Although there has been one answer giving an algorithm using a Priority Queue (PQ) as in a SkewBinomialHeap, it is perhaps not the right PQ for the job. What the incremental Sieve of Eratosthenes (iEoS) requires is a PQ that has excellent performance for getting the minimum value and reinserting values mostly slightly further down the queue but doesn't need the ultimate in performance for adding new values as iSoE only adds as new values a total of the primes up to the the square root of the range (which is a tiny fraction of the number of re-insertions that occur once per reduction). The SkewBinomialHeap PQ doesn't really give much more than using the built-in Map which uses a balanced binary search tree - all O(log n) operations - other than it changes the weighting of the operations slightly in favour of the SoE's requirements. However, the SkewBinaryHeap still requires many O(log n) operations per reduction.

A PQ implemented as a Heap in more particular as a Binary Heap and even more particularly as a MinHeap pretty much satisfies iSoE's requirements with O(1) performance in getting the minimum and O(log n) performance for re-insertions and adding new entries, although the performance is actually a fraction of O(log n) as most of the re-insertions occur near the top of the queue and most of the additions of new values (which don't matter as they are infrequent) occur near the end of the queue where these operations are most efficient. In addition, the MinHeap PQ can efficiently implement the delete minimum and insert function in one (generally a fraction of) one O(log n) pass. Then, rather than for the Map (which is implemented as an AVL tree) where there is one O(log n) operation with generally a full 'log n' range due to the minimum value we require being at the far left last leaf of the tree, we are generally adding and removing the minimum at the root and inserting on the average of a few levels down in one pass. Thus the MinHeap PQ can be used with only one fraction of O(log n) operation per culling reduction rather than multiple larger fraction O(log n) operations.

The MinHeap PQ can be implemented with pure functional code (with no "removeMin" implemented as the iSoE doesn't require it but there is an "adjust" function for use in segmentation), as follows:

```
[<RequireQualifiedAccess>]
module MinHeap =
type MinHeapTreeEntry<'T> = class val k:uint32 val v:'T new(k,v) = { k=k;v=v } end
[<CompilationRepresentation(CompilationRepresentationFlags.UseNullAsTrueValue)>]
[<NoEquality; NoComparison>]
type MinHeapTree<'T> =
| HeapEmpty
| HeapOne of MinHeapTreeEntry<'T>
| HeapNode of MinHeapTreeEntry<'T> * MinHeapTree<'T> * MinHeapTree<'T> * uint32
let empty = HeapEmpty
let getMin pq = match pq with | HeapOne(kv) | HeapNode(kv,_,_,_) -> Some kv | _ -> None
let insert k v pq =
let kv = MinHeapTreeEntry(k,v)
let rec insert' kv msk pq =
match pq with
| HeapEmpty -> HeapOne kv
| HeapOne kv2 -> if k < kv2.k then HeapNode(kv,pq,HeapEmpty,2u)
else let nn = HeapOne kv in HeapNode(kv2,nn,HeapEmpty,2u)
| HeapNode(kv2,l,r,cnt) ->
let nc = cnt + 1u
let nmsk = if msk <> 0u then msk <<< 1
else let s = int32 (System.Math.Log (float nc) / System.Math.Log(2.0))
(nc <<< (32 - s)) ||| 1u //never ever zero again with the or'ed 1
if k <= kv2.k then if (nmsk &&& 0x80000000u) = 0u then HeapNode(kv,insert' kv2 nmsk l,r,nc)
else HeapNode(kv,l,insert' kv2 nmsk r,nc)
else if (nmsk &&& 0x80000000u) = 0u then HeapNode(kv2,insert' kv nmsk l,r,nc)
else HeapNode(kv2,l,insert' kv nmsk r,nc)
insert' kv 0u pq
let private reheapify kv k pq =
let rec reheapify' pq =
match pq with
| HeapEmpty -> HeapEmpty //should never be taken
| HeapOne kvn -> HeapOne kv
| HeapNode(kvn,l,r,cnt) ->
match r with
| HeapOne kvr when k > kvr.k ->
match l with //never HeapEmpty
| HeapOne kvl when k > kvl.k -> //both qualify, choose least
if kvl.k > kvr.k then HeapNode(kvr,l,HeapOne kv,cnt)
else HeapNode(kvl,HeapOne kv,r,cnt)
| HeapNode(kvl,_,_,_) when k > kvl.k -> //both qualify, choose least
if kvl.k > kvr.k then HeapNode(kvr,l,HeapOne kv,cnt)
else HeapNode(kvl,reheapify' l,r,cnt)
| _ -> HeapNode(kvr,l,HeapOne kv,cnt) //only right qualifies
| HeapNode(kvr,_,_,_) when k > kvr.k -> //need adjusting for left leaf or else left leaf
match l with //never HeapEmpty or HeapOne
| HeapNode(kvl,_,_,_) when k > kvl.k -> //both qualify, choose least
if kvl.k > kvr.k then HeapNode(kvr,l,reheapify' r,cnt)
else HeapNode(kvl,reheapify' l,r,cnt)
| _ -> HeapNode(kvr,l,reheapify' r,cnt) //only right qualifies
| _ -> match l with //r could be HeapEmpty but l never HeapEmpty
| HeapOne(kvl) when k > kvl.k -> HeapNode(kvl,HeapOne kv,r,cnt)
| HeapNode(kvl,_,_,_) when k > kvl.k -> HeapNode(kvl,reheapify' l,r,cnt)
| _ -> HeapNode(kv,l,r,cnt) //just replace the contents of pq node with sub leaves the same
reheapify' pq
let reinsertMinAs k v pq =
let kv = MinHeapTreeEntry(k,v)
reheapify kv k pq
let adjust f (pq:MinHeapTree<_>) = //adjust all the contents using the function, then rebuild by reheapify
let rec adjust' pq =
match pq with
| HeapEmpty -> pq
| HeapOne kv -> HeapOne(MinHeapTreeEntry(f kv.k kv.v))
| HeapNode (kv,l,r,cnt) -> let nkv = MinHeapTreeEntry(f kv.k kv.v)
reheapify nkv nkv.k (HeapNode(kv,adjust' l,adjust' r,cnt))
adjust' pq
```

