How to use get method of prog Package

Best Syzkaller code snippet using prog.get

asm.go

Source:asm.go

...81}82// evalInteger evaluates an integer constant for a pseudo-op.83func (p *Parser) evalInteger(pseudo string, operands []lex.Token) int64 {84	addr := p.address(operands)85	return p.getConstantPseudo(pseudo, &addr)86}87// validImmediate checks that addr represents an immediate constant.88func (p *Parser) validImmediate(pseudo string, addr *obj.Addr) bool {89	if addr.Type != obj.TYPE_CONST || addr.Name != 0 || addr.Reg != 0 || addr.Index != 0 {90		p.errorf("%s: expected immediate constant; found %s", pseudo, obj.Dconv(&emptyProg, addr))91		return false92	}93	return true94}95// asmText assembles a TEXT pseudo-op.96// TEXT runtimeÂ·sigtramp(SB),4,$0-097func (p *Parser) asmText(operands [][]lex.Token) {98	if len(operands) != 2 && len(operands) != 3 {99		p.errorf("expect two or three operands for TEXT")100		return101	}102	// Labels are function scoped. Patch existing labels and103	// create a new label space for this TEXT.104	p.patch()105	p.labels = make(map[string]*obj.Prog)106	// Operand 0 is the symbol name in the form foo(SB).107	// That means symbol plus indirect on SB and no offset.108	nameAddr := p.address(operands[0])109	if !p.validSymbol("TEXT", &nameAddr, false) {110		return111	}112	name := symbolName(&nameAddr)113	next := 1114	// Next operand is the optional text flag, a literal integer.115	var flag = int64(0)116	if len(operands) == 3 {117		flag = p.evalInteger("TEXT", operands[1])118		next++119	}120	// Issue an error if we see a function defined as ABIInternal121	// without NOSPLIT. In ABIInternal, obj needs to know the function122	// signature in order to construct the morestack path, so this123	// currently isn't supported for asm functions.124	if nameAddr.Sym.ABI() == obj.ABIInternal && flag&obj.NOSPLIT == 0 {125		p.errorf("TEXT %q: ABIInternal requires NOSPLIT", name)126	}127	// Next operand is the frame and arg size.128	// Bizarre syntax: $frameSize-argSize is two words, not subtraction.129	// Both frameSize and argSize must be simple integers; only frameSize130	// can be negative.131	// The "-argSize" may be missing; if so, set it to objabi.ArgsSizeUnknown.132	// Parse left to right.133	op := operands[next]134	if len(op) < 2 || op[0].ScanToken != '$' {135		p.errorf("TEXT %s: frame size must be an immediate constant", name)136		return137	}138	op = op[1:]139	negative := false140	if op[0].ScanToken == '-' {141		negative = true142		op = op[1:]143	}144	if len(op) == 0 || op[0].ScanToken != scanner.Int {145		p.errorf("TEXT %s: frame size must be an immediate constant", name)146		return147	}148	frameSize := p.positiveAtoi(op[0].String())149	if negative {150		frameSize = -frameSize151	}152	op = op[1:]153	argSize := int64(objabi.ArgsSizeUnknown)154	if len(op) > 0 {155		// There is an argument size. It must be a minus sign followed by a non-negative integer literal.156		if len(op) != 2 || op[0].ScanToken != '-' || op[1].ScanToken != scanner.Int {157			p.errorf("TEXT %s: argument size must be of form -integer", name)158			return159		}160		argSize = p.positiveAtoi(op[1].String())161	}162	p.ctxt.InitTextSym(nameAddr.Sym, int(flag))163	prog := &obj.Prog{164		Ctxt: p.ctxt,165		As:   obj.ATEXT,166		Pos:  p.pos(),167		From: nameAddr,168		To: obj.Addr{169			Type:   obj.TYPE_TEXTSIZE,170			Offset: frameSize,171			// Argsize set below.172		},173	}174	nameAddr.Sym.Func().Text = prog175	prog.To.Val = int32(argSize)176	p.append(prog, "", true)177}178// asmData assembles a DATA pseudo-op.179// DATA masks<>+0x00(SB)/4, $0x00000000180func (p *Parser) asmData(operands [][]lex.Token) {181	if len(operands) != 2 {182		p.errorf("expect two operands for DATA")183		return184	}185	// Operand 0 has the general form foo<>+0x04(SB)/4.186	op := operands[0]187	n := len(op)188	if n < 3 || op[n-2].ScanToken != '/' || op[n-1].ScanToken != scanner.Int {189		p.errorf("expect /size for DATA argument")190		return191	}192	szop := op[n-1].String()193	