llvm-6502/lib/Target/AArch64/AArch64CallingConv.td

//==-- AArch64CallingConv.td - Calling Conventions for ARM ----*- tblgen -*-==//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// This describes the calling conventions for AArch64 architecture.
//===----------------------------------------------------------------------===//


// The AArch64 Procedure Call Standard is unfortunately specified at a slightly
// higher level of abstraction than LLVM's target interface presents. In
// particular, it refers (like other ABIs, in fact) directly to
// structs. However, generic LLVM code takes the liberty of lowering structure
// arguments to the component fields before we see them.
//
// As a result, the obvious direct map from LLVM IR to PCS concepts can't be
// implemented, so the goals of this calling convention are, in decreasing
// priority order:
//     1. Expose *some* way to express the concepts required to implement the
//        generic PCS from a front-end.
//     2. Provide a sane ABI for pure LLVM.
//     3. Follow the generic PCS as closely as is naturally possible.
//
// The suggested front-end implementation of PCS features is:
//     * Integer, float and vector arguments of all sizes which end up in
//       registers are passed and returned via the natural LLVM type.
//     * Structure arguments with size <= 16 bytes are passed and returned in
//       registers as similar integer or composite types. For example:
//       [1 x i64], [2 x i64] or [1 x i128] (if alignment 16 needed).
//     * HFAs in registers follow rules similar to small structs: appropriate
//       composite types.
//     * Structure arguments with size > 16 bytes are passed via a pointer,
//       handled completely by the front-end.
//     * Structure return values > 16 bytes via an sret pointer argument.
//     * Other stack-based arguments (not large structs) are passed using byval
//       pointers. Padding arguments are added beforehand to guarantee a large
//       struct doesn't later use integer registers.
//
// N.b. this means that it is the front-end's responsibility (if it cares about
// PCS compliance) to check whether enough registers are available for an
// argument when deciding how to pass it.

class CCIfAlign<int Align, CCAction A>:
  CCIf<"ArgFlags.getOrigAlign() == " # Align, A>;

def CC_A64_APCS : CallingConv<[
  // SRet is an LLVM-specific concept, so it takes precedence over general ABI
  // concerns. However, this rule will be used by C/C++ frontends to implement
  // structure return.
  CCIfSRet<CCAssignToReg<[X8]>>,

  // Put ByVal arguments directly on the stack. Minimum size and alignment of a
  // slot is 64-bit.
  CCIfByVal<CCPassByVal<8, 8>>,

  // Canonicalise the various types that live in different floating-point
  // registers. This makes sense because the PCS does not distinguish Short
  // Vectors and Floating-point types.
  CCIfType<[v2i8], CCBitConvertToType<f16>>,
  CCIfType<[v4i8, v2i16], CCBitConvertToType<f32>>,
  CCIfType<[v8i8, v4i16, v2i32, v2f32], CCBitConvertToType<f64>>,
  CCIfType<[v16i8, v8i16, v4i32, v2i64, v4f32, v2f64],
           CCBitConvertToType<f128>>,

  // PCS: "C.1: If the argument is a Half-, Single-, Double- or Quad- precision
  // Floating-point or Short Vector Type and the NSRN is less than 8, then the
  // argument is allocated to the least significant bits of register
  // v[NSRN]. The NSRN is incremented by one. The argument has now been
  // allocated."
  CCIfType<[f16],  CCAssignToReg<[B0, B1, B2, B3, B4, B5, B6, B7]>>,
  CCIfType<[f32],  CCAssignToReg<[S0, S1, S2, S3, S4, S5, S6, S7]>>,
  CCIfType<[f64],  CCAssignToReg<[D0, D1, D2, D3, D4, D5, D6, D7]>>,
  CCIfType<[f128], CCAssignToReg<[Q0, Q1, Q2, Q3, Q4, Q5, Q6, Q7]>>,

  // PCS: "C.2: If the argument is an HFA and there are sufficient unallocated
  // SIMD and Floating-point registers (NSRN - number of elements < 8), then the
  // argument is allocated to SIMD and Floating-point registers (with one
  // register per element of the HFA). The NSRN is incremented by the number of
  // registers used. The argument has now been allocated."
  //
  // N.b. As above, this rule is the responsibility of the front-end.

