X-Git-Url: https://code.grnet.gr/git/ganeti-local/blobdiff_plain/9188aeef6e1dd61a16053dbf56c7b16a077f01c8..7d3f42530a2e1cdd6ec09a6098402c7e05fc3bdf:/Ganeti/HTools/Cluster.hs diff --git a/Ganeti/HTools/Cluster.hs b/Ganeti/HTools/Cluster.hs index a3d27c2..c52093d 100644 --- a/Ganeti/HTools/Cluster.hs +++ b/Ganeti/HTools/Cluster.hs @@ -5,40 +5,70 @@ goes into the "Main" module for the individual binaries. -} +{- + +Copyright (C) 2009, 2010 Google Inc. + +This program is free software; you can redistribute it and/or modify +it under the terms of the GNU General Public License as published by +the Free Software Foundation; either version 2 of the License, or +(at your option) any later version. + +This program is distributed in the hope that it will be useful, but +WITHOUT ANY WARRANTY; without even the implied warranty of +MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU +General Public License for more details. + +You should have received a copy of the GNU General Public License +along with this program; if not, write to the Free Software +Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA +02110-1301, USA. + +-} + module Ganeti.HTools.Cluster ( -- * Types - Placement - , Solution(..) + AllocSolution , Table(..) - , Removal - , Score - , IMove(..) + , CStats(..) + , AllocStats -- * Generic functions , totalResources + , computeAllocationDelta -- * First phase functions , computeBadItems -- * Second phase functions - , computeSolution - , applySolution - , printSolution , printSolutionLine , formatCmds + , involvedNodes + , splitJobs + -- * Display functions , printNodes + , printInsts -- * Balacing functions - , applyMove , checkMove + , doNextBalance + , tryBalance , compCV , printStats + , iMoveToJob -- * IAllocator functions - , allocateOnSingle - , allocateOnPair + , tryAlloc + , tryReloc + , tryEvac + , collapseFailures + -- * Allocation functions + , iterateAlloc + , tieredAlloc + , instanceGroup + , findSplitInstances + , splitCluster ) where import Data.List -import Data.Maybe (isNothing, fromJust) +import Data.Ord (comparing) import Text.Printf (printf) -import Data.Function import Control.Monad import qualified Ganeti.HTools.Container as Container @@ -46,58 +76,49 @@ import qualified Ganeti.HTools.Instance as Instance import qualified Ganeti.HTools.Node as Node import Ganeti.HTools.Types import Ganeti.HTools.Utils +import qualified Ganeti.OpCodes as OpCodes -- * Types --- | A separate name for the cluster score type. -type Score = Double - --- | The description of an instance placement. -type Placement = (Idx, Ndx, Ndx, Score) - --- | A cluster solution described as the solution delta and the list --- of placements. -data Solution = Solution Int [Placement] - deriving (Eq, Ord, Show) - --- | A removal set. -data Removal = Removal Node.List [Instance.Instance] - --- | An instance move definition -data IMove = Failover -- ^ Failover the instance (f) - | ReplacePrimary Ndx -- ^ Replace primary (f, r:np, f) - | ReplaceSecondary Ndx -- ^ Replace secondary (r:ns) - | ReplaceAndFailover Ndx -- ^ Replace secondary, failover (r:np, f) - | FailoverAndReplace Ndx -- ^ Failover, replace secondary (f, r:ns) - deriving (Show) +-- | Allocation\/relocation solution. +type AllocSolution = ([FailMode], Int, [(Score, Node.AllocElement)]) -- | The complete state for the balancing solution data Table = Table Node.List Instance.List Score [Placement] deriving (Show) --- * Utility functions - --- | Returns the delta of a solution or -1 for Nothing. -solutionDelta :: Maybe Solution -> Int -solutionDelta sol = case sol of - Just (Solution d _) -> d - _ -> -1 +data CStats = CStats { csFmem :: Int -- ^ Cluster free mem + , csFdsk :: Int -- ^ Cluster free disk + , csAmem :: Int -- ^ Cluster allocatable mem + , csAdsk :: Int -- ^ Cluster allocatable disk + , csAcpu :: Int -- ^ Cluster allocatable cpus + , csMmem :: Int -- ^ Max node allocatable mem + , csMdsk :: Int -- ^ Max node allocatable disk + , csMcpu :: Int -- ^ Max node allocatable cpu + , csImem :: Int -- ^ Instance used mem + , csIdsk :: Int -- ^ Instance used disk + , csIcpu :: Int -- ^ Instance used cpu + , csTmem :: Double -- ^ Cluster total mem + , csTdsk :: Double -- ^ Cluster total disk + , csTcpu :: Double -- ^ Cluster total cpus + , csVcpu :: Int -- ^ Cluster virtual cpus (if + -- node pCpu has been set, + -- otherwise -1) + , csXmem :: Int -- ^ Unnacounted for mem + , csNmem :: Int -- ^ Node own memory + , csScore :: Score -- ^ The cluster score + , csNinst :: Int -- ^ The total number of instances + } + deriving (Show) + +-- | Currently used, possibly to allocate, unallocable +type AllocStats = (RSpec, RSpec, RSpec) --- | Cap the removal list if needed. -capRemovals :: [a] -> Int -> [a] -capRemovals removals max_removals = - if max_removals > 0 then - take max_removals removals - else - removals - --- | Check if the given node list fails the N+1 check. -verifyN1Check :: [Node.Node] -> Bool -verifyN1Check nl = any Node.failN1 nl +-- * Utility functions -- | Verifies the N+1 status and return the affected nodes. verifyN1 :: [Node.Node] -> [Node.Node] -verifyN1 nl = filter Node.failN1 nl +verifyN1 = filter Node.failN1 {-| Computes the pair of bad nodes and instances. @@ -109,302 +130,153 @@ those nodes. computeBadItems :: Node.List -> Instance.List -> ([Node.Node], [Instance.Instance]) computeBadItems nl il = - let bad_nodes = verifyN1 $ filter (not . Node.offline) $ Container.elems nl - bad_instances = map (\idx -> Container.find idx il) $ - sort $ nub $ concat $ - map (\ n -> (Node.slist n) ++ (Node.plist n)) bad_nodes + let bad_nodes = verifyN1 $ getOnline nl + bad_instances = map (`Container.find` il) . + sort . nub $ + concatMap (\ n -> Node.sList n ++ Node.pList n) bad_nodes in (bad_nodes, bad_instances) +-- | Zero-initializer for the CStats type +emptyCStats :: CStats +emptyCStats = CStats 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 + +-- | Update stats with data from a new node +updateCStats :: CStats -> Node.Node -> CStats +updateCStats cs node = + let CStats { csFmem = x_fmem, csFdsk = x_fdsk, + csAmem = x_amem, csAcpu = x_acpu, csAdsk = x_adsk, + csMmem = x_mmem, csMdsk = x_mdsk, csMcpu = x_mcpu, + csImem = x_imem, csIdsk = x_idsk, csIcpu = x_icpu, + csTmem = x_tmem, csTdsk = x_tdsk, csTcpu = x_tcpu, + csVcpu = x_vcpu, + csXmem = x_xmem, csNmem = x_nmem, csNinst = x_ninst + } + = cs + inc_amem = Node.fMem node - Node.rMem node + inc_amem' = if inc_amem > 0 then inc_amem else 0 + inc_adsk = Node.availDisk node + inc_imem = truncate (Node.tMem node) - Node.nMem node + - Node.xMem node - Node.fMem node + inc_icpu = Node.uCpu node + inc_idsk = truncate (Node.tDsk node) - Node.fDsk node + inc_vcpu = Node.hiCpu node + + in cs { csFmem = x_fmem + Node.fMem node + , csFdsk = x_fdsk + Node.fDsk node + , csAmem = x_amem + inc_amem' + , csAdsk = x_adsk + inc_adsk + , csAcpu = x_acpu + , csMmem = max x_mmem inc_amem' + , csMdsk = max x_mdsk inc_adsk + , csMcpu = x_mcpu + , csImem = x_imem + inc_imem + , csIdsk = x_idsk + inc_idsk + , csIcpu = x_icpu + inc_icpu + , csTmem = x_tmem + Node.tMem node + , csTdsk = x_tdsk + Node.tDsk node + , csTcpu = x_tcpu + Node.tCpu node + , csVcpu = x_vcpu + inc_vcpu + , csXmem = x_xmem + Node.xMem node + , csNmem = x_nmem + Node.nMem node + , csNinst = x_ninst + length (Node.pList node) + } + -- | Compute the total free disk and memory in the cluster. -totalResources :: Container.Container Node.Node -> (Int, Int) +totalResources :: Node.List -> CStats totalResources nl = - foldl' - (\ (mem, dsk) node -> (mem + (Node.f_mem node), - dsk + (Node.f_dsk node))) - (0, 0) (Container.elems nl) + let cs = foldl' updateCStats emptyCStats . Container.elems $ nl + in cs { csScore = compCV nl } + +-- | Compute the delta between two cluster state. +-- +-- This is used when doing allocations, to understand better the +-- available cluster resources. The return value is a triple of the +-- current used values, the delta that was still allocated, and what +-- was left unallocated. +computeAllocationDelta :: CStats -> CStats -> AllocStats +computeAllocationDelta cini cfin = + let CStats {csImem = i_imem, csIdsk = i_idsk, csIcpu = i_icpu} = cini + CStats {csImem = f_imem, csIdsk = f_idsk, csIcpu = f_icpu, + csTmem = t_mem, csTdsk = t_dsk, csVcpu = v_cpu } = cfin + rini = RSpec i_icpu i_imem i_idsk + rfin = RSpec (f_icpu - i_icpu) (f_imem - i_imem) (f_idsk - i_idsk) + un_cpu = v_cpu - f_icpu + runa = RSpec un_cpu (truncate t_mem - f_imem) (truncate t_dsk - f_idsk) + in (rini, rfin, runa) + +-- | The names and weights of the individual elements in the CV list +detailedCVInfo :: [(Double, String)] +detailedCVInfo = [ (1, "free_mem_cv") + , (1, "free_disk_cv") + , (1, "n1_cnt") + , (1, "reserved_mem_cv") + , (4, "offline_all_cnt") + , (16, "offline_pri_cnt") + , (1, "vcpu_ratio_cv") + , (1, "cpu_load_cv") + , (1, "mem_load_cv") + , (1, "disk_load_cv") + , (1, "net_load_cv") + , (2, "pri_tags_score") + ] + +detailedCVWeights :: [Double] +detailedCVWeights = map fst detailedCVInfo -- | Compute the mem and disk covariance. -compDetailedCV :: Node.List -> (Double, Double, Double, Double, Double) +compDetailedCV :: Node.List -> [Double] compDetailedCV nl = let all_nodes = Container.elems nl (offline, nodes) = partition Node.offline all_nodes - mem_l = map Node.p_mem nodes - dsk_l = map Node.p_dsk nodes + mem_l = map Node.pMem nodes + dsk_l = map Node.pDsk nodes + -- metric: memory covariance mem_cv = varianceCoeff mem_l + -- metric: disk covariance dsk_cv = varianceCoeff dsk_l - n1_l = length $ filter Node.failN1 nodes - n1_score = (fromIntegral n1_l) / (fromIntegral $ length nodes) - res_l = map Node.p_rem nodes + -- metric: count of instances living on N1 failing nodes + n1_score = fromIntegral . sum . map (\n -> length (Node.sList n) + + length (Node.pList n)) . + filter Node.failN1 $ nodes :: Double + res_l = map Node.pRem nodes + -- metric: reserved memory covariance res_cv = varianceCoeff res_l - offline_inst = sum . map (\n -> (length . Node.plist $ n) + - (length . Node.slist $ n)) $ offline - online_inst = sum . map (\n -> (length . Node.plist $ n) + - (length . Node.slist $ n)) $ nodes - off_score = (fromIntegral offline_inst) / - (fromIntegral $ online_inst + offline_inst) - in (mem_cv, dsk_cv, n1_score, res_cv, off_score) + -- offline instances metrics + offline_ipri = sum . map (length . Node.pList) $ offline + offline_isec = sum . map (length . Node.sList) $ offline + -- metric: count of instances on offline nodes + off_score = fromIntegral (offline_ipri + offline_isec)::Double + -- metric: count of primary instances on offline nodes (this + -- helps with evacuation/failover of primary instances on + -- 2-node clusters with one node offline) + off_pri_score = fromIntegral offline_ipri::Double + cpu_l = map Node.pCpu nodes + -- metric: covariance of vcpu/pcpu ratio + cpu_cv = varianceCoeff cpu_l + -- metrics: covariance of cpu, memory, disk and network load + (c_load, m_load, d_load, n_load) = unzip4 $ + map (\n -> + let DynUtil c1 m1 d1 n1 = Node.utilLoad n + DynUtil c2 m2 d2 n2 = Node.utilPool n + in (c1/c2, m1/m2, d1/d2, n1/n2) + ) nodes + -- metric: conflicting instance count + pri_tags_inst = sum $ map Node.conflictingPrimaries nodes + pri_tags_score = fromIntegral pri_tags_inst::Double + in [ mem_cv, dsk_cv, n1_score, res_cv, off_score, off_pri_score, cpu_cv + , varianceCoeff c_load, varianceCoeff m_load + , varianceCoeff d_load, varianceCoeff