ppc64

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Published: Jan 9, 2024 License: BSD-3-Clause Imports: 12 Imported by: 0

Documentation

Overview

Package ppc64 implements a PPC64 assembler that assembles Go asm into the corresponding PPC64 instructions as defined by the Power ISA 3.0B.

This document provides information on how to write code in Go assembler for PPC64, focusing on the differences between Go and PPC64 assembly language. It assumes some knowledge of PPC64 assembler. The original implementation of PPC64 in Go defined many opcodes that are different from PPC64 opcodes, but updates to the Go assembly language used mnemonics that are mostly similar if not identical to the PPC64 mneumonics, such as VMX and VSX instructions. Not all detail is included here; refer to the Power ISA document if interested in more detail.

Starting with Go 1.15 the Go objdump supports the -gnu option, which provides a side by side view of the Go assembler and the PPC64 assembler output. This is extremely helpful in determining what final PPC64 assembly is generated from the corresponding Go assembly.

In the examples below, the Go assembly is on the left, PPC64 assembly on the right.

1. Operand ordering

In Go asm, the last operand (right) is the target operand, but with PPC64 asm, the first operand (left) is the target. The order of the remaining operands is not consistent: in general opcodes with 3 operands that perform math or logical operations have their operands in reverse order. Opcodes for vector instructions and those with more than 3 operands usually have operands in the same order except for the target operand, which is first in PPC64 asm and last in Go asm.

Example:

ADD R3, R4, R5		<=>	add r5, r4, r3

2. Constant operands

In Go asm, an operand that starts with '$' indicates a constant value. If the instruction using the constant has an immediate version of the opcode, then an immediate value is used with the opcode if possible.

Example:

ADD $1, R3, R4		<=> 	addi r4, r3, 1

3. Opcodes setting condition codes

In PPC64 asm, some instructions other than compares have variations that can set the condition code where meaningful. This is indicated by adding '.' to the end of the PPC64 instruction. In Go asm, these instructions have 'CC' at the end of the opcode. The possible settings of the condition code depend on the instruction. CR0 is the default for fixed-point instructions; CR1 for floating point; CR6 for vector instructions.

Example:

ANDCC R3, R4, R5		<=>	and. r5, r3, r4 (set CR0)

4. Loads and stores from memory

In Go asm, opcodes starting with 'MOV' indicate a load or store. When the target is a memory reference, then it is a store; when the target is a register and the source is a memory reference, then it is a load.

MOV{B,H,W,D} variations identify the size as byte, halfword, word, doubleword.

Adding 'Z' to the opcode for a load indicates zero extend; if omitted it is sign extend. Adding 'U' to a load or store indicates an update of the base register with the offset. Adding 'BR' to an opcode indicates byte-reversed load or store, or the order opposite of the expected endian order. If 'BR' is used then zero extend is assumed.

Memory references n(Ra) indicate the address in Ra + n. When used with an update form of an opcode, the value in Ra is incremented by n.

Memory references (Ra+Rb) or (Ra)(Rb) indicate the address Ra + Rb, used by indexed loads or stores. Both forms are accepted. When used with an update then the base register is updated by the value in the index register.

Examples:

MOVD (R3), R4		<=>	ld r4,0(r3)
MOVW (R3), R4		<=>	lwa r4,0(r3)
MOVWZU 4(R3), R4		<=>	lwzu r4,4(r3)
MOVWZ (R3+R5), R4		<=>	lwzx r4,r3,r5
MOVHZ  (R3), R4		<=>	lhz r4,0(r3)
MOVHU 2(R3), R4		<=>	lhau r4,2(r3)
MOVBZ (R3), R4		<=>	lbz r4,0(r3)

MOVD R4,(R3)		<=>	std r4,0(r3)
MOVW R4,(R3)		<=>	stw r4,0(r3)
MOVW R4,(R3+R5)		<=>	stwx r4,r3,r5
MOVWU R4,4(R3)		<=>	stwu r4,4(r3)
MOVH R4,2(R3)		<=>	sth r4,2(r3)
MOVBU R4,(R3)(R5)		<=>	stbux r4,r3,r5

4. Compares

When an instruction does a compare or other operation that might result in a condition code, then the resulting condition is set in a field of the condition register. The condition register consists of 8 4-bit fields named CR0 - CR7. When a compare instruction identifies a CR then the resulting condition is set in that field to be read by a later branch or isel instruction. Within these fields, bits are set to indicate less than, greater than, or equal conditions.

Once an instruction sets a condition, then a subsequent branch, isel or other instruction can read the condition field and operate based on the bit settings.

Examples:

CMP R3, R4			<=>	cmp r3, r4	(CR0 assumed)
CMP R3, R4, CR1		<=>	cmp cr1, r3, r4

Note that the condition register is the target operand of compare opcodes, so the remaining operands are in the same order for Go asm and PPC64 asm. When CR0 is used then it is implicit and does not need to be specified.

5. Branches

Many branches are represented as a form of the BC instruction. There are other extended opcodes to make it easier to see what type of branch is being used.

The following is a brief description of the BC instruction and its commonly used operands.

BC op1, op2, op3

  op1: type of branch
      16 -> bctr (branch on ctr)
      12 -> bcr  (branch if cr bit is set)
      8  -> bcr+bctr (branch on ctr and cr values)
	4  -> bcr != 0 (branch if specified cr bit is not set)

	There are more combinations but these are the most common.

  op2: condition register field and condition bit

	This contains an immediate value indicating which condition field
	to read and what bits to test. Each field is 4 bits long with CR0
      at bit 0, CR1 at bit 4, etc. The value is computed as 4*CR+condition
      with these condition values:

      0 -> LT
      1 -> GT
      2 -> EQ
      3 -> OVG

	Thus 0 means test CR0 for LT, 5 means CR1 for GT, 30 means CR7 for EQ.

  op3: branch target

Examples:

BC 12, 0, target		<=>	blt cr0, target
BC 12, 2, target		<=>	beq cr0, target
BC 12, 5, target		<=>	bgt cr1, target
BC 12, 30, target		<=>	beq cr7, target
BC 4, 6, target		<=>	bne cr1, target
BC 4, 1, target		<=>	ble cr1, target

The following extended opcodes are available for ease of use and readability:

BNE CR2, target		<=>	bne cr2, target
BEQ CR4, target		<=>	beq cr4, target
BLT target			<=>	blt target (cr0 default)
BGE CR7, target		<=>	bge cr7, target

Refer to the ISA for more information on additional values for the BC instruction, how to handle OVG information, and much more.

5. Align directive

Starting with Go 1.12, Go asm supports the PCALIGN directive, which indicates that the next instruction should be aligned to the specified value. Currently 8 and 16 are the only supported values, and a maximum of 2 NOPs will be added to align the code. That means in the case where the code is aligned to 4 but PCALIGN $16 is at that location, the code will only be aligned to 8 to avoid adding 3 NOPs.

