/** * \file * intrinsics for variable sized int/floats * * Author: * Rodrigo Kumpera (kumpera@gmail.com) * * (C) 2013 Xamarin * Licensed under the MIT license. See LICENSE file in the project root for full license information. */ #include #include #include "mini.h" #include "ir-emit.h" #include "glib.h" typedef struct { const char *op_name; short op_table[4]; } IntIntrisic; typedef struct { short op_index; short big_stack_type; short small_stack_type; short stack_type; short conv_4_to_8; short conv_8_to_4; short move; short inc_op; short dec_op; short store_op; short compare_op; } MagicTypeInfo; #if SIZEOF_VOID_P == 8 #define OP_PT_ADD OP_LADD #define OP_PT_SUB OP_LSUB #define OP_PT_MUL OP_LMUL #define OP_PT_DIV OP_LDIV #define OP_PT_REM OP_LREM #define OP_PT_NEG OP_LNEG #define OP_PT_AND OP_LAND #define OP_PT_OR OP_LOR #define OP_PT_XOR OP_LXOR #define OP_PT_NOT OP_LNOT #define OP_PT_SHL OP_LSHL #define OP_PT_SHR OP_LSHR #define OP_PT_DIV_UN OP_LDIV_UN #define OP_PT_REM_UN OP_LREM_UN #define OP_PT_SHR_UN OP_LSHR_UN #define OP_PT_ADD_IMM OP_LADD_IMM #define OP_PT_SUB_IMM OP_LSUB_IMM #define OP_PT_STORE_FP_MEMBASE_REG OP_STORER8_MEMBASE_REG #define OP_PCOMPARE OP_LCOMPARE #else #define OP_PT_ADD OP_IADD #define OP_PT_SUB OP_ISUB #define OP_PT_MUL OP_IMUL #define OP_PT_DIV OP_IDIV #define OP_PT_REM OP_IREM #define OP_PT_NEG OP_INEG #define OP_PT_AND OP_IAND #define OP_PT_OR OP_IOR #define OP_PT_XOR OP_IXOR #define OP_PT_NOT OP_INOT #define OP_PT_SHL OP_ISHL #define OP_PT_SHR OP_ISHR #define OP_PT_DIV_UN OP_IDIV_UN #define OP_PT_REM_UN OP_IREM_UN #define OP_PT_SHR_UN OP_ISHR_UN #define OP_PT_ADD_IMM OP_IADD_IMM #define OP_PT_SUB_IMM OP_ISUB_IMM #define OP_PT_STORE_FP_MEMBASE_REG OP_STORER4_MEMBASE_REG #define OP_PCOMPARE OP_ICOMPARE #endif static const IntIntrisic int_binop[] = { { "op_Addition", { OP_PT_ADD, OP_PT_ADD, OP_FADD, OP_RADD } }, { "op_Subtraction", { OP_PT_SUB, OP_PT_SUB, OP_FSUB, OP_RSUB } }, { "op_Multiply", { OP_PT_MUL, OP_PT_MUL, OP_FMUL, OP_RMUL } }, { "op_Division", { OP_PT_DIV, OP_PT_DIV_UN, OP_FDIV, OP_RDIV } }, { "op_Modulus", { OP_PT_REM, OP_PT_REM_UN, OP_FREM, OP_RREM } }, { "op_BitwiseAnd", { OP_PT_AND, OP_PT_AND } }, { "op_BitwiseOr", { OP_PT_OR, OP_PT_OR } }, { "op_ExclusiveOr", { OP_PT_XOR, OP_PT_XOR } }, { "op_LeftShift", { OP_PT_SHL, OP_PT_SHL } }, { "op_RightShift", { OP_PT_SHR, OP_PT_SHR_UN } }, }; static const IntIntrisic int_unnop[] = { { "op_UnaryPlus", { OP_MOVE, OP_MOVE, OP_FMOVE, OP_RMOVE } }, { "op_UnaryNegation", { OP_PT_NEG, OP_PT_NEG, OP_FNEG, OP_RNEG } }, { "op_OnesComplement", { OP_PT_NOT, OP_PT_NOT, OP_FNOT, OP_RNOT } }, }; static const IntIntrisic int_cmpop[] = { { "op_Inequality", { OP_ICNEQ, OP_ICNEQ, OP_FCNEQ, OP_RCNEQ } }, { "op_Equality", { OP_ICEQ, OP_ICEQ, OP_FCEQ, OP_RCEQ } }, { "op_GreaterThan", { OP_ICGT, OP_ICGT_UN, OP_FCGT, OP_RCGT } }, { "op_GreaterThanOrEqual", { OP_ICGE, OP_ICGE_UN, OP_FCGE, OP_RCGE } }, { "op_LessThan", { OP_ICLT, OP_ICLT_UN, OP_FCLT, OP_RCLT } }, { "op_LessThanOrEqual", { OP_ICLE, OP_ICLE_UN, OP_FCLE, OP_RCLE } }, }; static const MagicTypeInfo type_info[] = { //nint { 0, STACK_I8, STACK_I4, STACK_PTR, OP_ICONV_TO_I8, OP_LCONV_TO_I4, OP_MOVE, OP_PT_ADD_IMM, OP_PT_SUB_IMM, OP_STORE_MEMBASE_REG, OP_PCOMPARE }, //nuint { 1, STACK_I8, STACK_I4, STACK_PTR, OP_ICONV_TO_U8, OP_LCONV_TO_U4, OP_MOVE, OP_PT_ADD_IMM, OP_PT_SUB_IMM, OP_STORE_MEMBASE_REG, OP_PCOMPARE }, //nfloat { 2, STACK_R8, STACK_R8, STACK_R8, OP_FCONV_TO_R8, OP_FCONV_TO_R4, OP_FMOVE, 0, 0, OP_PT_STORE_FP_MEMBASE_REG, 0 }, }; static inline gboolean type_size (MonoCompile *cfg, MonoType *type) { if (type->type == MONO_TYPE_I4 || type->type == MONO_TYPE_U4) return 4; else if (type->type == MONO_TYPE_I8 || type->type == MONO_TYPE_U8) return 8; else if (type->type == MONO_TYPE_R4 && !type->byref && cfg->r4fp) return 4; else if (type->type == MONO_TYPE_R8 && !type->byref) return 8; return SIZEOF_VOID_P; } #ifndef DISABLE_JIT static gboolean is_int_type (MonoType *t); static gboolean is_float_type (MonoType *t); static MonoInst* emit_narrow (MonoCompile *cfg, const MagicTypeInfo *info, int sreg) { MonoInst *ins; MONO_INST_NEW (cfg, ins, info->conv_8_to_4); ins->sreg1 = sreg; if (info->conv_8_to_4 == OP_FCONV_TO_R4) ins->type = cfg->r4_stack_type; else ins->type = info->small_stack_type; ins->dreg = alloc_dreg (cfg, ins->type); MONO_ADD_INS (cfg->cbb, ins); return mono_decompose_opcode (cfg, ins); } static MonoInst* emit_widen (MonoCompile *cfg, const MagicTypeInfo *info, int sreg) { MonoInst *ins; if (cfg->r4fp && info->conv_4_to_8 == OP_FCONV_TO_R8) MONO_INST_NEW (cfg, ins, OP_RCONV_TO_R8); else MONO_INST_NEW (cfg, ins, info->conv_4_to_8); ins->sreg1 = sreg; ins->type = info->big_stack_type; ins->dreg = alloc_dreg (cfg, info->big_stack_type); MONO_ADD_INS (cfg->cbb, ins); return mono_decompose_opcode (cfg, ins); } static MonoInst* emit_intrinsics (MonoCompile *cfg, MonoMethod *cmethod, MonoMethodSignature *fsig, MonoInst **args, const MagicTypeInfo *info) { int i = 0; const char *name = cmethod->name; MonoInst *ins; int type_index, stack_type; if (info->op_index == 2 && cfg->r4fp && SIZEOF_VOID_P == 4) { type_index = 3; stack_type = STACK_R4; } else { type_index = info->op_index; stack_type = info->stack_type; } if (!strcmp ("op_Implicit", name) || !strcmp ("op_Explicit", name)) { int source_size = type_size (cfg, fsig->params [0]); int dest_size = type_size (cfg, fsig->ret); switch (info->big_stack_type) { case STACK_I8: if (!is_int_type (fsig->params [0]) || !is_int_type (fsig->ret)) return NULL; break; case STACK_R8: if (!is_float_type (fsig->params [0]) || !is_float_type (fsig->ret)) return NULL; break; default: g_assert_not_reached (); } //4 -> 4 or 8 -> 8 if (source_size == dest_size) return args [0]; //4 -> 8 if (source_size < dest_size) return emit_widen (cfg, info, args [0]->dreg); //8 -> 4 return emit_narrow (cfg, info, args [0]->dreg); } if (!strcmp (".ctor", name)) { gboolean is_ldaddr = args [0]->opcode == OP_LDADDR; int arg0 = args [1]->dreg; int arg_size = type_size (cfg, fsig->params [0]); if (arg_size > SIZEOF_VOID_P) //8 -> 4 arg0 = emit_narrow (cfg, info, arg0)->dreg; else if (arg_size < SIZEOF_VOID_P) //4 -> 8 arg0 = emit_widen (cfg, info, arg0)->dreg; if (is_ldaddr) { /*Eliminate LDADDR if it's initing a local var*/ int dreg = ((MonoInst*)args [0]->inst_p0)->dreg; NULLIFY_INS (args [0]); EMIT_NEW_UNALU (cfg, ins, info->move, dreg, arg0); cfg->has_indirection = TRUE; } else { EMIT_NEW_STORE_MEMBASE (cfg, ins, info->store_op, args [0]->dreg, 0, arg0); } return ins; } if (!strcmp ("op_Increment", name) || !strcmp ("op_Decrement", name)) { gboolean inc = !strcmp ("op_Increment", name); /* FIXME float inc is too complex to bother with*/ //this is broken with ints too // if (!info->inc_op) return NULL; /* We have IR for inc/dec */ MONO_INST_NEW (cfg, ins, inc ? info->inc_op : info->dec_op); ins->dreg = alloc_dreg (cfg, info->stack_type); ins->sreg1 = args [0]->dreg; ins->inst_imm = 1; ins->type = info->stack_type; MONO_ADD_INS (cfg->cbb, ins); return ins; } for (i = 0; i < sizeof (int_binop) / sizeof (IntIntrisic); ++i) { if (!strcmp (int_binop [i].op_name, name)) { if (!int_binop [i].op_table [info->op_index]) return NULL; g_assert (int_binop [i].op_table [type_index]); MONO_INST_NEW (cfg, ins, int_binop [i].op_table [type_index]); ins->dreg = alloc_dreg (cfg, stack_type); ins->sreg1 = args [0]->dreg; ins->sreg2 = args [1]->dreg; ins->type = stack_type; MONO_ADD_INS (cfg->cbb, ins); return mono_decompose_opcode (cfg, ins); } } for (i = 0; i < sizeof (int_unnop) / sizeof (IntIntrisic); ++i) { if (!strcmp (int_unnop [i].op_name, name)) { g_assert (int_unnop [i].op_table [type_index]); MONO_INST_NEW (cfg, ins, int_unnop [i].op_table [type_index]); ins->dreg = alloc_dreg (cfg, stack_type); ins->sreg1 = args [0]->dreg; ins->type = stack_type; MONO_ADD_INS (cfg->cbb, ins); return ins; } } for (i = 0; i < sizeof (int_cmpop) / sizeof (IntIntrisic); ++i) { if (!strcmp (int_cmpop [i].op_name, name)) { g_assert (int_cmpop [i].op_table [type_index]); if (info->compare_op) { MONO_INST_NEW (cfg, ins, info->compare_op); ins->dreg = -1; ins->sreg1 = args [0]->dreg; ins->sreg2 = args [1]->dreg; MONO_ADD_INS (cfg->cbb, ins); MONO_INST_NEW (cfg, ins, int_cmpop [i].op_table [type_index]); ins->dreg = alloc_preg (cfg); ins->type = STACK_I4; MONO_ADD_INS (cfg->cbb, ins); } else { MONO_INST_NEW (cfg, ins, int_cmpop [i].op_table [type_index]); ins->dreg = alloc_ireg (cfg); ins->sreg1 = args [0]->dreg; ins->sreg2 = args [1]->dreg; MONO_ADD_INS (cfg->cbb, ins); } return ins; } } return NULL; } MonoInst* mono_emit_native_types_intrinsics (MonoCompile *cfg, MonoMethod *cmethod, MonoMethodSignature *fsig, MonoInst **args) { if (mono_class_is_magic_int (cmethod->klass)) { const char *class_name = cmethod->klass->name; if (!strcmp ("nint", class_name)) return emit_intrinsics (cfg, cmethod, fsig, args, &type_info [0]); else return emit_intrinsics (cfg, cmethod, fsig, args, &type_info [1]); } else if (mono_class_is_magic_float (cmethod->klass)) return emit_intrinsics (cfg, cmethod, fsig, args, &type_info [2]); return NULL; } #endif /* !DISABLE_JIT */ static inline gboolean mono_class_is_magic_assembly (MonoClass *klass) { if (!klass->image->assembly_name) return FALSE; if (!strcmp ("Xamarin.iOS", klass->image->assembly_name)) return TRUE; if (!strcmp ("Xamarin.Mac", klass->image->assembly_name)) return TRUE; if (!strcmp ("Xamarin.WatchOS", klass->image->assembly_name)) return TRUE; /* regression test suite */ if (!strcmp ("builtin-types", klass->image->assembly_name)) return TRUE; if (!strcmp ("mini_tests", klass->image->assembly_name)) return TRUE; return FALSE; } gboolean mono_class_is_magic_int (MonoClass *klass) { static MonoClass *magic_nint_class; static MonoClass *magic_nuint_class; if (klass == magic_nint_class) return TRUE; if (klass == magic_nuint_class) return TRUE; if (magic_nint_class && magic_nuint_class) return FALSE; if (!mono_class_is_magic_assembly (klass)) return FALSE; if (strcmp ("System", klass->name_space) != 0) return FALSE; if (strcmp ("nint", klass->name) == 0) { magic_nint_class = klass; return TRUE; } if (strcmp ("nuint", klass->name) == 0){ magic_nuint_class = klass; return TRUE; } return FALSE; } gboolean mono_class_is_magic_float (MonoClass *klass) { static MonoClass *magic_nfloat_class; if (klass == magic_nfloat_class) return TRUE; if (magic_nfloat_class) return FALSE; if (!mono_class_is_magic_assembly (klass)) return FALSE; if (strcmp ("System", klass->name_space) != 0) return FALSE; if (strcmp ("nfloat", klass->name) == 0) { magic_nfloat_class = klass; /* Assert that we are using the matching assembly */ MonoClassField *value_field = mono_class_get_field_from_name (klass, "v"); g_assert (value_field); MonoType *t = mono_field_get_type (value_field); MonoType *native = mini_native_type_replace_type (&klass->byval_arg); if (t->type != native->type) g_error ("Assembly used for native types '%s' doesn't match this runtime, %s is mapped to %s, expecting %s.\n", klass->image->name, klass->name, mono_type_full_name (t), mono_type_full_name (native)); return TRUE; } return FALSE; } static gboolean is_int_type (MonoType *t) { if (t->type != MONO_TYPE_I4 && t->type != MONO_TYPE_I8 && t->type != MONO_TYPE_U4 && t->type != MONO_TYPE_U8 && !mono_class_is_magic_int (mono_class_from_mono_type (t))) return FALSE; return TRUE; } static gboolean is_float_type (MonoType *t) { if (t->type != MONO_TYPE_R4 && t->type != MONO_TYPE_R8 && !mono_class_is_magic_float (mono_class_from_mono_type (t))) return FALSE; return TRUE; } MonoType* mini_native_type_replace_type (MonoType *type) { MonoClass *klass; if (type->type != MONO_TYPE_VALUETYPE) return type; klass = type->data.klass; if (mono_class_is_magic_int (klass)) return type->byref ? &mono_defaults.int_class->this_arg : &mono_defaults.int_class->byval_arg; if (mono_class_is_magic_float (klass)) #if SIZEOF_VOID_P == 8 return type->byref ? &mono_defaults.double_class->this_arg : &mono_defaults.double_class->byval_arg; #else return type->byref ? &mono_defaults.single_class->this_arg : &mono_defaults.single_class->byval_arg; #endif return type; }