n_load + , pri_tags_score ] -- | Compute the /total/ variance. compCV :: Node.List -> Double -compCV nl = - let (mem_cv, dsk_cv, n1_score, res_cv, off_score) = compDetailedCV nl - in mem_cv + dsk_cv + n1_score + res_cv + off_score - --- * hn1 functions - --- | Add an instance and return the new node and instance maps. -addInstance :: Node.List -> Instance.Instance -> - Node.Node -> Node.Node -> Maybe Node.List -addInstance nl idata pri sec = - let pdx = Node.idx pri - sdx = Node.idx sec - in do - pnode <- Node.addPri pri idata - snode <- Node.addSec sec idata pdx - new_nl <- return $ Container.addTwo sdx snode - pdx pnode nl - return new_nl - --- | Remove an instance and return the new node and instance maps. -removeInstance :: Node.List -> Instance.Instance -> Node.List -removeInstance nl idata = - let pnode = Instance.pnode idata - snode = Instance.snode idata - pn = Container.find pnode nl - sn = Container.find snode nl - new_nl = Container.addTwo - pnode (Node.removePri pn idata) - snode (Node.removeSec sn idata) nl in - new_nl - --- | Remove an instance and return the new node map. -removeInstances :: Node.List -> [Instance.Instance] -> Node.List -removeInstances = foldl' removeInstance - - -{-| Compute a new version of a cluster given a solution. - -This is not used for computing the solutions, but for applying a -(known-good) solution to the original cluster for final display. - -It first removes the relocated instances after which it places them on -their new nodes. - - -} -applySolution :: Node.List -> Instance.List -> [Placement] -> Node.List -applySolution nl il sol = - let odxes = map (\ (a, b, c, _) -> (Container.find a il, - Node.idx (Container.find b nl), - Node.idx (Container.find c nl)) - ) sol - idxes = (\ (x, _, _) -> x) (unzip3 odxes) - nc = removeInstances nl idxes - in - foldl' (\ nz (a, b, c) -> - let new_p = Container.find b nz - new_s = Container.find c nz in - fromJust (addInstance nz a new_p new_s) - ) nc odxes - - --- ** First phase functions - -{-| Given a list 1,2,3..n build a list of pairs [(1, [2..n]), (2, - [3..n]), ...] - --} -genParts :: [a] -> Int -> [(a, [a])] -genParts l count = - case l of - [] -> [] - x:xs -> - if length l < count then - [] - else - (x, xs) : (genParts xs count) - --- | Generates combinations of count items from the names list. -genNames :: Int -> [b] -> [[b]] -genNames count1 names1 = - let aux_fn count names current = - case count of - 0 -> [current] - _ -> - concatMap - (\ (x, xs) -> aux_fn (count - 1) xs (x:current)) - (genParts names count) - in - aux_fn count1 names1 [] - -{-| Checks if removal of instances results in N+1 pass. +compCV = sum . zipWith (*) detailedCVWeights . compDetailedCV -Note: the check removal cannot optimize by scanning only the affected -nodes, since the cluster is known to be not healthy; only the check -placement can make this shortcut. - --} -checkRemoval :: Node.List -> [Instance.Instance] -> Maybe Removal -checkRemoval nl victims = - let nx = removeInstances nl victims - failN1 = verifyN1Check (Container.elems nx) - in - if failN1 then - Nothing - else - Just $ Removal nx victims - - --- | Computes the removals list for a given depth. -computeRemovals :: Node.List - -> [Instance.Instance] - -> Int - -> [Maybe Removal] -computeRemovals nl bad_instances depth = - map (checkRemoval nl) $ genNames depth bad_instances - --- ** Second phase functions - --- | Single-node relocation cost. -nodeDelta :: Ndx -> Ndx -> Ndx -> Int -nodeDelta i p s = - if i == p || i == s then - 0 - else - 1 - --- | Compute best solution. --- --- This function compares two solutions, choosing the minimum valid --- solution. -compareSolutions :: Maybe Solution -> Maybe Solution -> Maybe Solution -compareSolutions a b = case (a, b) of - (Nothing, x) -> x - (x, Nothing) -> x - (x, y) -> min x y - --- | Check if a given delta is worse then an existing solution. -tooHighDelta :: Maybe Solution -> Int -> Int -> Bool -tooHighDelta sol new_delta max_delta = - if new_delta > max_delta && max_delta >=0 then - True - else - case sol of - Nothing -> False - Just (Solution old_delta _) -> old_delta <= new_delta - -{-| Check if placement of instances still keeps the cluster N+1 compliant. - - This is the workhorse of the allocation algorithm: given the - current node and instance maps, the list of instances to be - placed, and the current solution, this will return all possible - solution by recursing until all target instances are placed. - --} -checkPlacement :: Node.List -- ^ The current node list - -> [Instance.Instance] -- ^ List of instances still to place - -> [Placement] -- ^ Partial solution until now - -> Int -- ^ The delta of the partial solution - -> Maybe Solution -- ^ The previous solution - -> Int -- ^ Abort if the we go above this delta - -> Maybe Solution -- ^ The new solution -checkPlacement nl victims current current_delta prev_sol max_delta = - let target = head victims - opdx = Instance.pnode target - osdx = Instance.snode target - vtail = tail victims - have_tail = (length vtail) > 0 - nodes = Container.elems nl - iidx = Instance.idx target - in - foldl' - (\ accu_p pri -> - let - pri_idx = Node.idx pri - upri_delta = current_delta + nodeDelta pri_idx opdx osdx - new_pri = Node.addPri pri target - fail_delta1 = tooHighDelta accu_p upri_delta max_delta - in - if fail_delta1 || isNothing(new_pri) then accu_p - else let pri_nl = Container.add pri_idx (fromJust new_pri) nl in - foldl' - (\ accu sec -> - let - sec_idx = Node.idx sec - upd_delta = upri_delta + - nodeDelta sec_idx opdx osdx - fail_delta2 = tooHighDelta accu upd_delta max_delta - new_sec = Node.addSec sec target pri_idx - in - if sec_idx == pri_idx || fail_delta2 || - isNothing