endif #endif // MICROPY_INCLUDED_PY_ASMRV32_H