Using the above module, the iSoE can be written with the wheel factorization optimizations and using efficient Co-Inductive Streams (CIS's) as follows:

```
type CIS<'T> = class val v:'T val cont:unit->CIS<'T> new(v,cont) = { v=v;cont=cont } end
type cullstate = struct val p:uint32 val wi:int new(cnd,cndwi) = { p=cnd;wi=cndwi } end
let primesPQWSE() =
let WHLPRMS = [| 2u;3u;5u;7u |] in let FSTPRM = 11u in let WHLCRC = int (WHLPRMS |> Seq.fold (*) 1u) >>> 1
let WHLLMT = int (WHLPRMS |> Seq.fold (fun o n->o*(n-1u)) 1u) - 1
let WHLPTRN =
let wp = Array.zeroCreate (WHLLMT+1)
let gaps (a:int[]) = let rec gap i acc = if a.[i]=0 then gap (i+1) (acc+1uy) else acc
{0..WHLCRC-1} |> Seq.fold (fun s i->
let ns = if a.[i]<>0 then wp.[s]<-2uy*gap (i+1) 1uy;(s+1) else s in ns) 0 |> ignore
Array.init (WHLCRC+1) (fun i->if WHLPRMS |> Seq.forall (fun p->(FSTPRM+uint32(i<<<1))%p<>0u)
then 1 else 0) |> gaps;wp
let inline whladv i = if i < WHLLMT then i + 1 else 0 in let advcnd c i = c + uint32 WHLPTRN.[i]
let inline culladv c p i = let n = c + uint32 WHLPTRN.[i] * p in if n < c then 0xFFFFFFFFu else n
let rec mkprm (n,wi,pq,(bps:CIS<_>),q) =
let nxt = advcnd n wi in let nxti = whladv wi
if nxt < n then (0u,0,(0xFFFFFFFFu,0,MinHeap.empty,bps,q))
elif n>=q then let bp,bpi = bps.v in let nc,nci = culladv n bp bpi,whladv bpi
let nsd = bps.cont() in let np,_ = nsd.v in let sqr = if np>65535u then 0xFFFFFFFFu else np*np
mkprm (nxt,nxti,(MinHeap.insert nc (cullstate(bp,nci)) pq),nsd,sqr)
else match MinHeap.getMin pq with | None -> (n,wi,(nxt,nxti,pq,bps,q))
| Some kv -> let ca,cs = culladv kv.k kv.v.p kv.v.wi,cullstate(kv.v.p,whladv kv.v.wi)
if n>kv.k then mkprm (n,wi,(MinHeap.reinsertMinAs ca cs pq),bps,q)
elif n=kv.k then mkprm (nxt,nxti,(MinHeap.reinsertMinAs ca cs pq),bps,q)
else (n,wi,(nxt,nxti,pq,bps,q))
let rec pCID p pi pq bps q = CIS((p,pi),fun()->let (np,npi,(nxt,nxti,npq,nbps,nq))=mkprm (advcnd p pi,whladv pi,pq,bps,q)
pCID np npi npq nbps nq)
let rec baseprimes() = CIS((FSTPRM,0),fun()->let np=FSTPRM+uint32 WHLPTRN.[0]
pCID np (whladv 0) MinHeap.empty (baseprimes()) (FSTPRM*FSTPRM))
let genseq sd = Seq.unfold (fun (p,pi,pcc) ->if p=0u then None else Some(p,mkprm pcc)) sd
seq { yield! WHLPRMS; yield! mkprm (FSTPRM,0,MinHeap.empty,baseprimes(),(FSTPRM*FSTPRM)) |> genseq }
```

