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|
(* *********************************************************************)
(* *)
(* The Compcert verified compiler *)
(* *)
(* Xavier Leroy, INRIA Paris-Rocquencourt *)
(* *)
(* Copyright Institut National de Recherche en Informatique et en *)
(* Automatique. All rights reserved. This file is distributed *)
(* under the terms of the INRIA Non-Commercial License Agreement. *)
(* *)
(* *********************************************************************)
(** Translation from Mach to PPC. *)
Require Import Coqlib.
Require Import Errors.
Require Import AST.
Require Import Integers.
Require Import Floats.
Require Import Op.
Require Import Locations.
Require Import Mach.
Require Import Asm.
Open Local Scope string_scope.
Open Local Scope error_monad_scope.
(** The code generation functions take advantage of several
characteristics of the [Mach] code generated by earlier passes of the
compiler, mostly that argument and result registers are of the correct
types. These properties are true by construction, but it's easier to
recheck them during code generation and fail if they do not hold. *)
(** Extracting integer or float registers. *)
Definition ireg_of (r: mreg) : res ireg :=
match preg_of r with IR mr => OK mr | _ => Error(msg "Asmgen.ireg_of") end.
Definition freg_of (r: mreg) : res freg :=
match preg_of r with FR mr => OK mr | _ => Error(msg "Asmgen.freg_of") end.
(** Decomposition of integer constants. As noted in file [Asm],
immediate arguments to PowerPC instructions must fit into 16 bits,
and are interpreted after zero extension, sign extension, or
left shift by 16 bits, depending on the instruction. Integer
constants that do not fit must be synthesized using two
processor instructions. The following functions decompose
arbitrary 32-bit integers into two 16-bit halves (high and low
halves). They satisfy the following properties:
- [low_u n] is an unsigned 16-bit integer;
- [low_s n] is a signed 16-bit integer;
- [(high_u n) << 16 | low_u n] equals [n];
- [(high_s n) << 16 + low_s n] equals [n].
*)
Definition low_u (n: int) := Int.and n (Int.repr 65535).
Definition high_u (n: int) := Int.shru n (Int.repr 16).
Definition low_s (n: int) := Int.sign_ext 16 n.
Definition high_s (n: int) := Int.shru (Int.sub n (low_s n)) (Int.repr 16).
(** Smart constructors for arithmetic operations involving
a 32-bit integer constant. Depending on whether the
constant fits in 16 bits or not, one or several instructions
are generated as required to perform the operation
and prepended to the given instruction sequence [k]. *)
Definition loadimm (r: ireg) (n: int) (k: code) :=
if Int.eq (high_s n) Int.zero then
Paddi r GPR0 (Cint n) :: k
else if Int.eq (low_s n) Int.zero then
Paddis r GPR0 (Cint (high_s n)) :: k
else
Paddis r GPR0 (Cint (high_u n)) ::
Pori r r (Cint (low_u n)) :: k.
Definition addimm (r1 r2: ireg) (n: int) (k: code) :=
if Int.eq (high_s n) Int.zero then
Paddi r1 r2 (Cint n) :: k
else if Int.eq (low_s n) Int.zero then
Paddis r1 r2 (Cint (high_s n)) :: k
else
Paddis r1 r2 (Cint (high_s n)) ::
Paddi r1 r1 (Cint (low_s n)) :: k.
Definition andimm_base (r1 r2: ireg) (n: int) (k: code) :=
if Int.eq (high_u n) Int.zero then
Pandi_ r1 r2 (Cint n) :: k
else if Int.eq (low_u n) Int.zero then
Pandis_ r1 r2 (Cint (high_u n)) :: k
else
loadimm GPR0 n (Pand_ r1 r2 GPR0 :: k).
Definition andimm (r1 r2: ireg) (n: int) (k: code) :=
if is_rlw_mask n then
Prlwinm r1 r2 Int.zero n :: k
else
andimm_base r1 r2 n k.
Definition orimm (r1 r2: ireg) (n: int) (k: code) :=
if Int.eq (high_u n) Int.zero then
Pori r1 r2 (Cint n) :: k
else if Int.eq (low_u n) Int.zero then
Poris r1 r2 (Cint (high_u n)) :: k
else
Poris r1 r2 (Cint (high_u n)) ::
Pori r1 r1 (Cint (low_u n)) :: k.
