/* * A64 code generator for TCC * * Copyright (c) 2014-2015 Edmund Grimley Evans * * Copying and distribution of this file, with or without modification, * are permitted in any medium without royalty provided the copyright * notice and this notice are preserved. This file is offered as-is, * without any warranty. */ #ifdef TARGET_DEFS_ONLY // Number of registers available to allocator: #define NB_REGS 28 // x0-x18, x30, v0-v7 #define TREG_R(x) (x) // x = 0..18 #define TREG_R30 19 #define TREG_F(x) (x + 20) // x = 0..7 // Register classes sorted from more general to more precise: #define RC_INT (1 << 0) #define RC_FLOAT (1 << 1) #define RC_R(x) (1 << (2 + (x))) // x = 0..18 #define RC_R30 (1 << 21) #define RC_F(x) (1 << (22 + (x))) // x = 0..7 #define RC_IRET (RC_R(0)) // int return register class #define RC_FRET (RC_F(0)) // float return register class #define REG_IRET (TREG_R(0)) // int return register number #define REG_FRET (TREG_F(0)) // float return register number #define PTR_SIZE 8 #define LDOUBLE_SIZE 16 #define LDOUBLE_ALIGN 16 #define MAX_ALIGN 16 #define CHAR_IS_UNSIGNED /******************************************************/ #else /* ! TARGET_DEFS_ONLY */ /******************************************************/ #define USING_GLOBALS #include "tcc.h" #include ST_DATA const int reg_classes[NB_REGS] = { RC_INT | RC_R(0), RC_INT | RC_R(1), RC_INT | RC_R(2), RC_INT | RC_R(3), RC_INT | RC_R(4), RC_INT | RC_R(5), RC_INT | RC_R(6), RC_INT | RC_R(7), RC_INT | RC_R(8), RC_INT | RC_R(9), RC_INT | RC_R(10), RC_INT | RC_R(11), RC_INT | RC_R(12), RC_INT | RC_R(13), RC_INT | RC_R(14), RC_INT | RC_R(15), RC_INT | RC_R(16), RC_INT | RC_R(17), RC_INT | RC_R(18), RC_R30, // not in RC_INT as we make special use of x30 RC_FLOAT | RC_F(0), RC_FLOAT | RC_F(1), RC_FLOAT | RC_F(2), RC_FLOAT | RC_F(3), RC_FLOAT | RC_F(4), RC_FLOAT | RC_F(5), RC_FLOAT | RC_F(6), RC_FLOAT | RC_F(7) }; #define IS_FREG(x) ((x) >= TREG_F(0)) static uint32_t intr(int r) { assert(TREG_R(0) <= r && r <= TREG_R30); return r < TREG_R30 ? r : 30; } static uint32_t fltr(int r) { assert(TREG_F(0) <= r && r <= TREG_F(7)); return r - TREG_F(0); } // Add an instruction to text section: ST_FUNC void o(unsigned int c) { int ind1 = ind + 4; if (nocode_wanted) return; if (ind1 > cur_text_section->data_allocated) section_realloc(cur_text_section, ind1); write32le(cur_text_section->data + ind, c); ind = ind1; } static int arm64_encode_bimm64(uint64_t x) { int neg = x & 1; int rep, pos, len; if (neg) x = ~x; if (!x) return -1; if (x >> 2 == (x & (((uint64_t)1 << (64 - 2)) - 1))) rep = 2, x &= ((uint64_t)1 << 2) - 1; else if (x >> 4 == (x & (((uint64_t)1 << (64 - 4)) - 1))) rep = 4, x &= ((uint64_t)1 << 4) - 1; else if (x >> 8 == (x & (((uint64_t)1 << (64 - 8)) - 1))) rep = 8, x &= ((uint64_t)1 << 8) - 1; else if (x >> 16 == (x & (((uint64_t)1 << (64 - 16)) - 1))) rep = 16, x &= ((uint64_t)1 << 16) - 1; else if (x >> 32 == (x & (((uint64_t)1 << (64 - 32)) - 1))) rep = 32, x &= ((uint64_t)1 << 32) - 1; else rep = 64; pos = 0; if (!(x & (((uint64_t)1 << 32) - 1))) x >>= 32, pos += 32; if (!(x & (((uint64_t)1 << 16) - 1))) x >>= 16, pos += 16; if (!(x & (((uint64_t)1 << 8) - 1))) x >>= 8, pos += 8; if (!(x & (((uint64_t)1 << 4) - 1))) x >>= 4, pos += 4; if (!(x & (((uint64_t)1 << 2) - 1))) x >>= 2, pos += 2; if (!(x & (((uint64_t)1 << 1) - 1))) x >>= 1, pos += 1; len = 0; if (!(~x & (((uint64_t)1 << 32) - 1))) x >>= 32, len += 32; if (!(~x & (((uint64_t)1 << 16) - 1))) x >>= 16, len += 16; if (!(~x & (((uint64_t)1 << 8) - 1))) x >>= 8, len += 8; if (!(~x & (((uint64_t)1 << 4) - 1))) x >>= 4, len += 4; if (!(~x & (((uint64_t)1 << 2) - 1))) x >>= 2, len += 2; if (!(~x & (((uint64_t)1 << 1) - 1))) x >>= 1, len += 1; if (x) return -1; if (neg) { pos = (pos + len) & (rep - 1); len = rep - len; } return ((0x1000 & rep << 6) | (((rep - 1) ^ 31) << 1 & 63) | ((rep - pos) & (rep - 1)) << 6 | (len - 1)); } static uint32_t arm64_movi(int r, uint64_t x) { uint64_t m = 0xffff; int e; if (!(x & ~m)) return 0x52800000 | r | x << 5; // movz w(r),#(x) if (!(x & ~(m << 16))) return 0x52a00000 | r | x >> 11; // movz w(r),#(x >> 16),lsl #16 if (!(x & ~(m << 32))) return 0xd2c00000 | r | x >> 27; // movz x(r),#(x >> 32),lsl #32 if (!(x & ~(m << 48))) return 0xd2e00000 | r | x >> 43; // movz x(r),#(x >> 48),lsl #48 if ((x & ~m) == m << 16) return (0x12800000 | r | (~x << 5 & 0x1fffe0)); // movn w(r),#(~x) if ((x & ~(m << 16)) == m) return (0x12a00000 | r | (~x >> 11 & 0x1fffe0)); // movn w(r),#(~x >> 16),lsl #16 if (!~(x | m)) return (0x92800000 | r | (~x << 5 & 0x1fffe0)); // movn x(r),#(~x) if (!~(x | m << 16)) return (0x92a00000 | r | (~x >> 11 & 0x1fffe0)); // movn x(r),#(~x >> 16),lsl #16 if (!~(x | m << 32)) return (0x92c00000 | r | (~x >> 27 & 0x1fffe0)); // movn x(r),#(~x >> 32),lsl #32 if (!~(x | m << 48)) return (0x92e00000 | r | (~x >> 43 & 0x1fffe0)); // movn x(r),#(~x >> 32),lsl #32 if (!(x >> 32) && (e = arm64_encode_bimm64(x | x << 32)) >= 0) return 0x320003e0 | r | (uint32_t)e << 10; // movi w(r),#(x) if ((e = arm64_encode_bimm64(x)) >= 0) return 0xb20003e0 | r | (uint32_t)e << 10; // movi x(r),#(x) return 0; } static void arm64_movimm(int r, uint64_t x) { uint32_t i; if ((i = arm64_movi(r, x))) o(i); // a single MOV else { // MOVZ/MOVN and 1-3 MOVKs int z = 0, m = 0; uint32_t mov1 = 0xd2800000; // movz uint64_t x1 = x; for (i = 0; i < 64; i += 16) { z += !(x >> i & 0xffff); m += !