The above code calculates the first 100,000 primes in about 0.077 seconds, the first 1,000,000 primes in 0.977 seconds, the first 10,000,000 primes in about 14.33 seconds, and the first 100,000,000 primes in about 221.87 seconds, all on an i7-2700K (3.5GHz) as 64-bit code. This purely functional code is slightly faster than that of Dustin Cambell's mutable Dictionary based code with the added common optimizations of wheel factorization, deferred adding of base primes, and use of the more efficient CID's all added (tryfsharp and ideone) **but is still pure functional code where his using the Dictionary class is not**. However, for larger prime ranges of about of about two billion (about 100 million primes), the code using the hash table based Dictionary will be faster as the Dictionary operations do not have a O(log n) factor and this gain overcomes the computational complexity of using Dictionary hash tables.

The above program has the further feature that the factorization wheel is parameterized so that, for instance, one can use a extremely large wheel by setting WHLPRMS to [| 2u;3u;5u;7u;11u;13u;17u;19u |] and FSTPRM to 23u to get a run time of about two thirds for large ranges at about 9.34 seconds for ten million primes, although note that it takes several seconds to compute the WHLPTRN before the program starts to run, which is a constant overhead no matter the prime range.

**Comparative Analysis**: As compared to the pure functional incremental tree folding implementation, this algorithm is just slightly faster because the average used height of the MinHeap tree is less by a factor of two than the depth of the folded tree but that is offset by an equivalent constant factor loss in efficiency in ability to traverse the PQ tree levels due to it being based on a binary heap requiring processing of both the right and left leaves for every heap level and a branch either way rather than a single comparison per level for the tree folding with generally the less deep branch the taken one. As compared to other PQ and Map based functional algorithms, improvements are generally by a constant factor in reducing the number of O(log n) operations in traversing each level of the respective tree structures.

