lix-releng-staging/src/fstate.cc
Eelco Dolstra e877c69d78 * Substitutes now should produce a path with the same id as they are
substituting for (obvious, really).

* For greater efficiency, nix-pull/unnar will place the output in a
  path that is probably the same as what is actually needed, thus
  preventing a path copy.

* Even if a output id is given in a Fix package expression, ensure
  that the resulting Nix derive expression has a different id.  This
  is because Nix expressions that are semantically equivalent (i.e.,
  build the same result) might be different w.r.t. efficiency or
  divergence.  It is absolutely vital for the substitute mechanism
  that such expressions are not used interchangeably.
2003-07-22 15:15:15 +00:00

228 lines
5.7 KiB
C++

#include "fstate.hh"
#include "globals.hh"
#include "store.hh"
string printTerm(ATerm t)
{
char * s = ATwriteToString(t);
return s;
}
Error badTerm(const format & f, ATerm t)
{
return Error(format("%1%, in `%2%'") % f.str() % printTerm(t));
}
Hash hashTerm(ATerm t)
{
return hashString(printTerm(t));
}
ATerm termFromId(const FSId & id)
{
string path = expandId(id);
ATerm t = ATreadFromNamedFile(path.c_str());
if (!t) throw Error(format("cannot read aterm from `%1%'") % path);
return t;
}
FSId writeTerm(ATerm t, const string & suffix, FSId id)
{
/* By default, the id of a term is its hash. */
if (id == FSId()) id = hashTerm(t);
string path = canonPath(nixStore + "/" +
(string) id + suffix + ".nix");
if (!ATwriteToNamedTextFile(t, path.c_str()))
throw Error(format("cannot write aterm %1%") % path);
// debug(format("written term %1% = %2%") % (string) id %
// printTerm(t));
registerPath(path, id);
return id;
}
static void parseIds(ATermList ids, FSIds & out)
{
while (!ATisEmpty(ids)) {
char * s;
ATerm id = ATgetFirst(ids);
if (!ATmatch(id, "<str>", &s))
throw badTerm("not an id", id);
out.push_back(parseHash(s));
ids = ATgetNext(ids);
}
}
static void checkSlice(const Slice & slice)
{
if (slice.elems.size() == 0)
throw Error("empty slice");
FSIdSet decl;
for (SliceElems::const_iterator i = slice.elems.begin();
i != slice.elems.end(); i++)
decl.insert(i->id);
for (FSIds::const_iterator i = slice.roots.begin();
i != slice.roots.end(); i++)
if (decl.find(*i) == decl.end())
throw Error(format("undefined id: %1%") % (string) *i);
for (SliceElems::const_iterator i = slice.elems.begin();
i != slice.elems.end(); i++)
for (FSIds::const_iterator j = i->refs.begin();
j != i->refs.end(); j++)
if (decl.find(*j) == decl.end())
throw Error(format("undefined id: %1%") % (string) *j);
}
/* Parse a slice. */
static bool parseSlice(ATerm t, Slice & slice)
{
ATermList roots, elems;
if (!ATmatch(t, "Slice([<list>], [<list>])", &roots, &elems))
return false;
parseIds(roots, slice.roots);
while (!ATisEmpty(elems)) {
char * s1, * s2;
ATermList refs;
ATerm t = ATgetFirst(elems);
if (!ATmatch(t, "(<str>, <str>, [<list>])", &s1, &s2, &refs))
throw badTerm("not a slice element", t);
SliceElem elem;
elem.path = s1;
elem.id = parseHash(s2);
parseIds(refs, elem.refs);
slice.elems.push_back(elem);
elems = ATgetNext(elems);
}
checkSlice(slice);
return true;
}
static bool parseDerive(ATerm t, Derive & derive)
{
ATermList outs, ins, bnds;
char * builder;
char * platform;
if (!ATmatch(t, "Derive([<list>], [<list>], <str>, <str>, [<list>])",
&outs, &ins, &builder, &platform, &bnds))
return false;
while (!ATisEmpty(outs)) {
char * s1, * s2;
ATerm t = ATgetFirst(outs);
if (!ATmatch(t, "(<str>, <str>)", &s1, &s2))
throw badTerm("not a derive output", t);
derive.outputs.push_back(DeriveOutput(s1, parseHash(s2)));
outs = ATgetNext(outs);
}
parseIds(ins, derive.inputs);
derive.builder = builder;
derive.platform = platform;
while (!ATisEmpty(bnds)) {
char * s1, * s2;
ATerm bnd = ATgetFirst(bnds);
if (!ATmatch(bnd, "(<str>, <str>)", &s1, &s2))
throw badTerm("tuple of strings expected", bnd);
derive.env.push_back(StringPair(s1, s2));
bnds = ATgetNext(bnds);
}
return true;
}
FState parseFState(ATerm t)
{
FState fs;
if (parseSlice(t, fs.slice))
fs.type = FState::fsSlice;
else if (parseDerive(t, fs.derive))
fs.type = FState::fsDerive;
else throw badTerm("not an fstate-expression", t);
return fs;
}
static ATermList unparseIds(const FSIds & ids)
{
ATermList l = ATempty;
for (FSIds::const_iterator i = ids.begin();
i != ids.end(); i++)
l = ATinsert(l,
ATmake("<str>", ((string) *i).c_str()));
return ATreverse(l);
}
static ATerm unparseSlice(const Slice & slice)
{
ATermList roots = unparseIds(slice.roots);
ATermList elems = ATempty;
for (SliceElems::const_iterator i = slice.elems.begin();
i != slice.elems.end(); i++)
elems = ATinsert(elems,
ATmake("(<str>, <str>, <term>)",
i->path.c_str(),
((string) i->id).c_str(),
unparseIds(i->refs)));
return ATmake("Slice(<term>, <term>)", roots, elems);
}
static ATerm unparseDerive(const Derive & derive)
{
ATermList outs = ATempty;
for (DeriveOutputs::const_iterator i = derive.outputs.begin();
i != derive.outputs.end(); i++)
outs = ATinsert(outs,
ATmake("(<str>, <str>)",
i->first.c_str(), ((string) i->second).c_str()));
ATermList env = ATempty;
for (StringPairs::const_iterator i = derive.env.begin();
i != derive.env.end(); i++)
env = ATinsert(env,
ATmake("(<str>, <str>)",
i->first.c_str(), i->second.c_str()));
return ATmake("Derive(<term>, <term>, <str>, <str>, <term>)",
ATreverse(outs),
unparseIds(derive.inputs),
derive.builder.c_str(),
derive.platform.c_str(),
ATreverse(env));
}
ATerm unparseFState(const FState & fs)
{
if (fs.type == FState::fsSlice)
return unparseSlice(fs.slice);
else if (fs.type == FState::fsDerive)
return unparseDerive(fs.derive);
else abort();
}