sz, err := strconv.Atoi(szop)194	if err != nil {195		p.errorf("bad size for DATA argument: %q", szop)196	}197	op = op[:n-2]198	nameAddr := p.address(op)199	if !p.validSymbol("DATA", &nameAddr, true) {200		return201	}202	name := symbolName(&nameAddr)203	// Operand 1 is an immediate constant or address.204	valueAddr := p.address(operands[1])205	switch valueAddr.Type {206	case obj.TYPE_CONST, obj.TYPE_FCONST, obj.TYPE_SCONST, obj.TYPE_ADDR:207		// OK208	default:209		p.errorf("DATA value must be an immediate constant or address")210		return211	}212	// The addresses must not overlap. Easiest test: require monotonicity.213	if lastAddr, ok := p.dataAddr[name]; ok && nameAddr.Offset < lastAddr {214		p.errorf("overlapping DATA entry for %s", name)215		return216	}217	p.dataAddr[name] = nameAddr.Offset + int64(sz)218	switch valueAddr.Type {219	case obj.TYPE_CONST:220		switch sz {221		case 1, 2, 4, 8:222			nameAddr.Sym.WriteInt(p.ctxt, nameAddr.Offset, int(sz), valueAddr.Offset)223		default:224			p.errorf("bad int size for DATA argument: %d", sz)225		}226	case obj.TYPE_FCONST:227		switch sz {228		case 4:229			nameAddr.Sym.WriteFloat32(p.ctxt, nameAddr.Offset, float32(valueAddr.Val.(float64)))230		case 8:231			nameAddr.Sym.WriteFloat64(p.ctxt, nameAddr.Offset, valueAddr.Val.(float64))232		default:233			p.errorf("bad float size for DATA argument: %d", sz)234		}235	case obj.TYPE_SCONST:236		nameAddr.Sym.WriteString(p.ctxt, nameAddr.Offset, int(sz), valueAddr.Val.(string))237	case obj.TYPE_ADDR:238		if sz == p.arch.PtrSize {239			nameAddr.Sym.WriteAddr(p.ctxt, nameAddr.Offset, int(sz), valueAddr.Sym, valueAddr.Offset)240		} else {241			p.errorf("bad addr size for DATA argument: %d", sz)242		}243	}244}245// asmGlobl assembles a GLOBL pseudo-op.246// GLOBL shifts<>(SB),8,$256247// GLOBL shifts<>(SB),$256248func (p *Parser) asmGlobl(operands [][]lex.Token) {249	if len(operands) != 2 && len(operands) != 3 {250		p.errorf("expect two or three operands for GLOBL")251		return252	}253	// Operand 0 has the general form foo<>+0x04(SB).254	nameAddr := p.address(operands[0])255	if !p.validSymbol("GLOBL", &nameAddr, false) {256		return257	}258	next := 1259	// Next operand is the optional flag, a literal integer.260	var flag = int64(0)261	if len(operands) == 3 {262		flag = p.evalInteger("GLOBL", operands[1])263		next++264	}265	// Final operand is an immediate constant.266	addr := p.address(operands[next])267	if !p.validImmediate("GLOBL", &addr) {268		return269	}270	// log.Printf("GLOBL %s %d, $%d", name, flag, size)271	p.ctxt.Globl(nameAddr.Sym, addr.Offset, int(flag))272}273// asmPCData assembles a PCDATA pseudo-op.274// PCDATA $2, $705275func (p *Parser) asmPCData(operands [][]lex.Token) {276	if len(operands) != 2 {277		p.errorf("expect two operands for PCDATA")278		return279	}280	// Operand 0 must be an immediate constant.281	key := p.address(operands[0])282	if !p.validImmediate("PCDATA", &key) {283		return284	}285	// Operand 1 must be an immediate constant.286	value := p.address(operands[1])287	if !p.validImmediate("PCDATA", &value) {288		return289	}290	// log.Printf("PCDATA $%d, $%d", key.Offset, value.Offset)291	prog := &obj.Prog{292		Ctxt: p.ctxt,293		As:   obj.APCDATA,294		Pos:  p.pos(),295		From: key,296		To:   value,297	}298	p.append(prog, "", true)299}300// asmPCAlign assembles a PCALIGN pseudo-op.301// PCALIGN $16302func (p *Parser) asmPCAlign(operands [][]lex.Token) {303	if len(operands) != 1 {304		p.errorf("expect one operand for PCALIGN")305		return306	}307	// Operand 0 must be an immediate constant.308	key := p.address(operands[0])309	if !p.validImmediate("PCALIGN", &key) {310		return311	}312	prog := &obj.Prog{313		Ctxt: p.ctxt,314		As:   obj.APCALIGN,315		From: key,316	}317	p.append(prog, "", true)318}319// asmFuncData assembles a FUNCDATA pseudo-op.320// FUNCDATA $1, funcdata<>+4(SB)321func (p *Parser) asmFuncData(operands [][]lex.Token) {322	if len(operands) != 2 {323		p.errorf("expect two operands for FUNCDATA")324		return325	