(~x >> i & 0xffff); } if (m > z) { x1 = ~x; mov1 = 0x92800000; // movn } for (i = 0; i < 64; i += 16) if (x1 >> i & 0xffff) { o(mov1 | r | (x1 >> i & 0xffff) << 5 | i << 17); // movz/movn x(r),#(*),lsl #(i) break; } for (i += 16; i < 64; i += 16) if (x1 >> i & 0xffff) o(0xf2800000 | r | (x >> i & 0xffff) << 5 | i << 17); // movk x(r),#(*),lsl #(i) } } // Patch all branches in list pointed to by t to branch to a: ST_FUNC void gsym_addr(int t_, int a_) { uint32_t t = t_; uint32_t a = a_; while (t) { unsigned char *ptr = cur_text_section->data + t; uint32_t next = read32le(ptr); if (a - t + 0x8000000 >= 0x10000000) tcc_error("branch out of range"); write32le(ptr, (a - t == 4 ? 0xd503201f : // nop 0x14000000 | ((a - t) >> 2 & 0x3ffffff))); // b t = next; } } static int arm64_type_size(int t) { switch (t & VT_BTYPE) { case VT_INT: return 2; case VT_BYTE: return 0; case VT_SHORT: return 1; case VT_PTR: return 3; case VT_FUNC: return 3; case VT_FLOAT: return 2; case VT_DOUBLE: return 3; case VT_LDOUBLE: return 4; case VT_BOOL: return 0; case VT_LLONG: return 3; } assert(0); return 0; } static void arm64_spoff(int reg, uint64_t off) { uint32_t sub = off >> 63; if (sub) off = -off; if (off < 4096) o(0x910003e0 | sub << 30 | reg | off << 10); // (add|sub) x(reg),sp,#(off) else { arm64_movimm(30, off); // use x30 for offset o(0x8b3e63e0 | sub << 30 | reg); // (add|sub) x(reg),sp,x30 } } static void arm64_ldrx(int sg, int sz_, int dst, int bas, uint64_t off) { uint32_t sz = sz_; if (sz >= 2) sg = 0; if (!(off & ~((uint32_t)0xfff << sz))) o(0x39400000 | dst | bas << 5 | off << (10 - sz) | (uint32_t)!!sg << 23 | sz << 30); // ldr(*) x(dst),[x(bas),#(off)] else if (off < 256 || -off <= 256) o(0x38400000 | dst | bas << 5 | (off & 511) << 12 | (uint32_t)!!sg << 23 | sz << 30); // ldur(*) x(dst),[x(bas),#(off)] else { arm64_movimm(30, off); // use x30 for offset o(0x38206800 | dst | bas << 5 | (uint32_t)30 << 16 | (uint32_t)(!!sg + 1) << 22 | sz << 30); // ldr(*) x(dst),[x(bas),x30] } } static void arm64_ldrv(int sz_, int dst, int bas, uint64_t off) { uint32_t sz = sz_; if (!(off & ~((uint32_t)0xfff << sz))) o(0x3d400000 | dst | bas << 5 | off << (10 - sz) | (sz & 4) << 21 | (sz & 3) << 30); // ldr (s|d|q)(dst),[x(bas),#(off)] else if (off < 256 || -off <= 256) o(0x3c400000 | dst | bas << 5 | (off & 511) << 12 | (sz & 4) << 21 | (sz & 3) << 30); // ldur (s|d|q)(dst),[x(bas),#(off)] else { arm64_movimm(30, off); // use x30 for offset o(0x3c606800 | dst | bas << 5 | (uint32_t)30 << 16 | sz << 30 | (sz & 4) << 21); // ldr (s|d|q)(dst),[x(bas),x30] } } static void arm64_ldrs(int reg_, int size) { uint32_t reg = reg_; // Use x30 for intermediate value in some cases. switch (size) { default: assert(0); break; case 1: arm64_ldrx(0, 0, reg, reg, 0); break; case 2: arm64_ldrx(0, 1, reg, reg, 0); break; case 3: arm64_ldrx(0, 1, 30, reg, 0); arm64_ldrx(0, 0, reg, reg, 2); o(0x2a0043c0 | reg | reg << 16); // orr x(reg),x30,x(reg),lsl #16 break; case 4: arm64_ldrx(0, 2, reg, reg, 0); break; case 5: arm64_ldrx(0, 2, 30, reg, 0); arm64_ldrx(0, 0, reg, reg, 4); o(0xaa0083c0 | reg | reg << 16); // orr x(reg),x30,x(reg),lsl #32 break; case 6: arm64_ldrx(0, 2, 30, reg, 0); arm64_ldrx(0, 1, reg, reg, 4); o(0xaa0083c0 | reg | reg << 16); // orr x(reg),x30,x(reg),lsl #32 break; case 7: arm64_ldrx(0, 2, 30, reg, 0); arm64_ldrx(0, 2, reg, reg, 3); o(0x53087c00 | reg | reg << 5); // lsr w(reg), w(reg), #8 o(0xaa0083c0 | reg | reg << 16); // orr x(reg),x30,x(reg),lsl #32 break; case 8: arm64_ldrx(0, 3, reg, reg, 0); break; case 9: arm64_ldrx(0, 0, reg + 1, reg, 8); arm64_ldrx(0, 3, reg, reg, 0); break; case 10: arm64_ldrx(0, 1, reg + 1, reg, 8); arm64_ldrx(0, 3, reg, reg, 0); break; case 11: arm64_ldrx(0, 2, reg + 1, reg, 7); o(0x53087c00 | (reg+1) | (reg+1) << 5); // lsr w(reg+1), w(reg+1), #8 arm64_ldrx(0, 3, reg, reg, 0); break; case 12: arm64_ldrx(0, 2, reg + 1, reg, 8); arm64_ldrx(0, 3, reg, reg, 0); break; case 13: arm64_ldrx(0, 3, reg + 1, reg, 5); o(0xd358fc00 | (reg+1) | (reg+1) << 5); // lsr x(reg+1), x(reg+1), #24 arm64_ldrx(0, 3, reg, reg, 0); break; case 14: arm64_ldrx(0, 3, reg + 1, reg, 6); o(0xd350fc00 | (reg+1) | (reg+1) << 5); // lsr x(reg+1), x(reg+1), #16 arm64_ldrx(0, 3, reg, reg, 0); break; case 15: arm64_ldrx(0, 3, reg + 1, reg, 7); o(0xd348fc00 | (reg+1) | (reg+1) << 5); // lsr x(reg+1), x(reg+1), #8 arm64_ldrx(0, 3, reg, reg, 0); break; case 16: o(0xa9400000 | reg | (reg+1) << 10 | reg << 5); // ldp x(reg),x(reg+1),[x(reg)] break; } } static void arm64_strx(int sz_, int dst, int bas, uint64_t off) { uint32_t sz = sz_; if (!(off & ~((uint32_t)0xfff << sz))) o(0x39000000 | dst | bas << 5 | off << (10 - sz) | sz << 30); // str(*) x(dst),[x(bas],#(off)] else if (off < 256 || -off <= 256) o(0x38000000 | dst | bas << 5 | (off & 511) << 12 | sz << 30); // stur(*) x(dst),[x(bas],#(off)] else { arm64_movimm(30, off); // use x30 for offset o(0x38206800 | dst | bas << 5 | (uint32_t)30 << 16 | sz << 30); // str(*) x(dst),[x(bas),x30] } } static void arm64_strv(int sz_, int dst, int bas, uint64_t off) { uint32_t sz = sz_; if (!