Definition xorimm (r1 r2: ireg) (n: int) (k: code) :=
if Int.eq (high_u n) Int.zero then
Pxori r1 r2 (Cint n) :: k
else if Int.eq (low_u n) Int.zero then
Pxoris r1 r2 (Cint (high_u n)) :: k
else
Pxoris r1 r2 (Cint (high_u n)) ::
Pxori r1 r1 (Cint (low_u n)) :: k.
Definition rolm (r1 r2: ireg) (amount mask: int) (k: code) :=
if is_rlw_mask mask then
Prlwinm r1 r2 amount mask :: k
else
Prlwinm r1 r2 amount Int.mone :: andimm_base r1 r1 mask k.
(** Accessing slots in the stack frame. *)
Definition loadind (base: ireg) (ofs: int) (ty: typ) (dst: mreg) (k: code) :=
match ty with
| Tint =>
do r <- ireg_of dst;
OK (if Int.eq (high_s ofs) Int.zero then
Plwz r (Cint ofs) base :: k
else
loadimm GPR0 ofs (Plwzx r base GPR0 :: k))
| Tfloat =>
do r <- freg_of dst;
OK (if Int.eq (high_s ofs) Int.zero then
Plfd r (Cint ofs) base :: k
else
loadimm GPR0 ofs (Plfdx r base GPR0 :: k))
| Tlong =>
Error (msg "Asmgen.loadind")
end.
Definition storeind (src: mreg) (base: ireg) (ofs: int) (ty: typ) (k: code) :=
match ty with
| Tint =>
do r <- ireg_of src;
OK (if Int.eq (high_s ofs) Int.zero then
Pstw r (Cint ofs) base :: k
else
loadimm GPR0 ofs (Pstwx r base GPR0 :: k))
| Tfloat =>
do r <- freg_of src;
OK (if Int.eq (high_s ofs) Int.zero then
Pstfd r (Cint ofs) base :: k
else
loadimm GPR0 ofs (Pstfdx r base GPR0 :: k))
| Tlong =>
Error (msg "Asmgen.storeind")
end.
(** Constructor for a floating-point comparison. The PowerPC has
a single [fcmpu] instruction to compare floats, which sets
bits 0, 1 and 2 of the condition register to reflect ``less'',
``greater'' and ``equal'' conditions, respectively.
The ``less or equal'' and ``greater or equal'' conditions must be
synthesized by a [cror] instruction that computes the logical ``or''
of the corresponding two conditions. *)
Definition floatcomp (cmp: comparison) (r1 r2: freg) (k: code) :=
Pfcmpu r1 r2 ::
match cmp with
| Cle => Pcror CRbit_3 CRbit_2 CRbit_0 :: k
| Cge => Pcror CRbit_3 CRbit_2 CRbit_1 :: k
| _ => k
end.
(** Translation of a condition. Prepends to [k] the instructions
that evaluate the condition and leave its boolean result in one of
the bits of the condition register. The bit in question is
determined by the [crbit_for_cond] function. *)
Definition transl_cond
(cond: condition) (args: list mreg) (k: code) :=
match cond, args with
| Ccomp c, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; OK (Pcmpw r1 r2 :: k)
| Ccompu c, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; OK (Pcmplw r1 r2 :: k)
| Ccompimm c n, a1 :: nil =>
do r1 <- ireg_of a1;
if Int.eq (high_s n) Int.zero then
OK (Pcmpwi r1 (Cint n) :: k)
else
OK (loadimm GPR0 n (Pcmpw r1 GPR0 :: k))
| Ccompuimm c n, a1 :: nil =>
do r1 <- ireg_of a1;
if Int.eq (high_u n) Int.zero then
OK (Pcmplwi r1 (Cint n) :: k)
else
OK (loadimm GPR0 n (Pcmplw r1 GPR0 :: k))
| Ccompf cmp, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; OK (floatcomp cmp r1 r2 k)
| Cnotcompf cmp, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; OK (floatcomp cmp r1 r2 k)
| Cmaskzero n, a1 :: nil =>
do r1 <- ireg_of a1; OK (andimm_base GPR0 r1 n k)
| Cmasknotzero n, a1 :: nil =>
do r1 <- ireg_of a1; OK (andimm_base GPR0 r1 n k)
| _, _ =>
Error(msg "Asmgen.transl_cond")
end.
(* CRbit_0 = Less
CRbit_1 = Greater
CRbit_2 = Equal
CRbit_3 = Other *)
Definition crbit_for_icmp (cmp: comparison) :=
match cmp with
| Ceq => (CRbit_2, true)
| Cne => (CRbit_2, false)
| Clt => (CRbit_0, true)
| Cle => (CRbit_1, false)
| Cgt => (CRbit_1, true)
| Cge => (CRbit_0, false)
end.