The MinHeap is usually implemented as a mutable array binary heap after a genealogical tree based model invented by Michael Eytzinger over 400 years ago. I know the question said there was no interest in non-functional mutable code, but if one must avoid all sub code that uses mutability, then we couldn't use list's or LazyList's which use mutability "under the covers" for performance reasons. So imagine that the following alternate mutable version of the MinHeap PQ is as supplied by a library and enjoy another factor of over two for larger prime ranges in performance:

```
[<RequireQualifiedAccess>]
module MinHeap =
type MinHeapTreeEntry<'T> = class val k:uint32 val v:'T new(k,v) = { k=k;v=v } end
type MinHeapTree<'T> = ResizeArray<MinHeapTreeEntry<'T>>
let empty<'T> = MinHeapTree<MinHeapTreeEntry<'T>>()
let getMin (pq:MinHeapTree<_>) = if pq.Count > 0 then Some pq.[0] else None
let insert k v (pq:MinHeapTree<_>) =
if pq.Count = 0 then pq.Add(MinHeapTreeEntry(0xFFFFFFFFu,v)) //add an extra entry so there's always a right max node
let mutable nxtlvl = pq.Count in let mutable lvl = nxtlvl <<< 1 //1 past index of value added times 2
pq.Add(pq.[nxtlvl - 1]) //copy bottom entry then do bubble up while less than next level up
while ((lvl <- lvl >>> 1); nxtlvl <- nxtlvl >>> 1; nxtlvl <> 0) do
let t = pq.[nxtlvl - 1] in if t.k > k then pq.[lvl - 1] <- t else lvl <- lvl <<< 1; nxtlvl <- 0 //causes loop break
pq.[lvl - 1] <- MinHeapTreeEntry(k,v); pq
let reinsertMinAs k v (pq:MinHeapTree<_>) = //do minify down for value to insert
let mutable nxtlvl = 1 in let mutable lvl = nxtlvl in let cnt = pq.Count
while (nxtlvl <- nxtlvl <<< 1; nxtlvl < cnt) do
let lk = pq.[nxtlvl - 1].k in let rk = pq.[nxtlvl].k in let oldlvl = lvl
let k = if k > lk then lvl <- nxtlvl; lk else k in if k > rk then nxtlvl <- nxtlvl + 1; lvl <- nxtlvl
if lvl <> oldlvl then pq.[oldlvl - 1] <- pq.[lvl - 1] else nxtlvl <- cnt //causes loop break
pq.[lvl - 1] <- MinHeapTreeEntry(k,v); pq
let adjust f (pq:MinHeapTree<_>) = //adjust all the contents using the function, then re-heapify
if pq <> null then
let cnt = pq.Count
if cnt > 1 then
for i = 0 to cnt - 2 do //change contents using function
let e = pq.[i] in let k,v = e.k,e.v in pq.[i] <- MinHeapTreeEntry (f k v)
for i = cnt/2 downto 1 do //rebuild by reheapify
let kv = pq.[i - 1] in let k = kv.k
let mutable nxtlvl = i in let mutable lvl = nxtlvl
while (nxtlvl <- nxtlvl <<< 1; nxtlvl < cnt) do
let lk = pq.[nxtlvl - 1].k in let rk = pq.[nxtlvl].k in let oldlvl = lvl
let k = if k > lk then lvl <- nxtlvl; lk else k in if k > rk then nxtlvl <- nxtlvl + 1; lvl <- nxtlvl
if lvl <> oldlvl then pq.[oldlvl - 1] <- pq.[lvl - 1] else nxtlvl <- cnt //causes loop break
pq.[lvl - 1] <- kv
pq
```

Geek note: I had actually expected the mutable version to offer a much better improved performance ratio, but it bogs down in the re-insertions due to the nested if-then-else code structure and the random behavior of the prime cull values meaning that the CPU branch prediction fails for a large proportion of the branches resulting in many additional 10's of CPU clock cycles per cull reduction to rebuilt the instruction pre-fetch cache.

The only other constant factor performance gains on this algorithm would be segmentation and use of multi-tasking for a performance gain proportional to the number of CPU cores; however, as it stands, this is the fastest pure functional SoE algorithm to date, and even the pure functional form using the functional MinHeap beats simplistic imperative implementations such as Jon Harrop's code or Johan Kullbom's Sieve of Atkin (which is in error in his timing as he only calculated the **primes to 10 million rather than the 10 millionth prime**), but those algorithms would be about five times faster if better optimizations were used. That ratio of about five between functional and imperative code will be somewhat reduced when we add multi-threading of larger wheel factorization as the computational complexity of the imperative code increases faster than the functional code and multi-threading helps the slower functional code more than the faster imperative code as the latter gets closer to the base limit of the time required to enumerate through the found primes.

**EDIT_ADD:** Even though one could elect to continue to use the pure functional version of MinHeap, adding **efficient** segmentation in preparation for multi-threading would slightly "break" the "pureness" of the functional code as follows: 1) The most efficient way of transferring a representation of composite-culled primes is a packed-bit array the size of the segment, 2) While the size of the array is known, using an array comprehension to initialize it in a functional way isn't efficient as it uses "ResizeArray" under the covers which needs to copy itself for every x additions (I think 'x' is eight for the current implementation) and using Array.init doesn't work as many values at particular indexes are skipped, 3) Therefore, the easiest way to fill the culled-composite array is to zeroCreate it of the correct size and then run an initialization function which could write to each mutable array index no more than once. Although this isn't strictly "functional", it is close in that the array is initialized and then never modified again.