The purpose of this directive is to improve performance for cases like loops where better alignment (8 or 16 instead of 4) might be helpful. This directive exists in PPC64 assembler and is frequently used by PPC64 assembler writers.

PCALIGN $16 PCALIGN $8

By default, functions in Go are aligned to 16 bytes, as is the case in all other compilers for PPC64. If there is a PCALIGN directive requesting alignment greater than 16, then the alignment of the containing function must be promoted to that same alignment or greater.

The behavior of PCALIGN is changed in Go 1.21 to be more straightforward to ensure the alignment required for some instructions in power10. The acceptable values are 8, 16, 32 and 64, and the use of those values will always provide the specified alignment.

6. Shift instructions

The simple scalar shifts on PPC64 expect a shift count that fits in 5 bits for 32-bit values or 6 bit for 64-bit values. If the shift count is a constant value greater than the max then the assembler sets it to the max for that size (31 for 32 bit values, 63 for 64 bit values). If the shift count is in a register, then only the low 5 or 6 bits of the register will be used as the shift count. The Go compiler will add appropriate code to compare the shift value to achieve the correct result, and the assembler does not add extra checking.

Examples:

SRAD $8,R3,R4		=>	sradi r4,r3,8
SRD $8,R3,R4		=>	rldicl r4,r3,56,8
SLD $8,R3,R4		=>	rldicr r4,r3,8,55
SRAW $16,R4,R5		=>	srawi r5,r4,16
SRW $40,R4,R5		=>	rlwinm r5,r4,0,0,31
SLW $12,R4,R5		=>	rlwinm r5,r4,12,0,19

Some non-simple shifts have operands in the Go assembly which don't map directly onto operands in the PPC64 assembly. When an operand in a shift instruction in the Go assembly is a bit mask, that mask is represented as a start and end bit in the PPC64 assembly instead of a mask. See the ISA for more detail on these types of shifts. Here are a few examples:

RLWMI $7,R3,$65535,R6 	=>	rlwimi r6,r3,7,16,31
RLDMI $0,R4,$7,R6 		=>	rldimi r6,r4,0,61

More recently, Go opcodes were added which map directly onto the PPC64 opcodes. It is recommended to use the newer opcodes to avoid confusion.

RLDICL $0,R4,$15,R6		=>	rldicl r6,r4,0,15
RLDICR $0,R4,$15,R6		=>	rldicr r6.r4,0,15

Register naming

1. Special register usage in Go asm

The following registers should not be modified by user Go assembler code.

R0: Go code expects this register to contain the value 0.
R1: Stack pointer
R2: TOC pointer when compiled with -shared or -dynlink (a.k.a position independent code)
R13: TLS pointer
R30: g (goroutine)

Register names:

Rn is used for general purpose registers. (0-31)
Fn is used for floating point registers. (0-31)
Vn is used for vector registers. Slot 0 of Vn overlaps with Fn. (0-31)
VSn is used for vector-scalar registers. V0-V31 overlap with VS32-VS63. (0-63)
CTR represents the count register.
LR represents the link register.
CR represents the condition register
CRn represents a condition register field. (0-7)
CRnLT represents CR bit 0 of CR field n. (0-7)
CRnGT represents CR bit 1 of CR field n. (0-7)
CRnEQ represents CR bit 2 of CR field n. (0-7)
CRnSO represents CR bit 3 of CR field n. (0-7)

GOPPC64 >= power10 and its effects on Go asm

When GOPPC64=power10 is used to compile a Go program for ppc64le/linux, MOV*, FMOV*, and ADD opcodes which would require 2 or more machine instructions to emulate a 32 bit constant, or symbolic reference are implemented using prefixed instructions.

A user who wishes granular control over the generated machine code is advised to use Go asm opcodes which explicitly translate to one PPC64 machine instruction. Most common opcodes are supported.

Some examples of how pseudo-op assembly changes with GOPPC64:

Go asm                       GOPPC64 <= power9          GOPPC64 >= power10
MOVD mypackage·foo(SB), R3   addis r2, r3, ...          pld r3, ...
                             ld    r3, r3, ...

MOVD 131072(R3), R4          addis r31, r4, 2           pld r4, 131072(r3)
                             ld    r4, 0(R3)

ADD $131073, R3              lis  r31, 2                paddi r3, r3, 131073
                             addi r31, 1
                             add  r3,r31,r3

MOVD $131073, R3             lis  r3, 2                 pli r3, 131073
                             addi r3, 1

MOVD $mypackage·foo(SB), R3  addis r2, r3, ...          pla r3, ...
                             addi  r3, r3, ...

Index

Constants

View Source
const (
	NSNAME = 8
	NSYM   = 50
	NREG   = 32 /* number of general registers */
	NFREG  = 32 /* number of floating point registers */
)

* powerpc 64

View Source
const (
	/* RBasePPC64 = 4096 */
	/* R0=4096 ... R31=4127 */
	REG_R0 = obj.RBasePPC64 + iota
	REG_R1
	REG_R2
	REG_R3
	REG_R4
	REG_R5
	REG_R6
	REG_R7
	REG_R8
	REG_R9
	REG_R10
	REG_R11
	REG_R12
	REG_R13
	REG_R14
	REG_R15
	REG_R16
	REG_R17
	REG_R18
	REG_R19
	REG_R20
	REG_R21
	REG_R22
	REG_R23
	REG_R24
	REG_R25
	REG_R26
	REG_R27
	REG_R28
	REG_R29
	REG_R30
	REG_R31

	// CR bits. Use Book 1, chapter 2 naming for bits. Keep aligned to 32
	REG_CR0LT
	REG_CR0GT
	REG_CR0EQ
	REG_CR0SO
	REG_CR1LT
	REG_CR1GT
	REG_CR1EQ
	REG_CR1SO
	REG_CR2LT
	REG_CR2GT
	REG_CR2EQ
	REG_CR2SO
	REG_CR3LT
	REG_CR3GT
	REG_CR3EQ
	REG_CR3SO
	REG_CR4LT
	REG_CR4GT
	REG_CR4EQ
	REG_CR4SO
	REG_CR5LT
	REG_CR5GT
	REG_CR5EQ
	REG_CR5SO
	REG_CR6LT
	REG_CR6GT
	REG_CR6EQ
	REG_CR6SO
	REG_CR7LT
	REG_CR7GT
	REG_CR7EQ
	REG_CR7SO

