Mercurial > urweb
view src/cjrize.sml @ 1739:c414850f206f
Add support for -boot flag, which allows in-tree execution of Ur/Web
The boot flag rewrites most hardcoded paths to point to the build
directory, and also forces static compilation. This is convenient
for developing Ur/Web, or if you cannot 'sudo make install' Ur/Web.
The following changes were made:
* Header files were moved to include/urweb instead of include;
this lets FFI users point their C_INCLUDE_PATH at this directory
at write <urweb/urweb.h>. For internal Ur/Web executables,
we simply pass -I$PATH/include/urweb as normal.
* Differentiate between LIB and SRCLIB; SRCLIB is Ur and JavaScript
source files, while LIB is compiled products from libtool. For
in-tree compilation these live in different places.
* No longer reference Config for paths; instead use Settings; these
settings can be changed dynamically by Compiler.enableBoot ()
(TODO: add a disableBoot function.)
* config.h is now generated directly in include/urweb/config.h,
for consistency's sake (especially since it gets installed
along with the rest of the headers!)
* All of the autotools build products got updated.
* The linkStatic field in protocols now only contains the name of the
build product, and not the absolute path.
Future users have to be careful not to reference the Settings files
to early, lest they get an old version (this was the source of two
bugs during development of this patch.)
| author | Edward Z. Yang <ezyang@mit.edu> |
|---|---|
| date | Wed, 02 May 2012 17:17:57 -0400 |
| parents | 0577be31a435 |
| children | e8149592990e |
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(* Copyright (c) 2008-2010, Adam Chlipala * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * - Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * - Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * - The names of contributors may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. *) structure Cjrize :> CJRIZE = struct structure L = Mono structure L' = Cjr structure IM = IntBinaryMap structure Sm :> sig type t val empty : t val find : t * (string * L.typ) list * (string * L'.typ) list -> t * int val findList : t * L.typ * L'.typ -> t * int val declares : t -> (int * (string * L'.typ) list) list val clearDeclares : t -> t end = struct structure FM = BinaryMapFn(struct type ord_key = L.typ val compare = MonoUtil.Typ.compare end) type t = { count : int, normal : int FM.map, lists : int FM.map, decls : (int * (string * L'.typ) list) list } val empty : t = { count = 1, normal = FM.insert (FM.empty, (L.TRecord [], ErrorMsg.dummySpan), 0), lists = FM.empty, decls = [] } fun find (v as {count, normal, decls, lists}, xts, xts') = let val t = (L.TRecord xts, ErrorMsg.dummySpan) in case FM.find (normal, t) of SOME i => (v, i) | NONE => ({count = count+1, normal = FM.insert (normal, t, count), lists = lists, decls = (count, xts') :: decls}, count) end fun findList (v as {count, normal, decls, lists}, t, t') = case FM.find (lists, t) of SOME i => (v, i) | NONE => let val xts = [("1", t), ("2", (L.TList t, #2 t))] val xts' = [("1", t'), ("2", (L'.TList (t', count), #2 t'))] in ({count = count+1, normal = FM.insert (normal, (L.TRecord xts, ErrorMsg.dummySpan), count), lists = FM.insert (lists, t, count), decls = (count, xts') :: decls}, count) end fun declares (v : t) = #decls v fun clearDeclares (v : t) = {count = #count v, normal = #normal v, lists = #lists v, decls = []} end fun cifyTyp x = let fun cify dtmap ((t, loc), sm) = case t of L.TFun (t1, t2) => let val (t1, sm) = cify dtmap (t1, sm) val (t2, sm) = cify dtmap (t2, sm) in ((L'.TFun (t1, t2), loc), sm) end | L.TRecord xts => let val xts = MonoUtil.Typ.sortFields xts val old_xts = xts val (xts, sm) = ListUtil.foldlMap (fn ((x, t), sm) => let val (t, sm) = cify dtmap (t, sm) in ((x, t), sm) end) sm xts val (sm, si) = Sm.find (sm, old_xts, xts) in ((L'.TRecord si, loc), sm) end | L.TDatatype (n, ref (dk, xncs)) => (case IM.find (dtmap, n) of SOME r => ((L'.TDatatype (dk, n, r), loc), sm) | NONE => let val r = ref [] val dtmap = IM.insert (dtmap, n, r) val (xncs, sm) = ListUtil.foldlMap (fn ((x, n, to), sm) => case to of NONE => ((x, n, NONE), sm) | SOME t => let val (t, sm) = cify dtmap (t, sm) in ((x, n, SOME t), sm) end) sm xncs in r := xncs; ((L'.TDatatype (dk, n, r), loc), sm) end) | L.TFfi mx => ((L'.TFfi mx, loc), sm) | L.TOption t => let val (t, sm) = cify dtmap (t, sm) in ((L'.TOption t, loc), sm) end | L.TList t => let val (t', sm) = cify dtmap (t, sm) val (sm, si) = Sm.findList (sm, t, t') in ((L'.TList (t', si), loc), sm) end | L.TSource => ((L'.TFfi ("Basis", "source"), loc), sm) | L.TSignal _ => raise Fail "Cjrize: TSignal remains" in cify IM.empty x end val dummye = (L'.EPrim (Prim.Int 0), ErrorMsg.dummySpan) fun cifyPatCon (pc, sm) = case pc of L.PConVar n => (L'.PConVar n, sm) | L.PConFfi {mod = m, datatyp, con, arg} => let val (arg, sm) = case arg of NONE => (NONE, sm) | SOME t => let val (t, sm) = cifyTyp (t, sm) in (SOME t, sm) end in (L'.PConFfi {mod = m, datatyp = datatyp, con = con, arg = arg}, sm) end fun cifyPat ((p, loc), sm) = case p of L.PWild => ((L'.PWild, loc), sm) | L.PVar (x, t) => let val (t, sm) = cifyTyp (t, sm) in ((L'.PVar (x, t), loc), sm) end | L.PPrim p => ((L'.PPrim p, loc), sm) | L.PCon (dk, pc, NONE) => let val (pc, sm) = cifyPatCon (pc, sm) in ((L'.PCon (dk, pc, NONE), loc), sm) end | L.PCon (dk, pc, SOME p) => let val (pc, sm) = cifyPatCon (pc, sm) val (p, sm) = cifyPat (p, sm) in ((L'.PCon (dk, pc, SOME p), loc), sm) end | L.PRecord xps => let val (xps, sm) = ListUtil.foldlMap (fn ((x, p, t), sm) => let val (p, sm) = cifyPat (p, sm) val (t, sm) = cifyTyp (t, sm) in ((x, p, t), sm) end) sm xps in ((L'.PRecord xps, loc), sm) end | L.PNone t => let val (t, sm) = cifyTyp (t, sm) in ((L'.PNone t, loc), sm) end | L.PSome (t, p) => let val (t, sm) = cifyTyp (t, sm) val (p, sm) = cifyPat (p, sm) in ((L'.PSome (t, p), loc), sm) end fun cifyExp (eAll as (e, loc), sm) = let fun fail msg = (ErrorMsg.errorAt loc msg; ((L'.EPrim (Prim.String ""), loc), sm)) in case e of L.EPrim p => ((L'.EPrim p, loc), sm) | L.ERel n => ((L'.ERel n, loc), sm) | L.ENamed n => ((L'.ENamed n, loc), sm) | L.ECon (dk, pc, eo) => let val (eo, sm) = case eo of NONE => (NONE, sm) | SOME e => let val (e, sm) = cifyExp (e, sm) in (SOME e, sm) end val (pc, sm) = cifyPatCon (pc, sm) in ((L'.ECon (dk, pc, eo), loc), sm) end | L.ENone t => let val (t, sm) = cifyTyp (t, sm) in ((L'.ENone t, loc), sm) end | L.ESome (t, e) => let val (t, sm) = cifyTyp (t, sm) val (e, sm) = cifyExp (e, sm) in ((L'.ESome (t, e), loc), sm) end | L.EFfi mx => ((L'.EFfi mx, loc), sm) | L.EFfiApp (m, x, es) => let val (es, sm) = ListUtil.foldlMap (fn ((e, t), sm) => let val (t, sm) = cifyTyp (t, sm) val (e, sm) = cifyExp (e, sm) in ((e, t), sm) end) sm es in ((L'.EFfiApp (m, x, es), loc), sm) end | L.EApp (e1, e2) => let fun unravel (e, args) = case e of (L.EApp (e1, e2), _) => unravel (e1, e2 :: args) | _ => (e, args) val (f, es) = unravel (e1, [e2]) val (f, sm) = cifyExp (f, sm) val (es, sm) = ListUtil.foldlMap cifyExp sm es in ((L'.EApp (f, es), loc), sm) end | L.EAbs _ => (ErrorMsg.errorAt loc "Anonymous function remains at code generation"; Print.prefaces' [("Function", MonoPrint.p_exp MonoEnv.empty eAll)]; (dummye, sm)) | L.EUnop (s, e1) => let val (e1, sm) = cifyExp (e1, sm) in ((L'.EUnop (s, e1), loc), sm) end | L.EBinop (_, s, e1, e2) => let val (e1, sm) = cifyExp (e1, sm) val (e2, sm) = cifyExp (e2, sm) in ((L'.EBinop (s, e1, e2), loc), sm) end | L.ERecord xes => let val old_xts = map (fn (x, _, t) => (x, t)) xes val (xets, sm) = ListUtil.foldlMap (fn ((x, e, t), sm) => let val (e, sm) = cifyExp (e, sm) val (t, sm) = cifyTyp (t, sm) in ((x, e, t), sm) end) sm xes val (sm, si) = Sm.find (sm, old_xts, map (fn (x, _, t) => (x, t)) xets) val xes = map (fn (x, e, _) => (x, e)) xets val xes = ListMergeSort.sort (fn ((x1, _), (x2, _)) => String.compare (x1, x2) = GREATER) xes in ((L'.ERecord (si, xes), loc), sm) end | L.EField (e, x) => let val (e, sm) = cifyExp (e, sm) in ((L'.EField (e, x), loc), sm) end | L.ECase (e, pes, {disc, result}) => let val (e, sm) = cifyExp (e, sm) val (pes, sm) = ListUtil.foldlMap (fn ((p, e), sm) => let val (e, sm) = cifyExp (e, sm) val (p, sm) = cifyPat (p, sm) in ((p, e), sm) end) sm pes val (disc, sm) = cifyTyp (disc, sm) val (result, sm) = cifyTyp (result, sm) in ((L'.ECase (e, pes, {disc = disc, result = result}), loc), sm) end | L.EError (e, t) => let val (e, sm) = cifyExp (e, sm) val (t, sm) = cifyTyp (t, sm) in ((L'.EError (e, t), loc), sm) end | L.EReturnBlob {blob, mimeType, t} => let val (blob, sm) = cifyExp (blob, sm) val (mimeType, sm) = cifyExp (mimeType, sm) val (t, sm) = cifyTyp (t, sm) in ((L'.EReturnBlob {blob = blob, mimeType = mimeType, t = t}, loc), sm) end | L.ERedirect (e, t) => let val (e, sm) = cifyExp (e, sm) val (t, sm) = cifyTyp (t, sm) in ((L'.ERedirect (e, t), loc), sm) end | L.EStrcat (e1, e2) => let val (e1, sm) = cifyExp (e1, sm) val (e2, sm) = cifyExp (e2, sm) val s = (L'.TFfi ("Basis", "string"), loc) in ((L'.EFfiApp ("Basis", "strcat", [(e1, s), (e2, s)]), loc), sm) end | L.EWrite e => let val (e, sm) = cifyExp (e, sm) in ((L'.EWrite e, loc), sm) end | L.ESeq (e1, e2) => let val (e1, sm) = cifyExp (e1, sm) val (e2, sm) = cifyExp (e2, sm) in ((L'.ESeq (e1, e2), loc), sm) end | L.ELet (x, t, e1, e2) => let val (t, sm) = cifyTyp (t, sm) val (e1, sm) = cifyExp (e1, sm) val (e2, sm) = cifyExp (e2, sm) in ((L'.ELet (x, t, e1, e2), loc), sm) end | L.EClosure _ => (ErrorMsg.errorAt loc "Nested closure remains in code generation"; (dummye, sm)) | L.EQuery {exps, tables, state, query, body, initial} => let val (exps', sm) = ListUtil.foldlMap (fn ((x, t), sm) => let val (t, sm) = cifyTyp (t, sm) in ((x, t), sm) end) sm exps val (tables', sm) = ListUtil.foldlMap (fn ((x, xts), sm) => let val (xts, sm) = ListUtil.foldlMap (fn ((x, t), sm) => let val (t, sm) = cifyTyp (t, sm) in ((x, t), sm) end) sm xts in ((x, xts), sm) end) sm tables val row = exps @ map (fn (x, xts) => (x, (L.TRecord xts, loc))) tables val row = ListMergeSort.sort (fn ((x, _), (y, _)) => String.compare (x, y) = GREATER) row val (tableRows, sm) = ListUtil.foldlMap (fn (((x, xts), (_, xts')), sm) => let val (sm, rnum) = Sm.find (sm, xts, xts') in ((x, rnum), sm) end) sm (ListPair.zip (tables, tables')) val row' = exps' @ map (fn (x, n) => (x, (L'.TRecord n, loc))) tableRows val row' = ListMergeSort.sort (fn ((x, _), (y, _)) => String.compare (x, y) = GREATER) row' val (sm, rnum) = Sm.find (sm, row, row') val (state, sm) = cifyTyp (state, sm) val (query, sm) = cifyExp (query, sm) val (body, sm) = cifyExp (body, sm) val (initial, sm) = cifyExp (initial, sm) in ((L'.EQuery {exps = exps', tables = tables', rnum = rnum, state = state, query = query, body = body, initial = initial, prepared = NONE}, loc), sm) end | L.EDml (e, mode) => let val (e, sm) = cifyExp (e, sm) in ((L'.EDml {dml = e, prepared = NONE, mode = mode}, loc), sm) end | L.ENextval e => let val (e, sm) = cifyExp (e, sm) in ((L'.ENextval {seq = e, prepared = NONE}, loc), sm) end | L.ESetval (e1, e2) => let val (e1, sm) = cifyExp (e1, sm) val (e2, sm) = cifyExp (e2, sm) in ((L'.ESetval {seq = e1, count = e2}, loc), sm) end | L.EUnurlify (e, t, b) => let val (e, sm) = cifyExp (e, sm) val (t, sm) = cifyTyp (t, sm) in ((L'.EUnurlify (e, t, b), loc), sm) end | L.EJavaScript _ => fail "Uncompilable JavaScript remains" | L.ESignalReturn _ => fail "Signal monad 'return' remains in server-side code" | L.ESignalBind _ => fail "Signal monad 'bind' remains in server-side code" | L.ESignalSource _ => fail "Signal monad 'source' remains in server-side code" | L.EServerCall _ => fail "RPC in server-side code" | L.ERecv _ => fail "Message receive in server-side code" | L.ESleep _ => fail "Sleep in server-side code" | L.ESpawn _ => fail "Thread spawn in server-side code" end fun cifyDecl ((d, loc), sm) = case d of L.DDatatype dts => let val (dts, sm) = ListUtil.foldlMap (fn ((x, n, xncs), sm) => let val dk = ElabUtil.classifyDatatype xncs val (xncs, sm) = ListUtil.foldlMap (fn ((x, n, to), sm) => case to of NONE => ((x, n, NONE), sm) | SOME t => let val (t, sm) = cifyTyp (t, sm) in ((x, n, SOME t), sm) end) sm xncs in ((dk, x, n, xncs), sm) end) sm dts in (SOME (L'.DDatatype dts, loc), NONE, sm) end | L.DVal (x, n, t, e, _) => let val (t, sm) = cifyTyp (t, sm) val (d, sm) = case #1 t of L'.TFun _ => let fun unravel (tAll as (t, _), eAll as (e, _)) = case (t, e) of (L'.TFun (dom, ran), L.EAbs (ax, _, _, e)) => let val (args, t, e) = unravel (ran, e) in ((ax, dom) :: args, t, e) end | (L'.TFun (dom, ran), _) => let val e = MonoEnv.liftExpInExp 0 eAll val e = (L.EApp (e, (L.ERel 0, loc)), loc) val (args, t, e) = unravel (ran, e) in (("x", dom) :: args, t, e) end | _ => ([], tAll, eAll) val (args, ran, e) = unravel (t, e) val (e, sm) = cifyExp (e, sm) in (L'.DFun (x, n, args, ran, e), sm) end | _ => let val (e, sm) = cifyExp (e, sm) in (L'.DVal (x, n, t, e), sm) end in (SOME (d, loc), NONE, sm) end | L.DValRec vis => let val (vis, sm) = ListUtil.foldlMap (fn ((x, n, t, e, _), sm) => let val (t, sm) = cifyTyp (t, sm) fun unravel (tAll as (t, _), eAll as (e, _)) = case (t, e) of (L'.TFun (dom, ran), L.EAbs (ax, _, _, e)) => let val (args, t, e) = unravel (ran, e) in ((ax, dom) :: args, t, e) end | (L'.TFun _, _) => (ErrorMsg.errorAt loc "Function isn't explicit at code generation"; ([], tAll, eAll)) | _ => ([], tAll, eAll) val (args, ran, e) = unravel (t, e) val (e, sm) = cifyExp (e, sm) in ((x, n, args, ran, e), sm) end) sm vis in (SOME (L'.DFunRec vis, loc), NONE, sm) end | L.DExport (ek, s, n, ts, t, b) => let val (ts, sm) = ListUtil.foldlMap cifyTyp sm ts val (t, sm) = cifyTyp (t, sm) in (NONE, SOME (ek, "/" ^ s, n, ts, t, L'.ServerAndPullAndPush, b), sm) end | L.DTable (s, xts, pe, ce) => let val (xts, sm) = ListUtil.foldlMap (fn ((x, t), sm) => let val (t, sm) = cifyTyp (t, sm) in ((x, t), sm) end) sm xts fun flatten e = case #1 e of L.ERecord [] => [] | L.ERecord [(x, (L.EPrim (Prim.String v), _), _)] => [(x, v)] | L.EStrcat (e1, e2) => flatten e1 @ flatten e2 | _ => (ErrorMsg.errorAt loc "Constraint has not been fully determined"; Print.prefaces "Undetermined constraint" [("e", MonoPrint.p_exp MonoEnv.empty e)]; []) val pe = case #1 pe of L.EPrim (Prim.String s) => s | _ => (ErrorMsg.errorAt loc "Primary key has not been fully determined"; Print.prefaces "Undetermined constraint" [("e", MonoPrint.p_exp MonoEnv.empty pe)]; "") in (SOME (L'.DTable (s, xts, pe, flatten ce), loc), NONE, sm) end | L.DSequence s => (SOME (L'.DSequence s, loc), NONE, sm) | L.DView (s, xts, e) => let val (xts, sm) = ListUtil.foldlMap (fn ((x, t), sm) => let val (t, sm) = cifyTyp (t, sm) in ((x, t), sm) end) sm xts fun flatten e = case #1 e of L.ERecord [] => [] | L.ERecord [(x, (L.EPrim (Prim.String v), _), _)] => [(x, v)] | L.EStrcat (e1, e2) => flatten e1 @ flatten e2 | _ => (ErrorMsg.errorAt loc "Constraint has not been fully determined"; Print.prefaces "Undetermined constraint" [("e", MonoPrint.p_exp MonoEnv.empty e)]; []) val e = case #1 e of L.EPrim (Prim.String s) => s | _ => (ErrorMsg.errorAt loc "VIEW query has not been fully determined"; Print.prefaces "Undetermined VIEW query" [("e", MonoPrint.p_exp MonoEnv.empty e)]; "") in (SOME (L'.DView (s, xts, e), loc), NONE, sm) end | L.DDatabase s => (SOME (L'.DDatabase s, loc), NONE, sm) | L.DJavaScript s => (SOME (L'.DJavaScript s, loc), NONE, sm) | L.DCookie args => (SOME (L'.DCookie args, loc), NONE, sm) | L.DStyle args => (SOME (L'.DStyle args, loc), NONE, sm) | L.DTask (e1, e2) => (case #1 e2 of L.EAbs (x1, _, _, (L.EAbs (x2, _, _, e), _)) => let val tk = case #1 e1 of L.EFfi ("Basis", "initialize") => L'.Initialize | L.EFfi ("Basis", "clientLeaves") => L'.ClientLeaves | L.EFfiApp ("Basis", "periodic", [((L.EPrim (Prim.Int n), _), _)]) => L'.Periodic n | _ => (ErrorMsg.errorAt loc "Task kind not fully determined"; L'.Initialize) val (e, sm) = cifyExp (e, sm) in (SOME (L'.DTask (tk, x1, x2, e), loc), NONE, sm) end | _ => (ErrorMsg.errorAt loc "Initializer has not been fully determined"; (NONE, NONE, sm))) | L.DPolicy _ => (NONE, NONE, sm) | L.DOnError n => (SOME (L'.DOnError n, loc), NONE, sm) fun cjrize ds = let val (dsF, ds, ps, sm) = foldl (fn (d, (dsF, ds, ps, sm)) => let val (dop, pop, sm) = cifyDecl (d, sm) val dsF = case dop of SOME (L'.DDatatype dts, loc) => map (fn (dk, x, n, _) => (L'.DDatatypeForward (dk, x, n), loc)) dts @ dsF | _ => dsF val dsF = map (fn v => (L'.DStruct v, ErrorMsg.dummySpan)) (Sm.declares sm) @ dsF val (dsF, ds) = case dop of NONE => (dsF, ds) | SOME (d as (L'.DDatatype _, loc)) => (d :: dsF, ds) | SOME d => (dsF, d :: ds) val ps = case pop of NONE => ps | SOME p => p :: ps in (dsF, ds, ps, Sm.clearDeclares sm) end) ([], [], [], Sm.empty) ds in (List.revAppend (dsF, rev ds), ps) end end