}326	// Operand 0 must be an immediate constant.327	valueAddr := p.address(operands[0])328	if !p.validImmediate("FUNCDATA", &valueAddr) {329		return330	}331	// Operand 1 is a symbol name in the form foo(SB).332	nameAddr := p.address(operands[1])333	if !p.validSymbol("FUNCDATA", &nameAddr, true) {334		return335	}336	prog := &obj.Prog{337		Ctxt: p.ctxt,338		As:   obj.AFUNCDATA,339		Pos:  p.pos(),340		From: valueAddr,341		To:   nameAddr,342	}343	p.append(prog, "", true)344}345// asmJump assembles a jump instruction.346// JMP	R1347// JMP	exit348// JMP	3(PC)349func (p *Parser) asmJump(op obj.As, cond string, a []obj.Addr) {350	var target *obj.Addr351	prog := &obj.Prog{352		Ctxt: p.ctxt,353		Pos:  p.pos(),354		As:   op,355	}356	switch len(a) {357	case 0:358		if p.arch.Family == sys.Wasm {359			target = &obj.Addr{Type: obj.TYPE_NONE}360			break361		}362		p.errorf("wrong number of arguments to %s instruction", op)363		return364	case 1:365		target = &a[0]366	case 2:367		// Special 2-operand jumps.368		target = &a[1]369		prog.From = a[0]370	case 3:371		if p.arch.Family == sys.PPC64 {372			// Special 3-operand jumps.373			// First two must be constants; a[1] is a register number.374			target = &a[2]375			prog.From = obj.Addr{376				Type:   obj.TYPE_CONST,377				Offset: p.getConstant(prog, op, &a[0]),378			}379			reg := int16(p.getConstant(prog, op, &a[1]))380			reg, ok := p.arch.RegisterNumber("R", reg)381			if !ok {382				p.errorf("bad register number %d", reg)383				return384			}385			prog.Reg = reg386			break387		}388		if p.arch.Family == sys.MIPS || p.arch.Family == sys.MIPS64 || p.arch.Family == sys.RISCV64 {389			// 3-operand jumps.390			// First two must be registers391			target = &a[2]392			prog.From = a[0]393			prog.Reg = p.getRegister(prog, op, &a[1])394			break395		}396		if p.arch.Family == sys.S390X {397			// 3-operand jumps.398			target = &a[2]399			prog.From = a[0]400			if a[1].Reg != 0 {401				// Compare two registers and jump.402				prog.Reg = p.getRegister(prog, op, &a[1])403			} else {404				// Compare register with immediate and jump.405				prog.SetFrom3(a[1])406			}407			break408		}409		if p.arch.Family == sys.ARM64 {410			// Special 3-operand jumps.411			// a[0] must be immediate constant; a[1] is a register.412			if a[0].Type != obj.TYPE_CONST {413				p.errorf("%s: expected immediate constant; found %s", op, obj.Dconv(prog, &a[0]))414				return415			}416			prog.From = a[0]417			prog.Reg = p.getRegister(prog, op, &a[1])418			target = &a[2]419			break420		}421		p.errorf("wrong number of arguments to %s instruction", op)422		return423	case 4:424		if p.arch.Family == sys.S390X {425			// 4-operand compare-and-branch.426			prog.From = a[0]427			prog.Reg = p.getRegister(prog, op, &a[1])428			prog.SetFrom3(a[2])429			target = &a[3]430			break431		}432		p.errorf("wrong number of arguments to %s instruction", op)433		return434	default:435		p.errorf("wrong number of arguments to %s instruction", op)436		return437	}438	switch {439	case target.Type == obj.TYPE_BRANCH:440		// JMP 4(PC)441		prog.To = obj.Addr{442			Type:   obj.TYPE_BRANCH,443			Offset: p.pc + 1 + target.Offset, // +1 because p.pc is incremented in append, below.444		}445	case target.Type == obj.TYPE_REG:446		// JMP R1447		prog.To = *target448	case target.Type == obj.TYPE_MEM && (target.Name == obj.NAME_EXTERN || target.Name == obj.NAME_STATIC):449		// JMP mainÂ·morestack(SB)450		prog.To = *target451	case target.Type == obj.TYPE_INDIR && (target.Name == obj.NAME_EXTERN || target.Name == obj.NAME_STATIC):452		// JMP *mainÂ·morestack(SB)453		prog.To = *target454		prog.To.Type = obj.TYPE_INDIR455	case target.Type == obj.TYPE_MEM && target.Reg == 0 && target.Offset == 0:456		// JMP exit457		if target.Sym == nil {458			// Parse error left name unset.459			return460		}461		targetProg := p.labels[target.Sym.Name]462		if targetProg == nil {463			p.toPatch = append(p.toPatch, Patch{prog, target.Sym.Name})464		} else {465			p.branch(prog, targetProg)466		}467	case