(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* = String.length !out_buffer then begin let len = String.length !out_buffer in let new_buffer = String.create (2 * len) in String.blit !out_buffer 0 new_buffer 0 len; out_buffer := new_buffer end; String.unsafe_set !out_buffer p (Char.unsafe_chr b1); String.unsafe_set !out_buffer (p+1) (Char.unsafe_chr b2); String.unsafe_set !out_buffer (p+2) (Char.unsafe_chr b3); String.unsafe_set !out_buffer (p+3) (Char.unsafe_chr b4); out_position := p + 4 *) let out_word b1 b2 b3 b4 = let p = !out_position in if p >= String.length !out_buffer then begin let len = String.length !out_buffer in let new_len = if len <= Sys.max_string_length / 2 then 2 * len else if len = Sys.max_string_length then raise (Invalid_argument "String.create") (* Pas la bonne execption .... *) else Sys.max_string_length in let new_buffer = String.create new_len in String.blit !out_buffer 0 new_buffer 0 len; out_buffer := new_buffer end; String.unsafe_set !out_buffer p (Char.unsafe_chr b1); String.unsafe_set !out_buffer (p+1) (Char.unsafe_chr b2); String.unsafe_set !out_buffer (p+2) (Char.unsafe_chr b3); String.unsafe_set !out_buffer (p+3) (Char.unsafe_chr b4); out_position := p + 4 let out opcode = out_word opcode 0 0 0 let out_int n = out_word n (n asr 8) (n asr 16) (n asr 24) (* Handling of local labels and backpatching *) type label_definition = Label_defined of int | Label_undefined of (int * int) list let label_table = ref ([| |] : label_definition array) (* le ieme element de la table = Label_defined n signifie que l'on a deja rencontrer le label i et qu'il est a l'offset n. = Label_undefined l signifie que l'on a pas encore rencontrer ce label, le premier entier indique ou est l'entier a patcher dans la string, le deuxieme son origine *) let extend_label_table needed = let new_size = ref(Array.length !label_table) in while needed >= !new_size do new_size := 2 * !new_size done; let new_table = Array.create !new_size (Label_undefined []) in Array.blit !label_table 0 new_table 0 (Array.length !label_table); label_table := new_table let backpatch (pos, orig) = let displ = (!out_position - orig) asr 2 in !out_buffer.[pos] <- Char.unsafe_chr displ; !out_buffer.[pos+1] <- Char.unsafe_chr (displ asr 8); !out_buffer.[pos+2] <- Char.unsafe_chr (displ asr 16); !out_buffer.[pos+3] <- Char.unsafe_chr (displ asr 24) let define_label lbl = if lbl >= Array.length !label_table then extend_label_table lbl; match (!label_table).(lbl) with Label_defined _ -> raise(Failure "CEmitcode.define_label") | Label_undefined patchlist -> List.iter backpatch patchlist; (!label_table).(lbl) <- Label_defined !out_position let out_label_with_orig orig lbl = if lbl >= Array.length !label_table then extend_label_table lbl; match (!label_table).(lbl) with Label_defined def -> out_int((def - orig) asr 2) | Label_undefined patchlist -> (* spiwack: patchlist is supposed to be non-empty all the time thus I commented that out. If there is no problem I suggest removing it for next release (cur: 8.1) *) (*if patchlist = [] then *) (!label_table).