// Copyright 2018 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package x86 import ( "cmd/internal/obj" "errors" "fmt" "strings" ) // evexBits stores EVEX prefix info that is used during instruction encoding. type evexBits struct { b1 byte // [W1mmLLpp] b2 byte // [NNNbbZRS] // Associated instruction opcode. opcode byte } // newEVEXBits creates evexBits object from enc bytes at z position. func newEVEXBits(z int, enc *opBytes) evexBits { return evexBits{ b1: enc[z+0], b2: enc[z+1], opcode: enc[z+2], } } // P returns EVEX.pp value. func (evex evexBits) P() byte { return (evex.b1 & evexP) >> 0 } // L returns EVEX.L'L value. func (evex evexBits) L() byte { return (evex.b1 & evexL) >> 2 } // M returns EVEX.mm value. func (evex evexBits) M() byte { return (evex.b1 & evexM) >> 4 } // W returns EVEX.W value. func (evex evexBits) W() byte { return (evex.b1 & evexW) >> 7 } // BroadcastEnabled reports whether BCST suffix is permitted. func (evex evexBits) BroadcastEnabled() bool { return evex.b2&evexBcst != 0 } // ZeroingEnabled reports whether Z suffix is permitted. func (evex evexBits) ZeroingEnabled() bool { return (evex.b2&evexZeroing)>>2 != 0 } // RoundingEnabled reports whether RN_SAE, RZ_SAE, RD_SAE and RU_SAE suffixes // are permitted. func (evex evexBits) RoundingEnabled() bool { return (evex.b2&evexRounding)>>1 != 0 } // SaeEnabled reports whether SAE suffix is permitted. func (evex evexBits) SaeEnabled() bool { return (evex.b2&evexSae)>>0 != 0 } // DispMultiplier returns displacement multiplier that is calculated // based on tuple type, EVEX.W and input size. // If embedded broadcast is used, bcst should be true. func (evex evexBits) DispMultiplier(bcst bool) int32 { if bcst { switch evex.b2 & evexBcst { case evexBcstN4: return 4 case evexBcstN8: return 8 } return 1 } switch evex.b2 & evexN { case evexN1: return 1 case evexN2: return 2 case evexN4: return 4 case evexN8: return 8 case evexN16: return 16 case evexN32: return 32 case evexN64: return 64 case evexN128: return 128 } return 1 } // EVEX is described by using 2-byte sequence. // See evexBits for more details. const ( evexW = 0x80 // b1[W... ....] evexWIG = 0 << 7 evexW0 = 0 << 7 evexW1 = 1 << 7 evexM = 0x30 // b2[..mm ...] evex0F = 1 << 4 evex0F38 = 2 << 4 evex0F3A = 3 << 4 evexL = 0x0C // b1[.... LL..] evexLIG = 0 << 2 evex128 = 0 << 2 evex256 = 1 << 2 evex512 = 2 << 2 evexP = 0x03 // b1[.... ..pp] evex66 = 1 << 0 evexF3 = 2 << 0 evexF2 = 3 << 0 // Precalculated Disp8 N value. // N acts like a multiplier for 8bit displacement. // Note that some N are not used, but their bits are reserved. evexN = 0xE0 // b2[NNN. ....] evexN1 = 0 << 5 evexN2 = 1 << 5 evexN4 = 2 << 5 evexN8 = 3 << 5 evexN16 = 4 << 5 evexN32 = 5 << 5 evexN64 = 6 << 5 evexN128 = 7 << 5 // Disp8 for broadcasts. evexBcst = 0x18 // b2[...b b...] evexBcstN4 = 1 << 3 evexBcstN8 = 2 << 3 // Flags that permit certain AVX512 features. // It's semantically illegal to combine evexZeroing and evexSae. evexZeroing = 0x4 // b2[.... .Z..] evexZeroingEnabled = 1 << 2 evexRounding = 0x2 // b2[.... ..R.] evexRoundingEnabled = 1 << 1 evexSae = 0x1 // b2[.... ...S] evexSaeEnabled = 1 << 0 ) // compressedDisp8 calculates EVEX compressed displacement, if applicable. func compressedDisp8(disp, elemSize int32) (disp8 byte, ok bool) { if disp%elemSize == 0 { v := disp / elemSize if v >= -128 && v <= 127 { return byte(v), true } } return 0, false } // evexZcase reports whether given Z-case belongs to EVEX group. func evexZcase(zcase uint8) bool { return zcase > Zevex_first && zcase < Zevex_last } // evexSuffixBits carries instruction EVEX suffix set flags. // // Examples: // "RU_SAE.Z" => {rounding: 3, zeroing: true} // "Z" => {zeroing: true} // "BCST" => {broadcast: true} // "SAE.Z" => {sae: true, zeroing: true} type evexSuffix struct { rounding byte sae bool zeroing bool broadcast bool } // Rounding control values. // Match exact value for EVEX.L'L field (with exception of rcUnset). const ( rcRNSAE = 0 // Round towards nearest rcRDSAE = 1 // Round towards -Inf rcRUSAE = 2 // Round towards +Inf rcRZSAE = 3 // Round towards zero rcUnset = 4 ) // newEVEXSuffix returns proper zero value for evexSuffix. func newEVEXSuffix() evexSuffix { return evexSuffix{rounding: rcUnset} } // evexSuffixMap maps obj.X86suffix to its decoded version. // Filled during init(). var evexSuffixMap [255]evexSuffix func init() { // Decode all valid suffixes for later use. for i := range opSuffixTable { suffix := newEVEXSuffix() parts := strings.Split(opSuffixTable[i], ".") for j := range parts { switch parts[j] { case "Z": suffix.zeroing = true case "BCST": suffix.broadcast = true case "SAE": suffix.sae = true case "RN_SAE": suffix.rounding = rcRNSAE case "RD_SAE": suffix.rounding = rcRDSAE case "RU_SAE": suffix.rounding = rcRUSAE case "RZ_SAE": suffix.rounding = rcRZSAE } } evexSuffixMap[i] = suffix } } // toDisp8 tries to convert disp to proper 8-bit displacement value. func toDisp8(disp int32, p *obj.Prog, asmbuf *AsmBuf) (disp8 byte, ok bool) { if asmbuf.evexflag { bcst := evexSuffixMap[p.Scond].broadcast elemSize := asmbuf.evex.DispMultiplier(bcst) return compressedDisp8(disp, elemSize) } return byte(disp), disp >= -128 && disp < 128 } // EncodeRegisterRange packs [reg0-reg1] list into 64-bit value that // is intended to be stored inside obj.Addr.Offset with TYPE_REGLIST. func EncodeRegisterRange(reg0, reg1 int16) int64 { return (int64(reg0) << 0) | (int64(reg1) << 16) | obj.RegListX86Lo } // decodeRegisterRange unpacks [reg0-reg1] list from 64-bit value created by EncodeRegisterRange. func decodeRegisterRange(list int64) (reg0, reg1 int) { return int((list >> 0) & 0xFFFF), int((list >> 16) & 0xFFFF) } // ParseSuffix handles the special suffix for the 386/AMD64. // Suffix bits are stored into p.Scond. // // Leading "." in cond is ignored. func ParseSuffix(p *obj.Prog, cond string) error { cond = strings.TrimPrefix(cond, ".") suffix := newOpSuffix(cond) if !suffix.IsValid() { return inferSuffixError(cond) } p.Scond = uint8(suffix) return nil } // inferSuffixError returns non-nil error that describes what could be // the cause of suffix parse failure. // // At the point this function is executed there is already assembly error, // so we can burn some clocks to construct good error message. // // Reported issues: // - duplicated suffixes // - illegal rounding/SAE+broadcast combinations // - unknown suffixes // - misplaced suffix (e.g. wrong Z suffix position) func inferSuffixError(cond string) error { suffixSet := make(map[string]bool) // Set for duplicates detection. unknownSet := make(map[string]bool) // Set of unknown suffixes. hasBcst := false hasRoundSae := false var msg []string // Error message parts suffixes := strings.Split(cond, ".") for i, suffix := range suffixes { switch suffix { case "Z": if i != len(suffixes)-1 { msg = append(msg, "Z suffix should be the last") } case "BCST": hasBcst = true case "SAE", "RN_SAE", "RZ_SAE", "RD_SAE", "RU_SAE": hasRoundSae = true default: if !unknownSet[suffix] { msg = append(msg, fmt.Sprintf("unknown suffix %q", suffix)) } unknownSet[suffix] = true } if suffixSet[suffix] { msg = append(msg, fmt.Sprintf("duplicate suffix %q", suffix)) } suffixSet[suffix] = true } if hasBcst && hasRoundSae { msg = append(msg, "can't combine rounding/SAE and broadcast") } if len(msg) == 0 { return errors.New("bad suffix combination") } return errors.New(strings.Join(msg, "; ")) } // opSuffixTable is a complete list of possible opcode suffix combinations. // It "maps" uint8 suffix bits to their string representation. // With the exception of first and last elements, order is not important. var opSuffixTable = [...]string{ "", // Map empty suffix to empty string. "Z", "SAE", "SAE.Z", "RN_SAE", "RZ_SAE", "RD_SAE", "RU_SAE", "RN_SAE.Z", "RZ_SAE.Z", "RD_SAE.Z", "RU_SAE.Z", "BCST", "BCST.Z", "", } // opSuffix represents instruction opcode suffix. // Compound (multi-part) suffixes expressed with single opSuffix value. // // uint8 type is used to fit obj.Prog.Scond. type opSuffix uint8 // badOpSuffix is used to represent all invalid suffix combinations. const badOpSuffix = opSuffix(len(opSuffixTable) - 1) // newOpSuffix returns opSuffix object that matches suffixes string. // // If no matching suffix is found, special "invalid" suffix is returned. // Use IsValid method to check against this case. func newOpSuffix(suffixes string) opSuffix { for i := range opSuffixTable { if opSuffixTable[i] == suffixes { return opSuffix(i) } } return badOpSuffix } // IsValid reports whether suffix is valid. // Empty suffixes are valid. func (suffix opSuffix) IsValid() bool { return suffix != badOpSuffix } // String returns suffix printed representation. // // It matches the string that was used to create suffix with NewX86Suffix() // for valid suffixes. // For all invalid suffixes, special marker is returned. func (suffix opSuffix) String() string { return opSuffixTable[suffix] }