	/* Align FPR and VSR vectors such that when masked with 0x3F they produce
	   an equivalent VSX register. */
	/* F0=4160 ... F31=4191 */
	REG_F0
	REG_F1
	REG_F2
	REG_F3
	REG_F4
	REG_F5
	REG_F6
	REG_F7
	REG_F8
	REG_F9
	REG_F10
	REG_F11
	REG_F12
	REG_F13
	REG_F14
	REG_F15
	REG_F16
	REG_F17
	REG_F18
	REG_F19
	REG_F20
	REG_F21
	REG_F22
	REG_F23
	REG_F24
	REG_F25
	REG_F26
	REG_F27
	REG_F28
	REG_F29
	REG_F30
	REG_F31

	/* V0=4192 ... V31=4223 */
	REG_V0
	REG_V1
	REG_V2
	REG_V3
	REG_V4
	REG_V5
	REG_V6
	REG_V7
	REG_V8
	REG_V9
	REG_V10
	REG_V11
	REG_V12
	REG_V13
	REG_V14
	REG_V15
	REG_V16
	REG_V17
	REG_V18
	REG_V19
	REG_V20
	REG_V21
	REG_V22
	REG_V23
	REG_V24
	REG_V25
	REG_V26
	REG_V27
	REG_V28
	REG_V29
	REG_V30
	REG_V31

	/* VS0=4224 ... VS63=4287 */
	REG_VS0
	REG_VS1
	REG_VS2
	REG_VS3
	REG_VS4
	REG_VS5
	REG_VS6
	REG_VS7
	REG_VS8
	REG_VS9
	REG_VS10
	REG_VS11
	REG_VS12
	REG_VS13
	REG_VS14
	REG_VS15
	REG_VS16
	REG_VS17
	REG_VS18
	REG_VS19
	REG_VS20
	REG_VS21
	REG_VS22
	REG_VS23
	REG_VS24
	REG_VS25
	REG_VS26
	REG_VS27
	REG_VS28
	REG_VS29
	REG_VS30
	REG_VS31
	REG_VS32
	REG_VS33
	REG_VS34
	REG_VS35
	REG_VS36
	REG_VS37
	REG_VS38
	REG_VS39
	REG_VS40
	REG_VS41
	REG_VS42
	REG_VS43
	REG_VS44
	REG_VS45
	REG_VS46
	REG_VS47
	REG_VS48
	REG_VS49
	REG_VS50
	REG_VS51
	REG_VS52
	REG_VS53
	REG_VS54
	REG_VS55
	REG_VS56
	REG_VS57
	REG_VS58
	REG_VS59
	REG_VS60
	REG_VS61
	REG_VS62
	REG_VS63

	REG_CR0
	REG_CR1
	REG_CR2
	REG_CR3
	REG_CR4
	REG_CR5
	REG_CR6
	REG_CR7

	// MMA accumulator registers, these shadow VSR 0-31
	// e.g MMAx shadows VSRx*4-VSRx*4+3 or
	//     MMA0 shadows VSR0-VSR3
	REG_A0
	REG_A1
	REG_A2
	REG_A3
	REG_A4
	REG_A5
	REG_A6
	REG_A7

	REG_MSR
	REG_FPSCR
	REG_CR

	REG_SPECIAL = REG_CR0

	REG_CRBIT0 = REG_CR0LT // An alias for a Condition Register bit 0

	REG_SPR0 = obj.RBasePPC64 + 1024 // first of 1024 registers

	REG_XER = REG_SPR0 + 1
	REG_LR  = REG_SPR0 + 8
	REG_CTR = REG_SPR0 + 9

	REGZERO = REG_R0 /* set to zero */
	REGSP   = REG_R1
	REGSB   = REG_R2
	REGRET  = REG_R3
	REGARG  = -1      /* -1 disables passing the first argument in register */
	REGRT1  = REG_R20 /* reserved for runtime, duffzero and duffcopy */
	REGRT2  = REG_R21 /* reserved for runtime, duffcopy */
	REGMIN  = REG_R7  /* register variables allocated from here to REGMAX */
	REGCTXT = REG_R11 /* context for closures */
	REGTLS  = REG_R13 /* C ABI TLS base pointer */
	REGMAX  = REG_R27
	REGEXT  = REG_R30 /* external registers allocated from here down */
	REGG    = REG_R30 /* G */
	REGTMP  = REG_R31 /* used by the linker */
	FREGRET = REG_F0
	FREGMIN = REG_F17 /* first register variable */
	FREGMAX = REG_F26 /* last register variable for 9g only */
	FREGEXT = REG_F26 /* first external register */
)
View Source
const (
	/* mark flags */
	LABEL    = 1 << 0
	LEAF     = 1 << 1
	FLOAT    = 1 << 2
	BRANCH   = 1 << 3
	LOAD     = 1 << 4
	FCMP     = 1 << 5
	SYNC     = 1 << 6
	LIST     = 1 << 7
	FOLL     = 1 << 8
	NOSCHED  = 1 << 9
	PFX_X64B = 1 << 10 // A prefixed instruction crossing a 64B boundary
)
View Source
const (
	BI_CR0 = 0
	BI_CR1 = 4
	BI_CR2 = 8
	BI_CR3 = 12
	BI_CR4 = 16
	BI_CR5 = 20
	BI_CR6 = 24
	BI_CR7 = 28
	BI_LT  = 0
	BI_GT  = 1
	BI_EQ  = 2
	BI_FU  = 3
)
View Source
const (
	BO_ALWAYS  = 20 // branch unconditionally
	BO_BCTR    = 16 // decrement ctr, branch on ctr != 0
	BO_NOTBCTR = 18 // decrement ctr, branch on ctr == 0
	BO_BCR     = 12 // branch on cr value
	BO_BCRBCTR = 8  // decrement ctr, branch on ctr != 0 and cr value
	BO_NOTBCR  = 4  // branch on not cr value
)
View Source
const (
	C_COND_LT = iota // 0 result is negative
	C_COND_GT        // 1 result is positive
	C_COND_EQ        // 2 result is zero
	C_COND_SO        // 3 summary overflow or FP compare w/ NaN
)
View Source
const (
	C_NONE     = iota
	C_REGP     /* An even numbered gpr which can be used a gpr pair argument */
	C_REG      /* Any gpr register */
	C_FREGP    /* An even numbered fpr which can be used a fpr pair argument */
	C_FREG     /* Any fpr register */
	C_VREG     /* Any vector register */
	C_VSREGP   /* An even numbered vsx register which can be used as a vsx register pair argument */
	C_VSREG    /* Any vector-scalar register */
	C_CREG     /* The condition registor (CR) */
	C_CRBIT    /* A single bit of the CR register (0-31) */
	C_SPR      /* special processor register */
	C_AREG     /* MMA accumulator register */
	C_ZCON     /* The constant zero */
	C_U1CON    /* 1 bit unsigned constant */
	C_U2CON    /* 2 bit unsigned constant */
	C_U3CON    /* 3 bit unsigned constant */
	C_U4CON    /* 4 bit unsigned constant */
	C_U5CON    /* 5 bit unsigned constant */
	C_U8CON    /* 8 bit unsigned constant */
	C_U15CON   /* 15 bit unsigned constant */
	C_S16CON   /* 16 bit signed constant */
	C_U16CON   /* 16 bit unsigned constant */
	C_32S16CON /* Any 32 bit constant of the form 0x....0000, signed or unsigned */
	C_32CON    /* Any constant which fits into 32 bits. Can be signed or unsigned */
	C_S34CON   /* 34 bit signed constant */
	C_64CON    /* Any constant which fits into 64 bits. Can be signed or unsigned */
	C_SACON    /* $n(REG) where n <= int16 */
	C_LACON    /* $n(REG) where n <= int32 */
	C_DACON    /* $n(REG) where n <= int64 */
	C_SBRA     /* A short offset argument to a branching instruction */
	C_LBRA     /* A long offset argument to a branching instruction */
	C_LBRAPIC  /* Like C_LBRA, but requires an extra NOP for potential TOC restore by the linker. */
	C_ZOREG    /* An $0+reg memory op */
	C_SOREG    /* An $n+reg memory arg where n is a 16 bit signed offset */
	C_LOREG    /* An $n+reg memory arg where n is a 32 bit signed offset */
	C_XOREG    /* An reg+reg memory arg */
	C_FPSCR    /* The fpscr register */
	C_XER      /* The xer, holds the carry bit */
	C_LR       /* The link register */
	C_CTR      /* The count register */
	C_ANY      /* Any argument */
	C_GOK      /* A non-matched argument */
	C_ADDR     /* A symbolic memory location */
	C_TLS_LE   /* A thread local, local-exec, type memory arg */
	C_TLS_IE   /* A thread local, initial-exec, type memory arg */
	C_TEXTSIZE /* An argument with Type obj.TYPE_TEXTSIZE */