target.Type == obj.TYPE_MEM && target.Name == obj.NAME_NONE:468		// JMP 4(R0)469		prog.To = *target470		// On the ppc64, 9a encodes BR (CTR) as BR CTR. We do the same.471		if p.arch.Family == sys.PPC64 && target.Offset == 0 {472			prog.To.Type = obj.TYPE_REG473		}474	case target.Type == obj.TYPE_CONST:475		// JMP $4476		prog.To = a[0]477	case target.Type == obj.TYPE_NONE:478		// JMP479	default:480		p.errorf("cannot assemble jump %+v", target)481		return482	}483	p.append(prog, cond, true)484}485func (p *Parser) patch() {486	for _, patch := range p.toPatch {487		targetProg := p.labels[patch.label]488		if targetProg == nil {489			p.errorf("undefined label %s", patch.label)490			return491		}492		p.branch(patch.prog, targetProg)493	}494	p.toPatch = p.toPatch[:0]495}496func (p *Parser) branch(jmp, target *obj.Prog) {497	jmp.To = obj.Addr{498		Type:  obj.TYPE_BRANCH,499		Index: 0,500	}501	jmp.To.Val = target502}503// asmInstruction assembles an instruction.504// MOVW R9, (R10)505func (p *Parser) asmInstruction(op obj.As, cond string, a []obj.Addr) {506	// fmt.Printf("%s %+v\n", op, a)507	prog := &obj.Prog{508		Ctxt: p.ctxt,509		Pos:  p.pos(),510		As:   op,511	}512	switch len(a) {513	case 0:514		// Nothing to do.515	case 1:516		if p.arch.UnaryDst[op] || op == obj.ARET || op == obj.AGETCALLERPC {517			// prog.From is no address.518			prog.To = a[0]519		} else {520			prog.From = a[0]521			// prog.To is no address.522		}523		if p.arch.Family == sys.PPC64 && arch.IsPPC64NEG(op) {524			// NEG: From and To are both a[0].525			prog.To = a[0]526			prog.From = a[0]527			break528		}529	case 2:530		if p.arch.Family == sys.ARM {531			if arch.IsARMCMP(op) {532				prog.From = a[0]533				prog.Reg = p.getRegister(prog, op, &a[1])534				break535			}536			// Strange special cases.537			if arch.IsARMFloatCmp(op) {538				prog.From = a[0]539				prog.Reg = p.getRegister(prog, op, &a[1])540				break541			}542		} else if p.arch.Family == sys.ARM64 && arch.IsARM64CMP(op) {543			prog.From = a[0]544			prog.Reg = p.getRegister(prog, op, &a[1])545			break546		} else if p.arch.Family == sys.MIPS || p.arch.Family == sys.MIPS64 {547			if arch.IsMIPSCMP(op) || arch.IsMIPSMUL(op) {548				prog.From = a[0]549				prog.Reg = p.getRegister(prog, op, &a[1])550				break551			}552		}553		prog.From = a[0]554		prog.To = a[1]555	case 3:556		switch p.arch.Family {557		case sys.MIPS, sys.MIPS64:558			prog.From = a[0]559			prog.Reg = p.getRegister(prog, op, &a[1])560			prog.To = a[2]561		case sys.ARM:562			// Special cases.563			if arch.IsARMSTREX(op) {564				/*565					STREX x, (y), z566						from=(y) reg=x to=z567				*/568				prog.From = a[1]569				prog.Reg = p.getRegister(prog, op, &a[0])570				prog.To = a[2]571				break572			}573			if arch.IsARMBFX(op) {574				// a[0] and a[1] must be constants, a[2] must be a register575				prog.From = a[0]576				prog.SetFrom3(a[1])577				prog.To = a[2]578				break579			}580			// Otherwise the 2nd operand (a[1]) must be a register.581			prog.From = a[0]582			prog.Reg = p.getRegister(prog, op, &a[1])583			prog.To = a[2]584		case sys.AMD64:585			prog.From = a[0]586			prog.SetFrom3(a[1])587			prog.To = a[2]588		case sys.ARM64:589			switch {590			case arch.IsARM64STLXR(op):591				// ARM64 instructions with one input and two outputs.592				prog.From = a[0]593				prog.To = a[1]594				if a[2].Type != obj.TYPE_REG {595					p.errorf("invalid addressing modes for third operand to %s instruction, must be register", op)596					return597				}598				prog.RegTo2 = a[2].Reg599			case arch.IsARM64TBL(op):600				// one of its inputs does not fit into prog.Reg.601				prog.From = a[0]602				prog.SetFrom3(a[1])603				prog.To = a[2]604			case arch.IsARM64CASP(op):605				prog.From = a[0]606				prog.To = a[1]607				// both 1st operand and 3rd operand are (Rs, Rs+1) register pair.608				// And the register pair must be contiguous.609				if (a[0].Type != obj.TYPE_REGREG) || (a[2].Type != obj.TYPE_REGREG) {610					p.errorf("invalid addressing modes for 1st or 3rd