Definition crbit_for_fcmp (cmp: comparison) :=
match cmp with
| Ceq => (CRbit_2, true)
| Cne => (CRbit_2, false)
| Clt => (CRbit_0, true)
| Cle => (CRbit_3, true)
| Cgt => (CRbit_1, true)
| Cge => (CRbit_3, true)
end.
Definition crbit_for_cond (cond: condition) :=
match cond with
| Ccomp cmp => crbit_for_icmp cmp
| Ccompu cmp => crbit_for_icmp cmp
| Ccompimm cmp n => crbit_for_icmp cmp
| Ccompuimm cmp n => crbit_for_icmp cmp
| Ccompf cmp => crbit_for_fcmp cmp
| Cnotcompf cmp => let p := crbit_for_fcmp cmp in (fst p, negb (snd p))
| Cmaskzero n => (CRbit_2, true)
| Cmasknotzero n => (CRbit_2, false)
end.
(** Recognition of comparisons [>= 0] and [< 0]. *)
Inductive condition_class: condition -> list mreg -> Type :=
| condition_eq0:
forall n r, n = Int.zero -> condition_class (Ccompimm Ceq n) (r :: nil)
| condition_ne0:
forall n r, n = Int.zero -> condition_class (Ccompimm Cne n) (r :: nil)
| condition_ge0:
forall n r, n = Int.zero -> condition_class (Ccompimm Cge n) (r :: nil)
| condition_lt0:
forall n r, n = Int.zero -> condition_class (Ccompimm Clt n) (r :: nil)
| condition_default:
forall c rl, condition_class c rl.
Definition classify_condition (c: condition) (args: list mreg): condition_class c args :=
match c as z1, args as z2 return condition_class z1 z2 with
| Ccompimm Ceq n, r :: nil =>
match Int.eq_dec n Int.zero with
| left EQ => condition_eq0 n r EQ
| right _ => condition_default (Ccompimm Ceq n) (r :: nil)
end
| Ccompimm Cne n, r :: nil =>
match Int.eq_dec n Int.zero with
| left EQ => condition_ne0 n r EQ
| right _ => condition_default (Ccompimm Cne n) (r :: nil)
end
| Ccompimm Cge n, r :: nil =>
match Int.eq_dec n Int.zero with
| left EQ => condition_ge0 n r EQ
| right _ => condition_default (Ccompimm Cge n) (r :: nil)
end
| Ccompimm Clt n, r :: nil =>
match Int.eq_dec n Int.zero with
| left EQ => condition_lt0 n r EQ
| right _ => condition_default (Ccompimm Clt n) (r :: nil)
end
| x, y =>
condition_default x y
end.
(** Translation of a condition operator. The generated code sets
the [r] target register to 0 or 1 depending on the truth value of the
condition. *)
Definition transl_cond_op
(cond: condition) (args: list mreg) (r: mreg) (k: code) :=
do r' <- ireg_of r;
match classify_condition cond args with
| condition_eq0 _ a _ =>
do a' <- ireg_of a;
OK (Psubfic GPR0 a' (Cint Int.zero) ::
Padde r' GPR0 a' :: k)
| condition_ne0 _ a _ =>
do a' <- ireg_of a;
OK (Paddic GPR0 a' (Cint Int.mone) ::
Psubfe r' GPR0 a' :: k)
| condition_ge0 _ a _ =>
do a' <- ireg_of a;
OK (Prlwinm r' a' Int.one Int.one ::
Pxori r' r' (Cint Int.one) :: k)
| condition_lt0 _ a _ =>
do a' <- ireg_of a;
OK (Prlwinm r' a' Int.one Int.one :: k)
| condition_default _ _ =>
let p := crbit_for_cond cond in
transl_cond cond args
(Pmfcrbit r' (fst p) ::
if snd p
then k
else Pxori r' r' (Cint Int.one) :: k)
end.
(** Translation of the arithmetic operation [r <- op(args)].