	C_NCLASS /* must be the last */

	/* Aliased names which should be cleaned up, or integrated. */
	C_SCON   = C_U15CON
	C_UCON   = C_32S16CON
	C_ADDCON = C_S16CON
	C_ANDCON = C_U16CON
	C_LCON   = C_32CON

	/* Aliased names which may be generated by ppc64map for the optab. */
	C_S3216CON = C_32S16CON // TODO: these should be treated differently (e.g xoris vs addis)
	C_U3216CON = C_32S16CON
	C_S32CON   = C_32CON
	C_U32CON   = C_32CON
)
View Source
const (
	AADD = obj.ABasePPC64 + obj.A_ARCHSPECIFIC + iota
	AADDCC
	AADDIS
	AADDV
	AADDVCC
	AADDC
	AADDCCC
	AADDCV
	AADDCVCC
	AADDME
	AADDMECC
	AADDMEVCC
	AADDMEV
	AADDE
	AADDECC
	AADDEVCC
	AADDEV
	AADDZE
	AADDZECC
	AADDZEVCC
	AADDZEV
	AADDEX
	AAND
	AANDCC
	AANDN
	AANDNCC
	AANDISCC
	ABC
	ABCL
	ABEQ
	ABGE // not LT = G/E/U
	ABGT
	ABLE // not GT = L/E/U
	ABLT
	ABNE  // not EQ = L/G/U
	ABVC  // Branch if float not unordered (also branch on not summary overflow)
	ABVS  // Branch if float unordered (also branch on summary overflow)
	ABDNZ // Decrement CTR, and branch if CTR != 0
	ABDZ  // Decrement CTR, and branch if CTR == 0
	ACMP
	ACMPU
	ACMPEQB
	ACNTLZW
	ACNTLZWCC
	ACRAND
	ACRANDN
	ACREQV
	ACRNAND
	ACRNOR
	ACROR
	ACRORN
	ACRXOR
	ADIVW
	ADIVWCC
	ADIVWVCC
	ADIVWV
	ADIVWU
	ADIVWUCC
	ADIVWUVCC
	ADIVWUV
	AMODUD
	AMODUW
	AMODSD
	AMODSW
	AEQV
	AEQVCC
	AEXTSB
	AEXTSBCC
	AEXTSH
	AEXTSHCC
	AFABS
	AFABSCC
	AFADD
	AFADDCC
	AFADDS
	AFADDSCC
	AFCMPO
	AFCMPU
	AFCTIW
	AFCTIWCC
	AFCTIWZ
	AFCTIWZCC
	AFDIV
	AFDIVCC
	AFDIVS
	AFDIVSCC
	AFMADD
	AFMADDCC
	AFMADDS
	AFMADDSCC
	AFMOVD
	AFMOVDCC
	AFMOVDU
	AFMOVS
	AFMOVSU
	AFMOVSX
	AFMOVSZ
	AFMSUB
	AFMSUBCC
	AFMSUBS
	AFMSUBSCC
	AFMUL
	AFMULCC
	AFMULS
	AFMULSCC
	AFNABS
	AFNABSCC
	AFNEG
	AFNEGCC
	AFNMADD
	AFNMADDCC
	AFNMADDS
	AFNMADDSCC
	AFNMSUB
	AFNMSUBCC
	AFNMSUBS
	AFNMSUBSCC
	AFRSP
	AFRSPCC
	AFSUB
	AFSUBCC
	AFSUBS
	AFSUBSCC
	AISEL
	AMOVMW
	ALBAR
	ALHAR
	ALSW
	ALWAR
	ALWSYNC
	AMOVDBR
	AMOVWBR
	AMOVB
	AMOVBU
	AMOVBZ
	AMOVBZU
	AMOVH
	AMOVHBR
	AMOVHU
	AMOVHZ
	AMOVHZU
	AMOVW
	AMOVWU
	AMOVFL
	AMOVCRFS
	AMTFSB0
	AMTFSB0CC
	AMTFSB1
	AMTFSB1CC
	AMULHW
	AMULHWCC
	AMULHWU
	AMULHWUCC
	AMULLW
	AMULLWCC
	AMULLWVCC
	AMULLWV
	ANAND
	ANANDCC
	ANEG
	ANEGCC
	ANEGVCC
	ANEGV
	ANOR
	ANORCC
	AOR
	AORCC
	AORN
	AORNCC
	AORIS
	AREM
	AREMU
	ARFI
	ARLWMI
	ARLWMICC
	ARLWNM
	ARLWNMCC
	ACLRLSLWI
	ASLW
	ASLWCC
	ASRW
	ASRAW
	ASRAWCC
	ASRWCC
	ASTBCCC
	ASTHCCC
	ASTSW
	ASTWCCC
	ASUB
	ASUBCC
	ASUBVCC
	ASUBC
	ASUBCCC
	ASUBCV
	ASUBCVCC
	ASUBME
	ASUBMECC
	ASUBMEVCC
	ASUBMEV
	ASUBV
	ASUBE
	ASUBECC
	ASUBEV
	ASUBEVCC
	ASUBZE
	ASUBZECC
	ASUBZEVCC
	ASUBZEV
	ASYNC
	AXOR
	AXORCC
	AXORIS