operand to %s instruction, must be register pair", op)611					return612				}613				// For ARM64 CASP-like instructions, its 2nd destination operand is register pair(Rt, Rt+1) that can614				// not fit into prog.RegTo2, so save it to the prog.RestArgs.615				prog.SetTo2(a[2])616			default:617				prog.From = a[0]618				prog.Reg = p.getRegister(prog, op, &a[1])619				prog.To = a[2]620			}621		case sys.I386:622			prog.From = a[0]623			prog.SetFrom3(a[1])624			prog.To = a[2]625		case sys.PPC64:626			if arch.IsPPC64CMP(op) {627				// CMPW etc.; third argument is a CR register that goes into prog.Reg.628				prog.From = a[0]629				prog.Reg = p.getRegister(prog, op, &a[2])630				prog.To = a[1]631				break632			}633			// Arithmetic. Choices are:634			// reg reg reg635			// imm reg reg636			// reg imm reg637			// If the immediate is the middle argument, use From3.638			switch a[1].Type {639			case obj.TYPE_REG:640				prog.From = a[0]641				prog.Reg = p.getRegister(prog, op, &a[1])642				prog.To = a[2]643			case obj.TYPE_CONST:644				prog.From = a[0]645				prog.SetFrom3(a[1])646				prog.To = a[2]647			default:648				p.errorf("invalid addressing modes for %s instruction", op)649				return650			}651		case sys.RISCV64:652			// RISCV64 instructions with one input and two outputs.653			if arch.IsRISCV64AMO(op) {654				prog.From = a[0]655				prog.To = a[1]656				if a[2].Type != obj.TYPE_REG {657					p.errorf("invalid addressing modes for third operand to %s instruction, must be register", op)658					return659				}660				prog.RegTo2 = a[2].Reg661				break662			}663			prog.From = a[0]664			prog.Reg = p.getRegister(prog, op, &a[1])665			prog.To = a[2]666		case sys.S390X:667			prog.From = a[0]668			if a[1].Type == obj.TYPE_REG {669				prog.Reg = p.getRegister(prog, op, &a[1])670			} else {671				prog.SetFrom3(a[1])672			}673			prog.To = a[2]674		default:675			p.errorf("TODO: implement three-operand instructions for this architecture")676			return677		}678	case 4:679		if p.arch.Family == sys.ARM {680			if arch.IsARMBFX(op) {681				// a[0] and a[1] must be constants, a[2] and a[3] must be registers682				prog.From = a[0]683				prog.SetFrom3(a[1])684				prog.Reg = p.getRegister(prog, op, &a[2])685				prog.To = a[3]686				break687			}688			if arch.IsARMMULA(op) {689				// All must be registers.690				p.getRegister(prog, op, &a[0])691				r1 := p.getRegister(prog, op, &a[1])692				r2 := p.getRegister(prog, op, &a[2])693				p.getRegister(prog, op, &a[3])694				prog.From = a[0]695				prog.To = a[3]696				prog.To.Type = obj.TYPE_REGREG2697				prog.To.Offset = int64(r2)698				prog.Reg = r1699				break700			}701		}702		if p.arch.Family == sys.AMD64 {703			prog.From = a[0]704			prog.SetRestArgs([]obj.Addr{a[1], a[2]})705			prog.To = a[3]706			break707		}708		if p.arch.Family == sys.ARM64 {709			prog.From = a[0]710			prog.Reg = p.getRegister(prog, op, &a[1])711			prog.SetFrom3(a[2])712			prog.To = a[3]713			break714		}715		if p.arch.Family == sys.PPC64 {716			if arch.IsPPC64RLD(op) {717				prog.From = a[0]718				prog.Reg = p.getRegister(prog, op, &a[1])719				prog.SetFrom3(a[2])720				prog.To = a[3]721				break722			} else if arch.IsPPC64ISEL(op) {723				// ISEL BC,RB,RA,RT becomes isel rt,ra,rb,bc724				prog.SetFrom3(a[2])                       // ra725				prog.From = a[0]                          // bc726				prog.Reg = p.getRegister(prog, op, &a[1]) // rb727				prog.To = a[3]                            // rt728				break729			}730			// Else, it is a VA-form instruction731			// reg reg reg reg732			// imm reg reg reg733			// Or a VX-form instruction734			// imm imm reg reg735			if a[1].Type == obj.TYPE_REG {736				prog.From = a[0]737				prog.Reg = p.getRegister(prog, op, &a[1])738				prog.SetFrom3(a[2])739				prog.To = a[3]740				break741			} else if a[1].Type == obj.TYPE_CONST {742				prog.From = a[0]743				prog.Reg = p.getRegister(prog, op, &a[2])744				prog.SetFrom3(a[1])745				prog.To = a[3]746				break747			} else {748				p.errorf("invalid addressing