(off & ~((uint32_t)0xfff << sz))) o(0x3d000000 | dst | bas << 5 | off << (10 - sz) | (sz & 4) << 21 | (sz & 3) << 30); // str (s|d|q)(dst),[x(bas),#(off)] else if (off < 256 || -off <= 256) o(0x3c000000 | dst | bas << 5 | (off & 511) << 12 | (sz & 4) << 21 | (sz & 3) << 30); // stur (s|d|q)(dst),[x(bas),#(off)] else { arm64_movimm(30, off); // use x30 for offset o(0x3c206800 | dst | bas << 5 | (uint32_t)30 << 16 | sz << 30 | (sz & 4) << 21); // str (s|d|q)(dst),[x(bas),x30] } } static void arm64_sym(int r, Sym *sym, unsigned long addend) { // Currently TCC's linker does not generate COPY relocations for // STT_OBJECTs when tcc is invoked with "-run". This typically // results in "R_AARCH64_ADR_PREL_PG_HI21 relocation failed" when // a program refers to stdin. A workaround is to avoid that // relocation and use only relocations with unlimited range. int avoid_adrp = 1; if (avoid_adrp || sym->a.weak) { // (GCC uses a R_AARCH64_ABS64 in this case.) greloca(cur_text_section, sym, ind, R_AARCH64_MOVW_UABS_G0_NC, addend); o(0xd2800000 | r); // mov x(rt),#0,lsl #0 greloca(cur_text_section, sym, ind, R_AARCH64_MOVW_UABS_G1_NC, addend); o(0xf2a00000 | r); // movk x(rt),#0,lsl #16 greloca(cur_text_section, sym, ind, R_AARCH64_MOVW_UABS_G2_NC, addend); o(0xf2c00000 | r); // movk x(rt),#0,lsl #32 greloca(cur_text_section, sym, ind, R_AARCH64_MOVW_UABS_G3, addend); o(0xf2e00000 | r); // movk x(rt),#0,lsl #48 } else { greloca(cur_text_section, sym, ind, R_AARCH64_ADR_PREL_PG_HI21, addend); o(0x90000000 | r); greloca(cur_text_section, sym, ind, R_AARCH64_ADD_ABS_LO12_NC, addend); o(0x91000000 | r | r << 5); } } static void arm64_load_cmp(int r, SValue *sv); ST_FUNC void load(int r, SValue *sv) { int svtt = sv->type.t; int svr = sv->r; int svrv = svr & VT_VALMASK; uint64_t svcul = (uint32_t)sv->c.i; svcul = svcul >> 31 & 1 ? svcul - ((uint64_t)1 << 32) : svcul; if (svr == (VT_LOCAL | VT_LVAL)) { if (IS_FREG(r)) arm64_ldrv(arm64_type_size(svtt), fltr(r), 29, svcul); else arm64_ldrx(!(svtt & VT_UNSIGNED), arm64_type_size(svtt), intr(r), 29, svcul); return; } if ((svr & ~VT_VALMASK) == VT_LVAL && svrv < VT_CONST) { if (IS_FREG(r)) arm64_ldrv(arm64_type_size(svtt), fltr(r), intr(svrv), 0); else arm64_ldrx(!(svtt & VT_UNSIGNED), arm64_type_size(svtt), intr(r), intr(svrv), 0); return; } if (svr == (VT_CONST | VT_LVAL | VT_SYM)) { arm64_sym(30, sv->sym, svcul); // use x30 for address if (IS_FREG(r)) arm64_ldrv(arm64_type_size(svtt), fltr(r), 30, 0); else arm64_ldrx(!(svtt & VT_UNSIGNED), arm64_type_size(svtt), intr(r), 30, 0); return; } if (svr == (VT_CONST | VT_SYM)) { arm64_sym(intr(r), sv->sym, svcul); return; } if (svr == VT_CONST) { if ((svtt & VT_BTYPE) != VT_VOID) arm64_movimm(intr(r), arm64_type_size(svtt) == 3 ? sv->c.i : (uint32_t)svcul); return; } if (svr < VT_CONST) { if (IS_FREG(r) && IS_FREG(svr)) if (svtt == VT_LDOUBLE) o(0x4ea01c00 | fltr(r) | fltr(svr) << 5); // mov v(r).16b,v(svr).16b else o(0x1e604000 | fltr(r) | fltr(svr) << 5); // fmov d(r),d(svr) else if (!IS_FREG(r) && !IS_FREG(svr)) o(0xaa0003e0 | intr(r) | intr(svr) << 16); // mov x(r),x(svr) else assert(0); return; } if (svr == VT_LOCAL) { if (-svcul < 0x1000) o(0xd10003a0 | intr(r) | -svcul << 10); // sub x(r),x29,#... else { arm64_movimm(30, -svcul); // use x30 for offset o(0xcb0003a0 | intr(r) | (uint32_t)30 << 16); // sub x(r),x29,x30 } return; } if (svr == VT_JMP || svr == VT_JMPI) { int t = (svr == VT_JMPI); arm64_movimm(intr(r), t); o(0x14000002); // b .+8 gsym(svcul); arm64_movimm(intr(r), t ^ 1); return; } if (svr == (VT_LLOCAL | VT_LVAL)) { arm64_ldrx(0, 3, 30, 29, svcul); // use x30 for offset if (IS_FREG(r)) arm64_ldrv(arm64_type_size(svtt), fltr(r), 30, 0); else arm64_ldrx(!(svtt & VT_UNSIGNED), arm64_type_size(svtt), intr(r), 30, 0); return; } if (svr == VT_CMP) { arm64_load_cmp(r, sv); return; } printf("load(%x, (%x, %x, %llx))\n", r, svtt, sv->r, (long long)svcul); assert(0); } ST_FUNC void store(int r, SValue *sv) { int svtt = sv->type.t; int svr = sv->r; int svrv = svr & VT_VALMASK; uint64_t svcul = (uint32_t)sv->c.i; svcul = svcul >> 31 & 1 ? svcul - ((uint64_t)1 << 32) : svcul; if (svr == (VT_LOCAL | VT_LVAL)) { if (IS_FREG(r)) arm64_strv(arm64_type_size(svtt), fltr(r), 29, svcul); else arm64_strx(arm64_type_size(svtt), intr(r), 29, svcul); return; } if ((svr & ~VT_VALMASK) == VT_LVAL && svrv < VT_CONST) { if (IS_FREG(r)) arm64_strv(arm64_type_size(svtt), fltr(r), intr(svrv), 0); else arm64_strx(arm64_type_size(svtt), intr(r), intr(svrv), 0); return; } if (svr == (VT_CONST | VT_LVAL | VT_SYM)) { arm64_sym(30, sv->sym, svcul); // use x30 for address if (IS_FREG(r)) arm64_strv(arm64_type_size(svtt), fltr(r), 30, 0); else arm64_strx(arm64_type_size(svtt), intr(r), 30, 0); return; } printf("store(%x, (%x, %x, %llx))\n", r, svtt, sv->r, (long long)svcul); assert(0); } static void arm64_gen_bl_or_b(int b) { if ((vtop->r & (VT_VALMASK | VT_LVAL)) == VT_CONST && (vtop->r & VT_SYM)) { assert(!b); greloca(cur_text_section, vtop->sym, ind, R_AARCH64_CALL26, 0); o(0x94000000); // bl . } else o(0xd61f0000 | (uint32_t)!b << 21 | intr(gv(RC_R30)) << 5); // br/blr } static int arm64_hfa_aux(CType *type, int *fsize, int num) { if (is_float(type->t)) { int a, n = type_size(type, &a); if (num >= 4 || (*fsize && *fsize != n)) return -1; *fsize = n; return num + 1; } else if ((type->t & VT_BTYPE) == VT_STRUCT) { int is_struct = 0; // rather than union Sym *field; for (field = type->ref->next; field; field = field->next) if (field->c) { is_struct = 1; break; } if (is_struct) { int num0 = num; for (field = type->ref->next; field; field = field->next) { if (field->c != (num - num0) * *fsize) return -1; num = arm64_hfa_aux(&field->type, fsize, num); if (num == -1) return -1; } if (type->ref->c != (num - num0) * *fsize) return -1; return num; } else { // union int num0 = num; for (field = type->ref->next; field; field = field->next) { int num1 = arm64_hfa_aux(&field->type, fsize, num0); if (num1 == -1) return -1; num = num1 < num ? num : num1; } if (type->ref->c != (num - num0) * *fsize) return -1; return num; } } else if (type->t & VT_ARRAY) { int num1; if (!type->ref->c) return num; num1 = arm64_hfa_aux(&type->ref->type, fsize, num); if (num1 == -1 || (num1 != num && type->ref->c > 4)) return -1; num1 = num + type->ref->c * (num1 - num); if (num1 > 4) return -1; return num1; } return -1; } static int arm64_hfa(CType *type, int *fsize) { if ((type->t & VT_BTYPE) == VT_STRUCT || (type->t & VT_ARRAY)) { int sz = 0; int n = arm64_hfa_aux(type, &sz, 0); if (0 < n && n <= 4) { if (fsize) *fsize = sz; return n; } } return 0; } static unsigned long arm64_pcs_aux(int n, CType **type, unsigned long *a) { int nx = 0; // next integer register int nv = 0; // next vector register unsigned long ns = 32; // next stack offset int i; for (i = 0; i < n; i++) { int hfa = arm64_hfa(type[i], 0); int size, align; if ((type[i]->t & VT_ARRAY) || (type[i]->t & VT_BTYPE) == VT_FUNC) size = align = 8; else size = type_size(type[i], &align); if (hfa) // B.2 ; else if (size > 16) { // B.3: replace with pointer if (nx < 8) a[i] = nx++ << 1 | 1; else { ns = (ns + 7) & ~7; a[i] = ns | 1; ns += 8; } continue; } else if ((type[i]->t & VT_BTYPE) == VT_STRUCT) // B.4 size = (size + 7) & ~7; // C.1 if (is_float(type[i]->t) && nv < 8) { a[i] = 16 + (nv++ << 1); continue; } // C.2 if (hfa && nv + hfa <= 8) { a[i] = 16 + (nv << 1); nv += hfa; continue; } // C.3 if (hfa) { nv = 8; size = (size + 7) & ~7; } // C.4 if (hfa || (type[i]->t & VT_BTYPE) == VT_LDOUBLE) { ns = (ns + 7) & ~7; ns = (ns + align - 1) & -align; } // C.5 if ((type[i]->t & VT_BTYPE) == VT_FLOAT) size = 8; // C.6 if (hfa || is_float(type[i]->t)) { a[i] = ns; ns += size; continue; } // C.7 if ((type[i]->t & VT_BTYPE) != VT_STRUCT && size <= 8 && nx < 8) { a[i] = nx++ << 1; continue; } // C.8 if (align == 16) nx = (nx + 1) & ~1; // C.9 if ((type[i]->t & VT_BTYPE) != VT_STRUCT && size == 16 && nx < 7) { a[i] = nx << 1; nx += 2; continue; } // C.10 if ((type[i]->t & VT_BTYPE) == VT_STRUCT && size <= (8 - nx) * 8) { a[i] = nx << 1; nx += (size + 7) >> 3; continue; } // C.11 nx = 8; // C.12 ns = (ns + 7) & ~7; ns = (ns + align - 1) & -align; // C.13 if ((type[i]->t & VT_BTYPE) == VT_STRUCT) { a[i] = ns; ns += size; continue; } // C.14 if (size < 8) size = 8; // C.15 a[i] = ns; ns += size; } return ns - 32; } static unsigned long arm64_pcs(int n, CType **type, unsigned long *a) { unsigned long stack; // Return type: if ((type[0]->t & VT_BTYPE) == VT_VOID) a[0] = -1; else { arm64_pcs_aux(1, type, a); assert(a[0] == 0 || a[0] == 1 || a[0] == 16); } // Argument types: stack = arm64_pcs_aux(n, type + 1, a + 1); if (0) { int i; for (i = 0; i <= n; i++) { if (!i) printf("arm64_pcs return: "); else printf("arm64_pcs arg %d: ", i); if (a[i] == (unsigned long)-1) printf("void\n"); else if (a[i] == 1 && !i) printf("X8 pointer\n"); else if (a[i] < 16) printf("X%lu%s\n", a[i] / 2, a[i] & 1 ? " pointer" : ""); else if (a[i] < 32) printf("V%lu\n", a[i] / 2 - 8); else printf("stack %lu%s\n", (a[i] - 32) & ~1, a[i] & 1 ? " pointer" : ""); } } return stack; } ST_FUNC void gfunc_call(int nb_args) { CType *return_type; CType **t; unsigned long *a, *a1; unsigned long stack; int i; return_type = &vtop[-nb_args].type.ref->type; if ((return_type->t & VT_BTYPE) == VT_STRUCT) --nb_args; t = tcc_malloc((nb_args + 1) * sizeof(*t)); a = tcc_malloc((nb_args + 1) * sizeof(*a)); a1 = tcc_malloc((nb_args + 1) * sizeof(*a1)); t[0] = return_type; for (i = 0; i < nb_args; i++) t[nb_args - i] = &vtop[-i].type; stack = arm64_pcs(nb_args, t, a); // Allocate space for structs replaced by pointer: for (i = nb_args; i; i--) if (a[i] & 1) { SValue *arg = &vtop[i - nb_args]; int align, size = type_size(&arg->type, &align); assert((arg->type.t & VT_BTYPE) == VT_STRUCT); stack = (stack + align - 1) & -align; a1[i] = stack; stack += size; } stack = (stack + 15) >> 4 << 4; assert(stack < 0x1000); if (stack) o(0xd10003ff | stack << 10); // sub sp,sp,#(n) // First pass: set all values on stack for (i = nb_args; i; i--) { vpushv(vtop - nb_args + i); if (a[i] & 1) { // struct replaced by pointer int r = get_reg(RC_INT); arm64_spoff(intr(r), a1[i]); vset(&vtop->type, r | VT_LVAL, 0); vswap(); vstore(); if (a[i] >= 32) { // pointer on stack r = get_reg(RC_INT); arm64_spoff(intr(r), a1[i]); arm64_strx(3, intr(r), 31, (a[i] - 32) >> 1 << 1); } } else if (a[i] >= 32) { // value on stack if ((vtop->type.t & VT_BTYPE) == VT_STRUCT) { int r = get_reg(RC_INT); arm64_spoff(intr(r), a[i] - 32); vset(&vtop->type, r | VT_LVAL, 0); vswap(); vstore(); } else if (is_float(vtop->type.t)) { gv(RC_FLOAT); arm64_strv(arm64_type_size(vtop[0].type.t), fltr(vtop[0].r), 31, a[i] - 32); } else { gv(RC_INT); arm64_strx(arm64_type_size(vtop[0].type.t), intr(vtop[0].r), 31, a[i] - 32); } } --vtop; } // Second pass: assign values to registers for (i = nb_args; i; i--, vtop--) { if (a[i] < 16 && !(a[i] & 1)) { // value in general-purpose registers if ((vtop->type.t & VT_BTYPE) == VT_STRUCT) { int align, size = type_size(&vtop->type, &align); vtop->type.t = VT_PTR; gaddrof(); gv(RC_R(a[i] / 2)); arm64_ldrs(a[i] / 2, size); } else gv(RC_R(a[i] / 2)); } else if (a[i] < 16) // struct replaced by pointer in register arm64_spoff(a[i] / 2, a1[i]); else if (a[i] < 32) { // value in floating-point registers if ((vtop->type.t & VT_BTYPE) == VT_STRUCT) { uint32_t j, sz, n = arm64_hfa(&vtop->type, &sz); vtop->type.t = VT_PTR; gaddrof(); gv(RC_R30); for (j = 0; j < n; j++) o(0x3d4003c0 | (sz & 16) << 19 | -(sz & 8) << 27 | (sz & 4) << 29 | (a[i] / 2 - 8 + j) | j << 10); // ldr ([sdq])(*),[x30,#(j * sz)] } else gv(RC_F(a[i] / 2 - 8)); } } if ((return_type->t & VT_BTYPE) == VT_STRUCT) { if (a[0] == 1) { // indirect return: set x8 and discard the stack value gv(RC_R(8)); --vtop; } else // return in registers: keep the address for after the call vswap(); } save_regs(0); arm64_gen_bl_or_b(0); --vtop; if (stack) o(0x910003ff | stack << 10); // add sp,sp,#(n) { int rt = return_type->t; int bt = rt & VT_BTYPE; if (bt == VT_BYTE || bt == VT_SHORT) // Promote small integers: o(0x13001c00 | (bt == VT_SHORT) << 13 | (uint32_t)!!