new_sec then accu - else let - nx = Container.add sec_idx (fromJust new_sec) pri_nl - upd_cv = compCV nx - plc = (iidx, pri_idx, sec_idx, upd_cv) - c2 = plc:current - result = - if have_tail then - checkPlacement nx vtail c2 upd_delta - accu max_delta - else - Just (Solution upd_delta c2) - in compareSolutions accu result - ) accu_p nodes - ) prev_sol nodes - -{-| Auxiliary function for solution computation. - -We write this in an explicit recursive fashion in order to control -early-abort in case we have met the min delta. We can't use foldr -instead of explicit recursion since we need the accumulator for the -abort decision. - --} -advanceSolution :: [Maybe Removal] -- ^ The removal to process - -> Int -- ^ Minimum delta parameter - -> Int -- ^ Maximum delta parameter - -> Maybe Solution -- ^ Current best solution - -> Maybe Solution -- ^ New best solution -advanceSolution [] _ _ sol = sol -advanceSolution (Nothing:xs) m n sol = advanceSolution xs m n sol -advanceSolution ((Just (Removal nx removed)):xs) min_d max_d prev_sol = - let new_sol = checkPlacement nx removed [] 0 prev_sol max_d - new_delta = solutionDelta $! new_sol - in - if new_delta >= 0 && new_delta <= min_d then - new_sol - else - advanceSolution xs min_d max_d new_sol - --- | Computes the placement solution. -solutionFromRemovals :: [Maybe Removal] -- ^ The list of (possible) removals - -> Int -- ^ Minimum delta parameter - -> Int -- ^ Maximum delta parameter - -> Maybe Solution -- ^ The best solution found -solutionFromRemovals removals min_delta max_delta = - advanceSolution removals min_delta max_delta Nothing - -{-| Computes the solution at the given depth. - -This is a wrapper over both computeRemovals and -solutionFromRemovals. In case we have no solution, we return Nothing. - --} -computeSolution :: Node.List -- ^ The original node data - -> [Instance.Instance] -- ^ The list of /bad/ instances - -> Int -- ^ The /depth/ of removals - -> Int -- ^ Maximum number of removals to process - -> Int -- ^ Minimum delta parameter - -> Int -- ^ Maximum delta parameter - -> Maybe Solution -- ^ The best solution found (or Nothing) -computeSolution nl bad_instances depth max_removals min_delta max_delta = - let - removals = computeRemovals nl bad_instances depth - removals' = capRemovals removals max_removals - in - solutionFromRemovals removals' min_delta max_delta +-- | Compute online nodes from a Node.List +getOnline :: Node.List -> [Node.Node] +getOnline = filter (not . Node.offline) . Container.elems -- * hbal functions @@ -415,101 +287,123 @@ compareTables a@(Table _ _ a_cv _) b@(Table _ _ b_cv _ ) = -- | Applies an instance move to a given node list and instance. applyMove :: Node.List -> Instance.Instance - -> IMove -> (Maybe Node.List, Instance.Instance, Ndx, Ndx) + -> IMove -> OpResult (Node.List, Instance.Instance, Ndx, Ndx) -- Failover (f) applyMove nl inst Failover = - let old_pdx = Instance.pnode inst - old_sdx = Instance.snode inst + let old_pdx = Instance.pNode inst + old_sdx = Instance.sNode inst old_p = Container.find old_pdx nl old_s = Container.find old_sdx nl int_p = Node.removePri old_p inst int_s = Node.removeSec old_s inst + force_p = Node.offline old_p new_nl = do -- Maybe monad - new_p <- Node.addPri int_s inst + new_p <- Node.addPriEx force_p int_s inst new_s <- Node.addSec int_p inst old_sdx - return $ Container.addTwo old_pdx new_s old_sdx new_p nl - in (new_nl, Instance.setBoth inst old_sdx old_pdx, old_sdx, old_pdx) + let new_inst = Instance.setBoth inst old_sdx old_pdx + return (Container.addTwo old_pdx new_s old_sdx new_p nl, + new_inst, old_sdx, old_pdx) + in new_nl -- Replace the primary (f:, r:np, f) applyMove nl inst (ReplacePrimary new_pdx) = - let old_pdx = Instance.pnode inst - old_sdx = Instance.snode inst + let old_pdx = Instance.pNode inst + old_sdx = Instance.sNode inst old_p = Container.find old_pdx nl old_s = Container.find old_sdx nl tgt_n = Container.find new_pdx nl int_p = Node.removePri old_p inst int_s = Node.removeSec old_s inst + force_p = Node.offline old_p new_nl = do -- Maybe monad - new_p <- Node.addPri tgt_n inst - new_s <- Node.addSec int_s inst new_pdx - return $ Container.add new_pdx new_p $ - Container.addTwo old_pdx int_p old_sdx new_s nl - in (new_nl, Instance.setPri inst new_pdx, new_pdx, old_sdx) + -- check that the current secondary can host the instance + -- during the migration + tmp_s <- Node.addPriEx force_p int_s inst + let tmp_s' = Node.removePri tmp_s inst + new_p <- Node.addPriEx force_p tgt_n inst + new_s <- Node.addSecEx force_p tmp_s' inst new_pdx + let new_inst = Instance.setPri inst new_pdx + return (Container.add new_pdx new_p $ + Container.addTwo old_pdx int_p old_sdx new_s nl, + new_inst, new_pdx, old_sdx) + in new_nl -- Replace the secondary (r:ns) applyMove nl inst (ReplaceSecondary new_sdx) = - let old_pdx = Instance.pnode inst - old_sdx = Instance.snode inst + let old_pdx = Instance.pNode inst + old_sdx = Instance.sNode inst old_s = Container.find old_sdx nl tgt_n = Container.find new_sdx nl int_s = Node.removeSec old_s inst - new_nl = Node.addSec tgt_n inst old_pdx >>= - \new_s -> return $ Container.addTwo new_sdx - new_s old_sdx int_s nl - in (new_nl, Instance.setSec inst new_sdx, old_pdx, new_sdx) + force_s = Node.offline old_s + new_inst = Instance.setSec inst new_sdx + new_nl = Node.addSecEx force_s tgt_n inst old_pdx >>= + \new_s -> return (Container.addTwo new_sdx + new_s old_sdx int_s nl, + new_inst, old_pdx, new_sdx) + in new_nl -- Replace the secondary and failover (r:np, f) applyMove nl inst (ReplaceAndFailover new_pdx) = - let old_pdx = Instance.pnode inst - old_sdx = Instance.snode inst + let old_pdx = Instance.pNode inst + old_sdx = Instance.sNode inst old_p = Container.find old_pdx nl old_s = Container.find old_sdx nl tgt_n = Container.find new_pdx nl int_p = Node.removePri old_p inst int_s = Node.removeSec old_s inst + force_s = Node.offline old_s new_nl = do -- Maybe monad new_p <- Node.addPri tgt_n inst - new_s <- Node.addSec int_p inst new_pdx - return $ Container.add new_pdx new_p $ - Container.addTwo old_pdx new_s old_sdx int_s nl - in (new_nl, Instance.setBoth inst new_pdx old_pdx, new_pdx, old_pdx) + new_s <- Node.addSecEx force_s int_p inst new_pdx + let new_inst = Instance.setBoth inst new_pdx old_pdx + return (Container.add new_pdx new_p $ + Container.addTwo old_pdx new_s old_sdx int_s nl, + new_inst, new_pdx, old_pdx) + in new_nl -- Failver and replace the secondary (f, r:ns) applyMove nl inst (FailoverAndReplace new_sdx) = - let old_pdx = Instance.pnode inst - old_sdx = Instance.snode inst + let old_pdx = Instance.pNode inst + old_sdx = Instance.sNode inst old_p = Container.find old_pdx nl old_s = Container.find old_sdx nl tgt_n = Container.find new_sdx nl int_p = Node.removePri old_p inst int_s = Node.removeSec old_s inst + force_p = Node.offline old_p new_nl = do -- Maybe monad - new_p <- Node.addPri int_s inst - new_s <- Node.addSec tgt_n inst old_sdx - return $ Container.add new_sdx new_s $ - Container.addTwo old_sdx new_p old_pdx int_p nl - in (new_nl, Instance.setBoth inst old_sdx new_sdx, old_sdx, new_sdx) + new_p <- Node.addPriEx force_p int_s inst + new_s <- Node.addSecEx force_p tgt_n inst old_sdx + let new_inst = Instance.setBoth inst old_sdx new_sdx + return (Container.add new_sdx new_s $ + Container.addTwo old_sdx new_p old_pdx int_p nl, + new_inst, old_sdx, new_sdx) + in new_nl -- | Tries to allocate an instance on one given node. allocateOnSingle :: Node.List -> Instance.Instance -> Node.Node - -> (Maybe Node.List, Instance.Instance) + -> OpResult Node.AllocElement allocateOnSingle nl inst p = let new_pdx = Node.idx p - new_nl = Node.addPri p inst >>= \new_p -> - return $ Container.add new_pdx new_p nl - in (new_nl, Instance.setBoth inst new_pdx Node.noSecondary) + new_inst = Instance.setBoth inst new_pdx Node.noSecondary + in Node.addPri p inst >>= \new_p -> do + let new_nl = Container.add new_pdx new_p nl + new_score = compCV nl + return (new_nl, new_inst, [new_p], new_score) -- | Tries to allocate an instance on a given pair of nodes. allocateOnPair :: Node.List -> Instance.Instance -> Node.Node -> Node.Node - -> (Maybe Node.List, Instance.Instance) + -> OpResult Node.AllocElement allocateOnPair nl inst tgt_p tgt_s = let new_pdx = Node.idx tgt_p new_sdx = Node.idx tgt_s - new_nl = do -- Maybe monad - new_p <- Node.addPri tgt_p inst - new_s <- Node.addSec tgt_s inst new_pdx - return $ Container.addTwo new_pdx new_p new_sdx new_s nl - in (new_nl, Instance.setBoth inst new_pdx new_sdx) + in do + new_p <- Node.addPri tgt_p inst + new_s <- Node.addSec tgt_s inst new_pdx + let new_inst = Instance.setBoth inst new_pdx new_sdx + new_nl = Container.addTwo new_pdx new_p new_sdx new_s nl + return (new_nl, new_inst, [new_p, new_s], compCV new_nl) -- | Tries to perform an instance move and returns the best table -- between the original one and the new one. @@ -521,23 +415,25 @@ checkSingleStep :: Table -- ^ The original table checkSingleStep ini_tbl target cur_tbl move = let Table ini_nl ini_il _ ini_plc = ini_tbl - (tmp_nl, new_inst, pri_idx, sec_idx) = applyMove ini_nl target move + tmp_resu = applyMove ini_nl target move in - if isNothing tmp_nl then cur_tbl - else - let tgt_idx = Instance.idx target - upd_nl = fromJust tmp_nl - upd_cvar = compCV upd_nl - upd_il = Container.add tgt_idx new_inst ini_il - upd_plc = (tgt_idx, pri_idx, sec_idx, upd_cvar):ini_plc - upd_tbl = Table upd_nl upd_il upd_cvar upd_plc - in - compareTables cur_tbl upd_tbl - --- | Given the status of the current secondary as a valid new node --- and the current candidate target node, --- generate the possible moves for a instance. -possibleMoves :: Bool -> Ndx -> [IMove] + case tmp_resu of + OpFail _ -> cur_tbl + OpGood (upd_nl, new_inst, pri_idx, sec_idx) -> + let tgt_idx = Instance.idx target + upd_cvar = compCV upd_nl + upd_il = Container.add tgt_idx new_inst ini_il + upd_plc = (tgt_idx, pri_idx, sec_idx, move, upd_cvar):ini_plc + upd_tbl = Table upd_nl upd_il upd_cvar upd_plc + in + compareTables cur_tbl upd_tbl + +-- | Given the status of the current secondary as a valid new node and +-- the current candidate target node, generate the possible moves for +-- a instance. +possibleMoves :: Bool -- ^ Whether the secondary node is a valid new node + -> Ndx -- ^ Target node candidate + -> [IMove] -- ^ List of valid result moves possibleMoves True tdx = [ReplaceSecondary tdx, ReplaceAndFailover tdx, @@ -549,53 +445,239 @@ possibleMoves False tdx = ReplaceAndFailover tdx] -- | Compute the best move for a given instance. -checkInstanceMove :: [Ndx] -- Allowed target node indices - -> Table -- Original table - -> Instance.Instance -- Instance to move - -> Table -- Best new table for this instance -checkInstanceMove nodes_idx ini_tbl target = +checkInstanceMove :: [Ndx] -- ^ Allowed target node indices + -> Bool -- ^ Whether disk moves are allowed + -> Table -- ^ Original table + -> Instance.Instance -- ^ Instance to move + -> Table -- ^ Best new table for this instance +checkInstanceMove nodes_idx disk_moves ini_tbl target = let - opdx = Instance.pnode target - osdx = Instance.snode target + opdx = Instance.pNode target + osdx = Instance.sNode target nodes = filter (\idx -> idx /= opdx && idx /= osdx) nodes_idx use_secondary = elem osdx nodes_idx aft_failover = if use_secondary -- if allowed to failover then checkSingleStep ini_tbl target ini_tbl Failover else ini_tbl - all_moves = concatMap (possibleMoves use_secondary) nodes + all_moves = if disk_moves + then concatMap (possibleMoves use_secondary) nodes + else [] in -- iterate over the possible nodes for this instance foldl' (checkSingleStep ini_tbl target) aft_failover all_moves -- | Compute the best next move. checkMove :: [Ndx] -- ^ Allowed target node indices + -> Bool -- ^ Whether disk moves are allowed -> Table -- ^ The current solution -> [Instance.Instance] -- ^ List of instances still to move -> Table -- ^ The new solution -checkMove nodes_idx ini_tbl victims = +checkMove nodes_idx disk_moves ini_tbl victims = let Table _ _ _ ini_plc = ini_tbl -- iterate over all instances, computing the best move best_tbl = foldl' - (\ step_tbl elem -> - if Instance.snode elem == Node.noSecondary then step_tbl - else compareTables step_tbl $ - checkInstanceMove nodes_idx ini_tbl elem) + (\ step_tbl em -> + compareTables step_tbl $ + checkInstanceMove nodes_idx disk_moves ini_tbl em) ini_tbl victims Table _ _ _ best_plc = best_tbl + in if length best_plc == length ini_plc + then ini_tbl -- no advancement + else best_tbl + +-- | Check if we are allowed to go deeper in the balancing +doNextBalance :: Table -- ^ The starting table + -> Int -- ^ Remaining length + -> Score -- ^ Score at which to stop + -> Bool -- ^ The resulting table and commands +doNextBalance ini_tbl max_rounds min_score = + let Table _ _ ini_cv ini_plc = ini_tbl + ini_plc_len = length ini_plc + in (max_rounds < 0 || ini_plc_len < max_rounds) && ini_cv > min_score + +-- | Run a balance move +tryBalance :: Table -- ^ The starting table + -> Bool -- ^ Allow disk moves + -> Bool -- ^ Only evacuate moves + -> Score -- ^ Min gain threshold + -> Score -- ^ Min gain + -> Maybe Table -- ^ The resulting table and commands +tryBalance ini_tbl disk_moves evac_mode mg_limit min_gain = + let Table ini_nl ini_il ini_cv _ = ini_tbl + all_inst = Container.elems ini_il + all_inst' = if evac_mode + then let bad_nodes = map Node.idx . filter Node.offline $ + Container.elems ini_nl + in filter (\e -> Instance.sNode e `elem` bad_nodes || + Instance.pNode e `elem` bad_nodes) + all_inst + else all_inst + reloc_inst = filter Instance.movable all_inst' + node_idx = map Node.idx . filter (not . Node.offline) $ + Container.elems ini_nl + fin_tbl = checkMove node_idx disk_moves ini_tbl reloc_inst + (Table _ _ fin_cv _) = fin_tbl in - if length best_plc == length ini_plc then -- no advancement - ini_tbl - else - best_tbl - + if fin_cv < ini_cv && (ini_cv > mg_limit || ini_cv - fin_cv >= min_gain) + then Just fin_tbl -- this round made success, return the new table + else Nothing + +-- * Allocation functions + +-- | Build failure stats out of a list of failures +collapseFailures :: [FailMode] -> FailStats +collapseFailures flst = + map (\k -> (k, length $ filter (k ==) flst)) [minBound..maxBound] + +-- | Update current Allocation solution and failure stats with new +-- elements +concatAllocs :: AllocSolution -> OpResult Node.AllocElement -> AllocSolution +concatAllocs (flst, cntok, sols) (OpFail reason) = (reason:flst, cntok, sols) + +concatAllocs (flst, cntok, osols) (OpGood ns@(_, _, _, nscore)) = + let -- Choose the old or new solution, based on the cluster score + nsols = case osols of + [] -> [(nscore, ns)] + (oscore, _):[] -> + if oscore < nscore + then osols + else [(nscore, ns)] + -- FIXME: here we simply concat to lists with more + -- than one element; we should instead abort, since + -- this is not a valid usage of this function + xs -> (nscore, ns):xs + nsuc = cntok + 1 + -- Note: we force evaluation of nsols here in order to keep the + -- memory profile low - we know that we will need nsols for sure + -- in the next cycle, so we force evaluation of nsols, since the + -- foldl' in the caller will only evaluate the tuple, but not the + -- elements of the tuple + in nsols `seq` nsuc `seq` (flst, nsuc, nsols) + +-- | Try to allocate an instance on the cluster. +tryAlloc :: (Monad m) => + Node.List -- ^ The node list + -> Instance.List -- ^ The instance list + -> Instance.Instance -- ^ The instance to allocate + -> Int -- ^ Required number of nodes + -> m AllocSolution -- ^ Possible solution list +tryAlloc nl _ inst 2 = + let all_nodes = getOnline nl + all_pairs = liftM2 (,) all_nodes all_nodes + ok_pairs = filter (\(x, y) -> Node.idx x /= Node.idx y) all_pairs + sols = foldl' (\cstate (p, s) -> + concatAllocs cstate $ allocateOnPair nl inst p s + ) ([], 0, []) ok_pairs + in return sols + +tryAlloc nl _ inst 1 = + let all_nodes = getOnline nl + sols = foldl' (\cstate -> + concatAllocs cstate . allocateOnSingle nl inst + ) ([], 0, []) all_nodes + in return sols + +tryAlloc _ _ _ reqn = fail $ "Unsupported number of allocation \ + \destinations required (" ++ show reqn ++ + "), only two supported" + +-- | Try to allocate an instance on the cluster. +tryReloc :: (Monad m) => + Node.List -- ^ The node list + -> Instance.List -- ^ The instance list + -> Idx -- ^ The index of the instance to move + -> Int -- ^ The number of nodes required + -> [Ndx] -- ^ Nodes which should not be used + -> m AllocSolution -- ^ Solution list +tryReloc nl il xid 1 ex_idx = + let all_nodes = getOnline nl + inst = Container.find xid il + ex_idx' = Instance.pNode inst:ex_idx + valid_nodes = filter (not . flip elem ex_idx' . Node.idx) all_nodes + valid_idxes = map Node.idx valid_nodes + sols1 = foldl' (\cstate x -> + let em = do + (mnl, i, _, _) <- + applyMove nl inst (ReplaceSecondary x) + return (mnl, i, [Container.find x mnl], + compCV mnl) + in concatAllocs cstate em + ) ([], 0, []) valid_idxes + in return sols1 + +tryReloc _ _ _ reqn _ = fail $ "Unsupported number of relocation \ + \destinations required (" ++ show reqn ++ + "), only one supported" + +-- | Try to evacuate a list of nodes. +tryEvac :: (Monad m) => + Node.List -- ^ The node list + -> Instance.List -- ^ The instance list + -> [Ndx] -- ^ Nodes to be evacuated + -> m AllocSolution -- ^ Solution list +tryEvac nl il ex_ndx = + let ex_nodes = map (`Container.find` nl) ex_ndx + all_insts = nub . concatMap Node.sList $ ex_nodes + in do + (_, sol) <- foldM (\(nl', (_, _, rsols)) idx -> do + -- FIXME: hardcoded one node here + (fm, cs, aes) <- tryReloc nl' il idx 1 ex_ndx + case aes of + csol@(_, (nl'', _, _, _)):_ -> + return (nl'', (fm, cs, csol:rsols)) + _ -> fail $ "Can't evacuate instance " ++ + Instance.name (Container.find idx il) + ) (nl, ([], 0, [])) all_insts + return sol + +-- | Recursively place instances on the cluster until we're out of space +iterateAlloc :: Node.List + -> Instance.List + -> Instance.Instance + -> Int + -> [Instance.Instance] + -> Result (FailStats, Node.List, Instance.List, + [Instance.Instance]) +iterateAlloc nl il newinst nreq ixes = + let depth = length ixes + newname = printf "new-%d" depth::String + newidx = length (Container.elems il) + depth + newi2 = Instance.setIdx (Instance.setName newinst newname) newidx + in case tryAlloc nl il newi2 nreq of + Bad s -> Bad s + Ok (errs, _, sols3) -> + case sols3 of + [] -> Ok (collapseFailures errs, nl, il, ixes) + (_, (xnl, xi, _, _)):[] -> + iterateAlloc xnl (Container.add newidx xi il) + newinst nreq $! (xi:ixes) + _ -> Bad "Internal error: multiple solutions for single\ + \ allocation" + +tieredAlloc :: Node.List + -> Instance.List + -> Instance.Instance + -> Int + -> [Instance.Instance] + -> Result (FailStats, Node.List, Instance.List, + [Instance.Instance]) +tieredAlloc nl il newinst nreq ixes = + case iterateAlloc nl il newinst nreq ixes of + Bad s -> Bad s + Ok (errs, nl', il', ixes') -> + case Instance.shrinkByType newinst . fst . last $ + sortBy (comparing snd) errs of + Bad _ -> Ok (errs, nl', il', ixes') + Ok newinst' -> + tieredAlloc nl' il' newinst' nreq ixes' -- * Formatting functions -- | Given the original and final nodes, computes the relocation description. -computeMoves :: String -- ^ The instance name - -> String -- ^ Original primary - -> String -- ^ Original secondary +computeMoves :: Instance.Instance -- ^ The instance to be moved + -> String -- ^ The instance name + -> IMove -- ^ The move being performed -> String -- ^ New primary -> String -- ^ New secondary -> (String, [String]) @@ -603,38 +685,16 @@ computeMoves :: String -- ^ The instance name -- either @/f/@ for failover or @/r:name/@ for replace -- secondary, while the command list holds gnt-instance -- commands (without that prefix), e.g \"@failover instance1@\" -computeMoves i a b c d = - if c == a then {- Same primary -} - if d == b then {- Same sec??! -} - ("-", []) - else {- Change of secondary -} - (printf "r:%s" d, - [printf "replace-disks -n %s %s" d i]) - else - if c == b then {- Failover and ... -} - if d == a then {- that's all -} - ("f", [printf "migrate -f %s" i]) - else - (printf "f r:%s" d, - [printf "migrate -f %s" i, - printf "replace-disks -n %s %s" d i]) - else - if d == a then {- ... and keep primary as secondary -} - (printf "r:%s f" c, - [printf "replace-disks -n %s %s" c i, - printf "migrate -f %s" i]) - else - if d == b then {- ... keep same secondary -} - (printf "f r:%s f" c, - [printf "migrate -f %s" i, - printf "replace-disks -n %s %s" c i, - printf "migrate -f %s" i]) - - else {- Nothing in common -} - (printf "r:%s f r:%s" c d, - [printf "replace-disks -n %s %s" c i, - printf "migrate -f %s" i, - printf "replace-disks -n %s %s" d i]) +computeMoves i inam mv c d = + case mv of + Failover -> ("f", [mig]) + FailoverAndReplace _ -> (printf "f r:%s" d, [mig, rep d]) + ReplaceSecondary _ -> (printf "r:%s" d, [rep d]) + ReplaceAndFailover _ -> (printf "r:%s f" c, [rep c, mig]) + ReplacePrimary _ -> (printf "f r:%s f" c, [mig, rep c, mig]) + where morf = if Instance.running i then "migrate" else "failover" + mig = printf "%s -f %s" morf inam::String + rep n = printf "replace-disks -n %s %s" n inam -- | Converts a placement to string format. printSolutionLine :: Node.List -- ^ The node list @@ -648,63 +708,160 @@ printSolutionLine :: Node.List -- ^ The node list printSolutionLine nl il nmlen imlen plc pos = let pmlen = (2*nmlen + 1) - (i, p, s, c) = plc + (i, p, s, mv, c) = plc inst = Container.find i il - inam = Instance.name inst - npri = Container.nameOf nl p - nsec = Container.nameOf nl s - opri = Container.nameOf nl $ Instance.pnode inst - osec = Container.nameOf nl $ Instance.snode inst - (moves, cmds) = computeMoves inam opri osec npri nsec - ostr = (printf "%s:%s" opri osec)::String - nstr = (printf "%s:%s" npri nsec)::String + inam = Instance.alias inst + npri = Node.alias $ Container.find p nl + nsec = Node.alias $ Container.find s nl + opri = Node.alias $ Container.find (Instance.pNode inst) nl + osec = Node.alias $ Container.find (Instance.sNode inst) nl + (moves, cmds) = computeMoves inst inam mv npri nsec + ostr = printf "%s:%s" opri osec::String + nstr = printf "%s:%s" npri nsec::String in (printf " %3d. %-*s %-*s => %-*s %.8f a=%s" pos imlen inam pmlen ostr pmlen nstr c moves, cmds) +-- | Return the instance and involved nodes in an instance move. +involvedNodes :: Instance.List -> Placement -> [Ndx] +involvedNodes il plc = + let (i, np, ns, _, _) = plc + inst = Container.find i il + op = Instance.pNode inst + os = Instance.sNode inst + in nub [np, ns, op, os] + +-- | Inner function for splitJobs, that either appends the next job to +-- the current jobset, or starts a new jobset. +mergeJobs :: ([JobSet], [Ndx]) -> MoveJob -> ([JobSet], [Ndx]) +mergeJobs ([], _) n@(ndx, _, _, _) = ([[n]], ndx) +mergeJobs (cjs@(j:js), nbuf) n@(ndx, _, _, _) + | null (ndx `intersect` nbuf) = ((n:j):js, ndx ++ nbuf) + | otherwise = ([n]:cjs, ndx) + +-- | Break a list of moves into independent groups. Note that this +-- will reverse the order of jobs. +splitJobs :: [MoveJob] -> [JobSet] +splitJobs = fst . foldl mergeJobs ([], []) + -- | Given a list of commands, prefix them with @gnt-instance@ and -- also beautify the display a little. -formatCmds :: [[String]] -> String -formatCmds cmd_strs = - unlines $ - concat $ map (\(a, b) -> - (printf "echo step %d" (a::Int)): - (printf "check"): - (map ("gnt-instance " ++) b)) $ - zip [1..] cmd_strs - --- | Converts a solution to string format. -printSolution :: Node.List - -> Instance.List - -> [Placement] - -> ([String], [[String]]) -printSolution nl il sol = - let - nmlen = Container.maxNameLen nl - imlen = Container.maxNameLen il - in - unzip $ map (uncurry $ printSolutionLine nl il nmlen imlen) $ - zip sol [1..] +formatJob :: Int -> Int -> (Int, MoveJob) -> [String] +formatJob jsn jsl (sn, (_, _, _, cmds)) = + let out = + printf " echo job %d/%d" jsn sn: + printf " check": + map (" gnt-instance " ++) cmds + in if sn == 1 + then ["", printf "echo jobset %d, %d jobs" jsn jsl] ++ out + else out + +-- | Given a list of commands, prefix them with @gnt-instance@ and +-- also beautify the display a little. +formatCmds :: [JobSet] -> String +formatCmds = + unlines . + concatMap (\(jsn, js) -> concatMap (formatJob jsn (length js)) + (zip [1..] js)) . + zip [1..] -- | Print the node list. -printNodes :: Node.List -> String -printNodes nl = - let snl = sortBy (compare `on` Node.idx) (Container.elems nl) - m_name = maximum . map (length . Node.name) $ snl - helper = Node.list m_name - header = printf - "%2s %-*s %5s %5s %5s %5s %5s %5s %5s %5s %3s %3s %7s %7s" - " F" m_name "Name" - "t_mem" "n_mem" "i_mem" "x_mem" "f_mem" "r_mem" - "t_dsk" "f_dsk" - "pri" "sec" "p_fmem" "p_fdsk" - in unlines $ (header:map helper snl) +printNodes :: Node.List -> [String] -> String +printNodes nl fs = + let fields = case fs of + [] -> Node.defaultFields + "+":rest -> Node.defaultFields ++ rest + _ -> fs + snl = sortBy (comparing Node.idx) (Container.elems nl) + (header, isnum) = unzip $ map Node.showHeader fields + in unlines . map ((:) ' ' . intercalate " ") $ + formatTable (header:map (Node.list fields) snl) isnum + +-- | Print the instance list. +printInsts :: Node.List -> Instance.List -> String +printInsts nl il = + let sil = sortBy (comparing Instance.idx) (Container.elems il) + helper inst = [ if Instance.running inst then "R" else " " + , Instance.name inst + , Container.nameOf nl (Instance.pNode inst) + , let sdx = Instance.sNode inst + in if sdx == Node.noSecondary + then "" + else Container.nameOf nl sdx + , printf "%3d" $ Instance.vcpus inst + , printf "%5d" $ Instance.mem inst + , printf "%5d" $ Instance.dsk inst `div` 1024 + , printf "%5.3f" lC + , printf "%5.3f" lM + , printf "%5.3f" lD + , printf "%5.3f" lN + ] + where DynUtil lC lM lD lN = Instance.util inst + header = [ "F", "Name", "Pri_node", "Sec_node", "vcpu", "mem" + , "dsk", "lCpu", "lMem", "lDsk", "lNet" ] + isnum = False:False:False:False:repeat True + in unlines . map ((:) ' ' . intercalate " ") $ + formatTable (header:map helper sil) isnum -- | Shows statistics for a given node list. printStats :: Node.List -> String printStats nl = - let (mem_cv, dsk_cv, n1_score, res_cv, off_score) = compDetailedCV nl - in printf "f_mem=%.8f, r_mem=%.8f, f_dsk=%.8f, n1=%.3f, uf=%.3f" - mem_cv res_cv dsk_cv n1_score off_score + let dcvs = compDetailedCV nl + (weights, names) = unzip detailedCVInfo + hd = zip3 (weights ++ repeat 1) (names ++ repeat "unknown") dcvs + formatted = map (\(w, header, val) -> + printf "%s=%.8f(x%.2f)" header val w::String) hd + in intercalate ", " formatted + +-- | Convert a placement into a list of OpCodes (basically a job). +iMoveToJob :: Node.List -> Instance.List + -> Idx -> IMove -> [OpCodes.OpCode] +iMoveToJob nl il idx move = + let inst = Container.find idx il + iname = Instance.name inst + lookNode = Just . Container.nameOf nl + opF = if Instance.running inst + then OpCodes.OpMigrateInstance iname True False + else OpCodes.OpFailoverInstance iname False + opR n = OpCodes.OpReplaceDisks iname (lookNode n) + OpCodes.ReplaceNewSecondary [] Nothing + in case move of + Failover -> [ opF ] + ReplacePrimary np -> [ opF, opR np, opF ] + ReplaceSecondary ns -> [ opR ns ] + ReplaceAndFailover np -> [ opR np, opF ] + FailoverAndReplace ns -> [ opF, opR ns ] + +-- | Computes the group of an instance +instanceGroup :: Node.List -> Instance.Instance -> Result GroupID +instanceGroup nl i = + let sidx = Instance.sNode i + pnode = Container.find (Instance.pNode i) nl + snode = if sidx == Node.noSecondary + then pnode + else Container.find sidx nl + puuid = Node.group pnode + suuid = Node.group snode + in if puuid /= suuid + then fail ("Instance placed accross two node groups, primary " ++ puuid ++ + ", secondary " ++ suuid) + else return puuid + +-- | Compute the list of badly allocated instances (split across node +-- groups) +findSplitInstances :: Node.List -> Instance.List -> [Instance.Instance] +findSplitInstances nl il = + filter (not . isOk . instanceGroup nl) (Container.elems il) + +-- | Splits a cluster into the component node groups +splitCluster :: Node.List -> Instance.List -> + [(GroupID, (Node.List, Instance.List))] +splitCluster nl il = + let ngroups = Node.computeGroups (Container.elems nl) + in map (\(guuid, nodes) -> + let nidxs = map Node.idx nodes + nodes' = zip nidxs nodes + instances = Container.filter ((`elem` nidxs) . Instance.pNode) il + in (guuid, (Container.fromAssocList nodes', instances))) ngroups