  // "C.3: If the argument is an HFA then the NSRN is set to 8 and the size of
  // the argument is rounded up to the nearest multiple of 8 bytes."
  //
  // "C.4: If the argument is an HFA, a Quad-precision Floating-point or Short
  // Vector Type then the NSAA is rounded up to the larger of 8 or the Natural
  // Alignment of the Argument's type."
  //
  // It is expected that these will be satisfied by adding dummy arguments to
  // the prototype.

  // PCS: "C.5: If the argument is a Half- or Single- precision Floating-point
  // type then the size of the argument is set to 8 bytes. The effect is as if
  // the argument had been copied to the least significant bits of a 64-bit
  // register and the remaining bits filled with unspecified values."
  CCIfType<[f16, f32], CCPromoteToType<f64>>,

  // PCS: "C.6: If the argument is an HFA, a Half-, Single-, Double- or Quad-
  // precision Floating-point or Short Vector Type, then the argument is copied
  // to memory at the adjusted NSAA. The NSAA is incremented by the size of the
  // argument. The argument has now been allocated."
  CCIfType<[f64], CCAssignToStack<8, 8>>,
  CCIfType<[f128], CCAssignToStack<16, 16>>,

  // PCS: "C.7: If the argument is an Integral Type, the size of the argument is
  // less than or equal to 8 bytes and the NGRN is less than 8, the argument is
  // copied to the least significant bits of x[NGRN]. The NGRN is incremented by
  // one. The argument has now been allocated."

  // First we implement C.8 and C.9 (128-bit types get even registers). i128 is
  // represented as two i64s, the first one being split. If we delayed this
  // operation C.8 would never be reached.
  CCIfType<[i64],
        CCIfSplit<CCAssignToRegWithShadow<[X0, X2, X4, X6], [X0, X1, X3, X5]>>>,

  // Note: the promotion also implements C.14.
  CCIfType<[i8, i16, i32], CCPromoteToType<i64>>,

  // And now the real implementation of C.7
  CCIfType<[i64], CCAssignToReg<[X0, X1, X2, X3, X4, X5, X6, X7]>>,

  // PCS: "C.8: If the argument has an alignment of 16 then the NGRN is rounded
  // up to the next even number."
  //
  // "C.9: If the argument is an Integral Type, the size of the argument is
  // equal to 16 and the NGRN is less than 7, the argument is copied to x[NGRN]
  // and x[NGRN+1], x[NGRN] shall contain the lower addressed double-word of the
  // memory representation of the argument. The NGRN is incremented by two. The
  // argument has now been allocated."
  //
  // Subtlety here: what if alignment is 16 but it is not an integral type? All
  // floating-point types have been allocated already, which leaves composite
  // types: this is why a front-end may need to produce i128 for a struct <= 16
  // bytes.

  // PCS: "C.10 If the argument is a Composite Type and the size in double-words
  // of the argument is not more than 8 minus NGRN, then the argument is copied
  // into consecutive general-purpose registers, starting at x[NGRN]. The
  // argument is passed as though it had been loaded into the registers from a
  // double-word aligned address with an appropriate sequence of LDR
  // instructions loading consecutive registers from memory (the contents of any
  // unused parts of the registers are unspecified by this standard). The NGRN
  // is incremented by the number of registers used. The argument has now been
  // allocated."
  //
  // Another one that's the responsibility of the front-end (sigh).

  // PCS: "C.11: The NGRN is set to 8."
  CCCustom<"CC_AArch64NoMoreRegs">,

  // PCS: "C.12: The NSAA is rounded up to the larger of 8 or the Natural
  // Alignment of the argument's type."
  //
  // PCS: "C.13: If the argument is a composite type then the argument is copied
  // to memory at the adjusted NSAA. The NSAA is by the size of the
  // argument. The argument has now been allocated."
  //
  // Note that the effect of this corresponds to a memcpy rather than register
  // stores so that the struct ends up correctly addressable at the adjusted
  // NSAA.

  // PCS: "C.14: If the size of the argument is less than 8 bytes then the size
  // of the argument is set to 8 bytes. The effect is as if the argument was
  // copied to the least significant bits of a 64-bit register and the remaining
  // bits filled with unspecified values."
  //
  // Integer types were widened above. Floating-point and composite types have
  // already been allocated completely. Nothing to do.