(rt & VT_UNSIGNED) << 30); // [su]xt[bh] w0,w0 else if (bt == VT_STRUCT && !(a[0] & 1)) { // A struct was returned in registers, so write it out: gv(RC_R(8)); --vtop; if (a[0] == 0) { int align, size = type_size(return_type, &align); assert(size <= 16); if (size > 8) o(0xa9000500); // stp x0,x1,[x8] else if (size) arm64_strx(size > 4 ? 3 : size > 2 ? 2 : size > 1, 0, 8, 0); } else if (a[0] == 16) { uint32_t j, sz, n = arm64_hfa(return_type, &sz); for (j = 0; j < n; j++) o(0x3d000100 | (sz & 16) << 19 | -(sz & 8) << 27 | (sz & 4) << 29 | (a[i] / 2 - 8 + j) | j << 10); // str ([sdq])(*),[x8,#(j * sz)] } } } tcc_free(a1); tcc_free(a); tcc_free(t); } static unsigned long arm64_func_va_list_stack; static int arm64_func_va_list_gr_offs; static int arm64_func_va_list_vr_offs; static int arm64_func_sub_sp_offset; ST_FUNC void gfunc_prolog(Sym *func_sym) { CType *func_type = &func_sym->type; int n = 0; int i = 0; Sym *sym; CType **t; unsigned long *a; // Why doesn't the caller (gen_function) set func_vt? func_vt = func_type->ref->type; func_vc = 144; // offset of where x8 is stored for (sym = func_type->ref; sym; sym = sym->next) ++n; t = tcc_malloc(n * sizeof(*t)); a = tcc_malloc(n * sizeof(*a)); for (sym = func_type->ref; sym; sym = sym->next) t[i++] = &sym->type; arm64_func_va_list_stack = arm64_pcs(n - 1, t, a); o(0xa9b27bfd); // stp x29,x30,[sp,#-224]! o(0xad0087e0); // stp q0,q1,[sp,#16] o(0xad018fe2); // stp q2,q3,[sp,#48] o(0xad0297e4); // stp q4,q5,[sp,#80] o(0xad039fe6); // stp q6,q7,[sp,#112] o(0xa90923e8); // stp x8,x8,[sp,#144] o(0xa90a07e0); // stp x0,x1,[sp,#160] o(0xa90b0fe2); // stp x2,x3,[sp,#176] o(0xa90c17e4); // stp x4,x5,[sp,#192] o(0xa90d1fe6); // stp x6,x7,[sp,#208] arm64_func_va_list_gr_offs = -64; arm64_func_va_list_vr_offs = -128; for (i = 1, sym = func_type->ref->next; sym; i++, sym = sym->next) { int off = (a[i] < 16 ? 160 + a[i] / 2 * 8 : a[i] < 32 ? 16 + (a[i] - 16) / 2 * 16 : 224 + ((a[i] - 32) >> 1 << 1)); sym_push(sym->v & ~SYM_FIELD, &sym->type, (a[i] & 1 ? VT_LLOCAL : VT_LOCAL) | VT_LVAL, off); if (a[i] < 16) { int align, size = type_size(&sym->type, &align); arm64_func_va_list_gr_offs = (a[i] / 2 - 7 + (!(a[i] & 1) && size > 8)) * 8; } else if (a[i] < 32) { uint32_t hfa = arm64_hfa(&sym->type, 0); arm64_func_va_list_vr_offs = (a[i] / 2 - 16 + (hfa ? hfa : 1)) * 16; } // HFAs of float and double need to be written differently: if (16 <= a[i] && a[i] < 32 && (sym->type.t & VT_BTYPE) == VT_STRUCT) { uint32_t j, sz, k = arm64_hfa(&sym->type, &sz); if (sz < 16) for (j = 0; j < k; j++) { o(0x3d0003e0 | -(sz & 8) << 27 | (sz & 4) << 29 | ((a[i] - 16) / 2 + j) | (off / sz + j) << 10); // str ([sdq])(*),[sp,#(j * sz)] } } } tcc_free(a); tcc_free(t); o(0x910003fd); // mov x29,sp arm64_func_sub_sp_offset = ind; // In gfunc_epilog these will be replaced with code to decrement SP: o(0xd503201f); // nop o(0xd503201f); // nop loc = 0; } ST_FUNC void gen_va_start(void) { int r; --vtop; // we don't need the "arg" gaddrof(); r = intr(gv(RC_INT)); if (arm64_func_va_list_stack) { //xx could use add (immediate) here arm64_movimm(30, arm64_func_va_list_stack + 224); o(0x8b1e03be); // add x30,x29,x30 } else o(0x910383be); // add x30,x29,#224 o(0xf900001e | r << 5); // str x30,[x(r)] if (arm64_func_va_list_gr_offs) { if (arm64_func_va_list_stack) o(0x910383be); // add x30,x29,#224 o(0xf900041e | r << 5); // str x30,[x(r),#8] } if (arm64_func_va_list_vr_offs) { o(0x910243be); // add x30,x29,#144 o(0xf900081e | r << 5); // str x30,[x(r),#16] } arm64_movimm(30, arm64_func_va_list_gr_offs); o(0xb900181e | r << 5); // str w30,[x(r),#24] arm64_movimm(30, arm64_func_va_list_vr_offs); o(0xb9001c1e | r << 5); // str w30,[x(r),#28] --vtop; } ST_FUNC void gen_va_arg(CType *t) { int align, size = type_size(t, &align); int fsize, hfa = arm64_hfa(t, &fsize); uint32_t r0, r1; if (is_float(t->t)) { hfa = 1; fsize = size; } gaddrof(); r0 = intr(gv(RC_INT)); r1 = get_reg(RC_INT); vtop[0].r = r1 | VT_LVAL; r1 = intr(r1); if (!hfa) { uint32_t n = size > 16 ? 8 : (size + 7) & -8; o(0xb940181e | r0 << 5); // ldr w30,[x(r0),#24] // __gr_offs if (align == 16) { assert(0); // this path untested but needed for __uint128_t o(0x11003fde); // add w30,w30,#15 o(0x121c6fde); // and w30,w30,#-16 } o(0x310003c0 | r1 | n << 10); // adds w(r1),w30,#(n) o(0x540000ad); // b.le .+20 o(0xf9400000 | r1 | r0 << 5); // ldr x(r1),[x(r0)] // __stack o(0x9100001e | r1 << 5 | n << 10); // add x30,x(r1),#(n) o(0xf900001e | r0 << 5); // str x30,[x(r0)] // __stack o(0x14000004); // b .+16 o(0xb9001800 | r1 | r0 << 5); // str w(r1),[x(r0),#24] // __gr_offs o(0xf9400400 | r1 | r0 << 5); // ldr x(r1),[x(r0),#8] // __gr_top o(0x8b3ec000 | r1 | r1 << 5); // add x(r1),x(r1),w30,sxtw if (size > 16) o(0xf9400000 | r1 | r1 << 5); // ldr x(r1),[x(r1)] } else { uint32_t rsz = hfa << 4; uint32_t ssz = (size + 7) & -(uint32_t)8; uint32_t b1, b2; o(0xb9401c1e | r0 << 5); // ldr w30,[x(r0),#28] // __vr_offs o(0x310003c0 | r1 | rsz << 10); // adds w(r1),w30,#(rsz) b1 = ind; o(0x5400000d); // b.le lab1 o(0xf9400000 | r1 | r0 << 5); // ldr x(r1),[x(r0)] // __stack if (fsize == 16) { o(0x91003c00 | r1 | r1 << 5); // add x(r1),x(r1),#15 o(0x927cec00 | r1 | r1 << 5); // and x(r1),x(r1),#-16 } o(0x9100001e | r1 << 5 | ssz << 10); // add x30,x(r1),#(ssz) o(0xf900001e | r0 << 5); // str x30,[x(r0)] // __stack b2 = ind; o(0x14000000); // b lab2 // lab1: write32le(cur_text_section->data + b1, 0x5400000d | (ind - b1) << 3); o(0xb9001c00 | r1 | r0 << 5); // str w(r1),[x(r0),#28] // __vr_offs o(0xf9400800 | r1 | r0 << 5); // ldr x(r1),[x(r0),#16] // __vr_top if (hfa == 1 || fsize == 16) o(0x8b3ec000 | r1 | r1 << 5); // add x(r1),x(r1),w30,sxtw else { // We need to change the layout of this HFA. // Get some space on the stack using global variable "loc": loc = (loc - size) & -(uint32_t)align; o(0x8b3ec000 | 30 | r1 << 5); // add x30,x(r1),w30,sxtw arm64_movimm(r1, loc); o(0x8b0003a0 | r1 | r1 << 16); // add x(r1),x29,x(r1) o(0x4c402bdc | (uint32_t)fsize << 7 | (uint32_t)(hfa == 2) << 15 | (uint32_t)(hfa == 3) << 14); // ld1 {v28.