static void coalesce(Value::Ranges* ranges, const Value::Range& range)
{
// Note that we assume that ranges has already been coalesced.
Value::Ranges result;
Value::Range temp = range;
for (int i = 0; i < ranges->range_size(); i++) {
const Value::Range& current = ranges->range(i);
// Check if current and range overlap. Note, we only need to
// compare with range and not with temp to check for overlap
// because we expect ranges to be coalesced to begin with!
if (current.begin() <= range.end() && current.end() >= range.begin() ) {
// Update temp with new boundaries.
temp.set_begin(std::min(range.begin(), current.begin()));
temp.set_end(std::max(range.end(), current.end()));
} else { // No overlap.
result.add_range()->MergeFrom(current);
}
}
result.add_range()->MergeFrom(temp);
*ranges = result;
}
static void add(Value::Ranges* result, int64_t begin, int64_t end)
{
if (begin > end) {
return;
}
Value::Range* range = result->add_range();
range->set_begin(begin);
range->set_end(end);
}
TEST(ResourcesTest, ParsingWithRoles)
{
Resources parse1 = Resources::parse("cpus(role1):2;mem(role1):3").get();
Resource cpus;
cpus.set_name("cpus");
cpus.set_type(Value::SCALAR);
cpus.mutable_scalar()->set_value(2);
cpus.set_role("role1");
Resource mem;
mem.set_name("mem");
mem.set_type(Value::SCALAR);
mem.mutable_scalar()->set_value(3);
mem.set_role("role1");
Resources resources1;
resources1 += cpus;
resources1 += mem;
EXPECT_EQ(parse1, resources1);
EXPECT_EQ(resources1, Resources::parse(stringify(resources1)).get());
Resources parse2 = Resources::parse(
"cpus(role1):2.5;ports(role2):[0-100]").get();
Resource cpus2;
cpus2.set_name("cpus");
cpus2.set_type(Value::SCALAR);
cpus2.mutable_scalar()->set_value(2.5);
cpus2.set_role("role1");
Resource ports;
ports.set_name("ports");
ports.set_type(Value::RANGES);
Value::Range* range = ports.mutable_ranges()->add_range();
range->set_begin(0);
range->set_end(100);
ports.set_role("role2");
Resources resources2;
resources2 += ports;
resources2 += cpus2;
EXPECT_EQ(parse2, resources2);
EXPECT_EQ(resources2, Resources::parse(stringify(resources2)).get());
Resources parse3 = Resources::parse(
"cpus:2.5;ports(role2):[0-100]", "role1").get();
EXPECT_EQ(parse2, parse3);
}
// Subtract `right_` from `left_`, and return the result as Value::Ranges.
Value::Ranges subtract(const Value::Ranges& left_, const Value::Ranges& right_)
{
if (left_.range_size() == 0 || right_.range_size() == 0) {
return left_;
}
// Convert the input `Ranges` to `vector<internal::Range>` and
// sort the vector based on the start of a range.
auto sortRanges = [](const Value::Ranges& ranges) {
vector<internal::Range> result;
result.reserve(ranges.range_size());
foreach (const Value::Range& range, ranges.range()) {
result.push_back({range.begin(), range.end()});
}
std::sort(
result.begin(),
result.end(),
[](const internal::Range& left, const internal::Range& right) {
return left.start < right.start;
});
return result;
};
Value::Ranges result;
vector<internal::Range> left = sortRanges(left_);
vector<internal::Range> right = sortRanges(right_);
vector<internal::Range>::iterator itLeft = left.begin();
for (vector<internal::Range>::const_iterator itRight = right.cbegin();
itLeft != left.end() && itRight != right.cend();) {
// Non-overlap:
// L: |___|
// R: |___|
if (itLeft->end < itRight->start) {
Value::Range* newRange = result.add_range();
newRange->set_begin(itLeft->start);
newRange->set_end(itLeft->end);
itLeft++;
continue;
}
// Non-overlap:
// L: |___|
// R: |___|
if (itLeft->start > itRight->end) {
itRight++;
continue;
}
if (itLeft->start < itRight->start) {
Value::Range* newRange = result.add_range();
newRange->set_begin(itLeft->start);
newRange->set_end(itRight->start - 1);
if (itLeft->end <= itRight->end) {
// L: |_____|
// R: |____|
itLeft++;
} else {
// L: |________|
// R: |___|
itLeft->start = itRight->end + 1;
itRight++;
}
} else { // itLeft->start >= itRight->start
if (itLeft->end <= itRight->end) {
// L: |____|
// R: |________|
itLeft++;
} else {
// L: |_____|
// R: |____|
itLeft->start = itRight->end + 1;
itRight++;
}
}
}
// Traverse what's left in the `left`, if any.
while (itLeft != left.end()) {
// TODO(mzhu): Consider reserving the exact size.
Value::Range* newRange = result.add_range();
newRange->set_begin(itLeft->start);
newRange->set_end(itLeft->end);
itLeft++;
}
return result;
}