  // PCS: "C.15: The argument is copied to memory at the adjusted NSAA. The NSAA
  // is incremented by the size of the argument. The argument has now been
  // allocated."
  CCIfType<[i64], CCIfSplit<CCAssignToStack<8, 16>>>,
  CCIfType<[i64], CCAssignToStack<8, 8>>

]>;

// According to the PCS, X19-X30 are callee-saved, however only the low 64-bits
// of vector registers (8-15) are callee-saved. The order here is is picked up
// by PrologEpilogInserter.cpp to allocate stack slots, starting from top of
// stack upon entry. This gives the customary layout of x30 at [sp-8], x29 at
// [sp-16], ...
def CSR_PCS : CalleeSavedRegs<(add (sequence "X%u", 30, 19),
                                   (sequence "D%u", 15, 8))>;


// TLS descriptor calls are extremely restricted in their changes, to allow
// optimisations in the (hopefully) more common fast path where no real action
// is needed. They actually have to preserve all registers, except for the
// unavoidable X30 and the return register X0.
def TLSDesc : CalleeSavedRegs<(add (sequence "X%u", 29, 1),
                                   (sequence "Q%u", 31, 0))>;
Add AArch64 as an experimental target. This patch adds support for AArch64 (ARM's 64-bit architecture) to LLVM in the "experimental" category. Currently, it won't be built unless requested explicitly. This initial commit should have support for: + Assembly of all scalar (i.e. non-NEON, non-Crypto) instructions (except the late addition CRC instructions). + CodeGen features required for C++03 and C99. + Compilation for the "small" memory model: code+static data < 4GB. + Absolute and position-independent code. + GNU-style (i.e. "__thread") TLS. + Debugging information. The principal omission, currently, is performance tuning. This patch excludes the NEON support also reviewed due to an outbreak of batshit insanity in our legal department. That will be committed soon bringing the changes to precisely what has been approved. Further reviews would be gratefully received. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@174054 91177308-0d34-0410-b5e6-96231b3b80d8 2013-01-31 12:12:40 +00:00			`//==-- AArch64CallingConv.td - Calling Conventions for ARM ----- tblgen --==//`
			`//`
			`// The LLVM Compiler Infrastructure`
			`//`
			`// This file is distributed under the University of Illinois Open Source`
			`// License. See LICENSE.TXT for details.`
			`//`
			`//===----------------------------------------------------------------------===//`
			`// This describes the calling conventions for AArch64 architecture.`
			`//===----------------------------------------------------------------------===//`


			`// The AArch64 Procedure Call Standard is unfortunately specified at a slightly`
			`// higher level of abstraction than LLVM's target interface presents. In`
			`// particular, it refers (like other ABIs, in fact) directly to`
			`// structs. However, generic LLVM code takes the liberty of lowering structure`
			`// arguments to the component fields before we see them.`
			`//`
			`// As a result, the obvious direct map from LLVM IR to PCS concepts can't be`
			`// implemented, so the goals of this calling convention are, in decreasing`
			`// priority order:`
			`// 1. Expose some way to express the concepts required to implement the`
			`// generic PCS from a front-end.`
			`// 2. Provide a sane ABI for pure LLVM.`
			`// 3. Follow the generic PCS as closely as is naturally possible.`
			`//`
			`// The suggested front-end implementation of PCS features is:`
			`// * Integer, float and vector arguments of all sizes which end up in`
			`// registers are passed and returned via the natural LLVM type.`
			`// * Structure arguments with size <= 16 bytes are passed and returned in`
			`// registers as similar integer or composite types. For example:`
			`// [1 x i64], [2 x i64] or [1 x i128] (if alignment 16 needed).`
			`// * HFAs in registers follow rules similar to small structs: appropriate`
			`// composite types.`
			`// * Structure arguments with size > 16 bytes are passed via a pointer,`
			`// handled completely by the front-end.`
			`// * Structure return values > 16 bytes via an sret pointer argument.`
			`// * Other stack-based arguments (not large structs) are passed using byval`
			`// pointers. Padding arguments are added beforehand to guarantee a large`
			`// struct doesn't later use integer registers.`
			`//`
			`// N.b. this means that it is the front-end's responsibility (if it cares about`
			`// PCS compliance) to check whether enough registers are available for an`
			`// argument when deciding how to pass it.`