(4s|2d),...},[x30] o(0x0d00801c | r1 << 5 | (fsize == 8) << 10 | (uint32_t)(hfa != 2) << 13 | (uint32_t)(hfa != 3) << 21); // st(hfa) {v28.(s|d),...}[0],[x(r1)] } // lab2: write32le(cur_text_section->data + b2, 0x14000000 | (ind - b2) >> 2); } } ST_FUNC int gfunc_sret(CType *vt, int variadic, CType *ret, int *align, int *regsize) { return 0; } ST_FUNC void gfunc_return(CType *func_type) { CType *t = func_type; unsigned long a; arm64_pcs(0, &t, &a); switch (a) { case -1: break; case 0: if ((func_type->t & VT_BTYPE) == VT_STRUCT) { int align, size = type_size(func_type, &align); gaddrof(); gv(RC_R(0)); arm64_ldrs(0, size); } else gv(RC_IRET); break; case 1: { CType type = *func_type; mk_pointer(&type); vset(&type, VT_LOCAL | VT_LVAL, func_vc); indir(); vswap(); vstore(); break; } case 16: if ((func_type->t & VT_BTYPE) == VT_STRUCT) { uint32_t j, sz, n = arm64_hfa(&vtop->type, &sz); gaddrof(); gv(RC_R(0)); for (j = 0; j < n; j++) o(0x3d400000 | (sz & 16) << 19 | -(sz & 8) << 27 | (sz & 4) << 29 | j | j << 10); // ldr ([sdq])(*),[x0,#(j * sz)] } else gv(RC_FRET); break; default: assert(0); } vtop--; } ST_FUNC void gfunc_epilog(void) { if (loc) { // Insert instructions to subtract size of stack frame from SP. unsigned char *ptr = cur_text_section->data + arm64_func_sub_sp_offset; uint64_t diff = (-loc + 15) & ~15; if (!(diff >> 24)) { if (diff & 0xfff) // sub sp,sp,#(diff & 0xfff) write32le(ptr, 0xd10003ff | (diff & 0xfff) << 10); if (diff >> 12) // sub sp,sp,#(diff >> 12),lsl #12 write32le(ptr + 4, 0xd14003ff | (diff >> 12) << 10); } else { // In this case we may subtract more than necessary, // but always less than 17/16 of what we were aiming for. int i = 0; int j = 0; while (diff >> 20) { diff = (diff + 0xffff) >> 16; ++i; } while (diff >> 16) { diff = (diff + 1) >> 1; ++j; } write32le(ptr, 0xd2800010 | diff << 5 | i << 21); // mov x16,#(diff),lsl #(16 * i) write32le(ptr + 4, 0xcb3063ff | j << 10); // sub sp,sp,x16,lsl #(j) } } o(0x910003bf); // mov sp,x29 o(0xa8ce7bfd); // ldp x29,x30,[sp],#224 o(0xd65f03c0); // ret } ST_FUNC void gen_fill_nops(int bytes) { if ((bytes & 3)) tcc_error("alignment of code section not multiple of 4"); while (bytes > 0) { o(0xd503201f); // nop bytes -= 4; } } // Generate forward branch to label: ST_FUNC int gjmp(int t) { int r = ind; if (nocode_wanted) return t; o(t); return r; } // Generate branch to known address: ST_FUNC void gjmp_addr(int a) { assert(a - ind + 0x8000000 < 0x10000000); o(0x14000000 | ((a - ind) >> 2 & 0x3ffffff)); } ST_FUNC int gjmp_append(int n, int t) { void *p; /* insert vtop->c jump list in t */ if (n) { uint32_t n1 = n, n2; while ((n2 = read32le(p = cur_text_section->data + n1))) n1 = n2; write32le(p, t); t = n; } return t; } void arm64_vset_VT_CMP(int op) { if (op >= TOK_ULT && op <= TOK_GT) { vtop->cmp_r = vtop->r; vset_VT_CMP(0x80); } } static void arm64_gen_opil(int op, uint32_t l); static void arm64_load_cmp(int r, SValue *sv) { sv->r = sv->cmp_r; if (sv->c.i & 1) { vpushi(1); arm64_gen_opil('^', 0); } if (r != sv->r) { load(r, sv); sv->r = r; } } ST_FUNC int gjmp_cond(int op, int t) { int bt = vtop->type.t & VT_BTYPE; int inv = op & 1; vtop->r = vtop->cmp_r; if (bt == VT_LDOUBLE) { uint32_t a, b, f = fltr(gv(RC_FLOAT)); a = get_reg(RC_INT); vpushi(0); vtop[0].r = a; b = get_reg(RC_INT); a = intr(a); b = intr(b); o(0x4e083c00 | a | f << 5); // mov x(a),v(f).d[0] o(0x4e183c00 | b | f << 5); // mov x(b),v(f).d[1] o(0xaa000400 | a | a << 5 | b << 16); // orr x(a),x(a),x(b),lsl #1 o(0xb4000040 | a | !!inv << 24); // cbz/cbnz x(a),.+8 --vtop; } else if (bt == VT_FLOAT || bt == VT_DOUBLE) { uint32_t a = fltr(gv(RC_FLOAT)); o(0x1e202008 | a << 5 | (bt != VT_FLOAT) << 22); // fcmp o(0x54000040 | !!inv); // b.eq/b.ne .+8 } else { uint32_t ll = (bt == VT_PTR || bt == VT_LLONG); uint32_t a = intr(gv(RC_INT)); o(0x34000040 | a | !!inv << 24 | ll << 31); // cbz/cbnz wA,.+8 } return gjmp(t); } static int arm64_iconst(uint64_t *val, SValue *sv) { if ((sv->r & (VT_VALMASK | VT_LVAL | VT_SYM)) != VT_CONST) return 0; if (val) { int t = sv->type.t; int bt = t & VT_BTYPE; *val = ((bt == VT_LLONG || bt == VT_PTR) ? sv->c.i : (uint32_t)sv->c.i | (t & VT_UNSIGNED ? 0 : -(sv->c.i & 0x80000000))); } return 1; } static int arm64_gen_opic(int op, uint32_t l, int rev, uint64_t val, uint32_t x, uint32_t a) { if (op == '-' && !rev) { val = -val; op = '+'; } val = l ? val : (uint32_t)val; switch (op) { case '+': { uint32_t s = l ? val >> 63 : val >> 31; val = s ? -val : val; val = l ? val : (uint32_t)val; if (!(val & ~(uint64_t)0xfff)) o(0x11000000 | l << 31 | s << 30 | x | a << 5 | val << 10); else if (!