llvm-6502/lib/Target/SystemZ/SystemZRegisterInfo.td

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//==- SystemZRegisterInfo.td - SystemZ register definitions -*- tablegen -*-==//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
// Class definitions.
//===----------------------------------------------------------------------===//
class SystemZReg<string n> : Register<n> {
let Namespace = "SystemZ";
}
class SystemZRegWithSubregs<string n, list<Register> subregs>
: RegisterWithSubRegs<n, subregs> {
let Namespace = "SystemZ";
}
let Namespace = "SystemZ" in {
def subreg_l32 : SubRegIndex<32, 0>; // Also acts as subreg_ll32.
def subreg_h32 : SubRegIndex<32, 32>; // Also acts as subreg_lh32.
def subreg_l64 : SubRegIndex<64, 0>;
def subreg_h64 : SubRegIndex<64, 64>;
def subreg_hh32 : ComposedSubRegIndex<subreg_h64, subreg_h32>;
def subreg_hl32 : ComposedSubRegIndex<subreg_h64, subreg_l32>;
}
// Define a register class that contains values of type TYPE and an
// associated operand called NAME. SIZE is the size and alignment
// of the registers and REGLIST is the list of individual registers.
multiclass SystemZRegClass<string name, ValueType type, int size, dag regList> {
def AsmOperand : AsmOperandClass {
let Name = name;
let ParserMethod = "parse"##name;
let RenderMethod = "addRegOperands";
}
def Bit : RegisterClass<"SystemZ", [type], size, regList> {
let Size = size;
}
def "" : RegisterOperand<!cast<RegisterClass>(name##"Bit")> {
let ParserMatchClass = !cast<AsmOperandClass>(name##"AsmOperand");
}
}
//===----------------------------------------------------------------------===//
// General-purpose registers
//===----------------------------------------------------------------------===//
// Lower 32 bits of one of the 16 64-bit general-purpose registers
class GPR32<bits<16> num, string n> : SystemZReg<n> {
let HWEncoding = num;
}
// One of the 16 64-bit general-purpose registers.
class GPR64<bits<16> num, string n, GPR32 low, GPR32 high>
: SystemZRegWithSubregs<n, [low, high]> {
let HWEncoding = num;
let SubRegIndices = [subreg_l32, subreg_h32];
}
// 8 even-odd pairs of GPR64s.
class GPR128<bits<16> num, string n, GPR64 low, GPR64 high>
: SystemZRegWithSubregs<n, [low, high]> {
let HWEncoding = num;
let SubRegIndices = [subreg_l64, subreg_h64];
}
// General-purpose registers
foreach I = 0-15 in {
def R#I#L : GPR32<I, "r"#I>;
def R#I#H : GPR32<I, "r"#I>;
def R#I#D : GPR64<I, "r"#I, !cast<GPR32>("R"#I#"L"), !cast<GPR32>("R"#I#"H")>,
DwarfRegNum<[I]>;
}
foreach I = [0, 2, 4, 6, 8, 10, 12, 14] in {
def R#I#Q : GPR128<I, "r"#I, !cast<GPR64>("R"#!add(I, 1)#"D"),
!cast<GPR64>("R"#I#"D")>;
}
/// Allocate the callee-saved R6-R13 backwards. That way they can be saved
/// together with R14 and R15 in one prolog instruction.
defm GR32 : SystemZRegClass<"GR32", i32, 32, (add (sequence "R%uL", 0, 5),
(sequence "R%uL", 15, 6))>;
defm GRH32 : SystemZRegClass<"GRH32", i32, 32, (add (sequence "R%uH", 0, 5),
(sequence "R%uH", 15, 6))>;
defm GR64 : SystemZRegClass<"GR64", i64, 64, (add (sequence "R%uD", 0, 5),
(sequence "R%uD", 15, 6))>;
// Combine the low and high GR32s into a single class. This can only be
// used for virtual registers if the high-word facility is available.
defm GRX32 : SystemZRegClass<"GRX32", i32, 32,
(add (sequence "R%uL", 0, 5),
(sequence "R%uH", 0, 5),
R15L, R15H, R14L, R14H, R13L, R13H,
R12L, R12H, R11L, R11H, R10L, R10H,
R9L, R9H, R8L, R8H, R7L, R7H, R6L, R6H)>;
// The architecture doesn't really have any i128 support, so model the
// register pairs as untyped instead.
defm GR128 : SystemZRegClass<"GR128", untyped, 128, (add R0Q, R2Q, R4Q,
R12Q, R10Q, R8Q, R6Q,
R14Q)>;
// Base and index registers. Everything except R0, which in an address
// context evaluates as 0.
defm ADDR32 : SystemZRegClass<"ADDR32", i32, 32, (sub GR32Bit, R0L)>;
defm ADDR64 : SystemZRegClass<"ADDR64", i64, 64, (sub GR64Bit, R0D)>;
// Not used directly, but needs to exist for ADDR32 and ADDR64 subregs
// of a GR128.
defm ADDR128 : SystemZRegClass<"ADDR128", untyped, 128, (sub GR128Bit, R0Q)>;
//===----------------------------------------------------------------------===//
// Floating-point registers
//===----------------------------------------------------------------------===//
// Lower 32 bits of one of the 16 64-bit floating-point registers
class FPR32<bits<16> num, string n> : SystemZReg<n> {
let HWEncoding = num;
}
// One of the 16 64-bit floating-point registers
class FPR64<bits<16> num, string n, FPR32 low>
: SystemZRegWithSubregs<n, [low]> {
let HWEncoding = num;
let SubRegIndices = [subreg_h32];
}
// 8 pairs of FPR64s, with a one-register gap inbetween.
class FPR128<bits<16> num, string n, FPR64 low, FPR64 high>
: SystemZRegWithSubregs<n, [low, high]> {
let HWEncoding = num;
let SubRegIndices = [subreg_l64, subreg_h64];
}
// Floating-point registers
foreach I = 0-15 in {
def F#I#S : FPR32<I, "f"#I>;
def F#I#D : FPR64<I, "f"#I, !cast<FPR32>("F"#I#"S")>,
DwarfRegNum<[!add(I, 16)]>;
}
foreach I = [0, 1, 4, 5, 8, 9, 12, 13] in {
def F#I#Q : FPR128<I, "f"#I, !cast<FPR64>("F"#!add(I, 2)#"D"),
!cast<FPR64>("F"#I#"D")>;
}
// There's no store-multiple instruction for FPRs, so we're not fussy
// about the order in which call-saved registers are allocated.
defm FP32 : SystemZRegClass<"FP32", f32, 32, (sequence "F%uS", 0, 15)>;
defm FP64 : SystemZRegClass<"FP64", f64, 64, (sequence "F%uD", 0, 15)>;
defm FP128 : SystemZRegClass<"FP128", f128, 128, (add F0Q, F1Q, F4Q, F5Q,
F8Q, F9Q, F12Q, F13Q)>;
//===----------------------------------------------------------------------===//
// Other registers
//===----------------------------------------------------------------------===//
// The 2-bit condition code field of the PSW. Every register named in an
// inline asm needs a class associated with it.
def CC : SystemZReg<"cc">;
def CCRegs : RegisterClass<"SystemZ", [i32], 32, (add CC)>;