The corresponding instructions are prepended to [k]. *)
Definition transl_op
(op: operation) (args: list mreg) (res: mreg) (k: code) :=
match op, args with
| Omove, a1 :: nil =>
match preg_of res, preg_of a1 with
| IR r, IR a => OK (Pmr r a :: k)
| FR r, FR a => OK (Pfmr r a :: k)
| _ , _ => Error(msg "Asmgen.Omove")
end
| Ointconst n, nil =>
do r <- ireg_of res; OK (loadimm r n k)
| Ofloatconst f, nil =>
do r <- freg_of res; OK (Plfi r f :: k)
| Oaddrsymbol s ofs, nil =>
do r <- ireg_of res;
OK (if symbol_is_small_data s ofs then
Paddi r GPR0 (Csymbol_sda s ofs) :: k
else
Paddis r GPR0 (Csymbol_high s ofs) ::
Paddi r r (Csymbol_low s ofs) :: k)
| Oaddrstack n, nil =>
do r <- ireg_of res; OK (addimm r GPR1 n k)
| Ocast8signed, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res; OK (Pextsb r r1 :: k)
| Ocast16signed, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res; OK (Pextsh r r1 :: k)
| Oadd, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Padd r r1 r2 :: k)
| Oaddimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res; OK (addimm r r1 n k)
| Osub, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Psubfc r r2 r1 :: k)
| Osubimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (if Int.eq (high_s n) Int.zero then
Psubfic r r1 (Cint n) :: k
else
loadimm GPR0 n (Psubfc r r1 GPR0 :: k))
| Omul, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pmullw r r1 r2 :: k)
| Omulimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (if Int.eq (high_s n) Int.zero then
Pmulli r r1 (Cint n) :: k
else
loadimm GPR0 n (Pmullw r r1 GPR0 :: k))
| Odiv, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pdivw r r1 r2 :: k)
| Odivu, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pdivwu r r1 r2 :: k)
| Oand, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pand_ r r1 r2 :: k)
| Oandimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (andimm r r1 n k)
| Oor, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Por r r1 r2 :: k)
| Oorimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (orimm r r1 n k)
| Oxor, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pxor r r1 r2 :: k)
| Oxorimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (xorimm r r1 n k)
| Onot, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (Pnor r r1 r1 :: k)
| Onand, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pnand r r1 r2 :: k)
| Onor, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pnor r r1 r2 :: k)
| Onxor, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Peqv r r1 r2 :: k)
| Oandc, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pandc r r1 r2 :: k)
| Oorc, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Porc r r1 r2 :: k)
| Oshl, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Pslw r r1 r2 :: k)
| Oshr, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Psraw r r1 r2 :: k)
| Oshrimm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (Psrawi r r1 n :: k)
| Oshrximm n, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (Psrawi r r1 n :: Paddze r r :: k)
| Oshru, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Psrw r r1 r2 :: k)
| Orolm amount mask, a1 :: nil =>
do r1 <- ireg_of a1; do r <- ireg_of res;
OK (rolm r r1 amount mask k)
| Oroli amount mask, a1 :: a2 :: nil =>
assertion (mreg_eq a1 res);
do r2 <- ireg_of a2; do r <- ireg_of res;
OK (Prlwimi r r2 amount mask :: k)
| Onegf, a1 :: nil =>
do r1 <- freg_of a1; do r <- freg_of res;
OK (Pfneg r r1 :: k)
| Oabsf, a1 :: nil =>
do r1 <- freg_of a1; do r <- freg_of res;
OK (Pfabs r r1 :: k)
| Oaddf, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; do r <- freg_of res;
OK (Pfadd r r1 r2 :: k)
| Osubf, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; do r <- freg_of res;
OK (Pfsub r r1 r2 :: k)
| Omulf, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; do r <- freg_of res;
OK (Pfmul r r1 r2 :: k)
| Odivf, a1 :: a2 :: nil =>
do r1 <- freg_of a1; do r2 <- freg_of a2; do r <- freg_of res;
OK (Pfdiv r r1 r2 :: k)
| Osingleoffloat, a1 :: nil =>
do r1 <- freg_of a1; do r <- freg_of res;
OK (Pfrsp r r1 :: k)
| Ointoffloat, a1 :: nil =>
do r1 <- freg_of a1; do r <- ireg_of res;
OK (Pfcti r r1 :: k)
| Ofloatofwords, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2; do r <- freg_of res;
OK (Pfmake r r1 r2 :: k)
| Ocmp cmp, _ =>
transl_cond_op cmp args res k
| _, _ =>
Error(msg "Asmgen.transl_op")
end.
(** Translation of memory accesses: loads, and stores. *)
Definition int_temp_for (r: mreg) :=
if mreg_eq r R12 then GPR11 else GPR12.