(val & ~(uint64_t)0xfff000)) o(0x11400000 | l << 31 | s << 30 | x | a << 5 | val >> 12 << 10); else { arm64_movimm(30, val); // use x30 o(0x0b1e0000 | l << 31 | s << 30 | x | a << 5); } return 1; } case '-': if (!val) o(0x4b0003e0 | l << 31 | x | a << 16); // neg else if (val == (l ? (uint64_t)-1 : (uint32_t)-1)) o(0x2a2003e0 | l << 31 | x | a << 16); // mvn else { arm64_movimm(30, val); // use x30 o(0x4b0003c0 | l << 31 | x | a << 16); // sub } return 1; case '^': if (val == -1 || (val == 0xffffffff && !l)) { o(0x2a2003e0 | l << 31 | x | a << 16); // mvn return 1; } // fall through case '&': case '|': { int e = arm64_encode_bimm64(l ? val : val | val << 32); if (e < 0) return 0; o((op == '&' ? 0x12000000 : op == '|' ? 0x32000000 : 0x52000000) | l << 31 | x | a << 5 | (uint32_t)e << 10); return 1; } case TOK_SAR: case TOK_SHL: case TOK_SHR: { uint32_t n = 32 << l; val = val & (n - 1); if (rev) return 0; if (!val) assert(0); else if (op == TOK_SHL) o(0x53000000 | l << 31 | l << 22 | x | a << 5 | (n - val) << 16 | (n - 1 - val) << 10); // lsl else o(0x13000000 | (op == TOK_SHR) << 30 | l << 31 | l << 22 | x | a << 5 | val << 16 | (n - 1) << 10); // lsr/asr return 1; } } return 0; } static void arm64_gen_opil(int op, uint32_t l) { uint32_t x, a, b; // Special treatment for operations with a constant operand: { uint64_t val; int rev = 1; if (arm64_iconst(0, &vtop[0])) { vswap(); rev = 0; } if (arm64_iconst(&val, &vtop[-1])) { gv(RC_INT); a = intr(vtop[0].r); --vtop; x = get_reg(RC_INT); ++vtop; if (arm64_gen_opic(op, l, rev, val, intr(x), a)) { vtop[0].r = x; vswap(); --vtop; return; } } if (!rev) vswap(); } gv2(RC_INT, RC_INT); assert(vtop[-1].r < VT_CONST && vtop[0].r < VT_CONST); a = intr(vtop[-1].r); b = intr(vtop[0].r); vtop -= 2; x = get_reg(RC_INT); ++vtop; vtop[0].r = x; x = intr(x); switch (op) { case '%': // Use x30 for quotient: o(0x1ac00c00 | l << 31 | 30 | a << 5 | b << 16); // sdiv o(0x1b008000 | l << 31 | x | (uint32_t)30 << 5 | b << 16 | a << 10); // msub break; case '&': o(0x0a000000 | l << 31 | x | a << 5 | b << 16); // and break; case '*': o(0x1b007c00 | l << 31 | x | a << 5 | b << 16); // mul break; case '+': o(0x0b000000 | l << 31 | x | a << 5 | b << 16); // add break; case '-': o(0x4b000000 | l << 31 | x | a << 5 | b << 16); // sub break; case '/': o(0x1ac00c00 | l << 31 | x | a << 5 | b << 16); // sdiv break; case '^': o(0x4a000000 | l << 31 | x | a << 5 | b << 16); // eor break; case '|': o(0x2a000000 | l << 31 | x | a << 5 | b << 16); // orr break; case TOK_EQ: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f17e0 | x); // cset wA,eq break; case TOK_GE: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9fb7e0 | x); // cset wA,ge break; case TOK_GT: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9fd7e0 | x); // cset wA,gt break; case TOK_LE: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9fc7e0 | x); // cset wA,le break; case TOK_LT: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9fa7e0 | x); // cset wA,lt break; case TOK_NE: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f07e0 | x); // cset wA,ne break; case TOK_SAR: o(0x1ac02800 | l << 31 | x | a << 5 | b << 16); // asr break; case TOK_SHL: o(0x1ac02000 | l << 31 | x | a << 5 | b << 16); // lsl break; case TOK_SHR: o(0x1ac02400 | l << 31 | x | a << 5 | b << 16); // lsr break; case TOK_UDIV: case TOK_PDIV: o(0x1ac00800 | l << 31 | x | a << 5 | b << 16); // udiv break; case TOK_UGE: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f37e0 | x); // cset wA,cs break; case TOK_UGT: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f97e0 | x); // cset wA,hi break; case TOK_ULT: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f27e0 | x); // cset wA,cc break; case TOK_ULE: o(0x6b00001f | l << 31 | a << 5 | b << 16); // cmp o(0x1a9f87e0 | x); // cset wA,ls break; case TOK_UMOD: // Use x30 for quotient: o(0x1ac00800 | l << 31 | 30 | a << 5 | b << 16); // udiv o(0x1b008000 | l << 31 | x | (uint32_t)30 << 5 | b << 16 | a << 10); // msub break; default: assert(0); } } ST_FUNC void gen_opi(int op) { arm64_gen_opil(op, 0); arm64_vset_VT_CMP(op); } ST_FUNC void gen_opl(int op) { arm64_gen_opil(op, 1); arm64_vset_VT_CMP(op); } ST_FUNC void gen_opf(int op) { uint32_t x, a, b, dbl; if (vtop[0].type.t == VT_LDOUBLE) { CType type = vtop[0].type; int func = 0; int cond = -1; switch (op) { case '*': func = TOK___multf3; break; case '+': func = TOK___addtf3; break; case '-': func = TOK___subtf3; break; case '/': func = TOK___divtf3; break; case TOK_EQ: func = TOK___eqtf2; cond = 1; break; case TOK_NE: func = TOK___netf2; cond = 0; break; case TOK_LT: func = TOK___lttf2; cond = 10; break; case TOK_GE: func = TOK___getf2; cond = 11; break; case TOK_LE: func = TOK___letf2; cond = 12; break; case TOK_GT: func = TOK___gttf2; cond = 13; break; default: assert(0); break; } vpush_global_sym(&func_old_type, func); vrott(3); gfunc_call(2); vpushi(0); vtop->r = cond < 0 ? REG_FRET : REG_IRET; if (cond < 0) vtop->type = type; else { o(0x7100001f); // cmp w0,#0 o(0x1a9f07e0 | (uint32_t)cond << 12); // cset w0,(cond) } return; } dbl = vtop[0].type.t != VT_FLOAT; gv2(RC_FLOAT, RC_FLOAT); assert(vtop[-1].r < VT_CONST && vtop[0].r < VT_CONST); a = fltr(vtop[-1].r); b = fltr(vtop[0].r); vtop -= 2; switch (op) { case TOK_EQ: case TOK_NE: case TOK_LT: case TOK_GE: case TOK_LE: case TOK_GT: x = get_reg(RC_INT); ++vtop; vtop[0].r = x; x = intr(x); break; default: x = get_reg(RC_FLOAT); ++vtop; vtop[0].r = x; x = fltr(x); break; } switch (op) { case '*': o(0x1e200800 | dbl << 22 | x | a << 5 | b << 16); // fmul break; case '+': o(0x1e202800 | dbl << 22 | x | a << 5 | b << 16); // fadd break; case '-': o(0x1e203800 | dbl << 22 | x | a << 5 | b << 16); // fsub break; case '/': o(0x1e201800 | dbl << 22 | x | a << 5 | b << 16); // fdiv break; case TOK_EQ: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9f17e0 | x); // cset w(x),eq break; case