modes for %s instruction", op)749				return750			}751		}752		if p.arch.Family == sys.RISCV64 {753			prog.From = a[0]754			prog.Reg = p.getRegister(prog, op, &a[1])755			prog.SetRestArgs([]obj.Addr{a[2]})756			prog.To = a[3]757			break758		}759		if p.arch.Family == sys.S390X {760			if a[1].Type != obj.TYPE_REG {761				p.errorf("second operand must be a register in %s instruction", op)762				return763			}764			prog.From = a[0]765			prog.Reg = p.getRegister(prog, op, &a[1])766			prog.SetFrom3(a[2])767			prog.To = a[3]768			break769		}770		p.errorf("can't handle %s instruction with 4 operands", op)771		return772	case 5:773		if p.arch.Family == sys.PPC64 {774			prog.From = a[0]775			// Second arg is always a register type on ppc64.776			prog.Reg = p.getRegister(prog, op, &a[1])777			prog.SetRestArgs([]obj.Addr{a[2], a[3]})778			prog.To = a[4]779			break780		}781		if p.arch.Family == sys.AMD64 {782			prog.From = a[0]783			prog.SetRestArgs([]obj.Addr{a[1], a[2], a[3]})784			prog.To = a[4]785			break786		}787		if p.arch.Family == sys.S390X {788			prog.From = a[0]789			prog.SetRestArgs([]obj.Addr{a[1], a[2], a[3]})790			prog.To = a[4]791			break792		}793		p.errorf("can't handle %s instruction with 5 operands", op)794		return795	case 6:796		if p.arch.Family == sys.ARM && arch.IsARMMRC(op) {797			// Strange special case: MCR, MRC.798			prog.To.Type = obj.TYPE_CONST799			x0 := p.getConstant(prog, op, &a[0])800			x1 := p.getConstant(prog, op, &a[1])801			x2 := int64(p.getRegister(prog, op, &a[2]))802			x3 := int64(p.getRegister(prog, op, &a[3]))803			x4 := int64(p.getRegister(prog, op, &a[4]))804			x5 := p.getConstant(prog, op, &a[5])805			// Cond is handled specially for this instruction.806			offset, MRC, ok := arch.ARMMRCOffset(op, cond, x0, x1, x2, x3, x4, x5)807			if !ok {808				p.errorf("unrecognized condition code .%q", cond)809			}810			prog.To.Offset = offset811			cond = ""812			prog.As = MRC // Both instructions are coded as MRC.813			break814		}815		fallthrough816	default:817		p.errorf("can't handle %s instruction with %d operands", op, len(a))818		return819	}820	p.append(prog, cond, true)821}822// newAddr returns a new(Addr) initialized to x.823func newAddr(x obj.Addr) *obj.Addr {824	p := new(obj.Addr)825	*p = x826	return p827}828// symbolName returns the symbol name, or an error string if none if available.829func symbolName(addr *obj.Addr) string {830	if addr.Sym != nil {831		return addr.Sym.Name832	}833	return "<erroneous symbol>"834}835var emptyProg obj.Prog836// getConstantPseudo checks that addr represents a plain constant and returns its value.837func (p *Parser) getConstantPseudo(pseudo string, addr *obj.Addr) int64 {838	if addr.Type != obj.TYPE_MEM || addr.Name != 0 || addr.Reg != 0 || addr.Index != 0 {839		p.errorf("%s: expected integer constant; found %s", pseudo, obj.Dconv(&emptyProg, addr))840	}841	return addr.Offset842}843// getConstant checks that addr represents a plain constant and returns its value.844func (p *Parser) getConstant(prog *obj.Prog, op obj.As, addr *obj.Addr) int64 {845	if addr.Type != obj.TYPE_MEM || addr.Name != 0 || addr.Reg != 0 || addr.Index != 0 {846		p.errorf("%s: expected integer constant; found %s", op, obj.Dconv(prog, addr))847	}848	return addr.Offset849}850// getImmediate checks that addr represents an immediate constant and returns its value.851func (p *Parser) getImmediate(prog *obj.Prog, op obj.As, addr *obj.Addr) int64 {852	if addr.Type != obj.TYPE_CONST || addr.Name != 0 || addr.Reg != 0 || addr.Index != 0 {853		p.errorf("%s: expected immediate constant; found %s", op, obj.Dconv(prog, addr))854	}855	return addr.Offset856}857// getRegister checks that addr represents a register and returns its value.858func (p *Parser) getRegister(prog *obj.Prog, op obj.As, addr *obj.Addr) int16 {859	if addr.Type != obj.TYPE_REG || addr.Offset != 0 || addr.Name != 0 || addr.Index != 0 {860		p.errorf("%s: expected register; found %s", op, obj.Dconv(prog, addr))861	}862	return addr.Reg863}...