Definition transl_memory_access
(mk1: constant -> ireg -> instruction)
(mk2: ireg -> ireg -> instruction)
(addr: addressing) (args: list mreg)
(temp: ireg) (k: code) :=
match addr, args with
| Aindexed ofs, a1 :: nil =>
do r1 <- ireg_of a1;
OK (if Int.eq (high_s ofs) Int.zero then
mk1 (Cint ofs) r1 :: k
else
Paddis temp r1 (Cint (high_s ofs)) ::
mk1 (Cint (low_s ofs)) temp :: k)
| Aindexed2, a1 :: a2 :: nil =>
do r1 <- ireg_of a1; do r2 <- ireg_of a2;
OK (mk2 r1 r2 :: k)
| Aglobal symb ofs, nil =>
OK (if symbol_is_small_data symb ofs then
mk1 (Csymbol_sda symb ofs) GPR0 :: k
else
Paddis temp GPR0 (Csymbol_high symb ofs) ::
mk1 (Csymbol_low symb ofs) temp :: k)
| Abased symb ofs, a1 :: nil =>
do r1 <- ireg_of a1;
OK (Paddis temp r1 (Csymbol_high symb ofs) ::
mk1 (Csymbol_low symb ofs) temp :: k)
| Ainstack ofs, nil =>
OK (if Int.eq (high_s ofs) Int.zero then
mk1 (Cint ofs) GPR1 :: k
else
Paddis temp GPR1 (Cint (high_s ofs)) ::
mk1 (Cint (low_s ofs)) temp :: k)
| _, _ =>
Error(msg "Asmgen.transl_memory_access")
end.
Definition transl_load (chunk: memory_chunk) (addr: addressing)
(args: list mreg) (dst: mreg) (k: code) :=
match chunk with
| Mint8signed =>
do r <- ireg_of dst;
transl_memory_access (Plbz r) (Plbzx r) addr args GPR12 (Pextsb r r :: k)
| Mint8unsigned =>
do r <- ireg_of dst;
transl_memory_access (Plbz r) (Plbzx r) addr args GPR12 k
| Mint16signed =>
do r <- ireg_of dst;
transl_memory_access (Plha r) (Plhax r) addr args GPR12 k
| Mint16unsigned =>
do r <- ireg_of dst;
transl_memory_access (Plhz r) (Plhzx r) addr args GPR12 k
| Mint32 =>
do r <- ireg_of dst;
transl_memory_access (Plwz r) (Plwzx r) addr args GPR12 k
| Mfloat32 =>
do r <- freg_of dst;
transl_memory_access (Plfs r) (Plfsx r) addr args GPR12 k
| Mfloat64 | Mfloat64al32 =>
do r <- freg_of dst;
transl_memory_access (Plfd r) (Plfdx r) addr args GPR12 k
| Mint64 =>
Error (msg "Asmgen.transl_load")
end.
Definition transl_store (chunk: memory_chunk) (addr: addressing)
(args: list mreg) (src: mreg) (k: code) :=
let temp := int_temp_for src in
match chunk with
| Mint8signed | Mint8unsigned =>
do r <- ireg_of src;
transl_memory_access (Pstb r) (Pstbx r) addr args temp k
| Mint16signed | Mint16unsigned =>
do r <- ireg_of src;
transl_memory_access (Psth r) (Psthx r) addr args temp k
| Mint32 =>
do r <- ireg_of src;
transl_memory_access (Pstw r) (Pstwx r) addr args temp k
| Mfloat32 =>
do r <- freg_of src;
transl_memory_access (Pstfs r) (Pstfsx r) addr args temp k
| Mfloat64 | Mfloat64al32 =>
do r <- freg_of src;
transl_memory_access (Pstfd r) (Pstfdx r) addr args temp k
| Mint64 =>
Error (msg "Asmgen.transl_store")
end.
(** Translation of arguments to annotations *)
Definition transl_annot_param (p: Mach.annot_param) : Asm.annot_param :=
match p with
| Mach.APreg r => APreg (preg_of r)
| Mach.APstack chunk ofs => APstack chunk ofs
end.