	ADCBF
	ADCBI
	ADCBST
	ADCBT
	ADCBTST
	ADCBZ
	AEIEIO
	AICBI
	AISYNC
	APTESYNC
	ATLBIE
	ATLBIEL
	ATLBSYNC
	ATW

	ASYSCALL
	AWORD

	ARFCI

	AFCPSGN
	AFCPSGNCC
	/* optional on 32-bit */
	AFRES
	AFRESCC
	AFRIM
	AFRIMCC
	AFRIP
	AFRIPCC
	AFRIZ
	AFRIZCC
	AFRIN
	AFRINCC
	AFRSQRTE
	AFRSQRTECC
	AFSEL
	AFSELCC
	AFSQRT
	AFSQRTCC
	AFSQRTS
	AFSQRTSCC

	ACNTLZD
	ACNTLZDCC
	ACMPW /* CMP with L=0 */
	ACMPWU
	ACMPB
	AFTDIV
	AFTSQRT
	ADIVD
	ADIVDCC
	ADIVDE
	ADIVDECC
	ADIVDEU
	ADIVDEUCC
	ADIVDVCC
	ADIVDV
	ADIVDU
	ADIVDUCC
	ADIVDUVCC
	ADIVDUV
	AEXTSW
	AEXTSWCC
	/* AFCFIW; AFCFIWCC */
	AFCFID
	AFCFIDCC
	AFCFIDU
	AFCFIDUCC
	AFCFIDS
	AFCFIDSCC
	AFCTID
	AFCTIDCC
	AFCTIDZ
	AFCTIDZCC
	ALDAR
	AMOVD
	AMOVDU
	AMOVWZ
	AMOVWZU
	AMULHD
	AMULHDCC
	AMULHDU
	AMULHDUCC
	AMULLD
	AMULLDCC
	AMULLDVCC
	AMULLDV
	ARFID
	ARLDMI
	ARLDMICC
	ARLDIMI
	ARLDIMICC
	ARLDC
	ARLDCCC
	ARLDCR
	ARLDCRCC
	ARLDICR
	ARLDICRCC
	ARLDCL
	ARLDCLCC
	ARLDICL
	ARLDICLCC
	ARLDIC
	ARLDICCC
	ACLRLSLDI
	AROTL
	AROTLW
	ASLBIA
	ASLBIE
	ASLBMFEE
	ASLBMFEV
	ASLBMTE
	ASLD
	ASLDCC
	ASRD
	ASRAD
	ASRADCC
	ASRDCC
	AEXTSWSLI
	AEXTSWSLICC
	ASTDCCC
	ATD
	ASETB

	/* 64-bit pseudo operation */
	ADWORD
	AREMD
	AREMDU

	/* more 64-bit operations */
	AHRFID
	APOPCNTD
	APOPCNTW
	APOPCNTB
	ACNTTZW
	ACNTTZWCC
	ACNTTZD
	ACNTTZDCC
	ACOPY
	APASTECC
	ADARN
	AMADDHD
	AMADDHDU
	AMADDLD

	/* Vector */
	ALVEBX
	ALVEHX
	ALVEWX
	ALVX
	ALVXL
	ALVSL
	ALVSR
	ASTVEBX
	ASTVEHX
	ASTVEWX
	ASTVX
	ASTVXL
	AVAND
	AVANDC
	AVNAND
	AVOR
	AVORC
	AVNOR
	AVXOR
	AVEQV
	AVADDUM
	AVADDUBM
	AVADDUHM
	AVADDUWM
	AVADDUDM
	AVADDUQM
	AVADDCU
	AVADDCUQ
	AVADDCUW
	AVADDUS
	AVADDUBS
	AVADDUHS
	AVADDUWS
	AVADDSS
	AVADDSBS
	AVADDSHS
	AVADDSWS
	AVADDE
	AVADDEUQM
	AVADDECUQ
	AVSUBUM
	AVSUBUBM
	AVSUBUHM
	AVSUBUWM
	AVSUBUDM
	AVSUBUQM
	AVSUBCU
	AVSUBCUQ
	AVSUBCUW
	AVSUBUS
	AVSUBUBS
	AVSUBUHS
	AVSUBUWS
	AVSUBSS
	AVSUBSBS
	AVSUBSHS
	AVSUBSWS
	AVSUBE
	AVSUBEUQM
	AVSUBECUQ
	AVMULESB
	AVMULOSB
	AVMULEUB
	AVMULOUB
	AVMULESH
	AVMULOSH
	AVMULEUH
	AVMULOUH
	AVMULESW
	AVMULOSW
	AVMULEUW
	AVMULOUW
	AVMULUWM
	AVPMSUM
	AVPMSUMB
	AVPMSUMH
	AVPMSUMW
	AVPMSUMD
	AVMSUMUDM
	AVR
	AVRLB
	AVRLH
	AVRLW
	AVRLD
	AVS
	AVSLB
	AVSLH
	AVSLW
	AVSL
	AVSLO
	AVSRB
	AVSRH
	AVSRW
	AVSR
	AVSRO
	AVSLD
	AVSRD
	AVSA
	AVSRAB
	AVSRAH
	AVSRAW
	AVSRAD
	AVSOI
	AVSLDOI
	AVCLZ
	AVCLZB
	AVCLZH
	AVCLZW
	AVCLZD
	AVPOPCNT
	AVPOPCNTB
	AVPOPCNTH
	AVPOPCNTW
	AVPOPCNTD
	AVCMPEQ
	AVCMPEQUB
	AVCMPEQUBCC
	AVCMPEQUH
	AVCMPEQUHCC
	AVCMPEQUW
	AVCMPEQUWCC
	AVCMPEQUD
	AVCMPEQUDCC
	AVCMPGT
	AVCMPGTUB
	AVCMPGTUBCC
	AVCMPGTUH
	AVCMPGTUHCC
	AVCMPGTUW
	AVCMPGTUWCC
	AVCMPGTUD
	AVCMPGTUDCC
	AVCMPGTSB
	AVCMPGTSBCC
	AVCMPGTSH
	AVCMPGTSHCC
	AVCMPGTSW
	AVCMPGTSWCC
	AVCMPGTSD
	AVCMPGTSDCC
	AVCMPNEZB
	AVCMPNEZBCC
	AVCMPNEB
	AVCMPNEBCC
	AVCMPNEH
	AVCMPNEHCC
	AVCMPNEW
	AVCMPNEWCC
	AVPERM
	AVPERMXOR
	AVPERMR
	AVBPERMQ
	AVBPERMD
	AVSEL
	AVSPLTB
	AVSPLTH
	AVSPLTW
	AVSPLTISB
	AVSPLTISH
	AVSPLTISW
	AVCIPH
	AVCIPHER
	AVCIPHERLAST
	AVNCIPH
	AVNCIPHER
	AVNCIPHERLAST
	AVSBOX
	AVSHASIGMA
	AVSHASIGMAW
	AVSHASIGMAD
	AVMRGEW
	AVMRGOW
	AVCLZLSBB
	AVCTZLSBB