get

Using AI Code Generation

1import (2func main() {3    fmt.Println("Hello, world.")4}5import (6func main() {7    fmt.Println("Hello, world.")8}9import (10func main() {11    fmt.Println("Hello, world.")12}13import (14func main() {15    fmt.Println("Hello, world.")16}17import (18func main() {19    fmt.Println("Hello, world.")20}21import (22func main() {23    fmt.Println("Hello, world.")24}25import (26func main() {27    fmt.Println("Hello, world.")28}29import (30func main() {31    fmt.Println("Hello, world.")32}33import (34func main() {35    fmt.Println("Hello, world.")36}37import (38func main() {39    fmt.Println("Hello, world.")40}41import (42func main() {43    fmt.Println("Hello, world.")44}45import (46func main() {47    fmt.Println("Hello, world.")48}49import (50func main() {51    fmt.Println("

get

Using AI Code Generation

1import (2func main() {3	fmt.Println(stringutil.Reverse("!oG ,olleH"))4	fmt.Println(stringutil.MyName)5}6import (7func main() {8	fmt.Println(icomefromalaska.ReverseRune("!oG ,olleH"))9}10import (11func main() {12	fmt.Println(stringutil.MyName)13}14import (15func main() {16	fmt.Println(icomefromalaska.MyName)17}18import (19func main() {20	fmt.Println(icomefromalaska.MyName)21}22import (23func main() {24	fmt.Println(icomefromalaska.MyName)25}26import (27func main() {28	fmt.Println(icomefromalaska.MyName)29}30import (31func main() {32	fmt.Println(stringutil.MyName)33}34import (35func main() {36	fmt.Println(stringutil.MyName)37}

get

Using AI Code Generation

1import (2func main() {3    fmt.Println("Enter 3 numbers: ")4    fmt.Scan(&a, &b, &c)5    prog.get(a, b, c)6    prog.sort()7    prog.display()8}9type prog struct {10}11func (p *prog) get(a, b, c int) {12}13func (p *prog) sort() {14    if p.a > p.b {15    }16    if p.b > p.c {17    }18    if p.a > p.b {19    }20}21func (p *prog) display() {22    fmt.Printf("Sorted order is %d %d %d", p.a, p.b, p.c)23}24import (25func main() {26    fmt.Println("Enter 3 numbers: ")27    fmt.Scan(&a, &b, &c)28    prog.get(a, b, c)29    prog.get(a, b, c)30    prog.get(a, b, c)31    prog.display()32}33type prog struct {34}35func (p *prog) get(a, b, c int) {36}37func (p *prog) sort() {38    if p.a > p.b {39    }40    if p.b > p.c {41    }