The code with added segmentation, multi-threading, programmable wheel factorial circumference, and many performance tweaks is as follows (other than some added new constants, the extra tuned code to implement the segmentation and multi-threading is the bottom approximately half of the code starting at the "prmspg" function):

```
type prmsCIS = class val pg:uint16 val bg:uint16 val pi:int val cont:unit->prmsCIS
new(pg,bg,pi,nxtprmf) = { pg=pg;bg=bg;pi=pi;cont=nxtprmf } end
type cullstate = struct val p:uint32 val wi:int new(cnd,cndwi) = { p=cnd;wi=cndwi } end
let primesPQOWSE() =
let WHLPRMS = [| 2u;3u;5u;7u;11u;13u;17u |] in let FSTPRM = 19u in let WHLCRC = int(WHLPRMS |> Seq.fold (*) 1u)
let MXSTP = uint64(FSTPRM-1u) in let BFSZ = 1<<<11 in let NUMPRCS = System.Environment.ProcessorCount
let WHLLMT = int (WHLPRMS |> Seq.fold (fun o n->o*(n-1u)) 1u) - 1 in let WHLPTRN = Array.zeroCreate (WHLLMT+1)
let WHLRNDUP = let gaps (a:int[]) = let rec gap i acc = if a.[i]=0 then gap (i+1) (acc+1)
else acc in let b = a |> Array.scan (+) 0
Array.init (WHLCRC>>>1) (fun i->
if a.[i]=0 then 0 else let g=2*gap (i+1) 1 in WHLPTRN.[b.[i]]<-byte g;1)
Array.init WHLCRC (fun i->if WHLPRMS |> Seq.forall (fun p->(FSTPRM+uint32(i<<<1))%p<>0u) then 1 else 0)
|> gaps |> Array.scan (+) 0
let WHLPOS = WHLPTRN |> Array.map (uint32) |> Array.scan (+) 0u in let advcnd cnd cndi = cnd + uint32 WHLPTRN.[cndi]
let MINRNGSTP = if WHLLMT<=31 then uint32(32/(WHLLMT+1)*WHLCRC) else if WHLLMT=47 then uint32 WHLCRC<<<1 else uint32 WHLCRC
let MINBFRNG = uint32((BFSZ<<<3)/(WHLLMT+1)*WHLCRC)/MINRNGSTP*MINRNGSTP
let MINBFRNG = if MINBFRNG=0u then MINRNGSTP else MINBFRNG
let inline whladv i = if i < WHLLMT then i+1 else 0 in let inline culladv c p i = c+uint32 WHLPTRN.[i]*p
let rec mkprm (n,wi,pq,(bps:prmsCIS),q,lstp,bgap) =
let nxt,nxti = advcnd n wi,whladv wi
if n>=q then let p = (uint32 bps.bg<<<16)+uint32 bps.pg
let nbps,nxtcmpst,npi = bps.cont(),culladv n p bps.pi,whladv bps.pi
let pg = uint32 nbps.pg in let np = p+pg in let sqr = q+pg*((p<<<1)+pg) //only works to p < about 13 million
let nbps = prmsCIS(uint16 np,uint16(np>>>16),nbps.pi,nbps.cont) //therefore, algorithm only works to p^2 or about
mkprm (nxt,nxti,(MinHeap.insert nxtcmpst (cullstate(p,npi)) pq),nbps,sqr,lstp,(bgap+1us)) //1.7 * 10^14
else match MinHeap.getMin pq with
| None -> (uint16(n-uint32 lstp),bgap,wi,(nxt,nxti,pq,bps,q,n,1us)) //fix with q is uint64
| Some kv -> let ca,cs = culladv kv.k kv.v.p kv.v.wi,cullstate(kv.v.p,whladv kv.v.wi)
if n>kv.k then mkprm (n,wi,(MinHeap.reinsertMinAs ca cs pq),bps,q,lstp,bgap)
elif n=kv.k then mkprm (nxt,nxti,(MinHeap.reinsertMinAs ca cs pq),bps,q,lstp,(bgap+1us))
else (uint16(n-uint32 lstp),bgap,wi,(nxt,nxti,pq,bps,q,n,1us))
let rec pCIS p pg bg pi pq bps q = prmsCIS(pg,bg,pi,fun()->
let (npg,nbg,npi,(nxt,nxti,npq,nbps,nq,nl,ng))=mkprm (p+uint32 WHLPTRN.[pi],whladv pi,pq,bps,q,p,0us)
pCIS (p+uint32 npg) npg nbg npi npq nbps nq)
let rec baseprimes() = prmsCIS(uint16 FSTPRM,0us,0,fun()->
let np,npi=advcnd FSTPRM 0,whladv 0