	/* VSX */
	ALXV
	ALXVL
	ALXVLL
	ALXVD2X
	ALXVW4X
	ALXVH8X
	ALXVB16X
	ALXVX
	ALXVDSX
	ASTXV
	ASTXVL
	ASTXVLL
	ASTXVD2X
	ASTXVW4X
	ASTXVH8X
	ASTXVB16X
	ASTXVX
	ALXSDX
	ASTXSDX
	ALXSIWAX
	ALXSIWZX
	ASTXSIWX
	AMFVSRD
	AMFFPRD
	AMFVRD
	AMFVSRWZ
	AMFVSRLD
	AMTVSRD
	AMTFPRD
	AMTVRD
	AMTVSRWA
	AMTVSRWZ
	AMTVSRDD
	AMTVSRWS
	AXXLAND
	AXXLANDC
	AXXLEQV
	AXXLNAND
	AXXLOR
	AXXLORC
	AXXLNOR
	AXXLORQ
	AXXLXOR
	AXXSEL
	AXXMRGHW
	AXXMRGLW
	AXXSPLTW
	AXXSPLTIB
	AXXPERM
	AXXPERMDI
	AXXSLDWI
	AXXBRQ
	AXXBRD
	AXXBRW
	AXXBRH
	AXSCVDPSP
	AXSCVSPDP
	AXSCVDPSPN
	AXSCVSPDPN
	AXVCVDPSP
	AXVCVSPDP
	AXSCVDPSXDS
	AXSCVDPSXWS
	AXSCVDPUXDS
	AXSCVDPUXWS
	AXSCVSXDDP
	AXSCVUXDDP
	AXSCVSXDSP
	AXSCVUXDSP
	AXVCVDPSXDS
	AXVCVDPSXWS
	AXVCVDPUXDS
	AXVCVDPUXWS
	AXVCVSPSXDS
	AXVCVSPSXWS
	AXVCVSPUXDS
	AXVCVSPUXWS
	AXVCVSXDDP
	AXVCVSXWDP
	AXVCVUXDDP
	AXVCVUXWDP
	AXVCVSXDSP
	AXVCVSXWSP
	AXVCVUXDSP
	AXVCVUXWSP
	ALASTAOUT // The last instruction in this list. Also the first opcode generated by ppc64map.