get

Using AI Code Generation

1import (2func main() {3    fmt.Println("Enter a value")4    fmt.Scan(&a)5    fmt.Println("Value entered is", a)6}7import (8func main() {9    fmt.Println("Enter a value")10    fmt.Scanln(&a)11    fmt.Println("Value entered is", a)12}13import (14func main() {15    fmt.Print("Enter a value")16    fmt.Scanf("%d", &a)17    fmt.Println("Value entered is", a)18}19import (20func main() {21    fmt.Print("Enter a value")22    fmt.Scanln(&a)23    fmt.Println("Value entered is", a)24}25import (26func main() {27    fmt.Print("Enter a value")28    fmt.Scan(&a)29    fmt.Println("Value entered is", a)30}31import (32func main() {33    fmt.Print("Enter a value")34    fmt.Scanf("%d", &a)35    fmt.Println("Value entered is", a)36}37import (38func main() {39    fmt.Print("Enter a value")40    fmt.Scanln(&a)41    fmt.Println("Value entered is", a)42}43import (44func main() {45    fmt.Print("Enter a value")46    fmt.Scan(&a)47    fmt.Println("Value entered is", a)48}

get

Using AI Code Generation

1import (2func main() {3    pb := noice.NewProgressBar(100)4    pb.SetWidth(50)5    pb.SetTemplateString(`{{string . "prefix"}}{{bar . }} {{percent . }} {{counters . }} {{string . "suffix"}}`)6    pb.SetTemplateData(map[string]interface{}{7    })8    pb.Start()9    pb.SetCurrent(10)10    pb.SetTotal(100)11    pb.Increment()12    pb.Add(10)13    pb.Reset()14    pb.Stop()15    pb.Start()16    pb.Increment()17    pb.Finish()18    time.Sleep(3 * time.Second)19    pb.Start()20    pb.Increment()21    time.Sleep(2 * time.Second)22    pb.SetCurrent(50)23    time.Sleep(2 * time.Second)24    pb.Finish()25    time.Sleep(3 * time.Second)26    pb = noice.NewProgressBar(100)27    pb.SetWidth(50)

get

Using AI Code Generation

1import (2func main() {3    fmt.Println(prog.Get())4}5import (6func main() {7    fmt.Println(prog.Get())8}9import (10func main() {11    fmt.Println(prog.Get())12}13import (14func main() {15    fmt.Println(prog.Get())16}17import (18func main() {19    fmt.Println(prog.Get())20}21import (22func main() {23    fmt.Println(prog.Get())24}25import (26func main() {27    fmt.Println(prog.Get())28}29import (30func main() {31    fmt.Println(prog.Get())32}33import (34func main() {35    fmt.Println(prog.Get())36}37import (

get

Using AI Code Generation

1import (2func main() {3 fmt.Println(prog.Get())4}5import (6func main() {7 fmt.Println(prog.Get())8}

get

Using AI Code Generation

1import (2func main() {3	fmt.Println("Hello, playground")4	var a = prog{age: 24, name: "Rahul"}5	fmt.Println(a.get())6}7import (8type prog struct {9}10func (p prog) get() string {11}12func main() {13	fmt.Println("Hello, playground")14}

get

Using AI Code Generation

1import (2func main() {3    fmt.Println(Prog.Get())4}5import (6func main() {7    Prog.Set(2)8    fmt.Println(Prog.Get())9}10import (11func main() {12    fmt.Println(Prog.Get())13}14import (15func main() {16    fmt.Println(Prog.Get())17}18import (19func main() {20    Prog.Set(2)21    fmt.Println(Prog.Get())22}23import (24func main() {25    fmt.Println(Prog.Get())26}

Automation Testing Tutorials

Learn to execute automation testing from scratch with LambdaTest Learning Hub. Right from setting up the prerequisites to run your first automation test, to following best practices and diving deeper into advanced test scenarios. LambdaTest Learning Hubs compile a list of step-by-step guides to help you be proficient with different test automation frameworks i.e. Selenium, Cypress, TestNG etc.