(lbl) <- Label_undefined((!out_position, orig) :: patchlist); out_int 0 let out_label l = out_label_with_orig !out_position l (* Relocation information *) let reloc_info = ref ([] : (reloc_info * int) list) let enter info = reloc_info := (info, !out_position) :: !reloc_info let slot_for_const c = enter (Reloc_const c); out_int 0 and slot_for_annot a = enter (Reloc_annot a); out_int 0 and slot_for_getglobal id = enter (Reloc_getglobal id); out_int 0 (* Emission of one instruction *) let emit_instr = function | Klabel lbl -> define_label lbl | Kacc n -> if n < 8 then out(opACC0 + n) else (out opACC; out_int n) | Kenvacc n -> if n >= 1 && n <= 4 then out(opENVACC1 + n - 1) else (out opENVACC; out_int n) | Koffsetclosure ofs -> if ofs = -2 || ofs = 0 || ofs = 2 then out (opOFFSETCLOSURE0 + ofs / 2) else (out opOFFSETCLOSURE; out_int ofs) | Kpush -> out opPUSH | Kpop n -> out opPOP; out_int n | Kpush_retaddr lbl -> out opPUSH_RETADDR; out_label lbl | Kapply n -> if n < 4 then out(opAPPLY1 + n - 1) else (out opAPPLY; out_int n) | Kappterm(n, sz) -> if n < 4 then (out(opAPPTERM1 + n - 1); out_int sz) else (out opAPPTERM; out_int n; out_int sz) | Kreturn n -> out opRETURN; out_int n | Kjump -> out opRETURN; out_int 0 | Krestart -> out opRESTART | Kgrab n -> out opGRAB; out_int n | Kgrabrec(rec_arg) -> out opGRABREC; out_int rec_arg | Kclosure(lbl, n) -> out opCLOSURE; out_int n; out_label lbl | Kclosurerec(nfv,init,lbl_types,lbl_bodies) -> out opCLOSUREREC;out_int (Array.length lbl_bodies); out_int nfv; out_int init; let org = !out_position in Array.iter (out_label_with_orig org) lbl_types; let org = !out_position in Array.iter (out_label_with_orig org) lbl_bodies | Kclosurecofix(nfv,init,lbl_types,lbl_bodies) -> out opCLOSURECOFIX;out_int (Array.length lbl_bodies); out_int nfv; out_int init; let org = !out_position in Array.iter (out_label_with_orig org) lbl_types; let org = !out_position in Array.iter (out_label_with_orig org) lbl_bodies | Kgetglobal q -> out opGETGLOBAL; slot_for_getglobal q | Kconst((Const_b0 i)) -> if i >= 0 && i <= 3 then out (opCONST0 + i) else (out opCONSTINT; out_int i) | Kconst c -> out opGETGLOBAL; slot_for_const c | Kmakeblock(n, t) -> if n = 0 then raise (Invalid_argument "emit_instr : block size = 0") else if n < 4 then (out(opMAKEBLOCK1 + n - 1); out_int t) else (out opMAKEBLOCK; out_int n; out_int t) | Kmakeprod -> out opMAKEPROD | Kmakeswitchblock(typlbl,swlbl,annot,sz) -> out opMAKESWITCHBLOCK; out_label typlbl; out_label swlbl; slot_for_annot annot;out_int sz | Kswitch (tbl_const, tbl_block) -> out opSWITCH; out_int (Array.length tbl_const + (Array.length tbl_block lsl 16)); let org = !out_position in Array.iter (out_label_with_orig org) tbl_const; Array.iter (out_label_with_orig org) tbl_block | Kpushfields n -> out opPUSHFIELDS;out_int n | Kfield n -> if n <= 1 then out (opGETFIELD0+n) else (out opGETFIELD;out_int n) | Ksetfield n -> if n <= 1 then out (opSETFIELD0+n) else (out opSETFIELD;out_int n) | Ksequence _ -> raise (Invalid_argument "Cemitcodes.emit_instr") (* spiwack *) | Kbranch lbl -> out opBRANCH; out_label lbl | Kaddint31 -> out opADDINT31 | Kaddcint31 -> out opADDCINT31 | Kaddcarrycint31 -> out opADDCARRYCINT31 | Ksubint31 -> out opSUBINT31 | Ksubcint31 -> out opSUBCINT31 | Ksubcarrycint31 -> out opSUBCARRYCINT31 | Kmulint31 -> out opMULINT31 | Kmulcint31 -> out opMULCINT31 | Kdiv21int31 -> out opDIV21INT31 | Kdivint31 -> out opDIVINT31 | Kaddmuldivint31 -> out opADDMULDIVINT31 | Kcompareint31 -> out opCOMPAREINT31 | Khead0int31 -> out opHEAD0INT31 | Ktail0int31 -> out opTAIL0INT31 | Kisconst lbl -> out opISCONST; out_label lbl | Kareconst(n,lbl) -> out opARECONST; out_int n; out_label lbl | Kcompint31 -> out opCOMPINT31 | Kdecompint31 -> out opDECOMPINT31 | Klorint31 -> out opORINT31 | Klandint31 -> out opANDINT31 | Klxorint31 -> out opXORINT31 (*/spiwack *) | Kstop -> out opSTOP (* Emission of a list of instructions. Include some peephole optimization. *) let rec emit = function | [] -> () (* Peephole optimizations *) | Kpush :: Kacc n :: c -> if n < 8 then out(opPUSHACC0 + n) else (out opPUSHACC; out_int n); emit c | Kpush :: Kenvacc n :: c -> if n >= 1 && n <= 4 then out(opPUSHENVACC1 + n - 1) else (out opPUSHENVACC; out_int n); emit c | Kpush :: Koffsetclosure ofs :: c -> if ofs = -2 || ofs = 0 || ofs = 2 then out(opPUSHOFFSETCLOSURE0 + ofs / 2) else (out opPUSHOFFSETCLOSURE; out_int ofs); emit c | Kpush :: Kgetglobal id :: c -> out opPUSHGETGLOBAL; slot_for_getglobal id; emit c | Kpush :: Kconst (Const_b0 i) :: c -> if i >= 0 && i <= 3 then out (opPUSHCONST0 + i) else (out opPUSHCONSTINT; out_int i); emit c | Kpush :: Kconst const :: c -> out opPUSHGETGLOBAL; slot_for_const const; emit c | Kpop n :: Kjump :: c -> out opRETURN; out_int n; emit c | Ksequence(c1,c2)::c -> emit c1; emit c2;emit c (* Default case *) | instr :: c -> emit_instr instr; emit c (* Initialization *) let init () = out_position := 0; label_table := Array.create 16 (Label_undefined []); reloc_info := [] type emitcodes = string let copy = String.copy let length = String.length type to_patch = emitcodes * (patch list) * fv (* Substitution *) let rec subst_strcst s sc = match sc with | Const_sorts _ | Const_b0 _ -> sc | Const_bn(tag,args) -> Const_bn(tag,Array.map (subst_strcst s) args) | Const_ind(ind) -> let kn,i = ind in Const_ind((subst_ind s kn, i)) let subst_patch s (ri,pos) = match ri with | Reloc_annot a -> let (kn,i) = a.ci.ci_ind in let ci = {a.ci with ci_ind = (subst_ind s kn,i)} in (Reloc_annot {a with ci = ci},pos) | Reloc_const sc -> (Reloc_const (subst_strcst s sc), pos) | Reloc_getglobal kn -> (Reloc_getglobal (fst (subst_con s kn)), pos) let subst_to_patch s (code,pl,fv) = code,List.rev_map (subst_patch s) pl,fv type body_code = | BCdefined of to_patch | BCallias of constant | BCconstant let subst_body_code s = function | BCdefined tp -> BCdefined (subst_to_patch s tp) | BCallias kn -> BCallias (fst (subst_con s kn)) | BCconstant -> BCconstant type to_patch_substituted = body_code substituted let from_val = from_val let force = force subst_body_code let subst_to_patch_subst = subst_substituted let repr_body_code = repr_substituted let to_memory (init_code, fun_code, fv) = init(); emit init_code; emit fun_code; let code = String.create !out_position in String.unsafe_blit !out_buffer 0 code 0 !out_position; let reloc = List.rev !reloc_info in Array.iter (fun lbl -> (match lbl with Label_defined _ -> assert true | Label_undefined patchlist -> assert (patchlist = []))) !label_table; (code, reloc, fv)