	// aliases
	ABR   = obj.AJMP
	ABL   = obj.ACALL
	ALAST = ALASTGEN // The final enumerated instruction value + 1. This is used to size the oprange table.
)
View Source
const (
	// R bit option in prefixed load/store/add D-form operations
	PFX_R_ABS   = 0 // Offset is absolute
	PFX_R_PCREL = 1 // Offset is relative to PC, RA should be 0
)
View Source
const (
	/* each rhs is OPVCC(_, _, _, _) */
	OP_ADD      = 31<<26 | 266<<1 | 0<<10 | 0
	OP_ADDI     = 14<<26 | 0<<1 | 0<<10 | 0
	OP_ADDIS    = 15<<26 | 0<<1 | 0<<10 | 0
	OP_ANDI     = 28<<26 | 0<<1 | 0<<10 | 0
	OP_EXTSB    = 31<<26 | 954<<1 | 0<<10 | 0
	OP_EXTSH    = 31<<26 | 922<<1 | 0<<10 | 0
	OP_EXTSW    = 31<<26 | 986<<1 | 0<<10 | 0
	OP_ISEL     = 31<<26 | 15<<1 | 0<<10 | 0
	OP_MCRF     = 19<<26 | 0<<1 | 0<<10 | 0
	OP_MCRFS    = 63<<26 | 64<<1 | 0<<10 | 0
	OP_MCRXR    = 31<<26 | 512<<1 | 0<<10 | 0
	OP_MFCR     = 31<<26 | 19<<1 | 0<<10 | 0
	OP_MFFS     = 63<<26 | 583<<1 | 0<<10 | 0
	OP_MFSPR    = 31<<26 | 339<<1 | 0<<10 | 0
	OP_MFSR     = 31<<26 | 595<<1 | 0<<10 | 0
	OP_MFSRIN   = 31<<26 | 659<<1 | 0<<10 | 0
	OP_MTCRF    = 31<<26 | 144<<1 | 0<<10 | 0
	OP_MTFSF    = 63<<26 | 711<<1 | 0<<10 | 0
	OP_MTFSFI   = 63<<26 | 134<<1 | 0<<10 | 0
	OP_MTSPR    = 31<<26 | 467<<1 | 0<<10 | 0
	OP_MTSR     = 31<<26 | 210<<1 | 0<<10 | 0
	OP_MTSRIN   = 31<<26 | 242<<1 | 0<<10 | 0
	OP_MULLW    = 31<<26 | 235<<1 | 0<<10 | 0
	OP_MULLD    = 31<<26 | 233<<1 | 0<<10 | 0
	OP_OR       = 31<<26 | 444<<1 | 0<<10 | 0
	OP_ORI      = 24<<26 | 0<<1 | 0<<10 | 0
	OP_ORIS     = 25<<26 | 0<<1 | 0<<10 | 0
	OP_RLWINM   = 21<<26 | 0<<1 | 0<<10 | 0
	OP_RLWNM    = 23<<26 | 0<<1 | 0<<10 | 0
	OP_SUBF     = 31<<26 | 40<<1 | 0<<10 | 0
	OP_RLDIC    = 30<<26 | 4<<1 | 0<<10 | 0
	OP_RLDICR   = 30<<26 | 2<<1 | 0<<10 | 0
	OP_RLDICL   = 30<<26 | 0<<1 | 0<<10 | 0
	OP_RLDCL    = 30<<26 | 8<<1 | 0<<10 | 0
	OP_EXTSWSLI = 31<<26 | 445<<2
	OP_SETB     = 31<<26 | 128<<1
)
View Source
const (
	D_FORM = iota
	DS_FORM
)
View Source
const (
	AXXSETACCZ = ALASTAOUT + iota
	AXXMTACC
	AXXMFACC
	AXXGENPCVWM
	AXXGENPCVHM
	AXXGENPCVDM
	AXXGENPCVBM
	AXVTLSBB
	AXVI8GER4SPP
	AXVI8GER4PP
	AXVI8GER4
	AXVI4GER8PP
	AXVI4GER8
	AXVI16GER2SPP
	AXVI16GER2S
	AXVI16GER2PP
	AXVI16GER2
	AXVF64GERPP
	AXVF64GERPN
	AXVF64GERNP
	AXVF64GERNN
	AXVF64GER
	AXVF32GERPP
	AXVF32GERPN
	AXVF32GERNP
	AXVF32GERNN
	AXVF32GER
	AXVF16GER2PP
	AXVF16GER2PN
	AXVF16GER2NP
	AXVF16GER2NN
	AXVF16GER2
	AXVCVSPBF16
	AXVCVBF16SPN
	AXVBF16GER2PP
	AXVBF16GER2PN
	AXVBF16GER2NP
	AXVBF16GER2NN
	AXVBF16GER2
	AXSMINCQP
	AXSMAXCQP
	AXSCVUQQP
	AXSCVSQQP
	AXSCVQPUQZ
	AXSCVQPSQZ
	AXSCMPGTQP
	AXSCMPGEQP
	AXSCMPEQQP
	AVSTRIHRCC
	AVSTRIHR
	AVSTRIHLCC
	AVSTRIHL
	AVSTRIBRCC
	AVSTRIBR
	AVSTRIBLCC
	AVSTRIBL
	AVSRQ
	AVSRDBI
	AVSRAQ
	AVSLQ
	AVSLDBI
	AVRLQNM
	AVRLQMI
	AVRLQ
	AVPEXTD
	AVPDEPD
	AVMULOUD
	AVMULOSD
	AVMULLD
	AVMULHUW
	AVMULHUD
	AVMULHSW
	AVMULHSD
	AVMULEUD
	AVMULESD
	AVMSUMCUD
	AVMODUW
	AVMODUQ
	AVMODUD
	AVMODSW
	AVMODSQ
	AVMODSD
	AVINSWVRX
	AVINSWVLX
	AVINSWRX
	AVINSWLX
	AVINSW
	AVINSHVRX
	AVINSHVLX
	AVINSHRX
	AVINSHLX
	AVINSDRX
	AVINSDLX
	AVINSD
	AVINSBVRX
	AVINSBVLX
	AVINSBRX
	AVINSBLX
	AVGNB
	AVEXTSD2Q
	AVEXTRACTWM
	AVEXTRACTQM
	AVEXTRACTHM
	AVEXTRACTDM
	AVEXTRACTBM
	AVEXTDUWVRX
	AVEXTDUWVLX
	AVEXTDUHVRX
	AVEXTDUHVLX
	AVEXTDUBVRX
	AVEXTDUBVLX
	AVEXTDDVRX
	AVEXTDDVLX
	AVEXPANDWM
	AVEXPANDQM
	AVEXPANDHM
	AVEXPANDDM
	AVEXPANDBM
	AVDIVUW
	AVDIVUQ
	AVDIVUD
	AVDIVSW
	AVDIVSQ
	AVDIVSD
	AVDIVEUW
	AVDIVEUQ
	AVDIVEUD
	AVDIVESW
	AVDIVESQ
	AVDIVESD
	AVCTZDM
	AVCNTMBW
	AVCNTMBH
	AVCNTMBD
	AVCNTMBB
	AVCMPUQ
	AVCMPSQ
	AVCMPGTUQCC
	AVCMPGTUQ
	AVCMPGTSQCC
	AVCMPGTSQ
	AVCMPEQUQCC
	AVCMPEQUQ
	AVCLZDM
	AVCLRRB
	AVCLRLB
	AVCFUGED
	ASTXVRWX
	ASTXVRHX
	ASTXVRDX
	ASTXVRBX
	ASTXVPX
	ASTXVP
	ASETNBCR
	ASETNBC
	ASETBCR
	ASETBC
	APEXTD
	APDEPD
	AMTVSRWM
	AMTVSRQM
	AMTVSRHM
	AMTVSRDM
	AMTVSRBMI
	AMTVSRBM
	ALXVRWX
	ALXVRHX
	ALXVRDX
	ALXVRBX
	ALXVPX
	ALXVP
	ALXVKQ
	ADCTFIXQQ
	ADCFFIXQQ
	ACNTTZDM
	ACNTLZDM
	ACFUGED
	ABRW
	ABRH
	ABRD
	AHASHSTP
	AHASHST
	AHASHCHKP
	AHASHCHK
	AXXSPLTIW
	AXXSPLTIDP
	AXXSPLTI32DX
	AXXPERMX
	AXXEVAL
	AXXBLENDVW
	AXXBLENDVH
	AXXBLENDVD
	AXXBLENDVB
	APSTXVP
	APSTXV
	APSTXSSP
	APSTXSD
	APSTW
	APSTQ
	APSTH
	APSTFS
	APSTFD
	APSTD
	APSTB
	APNOP
	APMXVI8GER4SPP
	APMXVI8GER4PP
	APMXVI8GER4
	APMXVI4GER8PP
	APMXVI4GER8
	APMXVI16GER2SPP
	APMXVI16GER2S
	APMXVI16GER2PP
	APMXVI16GER2
	APMXVF64GERPP
	APMXVF64GERPN
	APMXVF64GERNP
	APMXVF64GERNN
	APMXVF64GER
	APMXVF32GERPP
	APMXVF32GERPN
	APMXVF32GERNP
	APMXVF32GERNN
	APMXVF32GER
	APMXVF16GER2PP
	APMXVF16GER2PN
	APMXVF16GER2NP
	APMXVF16GER2NN
	APMXVF16GER2
	APMXVBF16GER2PP
	APMXVBF16GER2PN
	APMXVBF16GER2NP
	APMXVBF16GER2NN
	APMXVBF16GER2
	APLXVP
	APLXV
	APLXSSP
	APLXSD
	APLWZ
	APLWA
	APLQ
	APLHZ
	APLHA
	APLFS
	APLFD
	APLD
	APLBZ
	APADDI
	ALASTGEN
	AFIRSTGEN = AXXSETACCZ
)
View Source
const (
	BIG = 32768 - 8
)

* GENERAL: * * compiler allocates R3 up as temps * compiler allocates register variables R7-R27 * compiler allocates external registers R30 down * * compiler allocates register variables F17-F26 * compiler allocates external registers F26 down