			`class CCIfAlign<int Align, CCAction A>:`
			`CCIf<"ArgFlags.getOrigAlign() == " # Align, A>;`

			`def CC_A64_APCS : CallingConv<[`
			`// SRet is an LLVM-specific concept, so it takes precedence over general ABI`
			`// concerns. However, this rule will be used by C/C++ frontends to implement`
			`// structure return.`
			`CCIfSRet<CCAssignToReg<[X8]>>,`

			`// Put ByVal arguments directly on the stack. Minimum size and alignment of a`
			`// slot is 64-bit.`
			`CCIfByVal<CCPassByVal<8, 8>>,`

			`// Canonicalise the various types that live in different floating-point`
			`// registers. This makes sense because the PCS does not distinguish Short`
			`// Vectors and Floating-point types.`
			`CCIfType<[v2i8], CCBitConvertToType<f16>>,`
			`CCIfType<[v4i8, v2i16], CCBitConvertToType<f32>>,`
			`CCIfType<[v8i8, v4i16, v2i32, v2f32], CCBitConvertToType<f64>>,`
			`CCIfType<[v16i8, v8i16, v4i32, v2i64, v4f32, v2f64],`
			`CCBitConvertToType<f128>>,`

			`// PCS: "C.1: If the argument is a Half-, Single-, Double- or Quad- precision`
			`// Floating-point or Short Vector Type and the NSRN is less than 8, then the`
			`// argument is allocated to the least significant bits of register`
			`// v[NSRN]. The NSRN is incremented by one. The argument has now been`
			`// allocated."`
			`CCIfType<[f16], CCAssignToReg<[B0, B1, B2, B3, B4, B5, B6, B7]>>,`
			`CCIfType<[f32], CCAssignToReg<[S0, S1, S2, S3, S4, S5, S6, S7]>>,`
			`CCIfType<[f64], CCAssignToReg<[D0, D1, D2, D3, D4, D5, D6, D7]>>,`
			`CCIfType<[f128], CCAssignToReg<[Q0, Q1, Q2, Q3, Q4, Q5, Q6, Q7]>>,`

			`// PCS: "C.2: If the argument is an HFA and there are sufficient unallocated`
			`// SIMD and Floating-point registers (NSRN - number of elements < 8), then the`
			`// argument is allocated to SIMD and Floating-point registers (with one`
			`// register per element of the HFA). The NSRN is incremented by the number of`
			`// registers used. The argument has now been allocated."`
			`//`
			`// N.b. As above, this rule is the responsibility of the front-end.`

			`// "C.3: If the argument is an HFA then the NSRN is set to 8 and the size of`
			`// the argument is rounded up to the nearest multiple of 8 bytes."`
			`//`
			`// "C.4: If the argument is an HFA, a Quad-precision Floating-point or Short`
			`// Vector Type then the NSAA is rounded up to the larger of 8 or the Natural`
			`// Alignment of the Argument's type."`
			`//`
			`// It is expected that these will be satisfied by adding dummy arguments to`
			`// the prototype.`

			`// PCS: "C.5: If the argument is a Half- or Single- precision Floating-point`
			`// type then the size of the argument is set to 8 bytes. The effect is as if`
			`// the argument had been copied to the least significant bits of a 64-bit`
			`// register and the remaining bits filled with unspecified values."`
			`CCIfType<[f16, f32], CCPromoteToType<f64>>,`

			`// PCS: "C.6: If the argument is an HFA, a Half-, Single-, Double- or Quad-`
			`// precision Floating-point or Short Vector Type, then the argument is copied`
			`// to memory at the adjusted NSAA. The NSAA is incremented by the size of the`
			`// argument. The argument has now been allocated."`
			`CCIfType<[f64], CCAssignToStack<8, 8>>,`
			`CCIfType<[f128], CCAssignToStack<16, 16>>,`

			`// PCS: "C.7: If the argument is an Integral Type, the size of the argument is`
			`// less than or equal to 8 bytes and the NGRN is less than 8, the argument is`
			`// copied to the least significant bits of x[NGRN]. The NGRN is incremented by`
			`// one. The argument has now been allocated."`