(** Translation of a Mach instruction. *)
Definition transl_instr (f: Mach.function) (i: Mach.instruction)
(r11_is_parent: bool) (k: code) :=
match i with
| Mgetstack ofs ty dst =>
loadind GPR1 ofs ty dst k
| Msetstack src ofs ty =>
storeind src GPR1 ofs ty k
| Mgetparam ofs ty dst =>
if r11_is_parent then
loadind GPR11 ofs ty dst k
else
(do k1 <- loadind GPR11 ofs ty dst k;
loadind GPR1 f.(fn_link_ofs) Tint R11 k1)
| Mop op args res =>
transl_op op args res k
| Mload chunk addr args dst =>
transl_load chunk addr args dst k
| Mstore chunk addr args src =>
transl_store chunk addr args src k
| Mcall sig (inl r) =>
do r1 <- ireg_of r; OK (Pmtctr r1 :: Pbctrl :: k)
| Mcall sig (inr symb) =>
OK (Pbl symb :: k)
| Mtailcall sig (inl r) =>
do r1 <- ireg_of r;
OK (Pmtctr r1 ::
Plwz GPR0 (Cint f.(fn_retaddr_ofs)) GPR1 ::
Pmtlr GPR0 ::
Pfreeframe f.(fn_stacksize) f.(fn_link_ofs) ::
Pbctr :: k)
| Mtailcall sig (inr symb) =>
OK (Plwz GPR0 (Cint f.(fn_retaddr_ofs)) GPR1 ::
Pmtlr GPR0 ::
Pfreeframe f.(fn_stacksize) f.(fn_link_ofs) ::
Pbs symb :: k)
| Mbuiltin ef args res =>
OK (Pbuiltin ef (map preg_of args) (map preg_of res) :: k)
| Mannot ef args =>
OK (Pannot ef (map transl_annot_param args) :: k)
| Mlabel lbl =>
OK (Plabel lbl :: k)
| Mgoto lbl =>
OK (Pb lbl :: k)
| Mcond cond args lbl =>
let p := crbit_for_cond cond in
transl_cond cond args
(if (snd p) then Pbt (fst p) lbl :: k else Pbf (fst p) lbl :: k)
| Mjumptable arg tbl =>
do r <- ireg_of arg;
OK (Pbtbl r tbl :: k)
| Mreturn =>
OK (Plwz GPR0 (Cint f.(fn_retaddr_ofs)) GPR1 ::
Pmtlr GPR0 ::
Pfreeframe f.(fn_stacksize) f.(fn_link_ofs) ::
Pblr :: k)
end.
(** Translation of a code sequence *)
Definition it1_is_parent (before: bool) (i: Mach.instruction) : bool :=
match i with
| Msetstack src ofs ty => before
| Mgetparam ofs ty dst => negb (mreg_eq dst R11)
| Mop Omove args res => before && negb (mreg_eq res R11)
| _ => false
end.
(** This is the naive definition that we no longer use because it
is not tail-recursive. It is kept as specification. *)
Fixpoint transl_code (f: Mach.function) (il: list Mach.instruction) (it1p: bool) :=
match il with
| nil => OK nil
| i1 :: il' =>
do k <- transl_code f il' (it1_is_parent it1p i1);
transl_instr f i1 it1p k
end.
(** This is an equivalent definition in continuation-passing style
that runs in constant stack space. *)
Fixpoint transl_code_rec (f: Mach.function) (il: list Mach.instruction)
(it1p: bool) (k: code -> res code) :=
match il with
| nil => k nil
| i1 :: il' =>
transl_code_rec f il' (it1_is_parent it1p i1)
(fun c1 => do c2 <- transl_instr f i1 it1p c1; k c2)
end.
Definition transl_code' (f: Mach.function) (il: list Mach.instruction) (it1p: bool) :=
transl_code_rec f il it1p (fun c => OK c).
(** Translation of a whole function. Note that we must check
that the generated code contains less than [2^32] instructions,
otherwise the offset part of the [PC] code pointer could wrap
around, leading to incorrect executions. *)
Definition transl_function (f: Mach.function) :=
do c <- transl_code' f f.(Mach.fn_code) false;
OK (Pallocframe f.(fn_stacksize) f.(fn_link_ofs) ::
Pmflr GPR0 ::
Pstw GPR0 (Cint f.(fn_retaddr_ofs)) GPR1 :: c).
Definition transf_function (f: Mach.function) : res Asm.code :=
do c <- transl_function f;
if zlt Int.max_unsigned (list_length_z c)
then Error (msg "code size exceeded")
else OK c.
Definition transf_fundef (f: Mach.fundef) : res Asm.fundef :=
transf_partial_fundef transf_function f.
Definition transf_program (p: Mach.program) : res Asm.program :=
transform_partial_program transf_fundef p.
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