Variables

View Source
var Anames = []string{}/* 606 elements not displayed */
View Source
var GenAnames = []string{}/* 248 elements not displayed */
View Source
var GenOpcodes = [...]uint32{}/* 248 elements not displayed */
View Source
var GenPfxOpcodes = [...]uint32{
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x05000000,
	0x04000000,
	0x04000000,
	0x04000000,
	0x04000000,
	0x06000000,
	0x04000000,
	0x06000000,
	0x06000000,
	0x06000000,
	0x04000000,
	0x06000000,
	0x07000000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x07900000,
	0x04000000,
	0x04000000,
	0x04000000,
	0x04000000,
	0x06000000,
	0x04000000,
	0x04000000,
	0x06000000,
	0x06000000,
	0x06000000,
	0x06000000,
	0x04000000,
	0x06000000,
	0x06000000,
}
View Source
var Linkppc64 = obj.LinkArch{
	Arch:           sys.ArchPPC64,
	Init:           buildop,
	Preprocess:     preprocess,
	Assemble:       span9,
	Progedit:       progedit,
	UnaryDst:       unaryDst,
	DWARFRegisters: PPC64DWARFRegisters,
}
View Source
var Linkppc64le = obj.LinkArch{
	Arch:           sys.ArchPPC64LE,
	Init:           buildop,
	Preprocess:     preprocess,
	Assemble:       span9,
	Progedit:       progedit,
	UnaryDst:       unaryDst,
	DWARFRegisters: PPC64DWARFRegisters,
}
View Source
var PPC64DWARFRegisters = map[int16]int16{}

OpenPOWER ABI for Linux Supplement Power Architecture 64-Bit ELF V2 ABI https://openpowerfoundation.org/?resource_lib=64-bit-elf-v2-abi-specification-power-architecture

Functions

func AOP_DQ

func AOP_DQ(op uint32, xt uint32, a uint32, b uint32) uint32

DQ-form, VSR register, register + offset operands

func AOP_EXTSWSLI

func AOP_EXTSWSLI(op uint32, a uint32, s uint32, sh uint32) uint32

func AOP_IIRR

func AOP_IIRR(op uint32, d uint32, a uint32, sbit uint32, simm uint32) uint32

VX-form 2-register + ST + SIX operands

func AOP_IR

func AOP_IR(op uint32, d uint32, simm uint32) uint32

VX-form 1-register + SIM operands

func AOP_IRR

func AOP_IRR(op uint32, d uint32, a uint32, simm uint32) uint32

func AOP_IRRR

func AOP_IRRR(op uint32, d uint32, a uint32, b uint32, simm uint32) uint32

VA-form 3-register + SHB operands

func AOP_ISEL

func AOP_ISEL(op uint32, t uint32, a uint32, b uint32, bc uint32) uint32

func AOP_PFX_00_8LS added in v1.21.0

func AOP_PFX_00_8LS(r, ie uint32) uint32

func AOP_PFX_10_MLS added in v1.21.0

func AOP_PFX_10_MLS(r, ie uint32) uint32

func AOP_RLDIC

func AOP_RLDIC(op uint32, a uint32, s uint32, sh uint32, m uint32) uint32

func AOP_RR

func AOP_RR(op uint32, d uint32, a uint32) uint32

VX-form 2-register operands, r/none/r

func AOP_RRR

func AOP_RRR(op uint32, d uint32, a uint32, b uint32) uint32

the order is dest, a/s, b/imm for both arithmetic and logical operations.

func AOP_RRRI

func AOP_RRRI(op uint32, d uint32, a uint32, b uint32, c uint32) uint32

X-form, 3-register operands + EH field

func AOP_RRRR

func AOP_RRRR(op uint32, d uint32, a uint32, b uint32, c uint32) uint32

VA-form 4-register operands

func AOP_VIRR

func AOP_VIRR(op uint32, d uint32, a uint32, simm uint32) uint32

VX-form 2-register + UIM operands

func AOP_XX1

func AOP_XX1(op uint32, r uint32, a uint32, b uint32) uint32

XX1-form 3-register operands, 1 VSR operand

func AOP_XX2

func AOP_XX2(op uint32, xt uint32, a uint32, xb uint32) uint32

XX2-form 3-register operands, 2 VSR operands

func AOP_XX3

func AOP_XX3(op uint32, xt uint32, xa uint32, xb uint32) uint32

XX3-form 3 VSR operands

func AOP_XX3I

func AOP_XX3I(op uint32, xt uint32, xa uint32, xb uint32, c uint32) uint32

XX3-form 3 VSR operands + immediate

func AOP_XX4

func AOP_XX4(op uint32, xt uint32, xa uint32, xb uint32, xc uint32) uint32

XX4-form, 4 VSR operands

func AOP_Z23I

func AOP_Z23I(op uint32, d uint32, a uint32, b uint32, c uint32) uint32

Z23-form, 3-register operands + CY field

func ConstantToCRbit added in v1.19.1

func ConstantToCRbit(c int64) (int16, bool)

func DRconv

func DRconv(a int) string

func LOP_IRR

func LOP_IRR(op uint32, a uint32, s uint32, uimm uint32) uint32

func LOP_RRR

func LOP_RRR(op uint32, a uint32, s uint32, b uint32) uint32

func NeedTOCpointer added in v1.21.0

func NeedTOCpointer(ctxt *obj.Link) bool

Determine if the build configuration requires a TOC pointer. It is assumed this always called after buildop.

func OPCC

func OPCC(o uint32, xo uint32, rc uint32) uint32

func OPDQ

func OPDQ(o uint32, xo uint32, oe uint32) uint32

func OPMD

func OPMD(o, xo, rc uint32) uint32

Generate MD-form opcode

func OPVC

func OPVC(o uint32, xo uint32, oe uint32, rc uint32) uint32

func OPVCC

func OPVCC(o uint32, xo uint32, oe uint32, rc uint32) uint32

func OPVX

func OPVX(o uint32, xo uint32, oe uint32, rc uint32) uint32

func OPVXX1

func OPVXX1(o uint32, xo uint32, oe uint32) uint32

func OPVXX2

func OPVXX2(o uint32, xo uint32, oe uint32) uint32

func OPVXX2VA

func OPVXX2VA(o uint32, xo uint32, oe uint32) uint32

func OPVXX3

func OPVXX3(o uint32, xo uint32, oe uint32) uint32

func OPVXX4

func OPVXX4(o uint32, xo uint32, oe uint32) uint32

func OP_BC

func OP_BC(op uint32, bo uint32, bi uint32, bd uint32, aa uint32) uint32

func OP_BCR

func OP_BCR(op uint32, bo uint32, bi uint32) uint32

func OP_BR

func OP_BR(op uint32, li uint32, aa uint32) uint32

func OP_RLW

func OP_RLW(op uint32, a uint32, s uint32, sh uint32, mb uint32, me uint32) uint32

Types

type Optab

type Optab struct {
	// contains filtered or unexported fields
}

type PrefixableOptab added in v1.21.0

type PrefixableOptab struct {
	Optab
	// contains filtered or unexported fields
}

These are opcodes above which may generate different sequences depending on whether prefix opcode support is available

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