pCIS np (uint16 WHLPTRN.[0]) 1us npi MinHeap.empty (baseprimes()) (FSTPRM*FSTPRM))
let prmspg nxt adj pq bp q =
//compute next buffer size rounded up to next even wheel circle so at least one each base prime hits the page
let rng = max (((uint32(MXSTP+uint64(sqrt (float (MXSTP*(MXSTP+4UL*nxt))))+1UL)>>>1)+MINRNGSTP)/MINRNGSTP*MINRNGSTP) MINBFRNG
let nxtp() = async {
let rec addprms pqx (bpx:prmsCIS) qx =
if qx>=adj then pqx,bpx,qx //add primes to queue for new lower limit
else let p = (uint32 bpx.bg<<<16)+uint32 bpx.pg in let nbps = bpx.cont()
let pg = uint32 nbps.pg in let np = p+pg in let sqr = qx+pg*((p<<<1)+pg)
let nbps = prmsCIS(uint16 np,uint16(np>>>16),nbps.pi,nbps.cont)
addprms (MinHeap.insert qx (cullstate(p,bpx.pi)) pqx) nbps sqr
let adjcinpg low k (v:cullstate) = //adjust the cull states for the new page low value
let p = v.p in let WHLSPN = int64 WHLCRC*int64 p in let db = int64 p*int64 WHLPOS.[v.wi]
let db = if k<low then let nk = int64(low-k)+db in nk-((nk/WHLSPN)*WHLSPN)
else let nk = int64(k-low) in if db<nk then db+WHLSPN-nk else db-nk
let r = WHLRNDUP.[int((((db>>>1)%(WHLSPN>>>1))+int64 p-1L)/int64 p)] in let x = int64 WHLPOS.[r]*int64 p
let r = if r>WHLLMT then 0 else r in let x = if x<db then x+WHLSPN-db else x-db in uint32 x,cullstate(p,r)
let bfbtsz = int rng/WHLCRC*(WHLLMT+1) in let nbuf = Array.zeroCreate (bfbtsz>>>5)
let rec nxtp' wi cnt = let _,nbg,_,ncnt = mkprm cnt in let nwi = wi + int nbg
if nwi < bfbtsz then nbuf.[nwi>>>5] <- nbuf.[nwi>>>5] ||| (1u<<<(nwi&&&0x1F)); nxtp' nwi ncnt
else let _,_,pq,bp,q,_,_ = ncnt in nbuf,pq,bp,q //results incl buf and cont parms for next page
let npq,nbp,nq = addprms pq bp q
return nxtp' 0 (0u,0,MinHeap.adjust (adjcinpg adj) npq,nbp,nq-adj,0u,0us) }
rng,nxtp() |> Async.StartAsTask
let nxtpg nxt (cont:(_*System.Threading.Tasks.Task<_>)[]) = //(len,pq,bp,q) =
let adj = (cont |> Seq.fold (fun s (r,_) -> s+r) 0u)
let _,tsk = cont.[0] in let _,pq,bp,q = tsk.Result
let ncont = Array.init (NUMPRCS+1) (fun i -> if i<NUMPRCS then cont.[i+1]
else prmspg (nxt+uint64 adj) adj pq bp q)
let _,tsk = ncont.[0] in let nbuf,_,_,_ = tsk.Result in nbuf,ncont
//init cond buf[0], no queue, frst bp sqr offset
let initcond = 0u,System.Threading.Tasks.Task.Factory.StartNew (fun()->
(Array.empty,MinHeap.empty,baseprimes(),FSTPRM*FSTPRM-FSTPRM))
let nxtcond n = prmspg (uint64 n) (n-FSTPRM) MinHeap.empty (baseprimes()) (FSTPRM*FSTPRM-FSTPRM)
let initcont = Seq.unfold (fun (n,((r,_)as v))->Some(v,(n+r,nxtcond (n+r)))) (FSTPRM,initcond)
|> Seq.take (NUMPRCS+1) |> Seq.toArray
let rec nxtprm (c,ci,i,buf:uint32[],cont) =
let rec nxtprm' c ci i =
let nc = c + uint64 WHLPTRN.[ci] in let nci = whladv ci in let ni = i + 1 in let nw = ni>>>5
if nw >= buf.Length then let (npg,ncont)=nxtpg nc cont in nxtprm (c,ci,-1,npg,ncont)
elif (buf.[nw] &&& (1u <<< (ni &&& 0x1F))) = 0u then nxtprm' nc nci ni
else nc,nci,ni,buf,cont
nxtprm' c ci i
seq { yield! WHLPRMS |> Seq.map (uint64);
yield! Seq.unfold (fun ((c,_,_,_,_) as cont)->Some(c,nxtprm cont))
(nxtprm (uint64 FSTPRM-uint64 WHLPTRN.[WHLLMT],WHLLMT,-1,Array.empty,initcont)) }
```