			`// First we implement C.8 and C.9 (128-bit types get even registers). i128 is`
			`// represented as two i64s, the first one being split. If we delayed this`
			`// operation C.8 would never be reached.`
			`CCIfType<[i64],`
			`CCIfSplit<CCAssignToRegWithShadow<[X0, X2, X4, X6], [X0, X1, X3, X5]>>>,`

			`// Note: the promotion also implements C.14.`
			`CCIfType<[i8, i16, i32], CCPromoteToType<i64>>,`

			`// And now the real implementation of C.7`
			`CCIfType<[i64], CCAssignToReg<[X0, X1, X2, X3, X4, X5, X6, X7]>>,`

			`// PCS: "C.8: If the argument has an alignment of 16 then the NGRN is rounded`
			`// up to the next even number."`
			`//`
			`// "C.9: If the argument is an Integral Type, the size of the argument is`
			`// equal to 16 and the NGRN is less than 7, the argument is copied to x[NGRN]`
			`// and x[NGRN+1], x[NGRN] shall contain the lower addressed double-word of the`
			`// memory representation of the argument. The NGRN is incremented by two. The`
			`// argument has now been allocated."`
			`//`
			`// Subtlety here: what if alignment is 16 but it is not an integral type? All`
			`// floating-point types have been allocated already, which leaves composite`
			`// types: this is why a front-end may need to produce i128 for a struct <= 16`
			`// bytes.`

			`// PCS: "C.10 If the argument is a Composite Type and the size in double-words`
			`// of the argument is not more than 8 minus NGRN, then the argument is copied`
			`// into consecutive general-purpose registers, starting at x[NGRN]. The`
			`// argument is passed as though it had been loaded into the registers from a`
			`// double-word aligned address with an appropriate sequence of LDR`
			`// instructions loading consecutive registers from memory (the contents of any`
			`// unused parts of the registers are unspecified by this standard). The NGRN`
			`// is incremented by the number of registers used. The argument has now been`
			`// allocated."`
			`//`
			`// Another one that's the responsibility of the front-end (sigh).`

			`// PCS: "C.11: The NGRN is set to 8."`
			`CCCustom<"CC_AArch64NoMoreRegs">,`

			`// PCS: "C.12: The NSAA is rounded up to the larger of 8 or the Natural`
			`// Alignment of the argument's type."`
			`//`
			`// PCS: "C.13: If the argument is a composite type then the argument is copied`
			`// to memory at the adjusted NSAA. The NSAA is by the size of the`
			`// argument. The argument has now been allocated."`
			`//`
			`// Note that the effect of this corresponds to a memcpy rather than register`
			`// stores so that the struct ends up correctly addressable at the adjusted`
			`// NSAA.`

			`// PCS: "C.14: If the size of the argument is less than 8 bytes then the size`
			`// of the argument is set to 8 bytes. The effect is as if the argument was`
			`// copied to the least significant bits of a 64-bit register and the remaining`
			`// bits filled with unspecified values."`
			`//`
			`// Integer types were widened above. Floating-point and composite types have`
			`// already been allocated completely. Nothing to do.`

			`// PCS: "C.15: The argument is copied to memory at the adjusted NSAA. The NSAA`
			`// is incremented by the size of the argument. The argument has now been`
			`// allocated."`
			`CCIfType<[i64], CCIfSplit<CCAssignToStack<8, 16>>>,`
			`CCIfType<[i64], CCAssignToStack<8, 8>>`

			`]>;`

			`// According to the PCS, X19-X30 are callee-saved, however only the low 64-bits`
			`// of vector registers (8-15) are callee-saved. The order here is is picked up`
			`// by PrologEpilogInserter.cpp to allocate stack slots, starting from top of`
			`// stack upon entry. This gives the customary layout of x30 at [sp-8], x29 at`
			`// [sp-16], ...`
			`def CSR_PCS : CalleeSavedRegs<(add (sequence "X%u", 30, 19),`
			`(sequence "D%u", 15, 8))>;`


			`// TLS descriptor calls are extremely restricted in their changes, to allow`
			`// optimisations in the (hopefully) more common fast path where no real action`
			`// is needed. They actually have to preserve all registers, except for the`
			`// unavoidable X30 and the return register X0.`
			`def TLSDesc : CalleeSavedRegs<(add (sequence "X%u", 29, 1),`
			`(sequence "Q%u", 31, 0))>;`