/* * %CopyrightBegin% * * Copyright Ericsson AB 2004-2016. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * %CopyrightEnd% */ #include /* offsetof() */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "global.h" #include #include "error.h" #include "bif.h" #include "big.h" /* term_to_Sint() */ #include "hipe_arch.h" #include "hipe_bif0.h" #include "hipe_native_bif.h" /* nbif_callemu() */ #undef F_TIMO #undef THE_NON_VALUE #undef ERL_FUN_SIZE #include "hipe_literals.h" const Uint sse2_fnegate_mask[2] = {0x8000000000000000,0}; void hipe_patch_load_fe(Uint64 *address, Uint64 value) { /* address points to an imm64 operand */ *address = value; hipe_flush_icache_word(address); } int hipe_patch_insn(void *address, Uint64 value, Eterm type) { switch (type) { case am_closure: case am_constant: *(Uint64*)address = value; break; case am_c_const: case am_atom: /* check that value fits in an unsigned imm32 */ /* XXX: are we sure it's not really a signed imm32? */ if ((Uint)(Uint32)value != value) return -1; *(Uint32*)address = (Uint32)value; break; default: return -1; } hipe_flush_icache_word(address); return 0; } int hipe_patch_call(void *callAddress, void *destAddress, void *trampoline) { Sint rel32; ASSERT(trampoline == NULL); rel32 = (Sint)destAddress - (Sint)callAddress - 4; if ((Sint)(Sint32)rel32 != rel32) return -1; *(Uint32*)callAddress = (Uint32)rel32; hipe_flush_icache_word(callAddress); return 0; } /* * Memory allocator for executable code. * * We use a dedicated allocator for executable code (from OTP 19.0) * to make sure the memory we get is executable (PROT_EXEC) * and to ensure that executable code ends up in the low 2GB * of the address space, as required by HiPE/AMD64's small code model. */ static void *alloc_code(unsigned int alloc_bytes) { return erts_alloc(ERTS_ALC_T_HIPE_EXEC, alloc_bytes); } void *hipe_alloc_code(Uint nrbytes, Eterm callees, Eterm *trampolines, Process *p) { if (is_not_nil(callees)) return NULL; *trampolines = NIL; return alloc_code(nrbytes); } void hipe_free_code(void* code, unsigned int bytes) { erts_free(ERTS_ALC_T_HIPE_EXEC, code); } /* Make stub for native code calling exported beam function. */ void *hipe_make_native_stub(void *callee_exp, unsigned int beamArity) { /* * This creates a native code stub with the following contents: * * movq $Address, P_CALLEE_EXP(%ebp) %% Actually two movl * movb $Arity, P_ARITY(%ebp) * jmp callemu * * The stub has variable size, depending on whether the P_CALLEE_EXP * and P_ARITY offsets fit in 8-bit signed displacements or not. * The rel32 offset in the final jmp depends on its actual location, * which also depends on the size of the previous instructions. * Arity is stored with a movb because (a) Björn tells me arities * are <= 255, and (b) a movb is smaller and faster than a movl. */ unsigned int codeSize; unsigned char *code, *codep; unsigned int callEmuOffset; codeSize = /* 23, 26, 29, or 32 bytes */ 23 + /* 23 when all offsets are 8-bit */ (P_CALLEE_EXP >= 128 ? 3 : 0) + ((P_CALLEE_EXP + 4) >= 128 ? 3 : 0) + (P_ARITY >= 128 ? 3 : 0); codep = code = alloc_code(codeSize); if (!code) return NULL; /* movl $callee_exp, P_CALLEE_EXP(%ebp); 3 or 6 bytes, plus 4 */ codep[0] = 0xc7; #if P_CALLEE_EXP >= 128 codep[1] = 0x85; /* disp32[EBP] */ codep[2] = P_CALLEE_EXP & 0xFF; codep[3] = (P_CALLEE_EXP >> 8) & 0xFF; codep[4] = (P_CALLEE_EXP >> 16) & 0xFF; codep[5] = (P_CALLEE_EXP >> 24) & 0xFF; codep += 6; #else codep[1] = 0x45; /* disp8[EBP] */ codep[2] = P_CALLEE_EXP; codep += 3; #endif codep[0] = ((unsigned long)callee_exp ) & 0xFF; codep[1] = ((unsigned long)callee_exp >> 8) & 0xFF; codep[2] = ((unsigned long)callee_exp >> 16) & 0xFF; codep[3] = ((unsigned long)callee_exp >> 24) & 0xFF; codep += 4; /* movl (shl 32 $callee_exp), P_CALLEE_EXP+4(%ebp); 3 or 6 bytes, plus 4 */ codep[0] = 0xc7; #if P_CALLEE_EXP+4 >= 128 codep[1] = 0x85; /* disp32[EBP] */ codep[2] = (P_CALLEE_EXP+4) & 0xFF; codep[3] = ((P_CALLEE_EXP+4) >> 8) & 0xFF; codep[4] = ((P_CALLEE_EXP+4) >> 16) & 0xFF; codep[5] = ((P_CALLEE_EXP+4) >> 24) & 0xFF; codep += 6; #else codep[1] = 0x45; /* disp8[EBP] */ codep[2] = (P_CALLEE_EXP+4); codep += 3; #endif codep[0] = ((unsigned long)callee_exp >> 32) & 0xFF; codep[1] = ((unsigned long)callee_exp >> 40) & 0xFF; codep[2] = ((unsigned long)callee_exp >> 48) & 0xFF; codep[3] = ((unsigned long)callee_exp >> 56) & 0xFF; codep += 4; /* movb $beamArity, P_ARITY(%ebp); 3 or 6 bytes */ codep[0] = 0xc6; #if P_ARITY >= 128 codep[1] = 0x85; /* disp32[EBP] */ codep[2] = P_ARITY & 0xFF; codep[3] = (P_ARITY >> 8) & 0xFF; codep[4] = (P_ARITY >> 16) & 0xFF; codep[5] = (P_ARITY >> 24) & 0xFF; codep += 6; #else codep[1] = 0x45; /* disp8[EBP] */ codep[2] = P_ARITY; codep += 3; #endif codep[0] = beamArity; codep += 1; /* jmp callemu; 5 bytes */ callEmuOffset = (unsigned char*)nbif_callemu - (code + codeSize); codep[0] = 0xe9; codep[1] = callEmuOffset & 0xFF; codep[2] = (callEmuOffset >> 8) & 0xFF; codep[3] = (callEmuOffset >> 16) & 0xFF; codep[4] = (callEmuOffset >> 24) & 0xFF; codep += 5; ASSERT(codep == code + codeSize); /* I-cache flush? */ return code; } void hipe_free_native_stub(void* stub) { erts_free(ERTS_ALC_T_HIPE_EXEC, stub); } void hipe_arch_print_pcb(struct hipe_process_state *p) { #define U(n,x) \ printf(" % 4d | %s | 0x%0*lx | %*s |\r\n", (int)offsetof(struct hipe_process_state,x), n, 2*(int)sizeof(long), (unsigned long)p->x, 2+2*(int)sizeof(long), "") U("ncsp ", ncsp); U("narity ", narity); #undef U }