Note that the MinHeap modules, both functional and array-based, have had an "adjust" function added to permit adjusting of the cull state of each thread's version of the PQ at the beginning of every new segment page. Also note that it was possible to adjust the code so that most of the computation is done using 32 bit ranges with the final sequence output as uint64's at little cost in computational time so that currently the theoretical range is something over 100 trillion (ten raised to the fourteen power) if one were willing to wait the about three to four months required to compute that range. The numeric range checks were removed as it is unlikely that anyone would use this algorithm to compute up to that range let alone past it.

Using the pure functional MinHeap and 2,3,5,7 wheel factorization, the above program computes the first hundred thousand, one million, ten million, and a hundred million primes in 0.062, 0.629, 10.53, and 195.62 seconds, respectively. Using the array-based MinHeap speeds this up to 0.097, 0.276, 3.48, and 51.60 seconds, respectively. Using the 2,3,5,7,11,13,17 wheel by changing WHLPRMS to "[| 2u;3u;5u;7u;11u;13u;17u |]" and FSTPRM to 19u speeds that up yet a little more to 0.181, 0.308, 2.49, and 36.58 seconds, respectively (for constant factor improvement with a constant overhead). This fastest tweak calculates the 203,280,221 primes in the 32-bit number range in about 88.37 seconds. The "BFSZ" constant can be adjusted with trade-offs between slower times for smaller ranges version faster times for larger ranges, with a value of "1<<<14" recommended to be tried for the larger ranges. This constant only sets the minimum buffer size, with the program adjusting the buffer size above that size automatically for larger ranges such that the buffer is sufficient so that the largest base prime required for the page range will always "strike" each page at least once; this means that the complexity and overhead of an additional "bucket sieve" is not required. This last fully optimized version can compute the primes up to 10 and 100 billion in about 256.8 and 3617.4 seconds (just over an hour for the 100 billion) as tested using "primesPQOWSE() |> Seq.takeWhile ((>=)100000000000UL) |> Seq.fold (fun s p -> s + 1UL) 0UL" for output. This is where the estimates of about half a day for the count of primes to a trillion, a week for up to ten trillion and about three to four months for up to a hundred trillion come from.

I don't think it's possible to make functional or almost functional code using the incremental SoE algorithm to run much faster than this. As one can see in looking at the code, optimizing the basic incremental algorithm has added greatly to the code complexity such that it is likely slightly more complex than equivalently optimized code based on straight array culling with that code able to run approximately ten times faster than this and without the extra exponent in the performance meaning that this functional incremental code has an ever increasing extra percentage overhead.

So is this useful other than from an interesting theoretical and intellectual viewpoint? Probably it's not. For smaller ranges of primes up to about ten million, the best of the basic not fully optimized incremental functional SoE's are probably adequate and quite simple to write or have less RAM memory use than the simplest imperative SoE's. However, they are much slower than more imperative code using an array so they "run out of steam" for ranges above that. While it has been demonstrated here that the code can be sped up by optimization, it is still 10's of times slower than a more imperative pure array-based version yet has added to the complexity to be at least as complex as that code with equivalent optimizations, and even that code under F# on DotNet is about four times slower than using a language such as C++ compiled directly to native code; if one really wanted to investigate large ranges of primes, one would likely use one of those other languages and techniques where primesieve can calculate the number of primes in the hundred trillion range in under four hours instead of the about three months required for this code. **END_EDIT_ADD**

Neveruse a again!" You can give this a pure semantics, even though you have an impure implementation. In Mercury, for example, the array update function does this and the Mercury mode systemguaranteesthat your program will never be allowed to use a again. – Rafe Jan 10 '11 at 2:51neveruse 'a' again" constraint is exactly what Haskell's State and IO monads guarantee or what Mercury's unique modes guarantee. In Haskell, you never actually get your hands on the array itself because its hidden inside the monad and the monad ain't never going to give it to you! In Mercury, any updates to the array produce a new "unique" array and render the old array "dead" (never to be accessed again). Of course, the new array is exactly the old array after a destructive update. – Rafe Jan 11 '11 at 6:28