nix-super/src/libstore/storeexpr.cc
Eelco Dolstra f3dc231250 * Removed the `id' attribute hack.
* Formalise the notion of fixed-output derivations, i.e., derivations
  for which a cryptographic hash of the output is known in advance.
  Changes to such derivations should not propagate upwards through the
  dependency graph.  Previously this was done by specifying the hash
  component of the output path through the `id' attribute, but this is
  insecure since you can lie about it (i.e., you can specify any hash
  and then produce a completely different output).  Now the
  responsibility for checking the output is moved from the builder to
  Nix itself.

  A fixed-output derivation can be created by specifying the
  `outputHash' and `outputHashAlgo' attributes, the latter taking
  values `md5', `sha1', and `sha256', and the former specifying the
  actual hash in hexadecimal or in base-32 (auto-detected by looking
  at the length of the attribute value).  MD5 is included for
  compatibility but should be considered deprecated.

* Removed the `drvPath' pseudo-attribute in derivation results.  It's
  no longer necessary.

* Cleaned up the support for multiple output paths in derivation store
  expressions.  Each output now has a unique identifier (e.g., `out',
  `devel', `docs').  Previously there was no way to tell output paths
  apart at the store expression level.

* `nix-hash' now has a flag `--base32' to specify that the hash should
  be printed in base-32 notation.

* `fetchurl' accepts parameters `sha256' and `sha1' in addition to
  `md5'.

* `nix-prefetch-url' now prints out a SHA-1 hash in base-32.  (TODO: a
  flag to specify the hash.)
2005-01-17 16:55:19 +00:00

215 lines
5.7 KiB
C++

#include "storeexpr.hh"
#include "globals.hh"
#include "store.hh"
#include "storeexpr-ast.hh"
#include "storeexpr-ast.cc"
Hash hashTerm(ATerm t)
{
return hashString(htSHA256, atPrint(t));
}
Path writeTerm(ATerm t, const string & suffix)
{
char * s = ATwriteToString(t);
if (!s) throw Error("cannot print aterm");
return addTextToStore(suffix + ".store", string(s));
}
void checkPath(const string & s)
{
if (s.size() == 0 || s[0] != '/')
throw Error(format("bad path `%1%' in store expression") % s);
}
static void parsePaths(ATermList paths, PathSet & out)
{
for (ATermIterator i(paths); i; ++i) {
if (ATgetType(*i) != AT_APPL)
throw badTerm("not a path", *i);
string s = aterm2String(*i);
checkPath(s);
out.insert(s);
}
}
static void checkClosure(const Closure & closure)
{
if (closure.elems.size() == 0)
throw Error("empty closure");
PathSet decl;
for (ClosureElems::const_iterator i = closure.elems.begin();
i != closure.elems.end(); i++)
decl.insert(i->first);
for (PathSet::const_iterator i = closure.roots.begin();
i != closure.roots.end(); i++)
if (decl.find(*i) == decl.end())
throw Error(format("undefined root path `%1%'") % *i);
for (ClosureElems::const_iterator i = closure.elems.begin();
i != closure.elems.end(); i++)
for (PathSet::const_iterator j = i->second.refs.begin();
j != i->second.refs.end(); j++)
if (decl.find(*j) == decl.end())
throw Error(
format("undefined path `%1%' referenced by `%2%'")
% *j % i->first);
}
/* Parse a closure. */
static bool parseClosure(ATerm t, Closure & closure)
{
ATermList roots, elems;
if (!matchClosure(t, roots, elems))
return false;
parsePaths(roots, closure.roots);
for (ATermIterator i(elems); i; ++i) {
ATerm path;
ATermList refs;
if (!matchClosureElem(*i, path, refs))
throw badTerm("not a closure element", *i);
ClosureElem elem;
parsePaths(refs, elem.refs);
closure.elems[aterm2String(path)] = elem;
}
checkClosure(closure);
return true;
}
static bool parseDerivation(ATerm t, Derivation & derivation)
{
ATermList outs, ins, args, bnds;
ATerm builder, platform;
if (!matchDerive(t, outs, ins, platform, builder, args, bnds))
return false;
for (ATermIterator i(outs); i; ++i) {
ATerm id, path, hashAlgo, hash;
if (!matchDerivationOutput(*i, id, path, hashAlgo, hash))
return false;
DerivationOutput out;
out.path = aterm2String(path);
checkPath(out.path);
out.hashAlgo = aterm2String(hashAlgo);
out.hash = aterm2String(hash);
derivation.outputs[aterm2String(id)] = out;
}
parsePaths(ins, derivation.inputs);
derivation.builder = aterm2String(builder);
derivation.platform = aterm2String(platform);
for (ATermIterator i(args); i; ++i) {
if (ATgetType(*i) != AT_APPL)
throw badTerm("string expected", *i);
derivation.args.push_back(aterm2String(*i));
}
for (ATermIterator i(bnds); i; ++i) {
ATerm s1, s2;
if (!matchEnvBinding(*i, s1, s2))
throw badTerm("tuple of strings expected", *i);
derivation.env[aterm2String(s1)] = aterm2String(s2);
}
return true;
}
StoreExpr parseStoreExpr(ATerm t)
{
StoreExpr ne;
if (parseClosure(t, ne.closure))
ne.type = StoreExpr::neClosure;
else if (parseDerivation(t, ne.derivation))
ne.type = StoreExpr::neDerivation;
else throw badTerm("not a store expression", t);
return ne;
}
static ATermList unparsePaths(const PathSet & paths)
{
ATermList l = ATempty;
for (PathSet::const_iterator i = paths.begin();
i != paths.end(); i++)
l = ATinsert(l, toATerm(*i));
return ATreverse(l);
}
static ATerm unparseClosure(const Closure & closure)
{
ATermList roots = unparsePaths(closure.roots);
ATermList elems = ATempty;
for (ClosureElems::const_iterator i = closure.elems.begin();
i != closure.elems.end(); i++)
elems = ATinsert(elems,
makeClosureElem(
toATerm(i->first),
unparsePaths(i->second.refs)));
return makeClosure(roots, elems);
}
static ATerm unparseDerivation(const Derivation & derivation)
{
ATermList outputs = ATempty;
for (DerivationOutputs::const_iterator i = derivation.outputs.begin();
i != derivation.outputs.end(); i++)
outputs = ATinsert(outputs,
makeDerivationOutput(
toATerm(i->first),
toATerm(i->second.path),
toATerm(i->second.hashAlgo),
toATerm(i->second.hash)));
ATermList args = ATempty;
for (Strings::const_iterator i = derivation.args.begin();
i != derivation.args.end(); i++)
args = ATinsert(args, toATerm(*i));
ATermList env = ATempty;
for (StringPairs::const_iterator i = derivation.env.begin();
i != derivation.env.end(); i++)
env = ATinsert(env,
makeEnvBinding(
toATerm(i->first),
toATerm(i->second)));
return makeDerive(
ATreverse(outputs),
unparsePaths(derivation.inputs),
toATerm(derivation.platform),
toATerm(derivation.builder),
ATreverse(args),
ATreverse(env));
}
ATerm unparseStoreExpr(const StoreExpr & ne)
{
if (ne.type == StoreExpr::neClosure)
return unparseClosure(ne.closure);
else if (ne.type == StoreExpr::neDerivation)
return unparseDerivation(ne.derivation);
else abort();
}