TOK_GE: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9fb7e0 | x); // cset w(x),ge break; case TOK_GT: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9fd7e0 | x); // cset w(x),gt break; case TOK_LE: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9f87e0 | x); // cset w(x),ls break; case TOK_LT: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9f57e0 | x); // cset w(x),mi break; case TOK_NE: o(0x1e202000 | dbl << 22 | a << 5 | b << 16); // fcmp o(0x1a9f07e0 | x); // cset w(x),ne break; default: assert(0); } arm64_vset_VT_CMP(op); } // Generate sign extension from 32 to 64 bits: ST_FUNC void gen_cvt_sxtw(void) { uint32_t r = intr(gv(RC_INT)); o(0x93407c00 | r | r << 5); // sxtw x(r),w(r) } /* char/short to int conversion */ ST_FUNC void gen_cvt_csti(int t) { int r = intr(gv(RC_INT)); o(0x13001c00 | ((t & VT_BTYPE) == VT_SHORT) << 13 | (uint32_t)!!(t & VT_UNSIGNED) << 30 | r | r << 5); // [su]xt[bh] w(r),w(r) } ST_FUNC void gen_cvt_itof(int t) { if (t == VT_LDOUBLE) { int f = vtop->type.t; int func = (f & VT_BTYPE) == VT_LLONG ? (f & VT_UNSIGNED ? TOK___floatunditf : TOK___floatditf) : (f & VT_UNSIGNED ? TOK___floatunsitf : TOK___floatsitf); vpush_global_sym(&func_old_type, func); vrott(2); gfunc_call(1); vpushi(0); vtop->type.t = t; vtop->r = REG_FRET; return; } else { int d, n = intr(gv(RC_INT)); int s = !(vtop->type.t & VT_UNSIGNED); uint32_t l = ((vtop->type.t & VT_BTYPE) == VT_LLONG); --vtop; d = get_reg(RC_FLOAT); ++vtop; vtop[0].r = d; o(0x1e220000 | (uint32_t)!s << 16 | (uint32_t)(t != VT_FLOAT) << 22 | fltr(d) | l << 31 | n << 5); // [us]cvtf [sd](d),[wx](n) } } ST_FUNC void gen_cvt_ftoi(int t) { if ((vtop->type.t & VT_BTYPE) == VT_LDOUBLE) { int func = (t & VT_BTYPE) == VT_LLONG ? (t & VT_UNSIGNED ? TOK___fixunstfdi : TOK___fixtfdi) : (t & VT_UNSIGNED ? TOK___fixunstfsi : TOK___fixtfsi); vpush_global_sym(&func_old_type, func); vrott(2); gfunc_call(1); vpushi(0); vtop->type.t = t; vtop->r = REG_IRET; return; } else { int d, n = fltr(gv(RC_FLOAT)); uint32_t l = ((vtop->type.t & VT_BTYPE) != VT_FLOAT); --vtop; d = get_reg(RC_INT); ++vtop; vtop[0].r = d; o(0x1e380000 | (uint32_t)!!(t & VT_UNSIGNED) << 16 | (uint32_t)((t & VT_BTYPE) == VT_LLONG) << 31 | intr(d) | l << 22 | n << 5); // fcvtz[su] [wx](d),[sd](n) } } ST_FUNC void gen_cvt_ftof(int t) { int f = vtop[0].type.t & VT_BTYPE; assert(t == VT_FLOAT || t == VT_DOUBLE || t == VT_LDOUBLE); assert(f == VT_FLOAT || f == VT_DOUBLE || f == VT_LDOUBLE); if (t == f) return; if (t == VT_LDOUBLE || f == VT_LDOUBLE) { int func = (t == VT_LDOUBLE) ? (f == VT_FLOAT ? TOK___extendsftf2 : TOK___extenddftf2) : (t == VT_FLOAT ? TOK___trunctfsf2 : TOK___trunctfdf2); vpush_global_sym(&func_old_type, func); vrott(2); gfunc_call(1); vpushi(0); vtop->type.t = t; vtop->r = REG_FRET; } else { int x, a; gv(RC_FLOAT); assert(vtop[0].r < VT_CONST); a = fltr(vtop[0].r); --vtop; x = get_reg(RC_FLOAT); ++vtop; vtop[0].r = x; x = fltr(x); if (f == VT_FLOAT) o(0x1e22c000 | x | a << 5); // fcvt d(x),s(a) else o(0x1e624000 | x | a << 5); // fcvt s(x),d(a) } } ST_FUNC void ggoto(void) { arm64_gen_bl_or_b(1); --vtop; } ST_FUNC void gen_clear_cache(void) { uint32_t beg, end, dsz, isz, p, lab1, b1; gv2(RC_INT, RC_INT); vpushi(0); vtop->r = get_reg(RC_INT); vpushi(0); vtop->r = get_reg(RC_INT); vpushi(0); vtop->r = get_reg(RC_INT); beg = intr(vtop[-4].r); // x0 end = intr(vtop[-3].r); // x1 dsz = intr(vtop[-2].r); // x2 isz = intr(vtop[-1].r); // x3 p = intr(vtop[0].r); // x4 vtop -= 5; o(0xd53b0020 | isz); // mrs x(isz),ctr_el0 o(0x52800080 | p); // mov w(p),#4 o(0x53104c00 | dsz | isz << 5); // ubfx w(dsz),w(isz),#16,#4 o(0x1ac02000 | dsz | p << 5 | dsz << 16); // lsl w(dsz),w(p),w(dsz) o(0x12000c00 | isz | isz << 5); // and w(isz),w(isz),#15 o(0x1ac02000 | isz | p << 5 | isz << 16); // lsl w(isz),w(p),w(isz) o(0x51000400 | p | dsz << 5); // sub w(p),w(dsz),#1 o(0x8a240004 | p | beg << 5 | p << 16); // bic x(p),x(beg),x(p) b1 = ind; o(0x14000000); // b lab1 = ind; o(0xd50b7b20 | p); // dc cvau,x(p) o(0x8b000000 | p | p << 5 | dsz << 16); // add x(p),x(p),x(dsz) write32le(cur_text_section->data + b1, 0x14000000 | (ind - b1) >> 2); o(0xeb00001f | p << 5 | end << 16); // cmp x(p),x(end) o(0x54ffffa3 | ((lab1 - ind) << 3 & 0xffffe0)); // b.cc lab1 o(0xd5033b9f); // dsb ish o(0x51000400 | p | isz << 5); // sub w(p),w(isz),#1 o(0x8a240004 | p | beg << 5 | p << 16); // bic x(p),x(beg),x(p) b1 = ind; o(0x14000000); // b lab1 = ind; o(0xd50b7520 | p); // ic ivau,x(p) o(0x8b000000 | p | p << 5 | isz << 16); // add x(p),x(p),x(isz) write32le(cur_text_section->data + b1, 0x14000000 | (ind - b1) >> 2); o(0xeb00001f | p << 5 | end << 16); // cmp x(p),x(end) o(0x54ffffa3 | ((lab1 - ind) << 3 & 0xffffe0)); // b.cc lab1 o(0xd5033b9f); // dsb ish o(0xd5033fdf); // isb } ST_FUNC void gen_vla_sp_save(int addr) { uint32_t r = intr(get_reg(RC_INT)); o(0x910003e0 | r); // mov x(r),sp arm64_strx(3, r, 29, addr); } ST_FUNC void gen_vla_sp_restore(int addr) { // Use x30 because this function can be called when there // is a live return value in x0 but there is nothing on // the value stack to prevent get_reg from returning x0. uint32_t r = 30; arm64_ldrx(0, 3, r, 29, addr); o(0x9100001f | r << 5); // mov sp,x(r) } ST_FUNC void gen_vla_alloc(CType *type, int align) { uint32_t r = intr(gv(RC_INT)); o(0x91003c00 | r | r << 5); // add x(r),x(r),#15 o(0x927cec00 | r | r << 5); // bic x(r),x(r),#15 o(0xcb2063ff | r << 16); // sub sp,sp,x(r) vpop(); } /* end of A64 code generator */ /*************************************************************/ #endif /*************************************************************/